MT25-ProgramBook
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WELCOME<br />
On behalf of the Organizing and Program Committees, it is a great<br />
pleasure for us warmly welcoming you at the 25th International<br />
Conference on Magnet Technology in 2017, from August 27 to<br />
September 1 in Amsterdam, the Netherlands.<br />
It is the first time that a Magnet Technology conference is hosted<br />
in the Netherlands and for this reason, we have chosen the capital<br />
city of Amsterdam and its RAI Congress Center, a natural and<br />
perfect choice.<br />
The conference organization is a joint effort of the Applied Superconductivity<br />
and Cryogenics Laboratory at the University of<br />
Twente and the High Field Magnet Laboratory of the Radboud<br />
University Nijmegen.<br />
The conference covers plenary, oral and poster sessions and an<br />
exhibition of 49 industrial partners from Monday until Thursday.<br />
You are warmly invited to join us on Sunday for the Welcome reception,<br />
on Tuesday for the Exhibitor’s reception, and finally for<br />
the Conference Banquet on Thursday evening in the National<br />
Maritime Museum. Technical visits to five laboratories on Friday<br />
conclude the program.<br />
During the Conference opening session the IEEE Council on Superconductivity<br />
awards the ‘Award for Continuing and Significant<br />
Contributions in the Field of Large-Scale Applications of Superconductivity’,<br />
the ‘Max Swerdlow Award for Sustained Service to<br />
the Applied Superconductivity Community’ and finally the ‘Graduate<br />
Study Fellowship in Applied Superconductivity’.<br />
In addition, <strong>MT25</strong> Best Poster Awards are presented during the<br />
conference closing session on Thursday.<br />
We wish you all a great stay in the Netherlands and we truly hope<br />
for an inspiring meeting and pleasant week together.<br />
On behalf of all organizers,<br />
Herman ten Kate<br />
Andries den Ouden<br />
1
Sponsors<br />
The <strong>MT25</strong> Organizers express their appreciation to the following<br />
sponsors whose contributions significantly enhance the conference.<br />
Gold<br />
Silver<br />
2
Table of Contents<br />
Quick reference………………………………………….. 5<br />
Amsterdam cultural highlights and entertainment …… 7<br />
Awards…………………………………………………..... 7<br />
Social events………………………………………….….. 7<br />
Author information……………………………………..… 11<br />
Information for Poster presenters……………. 11<br />
Information for Oral presenters…………….… 11<br />
Information for Paper submission……….…… 11<br />
Technical visits on Friday……………………………….. 12<br />
Conference organization…………………………….….. 16<br />
Editors IEEE-TAS for the <strong>MT25</strong> Special Issue……….. 18<br />
Exhibitors…………………..……………………………… 18<br />
Floorplan………………………………………………….. 43<br />
Technical Program………………………………….…… 45<br />
Monday program….…………………………… 45<br />
Tuesday program….………………………….. 80<br />
Wednesday program.……………………….… 116<br />
Thursday program…….………………………. 152<br />
Friday program………….…………………….. 183<br />
Author list……………………………………….....…... 184<br />
3
4
Quick reference<br />
Conference website and e-mail address<br />
http://www.mt-25.org and info@mt-25.org<br />
Venue<br />
RAI Convention Amsterdam<br />
Europaplein 2-22, 1078 GZ Amsterdam, the Netherlands.<br />
Registration & information desk<br />
On Sunday the registration desk is in the Elicium building, entrance<br />
D. The rest of the week it is located at the entrance of the<br />
conference center, entrance G.<br />
Opening hours:<br />
on Sunday: 16.00-20.15 (Elicium building)<br />
on Monday through Thursday: 08.00-18.30.<br />
Badge<br />
Upon registration, participants receive a conference badge. For<br />
safety and security reasons please wear your badge visibly during<br />
all conference events.<br />
Publication office<br />
The Conference Publication Office is in room G104.<br />
The opening hours of the Publication Office are:<br />
Monday August 28 08:00-18:00<br />
Tuesday August 29 08:00-18:00<br />
Wednesday August 30 08:00-18:00<br />
Thursday August 31 08:00-17:00<br />
The deadline for paper submission is:<br />
Tuesday August 29, 2017 (24:00 CET).<br />
Speaker’s preparation room<br />
The speaker’s preparation room is G104 (except on Sunday). The<br />
office is open for previewing and uploading your presentations in<br />
.ppt or .pdf format. The opening hours are the same as for the<br />
Publication office.<br />
Message board<br />
A message board is located near to the registration desk at entrance<br />
of the conference center. It is used for conference announcements,<br />
ad-hoc meeting calls, personal messages, and job<br />
postings.<br />
Access to the WIFI network<br />
Network: CONGRESSWIFI<br />
Password: congress@rai<br />
5
6
Parking<br />
There are plenty paid car parks at RAI-Amsterdam.<br />
Dutch Railways (NS) train journey planner<br />
http://www.ns.nl<br />
Emergencies<br />
Dial 112 for Police, Fire Brigade and Medical Service.<br />
Amsterdam cultural highlights and entertainment<br />
http://www.iamsterdam.com/en<br />
See also our conference website:<br />
http://mt-25.org/venue/touristic tips.html<br />
Awards<br />
The following awards are presented at the conference opening<br />
session on the Monday morning at 9:00:<br />
The IEEE Award for Continuing and Significant Contributions in<br />
the Field of Applied Superconductivity, Large Scale, will be presented<br />
to Evgeny Yu. Klimenko.<br />
The IEEE Max Swerdlow Award for Sustainable Service to the<br />
Applied Superconductivity Community is presented to Kenichi<br />
Sato from the Japan Science and technology Agency.<br />
The IEEE-CSC Graduate Study Fellowship in Applied Super-conductivity<br />
is presented to Federico Scurti from the North Carolina<br />
State University, USA.<br />
The <strong>MT25</strong> Best Poster Awards, selected during the conference<br />
are presented in the Conference Closing session.<br />
Social events<br />
Welcome Reception<br />
The Welcome reception will take place on Sunday August 27 in<br />
the Elicium Ballroom at the RAI Convention Center, entrance D.<br />
The reception starts at 19:00 and ends at 20:30. Served are a<br />
buffet type meal and free drinks.<br />
Exhibitors Reception<br />
On Tuesday August 29, the exhibitors host a reception that will<br />
take place in the conference exhibition area. The reception starts<br />
at 18:45 and finishes at 20:15. Served are a buffet type meal and<br />
free drinks. Enjoy the excitement of the <strong>MT25</strong>’s exhibition while<br />
socializing with exhibitors and other conference participants.<br />
7
8
Conference Banquet<br />
The conference banquet is organized at the National Maritime<br />
Museum in Amsterdam, street address Kattenburgerplein 1, 1018<br />
KK Amsterdam.<br />
The banquet starts at 19:30 and finishes at 22:00.<br />
Especially for this occasion, we have arranged a boat tour through<br />
the historic canals of Amsterdam for about one hour to bring you<br />
from the RAI Convention Center to the Maritime Museum. Departure<br />
is starting at 18:00 from the backside of the conference center.<br />
On your way back, you may wish to walk and enjoy the cities secrets<br />
downtown, or use directly the Metro or the Tram to travel<br />
back to your hotel, both within few minutes waling distance from<br />
the museum.<br />
Amsterdam is a bustling city. Few cities in the world have a historic<br />
center as large and untouched as Amsterdam and you will<br />
find only a few cities where water is as predominant as it is in<br />
Amsterdam.<br />
While gliding through the old center of the city, guides will tell you<br />
more about the historical highlights and the beauty of the city of<br />
Amsterdam.<br />
The National Maritime Museum in Amsterdam shows you how the<br />
sea has shaped our Dutch culture. Stimulating, interactive exhibitions<br />
allow visitors to explore 500 years of maritime history.<br />
The National Maritime Museum is housed in ’s Lands Zee-magazijn<br />
(the Arsenal). This historic building dates from 1656 and was<br />
designed by Daniel Stalpaert as a storehouse for the Admiralty of<br />
Amsterdam.<br />
The Arsenal was built in the Golden Age, when Amsterdam was<br />
the largest port and market place in the world. Goods from all over<br />
the world could be bought right here.<br />
Today, over 350 years later, the Arsenal remains an imposing and<br />
impressive building with a great deal of character. It exudes history,<br />
making it the perfect location for The National Maritime Museum<br />
housed here since 1973.<br />
9
10
Author information<br />
Information for Poster presentations<br />
Posters are on display for a full day. You, as presenter shall be<br />
present for explanation during the scheduled poster session time<br />
of about 2 hours, see the technical program for details.<br />
All posters are made available online through the conference indico<br />
site. If you have not yet uploaded your poster please bring<br />
the pdf of your poster on a USB stick to the Publication Office (the<br />
opening hours are shown above).<br />
All poster boards will be provided with an order number. In the<br />
Technical Program section you can find your poster ID number<br />
and the poster board number. The assigned poster ID number<br />
should be included in each poster presentation.<br />
Posters HANG-UP and TAKE-DOWN times:<br />
Posters shall be hang up on the poster boards between 8:00-<br />
10:30, preferably before the plenary session starts.<br />
Posters shall be removed from the board between 17:30 and<br />
18:30. Posters left behind after 18:30 will be disposed (on<br />
Thursday before 17:30).<br />
Please remove your poster promptly. Posters are fixed to the<br />
board with tape, which is provided. Do not use other tape.<br />
Information for Oral presentations<br />
Regular Oral Presentations are 15 minutes in total, which includes<br />
3 minutes for questions. Invited Orals are 30 minutes, including 5<br />
minutes for discussion.<br />
Please arrive at least 10 minutes before the session start and introduce<br />
yourself to the session chairs.<br />
Oral presentations in MS PowerPoint 2013 fomat or in pdf format<br />
shall be submitted the day prior to the presentation at the Publications<br />
Office (opening hours are shown above).<br />
All presentations are available online for reading and download<br />
through the conference indico site. If you have not yet uploaded<br />
your presentation, bring the pdf of your presentation on a USB<br />
stick to the Publication Office, room G104.<br />
Oral presentations for the Monday sessions can be submitted at<br />
a temporary Publication Desk next to the registration desk in the<br />
Elicium building.<br />
Deadline for Paper submission<br />
The deadline for paper submission is Tuesday August 29, 2017<br />
(24:00 CET).<br />
11
Technical visits on the Friday<br />
All technical visits start at 8:30 from parking lot P6, at the southeast<br />
corner of the RAI (see map on page 14).<br />
If you need to catch a plane afterwards, please note that it takes<br />
about 30 minutes to get from RAI to Schiphol Airport.<br />
Visit 1<br />
The Dutch National Institute for Subatomic Physics, NIKHEF<br />
and Science Park in Amsterdam<br />
A high-tech tour of the NIKHEF facilities with specific focus on the<br />
new Einstein Telescope project, low-vibration interferometry systems<br />
and the design and assembly of particle detectors.<br />
08:30 Departure from RAI at parking P6<br />
12:30 Return at RAI parking P6<br />
12
Visit 2<br />
The European Space Research and Technology Center ES-<br />
TEC, in Noordwijk, the Netherlands<br />
This visit to ESA’s main technology department includes a tour of<br />
the Erasmus Space Exhibition Center, the Planetary Robotics Laboratory<br />
and Virtual Reality Theater.<br />
08:30 Departure from RAI parking P6<br />
13:00 Return at RAI parking P6<br />
Visit 3<br />
Philips Healthcare, Best, the Netherlands, and<br />
the Dutch Institute for Fundamental Energy Research DIF-<br />
FER, Eindhoven<br />
This excursion to the Eindhoven region combines first a tour of<br />
the fusion research facilities at DIFFER including the superconducting<br />
magnet system Magnum used for plasma-wall interaction<br />
studies; and second, a visit of the Philips Healthcare R&D center<br />
in Best, focusing on the design, testing, training on and demonstration<br />
of MRI systems<br />
08:30 Departure from RAI parking P6<br />
18:00 Return at RAI parking P6<br />
Visit 4<br />
The High Field Magnet Laboratory, HFML<br />
at the Radboud University, Nijmegen, the Netherlands<br />
The Radboud University in Nijmegen is home of the High Field<br />
Magnet Laboratory and the adjacent FELIX Laboratory equipped<br />
with a series of infrared free-electron lasers. Both laboratories are<br />
included in the tour.<br />
08:30 Departure from RAI parking P6<br />
17:30 Return at RAI parking P6<br />
Visit 5<br />
The Applied Superconductivity and Cryogenics Labs, and<br />
the MESA+ Nano-Technology Institute at the University of<br />
Twente, Enschede, the Netherlands<br />
At the University of Twente, a tour of the Twente Cryogenic and<br />
Applied Superconductivity Laboratories is combined with a visit<br />
of the Institute for Nanotechnology MESA+<br />
08:30 Departure from RAI parking P6<br />
18:30 Return at RAI parking P<br />
13
14
Busses for the technical visits<br />
will park here and leave at 8:30.<br />
15
Conference organization<br />
MT International Organizing Committee<br />
Name Country Institute<br />
Mark Bird USA NHMFL<br />
Pierluigi Bruzzone Switzerland CRPP<br />
Haigun Lee Korea Korea University<br />
Luis Garcia-Tabares Spain<br />
CIEMAT<br />
Fedor Gömöry Slovakia SAS<br />
Hitoshi Kitaguchi Japan NIMS<br />
Ziad Melhem UK Oxford Instruments<br />
Antti Stenvall Finland TUT<br />
Neil Mitchell<br />
ITER<br />
Riccardo Musenich Italy INFN<br />
Mathias Noe Germany KIT<br />
Ruediger Picker Canada TRIUMF<br />
Subrata Pradhan India IPR<br />
Lucio Rossi<br />
CERN<br />
Bruce Strauss<br />
IEEE-CSC<br />
Herman ten Kate The Netherlands University of Twente<br />
Pierre Vedrine France CEA<br />
Vitaly Vyotsky Russia VNIIKP<br />
Liye Xiao China IEE<br />
Ex-officio members:<br />
Herman ten Kate LOC, Conference Chairman<br />
Andries den Ouden LOC, Conference Co-chairman<br />
Local Organizing Committee<br />
Conference Chairman Herman ten Kate<br />
Conference Co-chairman Andries den Ouden<br />
Program Chairman Arjan Verweij (CERN)<br />
Resources Manager Jos Perenboom<br />
Exhibition Manager Arend Nijhuis<br />
Technical Tours<br />
Marc Dhallé<br />
Oral Sessions Manager Cris Vermeer<br />
Poster Sessions Manager Erik Krooshoop<br />
Publication Office Srinivas Vanapalli<br />
Technical Systems Sander Wessel, Gideon Laureijs<br />
Website and Informatics Jaap Kosse<br />
Indico Services<br />
Herman ten Kate, Arjan Verweij<br />
Conference Registration Jacqueline van der Lek - Rohof<br />
IEEE-TAS Editor in Chief Luisa Chiesa (Tufts University)<br />
16
Scientific Program Committee<br />
Name Country Institute<br />
Arjan Verweij (Chair) Switzerland CERN<br />
Giorgio Ambrosio USA FNAL<br />
Naoyuki Amemiya Japan Kyoto University<br />
Kathleen Amm USA GE<br />
Amalia Ballarino Switzerland CERN<br />
Pierluigi Bruzzone Switzerland CRPP<br />
Luisa Chiesa USA Tufts University<br />
Guram Chlachidze USA FNAL<br />
Arnaud Devred France ITER<br />
Marc Dhallé Netherlands Twente University<br />
Pasquale Fabbricatore Italy INFN<br />
Paolo Ferracin Switzerland CERN<br />
Fedor Gömöry Slovakia SAS<br />
Yury Ilin France ITER<br />
Anna Kario Germany KIT<br />
Glyn Kirby Switzerland CERN<br />
Takanobu Kiss Japan Kyushu University<br />
Haigun Lee South Korea Korea University<br />
Cesar Luongo USA Jefferson Lab<br />
Tatsushi Nakamoto Japan KEK<br />
Mathias Noe Germany KIT<br />
Toru Ogitsu Japan KEK<br />
Michael Parizh USA GE<br />
Subrata Pradhan India IPR<br />
Gianluca Sabbi USA LBNL<br />
Fernando Toral Spain CIEMAT<br />
Pierre Vedrine France CEA Saclay<br />
Vitaly Vysotsky Russia VNIKP<br />
Qiuliang Wang China CAS<br />
Huub Weijers USA NHMFL<br />
Liye Xiao China CAS<br />
Ex-officio members:<br />
Herman ten Kate LOC, Conference Chairman<br />
Andries den Ouden LOC, Conference Co-chairman<br />
17
Editors IEEE-TAS for the <strong>MT25</strong> Special Issue<br />
MT 25 Special Issue Editor-in-Chief: Luisa Chiesa<br />
Lead Editors:<br />
Naoyuki Amemiya, Juan Bascuñàn, Lance Cooley, Michael<br />
Green, Reinhard Heller, Sasha Ishmael, Michael Parizh, Minwon<br />
Park, Alexander Polasek, Carmine Senatore, Ezio Todesco, Vitali<br />
Vysotsky, and Al Zeller.<br />
Technical Editors:<br />
Minchul Ahn, Mark Ainslie, Cristian Boffo, Pierluigi Bruzzone,<br />
Chris Bumby, Nikolay Bykovsky, Ahmet Cansiz, Miquel Carrera,<br />
Daniel Cheng, Shailendra Chouhan, Tim Coombs, Valentina<br />
Corato, Gianluca De Marzi, Wescley de Sousa, Iain Dixon,<br />
Stefania Farinon, Sandor Feher, Yuting Gao, Luis Garcia-<br />
Tabares Rodriguez, Andrey Gavrilin, Francesco Grilli, XingLong<br />
Guo, Seungyong Hahn, William Hassenzahl, Trey Holik, Simon<br />
Hopkins, Lei Huang, Yuri Ilin, Susana Izquierdo Bermudez, Brian<br />
Johnson, Hom Kandel, Anna Kario, Pei Li, Quan Li, Chengcheng<br />
Liu, Jose Lopez, Clement Lorin, Goran Majkic, Vittorio Marinozzi,<br />
Arkadiy Matsekh, Dustin McRae, James Meen, Matthias Mentink,<br />
Nenad Mijatovic, João Murta-Pina, Luigi Muzzi, Naoko Nakamura,<br />
Shinichi Nomura, Thomas Paintereng Pan, Rüdiger Picker,<br />
Liudmila Potanina, Timing Qu, Lionel Quettier, Loïc Quéval, Renuka<br />
Rajput-Ghoshal Renuka, Etienne Rochepault, Igor Rodin,<br />
GianLuca Sabbi, Tiina Salmi, Santiago Sanz, Xabier Sarasola<br />
Martin, Pierre Schnizer, Kamil Sedlak, Zonghai Song, Xiaowei<br />
Song, Yoshikazu Takahashi, Frederic Trillaud, Melanie Turenne,<br />
John Voccio, Michal Vojenciak, Qiuliang Wang, Xiaorong Wang,<br />
Rainer Wesche, Michael Wolf, Liye Xiao, Xingchen Xu, Yuan<br />
Yang, Weijia Yuan, Min Zhang, Zhenyu Zhang, and Jiahui Zhu<br />
(list as of 18/8/2017).<br />
Exhibitors<br />
Exhibition schedule<br />
Exhibit show hours<br />
Monday, August 28, 2017 08:00 – 18:30<br />
Tuesday, August 29, 2017 09:00 – 20:15<br />
Wednesday, August 30, 2017 09:00 – 18:30<br />
Thursday, August 31, 2017 09:00 – 18:00<br />
Exhibitor Reception<br />
Tuesday, August 29, 2017 18:45 - 20:15<br />
18
Exhibitors<br />
Booth 1<br />
CAEN ELS s.r.l.<br />
Address: SS 14 km 163.5 - 34149 Basovizza (Trieste) - Italy<br />
+39403756610<br />
info@caenels.com<br />
www.caenels.com<br />
CAEN ELS is a leading<br />
company in power supply<br />
systems and precision current measurement solutions bringing highend<br />
research technology into industrial applications. The catalogue<br />
and custom-designed high-precision digital (unipolar-bipolar) power<br />
supplies as well as the DC current transducers and complete measurement<br />
/ calibration systems represent the state-of-the-art devices<br />
for magnet applications.<br />
Booth 2<br />
Supercon, Inc.<br />
830 Boston Turnpike,Shrewsbury, MA 01545,USA<br />
+15088420174<br />
dfrost@superconwire.com<br />
SUPERCON has been manufacturing low temperature NbTi and<br />
Nb3Sn superconductors as standard and specially designed wire and<br />
cable for over 55 years. Many of Supercon’s standard conductors,<br />
from 0.025 to 2.0mm diameter, are available from stock A wide variety<br />
of custom composite metal wires is also available. We can deliver research<br />
quantities to OEM require-ments from stock.<br />
Booth 3<br />
Japan Superconductor Technology, Inc<br />
5-9-12 Kitashinagawa, Shinagawa-ku, Tokyo 141-8688, Japan<br />
+81357395210<br />
fukumoto.yoshito@kobelco.com<br />
www.jastec-inc.com<br />
Japan Superconductor<br />
Technology, Inc. (JA-<br />
STEC),<br />
is a manufacturer of superconducting wire/magnet in Japan. We have<br />
been contributing to a variety of application fields; life science, medical,<br />
energy and other science & industries through our cutting-edge<br />
technologies.<br />
- Wire: Our high-performance NbTi and Nb3Sn wires are used<br />
for NMR/MRI as well as ITER TF/CS.<br />
- Magnet: We supply high-field NMR magnets as well as special<br />
MRI magnets. We have also rich experience in cryogen-free magnets<br />
for academic and industrial applications.<br />
19
Booth 4<br />
THEVA Dünnschichttechnik GmbH<br />
Rote-Kreuz-Straße 8,85737 Ismaning,Germany<br />
+49899233460<br />
info@theva.com<br />
www.theva.com<br />
THEVA stands for reliable and highest quality superconducting wire<br />
production. Various types of THEVA Pro-Line high temperature superconductor<br />
wire can be delivered in lengths up to several hundreds<br />
of meters.<br />
Applications range from high current cables to high-end research<br />
magnets. Additionally, we design and deliver customized HTS coils.<br />
Tapestar TM , our powerful characterization tool for HTS tapes, is already<br />
used all over the world.<br />
Booth 5<br />
thabuis@metrolab.com<br />
www.metrolab.com<br />
Metrolab Technology<br />
Metrolab Technology SA is the global market leader for precision<br />
magnetometers, used to measure high-intensity magnetic fields to a<br />
very high degree of precision. Over the past 30 years, we have won<br />
the trust of MRI manufacturers and physics laboratories across the<br />
world.<br />
Our company culture is one of solutions: more important than the<br />
product, our top priority is to help you effectively measure magnetic<br />
fields. We invest approximately 20% of our gross sales in R&D.<br />
Booth 6<br />
Sunpower Inc.<br />
Business Development, 2005 East State Street, Athens, Ohio 45701<br />
www.sunpowerinc.com<br />
+17405903063<br />
Sunpower’s CryoTel®<br />
cryocoolers are the result<br />
of over 40 years of<br />
technical leadership,<br />
innovation, and evolution in free-piston Stirling technology. Our cryocoolers<br />
are cost effective, exceptionally quiet, low in vibration, and<br />
extremely efficient.<br />
Since they require no maintenance, our customers can expect many<br />
years of high-performance, trouble-free cooling.<br />
For temperature requirements between 40K and 200K there is no better<br />
alternative with respect to small size, efficient operation, and price.<br />
20
Booth 7<br />
RUAG Space GmbH<br />
Stachegasse 16, 1120, Vienna, Austria<br />
+431801993070<br />
cryo.at.space@ruag.com<br />
www.ruag.com/thermal<br />
RUAG Space is the largest<br />
supplier of space products<br />
and related ground<br />
support equipment in Austria,<br />
focusing on electronics,<br />
mechanisms and thermal insulation. The company of 240 employees<br />
belongs to the Swiss RUAG Holding. The state-of-the art equipment<br />
comprises leading edge design and analyses tools, clean rooms<br />
and automated cutting machines. The "Coolcat" line of high quality<br />
cryogenic Multi-layer Insulation is efficiently produced at a large industrial<br />
scale.<br />
Booth 8<br />
Stangenes Industries, Inc.<br />
1052 East Meadow Circle, Palo Alto, CA 94303<br />
+16504930814<br />
info@stangenes.com<br />
www.stangenes.com<br />
For over 43 years,<br />
Stangenes Industries has been manufacturing critical components for<br />
government, industry and research. As an OEM supplier to major<br />
medical equipment manufactures we have developed a reputation for<br />
quality and reliability at globally competitive prices. The foremost<br />
particle accelerator facilities and research labs in the world rely on<br />
Stangenes Industries for innovation and excellence.<br />
• Pulse Transformers<br />
• Magnets<br />
• Magnetic Components<br />
• Modulators<br />
• Diagnostics.<br />
Booth 9<br />
CST-Computer Simulation Technology AG<br />
AG, Bad Nauheimer Strasse 19, 64289 Darmstadt, Germany<br />
+49615173030<br />
info@cst.com<br />
www.cst.com<br />
CST develops CST<br />
STUDIO SUITE, a market-leading package of high-performance software<br />
for the simulation of EM fields in all frequency bands. CST solutions<br />
are used by leading companies across many industries, including<br />
aerospace, automotive, defense, electronics, healthcare and telecommunications.<br />
CST is part of SIMULIA, a Dassault Systèmes<br />
brand. www.cst.com<br />
21
Booth 10<br />
www.mmluvata.com<br />
Luvata<br />
Luvata Special Products<br />
have factories on 3 continents<br />
producing special<br />
copper and low-temperature<br />
superconducting (LTS) wires, cables and hollow conductors for<br />
magnet applications. The products are generally designed with special<br />
application in mind and their features vary widely among the different<br />
products offerings. Wires are produced for all applications in<br />
the LTS wire industry. Products include monolithic wires in round and<br />
rectangular shape as well as Wire-in-channel or cable-in-channel integrated<br />
conductors. Please contact us with your specific needs.<br />
Booth 11<br />
Western Superconducting Technologies<br />
No.12, Mingguang Road, Xi’an, Shaanxi, China, 710018<br />
+86-29-89616812,<br />
wires@c-wst.com,<br />
www.wstitanium.com, www.c-wst.com<br />
Western Superconducting Technologies Co., Ltd. (WST) is located in<br />
Xi'an, the capital city of Shaanxi Province, with a registered capital of<br />
53 million USD on 28 Feb, 2003. WST is one of the biggest research<br />
and development centre for superconductor and titanium also related<br />
materials in China, We try our best to explore and develop domestic &<br />
oversea markets. The aim we struggled is to create WST into a Hi-<br />
Tech industrial corporation with the advanced technology, talented employees,<br />
and the best equipment.<br />
Booth 12 General Atomics<br />
General Atomics, 3550 General Atomics Ct., San Diego, CA 92121<br />
+1 858-455-3000<br />
John.Smith@ga.com<br />
www.ga.com/ga-iter-energy-program<br />
General Atomics (GA) is a world leader in electromagnetics and superconducting<br />
magnet technology. GA is currently fabricating powerful<br />
pulsed superconducting magnet modules for ITER, an unprecedented<br />
international tokamak facility that aims to demonstrate the<br />
commercial feasibility of nuclear fusion. When completely assembled,<br />
the ITER Central Solenoid will have a peak field of 13.1 T with 5.5 GJ<br />
of stored energy. Magnet research at GA has led to discoveries and<br />
22
spinoff technologies in medical diagnostics, cryogenics, energy storage,<br />
transportation, semiconductors, and defense applications. GA<br />
leverages its research for the U.S. government and private industry,<br />
delivering solutions ranging from next-generation nuclear reactors to<br />
remotely operated aircraft and electromagnetic systems including the<br />
EMALs systems to electro-magnetically launch airplanes from aircraft<br />
carriers<br />
Booth 13<br />
www.bigscience.nl<br />
Dutch Scientific and Big Science<br />
The ILO-Network, part of<br />
Dutch Scientific, is a collaboration<br />
between Dutch Industrial<br />
Liaison Officers<br />
(ILOs) with the aim of liaising<br />
between Dutch companies and Science-driven projects; offering<br />
industry greater continuity in challenging high-value work; enabling<br />
science to gain easier access to highly qualified companies; enabling<br />
SMEs with less international experience in conducting business to become<br />
more closely involved in Big Science Projects.<br />
The ILO-net is financially supported by NWO and has proven its importance<br />
for connecting SMEs with science projects over the last<br />
years. At the Dutch Scientific exhibition stand you will find several<br />
Dutch companies offering unique expertise on technologically challenging<br />
subjects. Al latest list of Dutch firms involved in Big Science<br />
projects can be found with their profile in the online brochure.<br />
Booth 14<br />
DEMACO HOLLAND bv.<br />
Oester 2, 1723 HW, Noord-Scharwoude, the Netherlands.<br />
rd@demaco.nl<br />
www.demaco.nl<br />
Demaco is a mid-sized<br />
company specialized in the field of cryogenic technology and is responsible<br />
for the infrastructure to transport liquefied gases from A to<br />
B. Demaco manufactures systems with measure and control technologies<br />
for cryogenic applications. All cryogenic systems are doublewalled<br />
where high vacuum is applied as ultimate isolator. These cryogenic<br />
systems enable the transportation and conditioning of liquid<br />
gases.<br />
Since 1985, Demaco has been a supplier for producers of industrial<br />
gases and end users of liquid gas. As we are a total integrated company,<br />
we are able to employ our expertise from initial concept, through<br />
engineering and manufacturing, right up to installation. Examples include<br />
the food industry, medical companies, as well as space research<br />
centers and scientific institutes. Demaco is part of the top 6<br />
companies in cryogenic technology world-wide.<br />
23
Booth 15<br />
Hyper Tech Research, Inc.<br />
539 Industrial Mile Rd, Columbus, OH 43228, USA<br />
mtomsic@hypertechresearch.com<br />
www.hypertechresearch.com<br />
614-481-8050 Ext. 2432<br />
Hyper Tech is a leading manufacturer<br />
of MgB2 and Nb3Sn superconductor<br />
wires. We have experience<br />
designing, manufacturing and testing coils using NbTi, Nb3Sn,<br />
MgB2, Nb3Sn, BSCCO, and (Re)BCO superconductors. Hyper Tech<br />
is developing small diameter high amperage Cable-in Conduits (CIC)<br />
for several superconducting applications, using NbTi, MgB2 and<br />
Nb3Sn strands. We also have system design experience for developing<br />
superconducting MRIs, fault current limiters, motors, wind generators,<br />
SMES, DC and AC cable applications.<br />
Booth 16<br />
Babcock Noell GmbH<br />
www.bng.bilfinger.com/en<br />
Babcock Noell GmbH is a company of Bilfinger SE and is your partner<br />
for magnet systems, vacuum and cryo-technology. Babcock Noell has<br />
been working closely with large-scale research facilities for developments,<br />
prototyping up to series production. Being your partner we<br />
have a comprehensive know-how and can develop solutions tailored<br />
to your needs, e.g. superconducting undulators for light sources,<br />
products for the energy market and comprehensive vacuum equipment<br />
and cryostats.<br />
Booth 17<br />
Sumitomo ELECTRIC INDUSTRIES Ltd<br />
http://global-sei.com; http://global-sei.com/super<br />
DI-BSCCO, 1st Grade superconductor, is the trade mark of Sumitomo<br />
Electric Industries (SEI). Using DI-BSCCO, researchers and manufactures<br />
from around the world have successfully manufactured superconducting<br />
cables, magnets, motors and current lead assemblies.<br />
Recently, SEI developed Type HT-NX, an extra high strength DI-<br />
BSCCO, superconductor wire design that is surpassing other HTS<br />
wires for high field magnet designs. DI-BSCCO Type G is widely used<br />
in magnet current lead designs. DI-BSCCO-MS, is a magnet system<br />
employing DI-BSCCO and AC and DC superconducting cable systems<br />
can be also supplied by Sumitomo Electric.<br />
24
Booth 18<br />
www.cryogenic.co.uk<br />
Cryogenic Ltd.<br />
Cryogenic Ltd leads the market in the design and manufacture of high<br />
field measurement systems for scientific research and industrial applications.<br />
The product range includes vibrating sample magnetometer, specific<br />
heat measurement via AC calorimetry and relaxation methods, AC<br />
susceptibility, resistivity and Hall Effect measurements and thermal<br />
conductivity. These are offered as either cryogen free or low boil off<br />
liquid helium cooled magnet systems, with fields of up 24 Tesla and<br />
ultra-low temperatures down to 300 mK with 3He or 50 mK with a<br />
dilution refrigerator.<br />
Booth 19<br />
Advanced Conductor Technologies LLC<br />
3082 Sterling Circle, Unit B, Boulder, CO 80301, USA<br />
www.advancedconductor.com<br />
info@advancedconductor.com<br />
+17204080105<br />
Advanced Conductor Technologies CORC® technology opens the<br />
door to new markets that require flexible, high-current density power<br />
transmission cables and wires.<br />
High-temperature superconducting CORC® cables and wires also<br />
enable practical high-field magnets that operate at magnetic fields<br />
above 20 Tesla, or at temperatures exceeding 20 Kelvin.<br />
Booth 20<br />
Clever Conductors BV<br />
(no text made available for display)<br />
25
Booth 21<br />
Sumitomo Cryogenics<br />
Sumitomo (SHI) Cryogenics of Europe, GmbH<br />
Daimlerweg 5a, Darmstadt D-64293, Germany<br />
+496151860610<br />
contact@sumitomocryo.de<br />
www.shicryogenics.com<br />
SHI Cryogenics Group, an integral part of the Precision Equipment<br />
Division of Sumitomo Heavy Industries, Ltd., is a leading worldwide<br />
provider of innovative cryogenic solutions to the magnet technology<br />
industry. With offices in Asia, Europe and the United States, it has<br />
been producing quality cryogenic equipment for over 50 years. SHI's<br />
renowned engineering departments continue to<br />
focus on the latest cryogenic technologies, including<br />
innovative cryocooler, pulse tube and<br />
shield cooler designs. In addition to our exhibit<br />
booth, SHI’s cryocooler technology will be featured<br />
in a co-authored paper with Siemens<br />
Magnet Technology. “Hub- and Site-cooling of<br />
MRI magnets using a mobile cryogenic system,”<br />
will be presented at 10:00 on Thursday,<br />
31 August, during the Cryogenics & Auxiliary<br />
Technologies session.<br />
www.shicryogenics.com<br />
Booth 22<br />
SuperOx<br />
http://www.superox.ru/en<br />
SuperOx company was<br />
founded in 2006 with a goal<br />
to establish production of<br />
textured high-temperature<br />
superconductor coatings<br />
on metal substrates – second<br />
generation high temperature<br />
superconducting tapes (2G HTS). The equipment built with<br />
materials can change the image of the modern energy and transport<br />
industry. As well, 2G HTS tapes enable the production of far more<br />
efficient magnetic equipment for research and medicine.<br />
Due to unique electric and physical properties of high temperature<br />
superconductors, the application of 2G HTS tapes results in unique<br />
and superior qualities of power cables, fault current limiters, transformers,<br />
motors, generators, energy storage systems and magnets.<br />
Superconducting equipment is of high power, is compact, efficient and<br />
environment-friendly.<br />
26
Booth 23<br />
Salzgitter Mannesmann Stainless Tubes<br />
Via Piò 30, 24062, Costa Volpino (BG) - Italy<br />
+39 035 975867<br />
m.valdiserri@smsttubes.com<br />
www.smst-tubes.com<br />
Salzgitter Mannesmann<br />
Stainless Tubes is one<br />
of the worldwide leading<br />
manufacturers of seamless<br />
stainless steel and<br />
nickel based alloy tubes and pipes. Our company has one of the largest<br />
product portfolios in this sector and a 125 years long history that<br />
dates back to invention of the seamless stainless steel tube. Salzgitter<br />
Mannesmann Stainless Tubes is a qualified supplier for TF and PF<br />
Jacket for ITER Tokamak and for JT60SA-TF.<br />
Booth 24<br />
Columbus Superconductors<br />
www.columbussuperconductors.com<br />
Columbus Superconductors SpA is a superconducting wire manufacturing<br />
company dedicated to MgB2–based wire production. Multifilamentary<br />
MgB2 conductors are produced and supplied in unit lengths<br />
exceeding 3 Km, targeting a variety of DC and AC applications. Conductors<br />
are available in different shapes (round, rectangular, tape)<br />
and internal configuration (by number of filaments, sheath material,<br />
twist, etc). Wires as well as components based on MgB2 can be realized<br />
according to customers’ request.<br />
Booth 25<br />
Cryomech Inc.<br />
Cryomech.com<br />
cryosales@cryomech.com<br />
Cryomech, Inc. is the leader in advanced cryocooler solutions. Our<br />
distinct product line includes over 30 different types of Gifford-<br />
McMahon and Pulse Tube Cycle Cryo-refrigerators.<br />
Cryomech’ s fast and open design process allows you to remain the<br />
expert in your field of research while they manage the interface with<br />
the cryo-refrigerator seamlessly.<br />
Cryomech also offers a broad array of Helium Liquefiers and Recovery<br />
Systems. Cryomech recently introduced Ultra-Low Vibration Cryostats<br />
for operation below 4.2 K.<br />
27
Booth 26<br />
FURUKAWA ELECTRIC CO.LTD.<br />
2-3, Marunouchi 2-chome, Chiyoda-ku, Tokyo, 100-8322, Japan<br />
+81332863231<br />
http://www.furukawa.co.jp/en/<br />
Furukawa Electric is the pioneer in superconductivity. Compre-hensiveness<br />
from low-temperature superconductivity to high-temperature<br />
superconductivity.<br />
Booth 27<br />
IOP Publishing<br />
Temple Circus, Temple Way, Bristol BS1 6HG, UK<br />
+441179297481<br />
http://ioppublishing.org<br />
IOP Publishing provides publications through which leading-edge scientific<br />
research is distributed worldwide. Beyond our traditional journals<br />
programme, we make high-value scientific information easily accessible<br />
through an ever-evolving portfolio of books, community websites,<br />
magazines, conference proceedings and a multitude of electronic<br />
services.<br />
Booth 28<br />
WEKA AG<br />
Schuerlistrasse 8, CH-8344, Baeretswil, Switzerland<br />
+41438334343<br />
asm@weka-ag.ch<br />
www.weka-ag.ch/en/cryogenic-components<br />
WEKA is a Swiss SME with more than 40 years of manufacturing and<br />
developing experience and know-how in cryogenic components below<br />
75K.<br />
Cryogenic technologies such as space qualified components, future<br />
energy technologies based on hydrogen, basic- , plasma- and fusion<br />
power research projects and others are in high demand for innovative<br />
technologies which continuously requesting new product ideas and<br />
developments.<br />
Our components provide optimal solutions for handling low-temperature<br />
liquefied gases under extreme operating conditions as well as for<br />
related components.<br />
28
Booth 29<br />
www.sigmaphi.fr<br />
Sigma Phi<br />
Sigmaphi has been providing turnkey<br />
systems and components for particle<br />
accelerators to major research labs<br />
and protontherapy system providers<br />
for more than 30 years.<br />
Our 200 highly skilled employees can design, make and measure:<br />
- Complete particle transport beam lines, from optics to<br />
installation and alignment<br />
- High precision magnets : resistive, superconducting,<br />
permanent magnet based, in vacuum<br />
- Turnkey injection or extraction systems<br />
- Ultra stable power supplies<br />
- RF power solutions: Solid state amplifiers, Klystron Modulators<br />
Booth 30<br />
+34914110963<br />
www.elytt.com<br />
angel.garcia@elytt.com<br />
ELYTT ENERGY<br />
Elytt Energy designs and<br />
manufactures resistive and superconducting electromagnets and<br />
power supplies for particle accelerators of all types.<br />
Designs standard and custom-built resistive magnets, reaching from<br />
small correctors, to very large magnets, 2D and 3D is used for magnetic<br />
field modelling. Our workshop has all manufacturing facilities<br />
necessary, winding machines, vacuum system, oven, inert gas oven<br />
and all measurement equipment. The following related services are<br />
available, Mechanical calculations, Beam optical calculations, Vacuum<br />
calculation and design, On-site Installation.<br />
Booth 31<br />
Oxford Instruments Nanoscience<br />
Tubney Woods, Abingdon, OX13 5QX, UK<br />
+441865393200<br />
nanoscience@oxinst.com<br />
www.oxford-instruments.com/nanoscience<br />
We design, manufacture and<br />
support market-leading research tools that enable quantum technologies,<br />
new materials and device development. Leading the field of superconducting<br />
magnets for over 55 years, we have an unrivalled track<br />
record of supplying some of the most challenging custom magnets<br />
across the world. Our tools support research down to the atomic scale<br />
through creation of high performance, cryogen-free low-temperature<br />
and magnetic environments, based upon our core technologies in low<br />
and ultra-low temperatures, high magnetic fields and system integration.<br />
29
Booth 32<br />
Website: www.ocem.eu<br />
OCEM Power Electronics<br />
OCEM Power Electronics has since<br />
1943 supplied power systems to research<br />
laboratories worldwide, enabling<br />
advances in the fields of plasma physics, particle physics and<br />
medical research. In recent years, OCEM engineers have published<br />
numerous papers, and developed and patented new power electronics<br />
technologies. The company’s commitment to high quality and its<br />
customer-oriented approach have made its tailor-made solutions an<br />
invaluable asset for more than 50 research facilities in 20-plus countries,<br />
including four Nobel-Prize winning labs.<br />
Booth 33<br />
www.americanmagnetics.com<br />
American Magnetics Inc.<br />
American Magnetics, Inc.<br />
(AMI) has been a manufacturer<br />
of super- conducting<br />
magnet systems and cryogenic<br />
equipment for more than 45 years. Founded in 1968, AMI supplies<br />
turn-key cryogen-free and liquid helium based superconducting<br />
magnet systems, with custom solutions ranging from completely conduction<br />
cooled multi-axis systems combined with an integrated variable<br />
temperature insert to large room temperature bore zero boil-off<br />
helium recondensing systems (Recon). When AMI's innovative superconducting<br />
magnets, such as the multi-axis (MAxes) series, are<br />
coupled with cutting-edge cryostats, the customer is buying a winning<br />
combination. Topping off AMI's premier superconducting magnet systems<br />
is the Model 430 power supply programmer, which yields extreme<br />
accuracy, high automation and easy control for customers, all<br />
via Ethernet. AMI offers a complete line of capacitance and resistance<br />
based instrumentation that can be utilized to measure any cryogenic<br />
fluid with unparallelled accuracy and reliability. AMI stands behind its<br />
products with a warranty offering full system protection for 15 months.<br />
Booth 34<br />
Shanghai Superconductor Technology<br />
Bldg. 25, 1388 ZhangdongRoad, Pudong, Shanghai, P.R.China<br />
+8613642357543<br />
yiming.hong@shsctec.com<br />
www.shsctec.com<br />
Shanghai Superconductor<br />
Technology Co., Ltd. (SSTC) employs physical<br />
vapour deposition and manufactures custom,<br />
cost effective 2G-HTS wires with superior mechanical<br />
properties and world leading critical<br />
current densities especially at high magnetic field and low temperature.<br />
The company also provides peripheral products and services including<br />
coil winding (machines) and vacuum deposition systems.<br />
30
Booth 35<br />
FEAC Engineering P.C.<br />
61, Afstralias Street, P.O. 26442, Patras, Greece<br />
+302613019794<br />
info@feacomp.com<br />
www.feacomp.com<br />
FEAC is a leading solutions pioneer,<br />
specialized in engineering<br />
simulation. The company<br />
develops tailor-made, innovative<br />
& multi-physics numerical<br />
models (including coupled structural, electromagnetic, thermal, vibroacoustic<br />
& fluid phenomena), based on the Finite Element (FEM)<br />
& Boundary Element (BEM) method. From initial design to prototype<br />
testing, FEAC applies simulation expertise and operational experience<br />
to assist its clients with high-value and accurate solutions during<br />
the R&D process of super/normal-conductive magnets, motors, generators<br />
and devices.<br />
Booth 36<br />
www.cryomagnetics.com<br />
Cryomagnetics Inc.<br />
Cryomagnetics, Inc., is a leading manufacturer of superconducting<br />
magnets and systems. Solenoidal, split pair, multi-axis, and dipole/quadrupole<br />
magnets are available in dry, wet, and recondensing<br />
designs.<br />
Our C-Mag line of cryogen-FREE magnet systems with integrated VTI<br />
feature a modular design with an evolving lineup of experimental modules.<br />
System accessories include: 4 quadrant power supplies, liquid cryogen<br />
level monitors, temperature monitors, gauss-meters, VTI's, He3<br />
inserts, current leads, LHe and LN2 sensors, Hall effect sensors, temperature<br />
sensors, and more.<br />
31
Booth 37 Bruker EST<br />
www.bruker. com/best<br />
Bruker Energy and Supercon Technologies<br />
(BEST) is a global leader in superconductor<br />
solutions, providing an unmatched<br />
range of products that meet<br />
the needs of healthcare, academic and<br />
industrial companies and organizations<br />
worldwide. In close cooperation with our<br />
customers, we design, develop and deliver<br />
product solutions that are at the<br />
heart of a majority of the superconductor<br />
magnets worldwide. They enable innovators<br />
to build leading edge healthcare<br />
and industrial products, as well as to<br />
conduct fundamental research, such as<br />
the search for the origins of the universe<br />
and sustainable clean energies.<br />
Booth 38<br />
Tesla Engineering Ltd<br />
Water Lane, Storrington, Sussex,<br />
RH20 3EA, United Kingdom<br />
+441903743941<br />
sales@teslamagnets.com<br />
www.tesla.co.uk<br />
www.bruker.com/best<br />
Tesla Engineering Ltd. was<br />
founded over 40 years ago to supply<br />
magnets for particle accelerators. Today, the Tesla group of companies<br />
has factories in the UK, the USA, and the Netherlands.<br />
The group has combined expertise in magnetics, composites, and<br />
precision manufacturing, and serves a wide range of well-known customers<br />
in national and international laboratories (CERN, Fermilab,<br />
ESRF, Brookhaven), and in several industries (MRI, Proton therapy,<br />
Radiotherapy, Semiconductor fabrication, Fusion).<br />
Booth 39<br />
www.stoehr-valves.de<br />
Stöhr Armaturen GmbH & Co KG<br />
STÖHR ARMATUREN has specialized<br />
in cryogenic valves and filters for<br />
gas handling in science & research<br />
institutes since the 1960s. Our customers are well-known companies<br />
and institutes worldwide. Cryogenic temperature down to 2K, high<br />
pressure up to 800 bar, high leak tightness, media compatibility and<br />
short shutter speed characterize our products. Our standard product<br />
range comprises highly precise control valves, globe valves and<br />
check valves for installation in valve boxes, vacuum jackets or regular<br />
pipes; relief valves, overflow valves and filters.<br />
STÖHR ARMATUREN – VALVES FOR THE EXTREMES !<br />
32
Booth 40<br />
Cryoworld B.V.<br />
Havenweg 11C, 1771RW, Wieringerwerf, the Netherlands<br />
+31228743930<br />
info@cryoworld.com<br />
www.cryoworld.com<br />
Cryoworld BV in Wieringerwerf<br />
is a manufacturer of advanced<br />
cryogenic equipment. Our core<br />
business is design, production, testing and installation of Helium and<br />
other custom designed cryogenic equipment. Cryoworld specializes<br />
in the development of new cryogenic technologies and delivers projects<br />
to renowned companies and scientific institutes worldwide.<br />
Booth 41<br />
DH Industries B.V.<br />
Science Park, Eindhoven 5003, 5692EB, Son,<br />
The Netherlands<br />
www.dh-industries.com<br />
DH Industries specializes in<br />
the design and production of<br />
Stirling Cryogenerators and<br />
closed-loop cooling systems. Our customers rely on our expertise to<br />
provide them with a cryogenic cooling system optimized for their applications.<br />
Combining our product lines Stirling Cryogenics, creating<br />
cooling power, and CryoZone, distributing cooling power, we have designed<br />
and build systems to pre-cool magnets down to 20K to reduce<br />
LHe costs for cool-down.Depending your requirements we can design<br />
and build a specific cooling system also for your unique application.<br />
Booth 42<br />
www.incaacomputers.com<br />
INCAA Computers B.V.<br />
NCAA Computers B.V. is a company<br />
specializing in design and<br />
manufacture of professional<br />
high-tech measurement and<br />
control equipment for industrial, scientific, OEM and automotive applications.<br />
Since INCAA was founded in 1975, our focus is to provide<br />
solutions for technical automation projects based on hardware, software<br />
and system design. These projects are realized mainly in Europe,<br />
products are sold worldwide. Our software development team<br />
can define scalable and high-performance projects and develop the<br />
right software for it. Due to our in-house hardware expertise, we know<br />
best to separate projects into hardware and software functions and<br />
how to interface them to build innovative fail-safe systems. One example<br />
is the Data-Acquisition System for the Magnetic Test Bench at<br />
CERN SM18.<br />
33
Booth 43<br />
www.basis-ep.com<br />
Basis Electronique de Puissance<br />
Basis EP designs and manufactures<br />
power converters<br />
for any high power application.<br />
Basis is an international<br />
specialist with an experienced<br />
team of engineers in the power electronics field.<br />
Basis EP specialization relies on:<br />
• High current rectifiers from 10A to 100kA<br />
• High voltage converters or capacitor chargers upto 90kVDC<br />
• AC or DC power supplies with very high accuracy and stability<br />
up to 5ppm<br />
• Special inverters with current reversibility for special applications.<br />
• Electronics development dedicated to analogic or digital Controller<br />
Booth 44<br />
Rolf Kind GmbH<br />
Nochener Str. 1-3, 51647 Gummersbach, Germany,<br />
info@r-kind.de / www.r-kind.de<br />
Rolf Kind GmbH is a supplier of<br />
open die forgings in high alloyed<br />
stainless steels, nickel based alloys<br />
and titanium.<br />
Since more than 40 years the company is producing sophisticated<br />
special products for the most demanding industries, such as the nuclear,<br />
chemical, petrochemical and machinery and construction sectors.<br />
The Germany-based company is deeply involved in research<br />
and development projects like ITER and CERN and is looking forward<br />
to support you in your demanding projects!<br />
Booth 45<br />
Alltech Medical Systems, LLC.<br />
201 Tianqin Road, High-Tech Industrial Zone (West Park),<br />
Chengdu,Sichuan, 611731, China<br />
+2887809200<br />
Sales-eng@alltechmed.com<br />
www.alltechmed.com<br />
With global operation in Cleveland,<br />
U.S. and Cheng-du, China,<br />
Alltech is a leading company in<br />
the engineering, manufacturing and service of superconducting magnets.<br />
We provide the MRI industry and research societies a variety of<br />
superconducting magnets, including the 1.5T standard and wide-bore<br />
magnets for clinical MR systems, 3T/7T/9.4T magnets for research<br />
and preclinical MR system, and 0-8T cryogen-free superconducting<br />
magnet with various bore size. We are committed to serve our customers<br />
with high quality and high reliability products.<br />
34
Booth 46<br />
HTS-110<br />
1B Quadrant Drive, Waiwhetu, Lower Hutt 5010, New Zealand<br />
+6445708880<br />
info@hts-110.com<br />
www.hts-110.com<br />
Innovators in design and<br />
manufacture of cryogen-free<br />
magnetic solutions utilizing<br />
high-Tc (HTS) wire. Products<br />
include compact magnets for beamline environments, short solenoids<br />
(1-3 T) ideal for optical applications, fast ramping split-pair magnets<br />
(7-8 T) for materials research, NMR (200, 400 MHz) and MRI magnets.<br />
Components designed for customer integration include CryoSaver<br />
current leads, and HTS coils; HTS-110 also assists with<br />
custom superconducting projects.<br />
Booth 47 ICEoxford Limited<br />
www.iceoxford.com<br />
ICEoxford manufacture cryogenic<br />
systems with magnetic<br />
fields for the global scientific<br />
community. With 150+ years of<br />
cryogenic experience to call<br />
on, ICEoxford is superbly positioned to supply bespoke systems<br />
suited to the particular needs of specific applications. Specialized in<br />
both wet and dry systems as well as repairs and service.<br />
Booth 48<br />
Valorization Opportunity at <strong>MT25</strong><br />
Young Scientists and Entrepreneurs<br />
A special booth for newcomer demonstrations is available at the<br />
<strong>MT25</strong> Exhibition sponsored by the conference hosts, the University of<br />
Twente and HFML, and supported by IEEE-CSC.<br />
Young Scientists and Young Entrepreneurs can take up the challenge<br />
to show to the conference attendees innovative valorization ideas,<br />
concepts or products that have the potential to make it to the market<br />
in the field of superconducting magnets.<br />
Newcomers is offered a platform for promoting innovative ideas or<br />
conceptual products under development to explore the market potential<br />
of an invention or product.<br />
Such demonstrators can be anything like smart sensors, actuators,<br />
devices, tools, etc., provided of general interest and not yet covered<br />
by an established company or institute. And, of course, size- and services<br />
wise, the object should be suitable for demonstration in a booth.<br />
35
Booth 49<br />
www.danfysik.com<br />
DANFYSIK<br />
Today we are proud of being one of the world’s leading companies<br />
within the development and manufacturing of high quality equipment<br />
for particle accelerator laboratories, healthcare and industry, and we<br />
employ some of the most skilled, experienced and dedicated engineers<br />
and technicians. Danfysik has customers and partners all over<br />
the world and our business is accelerating like our technology.<br />
Specialties:Accelerator components, Accelerator systems, Power<br />
supplies, Magnets, Insertion Devices, Particle Therapy accelerator<br />
systems, Beam diagnostics, Synchrotron<br />
Booth 50<br />
Springer Science + Business Media B.V.<br />
Springer Nature offers many opportunities for authors, customers and<br />
partners.<br />
http://www.springernature.com/gp/<br />
hisako.niko@springer.com<br />
36
Bruker EST<br />
www.bruker.com/best<br />
Gold sponsors<br />
Sumitomo Cryogenics<br />
www.shicryogenics.com<br />
contact@sumitomocryo.de<br />
DEMACO HOLLAND b.v.<br />
rd@demaco.nl<br />
www.demaco.nl<br />
Silver sponsors<br />
EMFL<br />
info@emfl.eu<br />
www.emfl.eu<br />
37
General Atomics<br />
Silver sponsors<br />
Continued<br />
John.Smith@ga.com<br />
www.ga.com/ga-iter-energy-program<br />
Western Superconducting Technologies<br />
wires@c-wst.com<br />
www.wstitanium.com , www.c-wst.com<br />
ALPHYSICA<br />
http://alphysica.com<br />
Amsterdam<br />
PHILIPS<br />
www.philips.com/newscenter<br />
Royal Philips (NYSE: PHG, AEX: PHIA) is a leading health technology<br />
company focused on improving people's health and enabling better<br />
outcomes across the health continuum from healthy living and prevention,<br />
to diagnosis, treatment and home care. Philips leverages advanced<br />
technology and deep clinical and consumer insights to deliver<br />
integrated solutions. Headquartered in the Netherlands, the company<br />
38
is a leader in diagnostic imaging, image-guided therapy, patient monitoring<br />
and health informatics, as well as in consumer health and<br />
home care. Philips' health technology portfolio generated 2016 sales<br />
of EUR 17.4 billion and employs approximately 70,000 employees<br />
with sales and services in more than 100 countries.<br />
NWO<br />
https://www.nwo.nl/en<br />
The Netherlands Organisation for Scientific Research supports a<br />
strong system of sciences in the Netherlands by encouraging quality<br />
and innovation in science. That is why NWO funds only the best research<br />
- both curiosity-driven research and research into issues that<br />
occupy the world - for which via peer-review independent, knowledgeable<br />
experts from throughout the world are used for the assessment<br />
and selection process.<br />
TeslaEngineering Ltd.<br />
sales@teslamagnets.com<br />
www.tesla.co.uk<br />
Sponsors<br />
Advanced Conductor Technologies<br />
www.advancedconductor.com<br />
info@advancedconductor.com<br />
Cryomech<br />
cryosales@cryomech.com<br />
39
40
41
Announcement of MT26-2019 in Vancouver<br />
42
Floorplan<br />
Conference center, ground floor<br />
Included are the exhibition booth numbers.<br />
Poster board numbers are displayed at the message board near<br />
the entrance and on the website www.MT-25.org<br />
43
Floorplan<br />
Conference center, first floor<br />
Included are the exhibition booth numbers.<br />
Poster board numbers are displayed at the message board near<br />
the entrance and on the website www.MT-25.org.<br />
44
Technical Program<br />
Sunday, August 27, 2017<br />
Registration at RAI in Elicium Building, entrance D<br />
16:00 – 19:00<br />
Mon<br />
Welcome reception 19:00 - 20:30 Elicium<br />
Welcome Reception in Elicium Ball Room, 1 st floor<br />
Monday, August 28, 2017<br />
Registration at RAI Conference Center, 08:00 – 18:30<br />
Plenary Session 1.1 08:45 - 09:00 Auditorium<br />
Conference Opening<br />
Plenary Session 1.2 09:00 - 09:15 Auditorium<br />
IEEE Awards Presentation<br />
Plenary Session 2 09:15 - 10:00 Auditorium<br />
ITER project<br />
Session Chairs: Herman ten Kate and Haigun Lee<br />
Mon-Mo-Pl2-01 09:15<br />
Overall Status of the ITER Project<br />
Bernard Bigot<br />
ITER International Organization, France<br />
45
Mon<br />
Oral Session 1 10:30 - 12:15 Auditorium<br />
LHC and HL-LHC magnets<br />
Session Chairs: Attilio Milanese and Luis Garcia-tabares<br />
Mon-Mo-Or1-01 10:30<br />
Hi-Lumi LHC Twin Aperture Orbit Correctors Magnet Assembly<br />
& Cold Test<br />
Glyn Kirby, Luca Gentini, Jacky Mazet, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Mo-Or1-02 10:45<br />
Training Performance with Increased Coil Pre-stress of<br />
the 2-m Model Magnet of Beam Separation Dipole for the<br />
HL-LHC Upgrade<br />
Michinaka Sugano, Andrea Musso, Ezio Todesco, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Mo-Or1-03 11:00<br />
Training of the main dipoles magnets in the Large Hadron<br />
Collider towards 7 TeV operation<br />
Ezio Todesco, Marta Bajko, Davide Tommasini, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Mo-Or1-04 11:15<br />
Detailed magnetic and mechanical design of the nested<br />
orbit correctors for HL-LHC<br />
Jesús Angel García-matos, Fernando Toral, et al.<br />
CIEMAT, Spain<br />
Mon-Mo-Or1-05 11:30<br />
Status of the Activity for the Construction of the HL-LHC<br />
Superconducting High Order Corrector Magnets at<br />
LASA-Milan<br />
Massimo Sorbi, Antonio Leone, et al.<br />
Milan University & INFN-LASA, Italy<br />
Mon-Mo-Or1-06 11:45<br />
Development of a short model of the superconducting<br />
separation dipoles D2 for the High Luminosity Upgrade<br />
of LHC<br />
Pasquale Fabbricatore, Andrea Bersani, et al.<br />
Universita e INFN Genova (IT), Genova, Italy<br />
Mon-Mo-Or1-07 12:00<br />
A Statistical Analysis of Electrical Faults in the LHC<br />
Magnets<br />
Luca Bottura, Jean-Philippe Tock, et al.<br />
CERN, Geneva, Switzerland<br />
46
Oral Session 2 10:30 - 12:15 Emerald Room<br />
High-field Magnets<br />
Session Chairs: Jos Perenboom and Todd Adkins<br />
Mon-Mo-Or2-01 10:30<br />
[Invited] Progress in the Construction of the 43 T Hybrid<br />
Magnet at LNCMI-Grenoble<br />
Pierre Pugnat<br />
CNRS-LNCMI, Grenoble, France<br />
Mon-Mo-Or2-02 11:00<br />
[Invited] The commissioning of a hybrid magnet at<br />
CHMFL<br />
Wenge Chen, Zhiyou Chen, Donghui Jiang, et al.<br />
China High Magnetic Field Laboratory, China<br />
Mon-Mo-Or2-03 11:30<br />
[Invited] Commissioning of the 36 T Series-Connected<br />
Hybrid Magnet at the NHMFL<br />
Mark Bird, William Brey, Iain Dixon, et al.<br />
NHMFL/FSU, Tallahassee, FL, USA<br />
Mon-Mo-Or2-04 12:00<br />
Design of the resistive insert coils for the HFML 45 T Hybrid<br />
Magnet<br />
Frans Wijnen, Jos Perenboom, Andries den Ouden, et al.<br />
HFML, Radboud University, Nijmegen, the Netherlands<br />
Mon<br />
47
Mon<br />
Oral Session 3 10:30 - 12:15 G102-103 Room<br />
Mechanical Aspects and Novel Diagnostics<br />
Session Chairs: Emmanuele Ravaioli and Patrick Noyes<br />
Mon-Mo-Or3-01 10:30<br />
Mechanical–electric Model for Multifilament Composite<br />
Superconducting Strands<br />
Yuanwen Gao, Xu Wang, Yang Liu and Youhe Zhou<br />
Lanzhou University, China<br />
Mon-Mo-Or3-02 10:45<br />
Analytical investigation in bending characteristic of pretwisted<br />
HTS tapes<br />
Wurui Ta and Yuanwen Gao<br />
Key Lab. of Mechanics on Environment and Disaster, China<br />
Mon-Mo-Or3-03 11:00<br />
Multi-scale approach to the mechanical behaviour of<br />
epoxy impregnated Nb3Sn Dipole Coils for the 11T Dipole<br />
Michael Daly, Christian Hannes Loffler, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Mo-Or3-04 11:15<br />
Structural Behavior of KSTAR CS Magnet during Plasma<br />
Operation<br />
Hee-Jae Ahn, H. K. Park, Y. Chu, Y. O. Kim, et al.<br />
National Fusion Research Institute, Korea<br />
Mon-Mo-Or3-05 11:30<br />
Fatigue failure analysis of a 60T pulsed magnet at WHMFC<br />
Quqin Sun, Fan Jiang, Le Deng, Houxiu Xiao, et al.<br />
China Academy of Engineering Physics, China<br />
Mon-Mo-Or3-06 11:45<br />
Real-time functional diagnostics of superconducting<br />
magnets using acoustic techniques<br />
Maxim Marchevsky, Stephen Gourlay, et al.<br />
Lawrence Berkeley National Lab. (US), Berkeley, CA, USA<br />
Mon-Mo-Or3-07 12:00<br />
Mechanical Analysis of the Short Model Magnets for the<br />
Nb3Sn Low-Beta Quadrupole MQXF<br />
Giorgio Vallone, Paolo Ferracin, Daniel Cheng, et al.<br />
CERN, Geneva, Switzerland<br />
48
Poster Session 1<br />
Session Chairs: Davide Uglietti and Chao Zhou<br />
Poster Session 1.01 13:15 - 15:00 Posters Area<br />
Nb 3Sn Magnets for HL-LHC and other Applications<br />
Mon-Af-Po1.01-01 [01]<br />
Frequency domain Diagnosis Methods for Quality Assessment<br />
of Nb3Sn coil Insulation systems and impedance<br />
measurement<br />
Arnaud Foussat, David Smekens, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Po1.01-02 [02]<br />
Mechanical Analysis of the Dipole Magnet FRESCA2<br />
During Assembly, Cool-Down and Training<br />
Etienne Rochepault, Philippe Grosclaude, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Po1.01-03 [03]<br />
Fabrication of the 7.2 m long coils for the prototype of<br />
MQXFB, the Nb3Sn low-b quadrupole magnet for the Hi-<br />
LHC<br />
Friedrich Lackner, Paolo Ferracin, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Po1.01-04 [04]<br />
Quench Location in the LARP MQXFS1 prototype<br />
Thomas Strauss, Giorgio Ambrosio, et al.<br />
Fermilab, USA<br />
Mon-Af-Po1.01-05 [05]<br />
Design and Fabrication of the 1.9 K Magnet Test Facility<br />
at BNL, and Test of the First 4 m Long MQXF Coil.<br />
Joseph F Muratore, Michael Anerella, et al.<br />
Brookhaven National Laboratory, USA<br />
Mon-Af-Po1.01-06 [06]<br />
Magnetic Measurements on Short Models and Long Coil<br />
Assemblies of the 11-T dipoles for HL-LHC<br />
Lucio Fiscarelli, Olaf Dunkel, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Po1.01-07 [07]<br />
Magnetic Measurements on the First Models of the Insertion<br />
Quadrupole MQXF for HL-LHC<br />
Lucio Fiscarelli, Giorgio Ambrosio, et al.<br />
CERN, Geneva, Switzerland<br />
Mon<br />
49
Mon<br />
Mon-Af-Po1.01-08 [08]<br />
Experimental and numerical investigation on losses in<br />
electrodynamic transients in a Nb3Sn prototype racetrack<br />
coil<br />
Marco Breschi, Pier Luigi Ribani, et al.<br />
University of Bologna, Italy<br />
Mon-Af-Po1.01-09 [09]<br />
Mechanical Design of a Nb3Sn Superconducting Magnet<br />
System for a 45 GHz ECR Ion Source<br />
Mariusz Juchno, Aurelio Hafalia, Daniel Xie, et al.<br />
LBNL, Berkeley, CA, USA<br />
Mon-Af-Po1.01-10 [10]<br />
Quench Protection of the 11 T Nb3Sn Dipole for the High<br />
Luminosity LHC<br />
Susana izquierdo Bermudez, Frederic Savary, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Po1.01-11 [11]<br />
Beam Trajectory Simulation Considering Each Harmonic<br />
Components in HTS Quadruple Triplet<br />
Zhan Zhang, Shaoqing Wei and Sangjin Lee<br />
Uiduk University, Korea<br />
Mon-Af-Po1.01-12 [12]<br />
Assembly and test of the support structure for the subscale<br />
dipole magnet FECD1<br />
Zhang Kai, Xu Qingjin, Wang Chengtao, et al.<br />
Institute of High Energy Physics, China<br />
Poster Session 1.02 13:15 - 15:00 Posters Area<br />
Detector Magnets<br />
Mon-Af-Po1.02-01 [13]<br />
Magnet System for the BabyMIND Neutrino Detector at J-<br />
PARC<br />
Alexey Dudarev, Gabriella Rolando, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Po1.02-02 [14]<br />
Design, manufacturing and testing of a unique coil collaring<br />
system for the Jefferson lab’s large superconducting<br />
magnets SHMS Dipole and Q2Q3 quadrupoles<br />
Amaury Porhiel, Frederick Forest, et al.<br />
Sigmaphi, France<br />
50
Mon-Af-Po1.02-03 [15]<br />
Commissioning of the R3B-Glad superconducting dipole<br />
magnet<br />
Bernard Gastineau, Christophe Mayri, et al.<br />
CEA Saclay, Gif-sur-Yvette, France<br />
Mon-Af-Po1.02-04 [16]<br />
Status of Design and Manufacturing of PENELOPE neutron<br />
trap<br />
Cristian Boffo, Jochen Steinmann, et al.<br />
Babcock Noell GmbH, Germany<br />
Mon-Af-Po1.02-05 [17]<br />
A passively shielded HTS magnet for polarized neutron<br />
scattering<br />
Taotao Huang, Donald Pooke and Vadim Chamritski<br />
HTS-110 Ltd., New Zealand<br />
Mon-Af-Po1.02-06 [18]<br />
Operational experience with the combined solenoid/dipole<br />
magnet system of the COMPASS Experiment at<br />
CERN<br />
Erwin Roland Bielert, Herman ten Kate, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Po1.02-07 [19]<br />
FCC-hh Detector Magnet Cryostats and Cold Mass Suspension<br />
system<br />
Helder F. p. Silva, Alexey Dudarev, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Po1.02-08 [20]<br />
Optimization, design, and operation assessment of a<br />
multipurpose detector for the NICA collider<br />
Martina Neri, Simone Grillo, Alessio Capelluto, et al.<br />
ASG Superconductors s.p.a., Genova, Italy<br />
Mon-Af-Po1.02-09 [21]<br />
Commissioning of the Superconducting Magnets for the<br />
SHMS Spectrometer at Jefferson Lab<br />
Paul Brindza, Amaury Porhiel, David Ramauge, et al.<br />
Jefferson Laboratory, USA<br />
Mon-Af-Po1.02-10 [22]<br />
Development of conductors for thin solenoids for ultra<br />
radiation-transparent detector magnets<br />
Tobias Kulenkampff, Alexey Dudarev, et al.<br />
Vienna University of Technology, Austria<br />
Mon<br />
51
Mon<br />
Poster Session 1.03 13:15 - 15:00 Posters Area<br />
HTS Inserts and Model Magnets<br />
Mon-Af-Po1.03-01 [23]<br />
Cryo-free multisection superconducting magnetic system<br />
with MgB2 coil<br />
Dmitry Abin, Maxim Osipov, Sergei Pokrovskii, et al.<br />
National Research Nuclear University, Moscow, Russia<br />
Mon-Af-Po1.03-02 [24]<br />
Transient Behaviors of a 3 T 100 mm Stainless Steel<br />
Cladding All-REBCO Magnet During Sudden Discharging<br />
Jae Young Jang, Young Jin Hwang, et al.<br />
Korea Basic Science Institute, Korea<br />
Mon-Af-Po1.03-03 [25]<br />
A Field-Shaking System to Eliminate the Screening-Current<br />
Field in the 800-MHz HTS Insert of the MIT 1.3-GHz<br />
LTS/HTS NMR Magnet: A Small-Model Study<br />
Jiho Lee, Dongkeun Park, Philip Michael, et al.<br />
Massachusetts Institute of Technology, USA<br />
Mon-Af-Po1.03-04 [26]<br />
Direct current decay in a closed YBCO No-insulation coil<br />
under external AC magnetic field<br />
Jun Ma<br />
Cambridge University, United Kingdom<br />
Mon-Af-Po1.03-05 [27]<br />
Defect-Irrelevant Behavior of No-Insulation REBCO Coils<br />
at 4.2 K<br />
Kyle Radcliff, Kwanglok Kim, Xinbo Hu, et al.<br />
Applied Superconductivity Center-NHMFL, FL, USA<br />
Mon-Af-Po1.03-06 [28]<br />
Optimal Design Methodology of Multi-Width HTS Magnet<br />
Min Cheol Ahn, Hongmin Yang, Kyungmin Kim, et al.<br />
Kunsan National University, Korea<br />
Mon-Af-Po1.03-07 [29]<br />
Controllability of the contact resistance of 2G HTS coil<br />
with metal insulation<br />
Myung-hwan Sohn, Kideok Sim, Beomyong Eom, et al.<br />
Korea Electro-technology Research Institute, Korea<br />
Mon-Af-Po1.03-08 [30]<br />
Quench Behaviour of Bi2Sr2CaCu2O8+x insert coils for<br />
high field magnets<br />
Steven Ball, Andrew Twin, David Warren, et al.<br />
Oxford Instruments, United Kingdom<br />
52
Poster Session 1.04 13:15 - 15:00 Posters Area<br />
Motors - I<br />
Mon-Af-Po1.04-01 [31]<br />
Estimation of Permanent Magnet Temperature using d-<br />
axis Current for IPMSM<br />
Chang-sung Jin, Sooyoung Cho and Jae-kwang Lee<br />
Hanwha Techwin, Korea<br />
Mon-Af-Po1.04-02 [32]<br />
Proposed Commutation Method for Performance Improvement<br />
of Brushless DC Motor<br />
Chang-sung Jin, Sooyoung Cho and Jae-kwang Lee<br />
Hanwha Techwin, Korea<br />
Mon-Af-Po1.04-03 [33]<br />
Investigation and Optimization of the Field Regulation<br />
Capacity in a Hybrid Axial Field Flux-Switching Permanent<br />
Magnet Machine<br />
Da Xu, Mingyao Lin, Li Hao, Nian Li and Qiang Li<br />
Southeast University, China<br />
Mon-Af-Po1.04-04 [34]<br />
Analysis and comparison of dual stator linear primary<br />
permanent magnet vernier machine and fault-tolerant linear<br />
vernier machine<br />
Fangfang Bian and Wenxiang Zhao<br />
Jiangsu University, China<br />
Mon-Af-Po1.04-05 [35]<br />
A new dual air-gap linear permanent magnet vernier machine<br />
using ring type windings<br />
Fangfang Bian and Wenxiang Zhao<br />
Jiangsu University, China<br />
Mon-Af-Po1.04-06 [36]<br />
Flux Characteristics Analysis of a Single-phase Tubular<br />
Switched Reluctance Linear Motor<br />
Hao Chen, Wenju Yan and Zhixiong Li<br />
China University of Mining & Technology, China<br />
Mon-Af-Po1.04-07 [37]<br />
Analytical Polynomial Models of Nonlinear Magnetic Flux<br />
Linkage for Switched Reluctance Motor<br />
Hao Chen, Wenju Yan, Lei Chen, Meng Sun and Zheng Liu<br />
China University of Mining & Technology, China<br />
Mon-Af-Po1.04-08 [38]<br />
Electromagnetic Analysis on Dual-Stator Switched Reluctance<br />
Motor<br />
Hao Chen, Rui Nie and Tong Xu<br />
China University of Mining & Technology, China<br />
Mon<br />
53
Mon<br />
Mon-Af-Po1.04-09 [39]<br />
Analysis of Magnetic Polarity Distribution for a Dual-rotor<br />
Switched Reluctance Machine<br />
Hao Chen, Tong Xu and Rui Nie<br />
China University of Mining & Technology, China<br />
Mon-Af-Po1.04-10 [40]<br />
A transverse flux single-phase tubular switched reluctance<br />
linear motor<br />
Hao Chen and Rui Nie<br />
China University of Mining & Technology, China<br />
Mon-Af-Po1.04-11 [41]<br />
SynRM Rib optimal Design method for High-Power Density<br />
Jae-Kwang Lee, Sol Kim and Ju Lee<br />
Hanyang University, Korea<br />
Mon-Af-Po1.04-12 [42]<br />
Design principle of WFSM for Electric Vehicle based<br />
magnetic-thermal equivalent circuit<br />
Jae-Jun Lee, Jae-Kwang Lee and Gang Seok Lee<br />
Hyundai Heavy Industries Co.,Ltd, Korea<br />
Mon-Af-Po1.04-13 [43]<br />
Design and Initial Results of a Novel in-situ A.C. loss<br />
Measurement in Axial Flux Synchronous Machine<br />
Jay Patel, Jie Sheng, Min Zhang and Weijia Yuan<br />
University of Bath, Bath, United Kingdom<br />
Mon-Af-Po1.04-14 [44]<br />
3D Electromagnetic Design and Analysis of a 1-HP-Class<br />
HTS Rotating Machine integrated with a Contactless HTS<br />
Excitation Device<br />
Ji Hyung Kim, Ho Min Kim, Chang Ju Hyeon, et al.<br />
Jeju National University, Korea<br />
Mon-Af-Po1.04-15 [45]<br />
High Efficiency Permanent Magnet Linear Synchronous<br />
Motor<br />
Hongliang Wang, Jian Li, Ronghai Qu, et al.<br />
Huazhong University of Science & Technology, China<br />
Mon-Af-Po1.04-16 [46]<br />
Numerical Analysis and Design of SPM Type Variable<br />
Flux Memory Motor Considering Magnetization and Demagnetization<br />
Characteristic of Permanent Magnet<br />
Jin-Seok Kim, Sang-Yong Jung and Dae-Woo Kim<br />
Sungkyunkwan University, Korea<br />
54
Mon-Af-Po1.04-17 [47]<br />
A Study on the Position Signal Compensation Control<br />
Technique of Hall Sensor Generated by Uneven Magnetic<br />
Flux Density<br />
Jongsuk Lim, Lee Ju, Sol Kim and Dong-Woo Kang<br />
Hanyang University, Korea<br />
Mon-Af-Po1.04-18 [48]<br />
Study on the design of a Very-high speed PM Motor/Generator<br />
for Electric-Turbo Compounding System<br />
Dong-Hoon Jung, Ju Lee, Jongsuk Lim, et al.<br />
Hanyang University, Korea<br />
Mon-Af-Po1.04-19 [49]<br />
Design method of an ultra-high speed PM Motor/Generator<br />
for Electric-Turbo Compounding System<br />
Dong-Hoon Jung, Ju Lee, Jongsuk Lim, et al.<br />
Hanyang University, Korea<br />
Mon-Af-Po1.04-20 [50]<br />
Effect of Multi-phase Winding on Surface Permanent-<br />
Magnet Machine with Low Space Harmonics for Electric<br />
Steering Gear<br />
Junqiang Zheng, Wenxiang Zhao and Jinghua Ji<br />
Jiangsu University, China<br />
Mon-Af-Po1.04-21 [51]<br />
Effect of Sub-Harmonics Reduction on Rotor loss in Permanent-Magnet<br />
Machines Considering Rotor Structures<br />
Junqiang Zheng, Wenxiang Zhao, Jinghua Ji, et al.<br />
Jiangsu University, China<br />
Mon-Af-Po1.04-22 [52]<br />
A study on the individual control method comparing the<br />
lateral displacement control of front wheel and rear<br />
wheel of IRWs system<br />
Junhui Won, Kyoung-jin Joo, Gang Seok Lee, et al.<br />
Hanyang Univiversity, Korea<br />
Mon-Af-Po1.04-23 [53]<br />
A study on the control method of lateral displacement<br />
and yaw angle in severely curved driving of IRWs system<br />
Junhui Won, Kyoung-Jin Joo, Gang Seok Lee, et al.<br />
Hanyang University, Korea<br />
Mon<br />
55
Mon<br />
Mon-Af-Po1.04-24 [54]<br />
A Synthetic Frozen Permeability Method to Separate PM<br />
torque in Hybrid Permanent Magnet Variable-Flux Machine<br />
Meng Ge, Jian Li, Ronghai Qu, Yang Lu and Junhua Chen<br />
Huazhong University of Science & Technology, China<br />
Mon-Af-Po1.04-25 [55]<br />
A novel non-salient pole rotor to improve self-starting<br />
performance of line start PM synchronous motor<br />
Mengxuan Lin, Dawei Li, Ronghai Qu, Xiang Ren, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.04-26 [56]<br />
Design of Dual-Channel Switched Reluctance Motor for<br />
Safety-Critical Applications Using Two 3-Phase Standard<br />
Inverters<br />
Qian Chen, Guohai Liu and Jian Wang<br />
Jiangsu University, China<br />
Mon-Af-Po1.04-27 [57]<br />
Design and Analysis of an Arc-teeth Permanent Magnet<br />
Linear Synchronous Motor for Direct-drive Application<br />
Rong Guo, Haitao Yu, Xiaomei Liu, Weibo Zhong, et al.<br />
School of Electrical Engineering, Southeast University, China<br />
Mon-Af-Po1.04-28 [58]<br />
A Multi-Phase Doubly-Fed Doubly-Salient HTS Linear<br />
Motor for Vertical Transportation<br />
Wenlong Li, Jianqiang Li, Rui Li and Zhong Ming<br />
Shenzhen University, China<br />
Mon-Af-Po1.04-29 [59]<br />
Analysis of Novel Mover Partitioned Linear Magnetic-<br />
Field Modulated Motors Having Single or Double Layer<br />
Windings<br />
Shiyuan Wang, Wenxiang Zhao and Jinghua Ji<br />
Jiangsu University, China<br />
Mon-Af-Po1.04-30 [60]<br />
Comparison of output characteristics of PMSM for EV<br />
according to water cooling and oil cooling<br />
Soo-Jin Jung, Kyoung-Jin Joo, Gang Seok Lee, et al.<br />
LG Electronics, Korea<br />
Mon-Af-Po1.04-31 [61]<br />
A Study on the Optimal Design of Step Skew Considering<br />
End Effect and Interaction Between Layers in Step<br />
Skew<br />
Sung Gu Lee, Won-Ho Kim and Jaenam Bae<br />
Busan University of Foreign Studies, Korea<br />
56
Mon-Af-Po1.04-32 [62]<br />
Optimization of the Pole Piece in Coaxial Magnetic Gears<br />
for Transfer Torque Ripple Improvement<br />
Sung-Jin Kim, Eui-Jong Park, Lee Sung-Ho, et al.<br />
Chosun University, Korea<br />
Mon-Af-Po1.04-33 [63]<br />
Design of Vernier Motor considering Irreversible Demagnetization<br />
in Permanent Magnet<br />
Sang-Yong Jung, Tae-Yong Lee, Dae-Woo Kim, et al.<br />
Sungkyunkwn University, Korea<br />
Mon-Af-Po1.04-34 [64]<br />
Electromagnetic Performances and Noise Analysis of IP-<br />
MSM according to the Control Method under Flux-Weakening<br />
Region<br />
Tae-Yong Lee, Sang-Yong Jung, Myung-Ki Seo, et al.<br />
Sungkyunkwn University, Korea<br />
Mon-Af-Po1.04-35 [65]<br />
Design and Analysis of A Novel Modular-Stator Tubular<br />
Vernier Permanent-Magnet Machine<br />
Tian Yao, Wenxiang Zhao, Fangfang Bian, et al.<br />
Jiangsu University, China<br />
Mon-Af-Po1.04-36 [66]<br />
New Modular Magnetic Equivalent Circuit of Dual-Permanent-Magnet-Excited<br />
Machine with Modulation Effect<br />
Consideration<br />
Tong Liu, Donghui Cao, Yang Shen and Jinghua Ji<br />
Jiangsu University, China<br />
Mon-Af-Po1.04-37 [67]<br />
Direct-Control Strategy for Bearingless Permanent Magnet<br />
Synchronous Motor<br />
Wei Pan, Huangqiu Zhu, Xiaoyan Diao, et al.<br />
Jiangsu University, China<br />
Mon-Af-Po1.04-38 [68]<br />
A Study on the New Skew Methodology by Cross-Stacking<br />
in Spoke type Ferrite Magnet Motor<br />
Won-Ho Kim and Sung-Gu Lee<br />
Gachon University, Korea<br />
Mon-Af-Po1.04-39 [69]<br />
Effect of Pole and Slot Combination on Vibration of<br />
Spoke-Type Permanent Magnet Motors<br />
Sunghyuk Park and Won-Ho Kim<br />
Samsung Electronics, Korea<br />
Mon<br />
57
Mon<br />
Poster Session 1.05 13:15 - 15:00 Posters Area<br />
Magnetic Levitation and Bearings<br />
Mon-Af-Po1.05-01 [70]<br />
Decoupling Control Based on Linear/Nonlinear Active<br />
Disturbance Rejection Switching for 3 Degrees of Freedom<br />
HMB<br />
Huangqiu Zhu, Zelong Zhao and Chenyin Zhao<br />
Jiangsu University, China<br />
Mon-Af-Po1.05-02 [71]<br />
Analysis of dynamic deformation and disturbing torque<br />
of superconducting spinning rotor<br />
Chunyan Cui, Xinning Hu, Hui Wang, Lankai Li, et al.<br />
Institute of Electrical Engineering, CAS, China<br />
Mon-Af-Po1.05-03 [72]<br />
Dynamic Responses of Stacked coated conductor tapes<br />
Levitated above a Permanent Magnet Guideway<br />
Kun Liu, Chang-Qing Ye, Xiang Li, Wen-Jiao Yang, et al.<br />
South West JiaoTong University, China<br />
Mon-Af-Po1.05-04 [73]<br />
Analysis on end effect and levitation force calculation<br />
for radial-type superconducting magnetic bearings<br />
Liwang Ai, Zhang Guomin, Wanjie Li, Guole Liu, et al.<br />
Institute of Electrical Engineering, CAS, China<br />
Mon-Af-Po1.05-05 [74]<br />
Levitation and guidance forces of CC-tape stacks<br />
Maxim Osipov, Sergei Pokrovskii, Dmitry Abin, et al.<br />
National Research Nuclear University, MEPhI, Russia<br />
Mon-Af-Po1.05-06 [75]<br />
Capacity Allocation of a Superconducting Flywheel Storage<br />
System (SFES) in Hybrid Energy Storage System for<br />
Wind Generation<br />
Rakkyung Ko, Youngwook Kim and Sung-kwan Joo<br />
Korea University, Korea<br />
Mon-Af-Po1.05-07 [76]<br />
A Superconducting Linear Variable Reluctance Machine<br />
for Urban Transportation Systems<br />
T.w. Ching and Wenlong Li<br />
University of Macau,China<br />
Mon-Af-Po1.05-08 [77]<br />
Decoupling Control of Bearingless Synchronous Reluctance<br />
Motor Based on Differential Geometry<br />
Xiaoyan Diao, Huangqiu Zhu and Chenyin Zhao<br />
Jiangsu University, China<br />
58
Mon-Af-Po1.05-09 [78]<br />
The performance of magnetic suspension and motor/generator<br />
of a bearingless BLDCM for flywheel energy<br />
storage system<br />
Yichen Liu, Huangqiu Zhu and Lei Huang<br />
Jiangsu University, China<br />
Mon-Af-Po1.05-10 [79]<br />
Levitation Performance of Bulk YBCO and GdBCO Under<br />
a Low-Pressure Condition<br />
Yong Zhang, Jun Zheng, Botian Zheng, Hongdi Wang, et al.<br />
Southwest Jiaotong University, China<br />
Mon-Af-Po1.05-11 [80]<br />
Electromagnetic Performance Optimization Design of 5-<br />
phase BPMSM Based on Third Harmonic Injection<br />
Yuemei Qin and Huangqiu Zhu<br />
Jiangsu university, China<br />
Mon-Af-Po1.05-12 [81]<br />
Design of Suspension Force Feedback Control System<br />
of Multiphase BPMSM Based on MRAS Inductance Parameter<br />
Identification<br />
Huangqiu Zhu and Yuemei Qin<br />
Jiangsu university, China<br />
Mon-Af-Po1.05-13 [82]<br />
Soft Sensing Modeling of Rotor Displacements Based on<br />
Continuous Hidden Markov Model<br />
Huangqiu Zhu, Hao Gu and Yuemei Qin<br />
Jiangsu University, China<br />
Mon<br />
Poster Session 1.06 13:15 - 15:00 Posters Area<br />
Transformers and SMES<br />
Mon-Af-Po1.06-01 [83]<br />
Test Winding of a 1-T Class Force-Balanced Coils Using<br />
High Temperature Superconducting Tapes<br />
Hiroharu Kamada, Toru Ueki, Akira Ninomiya, et al.<br />
Meiji University, Tokyo, Japan<br />
Mon-Af-Po1.06-02 [84]<br />
Manufacture and tests of a 1 MJ HTS Magnet for a SMES-<br />
FCL<br />
Jingye Zhang, Guomin Zhang, Liwei Jing, et al.<br />
59
Mon<br />
Mon-Af-Po1.06-03 [85]<br />
Modeling and Analysis of Parasitic Capacitance of High-<br />
Frequency High-Voltage Transformer Using Finite-Element<br />
Method<br />
Le Deng, Tao Peng, Shuang Wang, Fan Jiang, et al.<br />
Wuhan National High Magnetic Field Center, China<br />
Mon-Af-Po1.06-04 [86]<br />
Conceptual Design and Evaluation of a HTS Magnet for a<br />
SMES Used in Improving Transient Performance of a<br />
Grid-Connected PV System<br />
Lei Chen, Hongkun Chen, Jun Yang, Huiwen He, et al.<br />
Wuhan University, China<br />
Mon-Af-Po1.06-05 [87]<br />
Multi-objective filter designing for HTS SMES considering<br />
the voltage distribution characteristic<br />
Shi Jing, Liao Meng and Zhou Aobo<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.06-06 [88]<br />
Superconducting properties of Prototype Pancake Coil<br />
using MgB2 Cable<br />
Masaru Tomita, Taiki Onji, Atsushi Ishihara, et al.<br />
Railway Technical Research Institute, Japan<br />
Mon-Af-Po1.06-07 [89]<br />
Feasibility Study of MgB2 Cable for Pancake Coil of Energy<br />
Storage Device<br />
Shinya Mizuno, Tsuyoshi Yagai, Okubo Toru, et al.<br />
Sophia University, Tokyo, Japan<br />
Mon-Af-Po1.06-08 [90]<br />
Study on Integral Transformer / Reactor for Improving<br />
Power Density<br />
Su Yong Kim<br />
KETI, Korea<br />
Mon-Af-Po1.06-09 [91]<br />
Step-current method for improving energy storage density<br />
of superconducting magnet<br />
Yalan Huang and Yong Lei<br />
Sichuan University, China<br />
Mon-Af-Po1.06-10 [92]<br />
Dynamic performances analysis for HTS SMES Used in<br />
Power Grid Based on a Novel Field-Circuit Coupled<br />
Method<br />
Zuoshuai Wang, Li Ren, Yuejin Tang, Ying Xu, et al.<br />
Huazhong University of Science and Technology, China<br />
60
Poster Session 1.07 13:15 - 15:00 Posters Area<br />
Novel and Space Applications<br />
Mon-Af-Po1.07-01 [93]<br />
Design of the Conduction-cooled YBCO Magnet for a<br />
MW Class Induction Heating System<br />
Dong Zhang, Liye Xiao, Naihao Song, et al.<br />
Institute of Electrical Engineering, CAS, China<br />
Mon-Af-Po1.07-02 [94]<br />
Asymmetry in wireless power transfer between a superconducting<br />
coil and a copper coil<br />
Hui Yu, Guole Liu, Qi Liu and Zhang Guomin<br />
Institute of Electrical Engineering, CAS, China<br />
Mon-Af-Po1.07-03 [95]<br />
Design of maximum power density of TVC driving motor<br />
for space launch vehicle considering space environment<br />
Hyun-Woo Jun, Jongsuk Lim, Gang Seok Lee and Ju Lee<br />
Hanyang University, Korea<br />
Mon-Af-Po1.07-04 [96]<br />
Characteristics of SWPT according to the number of<br />
transmitting and receiver coils<br />
In-sung Jeong, Hyewon Choi, Noa Park, et al.<br />
Chosun University, Korea<br />
Mon-Af-Po1.07-05 [97]<br />
Optimization Design of a Permanent Magnetic Actuator<br />
for 126 kV Vacuum Circuit Breaker<br />
Jiaming Jiang, Lin Heyun, Shuhua Fang, et al.<br />
School of Electrical Engineering, Southeast University, China<br />
Mon-Af-Po1.07-06 [98]<br />
Decoupling Velocity and Thermal Effect in the Electromagnetic<br />
Ring Expansion Test<br />
Jiawei Wu, Qi Chen, Lei Qiu, Xiaotao Han, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.07-07 [99]<br />
Enhancement of trapped magnetic field using a largesize<br />
REBCO bulk in a desktop type superconducting<br />
bulk magnet<br />
Kazuya Yokoyama, Atsushi Katsuki, Atsuro Miura, et al.<br />
Ashikaga Institute of Technology, Japan<br />
Mon-Af-Po1.07-08 [100]<br />
Design and Optimization of a Multi-pulse Electromagnetic<br />
Deep Drawing System<br />
Lantao Huang, Jianhui Wang, Jing Zhang, et al.<br />
Xiamen University, China<br />
Mon<br />
61
Mon<br />
Mon-Af-Po1.07-09 [101]<br />
Analysis and Optimal Design of the Transmission Coils<br />
for the Wireless Power Transmission System<br />
Lantao Huang, Jianhui Wang and Jing Zhang<br />
Xiamen University, China<br />
Mon-Af-Po1.07-10 [102]<br />
Analysis of the coupling factor according to diameter of<br />
superconducting transmitting and receiving coils<br />
Noa Park, In-Sung Jeong, Seonho Hwang, et al.<br />
Chosun University, Korea<br />
Mon-Af-Po1.07-11 [103]<br />
Development of high-temperature superconducting magnet<br />
for 1 MW induction heater<br />
Shaotao Dai and Tao Ma<br />
School of Electrical Eng., Beijing Jiaotong University, China<br />
Mon-Af-Po1.07-12 [104]<br />
Design and Performance Evaluation of a Large-scale<br />
HTS DC reactor for Bulk-Power Transmission<br />
Sung-kyu Kim, Myung-hwan Sohn, Kideok Sim, et al.<br />
Korea Electrotechnology Research Institute, Korea<br />
Mon-Af-Po1.07-13 [105]<br />
Developemt of Magnetic Coupled-Connectorless Power<br />
Transfer System<br />
Suyeon Cho, Jongsuk Lim, Gang Seok Lee and Ju Lee<br />
Korea Automotive Technology Institute, Korea<br />
Mon-Af-Po1.07-14 [106]<br />
Design of a high temperature superconducting magnet<br />
for a single silicon crystal growth system<br />
Van Quan Dao, Chankyeng Lee, Jongho Choi, et al.<br />
Changwon National University, Korea<br />
Mon-Af-Po1.07-15 [107]<br />
Design and Analysis of a Superconducting Coil Magnet<br />
Applied for a Space Magnetoplasmadynamic Thruster<br />
Wenjiang Yang, Lu Yao, Baojun Wang and Haibing Tang<br />
Beihang University, China<br />
Mon-Af-Po1.07-16 [108]<br />
Investigation of bulging behavior of metallic tube in electro-magnetic<br />
forming process with a bias magnetic field<br />
Xiaoxiang Li, Quanliang Cao, Zhipeng Lai, et al.<br />
Huazhong University of Science and Technology, China<br />
62
Mon-Af-Po1.07-17 [109]<br />
Design and Analysis of a New HTS Electromagnetic<br />
Screw<br />
Zhijian Ling and Wenxiang Zhao<br />
Jiangsu University, China<br />
Poster Session 1.08 13:15 - 15:00 Posters Area<br />
Low-Tc Wires and Cables<br />
Mon<br />
Mon-Af-Po1.08-01 [110]<br />
Single-strand excitation for examining current sharing<br />
and ICR in cored and non-cored Nb3Sn Rutherford Cable<br />
at 4.2 K up to 12 tesla<br />
Chris Kovacs, Mike Sumption and Ted Collings<br />
Ohio State University, USA<br />
Mon-Af-Po1.08-02 [111]<br />
Superconducting properties of Nb3Al wires prepared<br />
with rapid heating, quenching and transformation<br />
method<br />
Xifeng Pan, Chuan Chen, Zhiming Bai and Guo Yan<br />
WST, Western Superconducting Technologies Co., China<br />
Mon-Af-Po1.08-03 [112]<br />
Ongoing efforts at internal-tin Nb3Sn strand with higher<br />
Jc and lower Qh for fusion application<br />
Jianwei Liu, Ke Zhang, Yigong Shi, Jianfeng Li, et al.<br />
WST, Western Superconducting Technologies, Co. China<br />
Mon-Af-Po1.08-04 [113]<br />
A Study on Draw-ability of Nb Filaments for Manufacturing<br />
Nb3Sn Strand<br />
Jiman Kim, Haigun Lee, Yoon Hyuck Choi, et al.<br />
Dep. of Materials Sci.&Eng., Korea University, Seoul, Korea<br />
Mon-Af-Po1.08-05 [114]<br />
3D Stress-Strain Modeling of Nb3Sn wire<br />
Jingping Chen, Ke Han and Yuhu Zhai<br />
Princeton Plasma Physics Laboratory, USA<br />
Mon-Af-Po1.08-06 [115]<br />
Enhanced critical current densities in Nb3Sn superconducting<br />
strands prepared by bronze process<br />
Ke Zhang, Xing Qin, Huixian Gao, Yigong Shi, Bo Wu, et al.<br />
WST, Western Superconducting Technologies Co., China<br />
63
Mon<br />
Mon-Af-Po1.08-07 [116]<br />
Nb-rod-method Cu-Nb/Nb3Sn wires for practical Reactand-Wind<br />
applications<br />
Masahiro Sugimoto, Kota Katayama, Akira Takagi, et al.<br />
Furukawa Electric Co., Ltd., Japan<br />
Mon-Af-Po1.08-08 [117]<br />
Low loss NbTi Superconducting Wires for the SIS100<br />
Main Magnets made by Luvata<br />
Mikael Holm and Jarmo Seppälä<br />
Luvata Pori Oy, Pori, Finland<br />
Mon-Af-Po1.08-09 [118]<br />
Irreversible strain characteristics of technical RHQT<br />
Nb3Al superconductors<br />
Nobuya Banno, Gen Nishijima, Hitoshi Kitaguchi, et al.<br />
NIMS, National Institute for Materials Science, Japan<br />
Mon-Af-Po1.08-10 [119]<br />
Influence of Reaction Heat Treatment Conditions on Interstrand<br />
Contact Resistances of Nb3Sn Rutherford Cables<br />
Ted Collings, Mike Sumption, Milan Majoros, et al.<br />
Ohio State University, USA<br />
Mon-Af-Po1.08-11 [120]<br />
Evaluation of thermal strain induced on components of<br />
Nb3Sn strand during cool down<br />
Tomone Suwa, Tsutomu Hemmi, Toru Saito, et al.<br />
Nat. Inst. for Quantum and Radiological Sci.&Techn., Japan<br />
Mon-Af-Po1.08-12 [121]<br />
Production of Aluminum Stabilized Superconducting Cable<br />
for the Mu2e Transport Solenoid<br />
Vito Lombardo, Giorgio Ambrosio, Daniel Evbota, et al.<br />
Fermilab, USA<br />
Mon-Af-Po1.08-13 [122]<br />
The influence of heating treatment on NbTi superconducting<br />
wires with Cu5Ni alloy matrix<br />
Xing Qin and Qiang Guo<br />
WST, Western Superconducting Technologies.,Ltd., China<br />
Mon-Af-Po1.08-14 [123]<br />
Superconducting properties and microstructure of high<br />
performance Nb3Al wires fabricated by RHQT and mechanically<br />
alloyed methods<br />
Yong Zhao, Y Zhang, Cc Hsin, Py Li, C Ke, G Yan, et al.<br />
Southwest Jiaotong University, China<br />
64
Mon-Af-Po1.08-15 [124]<br />
Changes of superconducting properties due to the unidirectional<br />
tensile deformation on bronze-processed<br />
Nb3Sn multifilamentary wires using various Cu-Sn-Zn<br />
ternary alloy matrices<br />
Yoshimitsu Hishinuma, Hidetoshi Oguro, et al.<br />
NIFS, National Institute for Fusion Science, Japan<br />
Poster Session 1.09 13:15 - 15:00 Posters Area<br />
Joints between Superconductors, Leads and Links<br />
Mon<br />
Mon-Af-Po1.09-01 [125]<br />
Superconducting joints made using internal Mg diffusion<br />
(IMD)-processed MgB2 wires<br />
Akiyoshi Matsumoto and Hiroaki Kumakura<br />
NIMS, National Institute for Materials Science, Japan<br />
Mon-Af-Po1.09-02 [126]<br />
Design of the internal embedded joints for the EU DEMO<br />
TF coils<br />
Aldo di Zenobio, Luigi Affinito, et al.<br />
ENEA, Italy<br />
Mon-Af-Po1.09-03 [127]<br />
Design, manufacture and test of 20 kA binary current<br />
leads for the HFML 45 T hybrid magnet<br />
Andries den Ouden, Matthias Hoffmann, et al.<br />
HFML, Radboud University, Nijmegen, the Netherlands<br />
Mon-Af-Po1.09-04 [128]<br />
Field-assisted Joining of (RE)Ba2Cu3O7-x Coated Conductors<br />
Carolyn Grimley and Justin Schwartz<br />
North Carolina State University, USA<br />
Mon-Af-Po1.09-05 [129]<br />
Simulation Analysis of Typical Defects on superconductor<br />
cable<br />
Shixiang Tang, Chunhua Fang and Yuqiu Zhou<br />
China Three Gorges University, China<br />
Mon-Af-Po1.09-06 [130]<br />
Design and Test of Joints for HIAF Superconducting Dipole<br />
Magnet Prototype<br />
Dongsheng Ni, Yuquan Chen, Lizhen Ma, Wei Wu, et al.<br />
Institute of Modern Physics CAS, China<br />
65
Mon<br />
Mon-Af-Po1.09-07 [131]<br />
Iseult-Neurospin 1500 A Currents Leads: Conceptual and<br />
Experimental Results<br />
Francois-Paul Juster, Lionel Quettier, et al.<br />
CEA, France<br />
Mon-Af-Po1.09-08 [132]<br />
MgB2 superconductive short winding joints: mathematical<br />
prevision of current behaviours and experimental<br />
validations<br />
Giovanni Valesi, Alessio Capelluto, et al.<br />
ASG superconductors SpA, Genoa, Italy<br />
Mon-Af-Po1.09-09 [133]<br />
Design, Testing and Commissioning of 25.7 kA HTS Current<br />
Leads<br />
Guido Consogno, Michael Boersch, Pascal Erni, et al.<br />
WEKA AG<br />
Mon-Af-Po1.09-10 [134]<br />
Manufacturing and Qualification Test of ITER Busbar<br />
Joint<br />
Hyungjun Kim, Chen-yu Gung, Yury Ilin, et al.<br />
ITER Organization, France<br />
Mon-Af-Po1.09-11 [135]<br />
Design and Performance Results of Optimal Vapor-<br />
Cooled MgB2 Current Leads for a 1.5 T MRI Magnet<br />
Jiman Kim, Haigun Lee, Yoon Hyuck Choi, et al.<br />
Dep. of Materials Sci.&Eng., Korea University, Seoul, Korea<br />
Mon-Af-Po1.09-12 [136]<br />
Development of 52 kA HTS Current Leads for the ITER<br />
CS Magnet Test Application<br />
Kaizhong Ding, Tingzhi Zhou, Kun Lu, et al.<br />
Institute of Plasma Physics, CAS, China<br />
Mon-Af-Po1.09-13 [137]<br />
Performance of a HTS Persistent Current System for<br />
REBCO pancake coil<br />
Kohki Takahashi, Tomoya Hase, Satoshi Awaji, et al.<br />
IMR, Tohoku University, Japan<br />
Mon-Af-Po1.09-14 [138]<br />
Development of Vapor-cooled Current Leads for LTS<br />
magnet in the EMPS<br />
Myung Su Kim and Yeon Suk Choi<br />
Korea Basic Science Institute, Korea<br />
66
Mon-Af-Po1.09-15 [139]<br />
Overview of JT-60SA HTS current lead manufacture and<br />
testing<br />
Reinhard Heller, Walter Fietz, Mathias Heiduk, et al.<br />
Karlsruhe Institute of Technology, Germany<br />
Mon-Af-Po1.09-16 [140]<br />
Electrical joints of pure aluminum stabilised sc conductors<br />
Sebi Curreli, Pasquale Fabbricatore, et al.<br />
Universita e INFN Genova (IT), Genoa, Italy<br />
Mon-Af-Po1.09-17 [141]<br />
A Prototype of a 500 A class Bi-2223/AgAu Current Lead<br />
for a Conduction Cooled Superconducting Magnet<br />
Takehisa Tsurudome, Jun Yoshida, Yukio Mikami, et al.<br />
Sumitomo Heavy Industries, Ltd., Japan<br />
Mon-Af-Po1.09-18 [142]<br />
Lead-free persistent mode joints between NbTi wires<br />
Timothy Davies, Tayebeh Mousavi, Adrian Thomas, et al.<br />
Department of Materials, University of Oxford, UK<br />
Mon-Af-Po1.09-19 [143]<br />
Optimization of 2G HTS Current Leads Working at External<br />
Magnetic Field<br />
Vasily Zubko, Vitaly Vysotsky, Sergey Fetisov, et al.<br />
Russian Scientific R&D Cable Institute, Russia<br />
Mon-Af-Po1.09-20 [144]<br />
Current transport characteristics of a superconducting<br />
joint between REBCO conductors made by a novel<br />
method<br />
Yoshinori Yanagisawa, Takeshi Ueno, et al.<br />
RIKEN, Japan<br />
Mon-Af-Po1.09-21 [145]<br />
Reliability Study on Using a Single Equivalent Connection<br />
Layer in Finite Element Models for Coated Conductors’<br />
Joint<br />
Yunhao Pan, Wei Wu, Jie Sheng, Yawei Wang, et al.<br />
Shanghai Jiao Tong University<br />
Mon-Af-Po1.09-22 [146]<br />
Resistance of splices in the LHC Main Superconducting<br />
Magnet Circuits at 1.9 K<br />
Arjan Verweij, Andrzej Siemko, et al.<br />
CERN, Geneva, Switzerland<br />
Mon<br />
67
Mon<br />
Poster Session 1.10 13:15 - 15:00 Posters Area<br />
Quench and Normal Zone Behavior<br />
Mon-Af-Po1.10-01 [147]<br />
The latest observations from results of comprehensive<br />
computer simulation of the NHMFL all-superconducting<br />
32T magnet quench tests<br />
Andrey Gavrilin, Hubertus Weijers, et al.<br />
NHMFL / FSU, Tallahassee, FL, USA<br />
Mon-Af-Po1.10-02 [148]<br />
Quench and Recovery Characteristics of Racetrack Coil<br />
for Large-capacity Wind Generator<br />
Anfeng Zhao, Binbin Zhu, Xingbin Huang, et al.<br />
Shanghai Jiao Tong University, China<br />
Mon-Af-Po1.10-03 [149]<br />
Experiments and Numerical Model of Quench Process<br />
Generated by Magnetic Disturbance in 2G HTS Tapes<br />
Anfeng Zhao, Binbin Zhu, Xingbin Huang, et al.<br />
Shanghai Jiao Tong University, China<br />
Mon-Af-Po1.10-04 [150]<br />
Quench propagation measurements on 2 km MgB2 coil<br />
up to 4 T<br />
Christophe Berriaud, Julien Avronsart, et al.<br />
CEA Saclay / Irfu, France<br />
Mon-Af-Po1.10-05 [151]<br />
Comparison of Measured and Simulated Quench Behaviors<br />
of Superconducting Magnets for Jefferson Lab’s 11<br />
GeV Super High Momentum Spectrometer<br />
Eric Sun, Paul Brindza, Steven Lassiter, et al.<br />
Jefferson Lab, USA<br />
Mon-Af-Po1.10-06 [152]<br />
Development of Quench Antennas for Quench Detection<br />
in Nb3Sn Magnets<br />
Gerard Willering, Matthias Probst, Marta Bajko, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Po1.10-07 [153]<br />
Quench Propagation Velocity and Hot Spot Temperature<br />
assessments in Nb3Sn Racetrack Model Coils using analytical<br />
and Finite Element Modelling approaches<br />
Hugo Bajas, Marta Bajko, Juan Carlos Perez, et al.<br />
CERN, Geneva, Switzerland<br />
68
Mon-Af-Po1.10-08 [154]<br />
Quench Behaviour of a Metallic Cladding REBCO Coil<br />
Containing Copper Strips for Outer Diameter Adjustment<br />
Kwangmin Kim, Kabindra Bhattarai, Kwanglok Kim, et al.<br />
National High Magnetic Field Laboratory<br />
Mon-Af-Po1.10-09 [155]<br />
Quench analysis and protection design of SECRAL II superconducting<br />
magnet<br />
Shijun Zheng, Wei Wu, Tongjun Yang, Beimin Wu, et al.<br />
Institute of Modern Physics, CAS, China<br />
Mon-Af-Po1.10-10 [156]<br />
Influence of local critical current degradation on quench<br />
characteristics of a ReBCO coil<br />
Momoe Ide, Daisuke Miyagi, Makoto Tsuda, et al.<br />
Tohoku University, Japan<br />
Mon-Af-Po1.10-11 [157]<br />
Experimental Study of Quench Performance for Superconducting<br />
Coil with YBCO Coated Conductors<br />
Panpan Chen and Jiahui Zhu<br />
China Electric Power Research Institute, China<br />
Mon-Af-Po1.10-12 [158]<br />
Unbalanced Torque in High Magnetic Field No-Insulation<br />
REBCO Pancake Magnet after Quench<br />
So Noguchi, Ryosuke Miyao and Seungyong Hahn<br />
Hokkaido University, Nat. High Magnetic Field Lab., Japan<br />
Mon-Af-Po1.10-13 [159]<br />
A Numerical Method for Simulating the Quench Behavior<br />
of Superconductors<br />
Wei Pi, Yinshun Wang, Jin Dong and Xiaochuan Shi<br />
North China Electric Power University, China<br />
Mon-Af-Po1.10-14 [160]<br />
A Study on Post-Quench Behaviors of No-insulation HTS<br />
Magnet under Over-Current Conditions<br />
Yoon Hyuck Choi, Haigun Lee, Jung-bin Song, et al.<br />
Dep. of Materials Science and Engineering, Korea University<br />
Mon-Af-Po1.10-15 [161]<br />
Investigation on Thermal and Electrical Characteristics<br />
of MgB2 Magnet Using Partial-Insulation Winding Technique<br />
Young-gyun Kim, Haigun Lee, Jiman Kim, et al.<br />
Dep. of Mat. Sci. and Eng., Korea University, Seoul, Korea<br />
Mon<br />
69
Mon<br />
Mon-Af-Po1.10-16 [162]<br />
Remarkable difference in thermal runaway behavior between<br />
a Ni-alloy reinforced Bi-2223 coil and REBCO coil<br />
Yu Suetomi, Yoshinori Yanagisawa, et al.<br />
RIKEN, Japan<br />
Mon-Af-Po1.10-17 [163]<br />
Experimental and numerical analysis of quench characteristics<br />
on a HTS coil by fault disturbance in HTS generator<br />
Zhen Huang<br />
Shanghai Jiao Tong University, China<br />
Poster Session 1.11 13:15 - 15:00 Posters Area<br />
Cryogenics for Magnet Cooling<br />
Mon-Af-Po1.11-01 [164]<br />
Development of a 1.5 Tesla whole-body MRI Magnet with<br />
a very low helium inventory<br />
Adam Johnstone, Simon Calvert, et al.<br />
Siemens Healthcare, Germany<br />
Mon-Af-Po1.11-02 [165]<br />
Low vibration vapour shielded cryostats for wide bore<br />
high field magnets<br />
Neil Clarke, Roman Viznichenko, Joe Brown, et al.<br />
Oxford Instruments, United Kingdom<br />
Mon-Af-Po1.11-03 [166]<br />
Cool-down of LTS magnets by a closed loop helium gas<br />
flow<br />
Francesco Dioguardi<br />
DH Industries BV, the Netherlands<br />
Mon-Af-Po1.11-04 [167]<br />
Thermal characteristics of a prototype HTS quadrupole<br />
magnet for In-flight fragment separator of RISP<br />
Seokho Kim, Heecheol Park, Changhyung Lee, et al.<br />
Changwon National University, Korea<br />
Mon-Af-Po1.11-05 [168]<br />
Cryogenic technologies of the NICA accelerator complex<br />
Iuliia Mitrofanova, Nikolay Agapov, et al.<br />
JINR, Russia<br />
Mon-Af-Po1.11-06 [169]<br />
Operation of the helium cryogenic system for the hybrid<br />
superconducting outsert at CHMFL<br />
Junjie Li, Zheng Rong Ouyang, Lei Shi, Xin Ai, et al.<br />
CHFML, High Field Magnet Laboratory, CAS, China<br />
70
Mon-Af-Po1.11-07 [170]<br />
Design and performance analysis of a cryostat for<br />
pulsed high magnetic field using a small scale helium<br />
liquefaction system<br />
Mengyu Liu, Shaoliang Wang and Liang Li<br />
HUST, Huazhong University of Science & Technology, China<br />
Mon-Af-Po1.11-08 [171]<br />
Design and Research of Cryostat for 3W1 SC Wiggler<br />
Magnet<br />
Miaofu Xu, Rui Ge, Lin Bian and Xiangzhen Zhang<br />
IHEP, Institute of High Energy Physics, CAS, China<br />
Mon-Af-Po1.11-09 [172]<br />
Design and construction of the magnet-cryostat for the<br />
SuperKEKB Interaction Region<br />
Norihito Ohuchi, Yasushi Arimoto, et al.<br />
KEK, Japan<br />
Mon-Af-Po1.11-10 [173]<br />
Cryogenic Oscillating Heat Pipe for Conduction-cooled<br />
Superconducting Magnets<br />
Qing Liang, Yi Li and Qiuliang Wang<br />
Institute of Electrical Engineering, CAS, China<br />
Mon-Af-Po1.11-11 [174]<br />
Cryogen Recondensed Cooling System for Electron<br />
Beam Ion Source Employing 7 T Superconducting Solenoid<br />
Magnet<br />
Su-hun Kim, Se-hee Lee and Seyong Choi<br />
Kyungpook National University, Korea<br />
Mon-Af-Po1.11-12 [175]<br />
Cooling experiment analysis of a prototype thermal siphon<br />
system for single crystal ingot growth magnet<br />
Woo Seung Lee, Kwang Myung Park, Chu Yong, et al.<br />
JH Engineering Corp., Korea<br />
Mon-Af-Po1.11-13 [176]<br />
Speed up the cooling process of superconducting magnets<br />
by applying a large cooling capacity Stirling cryocooler<br />
Xin Qiao, Daming Sun, Ya Xu, Qie Shen, Ning Zhang, et al.<br />
Inst. of Refriger. and Cryogenics, Zhejiang University, China<br />
Mon-Af-Po1.11-14 [177]<br />
Liquid nitrogen level detection method for the safe operation<br />
of onboard cryostats of high-temperature superconducting<br />
maglev vehicles under vibration condition<br />
Yu Ren, Yihuan Xu, Zhang Yulei, Yong Zhang, et al.<br />
Southwest Jiaotong University, China<br />
Mon<br />
71
Mon<br />
Poster Session 1.12 13:15 - 15:00 Posters Area<br />
Power Converters<br />
Mon-Af-Po1.12-01 [178]<br />
Design and Preliminary Test Results of the 60T Pulsed<br />
High Magnetic Field Facility at Xi'an Jiaotong University<br />
Chengxi Jiang, Hongfa Ding, Liang Li, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.12-02 [179]<br />
EMC tests at the location of the DCCT and ADC calibration<br />
laboratory at FAIR project<br />
Andrzej Stafiniak, Horst Welker, et al.<br />
GSI, Darmstadt, Germany<br />
Mon-Af-Po1.12-03 [180]<br />
Ramping Injector Power Supply for Dipole Magnets<br />
Dimitrios Papathanasiou, Bart-Jan Sustronk, et al.<br />
Ampulz, the Netherlands<br />
Mon-Af-Po1.12-04 [181]<br />
A novel digital magnet power supply approach<br />
Jan Marjanovič, Denis Molaro, Enrico Braidotti, et al.<br />
CAEN ELS s.r.l., France<br />
Mon-Af-Po1.12-05 [182]<br />
The implement of control and date acquisition system<br />
for the 100 T pulsed high magnetic field facility at<br />
WHMFC<br />
Jiangtao Shi, Xiaotao Han, Jianfeng Xie, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.12-06 [183]<br />
Research of Active Regulation for High-Stability Flat-Top<br />
Pulsed High Magnetic Field<br />
Jun Zhou, Hongfa Ding, Zhangfei Zhao, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.12-07 [184]<br />
Driving and protecting superconducting hybrid magnets<br />
Lou van Lieshout, Walter Zunnebeld, et al.<br />
Ampulz, the Netherlands<br />
Mon-Af-Po1.12-08 [185]<br />
Cascaded Multilevel Converter with Floating Capacitors<br />
for a small tokamak, PHiX<br />
Masamichi Murayama, Hiroyuki Sugino, et al.<br />
Tokyo Institute of Technology, Japan<br />
72
Mon-Af-Po1.12-09 [186]<br />
Upgrade of the Grenoble High Magnetic Field Facility<br />
Romain Barbier, François Debray, Rémi Jaymond, et al.<br />
LNCMI-EMFL-CNRS, France<br />
Mon-Af-Po1.12-10 [187]<br />
Indirectly cooled superconducting power supply for the<br />
CMD-3 thin solenoid<br />
Sergey Karpov, Alexey Bragin, Alexander Ruban, et al.<br />
Budker Institute of Nuclear Physics, Novosibirsk, Russia<br />
Mon-Af-Po1.12-11 [188]<br />
Research of a new DC breaker based on the electromagnetic<br />
forming technology for Battery power supply of<br />
long pulsed magnet<br />
Tonghai Ding, Xiaoxuan Sun, Ziqiang Song, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.12-12 [189]<br />
Design of an active ripple compensator for the 50 T highstability<br />
flat-top pulsed magnetic field<br />
Yongheng Huang, Hongfa Ding, Jun Zhou, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.12-13 [190]<br />
Design of a hybrid power supply for the 65 T high-stability<br />
flat-top pulsed magnetic field<br />
Hongfa Ding, Yongheng Huang, Jun Zhou, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.12-14 [191]<br />
Development of a new high stability of power supply in<br />
the superconducting system<br />
Bao-sheng Wang, Chen-yao Liu, Kuo-bin Liu, et al.<br />
Nat. Synchr. Radiation Research Center, Hsinchu, Taiwan<br />
Mon-Af-Po1.12-15 [192]<br />
Research on operation strategy of the pulse generator<br />
power system energizing the out coil of the 100 Tesla<br />
magnet<br />
Yun Xu, Taiqiang Sun, Zhangfei Zhao, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.12-16 [193]<br />
Development of Real-time Monitoring System of the 100<br />
MVA/100 MJ Flywheel Pulse Generator System<br />
Yun Xu, Taiqiang Sun, Zhangfei Zhao, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon<br />
73
Mon<br />
Mon-Af-Po1.12-17 [194]<br />
A new three-level repetitive pulse magnetic field power<br />
supply system<br />
Yun Xu, Kaiwen He, Siqi Huang, Jinhao Li, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.12-18 [195]<br />
Modified Design of Power Supply System for 100 Tesla<br />
Pulsed Magnetic Field<br />
Hongfa Ding, Zhangfei Zhao, Chengxi Jiang, et al.<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Po1.12-19 [196]<br />
Construction and Test of Three-coil Magnet Power Supply<br />
System for High Pulsed Magnetic Field<br />
Zhangfei Zhao, Hongfa Ding, Chengxi Jiang, et al.<br />
Huazhong University of Science and Technology, China<br />
Oral Session 4 15:00 - 16:30 G102-103 Room<br />
JT-60<br />
Session Chairs: Subrata Pradhan and Neil Mitchell<br />
Mon-Af-Or4-01 15:00<br />
[Invited] JT-60SA Magnet System Status<br />
Sam Davis, Antonio Cucchiaro, Christophe Mayri, et al.<br />
Fusion for Energy, F4E, Barcelona, Spain<br />
Mon-Af-Or4-02 15:30<br />
Vacuum Pressure Impregnation for Central Solenoid of<br />
JT-60SA<br />
Haruyuki Murakami, Kaname Kizu, et al.<br />
Nat. Inst. for Quantum and Radiological Sci.&Techn., Japan<br />
Mon-Af-Or4-03 15:45<br />
Completion of ENEA’s procurement for 9 TF coils of JT-<br />
60SA tokamak<br />
Gian Mario Polli, Antonio Cucchiaro, et al.<br />
ENEA FSN, Italy<br />
Mon-Af-Or4-04 16:00<br />
Progress of the JT-60 SA Toroidal Field coils tests in the<br />
Cold Test Facility<br />
Walid Abdel-Maksoud, Laurent Genini, et al.<br />
CEA, Saclay, France<br />
Mon-Af-Or4-05 16:15<br />
Development of a new generic analytical modeling of AC<br />
coupling losses in cable-in-conduit conductors (CICCs).<br />
Alexandre Louzguiti, Alexandre Torre, et al.<br />
CEA, Saclay, France<br />
74
Oral Session 5 15:00 - 16:30 Emerald Room<br />
NMR Magnets and Novel Medical Applications<br />
Session Chairs: Qiuliang Wang and Michael Parizh<br />
Mon-Af-Or5-01 15:00<br />
Design and technical development of a high-resolution<br />
1.3 GHz NMR magnet<br />
Yoshinori Yanagisawa, Mamoru Hamada, et al.<br />
RIKEN, Japan<br />
Mon-Af-Or5-02 15:15<br />
Fabrication and Testing of Bi-2223 Insert Coils for High<br />
Field NMR Magnets<br />
William Marshall, Mark Bird, et al.<br />
National High Magnetic Field Laboratory, Tallahassee, USA<br />
Mon-Af-Or5-03 15:30<br />
Development of liquid nitrogen cooled RE-Ba-Cu-O magnet<br />
for NMR use<br />
Gen Nishijima, Hitoshi Kitaguchi, et al.<br />
National Institute for Materials Science, Japan<br />
Mon-Af-Or5-04 15:45<br />
Development Progress of a 9.4 T 100 mm Metal-Clad No-<br />
Insulation All-REBCO High-Resolution NMR Magnet<br />
Cooled by Conduction<br />
Sanggap Lee, Seungyong Hahn, Sangwon Yoon, et al.<br />
Korea Basic Science Institute, Korea<br />
Mon-Af-Or5-05 16:00<br />
Control design of a magnetic catheter navigation system<br />
for cardiac arrhythmias<br />
Jianhua Liu, Housheng Wang and Qiuliang Wang<br />
Institute of Electrical Engineering, CAS, China<br />
Mon-Af-Or5-06 16:15<br />
Design study of an HTS magnet with REBCO coils for<br />
heavy ion beam-line experiments<br />
Kei Koyanagi, Masahiro Yoshimoto, Toru Ogitsu, et al.<br />
TOSHIBA Corporation, Japan<br />
Mon<br />
75
Mon<br />
Oral Session 6 15:00 - 16:30 Auditorium<br />
Dipole Accelerator Magnets beyond 16 T<br />
Session Chairs: Pierre Vedrine and Bernhard Auchmann<br />
Mon-Af-Or6-01 15:00<br />
[Invited] High Field Twin-aperture Dipole Magnet R&D for<br />
SPPC Pre-study<br />
Qingjin Xu, Kai Zhang, Chengtao Wang, et al.<br />
Institute for High Energy Physics, CAS, China<br />
Mon-Af-Or6-02 15:30<br />
Design of a Nb3Sn 16 T block dipole for the Future Circular<br />
Collider<br />
Clement Lorin, Maria Durante, Helene Felice, et al.<br />
CEA/IRFU,Centre d'etude de Saclay Gif-sur-Yvette, France<br />
Mon-Af-Or6-03 15:45<br />
Magnetic and mechanical design of a 16 T common coil<br />
dipole for FCC<br />
Fernando Toral and Javier Munilla<br />
CIEMAT, Spain<br />
Mon-Af-Or6-04 16:00<br />
Conceptual design of a 16 T cosθ bending dipole for the<br />
Future Circular Collider<br />
Vittorio Marinozzi, Giovanni Bellomo, et al.<br />
University of Milan / INFN, Italy<br />
Mon-Af-Or6-05 16:15<br />
Development and test of REBCO canted cosθ dipole<br />
coils with CORC® wires<br />
Andy Lin, Daniel Dietderich, et al.<br />
Lawrence Berkeley National Laboratory, Berkeley, CA, USA<br />
76
Oral Session 7 17:00 - 18:30 Emerald Room<br />
Nb 3Sn Dipole Magnets for Accelerators<br />
Session Chairs: Pasquale Fabbricatore & Giorgio Ambrosio<br />
Mon-Af-Or7-01 17:00<br />
Design and construction of the first full-length prototype<br />
of the 11T dipole magnet for the High Luminosity LHC<br />
Project at CERN<br />
Frederic Savary, Christian Hannes Loffler, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Or7-02 17:15<br />
Cold powering tests of the 2 meter Nb3Sn DS11T model<br />
magnets at CERN<br />
Gerard Willering, Marta Bajko, Hugo Bajas, et al.<br />
CERN, Geneva, Switzerland<br />
Mon-Af-Or7-03 17:30<br />
Design and test results of the Nb3Sn Canted-Cosine-<br />
Theta dipole magnet CCT4<br />
Diego Arbelaez, Lucas Brouwer, Shlomo Caspi, et al.<br />
Lawrence Berkeley National Laboratory, Berkeley, CA, USA<br />
Mon-Af-Or7-04 17:45<br />
Design and fabrication of a 15 T Nb3Sn accelerator dipole<br />
demonstrator<br />
Alexander Zlobin, Emanuela Barzi, Shlomo Caspi, et al.<br />
Fermilab, USA<br />
Mon-Af-Or7-05 18:00<br />
Measurements of Persistent Current Effects in FNAL<br />
11 T Nb3Sn Dipole Models<br />
Thomas Strauss, Gueorgui Velev, et al.<br />
Fermilab, USA<br />
Mon-Af-Or7-06 18:15<br />
Electromechanical Design of a 16 T CCT Twin-Aperture<br />
Dipole for FCC<br />
Bernhard Auchmann, Lucas Brouwer, Shlomo Caspi, et al.<br />
CERN, Geneva, Switzerland<br />
Mon<br />
77
Mon<br />
Oral Session 8 17:00 - 18:30 Auditorium<br />
Motors<br />
Session Chairs: Hao Chen and Markus Bauer<br />
Mon-Af-Or8-01 17:00<br />
Experimental Evaluation and Numerical Simulation of a<br />
HTS Linear Synchronous Motor for High Speed Railway<br />
Guangtong Ma, Liu Kang, Zhitao Wang, Kun Liu, et al.<br />
Southwest Jiaotong University, Leshan, China<br />
Mon-Af-Or8-02 17:15<br />
Design and Optimize an external rotor Ironless BLDCM<br />
used in a Flywheel Energy Storage System<br />
Kai Liu, Mingyao Lin and Xinghe Fu<br />
Southeast University, China<br />
Mon-Af-Or8-03 17:30<br />
Study on Counter-rotating Dual Rotors Radial Permanent<br />
Magnet Motor for underwater vehicle Propulsion<br />
Guangwei Liu, Qiu Guohua, Shi Jin and Zhang Fengge<br />
Shenyang University of Technology, Shenyang, China<br />
Mon-Af-Or8-04 17:45<br />
Power Loss Research and Demagnetization Analysis for<br />
High Speed Permanent Magnet Machine<br />
Yue Zhang, Sean Mcloone and Wenping Cao<br />
Queens University Belfast, United Kingdom<br />
Mon-Af-Or8-05 18:00<br />
A Novel Flux-Reversal Linear Permanent Magnet Machine<br />
with Consequent-pole Permanent Magnets and<br />
HTS Bulks<br />
Chaojie Shi, Ronghai Qu, Dawei Li and Yuting Gao<br />
Huazhong University of Science and Technology, China<br />
Mon-Af-Or8-06 18:15<br />
Design for high speed permanent magnet electrical machine<br />
with power loss research<br />
Yue Zhang, Sean Mcloone, Wenping Cao and Shi Jin<br />
Queens University Belfast, United Kingdom<br />
78
Oral Session 9 17:00 - 18:30 G102-103 Room<br />
Stability, Magnetisation and Field Quality<br />
Session Chairs: Fedor Gömöry and Matthias Mentink<br />
Mon-Af-Or9-01 17:00<br />
Overview of Recent Progress in No-Insulation REBCO<br />
Magnet Research<br />
Seungyong Hahn, Iain Dixon, Mark Bird, et al.<br />
Seoul National Uni. / Nat. High Magnetic Field Lab., Korea<br />
Mon-Af-Or9-02 17:15<br />
Mechanisms to enhance stability, post-quench recovery<br />
and availability in non-insulated REBCO magnets<br />
Wan Kan Chan and Justin Schwartz<br />
North Carolina State University, Raleigh, USA<br />
Mon-Af-Or9-03 17:30<br />
Self-heating effect in HTS coils<br />
Marc Dhallé, Anne Bergen, Erik Krooshoop, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Mon-Af-Or9-04 17:45<br />
A portable superconducting magnet system with trapped<br />
field > 3 T<br />
Zhou Difan, Mark Ainslie, Yunhua Shi, et al.<br />
University of Cambridge, Cambridge, UK<br />
Mon-Af-Or9-05 18:00<br />
Analysis of Minimum Quench Energy of ITER NbTi and<br />
Nb3Sn CICCs<br />
Tommaso Bagni, Marco Breschi, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Mon-Af-Or9-06 18:15<br />
Design of a Magnet Bore Field Mapper Consisting of a<br />
Cylindrically Fixed Array of Inexpensive Hall Elements to<br />
Probe Low-Order Spherical Harmonics in Real Time<br />
David K. Hilton, Seungyong Hahn, et al.<br />
NHMFL-FSU, Tallahassee, FL, USA<br />
Mon<br />
79
Tue<br />
Tuesday, August 29, 2017<br />
Registration at RAI Conference Center, 08:00 – 20:15<br />
Oral Session 10 08:45 - 10:15 Auditorium<br />
Wigglers, Undulators and Fast-cycling Accelerator<br />
Magnets<br />
Session Chairs: Toru Ogitsu and Sandor Feher<br />
Tue-Mo-O10-01 08:45<br />
Superconducting Undulators Toward Commercial Products<br />
Cristian Boffo, Melanie Turenne, et al.<br />
Babcock Noell GmbH, Germany<br />
Tue-Mo-O10-02 09:00<br />
Magnetic field measurements of full scale conduction<br />
cooled superconducting undulator coils<br />
Sara Casalbuoni, Nicole Glamann, Andreas Grau, et al.<br />
IBPT-KIT, Karlsruhe, Germany<br />
Tue-Mo-O10-03 09:15<br />
The Design of Magnetic Needles for Improving Magnetic<br />
Field Measurement System<br />
Yun-liang Chu, Ting-yi Chung, Fu-yuan Lin, et al.<br />
National Synchrotron Radiation Research Center, Taiwan<br />
Tue-Mo-O10-04 09:30<br />
Development of low resistance splicing between Nb3Sn<br />
and NbTi wires to make superconducting wigglers on the<br />
base of Nb3Sn superconductor<br />
Alexey Bragin, Nikolay Mezentsev, et al.<br />
Budker Institute of Nuclear Physics, Russia<br />
Tue-Mo-O10-05 09:45<br />
Status of Magnet System for CSNS RCS<br />
Changdong Deng, Jianxin Zhou, Lei Wang, Li Li, et al.<br />
Institute of High Energy Physics, China<br />
Tue-Mo-O10-06 10:00<br />
New design of a pulse magnet for the J-PARC RCS injection<br />
shift bump magnet<br />
Tomohiro Takayanagi, Yoshiro Irie, et al.<br />
JAEA/J-PARC, Japan<br />
80
Oral Session 11 08:45 - 10:15 G102-103 Room<br />
Novel Applications<br />
Session Chairs: Guangtong Ma and Bruce Strauss<br />
Tue-Mo-Or11-01 08:45<br />
[Invited] Recent Progress of Superconducting Induction<br />
Heater with HTS magnets in Korea<br />
Jongho Choi, Sangho Cho and Minwon Park<br />
Supercoil Co., Ltd., Korea<br />
Tue-Mo-Or11-02 09:15<br />
A new approach of tube bugling based on electromagnetic<br />
attractive force<br />
Qi Xiong, Hongtao Tang, Zhenxing Li, et al.<br />
China Three Gorges University, China<br />
Tue-Mo-Or11-03 09:30<br />
The limits of space radiation magnetic shielding<br />
Riccardo Musenich, Valerio Calvelli, et al.<br />
Universita e INFN Genova, Italy<br />
Tue-Mo-Or11-04 09:45<br />
Study on Electromagnetic Force Distribution and Material<br />
Forming Performance in Electromagnetic Tube Expansion<br />
with Concave Coils<br />
Li Qiu, Yijie Yu, Qi Xiong, Changzheng Deng, et al.<br />
China<br />
Tue-Mo-Or11-05 10:00<br />
Investigation of Design Considerations for an Electromagnetic<br />
Induction Coilgun System<br />
Dinh-vuong Le, Byeong-soo Go, Myung-geun Song, et al.<br />
Changwon National University, Korea<br />
Tue<br />
81
Tue<br />
Oral Session 12 08:45 - 10:15 Emerald Room<br />
Quench and Normal Zone Behaviour<br />
Session Chairs: Michinaka Sugano and Ulf P. Trociewitz<br />
Tue-Mo-Or12-01 08:45<br />
High-speed thermal imaging of quench propagation in<br />
HTS tapes using temperature-sensitive fluorescent films<br />
Roland Gyuráki, Frédéric Sirois, et al.<br />
Karlsruhe Institute of Technology, Germany<br />
Tue-Mo-Or12-02 09:00<br />
Quench propagation and degradation limits of prestrained<br />
HTS tapes with a spot heater<br />
Xingzhe Wang, Yujin Tong, Haisen Du and Huadong Qin<br />
Lanzhou University, China<br />
Tue-Mo-Or12-03 09:15<br />
Validation of Quench Protection simulations in High-<br />
Field Nb3Sn magnets by comparison with measurements.<br />
Tiina Salmi, Antti Aleksis Stenvall, et al.<br />
Tampere University of Technology, Finland<br />
Tue-Mo-Or12-04 09:30<br />
Quench Behaviour of the HL-LHC Twin Aperture Orbit<br />
Correctors<br />
Matthias Mentink, Jeroen van Nugteren, et al.<br />
CERN, Geneva, Switzerland<br />
Tue-Mo-Or12-05 09:45<br />
Prediction and analysis of quench propagation test results<br />
in the ITER TF Insert Coil using the 4C code<br />
Roberto Zanino, Roberto Bonifetto, et al.<br />
Politecnico di Torino, Italy<br />
Tue-Mo-Or12-06 10:00<br />
Electromagnetic Quench Propagation and Self-Protecting<br />
Behavior of a Stack of No-Insulation REBCO Double-<br />
Pancake Coils<br />
Kabindra Bhattarai, Kwangmin Kim, Kwanglok Kim, et al.<br />
Applied Superconductivity Center-NHMFL, Tallahassee, USA<br />
82
Oral Session 13 10:45 - 12:15 Auditorium<br />
ITER Magnets<br />
Session Chairs: Arnaud Foussat and Yury Ilin<br />
Tue-Mo-Or13-01 10:45<br />
Completion and test of the first ITER TF coil winding<br />
pack by Europe<br />
Alessandro Bonito Oliva, A. Devred, A. Felipe, et al.<br />
Fusion for Energy, Barcelona, Spain<br />
Tue-Mo-Or13-02 11:00<br />
Series Production of ITER TF Coil Winding Pack in Japan<br />
Norikiyo Koizumi, Kunihiro Matsui, et al.<br />
National Institutes for Quantum and Radiological Science<br />
and Technology, Japan<br />
Tue-Mo-Or13-03 11:15<br />
Test of ITER-TF joint samples with NIFS test facilities<br />
Shinsaku Imagawa, Norikiyo Koizumi, et al.<br />
National Institute for Fusion Science<br />
Tue-Mo-Or13-04 11:30<br />
Tcs Measurement Result of ITER Toroidal Field Insert<br />
Coil Tested in 2016<br />
Hidemasa Ozeki, Katsumi Kawano, Tomone Suwa, et al.<br />
National Institutes for Quantum and Radiological Science<br />
and Technology, Japan<br />
Tue-Mo-Or13-05 11:45<br />
Manufacture of the ITER Central Solenoid components<br />
Paul Libeyre, Carl Cormany, Nello Dolgetta, et al.<br />
ITER International Organization, France<br />
Tue-Mo-Or13-06 12:00<br />
Status of the ITER In-vessel Coils System and Progress<br />
on the Qualification of the In-Vessel Coil Conductor<br />
Anna Encheva, Arnaud Devred, Alexander Vostner, et al.<br />
ITER International Organization, France<br />
Tue<br />
83
Tue<br />
Oral Session 14 10:45 - 12:15 G102-103 Room<br />
Coils for Power, Energy, Transport, and other Applications<br />
Session Chairs: Liye Xia and Juergen Kellers<br />
Tue-Mo-Or14-01 10:45<br />
[Invited] HTS field coils with robust design for a superconducting<br />
wind turbine generator<br />
Markus Bauer, Raphaela Burzler, Veit Große, et al.<br />
THEVA Dünnschichttechnik GmbH, Germany<br />
Tue-Mo-Or14-02 11:15<br />
Hardware integration and performance analysis of a 10<br />
kW HTS wind power generator<br />
Hae-jin Sung, Byeong-soo Go, Minwon Park, et al.<br />
Changwon National University, Korea<br />
Tue-Mo-Or14-03 11:30<br />
In-vacuum magnet technology inspired from semiconductor<br />
equipment<br />
Ton Peijnenburg, Aernout Kisteman and Paul Blom<br />
VDL Enabling Technologies Group, the Netherlands<br />
Tue-Mo-Or14-04 11:45<br />
Measurement of Magnetic Materials at Room And Cryogenic<br />
Temperature for Their Application to Superconducting<br />
Wind Generators<br />
Yingzhen Liu, Jing Ou, Mathias Noe, et al.<br />
ITEP, KIT, Karlsruhe, Germany<br />
Tue-Mo-Or14-05 12:00<br />
Design and Test of a superconducting levitation system<br />
for gravity measurement<br />
Xinning Hu, Qiuliang Wang, Hui Wang, Chunyan Cui, et al.<br />
1Institute of Electrical Engineering, CAS, China<br />
84
Oral Session 15 10:45 - 12:15 Emerald Room<br />
Quench Detection and Protection Systems - I<br />
Session Chairs: Andrzej Siemko and Piyush Joshi<br />
Tue-Mo-Or15-01 10:45<br />
32T Protection Design and Operation<br />
Patrick Noyes, William Coniglio, Scott Hannahs, et al.<br />
FSU-NHMFL, Tallahassee, Fl, USA<br />
Tue-Mo-Or15-02 11:00<br />
Quench detection via Rayleigh backscattering interrogated<br />
optical fibers<br />
Federico Scurti, Weston Straka, et al.<br />
North Caroline State University, Raleigh, USA<br />
Tue-Mo-Or15-03 11:15<br />
Design and Manufacturing of the First Industrial-Grade<br />
CLIQ Units for the Protection of Superconducting Magnets<br />
for the High-Luminosity LHC Project at CERN<br />
Felix rodriguez Mateos, David Carrillo, et al.<br />
CERN, Geneva, Switzerland<br />
Tue-Mo-Or15-04 11:30<br />
Quench (Thermal Runaway) Protection of Bi2223 (DI-<br />
BSCCO) Magnets<br />
Eiji Shizuya, Takahiro Yamaguchi, et al.<br />
Sumitomo Electric Industries, Ltd., Japan<br />
Tue-Mo-Or15-05 11:45<br />
Dynamic strain characteristics and responds in a LTS<br />
sextupole magnet during excitation and spontaneous<br />
quench<br />
Mingzhi Guan, Wang Xingzhe and Youhe Zhou<br />
Institute of Modern Physics, CAS, China<br />
Tue-Mo-Or15-06 12:00<br />
Magnet quench protection of the FCC-hh 16 T block-type<br />
dipole magnet by means of quench absorption coils<br />
Matthias Mentink, Tiina-Mari Salmi, et al.<br />
CERN, Geneva, Switzerland<br />
Tue<br />
85
Tue<br />
Poster Session 2<br />
Session Chairs:<br />
Andries den Ouden and Susana Izquierdo Bermudez<br />
Poster Session 2.01 13:15 - 15:00 Posters Area<br />
Accelerator Magnets<br />
Tue-Af-Po2.01-01 [01]<br />
Preliminary design of the FAIR Super FRS superferric<br />
branched dipoles<br />
Arnaud Madur, Chhon Pes, Eun Jung Cho, et al.<br />
CEA Saclay, Fance<br />
Tue-Af-Po2.01-02 [02]<br />
Influence of 3D effects on field quality in the straight part<br />
of accelerator magnets for the High Luminosity Large<br />
Hadron Collider<br />
Emelie Nilsson, Susana izquierdo Bermudez, et al.<br />
CERN, Geneva, Switzerland<br />
Tue-Af-Po2.01-03 [03]<br />
Development of MQYY: a 90 mm NbTi double-aperture<br />
quadrupole magnet for HL-LHC<br />
Helene Felice, Jean-michel Rifflet, et al.<br />
CEA/IRFU,Centre d'etude de Saclay Gif-sur-Yvette, France<br />
Tue-Af-Po2.01-05 [04]<br />
Design Study of a Novel, LHC High-Lumi CCT Orbit Corrector.<br />
Glyn Kirby and Jeroen van Nugteren<br />
CERN, Geneva, Switzerland<br />
Tue-Af-Po2.01-06 [05]<br />
Quench Protection Heater Study with the 2-m Model<br />
Magnet of Beam Separation Dipole for the HL-LHC Upgrade<br />
Kento Suzuki, Andrea Musso, Ezio Todesco, et al.<br />
High Energy Accelerator Research Org., KEK, Japan<br />
Tue-Af-Po2.01-07 [06]<br />
Electromagnetic analysis of a superconducting bus-bar<br />
for SIS100 particle accelerator at FAIR<br />
Lukasz Tomkow, Stanislaw Trojanowski, et al.<br />
Wrocław University of Technology, Poland<br />
86
Tue-Af-Po2.01-08 [07]<br />
Magnetic Design Update of Large Aperture Beam Separation<br />
Dipole for the HL-LHC Upgrade<br />
Michinaka Sugano, Tatsushi Nakamoto, et al.<br />
KEK, Japan<br />
Tue-Af-Po2.01-09 [08]<br />
Field Measurement to evaluate iron saturation and coil<br />
end effects in the 2-m Model Magnet of Beam Separation<br />
Dipole for the HL-LHC Upgrade<br />
Shun Enomoto, Kenichi Sasaki, Nobuhiro Kimura, et al.<br />
KEK, Japan<br />
Tue-Af-Po2.01-10 [09]<br />
Magnetic measurements of the NICA booster superconducting<br />
magnets<br />
Vladimir Borisov, Pavel Akichine, et al.<br />
Joint Institute for Nuclear Research, JINR, Russia<br />
Tue-Af-Po2.01-11 [10]<br />
Measurement facility and test results for FRIB superconducting<br />
magnets at IMP<br />
Wenjie Yang, Beimin Wu, Wei Wu, Dongsheng Ni, et al.<br />
University of CAS, China<br />
Tue<br />
Poster Session 2.02 13:15 - 15:00 Posters Area<br />
Resistive Accelerator Magnets<br />
Tue-Af-Po2.02-01 [12]<br />
Sector DC Dipoles Design for the Beam Test Facility Upgrade<br />
A. Vannozzi, Lucia Sabbatini, Luigi Pellegrino, et al.<br />
INFN-LNF, Frascati, Italy<br />
Tue-Af-Po2.02-02 [13]<br />
Optimization of the Radiation Resistant Quadrupole<br />
Magnets for the SIS-100 Accelerator of the FAIR Project<br />
Carsten Muehle, P. Nalimov, Hanno Leibrock, et al.<br />
GSI, Darmstadt, Germany<br />
Tue-Af-Po2.02-03 [14]<br />
Accurate 3D Field Mapping of an Iron Shielded Split Coil<br />
Spectrometer Magnet<br />
Vjeran Vrankovic, Christina Wouters, et al.<br />
Paul Scherrer Institute, Villigen, Switzerland<br />
87
Tue<br />
Tue-Af-Po2.02-04 [15]<br />
Simulations, measurements and sorting of THOMX ring<br />
bending magnets.<br />
Cynthia Vallerand, Fabrice Marteau, et al.<br />
Linear Accelerator Laboratory, Orsay, France<br />
Tue-Af-Po2.02-05 [16]<br />
Design and characterisation of tunable high gradient<br />
permanent magnets quadrupoles<br />
Fabrice Marteau, Thomas Andre, et al.<br />
Synchrotron SOLEIL, St. Aubin, France<br />
Tue-Af-Po2.02-06 [17]<br />
Fast dipole magnet development<br />
Ivan Morozov, Ivan Okunev, Bernward Krause, et al.<br />
BINP, Novosibirsk, Russia<br />
Tue-Af-Po2.02-07 [18]<br />
Sirius - Details of the new 3.2 T Permanent Magnet Superbend<br />
James Citadini, L.n.p. Vilela, R. Basilio, et al.<br />
Brazilian Synchrotron Light Laboratory, Brazil<br />
Tue-Af-Po2.02-08 [19]<br />
Field quality from tolerance analyses in eight-piece<br />
quadrupole magnet<br />
Jie Liu, Rogue Dejus, Aric Donnelly, Chuck Doose, et al.<br />
Argonne National Laboratory, USA<br />
Tue-Af-Po2.02-09 [20]<br />
Lambertson Septum Magnet Design for the LCLS-II<br />
Beam Spreader at SLAC<br />
John Amann<br />
SLAC National Accelerator Laboratory, USA<br />
Tue-Af-Po2.02-10 [21]<br />
Quadrupole design for the 2 GeV upgrade of the CERN<br />
PS-Booster<br />
Jonathan David Speed and Antony Newborough<br />
CERN, Geneva, Switzerland<br />
Tue-Af-Po2.02-11 [22]<br />
Fast ramped dipole and DC quadrupoles design for the<br />
Beam Test Facility upgrade<br />
Lucia Sabbatini, Luigi Pellegrino, A. Vannozzi, et al.<br />
INFN-LNF, Frascati, Italy<br />
Tue-Af-Po2.02-12 [23]<br />
Design and measurent of a 2.4 tesla superbend magnet<br />
prototype at SSRF<br />
Maofei Qian, Qiaogen Zhou, Hongfei Wang, et al.<br />
Shanghai Institute of Applied Physics, CAS, China<br />
88
Tue-Af-Po2.02-13 [24]<br />
Field Measurement of a Pulse Bending Magnet for a<br />
Beam-Switching System in the J-PARC<br />
Masahiro Yoshimoto, Michikazu Kinsho, et al.<br />
JAEA/J-PARC, Japan<br />
Tue-Af-Po2.02-14 [25]<br />
Design Study of Main Magnets for the J-PARC RCS Energy<br />
Upgrade<br />
Norio Tani, Hideaki Hotchi, Hiroyuki Harada, et al.<br />
Japan Atomic Energy Agency, Japan<br />
Tue-Af-Po2.02-15 [26]<br />
Injection Kicker for HESR at FAIR using Semi-Conductor<br />
Switches<br />
Olivier Cosson, Olivier Maulat and Raimund Tölle<br />
Sigmaphi, France<br />
Tue-Af-Po2.02-16 [27]<br />
Magnetic Septa for the SIS100 Accelerator at FAIR<br />
Peter Rottländer, Carsten Mühle, et al.<br />
GSI Darmstadt, Germany<br />
Tue-Af-Po2.02-17 [28]<br />
SwissFEL Beam Dump Dipole Spectrometer Simplistic<br />
Design Backed by Accurate Magnetic Field Measurements<br />
Vjeran Vrankovic, Serguei Sidorov, et al.<br />
Paul Scherrer Institute, Villigen, Switzerland<br />
Tue<br />
Poster Session 2.03 13:15 - 15:00 Posters Area<br />
Fusion Magnets: Cooling, Testing and Quenching<br />
Tue-Af-Po2.03-01 [29]<br />
R&D of the Helium Inlet for the CFETR Central Solenoid<br />
Model Coil<br />
Aihua Xu<br />
institute of Plasma Physics, CAS, China<br />
Tue-Af-Po2.03-02 [30]<br />
Analyses of early quench development in JT-60SA toroidal<br />
field coils tested in the cold test facility<br />
Daniel Ciazynski, Frederic Molinie, et al.<br />
CEA, France<br />
89
Tue<br />
Tue-Af-Po2.03-03 [31]<br />
Dynamical Cryodistribution Model of the JT-60SA Toroidal<br />
Field Coil in Cold Test Facility<br />
François Bonne, Walid Abdel Maksoud, et al.<br />
CEA, France<br />
Tue-Af-Po2.03-04 [32]<br />
The Charging and Discharging characteristics of a YBCO<br />
Metal-insulation coil<br />
Jun Ma<br />
University of Cambridge, Cambridge, UK<br />
Tue-Af-Po2.03-05 [33]<br />
Study of the Hotspot Temperature during Quench in the<br />
Non-Planar Coils of W7-X<br />
Kamil Sedlak, Pierluigi Bruzzone, et al.<br />
Paul Scherrer Institute, Villigen, Switzerland<br />
Tue-Af-Po2.03-06 [34]<br />
Current Center Line Measurement of ITER TF Coil<br />
Mio Nakamoto, Norikiyo Koizumi, et al.<br />
Nat. Inst. Quantum and Radiological Sci. and Techn., Japan<br />
Tue-Af-Po2.03-07 [35]<br />
Quench simulation of a DEMO TF coil using a quasi-3D<br />
coupling tool<br />
Quentin le Coz, Daniel Ciazynski, et al.<br />
CEA/IRFM, France<br />
Tue-Af-Po2.03-08 [36]<br />
Evaluation of Voltage between Conductors for Resonance<br />
Phenomenon and Transient Response in JT-60SA<br />
Central Solenoid<br />
Kazuya Nakamura, Sho Fujiyama, Keisuke Nasu, et al.<br />
Sophia University, Tokyo, Japan<br />
Tue-Af-Po2.03-09 [37]<br />
Measurements of the Effective Thermal Conductivity of<br />
the ITER TF Coil Case Cooling System<br />
Xabier Sarasola and Pierluigi Bruzzone<br />
EPFL, Lausanne, Switzerland<br />
Tue-Af-Po2.03-10 [38]<br />
Superconducting Feeder System For ITER Central Solenoid<br />
Module Final Test Facility<br />
Zbigniew Piec<br />
General Atomics, USA<br />
90
Poster Session 2.04 13:15 - 15:00 Posters Area<br />
Superconducting, Resistive and Pulsed High Field<br />
Magnets<br />
Tue-Af-Po2.04-01 [39]<br />
Energy and material efficient non-circular bore Bitter<br />
magnets<br />
Andrey Akhmeteli and Andrey Gavrilin<br />
FSU, FL, USA<br />
Tue-Af-Po2.04-02 [40]<br />
A 9 T Cryocooler Cooled High current density NbTi superconducting<br />
magnet<br />
Bai Lifeng, Li Chengshan and Zhang Pingxiang<br />
Northwest Institute for Nonferrous Metal Research, China<br />
Tue-Af-Po2.04-03 [41]<br />
Electrical and Mechanical Interactions between Component<br />
Coils of Multi-Plex Pulsed Magnet Systems<br />
Doan Nguyen, Quyen Nguyen and Lynette Torez<br />
Los Alamos National Laboratory, USA<br />
Tue-Af-Po2.04-04 [42]<br />
A novel clamping method for resistive magnets<br />
Frans Wijnen, Chris Wulffers, Arno Engels, et al.<br />
Radboud University Nijmegen, the Netherlands<br />
Tue-Af-Po2.04-05 [43]<br />
Construction and test of the NHMFL 32 T superconducting<br />
magnet<br />
H.w. Weijers, D.v. Abraimov, S.r. Gundlach, et al.<br />
NHMFL/FSU, Tallahassee, Fl, USA<br />
Tue-Af-Po2.04-06 [44]<br />
High Speed Multi-Channel Acquisition and Mapping System<br />
based on FPGA for Pulsed Magnetic Field<br />
Yang Liu, Houxiu Xiao and Chen Li<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.04-07 [45]<br />
A Modularon-PCB-boardhigh voltage capacitor bank<br />
charger<br />
Houxiu Xiao, Fangmao Fu, Changran Li, Tao Peng, et al.<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.04-08 [46]<br />
A Desktop Size Power Supply based Marx Generator for<br />
Pulsed Magnetic Field<br />
Houxiu Xiao, Changran Li, Xinyuan Du, Fangmao Fu, et al.<br />
Huazhong University of Science and Technology, China<br />
Tue<br />
91
Tue<br />
Tue-Af-Po2.04-09 [47]<br />
Finite Element Model for the Elasto-plastic Stress Analysis<br />
of Pulsed High Field Magnets<br />
Houxiu Xiao, Tao Peng and Xinyuan Du<br />
Wuhan National High Magnetic Field Center, China<br />
Tue-Af-Po2.04-10 [48]<br />
Design and Implementation of Magnetic-Resonance-<br />
Based Wireless Power Transfer System for Sensors of<br />
Pulsed Magnetic Field System<br />
Houxiu Xiao, Xinyuan Du, Fangmao Fu and Changran Li<br />
Huazhong University of Science & Technology, China<br />
Tue-Af-Po2.04-11 [49]<br />
Research and Realization of High Stability Flat-top<br />
Pulsed Magnetic Field by a Compensation Power Supply<br />
Houxiu Xiao, Chen Li, Yang Liu, Xinyuan Du, et al.<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.04-12 [50]<br />
The conceptual design and analysis of the background<br />
magnet for a conductor test facility<br />
Linyu Sun, Pengyuan Li and Haihong Wei<br />
Southwestern Institute of Physics, China<br />
Tue-Af-Po2.04-13 [51]<br />
Static and transient magnetic design of a Septum magnet<br />
for ThomX accelerator<br />
Olivier Cosson and Patrice Jehanno<br />
Sigmaphi, France<br />
Tue-Af-Po2.04-14 [52]<br />
Development and Performance of 65 T Fast-cooling<br />
User Magnet with Long Service Life<br />
Tao Peng, Fritz Herlach and Liang Li<br />
Wuhan National High Magnetic Field Center, China<br />
Tue-Af-Po2.04-15 [53]<br />
Fast cooling high field pulsed magnet with distributed<br />
mini cooling gaps<br />
Yiliang Lv, Dong Xia, Bangduo Xu and Liang Li<br />
Huazhong University of Science and Technology, China<br />
92
Poster Session 2.05 13:15 - 15:00 Postera Area<br />
NMR Magnets<br />
Tue-Af-Po2.05-01 [54]<br />
HTS Shim Coils Energized by a Flux Pump for the MIT<br />
1.3-GHz LTS/HTS NMR magnet: Design, Construction,<br />
and Results of a Proof-of-Concept Prototype<br />
Dongkeun Park, Jiho Lee, Juan Bascuñán, et al.<br />
MIT, Plasma Science and Fusion Center, USA<br />
Tue-Af-Po2.05-02 [55]<br />
Construction and Test Results of Coils 2 and 3 of a 3-<br />
Nested-Coil 800-MHz REBCO Insert for the MIT 1.3-GHz<br />
LTS/HTS NMR Magnet<br />
Dongkeun Park, Juan Bascuñán, Philip Michael, et al.<br />
MIT, Plasma Science and Fusion Center, USA<br />
Tue-Af-Po2.05-03 [56]<br />
The Scanning Magnets For Proton Therapy at SAPT<br />
Jia Bolei and Ouyang Lianhua<br />
Shanghai Institute of Applied Physics, China<br />
Tue-Af-Po2.05-04 [57]<br />
Analytical Method to Evaluate the Manufacturing Tolerance<br />
and the Ferromagnetic Shim-ability of a 400-MHz<br />
HTS NMR Magnet<br />
Junseong Kim, Dongkeun Park, Seunghyun Song, et al.<br />
Electr. and Electr. Eng., Yonsei University, Korea<br />
Tue-Af-Po2.05-05 [58]<br />
Investigation of epoxy impregnated Nb3Sn superconducting<br />
coil for high field applications<br />
Junsheng Cheng, Wanshuo Sun, Lankai Li, et al.<br />
Institute of Electrical Engineering, CAS, China<br />
Tue-Af-Po2.05-06 [59]<br />
Construction and Test of a 400 MHz 100 mm Conduction-<br />
Cooled NMR Magnet wound with Metal-Clad GdBCO<br />
Tapes<br />
Sangwon Yoon, Kanghwan Shin, Jaemin Kim, et al.<br />
SuNAM Co., Ltd., Korea<br />
Tue-Af-Po2.05-07 [60]<br />
Design and Implementation of Ferromagnetic Shims for<br />
a 3-T 100 mm All-REBCO No-Insulation Magnet<br />
Min Cheol Ahn, Hongmin Yang, Jae Young Jang, et al.<br />
Kunsan National University, Korea<br />
Tue-Af-Po2.05-08 [61]<br />
NMR Solenoid for Multi-Sample Spectroscopy<br />
Peter Mcintyre, Akhdiyor Sattarov, et al.<br />
Texas A&M University, USA<br />
Tue<br />
93
Tue<br />
Tue-Af-Po2.05-09 [62]<br />
Development of HTS bulk NMR relaxometry with ringshaped<br />
iron rings<br />
Seokbeom Kim, Hiroshi Ueda, Susumu Fukada, et al.<br />
Okayama University, Japan<br />
Tue-Af-Po2.05-10 [63]<br />
A long solenoid HTS magnet with the Joint-less winding<br />
technique<br />
Woo-seok Kim, Seyeon Lee, Miyeon Yoon, et al.<br />
Korea Polytechnic University, Korea<br />
Tue-Af-Po2.05-11 [64]<br />
Development of a REBCO innermost coil for a persistent<br />
400 MHz (9.39 T) LTS/REBCO NMR magnet<br />
Takeshi Ueno, Hideaki Maeda, Kazama Yamagishi, et al.<br />
Sophia University, Tokyo, Japan<br />
Poster Session 2.06 13:15 - 15:00 Posters Area<br />
Motors - II<br />
Tue-Af-Po2.06-01 [65]<br />
Torque Ripple Minimization in a PM-assisted Synchronous<br />
Reluctance Motor with Different Flux Barrier Rotor<br />
Aamir Nazir and Guohai Liu<br />
Jiangsu University, Jiangsu University , China<br />
Tue-Af-Po2.06-02 [66]<br />
Research on control system of a novel coil assisted reluctance<br />
motor<br />
Aimin Liu, Peng Sun and Jiachuan Lou<br />
Shenyang University of Technology, China<br />
Tue-Af-Po2.06-03 [67]<br />
A Novel Linear Permanent Magnet Vernier Machine with<br />
HTS Coils and Halbach Permanent Magnet Array<br />
Chaojie Shi, Ronghai Qu, Dawei Li and Yuting Gao<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.06-04 [68]<br />
Performance Evaluation of a Novel Axial Flux Claw Pole<br />
Machine with Soft Magnetic Composite Cores<br />
Chengcheng Liu, Wang Youhua, Jianguo Zhu, Bo Ma, et al.<br />
Hebei University of Technology, Tianjin, China<br />
Tue-Af-Po2.06-05 [69]<br />
Analysis and optimization of bearingless flux-switching<br />
permanent motor<br />
Huangqiu Zhu and Chenyin Zhao<br />
Jiangsu University, China<br />
94
Tue-Af-Po2.06-06 [70]<br />
Flux-regulation performance for radial suspension<br />
forces of bearingless flux-switching motor<br />
Huangqiu Zhu and Chenyin Zhao<br />
Jiangsu University, China<br />
Tue-Af-Po2.06-07 [71]<br />
Design of a Novel Double-Stator Flux Reversal Machine<br />
with Hybrid HTS and PM Excitations<br />
Yuting Gao, Ronghai Qu and Dawei Li<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.06-08 [72]<br />
Optimization Design of Bearingless Synchronous Reluctance<br />
Motor<br />
Huangqiu Zhu, Ding Haifei, Lei Huang and Yuemei Qin<br />
Jiangsu University, China<br />
Tue-Af-Po2.06-09 [73]<br />
A Study on the Design of IPMSM for Reliability of Demagnetization<br />
Characteristics-based Rotor<br />
Geochul Jeong, Jong-Suk Lim, Gang-Seok Lee, et al.<br />
-<br />
Tue-Af-Po2.06-10 [74]<br />
Vibration Comparison of Two Fault-Tolerant Flux-Switching<br />
Permanent-Magnet Machines<br />
Guohai Liu, Yanxin Mao and Zheng Wang<br />
Jiangsu University, China<br />
Tue-Af-Po2.06-11 [75]<br />
Analysis and application of discrete Halbach magnet array<br />
with unequal arc lengths and unequally-changed<br />
magnetization directions<br />
Hailin Huang, Dawei Li, Ronghai Qu and Libing Jing<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.06-12 [76]<br />
3D Electromagnetic Analysis of Tubular Permanent Magnet<br />
Linear Launcher<br />
Hao Chen, Kun Liang, Rui Nie and Xiao Liu<br />
China University of Mining & Technology, China<br />
Tue-Af-Po2.06-13 [77]<br />
A Novel Five-phase Double-Stator Tubular Fault-tolerant<br />
Flux-Modulation Permanent Magnet Motor<br />
Huawei Zhou, Junjie Zhang, Zhen Lu, Guohai Liu, et al.<br />
Jiangsu University, China<br />
Tue<br />
95
Tue<br />
Tue-Af-Po2.06-14 [78]<br />
Magnetic Field Analysis of a Novel Configuration of Reluctance<br />
Machine with Axial Magnetic Flux and Radial<br />
Assisted Excitation<br />
Jiachuan Lou, Aimin Liu and Peng Sun<br />
Shenyang University of Technology, China<br />
Tue-Af-Po2.06-15 [79]<br />
A Novel Flux-Focusing Doubly Salient Memory Machine<br />
Hui Yang, Heyun Lin, Z. Q. Zhu, Jiaming Jiang, et al.<br />
Southeast University, China<br />
Tue-Af-Po2.06-16 [80]<br />
Analysis on Design Sensitivity of Permanent Magnet Motor<br />
using Lumped Magnetic Circuit Method<br />
Jung Sang-Yong, Jin-Seok Kim, Jae-Hak Lee, et al.<br />
Sungkyunkwan University, Korea<br />
Tue-Af-Po2.06-17 [81]<br />
A study on Double Layer V-Shape Magnet Type IPMSM<br />
design in view of demagnetization<br />
Jin-Seok Kim, Sang-Yong Jung, Yong-Jae Kim, et al.<br />
Sungkyunkwan University, Korea<br />
Tue-Af-Po2.06-18 [82]<br />
AC Current Transport Characteristics of HTS Stator<br />
Coils in HTS Induction/Synchronous Motor<br />
Kenichi Ikeda, Ryohei Nishino, et al.<br />
Kyoto University, Japan<br />
Tue-Af-Po2.06-19 [83]<br />
Characteristics Analysis of an HTS Homopolar Motor-<br />
Generator Set for DC to DC transformation<br />
Woo-seok Kim and Kyeongdal Choi<br />
Korea Polytechnic University, Korea<br />
Tue-Af-Po2.06-20 [84]<br />
Torque Actuator Control considering Nonlinearity of<br />
Magnetic Saturation<br />
Kyoung-Jin Joo and Sung-Hong Won<br />
Hanyang University, Korea<br />
Tue-Af-Po2.06-21 [85]<br />
Analytical Calculation for Rotor Eddy-Current Losses in<br />
Permanent Magnet machine<br />
Kyung-Hun Shin, Jang-Young Choi and Han-Wook Cho<br />
Chungnam National University, Korea<br />
Tue-Af-Po2.06-22 [86]<br />
Core Loss Calculation of Permanent Magnet Machines<br />
Using Analytical Method<br />
Kyung-Hun Shin, Jang-Young Choi and Han-Wook Cho<br />
Chungnam National University, Korea<br />
96
Tue-Af-Po2.06-25 [87]<br />
Research on a Coreless Superconducting Linear Machine<br />
for Electromagnetic Catapult<br />
Lei Huang, Jing Liu and Tao Xia<br />
Southeast University, China<br />
Tue-Af-Po2.06-26 [88]<br />
Design strategy of interior permanent magnet synchronous<br />
motor for maintaining torque performance at flux<br />
weakening region<br />
Sanghyeok Seo, Sang-yong Jung, Myung-ki Seo, et al.<br />
SungKyunKwan University, Korea<br />
Tue-Af-Po2.06-27 [89]<br />
Irreversible Demagnetization Analysis with Respect to<br />
Winding Connection and Current Ripple in Brushless DC<br />
Motor<br />
Myung-ki Seo, Sang-yong Jung, Tae-yong Lee, et al.<br />
Sungkyunkwan University, Korea<br />
Tue-Af-Po2.06-28 [90]<br />
Estimation of Flux Regulation Capability of a Hybrid PM<br />
Axial-Field Flux Switching Memory Machine Considering<br />
the Effect of Temperature<br />
Nian Li, Mingyao Lin, Gongde Yang, Li Hao, et al.<br />
Southeast University, China<br />
Tue-Af-Po2.06-29 [91]<br />
Cogging Force Reduction of Double-Sided Flux-Switching<br />
Permanent Magnet Linear Machine<br />
Qiang Liu<br />
Jiangsu Maritime Institute, China<br />
Tue-Af-Po2.06-30 [92]<br />
Low Speed Rotating Characteristics of 20 kW Class High<br />
Temperature Superconducting Induction/Synchronous<br />
Motor<br />
Siyu Guo, Taketsune Nakamura, Ryohei Nishino, et al.<br />
Kyoto University, Japan<br />
Tue-Af-Po2.06-31 [93]<br />
A Study for Flux-Variable Memory Motor Depending on<br />
the Position of the Permanent Magnets<br />
Su Yong Kim<br />
KETI, Korea<br />
Tue-Af-Po2.06-32 [94]<br />
A Study on the Selection of the Optimal Number of Poles<br />
for Maximizing the Magnetic Flux of Spoke type Permanent<br />
Magnet Motor<br />
Sung Gu Lee, Won-ho Kim and Jaenam Bae<br />
Busan University of Foreign Studies, Korea<br />
Tue<br />
97
Tue<br />
Tue-Af-Po2.06-33 [95]<br />
Variable-voltage-variable-frequency inverter drive of 20<br />
kW class the High-Temperature Superconducting Induction/Synchronous<br />
Motor<br />
Tomoharu Karashima, Taketsune Nakamura, et al.<br />
Kyoto University, Japan<br />
Tue-Af-Po2.06-34 [96]<br />
Novel 4/4 Stator/Rotor Single-Phase Asymmetric Stator-<br />
Pole Doubly Salient Machine with Permanent Magnets<br />
on Stator Teeth<br />
Wei Xu, Mingjie He and Caiyong Ye<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.06-35 [97]<br />
Improved Inner Stator-Magnet Moving-Iron Transversal-<br />
Flux Linear Oscillatory Machine with Magnets in Inner<br />
Stator Yoke<br />
Xiang Li, Wei Xu and Caiyong Ye<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.06-36 [98]<br />
Novel Heteropolar Hybrid Radial Magnetic Bearing with<br />
Double-Layer Stator for Flywheel Energy Storage System<br />
Wei Xu, Runze Zhu and Caiyong Ye<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.06-37 [99]<br />
Minimization design of torque ripple for bearingless synchronous<br />
reluctance motor<br />
Xiaoyan Diao, Huangqiu Zhu and Chenyin Zhao<br />
Jiangsu University, China<br />
Tue-Af-Po2.06-38 [100]<br />
A New Magnetic Field Modulation Type of Brushless<br />
Double-Fed Machine<br />
Xinbo Liu, Xu Zhong, Yi Du, Xun Chen and Deming Wang<br />
Jiangsu University, China<br />
Tue-Af-Po2.06-39 [101]<br />
A New Dual Stator Hybrid Excitation Flux Switching Machine<br />
with Iron Flux Bridge<br />
Yi Du, Qi Wang, Xiaoyong Zhu, Li Quan and Chao Zhang<br />
Jiangsu University, China<br />
Tue-Af-Po2.06-40 [102]<br />
A New Partitioned Stator Hybrid Excitation Flux Switching<br />
Motor with Ferrite Permanent Magnet<br />
Yi Du, Qi Wang, Xiaoyong Zhu, Li Quan and Chao Zhang<br />
Jiangsu University, China<br />
98
Tue-Af-Po2.06-41 [103]<br />
Design and Analysis of Outer-Rotor Permanent Magnet<br />
Synchronous Machine With Amorphous Stator Core<br />
Yong Kong, Mingyao Lin, Da Xu, Xinghe Fu and Liu Kai<br />
School of Electrical Engineering, Southeast University, China<br />
Poster Session 2.07 13:15 - 15:00 Posters Area<br />
Fault Current Limiters<br />
Tue-Af-Po2.07-01 [106]<br />
Study on quench and recovery characteristics of non-inductive<br />
YBCO coil under DC overcurrent<br />
Bangzhu Wang, Tao Ma, Lei Hu, Teng Zhang, et al.<br />
Beijing Jiaotong University, China<br />
Tue-Af-Po2.07-02 [107]<br />
Analysis of recovery characteristics of the SFCL applied<br />
to DC power system<br />
Byung Ik Jung, Hyeon Jin Lee and Ki Dong Park<br />
Dongkang University, Korea<br />
Tue-Af-Po2.07-03 [108]<br />
Application of the superconductive fault current limiter<br />
in limiting the transformer inrush current<br />
Chao Li, Bin Li, Xiuchang Zhang, Jianzhao Geng, et al.<br />
University of Cambridge, United Kingdom<br />
Tue-Af-Po2.07-04 [109]<br />
Electromagnetic Field Analysis of a Run - type High<br />
Temperature Superconducting Current Limiter Coil<br />
Chen Huang and Pan Wanjiang<br />
University of Science and Technology of China, China<br />
Tue-Af-Po2.07-05 [110]<br />
Winding Technology And Experimental Study On Superconductive<br />
Fault Current Limiter<br />
Chen Liang<br />
Xi'an Superconducting Magnet Technology Co.,LTD, China<br />
Tue-Af-Po2.07-06 [111]<br />
Test of a Prototype Inductive Superconducting Fault<br />
Current Limiter Using No-insulation Coil<br />
Derong Qiu, Zhuyong Li, Wei Wu, Zhen Huang, et al.<br />
Shanghai Jiao Tong University, China<br />
Tue-Af-Po2.07-07 [112]<br />
Magnetic field and characteristic analysis of the superconducting<br />
fault current limiter for DC applications<br />
Dong Xia<br />
Institute of Electrical Engineering, CAS, China<br />
Tue<br />
99
Tue<br />
Tue-Af-Po2.07-08 [113]<br />
Characteristics of superconducting coil-type DC Fault<br />
Current Limiter to increase stability in DC power system<br />
Hyewon Choi, Insung Jeong, Junbeom Kim, et al.<br />
Choson University, Korea<br />
Tue-Af-Po2.07-09 [114]<br />
Development of round flexible HTS CORC® wires for<br />
fault current limiting applications<br />
Jeremy Weiss, Danko van der Laan, Chul Kim, et al.<br />
Advanced Conductor Technologies (ACT), Boulder, USA<br />
Tue-Af-Po2.07-10 [115]<br />
Performance simulation of a bias-flux superconducting<br />
fault current limiter (SFCL) based on MATLAB/SIMULINK<br />
Jiang Shengqian, Zhu Jiahui, Wang Shanming, et al.<br />
China Electric Power Research Institute, China<br />
Tue-Af-Po2.07-11 [116]<br />
Study on Operation Charactersitcis with Flux-Lock Type<br />
SFCL considering Interruption of Circuit Breaker in<br />
Power Distribution System<br />
Jae-Chul Kim, Jin-Seok Kim and Lim Sung-hun<br />
Soongsil Unlversity, Korea<br />
Tue-Af-Po2.07-12 [117]<br />
Characteristic analysis of SFCL DC interrupting system<br />
in Windfarm<br />
Jun Beom Kim, In-Sung Jeong, Seon-Ho Hwang, et al.<br />
Chosun University, Korea<br />
Tue-Af-Po2.07-13 [118]<br />
Conceptual Design and Performance Evaluation of a 35<br />
kV / 500 A Flux-Coupling-Type SFCL for Protection of a<br />
DFIG-Based Wind Farm<br />
Lei Chen, Hongkun Chen, Huiwen He, Lei Wang, et al.<br />
Wuhan University, Wuhan, China<br />
Tue-Af-Po2.07-14 [119]<br />
Design and verification test of a flux-coupling type superconducting<br />
fault current limiter<br />
Li Ren, Sinian Yan, Ying Xu and Zuoshuai Wang<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.07-15 [120]<br />
Transient Current Limiting Characteristics of Autotransformer<br />
Type SFCL using Additional Winding<br />
Lim Sung-Hun, Han Tae-Hee and Seung-Taek Lim<br />
Soongsil University, Korea<br />
100
Tue-Af-Po2.07-16 [121]<br />
Effectiveness of Superconducting Fault Current Limiting<br />
Transformers in Power Systems<br />
Mariam Elshiekh, Min Zhang, Harsha Ravindra, et al.<br />
University of Bath, United Kingdom<br />
Tue-Af-Po2.07-17 [122]<br />
Design and Test of 10 kV/400 A Flux-coupling Type Superconducting<br />
Fault Current Limiting Module<br />
Qingquan Qiu, Liye Xiao, Zhifeng Zhang, et al.<br />
Institute of Electrical Engineering, CAS, China<br />
Tue-Af-Po2.07-18 [123]<br />
Research on the Cooling Enhancement of HTS Coil using<br />
Metal Insulation Tape<br />
Seokho Nam, Woo Seung Lee, Jinsub Kim, et al.<br />
Yonsei University, Seoul, Korea<br />
Tue-Af-Po2.07-19 [124]<br />
Effects on the Parasitic Capacitance of HTS Coils Considering<br />
Impulse Voltage for Dielectric Design<br />
Seokho Nam, Hongseok Lee, Yojong Choi, et al.<br />
Yonsei University, Seoul, Korea<br />
Tue-Af-Po2.07-20 [125]<br />
Analysis of Interruption Characteristics According to Application<br />
Position of Inductor-Combined Superconducting<br />
DC Fault Current Limiter<br />
Seonho Hwang, Hyewon Choi, In-sung Jeong, et al.<br />
Chosun University, Korea<br />
Tue-Af-Po2.07-21 [126]<br />
Comparative Study on Current Limiting Characteristics<br />
of Transformer Type Superconducting Fault Current<br />
Limiters (SFCLs) with Common Connection Point between<br />
Two Secondary Windings<br />
Shin-Won Lee, Tae-Hee Han and Sung-Hun Lim<br />
Jungwon University, Korea<br />
Tue-Af-Po2.07-22 [127]<br />
Performance Analysis and Electromagnetic Design of a<br />
Flux-coupling type SFCL<br />
Sinian Yan, Li Ren, Zuoshuai Wang, Ying Xu, et al.<br />
Huazhong University of Science and Technology, China<br />
Tue-Af-Po2.07-23 [128]<br />
Electromagnetic analysis and Optimized Design of a noval<br />
hybrid type DC Superconducting Fault Current Limiter<br />
Siyuan Liang and Yuejin Tang<br />
State Key Laboratory of Advanced Electromagnetic Engineering<br />
and Technology, China<br />
Tue<br />
101
Tue<br />
Tue-Af-Po2.07-24 [129]<br />
Current Limiting and Recovery Characteristics of A Trigger<br />
Type SFCL using Double Quench<br />
Sung-Hun Lim and Seung-Taek Lim<br />
Soongsil University, Korea<br />
Tue-Af-Po2.07-25 [130]<br />
Current Limiting Characteristics of Transformer Type<br />
Superconducting Fault Current Limiter (SFCL) due to<br />
Winding Direction of Additional Secondary Winding<br />
Tae-Hee Han, Shin-Won Lee and Sung-Hun Lim<br />
Jungwon University, Korea<br />
Tue-Af-Po2.07-26 [131]<br />
Design and fabrication of HTS DC bias coil for 500kV saturated<br />
iron core fault current limiter<br />
Tao Ma<br />
Beijing Jiaotong University, China<br />
Tue-Af-Po2.07-27 [132]<br />
Experimental tests on a superconducting hybrid DC circuit<br />
breaker<br />
Xiaoze Pei, Oliver Cwikowski, Alexander Smith, et al.<br />
University of Bath, United Kingdom<br />
Tue-Af-Po2.07-28 [133]<br />
Basic study of superconducting coils in rectifier transformers<br />
for railway electrification system<br />
Yusuke Fukumoto, Masaru Tomita, et al.<br />
Railway Technical Research Institute, Japan<br />
Tue-Af-Po2.07-29 [134]<br />
Analysis on AC Loss of DC HTS SFCL Coils due to AC<br />
Ripple Current<br />
Zhe Jiang and Yinshun Wang<br />
North China Electric Power University, China<br />
Tue-Af-Po2.07-30 [135]<br />
The optimal design of superconducting coil withstanding<br />
short-time large current impact in VSC-HVDC<br />
Zhifeng Zhang, Feng Qianqian, Haonan Wang, et al.<br />
Institute of Electrical Engineering CAS, China<br />
Poster Session 2.08 13:15 - 15:00 Posters Area<br />
ReBCO Cables and Nb3Sn CICC<br />
Tue-Af-Po2.08-01 [136]<br />
An Experimental Stability Diagram for ReBCO Roebel<br />
Cables at 4.2 K and Applied Fields up to 12 T<br />
Chris Kovacs, Mike Sumption and Milan Majoros<br />
Ohio State University, USA<br />
[137]<br />
102
Tue-Af-Po2.08-02<br />
Stacked tape HTS conductors for Fusion Magnets<br />
Davide Uglietti, Nikolay Bykovsky, et al.<br />
EPFL – SPC, Lausanne, Switzerland<br />
Tue-Af-Po2.08-03 [138]<br />
Finite element analysis of strain distribution of REBCO<br />
coated conductors subjected to bending conditions experienced<br />
in high-field magnet applications<br />
Federica Pierro, Luisa Chiesa, Soren Prestemon, et al.<br />
Tufts University, USA<br />
Tue-Af-Po2.08-04 [139]<br />
Recent progress in development of high performance<br />
CICCs for CFETR magnet<br />
Jinggang Qin<br />
-<br />
Tue-Af-Po2.08-05 [140]<br />
Manufacturing of CFETR CSMC Full-size Conductors<br />
Jinggang Qin<br />
Institute of Plasma Physics, CAS, China<br />
Tue-Af-Po2.08-06 [141]<br />
Current Capacity of Cu-sheathed Multi-filamentary<br />
Coated Conductors under the Influence of Spatial Variation<br />
of Local Critical Currents in Each Filament<br />
Kohei Higashikawa, Takumi Suzuki, et al.<br />
Kyushu University, Japan<br />
Tue-Af-Po2.08-07 [142]<br />
Numerical Study on Electro-thermal Characteristics of<br />
Core Cable Consisted Of YBCO Coated Conductor<br />
Shanshan Fu, Ming Qiu, Jianbo Guo, Jiahui Zhu, et al.<br />
China Electric Power Research Institute, China<br />
Tue-Af-Po2.08-08 [143]<br />
Experimental study on the effect of twisting on critical<br />
currents of Nb3Sn cable-in-conduit conductors<br />
Shinsaku Imagawa<br />
National Institute for Fusion Science, Japan<br />
Tue-Af-Po2.08-09 [144]<br />
Current sharing properties of REBCO superconducting<br />
parallel conductors wound into a coil<br />
Shintaro Sagawa, Masataka Iwakuma, et al.<br />
Kyushu University, Japan<br />
Tue-Af-Po2.08-10 [145]<br />
Lessons learnt by manufacturing 100 km of varied type<br />
of Cable-in-Conduit-Conductors<br />
Simonetta Turtu', Sandro Chiarelli, et al.<br />
ENEA, Italy<br />
Tue<br />
103
Tue<br />
Tue-Af-Po2.08-11 [146]<br />
Development of Analyzing Capability of React and Wind<br />
Process based on Strand Trace and Inter-Strand Resistance<br />
Measurement System for Cable-In-Conduit Conductor<br />
Tsuyoshi Yagai, Hayato Shoji, et al.<br />
Sophia University, Tokyo, Japan<br />
Tue-Af-Po2.08-12 [147]<br />
Development of small diameter HTS Cross Conductors<br />
for Fusion Magnet Application<br />
Walter H. Fietz, Nadja Bagrets, et al.<br />
Karlsruhe Institute of Technology (KIT), Karlsruhe, Germany<br />
Tue-Af-Po2.08-13 [148]<br />
Current Sharing Temperature and Quench Characteristics<br />
of ReBCO Quasi-isotropic Superconducting Strands<br />
in Different Sheaths<br />
Wei Pi, Xiaochuan Shi, Yinshun Wang and Jin Dong<br />
North China Electric Power University, China<br />
Tue-Af-Po2.08-14 [149]<br />
Experimental Study on AC Loss of a Quasi-isotropic<br />
Strand Fabricated by 2G HTS CCs in AC Magnetic Fields<br />
Yan Li, Yinshun Wang and Yanbing Hou<br />
-<br />
Tue-Af-Po2.08-15 [150]<br />
Evaluation of Electrical Characteristics for a Twisted Soldered-Stacked-Square<br />
(3S) HTS Wire with 1 mm Width<br />
Zhuyong Li, Yongkang Zhou, Daomin Hu, Dongmin Xi, et al.<br />
-<br />
Tue-Af-Po2.08-16 [151]<br />
Experimental Study on the Magnetization Losses of Triaxial<br />
CORC Cable used in All-Electric Aircraft<br />
Zixuan Zhu, Yawei Wang, Min Zhang, Jie Sheng, et al.<br />
University of Bath, United Kingdom<br />
Poster Session 2.09 13:15 - 15:00 Posters Area<br />
Mechanical Behaviour<br />
Tue-Af-Po2.09-01 [152]<br />
Mechanical properties of bulk MgB2 superconductors<br />
processed by spark plasma sintering at various temperatures<br />
Akira Murakami, Akifumi Iwamoto, et al.<br />
National Institute of Technology, Ichinoseki College, Japan<br />
104
Tue-Af-Po2.09-02 [153]<br />
Characterization of the Stress Distribution on Nb3Sn<br />
Rutherford Cables Under Transverse Compression<br />
Felix Josef Wolf, Christian Scheuerlein, et al.<br />
TU Bergakademie, Freiberg, Germany<br />
Tue-Af-Po2.09-03 [154]<br />
High definition 3D finite element analysis of low temperature<br />
Rutherford cable<br />
François Nunio and Pierre Manil<br />
CEA-IRFU, France<br />
Tue-Af-Po2.09-04 [155]<br />
Mechanical Design Analysis of MQXFB, the 7.2 m Long<br />
Low-β Quadrupole for the Hi-Luminosity LHC Upgrade<br />
Giorgio Vallone, Daniel Cheng, et al.<br />
CERN, Geneva, Switzerland<br />
Tue-Af-Po2.09-05 [156]<br />
Mechanical Performance of a Superconducting 28 GHz<br />
Ion Source Magnet for FRIB<br />
Heng Pan, Diego Arbelaez, Helene Felice, et al.<br />
Lawrence Berkeley National Laboratory, Berkeley, CA, USA<br />
Tue-Af-Po2.09-06 [157]<br />
Simulation studies of mechanical stresses and trapped<br />
field in annular REBaCuO superconducting bulk magnet<br />
for NMR spectrometer during field-cooled magnetization<br />
Hiroyuki Fujishiro, Keita Takahashi, et al.<br />
Iwate University, Japan<br />
Tue-Af-Po2.09-07 [158]<br />
Strain characteristics of Ic in brass laminated GdBCO<br />
CC tapes under various temperature and magnetic field<br />
conditions<br />
Hyung-seop Shin, Z. Bautista, M. A. Diaz, et al.<br />
Andong National University, Korea<br />
Tue-Af-Po2.09-08 [159]<br />
Investigation on Minimum Tolerable Bending Diameters<br />
of Reacted MgB2 Monofilament Wires<br />
Jung-bin Song, Haigun Lee, Jiman Kim, et al.<br />
Dep. of Materials Sci. & Eng., Korea University, Korea<br />
Tue-Af-Po2.09-09 [160]<br />
Numerical simulation of electromagnetic and thermal<br />
hoop stresses in REBaCuO superconducting ring and<br />
disk bulks reinforced by stainless steel ring with various<br />
thicknesses during field-cooled magnetization<br />
Keita Takahashi, Hiroyuki Fujishiro, et al.<br />
Iwate University, Japan<br />
Tue<br />
105
Tue<br />
Tue-Af-Po2.09-10 [161]<br />
Simulation of the ITER Toroidal Field Coil Case welding<br />
distortion using Finite Element Method<br />
Marc Jimenez, P. Aprili, P. Barbero, J. Cornella, et al.<br />
Fusion For Energy, Barcelona, Spain<br />
Tue-Af-Po2.09-11 [162]<br />
Influence of bolt positions and electrode structure in<br />
Yoroi-coil structure on stress distribution in an HTS coil<br />
winding<br />
Masahiro Kato, Daisuke Miyagi, Makoto Tsuda, et al.<br />
Tohoku University, Japan<br />
Tue-Af-Po2.09-12 [163]<br />
Tail Component Qualification for the EU ITER PF Coils<br />
Mikel bilbao Gutierrez, Kevin Smith, et al.<br />
Fusion for Energy, Barcelona, Spain<br />
Tue-Af-Po2.09-13 [164]<br />
Stress-strain behaviors of a Nb3Sn Superconducting<br />
prototype solenoid for ECR magnet during winding,<br />
cooldown and energizing processes<br />
Beimin Wu, Mingzhi Guan, Wang Xingzhe, Hu Qiang, et al.<br />
Tue-Af-Po2.09-14 [165]<br />
Strain response of superconducting magnets during excitation<br />
and quench training based on FBG and cryogenic<br />
strain gauge measurements<br />
Qiang Hu, Mingzhi Guan, Xingzhe Wang and Beimin Wu<br />
Lanzhou University; Institute of Modern Physics, CAS, China<br />
Tue-Af-Po2.09-15 [166]<br />
Degradation of Critical Current in an HTS Tape Considering<br />
Curvature of Elliptical Shape under Combined Bending<br />
and Torsion<br />
Seunghak Han, Jeyull Lee, Haeryong Jeon, et al.<br />
Yonsei University, Korea<br />
Tue-Af-Po2.09-16 [167]<br />
Experimental Study on the Mechanical Stress Effect on<br />
the Degradation of High Temperature Superconducting<br />
Coils<br />
Toru Ueki, Hiroharu Kamada, Akira Ninomiya, et al.<br />
Meiji University, Tokyo, Japan<br />
Tue-Af-Po2.09-17 [168]<br />
Study of bending behavior in Nb3Sn strands<br />
Tsutomu Hemmi, Stefanus Harjo, Hideki Kajitani, et al.<br />
National Institutes for Quantum and Radiological Science<br />
and Technology, Japan<br />
106
Poster Session 2.10 13:15 - 15:00 Posters Area<br />
Multiphysics Design and Analysis<br />
Tue-Af-Po2.10-01 [169]<br />
Comparative study between in-situ measurements and a<br />
3D efficient model for the computation of magnetic<br />
fields in High Field Polyhelix magnets<br />
Christophe Trophime, Cécile Daversin, et al.<br />
LNCMI – CNRS, France<br />
Tue-Af-Po2.10-02 [170]<br />
A Hybrid Method for the Sound Pressure Lever Analysis<br />
of a Balanced Armature Receiver<br />
Dan-ping Xu, Sang-moon Hwang, Joong-hak Kwon, et al.<br />
Sch. of Mech. Eng., Pusan National University, Korea<br />
Tue-Af-Po2.10-03 [171]<br />
A finite element model based on T-A formulation for simulating<br />
second generation high temperature superconducting<br />
coils/stacks with large number of turns<br />
Fei Liang, Huiming Zhang, Min Zhang, Weijia Yuan, et al.<br />
University of Bath, Bath, United Kingdom<br />
Tue-Af-Po2.10-04 [172]<br />
Refinement and application of a generic CFD toolkit covering<br />
the heat flows in combined solid–liquid systems to<br />
investigate thermal quench limits of superconducting<br />
magnets<br />
Fouad Aabid and Rob van Weelderen<br />
CERN, Geneva, Switzerland<br />
Tue-Af-Po2.10-05 [173]<br />
A Study on Analytical Methods of FEM-based Edge Heating<br />
System<br />
Geochul Jeong, Jong-suk Lim, Gang-seok Lee, et al.<br />
-<br />
Tue-Af-Po2.10-06 [174]<br />
Eddy Current Loss Analysis of Surface Mount High<br />
Speed Permanent Magnet Motor Base on Multi-physics<br />
Fields<br />
Rui Dai, Fengge Zhang, Guangwei Liu and Shi Jin<br />
Shenyang University of Technology<br />
Tue-Af-Po2.10-07 [175]<br />
Thermo-Magnetic Mechanical stability study of the MICE<br />
Spectrometer Solenoids<br />
Heng Pan, Soren Prestemon, Steve Virostek, et al.<br />
LBNL<br />
Tue<br />
107
Tue<br />
Tue-Af-Po2.10-08 [176]<br />
Optimal Design of the LTS Magnet employing Genetic Algorithm<br />
for EMPS<br />
Jang jae Young, Young Jin Hwang, Sangjin Lee, et al.<br />
Korea Basic Science Institute<br />
Tue-Af-Po2.10-09 [177]<br />
STEAM: A Hierarchical Co-Simulation Framework for Superconducting<br />
Accelerator Magnet Circuits<br />
Lorenzo Bortot, Bernhard Auchmann, et al.<br />
CERN, Geneva, Switzerland<br />
Tue-Af-Po2.10-10 [178]<br />
Improved Modeling of Canted-Cosine-Theta Magnets<br />
Lucas Brouwer, Diego Arbelaez, Shlomo Caspi, et al.<br />
Lawrence Berkeley National Laboratory, Berkeley, CA, USA<br />
Tue-Af-Po2.10-11 [179]<br />
Application of hierarchical matrices to large-scale electromagnetic<br />
field analyses of coils wound with coated<br />
conductors<br />
Naoki Tominaga, Takeshi Mifune, Akihiro Ida, et al.<br />
Kyoto University, Japan<br />
Tue-Af-Po2.10-12 [180]<br />
Towards real time computation of 3D magnetic field in<br />
parametrized Polyhelix magnets using a reduced basis<br />
Biot-Savart model<br />
Romain Hild, Cécile Daversin, et al.<br />
IRMA Strasbourg, France<br />
Tue-Af-Po2.10-13 [181]<br />
Shielding Current Analysis in High-Temperature Superconducting<br />
Film and Its Application<br />
Teruou Takayama, Ayumu Saitoh, et al.<br />
Yamagata University, Japan<br />
Tue-Af-Po2.10-14 [182]<br />
Research on Temperature Rise and Temperature Control<br />
for Giant Magnetostrictive Transducer<br />
Yafang Li, Bowen Wang, Wenmei Huang and Rongge Yan<br />
Hebei University of Technology, China<br />
108
Poster Session 2.11 13:15 - 15:00 Posters Area<br />
Flux Pumps and Switches<br />
Tue-Af-Po2.11-01 [183]<br />
Optimising rotor speed and design for an externallymounted<br />
HTS dynamo<br />
Rodney Badcock, Chris Bumby, Andres Pantoja, et al.<br />
Robinson Research Institute, Australia<br />
Tue-Af-Po2.11-02 [184]<br />
Impact of stator ring width on output of a dynamo-type<br />
HTS flux pump<br />
James Storey, Andres Pantoja, Zhenan Jiang, et al.<br />
Victoria University of Wellington, New Zealand<br />
Tue-Af-Po2.11-03 [185]<br />
Frequency ramping effects on a dynamo-type HTS flux<br />
pump<br />
Andres Pantoja, Rod Badcock, Zhenan Jiang, et al.<br />
Victoria University of Wellington, New Zealand<br />
Tue-Af-Po2.11-04 [186]<br />
Methods to Increase the Pumping Rate of Rotary HTS<br />
Flux-pump with Rotating HTS Tape to Charge the Field<br />
Coil of the Synchronous Motor.<br />
Haeryong Jeon, Jeyull Lee, Seunghak Han, et al.<br />
Yonsei University, Korea<br />
Tue-Af-Po2.11-05 [187]<br />
Experimental Analysis of Charging Characteristics of an<br />
HTS Field Coil with Contactless HTS Excitation Device<br />
Considering Various HTS Loads<br />
Jeyull Lee, Haeryong Jeon, Seunghak Han, et al.<br />
Yonsei University, Korea<br />
Tue-Af-Po2.11-06 [188]<br />
Thermal analysis for a fast AC field controlled HTS<br />
switch for flux pumps<br />
Jianzhao Geng<br />
University of Cambridge, UK<br />
Tue-Af-Po2.11-07 [189]<br />
A novel HTS Persistent Current Switch Controlled by AC<br />
Magnetic Field<br />
Chao Li, Jianzhao Geng, Boyang Shen, et al.<br />
University of Cambridge, UK<br />
Tue-Af-Po2.11-08 [190]<br />
Ultra-high field HTS flux-pumped magnets<br />
Tim Coombs, Jianzhao Geng, Chao Li, et al.<br />
University of Cambridge, UK<br />
Tue<br />
109
Tue<br />
Tue-Af-Po2.11-09 [191]<br />
Charging 2G HTS doable pancake coils with the HTS flux<br />
pump method<br />
Wei Wang<br />
Sichuan University, Chengdu, China<br />
Tue-Af-Po2.11-10 [192]<br />
Thermal and electric analysis of the flux pump to apply<br />
conduction cooled superconducting magnet<br />
Woo Seung Lee, Kwang Myung Park and Yoon Do Chung<br />
JH Engineering Corp., Korea<br />
Tue-Af-Po2.11-11 [193]<br />
Design Considerations and Characteristics of Antenna<br />
Arrays for Wireless Power Charging System in Superconducting<br />
MAGLEV<br />
Yoon Do Chung, Chang Young Lee and Woo Seung Lee<br />
Suwon Science College, Korea<br />
Poster Session 2.12 13:15 - 15:00 Posters Area<br />
Circuitry and Control of Magnet Systems<br />
Tue-Af-Po2.12-01 [194]<br />
Injection control by neural network approach for Pulsemagnet<br />
of Taiwan Light Source<br />
Hung-chiao Chen, Cheng-ying Kuo, Hsin-hui Chen, et al.<br />
NSRRC, Taiwan<br />
Tue-Af-Po2.12-02 [195]<br />
Determination of Threshold Electric Field for PPLP Specimen<br />
in Liquid Nitrogen Based on the Measurement of<br />
Electrical Conductivity<br />
Bang-Wook Lee, Ik-Soo Kwon, Kuniaki Sakamoto, et al.<br />
Hanyang University, Division of Electr. Eng., Korea<br />
Tue-Af-Po2.12-03 [196]<br />
Induced Voltage Characteristics by Back-Iron Effect for<br />
Electromagnetic Energy Harvester Using Magnetic Fluid<br />
Young Sun Kim and Kang Won Lee<br />
Joongbu University, Korea<br />
Tue-Af-Po2.12-04 [197]<br />
Operating characteristics of Arc-induction type DC circuit<br />
breaker<br />
Park Sangyong, Hyewon Choi, Seonho Hwang, et al.<br />
Korea<br />
110
Tue-Af-Po2.12-05 [198]<br />
Multi Objective Design Optimization of Permanent Magnet<br />
Driver Based on PSO Algorithm and Nonlinear Equivalent<br />
Magnetic Model<br />
Qingyan Wang, Shengrang Cao and Jing Zhang<br />
Jinling Institute of Technology Electrical Engineering, China<br />
Tue-Af-Po2.12-06 [199]<br />
Measurement and Analysis of Amplitude Magnetic Permeability<br />
and Magnetic Losses of Silicon Steel Sheet<br />
Ling Weng, Xiaoning Cao, Ying Sun, Wenmei Huang, et al.<br />
Hebei University of Technology, China<br />
Tue-Af-Po2.12-07 [200]<br />
Operating Characteristics of Underwater Wireless Power<br />
Transfer for Maritime Applications Using Strong Copper<br />
Resonance Coupling Coils<br />
Yoon Do Chung, Ji Seong Kim and Young Gun Park<br />
Suwon Science College, Korea<br />
Tue-Af-Po2.12-08 [201]<br />
Feasibility Study on a Multi-pole Electro-magnet using<br />
Parallel Iron-core Structure<br />
Young Jin Hwang, Jang jae Young and Yeon Suk Choi<br />
Korea Basic Science Institute, Korea<br />
Tue-Af-Po2.12-09 [202]<br />
Enhancement of the magnetic coupling by using Superconductors/Ferromagnet<br />
heterostructure<br />
Zhou Pengbo<br />
Southwest Jiaotong University, China<br />
Tue-Af-Po2.12-10 [203]<br />
Simulation and Experiment of HTS Coils with a New<br />
Structure as Inductors in STRETCH Meat Grinder Circuit<br />
Qi Dai, Yuejin Tang, Zuoshuai Wang and Li Ren<br />
R&D Center of Appl. Superc.; State Key Lab. of AEET, China<br />
Tue<br />
111
Tue<br />
Oral Session 16 15:00 - 16:30 Auditorium<br />
Nb-Ti Accelerator Magnets<br />
Session Chairs: Soren Prestemon and Fernando Toral<br />
Tue-Af-Or16-01 15:00<br />
Recommissioning and upgrades to the FNAL muon g-2<br />
magnets<br />
Karie Badgley<br />
Fermilab, USA<br />
Tue-Af-Or16-02 15:15<br />
Coil Dominated Superconducting Multiplets for the HIAF<br />
Fragment Separator Using the Canted-Cosine-Theta<br />
(CCT) geometry<br />
Wei Wu, Beimin Wu, Dongsheng Ni, Enming Mei, et al.<br />
Institute of Modern Physics, CAS, China<br />
Tue-Af-Or16-03 15:30<br />
Superconducting Magnets for High Performance ECR<br />
Ion Sources<br />
Liangting Sun, Hongwei W Zhao, Wei Wu, et al.<br />
Institute of Modern Physics, CAS, China<br />
Tue-Af-Or16-04 15:45<br />
Development of SECRAL II superconducting magnet<br />
Tongjun Yang, Wei Wu, Li Zhu, Enming Mei, et al.<br />
Institute of Modern Physics, CAS, China<br />
Tue-Af-Or16-05 16:00<br />
Status of manufacturing and testing of superconducting<br />
magnets for NICA and FAIR projects<br />
Hamlet Khodzhibagiyan, Vladimir Borisov, et al.<br />
Joint Institute for Nuclear Research (JINR), Russia<br />
Tue-Af-Or16-06 16:15<br />
A 8T Focusing Superconducting Solenoid for FRIB<br />
Chao Li, Peng Ma, Zhengfu Ge and Pingxiang Zhang<br />
Northwestern Polytechnical University, China<br />
112
Oral Session 17 15:00 - 16:30 Emerald Room<br />
ReBCO Conductor Properties & Characterisation<br />
Session Chairs: Marc Dhallé and Anna Kario<br />
Tue-Af-Or17-01 15:00<br />
Development of 300 to 500 A/mm2 at 10T/4.2K class<br />
ReBCO-CORC Round Wires<br />
Tim Mulder, Danko van der Laan, Jeremy Weiss, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Tue-Af-Or17-02 15:15<br />
In-field Characterization of Local Ic and n-indices as a<br />
Function of Longitudinal Coordinate in a Long-length<br />
GdBCO Coated Conductor<br />
Takanobu Kiss, Takumi Suzuki, et al.<br />
Kyushu University, Japan<br />
Tue-Af-Or17-03 15:30<br />
Progress in REBCO coated conductors for high magnetic<br />
field applications<br />
Venkat Selvamanickam, Rudra Pratap, et al.<br />
University of Houston, USA<br />
Tue-Af-Or17-04 15:45<br />
Superconducting properties of 2G HTS wires with artificial<br />
pinning centres fabricated using production scale<br />
PLD equipment<br />
Pavel Degtyarenko, Vsevolod Chepikov, et al.<br />
SuperOx, Russia<br />
Tue-Af-Or17-05 16:00<br />
High performance coated conductors wire for magnet<br />
applications<br />
Markus Bauer<br />
THEVA Dünnschichttechnik GmbH, Germany<br />
Tue-Af-Or17-06 16:15<br />
Defect formation and improved critical current density in<br />
YBCO superconducting films by electron beam irradiation<br />
Byung-hyuk Jun, Yeo-jin Lee and Chan-joong Kim<br />
Korea Atomic Energy Research Institute, Korea<br />
Tue<br />
113
Tue<br />
Oral Session 18 15:00 - 16:30 G102-103 Room<br />
AC Loss in Cables and Coils<br />
Session Chairs: Milan Majoros<br />
Tue-Af-Or18-01 15:00<br />
Magnetization of CORC, TWST, and Roebel Cables for<br />
HEP applications and Associated Error fields<br />
Mike Sumption, Milan Majoros, Chris Kovacs, et al.<br />
Ohio State University, USA<br />
Tue-Af-Or18-02 15:15<br />
AC Loss and inter-tape resistance in various HTS cable<br />
configurations<br />
Konstantin Yagotintsev, Peng Gao, V. A. Anvar, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Tue-Af-Or18-03 15:30<br />
Effect of striating coated conductors on reducing shielding-current-induced<br />
fields in pancake coils exposed to<br />
normal magnetic fields<br />
Naoyuki Amemiya, Naoki Tominaga, Yusuke Sogabe, et al.<br />
Kyoto University, Japan<br />
Tue-Af-Or18-04 15:45<br />
Ramping Turn-to-turn Loss and Magnetization Loss of<br />
HTS No-Insulation Coils due to Non-uniform Current Distributions<br />
(Overview)<br />
Honghai Song, Yawei Wang, Peter Wanderer, et al.<br />
BNL, Brookhaven National Laboratory, USA<br />
Tue-Af-Or18-05 16:00<br />
AC loss evaluation of a 10T class small REBCO coil with<br />
conduction-cooled configuration<br />
Sadanori Iwai, Taizo Tosaka, Shunji Nomura, et al.<br />
Toshiba Corporation, Japan<br />
Tue-Af-Or18-06 16:15<br />
Role of electrostatic charges in the calculation and<br />
measurement of AC losses in superconducting coils.<br />
Fedor Gömöry<br />
Slovak Academy of Sciences, Slovakia<br />
114
Plenary Session 3 17:00 - 18:45 Auditorium<br />
Quest and Development of Superconductors for<br />
Future Magnets<br />
Session Chairs: Lucio Rossi and Pierluigi Bruzzone<br />
Tue-Af-Pl3-01 17:00<br />
Development of superconductors for future large scale<br />
applications<br />
Amalia Ballarino<br />
CERN, Geneva, Switzerland<br />
Tue-Af-Pl3-02 17:25<br />
Advanced superconductors developed at WST<br />
Jianwei Liu<br />
WST, Western Superconducting Technologies Co, China<br />
Tue-Af-Pl3-03 17:50<br />
Development of Superconductors at Furukawa Electric<br />
Group<br />
Hisaki Sakamoto<br />
Furukawa Electric Co., Ltd., Japan<br />
Tue-Af-Pl3-04 18:15<br />
Meeting Divergent Expectations: Superconductors between<br />
Industrial Applications & Cutting-Edge Science<br />
Burkhard Prause<br />
Bruker EST, Inc., Germany<br />
Tue<br />
Exhibitors Reception 18:45 - 20:15<br />
Exhibition Area<br />
115
Wed<br />
Wednesday, August 30, 2017<br />
Registration at RAI Conference Center, 08:00 – 18:30<br />
Plenary Session 4 08:45 - 09:15 Auditorium<br />
Carbon-Ion Radio-therapy<br />
Session Chairs: Ziad Melhem and Mark Bird<br />
Wed-Mo-Pl4-01 08:45<br />
Development of Carbon-Ion Radiotherapy Facilities at<br />
NIRS<br />
Iwata Yoshiyuki<br />
National Institute of Radiological Sciences (NIRS), Japan<br />
Plenary Session 5 09:15 - 09:45 Auditorium<br />
High Field Facilities<br />
Session Chairs: Ziad Melhem and Mark Bird<br />
Wed-Mo-Pl5-01 09:15<br />
High Magnetic Field Science and Technology<br />
Greg Boebinger<br />
NHMFL/Florida State University, Tallahassee, Fl, USA<br />
Plenary Session 6 09:45 - 10:15 Auditorium<br />
Six Young Scientists Pitching Their Research<br />
Session Chairs: Sasha Ishmael and Luisa Chiesa<br />
Wed-Mo-Pl6-01 09:45<br />
High-speed thermal imaging of quench propagation in<br />
HTS tapes using temperature-sensitive fluorescent films<br />
Roland Gyuraki<br />
KIT, Karlsruhe, Germany<br />
Wed-Mo-Pl6-02 09:50<br />
1.3 GHz (30.5 T)-class super-high field NMR in a persistent<br />
current operation using HTS inner coils<br />
Yoshinori Yanagisawa<br />
RIKEN, Japan<br />
Wed-Mo-Pl6-03 09:55<br />
HTS high current cable for fusion application<br />
Nikolay Bykovsky<br />
EPFL, Switzerland<br />
Wed-Mo-Pl6-04 10:00<br />
Superconducting DC direct-drve wind generators<br />
Yingzhen Liu<br />
KIT, Karlsruhe, Germany<br />
116
Wed-Mo-Pl6-05 10:05<br />
A new understanding of the heat treatment of Nb3Sn superconducting<br />
wires<br />
Charlie Sanabria<br />
NHFML, USA<br />
Wed-Mo-Pl6-06 10:10<br />
Into the future with high temperature superconductors<br />
Jeroen van Nugteren<br />
CERN, Geneva, Switzerland<br />
Oral Session 19 10:45 - 12:15 G102-103 Room<br />
Resistive Accelerator Magnets<br />
Session Chairs: Rüdiger Picker<br />
Wed-Mo-Or19-01 10:45<br />
Twin aperture bending magnets and quadrupoles for<br />
FCC-ee<br />
Attilio Milanese and Marek Bohdanowicz<br />
CERN, Geneva, Switzerland<br />
Wed-Mo-Or19-02 11:00<br />
Design of a dipole with longitudinally variable field using<br />
permanent magnets for CLIC damping rings<br />
Manuel Angel dominguez Martinez<br />
CIEMAT, Spain<br />
Wed-Mo-Or19-03 11:15<br />
Status and realization of an high efficiency transport<br />
beamline for laser-driven ion beams<br />
Francesco Schillaci, P. Cirrone, M. Maggiore, et al.<br />
Inst. of Physics Czech Academy of Science Czech Republic<br />
Wed-Mo-Or19-04 11:30<br />
Development of prototype high gradient small aperture<br />
quadrupole magnets for HEPS-TF<br />
Yingshun Zhu, Fusan Chen, Yongji Yu, Ran Liang, et al.<br />
Institute of High Energy Physics,CAS, China<br />
Wed-Mo-Or19-05 11:45<br />
Permanent Magnet Dipoles For the ESRF Upgrade<br />
Joel Chavanne, Chamseddine Benabderrahmane, et al.<br />
European Synchrotron Radiation Facility, Grenoble, France<br />
Wed-Mo-Or19-06 12:00<br />
Tuneable permanent magnets: Power saving solutions<br />
for the next generation of high energy accelerators.<br />
Alexander Bainbridge, Jim Clarke, Ben Shepherd, et al.<br />
STFC, United Kingdom<br />
Wed<br />
117
Wed<br />
Oral Session 20 10:45 - 12:30 Auditorium<br />
Magnets for MRI<br />
Session Chairs: Michael Parizh and David Larbalestier<br />
Wed-Mo-Or20-01 10:45<br />
In Memory of David Hawksworth<br />
Graham Gilgrass<br />
Siemens Magnet Technology, Oxford, United Kingdom<br />
Wed-Mo-Or20-02 11:00<br />
Conductor for MRI magnets beyond NbTi<br />
Michael Parizh, Yuri Lvovsky and Mike Sumption<br />
GE Global Research, USA<br />
Wed-Mo-Or20-03 11:15<br />
Manufacturing Completion of the Iseult/INUMAC Whole<br />
Body 11.7 T MRI System<br />
Lionel Quettier, Guy Aubert, Thierry Schild, et al.<br />
CEA Saclay, France<br />
Wed-Mo-Or20-04 11:30<br />
Magnetic field homogeneity and stability of a conduction-cooled<br />
REBCO MRI magnet with a room-temperature<br />
bore of 396 mm<br />
Hiroshi Miyazaki, Atsushi Ishiyama, et al.<br />
Toshiba Corporation, Japan<br />
Wed-Mo-Or20-05 11:45<br />
Development of 3 T high-temperature superconducting<br />
magnet for MRI<br />
Masayoshi Oya, Tetsuya Matsuda, Tatsuya Inoue, et al.<br />
Mitsubishi Electric Corporation, Japan<br />
Wed-Mo-Or20-06 12:00<br />
Demonstration of a Wind and React MgB2 Solenoidal<br />
Coil Segment for MRI Applications<br />
Mike Sumption, Jacob Rochester, Danlu Zhang, et al.<br />
Ohio State University, USA<br />
Wed-Mo-Or20-07 12:15<br />
MRI scanner development in Russia<br />
Timophey Demikhov, Evgeny Kostrov, et al.<br />
Lebedev Physics Institute, Russia<br />
118
Oral Session 21 10:45 - 12:15 Emerald Room<br />
ReBCO Cables for Different Applications and Advanced<br />
Nb3Sn CICC<br />
Session Chairs: Takanobu Kiss and Arno Godeke<br />
Wed-Mo-Or21-01 10:45<br />
Investigation of the Roebel cable geometry and current<br />
homogeneity over lengths relevant to accelerator-type<br />
demonstrator magnet.<br />
Anna Kario, Simon Otten, Andrea Kling, et al.<br />
KIT, Karlsruhe, Germany<br />
Wed-Mo-Or21-02 11:00<br />
High-temperature superconducting CORC® magnet cable<br />
and wire development and their application<br />
Danko van der Laan, Jeremy Weiss, et al.<br />
ACT, Advanced Conductor Technologies, Boulder, USA<br />
Wed-Mo-Or21-03 11:15<br />
Bending of CORC cables, Experiments and Modeling<br />
Anvar Valiyaparambil Abdulsalam, Kirill Ilin, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Wed-Mo-Or21-04 11:30<br />
Influence of field cycle and applied current on coated<br />
conductor magentization and decay for accelerator applications<br />
Mike Sumption, Cory Myers and Ted Collings<br />
Ohio State University, USA<br />
Wed-Mo-Or21-05 11:45<br />
Demonstration Test of Two New 80 kA@12T/4K class<br />
ReBCO CORC Cable-In-Conduit Conductors for Fusion<br />
and Detector Magnets<br />
Tim Mulder, Danko van der Laan, Jeremy Weiss, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Wed-Mo-Or21-06 12:00<br />
Evolution of AC loss, inter-strand resistance and mechanical<br />
properties in prototype EU DEMO TF conductors<br />
during 30,000 load cycles<br />
Konstantin Yagotintsev, Sander Wessel, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Wed<br />
119
Wed<br />
Poster Session 3<br />
Session Chairs: Jos Perenboom and Helene Felice<br />
Poster Session 3.01 13:15 - 15:00 Posters Area<br />
FCC and other Future Accelerator Magnets<br />
Wed-Af-Po3.01-01 [01]<br />
Design Studies of High-Field Nb3Sn Dipoles for a post-<br />
LHC pp Collider<br />
Alexander Zlobin, Vadim Kashikhin, et al.<br />
Fermilab, USA<br />
Wed-Af-Po3.01-02 [02]<br />
High Gradient Nb3Sn Quadrupole Demonstrator MKQXF<br />
Engineering Design<br />
Charilaos Kokkinos and Mikko Karppinen<br />
FEAC Engineering P.C., Patras, Greece<br />
Wed-Af-Po3.01-03 [03]<br />
FEA Model and Mechanical Analysis of the Nb3Sn 15 T<br />
Dipole Demonstrator<br />
Charilaos Kokkinos, Igor Novitski, et al.<br />
FEAC Engineering P.C., Patras, Greece<br />
Wed-Af-Po3.01-04 [04]<br />
Electromagnetic Design of a Twin-Aperture Quadrupole<br />
Magnet with Common-Coil Configuration<br />
Chengtao Wang, Qingjin Xu, Ershuai Kong, et al.<br />
Inst. of High Energy Physics, CAS, China<br />
Wed-Af-Po3.01-05 [05]<br />
Design of a Nb3Sn 400 T/m quadrupole for the Future<br />
Circular Collider<br />
Clement Lorin, Maria Durante, Helene Felice, et al.<br />
CEA/IRFU,Centre d'etude de Saclay Gif-sur-Yvette, France<br />
Wed-Af-Po3.01-06 [06]<br />
Windability tests of Nb3Sn Rutherford cables for HL-LHC<br />
and FCC<br />
Dariusz Pulikowski, Friedrich Lackner, et al.<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Po3.01-07 [07]<br />
Parametric Study of Block-coil Dipoles Using Graded<br />
Conductors<br />
Etienne Rochepault, Paolo Ferracin, et al.<br />
CERN, Geneva, Switzerland<br />
120
Wed-Af-Po3.01-08 [08]<br />
3D Magnetic and Mechanical Design of Coil Ends for the<br />
Racetrack Model Magnet RMM<br />
Etienne Rochepault<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Po3.01-09 [09]<br />
A novel method for greatly reduced edge effects design<br />
in CCT magnets<br />
M Koratzinos, Glyn Kirby, Jeroen van Nugteren, et al.<br />
Universite de Geneve, Geneva, Switzerland<br />
Wed-Af-Po3.01-10 [10]<br />
Assembly of the Nb3Sn dipole magnet FRESCA2<br />
Nicolas Bourcey, Remy Gauthier, et al.<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Po3.01-11 [11]<br />
Stealth superconducting magnet technology for collider<br />
IR and injector requirements<br />
Peter Mcintyre, Jeff Breitschopf, et al.<br />
Texas A&M University, USA<br />
Wed-Af-Po3.01-12 [12]<br />
Development of the Mineral Insulated High Temperature<br />
Superconducting Magnet for Future High Intensity Muon<br />
Beamline<br />
Ye Yang, Masami Iio, Makoto Yoshida, et al.<br />
Kyushu University, Japan<br />
Wed-Af-Po3.01-13 [13]<br />
3D mechanical design and analysis of 20-T twin-aperture<br />
common-coil accelerator dipole magnet<br />
Zhang Kai, Xu Qingjin, Zhu Zian, Gianluca Sabbi, et al.<br />
Inst. of High Energy Physics, CAS, China<br />
Wed<br />
Poster Session 3.02 13:15 - 15:00 Posters Area<br />
Fusion Magnets: Manufacture and Joints<br />
Wed-Af-Po3.02-02 [15]<br />
NDT status of PF-1 coil welds<br />
Artem Belyaev, Egor Marushin, Igor Rodin, et al.<br />
JSC "NIIEFA" (Efremov Institute), Saint-Petersburg, Russia<br />
Wed-Af-Po3.02-03 [16]<br />
MIFI (Magnet Infrastructure Facilities for ITER) : activities<br />
overview<br />
Bertrand Peluso and Roland Piccin<br />
CEA, France<br />
121
Wed<br />
Wed-Af-Po3.02-04 [17]<br />
Progress on European ITER Toroidal Field Coil procurement:<br />
Cold Test and Insertion Work Package<br />
Boris Bellesia, Alessandro bonito Oliva, et al.<br />
Fusion for Energy, F4E, Barcelona, Spain<br />
Wed-Af-Po3.02-05 [18]<br />
Inter-layer Joint for the TF Coils of DEMO - Design and<br />
R&D<br />
Boris Stepanov and Pierluigi Bruzzone<br />
EPFL-SPC, Lausanne, Switzerland<br />
Wed-Af-Po3.02-06 [19]<br />
The PF1 coil electrical joint test results<br />
Egor Marushin, Andrei Mednikov, et al.<br />
JSC "NIIEFA" (Efremov Institute), Saint-Petersburg, Russia<br />
Wed-Af-Po3.02-07 [20]<br />
New inspection method of joint resistance at room temperature<br />
for ITER TF Coil<br />
Hideki Kajitani, Tsutomu Hemmi, Yasuhiro Uno, et al.<br />
Nat. Inst. for Quantum and Radiological Sci. & Techn., Japan<br />
Wed-Af-Po3.02-08 [21]<br />
Winding R&D for CFETR Central Solenoid Model Coil<br />
Houxiang Han, Dapeng Yin, Yu Wu, Jingang Qin, et al.<br />
ASIPP, Institute for Plasma Physics, CAS, China<br />
Wed-Af-Po3.02-09 [22]<br />
Optimization of the ITER Pre-Compression Ring Test Rig<br />
Flange<br />
Luigi Reccia, Luigi Semeraro, et al.<br />
Fusion for Energy, F4E, Barcelona, Spain<br />
Wed-Af-Po3.02-10 [23]<br />
Progress of ITER TF Coil Case fabrication in Japan<br />
Masahide Iguchi, Takeru Sakurai, et al.<br />
Nat. Inst. for Quantum and Radiological Sci. & Techn., Japan<br />
Wed-Af-Po3.02-11 [24]<br />
Completion of the French JT-60SA Toroïdal Field Magnet<br />
Contribution<br />
Patrick Decool, Gilles Gros, Guillaume Jiolat, et al.<br />
CEA, France<br />
Wed-Af-Po3.02-12 [25]<br />
Winding Deformation Caused by Reaction Heat-treatment<br />
for ITER TF coil<br />
Tsutomu Hemmi, Hideki Kajitani, et al.<br />
Nat. Inst. for Quantum and Radiological Sci. & Techn., Japan<br />
122
Wed-Af-Po3.02-13 [26]<br />
Basic Design and Progress of Central Solenoid Model<br />
Coil for CFETR<br />
Yu Wu, Yi Shi, Jinggang Qin, Bo Liu and Dapeng Yin<br />
ASIPP, Institute for Plasma Physics, CAS, China<br />
Poster Session 3.03 13:15 - 15:00 Posters Area<br />
HTS Inserts and Model Magnets<br />
Wed-Af-Po3.03-01 [27]<br />
A Study on Temporal Stabilization of Magnetic Flux Focused<br />
by a Superconducting Magnetic Lens<br />
Akihisa Miyazoe and Chishin Hori<br />
Hitachi Ltd., Japan<br />
Wed-Af-Po3.03-02 [28]<br />
Characteristics of an HTS dipole magnet<br />
Kento Suzuki, Toru Ogitsu, Yusuke Ishii, et al.<br />
High Energy Accelerator Research Organ., KEK, Japan<br />
Wed-Af-Po3.03-03 [29]<br />
Design and analysis of a coaxial-flux superconducting<br />
magnetic gear using superconducting bulk in halbach<br />
array<br />
Kun Dong<br />
Southeast University, China<br />
Wed-Af-Po3.03-04 [30]<br />
Stress-Strain Analysis in a 10 T non-Insulated GdBCO<br />
HTS Coil for the 25 T All-superconducting NMR Magnet<br />
Lei Wang, Qiuliang Wang, Lankai Li and Jianhua Liu<br />
Institute of Electrical Engineering, CAS, China<br />
Wed-Af-Po3.03-05 [31]<br />
Tests in Standalone Mode of the EuCARD 5.4-T REBCO<br />
Dipole Magnet.<br />
Maria Durante, Franck Borgnolutti, et al.<br />
CEA, France<br />
Wed-Af-Po3.03-06 [32]<br />
Racetrack-shaped large single pancake coils wound with<br />
1 km-long REBCO-coated conductors<br />
Sadanori Iwai, Hiroshi Miyazaki and Taizo Tosaka<br />
Toshiba Corporation, Japan<br />
Wed-Af-Po3.03-07 [33]<br />
A Method for Designing an HTS Magnet Processes High-<br />
Performance and High Thermal Stability<br />
Tao Wang, Atsushi Ishiyama, Xudong Wang, et al.<br />
Waseda University, Tokyo, Japan<br />
Wed<br />
123
Wed<br />
Wed-Af-Po3.03-08 [34]<br />
Conceptual Design of a Superconducting Magnet<br />
Stacked by REBCO Annulus Plates<br />
Xi Yuan<br />
North China Electric Power University, China<br />
Wed-Af-Po3.03-09 [35]<br />
Stability simulation of a new ring-shaped YBCO coated<br />
conductor sheets magnet<br />
Ying Min Cui and Yin Shun Wang<br />
North China Electric Power University, China<br />
Wed-Af-Po3.03-10 [36]<br />
A Compact Test Bed for Critical Current Evaluation on<br />
High Temperature Superconducting Tape Samples<br />
Yinming Dai, Hui Wang, Jianhua Liu, Jinshui Sun, et al.<br />
Institute of Electrical Engineering, CAS, China<br />
Poster Session 3.04 13:15 - 15:00 Posters Area<br />
Hadron Therapy Magnets and Novel Medical and<br />
Biological Applications<br />
Wed-Af-Po3.04-01 [37]<br />
Design considerations of gantry beamline with fast energy<br />
modulation for HUST Proton Therapy Facility<br />
Bin Qin, Kaifeng Liu, Jun Yang, Wei Chen, Xu Liu, et al.<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.04-02 [38]<br />
DESIGN STUDY OF AN OCTUPOLE SCANNING MAGNET<br />
FOR SPOT SCANNING IN PROTON THERAPY<br />
Bolei Jia and Lianhua Ouyang<br />
Shanghai Institute of Applied Physics, CAS, China<br />
Wed-Af-Po3.04-03 [39]<br />
Superconducting Coil system R&D for a 230 MeV Superconducting<br />
Cyclotron<br />
Chuan Wang, Tianjue Zhang, Meng Yin, et al.<br />
China Institute of Atomic Energy, China<br />
Wed-Af-Po3.04-04 [40]<br />
Cold Tests and Magnetic Characterization of a Superconducting<br />
Magnet for a Compact Cyclotron for Radioisotope<br />
Production<br />
Javier Munilla, Pablo Abramian, et al.<br />
CIEMAT, Spain<br />
124
Wed-Af-Po3.04-05 [41]<br />
Cryostat Design of 230 MeV Superconducting Isochronous<br />
Cyclotron for Proton Therapy<br />
Jun Yoshida, Atsushi Hashimoto, Takaaki Morie, et al.<br />
Sumitomo Heavy Industries, Ltd., Japan<br />
Wed-Af-Po3.04-06 [42]<br />
The Design and Manufacture of the 90 degree bending<br />
Magnets for Proton Beam Therapy<br />
Liu Zhihong and Wu Jiefeng<br />
Institute for Plasma Physics, CAS, China<br />
Wed-Af-Po3.04-07 [43]<br />
Stress Analysis of Canted–Cosine–Theta Superconducting<br />
Dipoles Coils During Winding , Cooling and Charging<br />
for Rotating Gantry<br />
Luncai Zhou, Rongzhen Zhao, Tongjun Yang, Wei Wu, et al.<br />
Institute of Modern Physics, CAS, China<br />
Wed-Af-Po3.04-08 [44]<br />
Analysis of losses in superconducting magnets based<br />
on the Nb3Sn Rutherford cable configuration for future<br />
gantries<br />
Marco Breschi, Pier Luigi Ribani, et al.<br />
University of Bologna, Italy<br />
Wed-Af-Po3.04-09 [45]<br />
Development of highly saturated dipole magnets for the<br />
SAPT booster<br />
Miao Zhang, Qiaogen Zhou, Rui Li and Deming Li<br />
Shanghai Institute of Applied Physics, CAS, China<br />
Wed-Af-Po3.04-10 [46]<br />
Modified Halbach Magnets in Medical Science Applications<br />
Nicholaos Tsoupas, Dejan Trbojevic, et al.<br />
Brookhaven National Laboratory, BNL, USA<br />
Wed-Af-Po3.04-11 [47]<br />
Design and analysis of a time-varying magnetic field<br />
generator for manipulating magnetic particles<br />
Shaozhe Zhang, Quanliang Cao, Zhen Wang, et al.<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.04-12 [48]<br />
Design Study on High Frequency Magnets for Magnetic<br />
Hyperthermia Applications<br />
Shinichi Nomura and Takanori Isobe<br />
Meiji University, Japan<br />
Wed<br />
125
Wed<br />
Wed-Af-Po3.04-13 [49]<br />
Design and construction of the main magnet for a 230<br />
MeV Superconducting Cyclotron<br />
Tianjue Zhang, Chuan Wang, Tao Cui, Ming Li, et al.<br />
China Institute of Atomic Energy, China<br />
Wed-Af-Po3.04-14 [50]<br />
Design of prototype magnets for HUST Proton Therapy<br />
beamline<br />
Wei Chen, Xiaoyu Fang, Zhikai Liang, Xu Liu, et al.<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.04-15 [51]<br />
Improved Overall Efficacy in Transcranial Magnetic Stimulation<br />
of Human Brain with Semi - ellipse Coil Pair<br />
Xiao Fang, Hongfa Ding, Jun Zhou, Qingjian Wang, et al.<br />
Huazhong University of Science and Technology, China<br />
Poster Session 3.05 13:15 - 15:00 Posters Area<br />
Motors - III<br />
Wed-Af-Po3.05-01 [52]<br />
Animproved rotating HF signal injection method for<br />
PMSM sensorless control<br />
Bo Xu, Guoding Shi, Jian Xu and Wei Ji<br />
Jiangsu University, China<br />
Wed-Af-Po3.05-02 [53]<br />
Integrated Motor Propulsor Magnet Design with Hybrid<br />
Halbach Array for Torque Ripple Reduction<br />
Ji-hun Ahn, Jang_young Choi, Cheol Han, et al.<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.05-03 [54]<br />
Design criteria for high-speed permanent magnet synchronous<br />
motors considering rotor magnet and sleeve<br />
material<br />
Ji-hun Ahn, Jang-young Choi, Chang-woo Kim, et al.<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.05-04 [55]<br />
Novel U-shaped Structure Switched Reluctance Machine<br />
With a Module Outer Rotor<br />
Hao Chen and Wenju Yan<br />
China University of Mining & Technology, China<br />
Wed-Af-Po3.05-05 [56]<br />
Flux Characteristics Analysis of Single-phase Tubular<br />
Permanent Magnet Linear Motor<br />
Hao Chen and Zhixiong Li<br />
China University of Mining & Technology, China<br />
126
Wed-Af-Po3.05-06 [57]<br />
Influence Analysis according to Shape Changes of Magnetic<br />
Salient Pole Structure on Performance Characteristics<br />
of Megawatt-Class HTS Wound Rotor Synchronous<br />
Motor<br />
Chang Ju Hyeon, Ho Min Kim, Huu Luong Quach, et al.<br />
Jeju National University, Korea<br />
Wed-Af-Po3.05-07 [58]<br />
A Three-Phase 27-Slot 8-Pole Interior Permanent-Magnet<br />
Machine with Low Space Harmonics for Hybrid Electric<br />
Vehicle<br />
Junqiang Zheng, Wenxiang Zhao and Jinghua Ji<br />
Jiangsu University, China<br />
Wed-Af-Po3.05-08 [59]<br />
Study on the torque ripple reduction design through varying<br />
the air-gap magnetic flux density in the SPM motor<br />
Kidoek Lee, Sehyun Rhyu and Jeongjong Lee<br />
Korea Electronics Technology Institute, Korea<br />
Wed-Af-Po3.05-09 [60]<br />
A Study on a New Structure Ferrite Magnet Motor with<br />
Improved Output Density and Mechanical Stability<br />
Kidoek Lee, Sehyun Rhyu and Jeongjong Lee<br />
Korea Electronics Technology Institute, Korea<br />
Wed-Af-Po3.05-10 [61]<br />
Analytical Investigation of the On-load Electromagnetic<br />
Performance of Magnetic-Geared Permanent-Magnet Machines<br />
Kyung-Hun Shin, Han-Wook Cho and Jang-Young Choi<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.05-12 [63]<br />
Superconducting synchronous motor With HTS stacked<br />
tape armature<br />
Mehdi Baghdadi and Timothy A. Coombs<br />
University of Greenwich, United Kingdom<br />
Wed-Af-Po3.05-13 [64]<br />
Minimization of Torque Ripple in Ferrite-Assisted Synchronous<br />
Reluctance Motors by Using Asymmetric Rotor<br />
Poles<br />
Meimei Xu and Guohai Liu<br />
Jiangsu University, China<br />
Wed<br />
127
Wed<br />
Wed-Af-Po3.05-14 [65]<br />
Torque Ripple Improvement for Ferrite-Assisted Synchronous<br />
Reluctance Motors by Using Asymmetric Fluxbarrier<br />
Arrangement<br />
Meimei Xu<br />
Jiangsu University, China<br />
Wed-Af-Po3.05-15 [66]<br />
Research on the thermal characteristics of permanent<br />
magnet linear motor operated in short-time duty cycle<br />
Xiaomei Liu, Haitao Yu, Zhenchuan Shi, Rong Guo, et al.<br />
School of Electrical Engineering,Southeast University, China<br />
Wed-Af-Po3.05-16 [67]<br />
Design of the high power density permanent magnet<br />
synchronous linear motor with water cooling structure in<br />
the end windings<br />
Xiaomei Liu, Haitao Yu, Zhenchuan Shi, Rong Guo, et al.<br />
Southeast University, China<br />
Wed-Af-Po3.05-17 [68]<br />
Magnetic Flux Estimation for Interior Permanent Magnet<br />
Synchronous Motor by using MRAC<br />
Hanwoong Ahn, Sooyoung Cho and Ju Lee<br />
Korea Aerospace Research Institute, Korea<br />
Wed-Af-Po3.05-18 [69]<br />
Analysis of magnetic flux density waveform distortion in<br />
sensor magnet for rotor position detection<br />
Se-young Oh, Sooyoung Cho, Gang Seok Lee and Ju Lee<br />
LG Innotek, Korea<br />
Wed-Af-Po3.05-19 [70]<br />
A Superconducting Vernier Motor for Electric Ship Propulsion<br />
Wenlong Li, T. W. Ching, K.T. Chau, et al.<br />
University of Hong Kong, Hong Kong<br />
Wed-Af-Po3.05-20 [71]<br />
Design and analysis of an interior permanent magnet<br />
synchronous machine with multi flux barriers based on<br />
electromagnetic-mechanical coupling method<br />
Wenye Wu, Xiaoyong Zhu, Li Quan and Yi Du<br />
Jiangsu University, China<br />
Wed-Af-Po3.05-21 [72]<br />
Design and analysis of a less-rare-earth PM-assisted<br />
synchronous reluctance machine considering tradeoffs<br />
of PM flux linkage and magnetic saliency<br />
Wenye Wu, Xiaoyong Zhu and Yi Du<br />
Jiangsu University, China<br />
128
Wed-Af-Po3.05-22 [73]<br />
Numerical Analysis of Variable Flux Memory Motor Considering<br />
Characteristics of Permanent Magent Load-Line<br />
Wonseok Han, Sang-Yong Jung, Yong-Jae Kim, et al.<br />
Sungkyunkwan University, Korea<br />
Wed-Af-Po3.05-23 [74]<br />
A Novel Dual-Rotor Flux-Modulation Permanent-Magnet<br />
Machine With Yokeless Stator for Hybrid Electric Vehicles<br />
Xuhui Zhu, Wenxiang Zhao and Jian Zhu<br />
Jiangsu University, China<br />
Wed-Af-Po3.05-24 [75]<br />
Double-Stator Permanent-Magnet Vernier Linear Machine<br />
With PMs Surface-Mounted on the Mover<br />
Jian Zhu, Wenxiang Zhao and Xuhui Zhu<br />
School of Electr. and Inform. Eng., Jiangsu University, China<br />
Wed-Af-Po3.05-25 [76]<br />
Electromagnetic Performance Analysis of Less-rareearth<br />
Stator-partitioned Multi-excitation Flux-switching<br />
Machine Considering Multi-operation Conditions<br />
Yunyun Chen and Xiaoyong Zhu<br />
Jiangsu University, China<br />
Poster Session 3.06 13:15 - 15:00 Posters Area<br />
Generators<br />
Wed<br />
Wed-Af-Po3.06-01 [77]<br />
A performance study on the flux pump based modularized<br />
exciter for a large-scale HTS wind power generator<br />
Byeong-Soo Go, Hae-Jin Sung, Hyun-Kyung Shin, et al.<br />
Changwon National University, Korea<br />
Wed-Af-Po3.06-02 [78]<br />
Obtaining of Inductance with Dependence on Rotor Position<br />
via Measurements, and Modeling of Inductance using<br />
Analytical and Fast Fourier transforms approaches<br />
for Lumped Parameter Model Applications<br />
Dmytro Bilyi<br />
FEAAM GmbH, Neubiberg, Germany<br />
Wed-Af-Po3.06-03 [79]<br />
Research on MgB2 armature windings in fully superconducting<br />
AC machine<br />
Feng Lin, Dawei Li and Ronghai Qu<br />
Huazhong University of Science and Technology, China<br />
129
Wed<br />
Wed-Af-Po3.06-04 [80]<br />
Study on fault-tolerant control of open-winding brushless<br />
doubly-fed wind power generator<br />
Shi Jin, Guangwei Liu, Long Shi and Liancheng Zhu<br />
Shenyang University of Technology, China<br />
Wed-Af-Po3.06-05 [81]<br />
Rotor Structure Design and Optimization of MW-class<br />
Brushless Doubly Fed Generator for Offshore Wind Turbine<br />
Hao Wang, Guangwei Liu, Fengge Zhang, Siyang Yu, et al.<br />
Shenyang University of Technology, China<br />
Wed-Af-Po3.06-06 [82]<br />
Design and Operation Performance Research of Brushless<br />
Doubly-Fed Generator with Cage Bar Assisted Reluctance<br />
Rotor<br />
Siyang Yu, Fengge Zhang, Yutao Wang, Shi Jin, et al.<br />
Shenyang University of Technology, China<br />
Wed-Af-Po3.06-07 [83]<br />
Design and Magnet Field Analysis of Slotless Linear<br />
Generator for Wave Energy Conversion<br />
Jing Zhang, Haitao Yu, Lei Huang and Rong Guo<br />
Jinling Institute of Technology, Nanjing, China<br />
Wed-Af-Po3.06-08 [84]<br />
Influence of Rotor Structure on End Effects of High-<br />
Speed Permanent Magnet Synchronous Generators Using<br />
3D Finite Element Analysis<br />
Kyung-hun Shin, Jang-Young Choi and Han-Wook Cho<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.06-09 [85]<br />
Analytical Modeling and Experimental Verification for<br />
Electromagnetic Analysis of Permanent Magnet Linear<br />
Synchronous Machines with Horizontally Magnetized Permanent<br />
Magnets accounting for Flux-Passing Iron Pole<br />
Kyung-hun Shin, Jang-Young Choi, Han-Wook Cho, et al.<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.06-10 [86]<br />
Study on a Novel Transverse-flux Tubular Linear Permanent-magnet<br />
Generator for Stirling Engine<br />
Weibo Zhong, Haitao Yu, Minqiang Hu, et al.<br />
School of Electrical Engineering, Southeast University, China<br />
Wed-Af-Po3.06-11 [87]<br />
AC loss analysis of the armature windings of a fully HTS<br />
rotating machine with dual field windings<br />
Woo-seok Kim, Sang Ho Park, Seyeon Lee, et al.<br />
Korea Polytechnic University, Korea<br />
130
Wed-Af-Po3.06-12 [88]<br />
Characteristic Analysis for the Influence of Auxiliary<br />
Teeth and Notching on the Reduction of the Detent<br />
Force of a Permanent Magnet Linear Synchronous Generator<br />
Sung-won Seo, Jang-young Choi, Min-mo Koo, et al.<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.06-13 [89]<br />
Characteristic Analysis and Experimental Verification for<br />
a Double-sided Permanent Magnet Linear Synchronous<br />
Generator According to Magnetization Array<br />
Sung-Won Seo, Jang-Young Choi, Gang-Hyeon Jang, et al.<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.06-14 [90]<br />
Moduling Axial-flux Compensated Pulsed Alternator<br />
Caiyong Ye, Jiangtao Yang and Xin Liang<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.06-15 [91]<br />
Study on the no-insulation ReBCO pancake coils for superconducting<br />
synchronous machines<br />
Yali Zheng<br />
Luoyang Normal University, China<br />
Poster Session 3.07 13:15 - 15:00 Posters Area<br />
Levitation, Bearing and Separation<br />
Wed<br />
Wed-Af-Po3.07-01 [92]<br />
Design of hybrid thrust magnetic bearing for heavy rotating<br />
shaft considering self-weight compensation according<br />
to axial load<br />
Ji-Hun Ahn, Jang-Young Choi, Cheol Han, et al.<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.07-02 [93]<br />
Detailed analysis of conduction-cooled MgB2 for use in<br />
superconducting magnetic density separation<br />
Marc Dhallé, Chao Zhou, Dorus Dijkstra, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Wed-Af-Po3.07-03 [94]<br />
The Number of Magnet Poles Decision Method of Magnetic<br />
Gear for Torque Ripple Reduction<br />
Eui-jong Park, Sang-Yong Jung, Sung-Jin Kim, et al.<br />
Chosun University, Korea<br />
131
Wed<br />
Wed-Af-Po3.07-04 [95]<br />
A Design of Outer Yoke and Enclosure Considering Magnet<br />
Eddy Current Loss of Magnetic Gear<br />
Eui-Jong Park, Sung-Jin Kim, Sang-Yong Jung, et al.<br />
Chosun Universtiy, Korea<br />
Wed-Af-Po3.07-05 [96]<br />
Quality and Stability Improvement of DC Power Systems<br />
in All Electric Ship Using SMES/Battery<br />
Hamoud Alafnan, Mariam Elshiekh, Jianwei Li, et al.<br />
University of Bath, Bath, United Kingdom<br />
Wed-Af-Po3.07-06 [97]<br />
A Superconducting Magnetic Density Separation Laboratory<br />
Demonstrator<br />
Jaap Kosse, Herman ten Kate, Marc Dhallé, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Wed-Af-Po3.07-07 [98]<br />
Test of the SMES working as a Power Buffer in a Multiple<br />
DC Distribution Power Network by Using the Real Time<br />
Digital Simulator<br />
Jianwei Li, Weijia Yuan and Min Zhang<br />
University of Bath, Bath, United Kingdom<br />
Wed-Af-Po3.07-08 [99]<br />
A quantitative benefits study of the superconducting<br />
magnetic energy storage system hybridized with the battery<br />
Jianwei Li and Weijia Yuan<br />
University of Bath, Bath, United Kingdom<br />
Wed-Af-Po3.07-09 [100]<br />
Force Calculation and Thermal Analysis of the Maglev<br />
Machine for the 1000 MW Hydraulic Generator Set<br />
Jing Liu, Hongzhong Ma and Lei Huang<br />
China University of Petroleum (Hua Dong), China<br />
Wed-Af-Po3.07-10 [101]<br />
High-gradient magnetic separation properties of rice hull<br />
magnetic activated carbon for water clarification<br />
Keisuke Ishida, Tatsuki Anzai and Osuke Miura<br />
Tokyo Metropolitan University, Japan<br />
Wed-Af-Po3.07-11 [102]<br />
Air-gap Control for Superconducting-Hybrid Magnetic<br />
Levitation Systems via Linear Matrix Inequality Optimization<br />
Chang-Hyun Kim, Kyoung-Jin Joo and Ju Lee<br />
Dep. of Electricity, Vision College of Jeonju, Korea<br />
132
Wed-Af-Po3.07-12 [103]<br />
Levitation separation of precious metals utilizing magneto-Archimedes<br />
effect in high gradient magnetic fields<br />
Osuke Miura<br />
Tokyo Metropolitan University, Japan<br />
Wed-Af-Po3.07-13 [104]<br />
Direct simulation of interactive motion of magnetic particles<br />
in an oscillating magnetic field<br />
Quanliang Cao, Zhenhao Li, Xiaotao Han, et al.<br />
Huazhong University of Science & Technology, China<br />
Wed-Af-Po3.07-14 [105]<br />
Energy-Shaping Control Strategy of SMES<br />
Xiaodong Lin and Yong Lei<br />
Sichuan University, China<br />
Wed-Af-Po3.07-15 [106]<br />
Analysis and Control of a Multi-Phase Bearingless Permanent<br />
Magnet Synchronous Motor<br />
Huangqiu Zhu and Yuemei Qin<br />
Jiangsu University, China<br />
Wed-Af-Po3.07-16 [107]<br />
Experimental and numerical investigations on the separation<br />
behavior of magnetic particles under an alternating<br />
gradient magnetic field<br />
Zhen Wang, Xiaotao Han, Quanliang Cao, et al.<br />
Huazhong University of Science & Technology, China<br />
Wed<br />
Poster Session 3.08 13:15 - 15:00 Posters Area<br />
Novel Applications<br />
Wed-Af-Po3.08-01 [108]<br />
A Wide Aperture Superconducting Vector Magnet for<br />
photon beamlines: WAVE Photons<br />
Arnaud Madur, Nicolas Jaouen, et al.<br />
CEA Saclay, France<br />
Wed-Af-Po3.08-02 [109]<br />
Design and structural analysis of induction type coilgun<br />
system<br />
Byeong-Soo Go, Myung-Geun Song, Dinh-Vuong Le, et al.<br />
Changwon National University, Korea<br />
Wed-Af-Po3.08-03 [110]<br />
Simulation of Thomson Parabola spectrometer for<br />
charged particle diagnostics in the PETAL+ project<br />
Chhon Pes, Jean-Eric Ducret, Bernard Gastineau, et al.<br />
CEA Saclay, Gif-sur-Yvette, France<br />
133
Wed<br />
Wed-Af-Po3.08-04 [111]<br />
Capability improvement design method considering<br />
eddy current loss reduction of axial-flux permanent magnet<br />
coupling with Halbach array structure using 3-D<br />
FEM.<br />
Jang-Young Choi, Gang-Hyeon Jang, Sung-Won Seo, et al.<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.08-05 [112]<br />
Design and Experimental Verification of Punching Using<br />
a Pulsed Electromagnetic Force<br />
Hang Zhang, Ning Liu, Qingjian Wang, et al.<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.08-06 [113]<br />
Embedded flexible Fe-Si-Al powder composite-film inductor<br />
for a Low Power DC-DC Converters<br />
Jae-woo Lim, Hee-jun Kim, Yong-seung Oh, et al.<br />
Dept. of Electr. Systems Eng., Hanyang University, China<br />
Wed-Af-Po3.08-07 [114]<br />
Analysis of Torque Characteristics according to Gear ratio<br />
of Coaxial Magnetic Gear<br />
Jeong-In Lee, Jang_Young Choi, Tae-Kyoung Bang, et al.<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.08-08 [115]<br />
Development of three stage electromagnetic forming facility<br />
and its timing control system<br />
Jianfeng Xie, Liang Li, Qunliang Cao, et al.<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.08-09 [116]<br />
Study on Electromagnetic Force Distribution and Copper<br />
Fatigue Performance in Electromagnetic Strengthening<br />
with Axial Compression<br />
Li Qiu, Yijie Yu and Liang Li<br />
-<br />
Wed-Af-Po3.08-10 [117]<br />
Electromagnetic Deep Drawing of Aluminum Cylindrical<br />
Cup with High Depth-diameter Ratio<br />
Meng Chen, Quanliang Cao, Zhipeng Lai, Hong Cai, et al.<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.08-11 [118]<br />
Influence of Operating Parameters on Discharge Characteristics<br />
of Superconducting High Field Magnetron<br />
Tianlong Wang, Qingquan Qiu, Fei Qu, Liwei Jing, et al.<br />
Institute of Electrical Engineering, CAS, China<br />
134
Wed-Af-Po3.08-12 [119]<br />
Design, fabrication, and test of a dual-coil system for<br />
electromagnetic sheet forming<br />
Ning Liu, Zhipeng Lai, Quanliang Cao, et al.<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.08-13 [120]<br />
Realization and commissioning of WAVE Neutrons a<br />
Wide Aperture Vector Magnet for Neutron scattering experiments<br />
delivered Turn Key<br />
Raphael Pasquet, Alexandre Bataille, et al.<br />
Sigmaphi, France<br />
Wed-Af-Po3.08-14 [121]<br />
A Study on the Power Converter Performance Comparison<br />
& Optimal design induction heating coil for IH jar<br />
Hee-jun Kim, Sang-taek Lee and Yong-seung Oh<br />
Hanyang University, Korea<br />
Wed-Af-Po3.08-15 [122]<br />
Analysis of deep drawing of stainlesss steel sheet using<br />
electromagnetic forming with a driver sheet<br />
Shoufeng Xu, Quanliang Cao, Xiaotao Han, et al.<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.08-16 [123]<br />
Measurement and Torque Calculation of Magnetic Spur<br />
Gear Based on Quasi 3-D Analytical Method<br />
Tae-Kyoung Bang, Jang-Young Choi, et al.<br />
Chungnam National University, Korea<br />
Wed-Af-Po3.08-17 [124]<br />
Development of Conduction-cooled Superconducting<br />
Split Coil for Metal Melting by DC Induction Heating<br />
Tomonori Watanabe, Shigeo Nagaya, Naoki Hirano, et al.<br />
Chubu Electric Power Co., Inc., Japan<br />
Wed-Af-Po3.08-18 [125]<br />
Study on Magnetic Field of Stacked Permanent Magnets<br />
in Magnetic Liquid Inclination Sensor<br />
Wenrong Yang, Xiaorui Yang, Lifei Chen and Bing Guo<br />
Hebei University of Technology, China<br />
Wed-Af-Po3.08-19 [126]<br />
Flow Analysis of Magnetic Fluid around a Permanent<br />
Magnet in Magnetic Fluid Damper<br />
Xiaorui Yang, Qingxin Yang, Wenrong Yang, et al.<br />
Hebei University of Technology, China<br />
Wed<br />
135
Wed<br />
Wed-Af-Po3.08-20 [127]<br />
Analysis and Optimization of Adjustable Magnetic Fluid<br />
Damper in DC Magnetic Field<br />
Xiaorui Yang, Qingxin Yang, Wenrong Yang, et al.<br />
Hebei University of Technology, China<br />
Wed-Af-Po3.08-21 [128]<br />
Vibration of Magnetically Controlled Saturated Reactor<br />
under AC and DC excitation<br />
Yan Rongge<br />
Hebei University of Technology, China<br />
Wed-Af-Po3.08-22 [129]<br />
Applied solenoid coils effects on the ignition experiments<br />
of an MPD thruster<br />
Yibai Wang and Haibin Tang<br />
Beihang University, China<br />
Wed-Af-Po3.08-23 [130]<br />
Design and implementation of a flexible pulsed electromagnetic<br />
blankholder system for electromagnetic forming<br />
Yujie Huang, Xiaotao Han, Quanliang Cao, et al.<br />
Huazhong University of Science and Technology, China<br />
Poster Session 3.09 13:15 - 15:00 Posters Area<br />
BSCCO, MgB2 and New HTS Wires and Cables<br />
Wed-Af-Po3.09-01 [131]<br />
A method of critical current measurement for HTS tape<br />
using pulsed current<br />
A-Rong Kim, Zhong-Soo Lim, Taewon Kim, et al.<br />
Research Inst. of industry. Sci.&Techn. (RIST), Korea<br />
Wed-Af-Po3.09-02 [132]<br />
Strong, round and rectangular HTS wires based on the<br />
Bi2212 superconductor<br />
Alexander Otto<br />
Solid Material Solutions, LLC, MA, USA<br />
Wed-Af-Po3.09-03 [133]<br />
The impact of conductor Jacket material to the performance<br />
of Bi-2212 round wire<br />
Chao Dai and Jinggang Qin<br />
ASIPP, Institute of Plasma Physics, CAS, China<br />
Wed-Af-Po3.09-04 [134]<br />
Uniaxial Strain Induced Critical Current Degradation of<br />
Ag-Sheathed Bi-2212 Round Wire<br />
Chao Dai and Jinggang Qin<br />
ASIPP, Institute of Plasma Physics, CAS, China<br />
136
Wed-Af-Po3.09-05 [135]<br />
Influence of Nd, Dy and Er substitution on the structural<br />
and superconducting properties of the<br />
RuSr2GdCu2O8±Z<br />
Mohamed Abatal, Hussain Alazki, et al.<br />
Universidad Autonoma del Carmen, Campeche, Mexico<br />
Wed-Af-Po3.09-06 [136]<br />
Heat treatment of MgB2 superconductors with different<br />
metal sheaths<br />
Ildar Abdyukhanov, Anastasia Tsapleva, et al.<br />
VNIINM, Bochvar Institute, Russia<br />
Wed-Af-Po3.09-07 [137]<br />
Measurement campaign on critical current for MgB2<br />
wires and tapes under a magnetic field up to 8T<br />
Julien Avronsart, Christophe Paul Berriaud, et al.<br />
CEA, France<br />
Wed-Af-Po3.09-08 [138]<br />
AC loss distribution in two-layer HTS twisted cable<br />
Jun Ogawa, Satoshi Fukui, Tetsuo Oka, et al.<br />
Niigata University, Japan<br />
Wed-Af-Po3.09-09 [139]<br />
Hysteresis modeling of MgB2 using simplified Jiles-Atheron<br />
model<br />
Kun Dong<br />
Ohio State University, USA<br />
Wed-Af-Po3.09-10 [140]<br />
Current Distribution Calculation of Superconducting<br />
Layer in HTS Cable Considering Magnetic Hysteresis by<br />
Using XFEM<br />
Nana Duan, Weijie Xu, Shuhong Wang, Y. Guo, et al.<br />
Xi'an Jiaotong University, China<br />
Wed-Af-Po3.09-11 [141]<br />
Twist Pitch Length Calculation for the HTS Cable Application<br />
Using Genetic Algorithm<br />
Seunghyun Song, Woo Seung Lee, Kideok Sim, et al.<br />
Yonsei University, Korea<br />
Wed-Af-Po3.09-12 [142]<br />
Progresses in Mg11B2 intermediate superconductors initiatives<br />
in India<br />
Subrata Pradhan<br />
Institute for Plasma Research, India<br />
Wed<br />
137
Wed<br />
Wed-Af-Po3.09-13 [143]<br />
Toward using artificial neural network to predict the outcomes<br />
of PMP heat treatments in Bi-2212 wires<br />
Shijian Yin, Wan Kan Chan and Justin Schwartz<br />
North Carolina State University, Raleigh, USA<br />
Wed-Af-Po3.09-14 [144]<br />
Fabrication of grain aligned Bi2223 thick films with high<br />
critical current properties<br />
Yasuaki Takeda, Ryo Koike, Takanori Motoki, et al.<br />
University of Tokyo, Japan<br />
Wed-Af-Po3.09-15 [145]<br />
Strong flux pinning caused by phase distribution characteristics<br />
in (Ba, K)Fe2As2 films<br />
Younjung Jo and Oh Myeongjun<br />
Kyungpook National University, Korea<br />
Wed-Af-Po3.09-16 [146]<br />
Axial tensile stress-strain characterization of Bi2212<br />
round wire with different heat treatment<br />
Zhehua Mao and Jinggang Qin<br />
ASIPP, Institute of Plasma Physics, CAS, China<br />
Poster Session 3.10 13:15 - 15:00 Posters Area<br />
Structural Materials, Electrical Insulation and other<br />
Magnet Components<br />
Wed-Af-Po3.10-01 [147]<br />
Hot cracking in laser welding with filler wire of ITER<br />
grade austenitic stainless steel<br />
Chao Fang, Jijun Xin, Jing Wei, Yuntao Song, et al.<br />
Institute of Plasma Physics, CAS, China<br />
Wed-Af-Po3.10-02 [148]<br />
Research and Analysis on Impulse Discharge of EAST<br />
Cryogenic Axial Insulation Breaks<br />
Cheng Wu, Wanjiang Pan, Yi Cao and Huang Chen<br />
Institute of Plasma Physics, CAS, China<br />
Wed-Af-Po3.10-03 [149]<br />
Thermomechanical behavior of the HL-LHC 11 tesla<br />
Nb3Sn magnet coil constituents during reaction heat<br />
treatment<br />
Christian Scheuerlein, Friedrich Lackner, et al.<br />
CERN, Geneva, Switzerland<br />
138
Wed-Af-Po3.10-04 [150]<br />
Structural optimization methodology of the 2-D inner-leg<br />
cross-section for the Toroidal Field Coils of fusion reactors<br />
Giordano Tomassetti, Lorenzo Giannini, et al.<br />
ENEA, Italy<br />
Wed-Af-Po3.10-05 [151]<br />
A Study on the V-t Characteristics of PPLP according to<br />
Electric Field Uniformity for a Superconducting Transformer<br />
Hyoungku Kang, Hongseok Lee and Onyou Lee<br />
Korea National University of Transportation, Korea<br />
Wed-Af-Po3.10-06 [152]<br />
Mechanical properties of aged 316LN butt-welding joint<br />
at cryogenic temperature for CFETR CS model coil<br />
Huan Jin, Yu Wu, Jingang Qin, Guojun Liao, et al.<br />
ASIPP, Institute of Plasma Physics, CAS, China<br />
Wed-Af-Po3.10-07 [153]<br />
Mechanical properties of ITER CICC jacket in China<br />
Jinggang Qin<br />
ASIPP, Institute of Plasma Physics, CAS, China<br />
Wed-Af-Po3.10-08 [154]<br />
Critical Current Properties of Precisely Cation Composition<br />
Controlled RE123 Melt-Solidified Bulks<br />
Jun-ichi Shimoyama, Takumi Sato, et al.<br />
Aoyama Gakuin University, Japan<br />
Wed-Af-Po3.10-09 [155]<br />
Particle Reinforced Cu Matrix Conductors for High Field<br />
Pulsed Magnets<br />
Ke Han, Robert Goddard, Vince Toplosky, et al.<br />
National High Magnetic Field Laboratory, Tallahassee, USA<br />
Wed-Af-Po3.10-10 [156]<br />
Upper critical and irreversibility magnetic fields and<br />
transport properties of bulk K-, Ni-, and Co-doped<br />
BaFe2As2 pnictides for different granularities and their<br />
prospects in magnet design<br />
Martin Nikolo, John Singleton, Jyanyi Jiang, et al.<br />
Saint Louis University, USA<br />
Wed-Af-Po3.10-11 [157]<br />
Size effect on the strength of Cu-Ag microcomposites by<br />
accumulative drawing and bundling process<br />
Ming Liang, Pengfei Wang, Xiaoyan Xu, Tao Peng, et al.<br />
Northwest Institute for Non-ferrous Metal Research, China<br />
Wed<br />
139
Wed<br />
Wed-Af-Po3.10-12 [158]<br />
Creepage Discharge Characteristics of a Solid Insulation<br />
Material for Superconducting Applications<br />
Hyoungku Kang, Onyou Lee and Hongseok Lee<br />
Korea National University of Transportation, Korea<br />
Wed-Af-Po3.10-13 [159]<br />
Zylon aging and light resistance<br />
Rongmei Niu and Ke Han<br />
National High Magnetic Field Laboratory, Tallahassee, USA<br />
Wed-Af-Po3.10-14 [160]<br />
Superconducting properties of YBaCuO bulk ceramics<br />
using melt process<br />
Sang Heon Lee<br />
Dep. of Electronic Eng., Sunmoon University, Korea<br />
Wed-Af-Po3.10-15 [161]<br />
Assessment of electrical insulation of a superconducting<br />
magnet winding pack under severe loading conditions<br />
Selanna Roccella, Gian Mario Polli, et al.<br />
ENEA FSN, Italy<br />
Wed-Af-Po3.10-16 [162]<br />
Investigation of Materials and Welds for the Precompression<br />
Structure of the ITER Central Solenoid<br />
Stefano Sgobba, Ignacio aviles Santillana, et al.<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Po3.10-17 [163]<br />
Friction-coefficient between the Ti6Al4V loading pole<br />
and the 316LN steel shims of the HL-LHC 11 T magnets<br />
Thomas Gradt, Christian Scheuerlein, et al.<br />
Federal Lab. for Materials Research (BAM), Switzerland<br />
Wed-Af-Po3.10-18 [164]<br />
Progress of ITER Feeder System Electrical Insulation<br />
Qualification<br />
Nicholas Clayton, Xiongyi Huang, Arnaud Devred, et al.<br />
ASIPP, Institute of Plasma Physics, CAS, China<br />
Wed-Af-Po3.10-19 [165]<br />
Cryogenic Hybrid Magnet with Praseodymium Permanent<br />
Magnet<br />
Yasuhiro Fuwa, Yoshihisa Iwashita, et al.<br />
Kyoto University, Japan<br />
140
Poster Session 3.11 13:15 - 15:00 Posters Area<br />
Stability<br />
Wed-Af-Po3.11-01 [166]<br />
Thermal Quench Characteristics of 2G HTS Race Track<br />
Field Coil with Kapton Polyimide Insulation and Smart<br />
Insulation Materials<br />
Ho Min Kim, Chang Ju Hyeon, Huu Luong Quach, et al.<br />
Jeju National University, Korea<br />
Wed-Af-Po3.11-02 [167]<br />
Mechanical Structure for the PSI Canted-Cosine-Theta<br />
(CCT) Magnet Program<br />
Ciro Calzolaio, Bernhard Auchmann, et al.<br />
Paul Scherrer Institute, Villigen, Switzerland<br />
Wed-Af-Po3.11-03 [168]<br />
A Study on Thermal and Electrical Stabilities of GdBCO<br />
Coils Impregnated with Epoxy Composites Using Surface-Treated<br />
Carbon Nanotube Fillers<br />
Hyun Hee Son, Haigun Lee, Jong Cheol Kim, et al.<br />
Dep. of Materials Sci.&Eng., Korea University, Korea<br />
Wed-Af-Po3.11-04 [169]<br />
2G HTS Magnet Stability Improvement via V2O3 Material<br />
and perforated HTS Wire<br />
Hyung-Wook Kim, Seog-Whan Kim, Rock-Kil Ko, et al.<br />
Korea Electro-technology Research Institute, Korea<br />
Wed-Af-Po3.11-05 [170]<br />
Measurement of overall thermal resistance and contact<br />
thermal resistance in conduction cooled HTS magnets<br />
Seokho Kim and Jihoon Seok<br />
Changwon National University, Korea<br />
Wed-Af-Po3.11-06 [171]<br />
A Study on Thermal and Electrical Characteristic of Metallic<br />
Cladding GdBCO Coil<br />
Jimin Kim, Haigun Lee, Jong Cheol Kim, et al.<br />
Dep. of Materials Sci.&Eng., Korea University, Korea<br />
Wed-Af-Po3.11-07 [172]<br />
Stability and Normal Zone Propagation in a conduction<br />
cooled racetrack coil wound of YBCO Coated Conductor<br />
Tape – FEM Modeling<br />
Milan Majoros, Mike Sumption, Ted Collings, et al.<br />
Ohio State University, USA<br />
Wed<br />
141
Wed<br />
Wed-Af-Po3.11-08 [173]<br />
YBCO pancake coil wound using an electrically non insulated<br />
tape: current sharing, stability, quench, and NZP<br />
measured at 4.2 K and 10 T<br />
Milan Majoros, Mike Sumption, Chris Kovacs, et al.<br />
Ohio State University, USA<br />
Wed-Af-Po3.11-09 [174]<br />
Stability of Superconducting Magnet and Wire Insulations<br />
Qingyu Hu and Xunqi Duan<br />
Ningbo Jansen Mechanism Co., Ltd., Ningbo, China<br />
Wed-Af-Po3.11-10 [175]<br />
Robust REBCO coated conductor with meatal stitching<br />
stabilizer<br />
Rock Kil Ko, No hyun Woo, Gwan Tae Kim, et al.<br />
Korea Electro-technology Research Institute, Korea<br />
Wed-Af-Po3.11-11 [176]<br />
Thermal and Electromagnetic Simulation of Multistacked<br />
No-Insulation REBCO Pancake Coils on Normalstate<br />
Transition by PEEC model<br />
Ryosuke Miyao, Hajime Igarashi, et al.<br />
Hokkaido University, Japan<br />
Wed-Af-Po3.11-12 [177]<br />
Characteristics of current bypassing and transient stability<br />
in partial insulation HTS coils<br />
Seokbeom Kim, Kentaro Tami, Haruyoshi Okusa, et al.<br />
Okayama University, Japan<br />
Wed-Af-Po3.11-13 [178]<br />
Temperature evolution in ITER CSU2 coil module during<br />
15 MA plasma scenario<br />
Tommaso Bagni, Arnaud Devred and Arend Nijhuis<br />
University of Twente, Enschede, the Netherlands<br />
Wed-Af-Po3.11-14 [179]<br />
Strand level modeling on AC loss and current distribution<br />
of prototype EU DEMO TF conductors<br />
Tommaso Bagni, Arnaud Devred and Arend Nijhuis<br />
University of Twente, Enschede, the Netherlands<br />
Wed-Af-Po3.11-15 [180]<br />
Quench energy in ITER conductors for different magnetic<br />
field perturbations with JackPot and THEA combined<br />
models<br />
Tommaso Bagni, Arnaud Devred and Arend Nijhuis<br />
University of Twente, Enschede, the Netherlands<br />
142
Wed-Af-Po3.11-16 [181]<br />
Influence of high thermal conduction plastic having negative<br />
thermal expansion property on cooling performance<br />
in conduction cooled HTS coils<br />
Tomoaki Takao, Yuki Tanaka, Shota Suga, et al.<br />
Sophia University, Japan<br />
Wed-Af-Po3.11-17 [182]<br />
Thermal Stable Analysis on Superconducting Magnet<br />
stacked by REBCO Annulus Plates<br />
Yanbing Hou, Yinshun Wan, Xi Yuan and Yan Li<br />
North China Electric Power University, China<br />
Wed-Af-Po3.11-18 [183]<br />
HTS Magnet with Smart Insulation Method<br />
Young-Sik Jo, Hyung-Wook Kim, Seog-Whan Kim, et al.<br />
Korea Electro-technology Research Institute, Korea<br />
Poster Session 3.12 13:15 - 15:00 Posters Area<br />
AC Losses<br />
Wed-Af-Po3.12-01 [184]<br />
AC Loss Investigation on the High Temperature Superconducting<br />
(HTS) Coil Under the Action of AC Currents<br />
and AC Magnetic Fields<br />
Boyang Shen, Jianzhao Geng, Chao Li, et al.<br />
University of Cambridge, United Kingdom<br />
Wed-Af-Po3.12-02 [185]<br />
AC Loss of a Quasi-isotropic Strand Stacked by 2G<br />
Wires by Numerical Simulation in Cryogenic Temperature<br />
Changtao Kan<br />
North China Electric Power University, China<br />
Wed-Af-Po3.12-03 [186]<br />
Evaluation of hysteresis losses in the (RE)BCO pancakewound<br />
insert of the NHMFL 32 T all-superconducting<br />
magnet using an iterative multi-scale approach<br />
Edgar Berrospe-juarez<br />
Universidad Nacional Autónoma de México, Mexico<br />
Wed-Af-Po3.12-04 [187]<br />
Influence of the modeling depth and voltage level on circulating<br />
currents in parallel conductors of a PMSM<br />
Florian Birnkammer, Junquan Chen, et al.<br />
Universitaet der Bundeswehr Muenchen, Germany<br />
Wed<br />
143
Wed<br />
Wed-Af-Po3.12-05 [188]<br />
Rotor Losses Research of Brushless Doubly-fed Machine<br />
with Hybrid Rotor<br />
Fengge Zhang, Guangwei Liu, Yutao Wang, et al.<br />
Shenyang University of Technology, China<br />
Wed-Af-Po3.12-06 [189]<br />
Experimental Research of AC Ripple Losses in A High<br />
Temperature Superconducting Current Lead of A Magnet<br />
Hongwei Liu, Guosheng Song and Wengang Feng<br />
North China Electric Power University, China<br />
Wed-Af-Po3.12-07 [190]<br />
Modeling of magnetization loss in HTS tape exposed to<br />
all magnetic field direction<br />
Jun Ogawa, Fukui Satoshi, Tetsuo Oka, Panpan Yan, et al.<br />
Niigata University, Japan<br />
Wed-Af-Po3.12-08 [191]<br />
Suppression of Flux Creep in HTS Coil by Applying Low<br />
AC Magnetic Field<br />
Kazuhiro Kajikawa, Tomokazu Honda, et al.<br />
Kyushu University, Japan<br />
Wed-Af-Po3.12-09 [192]<br />
Measurement of AC Losses of HTS Conductors on<br />
Round Core with Filamentary Strands<br />
Kyeongdal Choi and Woo-seok Kim<br />
Korea Polytechnic University, Korea<br />
Wed-Af-Po3.12-10 [193]<br />
A Digital Electrometric Method for Measuring the AC<br />
loss of a HTS Coil<br />
Zhong Xia, Yuejin Tang, Li Ren and Jing Shi<br />
Huazhong University of Science and Technology, China<br />
Wed-Af-Po3.12-11 [194]<br />
Modeling of AC losses in the CS and TF conductors for<br />
the ITER Project<br />
Marco Breschi, Marco Bianchi, et al.<br />
University of Bologna, Italy<br />
Wed-Af-Po3.12-12 [195]<br />
AC Loss Measurement of High-Tc Superconducting<br />
Coils Wound by Stacked Conductors under the Various<br />
Electro-magnetic Conditions<br />
Shuma Kawabata and Tadashi Hirayama<br />
Kagoshima University, Japan<br />
144
Wed-Af-Po3.12-13 [196]<br />
A Facile Method to Estimate Screening Current-Induced<br />
Fields in REBCO Pancake Coils<br />
So Noguchi, Hiroshi Ueda, Seungyong Hahn, et al.<br />
Hokkaido University, Japan<br />
Wed-Af-Po3.12-14 [197]<br />
Additional AC loss properties of REBCO superconducting<br />
two-strand parallel conductors<br />
Soichiro Oki and Masataka Iwakuma<br />
Kyushu University, Japan<br />
Wed-Af-Po3.12-15 [198]<br />
AC Loss Properties of Stacked Multifilamentary REBCO<br />
Superconducting Tapes<br />
Tetsuya Ito, Masataka Iwakuma, Akira Tomioka, et al.<br />
Kyushu University, Japan<br />
Wed-Af-Po3.12-16 [199]<br />
Magnetization loss in REBCO Roebel cables with varying<br />
strand numbers<br />
Wei Zhou, Zhenan Jiang, Michael Staines, et al.<br />
School of Electr. Engin., Beijing Jiaotong University, China<br />
Wed-Af-Po3.12-17 [200]<br />
Frequency and Time Domain Homogenization Model of<br />
Multistrand Windings based on Finite Element Method<br />
Yapeng Jiang, Dong Wang, Junquan Chen and Xuan Teng<br />
Shenyang University of Technology, China<br />
Wed-Af-Po3.12-18 [201]<br />
Non-uniform ramping loss distribution of multiple no-insulation<br />
REBCO magnet<br />
Yawei Wang, Honghai Song, Min Zhang, et al.<br />
University of Bath, Bath, United Kingdom<br />
Wed-Af-Po3.12-19 [202]<br />
Comparison between AC loss measurements and analyses<br />
in coil assemblies with different geometries and<br />
conductors<br />
Yusuke Sogabe, Zhenan Jiang, Stuart Wimbush, et al.<br />
Kyoto University, Japan<br />
Wed-Af-Po3.12-20 [203]<br />
Influence of Three Phases Imbalance on the AC Losses<br />
of Tri-axial HTS CORC Cable used in an All-Electric Aircraft<br />
Zixuan Zhu, Yawei Wang, Min Zhang and Weijia Yuan<br />
University of Bath, Bath, United Kingdom<br />
Wed<br />
145
Wed<br />
Oral Session 22 15:00 - 16:30 G102-103 Room<br />
Other Fusion Magnets<br />
Session Chairs: Paul Libeyre and Antonio della Corte<br />
Wed-Af-Or22-01 15:00<br />
Overview of the Present Progress on the Superconducting<br />
Magnet System of CFETR-PhaseII<br />
Jinxing Zheng, Song Yuntao, Liu Xufeng, et al.<br />
ASIPP, Institute of Plasma Physics, CAS, China<br />
Wed-Af-Or22-02 15:15<br />
Conductor Performance of Nb3Sn Sample for CFETR<br />
CSMC coil<br />
Yu Wu, Bo Liu, Jinggang Qin, Arnaud Devred, et al.<br />
ASIPP, Institute of Plasma Physics, CAS, China<br />
Wed-Af-Or22-03 15:30<br />
Design of a laser-driven kiloTesla magnetic bottle<br />
Francesco Schillaci, Massimo de Marco, et al.<br />
Inst. of Physics Czech Academy of Sci., Czech Republic<br />
Wed-Af-Or22-04 15:45<br />
A 2.5 T, 1.25 m free bore superconducting magnet for the<br />
Magnum-PSI linear plasma generator<br />
Hans van Eck, Herman ten Kate, Alexey Dudarev, et al.<br />
DIFFER, Eindhoven, the Netherlands<br />
Wed-Af-Or22-05 16:00<br />
A Prototype Conductor by React & Wind Method for the<br />
EUROfusion DEMO TF Coils<br />
Pierluigi Bruzzone, Kamil Sedlak, et al.<br />
EPFL-CRPP, Lausanne, Switzerland<br />
Wed-Af-Or22-06 16:15<br />
Progresses in cable in conduit for fusion magnets: from<br />
ITER to DEMO<br />
Davide Uglietti, Kamil Sedlak, Rainer Wesche, et al.<br />
University of Oxford, Oxford, United Kingdom<br />
146
Oral Session 23 15:00 - 16:30 Auditorium<br />
Nb 3Sn Quadrupole Magnets for Accelerators<br />
Session Chairs: Gijs de Rijk<br />
Wed-Af-Or23-01 15:00<br />
Fabrication and assembly performance of the first 4.2 m<br />
MQXFA magnet and mechanical model for the Hi-Lumi<br />
LHC Upgrade<br />
Daniel Cheng, Nicolas Bourcey, et al.<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Or23-02 15:15<br />
Summary of test results of MQXFS1 - the first short<br />
model 150 mm aperture Nb3Sn quadrupole for the High-<br />
Luminosity LHC upgrade<br />
Guram Chlachidze, Stoyan Stoynev, Fred Nobrega, et al.<br />
Fermilab, USA<br />
Wed-Af-Or23-03 15:30<br />
Test results of the short models MQXFS3 and MQXFS5<br />
for the HL-LHC upgrade<br />
Antonella Chiuchiolo, Daniel Cheng, et al.<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Or23-04 15:45<br />
Geometric field errors of Short Models for MQXF, the<br />
Nb3Sn low-beta Quadrupole for the High Luminosity LHC<br />
Susana Izquierdo Bermudez, Giorgio Ambrosio, et al.<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Or23-05 16:00<br />
Test of the first MQXFA prototype by LARP and status of<br />
the US High Luminosity LHC Accelerator Upgrade Project<br />
preparation<br />
Amalia Ballarino, Bernardo Bordini, et al.<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Or23-06 16:15<br />
Two-layer 16 Tesla cosθ dipole design based on MQXF<br />
Low-Beta Quadrupoles<br />
Eddie Holik, Giorgio Ambrosio, et al.<br />
Fermilab, USA<br />
Wed<br />
147
Wed<br />
Oral Session 24 15:00 - 16:30 Emerald Room<br />
Quench Detection and Protection Systems - II<br />
Session Chairs: Vitaly Vysotsky and Gerard Willering<br />
Wed-Af-Or24-01 15:00<br />
Performance of the quench protection system of the first<br />
LARP-CERN quadrupole magnet models<br />
Emmanuele Ravaioli<br />
Lawrence Berkeley National Laboratory, Berkeley, CA, USA<br />
Wed-Af-Or24-02 15:15<br />
Comparison of HTS Quench detection methods based<br />
on Spontaneous Raman and Rayleigh Scattering in Optical<br />
Fibers<br />
Junjie Jiang, Derong Qiu, Anfeng Zhao, Hu Daoyu, et al.<br />
Shanghai Jiao Tong University, China<br />
Wed-Af-Or24-03 15:30<br />
LTS-HTS Hybrid Dipole Magnet Quench Protection System<br />
Piyush Joshi, Ramesh Gupta and William Sampson<br />
BNL, Brookhaven National Laboratory, USA<br />
Wed-Af-Or24-04 15:45<br />
E3SPreSSO: A Quench Protection System for High-Field<br />
High-Temperature Superconducting Magnets<br />
Jeroen van Nugteren, Jaakko Samuel Murtomaki, et al.<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Or24-05 16:00<br />
Quench protection of HTS coil composed of multiple<br />
pancake-coils by changing current distribution in pancake-coils<br />
Ryuta Matsuo, Akane Kojima, Yoshiki Fuchida, et al.<br />
Sophia University, Tokyo, Japan<br />
Wed-Af-Or24-06 16:15<br />
Quench Protection Solutions for Magnets fabricated with<br />
HTS Conductors<br />
Michael Green<br />
LBNL & FRIB/MSU, USA<br />
148
Oral Session 25 17:00 - 18:30 Auditorium<br />
Particle Detector Magnets<br />
Session Chairs: Tatsushi Nakamoto and Alexey Dudarev<br />
Wed-Af-Or25-01 17:00<br />
Superconducting Detector Magnets for CERN’s Future<br />
Circular Collider<br />
Herman ten Kate, Alexey Dudarev, Andrea Gaddi, et al.<br />
CERN, Geneva, Switzerland<br />
Wed-Af-Or25-02 17:15<br />
PENeLOPE: testing a one-of-a-kind neutron storage<br />
magnet<br />
Rüdiger Picker, Dominic Gaisbauer, et al.<br />
TRIUMF, Canada<br />
Wed-Af-Or25-03 17:30<br />
High Field, Large Aperture HTS Solenoid for Axion Dark<br />
Matter Search<br />
Ramesh Gupta, Michael Anerella, Piyush Joshi, et al.<br />
BNL, Brookhaven National Laboratory, USA<br />
Wed-Af-Or25-04 17:45<br />
Design, Fabrication, and Test Results of an 18 T Metal<br />
Cladding GdBCO Magnet for Axion Detector<br />
Jaemin Kim, Yungil Kim, Kang Hwan Shin, et al.<br />
SuNAM Co., Ltd., Korea<br />
Wed-Af-Or25-05 18:00<br />
Design, Manufacture and Testing of a Pair of Superconducting<br />
Solenoids for the Upgrade of the Neutron Spin-<br />
Echo Spectrometer J-NSE at the Research Reactor FRM<br />
II (Munich)<br />
Cristian Boffo, Stefano Pasini, Olaf Holderer, et al.<br />
Babcock Noell, Germany<br />
Wed-Af-Or25-06 18:15<br />
Operational Experience with the MICE Spectrometer Solenoid<br />
System<br />
Sandor Feher, Alan Bross, Pierrick Hanlet, et al.<br />
Fermi National Accelerator Laboratory, USA<br />
Wed<br />
149
Wed<br />
Oral Session 26 17:00 - 18:30 G102-103 Room<br />
Joints and AC loss for Fusion Magnets<br />
Session Chairs: Sylvie Nicollet and Arend Nijhuis<br />
Wed-Af-Or26-01 18:15<br />
Performance of the ITER CS joints<br />
Nicolai Martovetsky, Boris Stepanov, et al.<br />
ORNL, USA<br />
Wed-Af-Or26-02 17:15<br />
Coupling loss in prototype CFETR CS conductors with<br />
different cable patterns, measurement and modeling<br />
Anvar Valiyaparambil Abdulsalam<br />
University of Twente, Enschede, the Netherlands<br />
Wed-Af-Or26-03 17:30<br />
Qualification Program of Joints for ITER Coils<br />
Y. Ilyin, F. Simon, B.s. Lim, C.y. Gung, et al.<br />
ITER International Organization, France<br />
Wed-Af-Or26-04 17:45<br />
Electro-mechanical measurements of mechanical lap<br />
joint of HTS STARS conductors<br />
Satoshi Ito, Tatsuki Nishio, Nagato Yanagi, et al.<br />
Tohoku University, Japan<br />
Wed-Af-Or26-05 18:00<br />
Pulsed field stability and AC loss of ITER NbTi PF joints<br />
by detailed quantitative modeling<br />
Jianfeng Huang, Tommaso Bagni, Yury Ilin, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Wed-Af-Or26-06 18.15<br />
Analyses of the ITER Poloidal Coil joints cold test results.<br />
Andrei Baikalov, Byung Su Lim, Fabrice Simon, et al.<br />
ITER International Organization, France<br />
150
Oral Session 27 17:00 - 18:30 Emerald Room<br />
Resistive and Pulsed High-field Magnets<br />
Session Chairs: Frans Wijnen and Pierre Pugnat<br />
Wed-Af-Or27-01 17:00<br />
Recent Magnet and Material Development at the Pulsed<br />
Field Facility – NHMFL<br />
Doan Nguyen, James Michel, Jason Lucero, Ke Han, et al.<br />
LANL, USA<br />
Wed-Af-Or27-02 17:15<br />
Development of the 100 T Pulsed Magnet at the Wuhan<br />
National High Magnetic Field Center<br />
Tao Peng, Liang Li, Shuang Wang, Fan Jiang, et al.<br />
Wuhan National High Magnetic Field Center, China<br />
Wed-Af-Or27-03 17:30<br />
Design and tests of the 100 T triple coil at LNCMI<br />
Jérôme Béard, Julien Billette, Nelson Ferreira, et al.<br />
LNCMI-CNRS-UPS-INSA-UGA, France<br />
Wed-Af-Or27-04 17:45<br />
Design and Operation of the Pulsed Magnets at the Dresden<br />
High Magnetic Field Laboratory<br />
S. Zherlitsyn, T. Herrmannsdoerfer, et al.<br />
Hochfeld-Magnetlabor (HLD-EMFL), Dresden, Germany<br />
Wed-Af-Or27-05 18:00<br />
Design for an Upgrade of the NHMFL 32-mm Bore Resistive<br />
Magnet<br />
Jack Toth and Scott Bole<br />
NHMFL, Tallahassee, FL, USA<br />
Wed-Af-Or27-06 18:15<br />
60 Tesla Pulse Coil Design and Manufacturing Facility<br />
Todd Adkins, Iain Dixon, Kurt Cantrell, et al.<br />
NHMFL, Tallahassee, FL, USA<br />
Wed<br />
151
Thu<br />
Thursday, August 31, 2017<br />
Registration at RAI Conference Center, 08:00 – 18:30<br />
Oral Session 28 08:45 - 10:30 Auditorium<br />
Magnets for Future Accelerators<br />
Session Chairs: Paolo Ferracin and Giorgio Apollinari<br />
Thu-Mo-Or28-01 08:45<br />
[Invited] The EuCARD2 Future Magnets Program for particle<br />
accelerator high field dipoles: review of results and<br />
next steps<br />
Alexander Usoskin, Amalia Ballarino, et al.<br />
CERN, Geneva, Switzerland<br />
Thu-Mo-Or28-02 09:15<br />
Status of the 16 T dipole development programme for a<br />
future hadron collider<br />
Davide Tommasini, Alexander Zlobin, et al.<br />
CERN, Geneva, Switzerland<br />
Thu-Mo-Or28-03 09:30<br />
Cold powering test results of the Nb3Sn FRESCA2 block<br />
coil magnet<br />
Gerard Willering, Gijs de Rijk, Marta Bajko, et al.<br />
CERN, Geneva, Switzerland<br />
Thu-Mo-Or28-04 09:45<br />
The US Magnet Development Program for High Field Accelerator<br />
Magnet R&D<br />
Soren Prestemon<br />
Lawrence Berkeley National Laboratory, Berkeley, CA, USA<br />
Thu-Mo-Or28-05 10:00<br />
Design, Construction and Test of HTS/LTS Hybrid Dipole<br />
Ramesh Gupta, Michael Anerella, John Cozzolino, et al.<br />
Brookhaven National Laboratory, USA<br />
Thu-Mo-Or28-06 10:15<br />
High-field dipoles using superconducting cable-in-conduit<br />
Peter Mcintyre, Jeff Breitschopf, et al.<br />
Texas A&M University, USA<br />
152
Oral Session 29 08:45 - 10:30 G102-103 Room<br />
Cryogenics & Auxiliary Technologies<br />
Session Chairs: Rob van Weelderen and Riccardo Musenich<br />
Thu-Mo-Or29-01 08:45<br />
A REBCO Persistent-Current Switch, Immersed in Solid<br />
Nitrogen, Operating In the Temperature Range 10-30 K<br />
Philip Michael, Jiho Lee, John Voccio, et al.<br />
MIT Francis Bitter Magnet Laboratory, USA<br />
Thu-Mo-Or29-02 09:00<br />
The Study of Pulsed Strong Magnetic Field Measurement<br />
System based on Distributed Magnetic Field Sensors<br />
Zhenhua Li, Li Qiu, Wenhui Zheng, Shuang Zhao, et al.<br />
China Three Gorges University, Yichang, China<br />
Thu-Mo-Or29-03 09:15<br />
Temperature dependent behaviour of a barrel-type HTS<br />
dynamo<br />
Chris Bumby, Rodney Badcock, Zhenan Jiang, et al.<br />
Victoria University of Wellington, New Zealand<br />
Thu-Mo-Or29-04 09:30<br />
Design and Test of the Cryogenic Cooling System for the<br />
Rotating Magnetic Validator of the 10 MW SU-<br />
PRAPOWER Offshore Superconducting Wind Turbine<br />
Jiuce Sun, Holger Neumann, Santiago Sanz, et al.<br />
KIT, Karlsruhe, Germany<br />
Thu-Mo-Or29-05 09:45<br />
CRYOGENIC ENVIRONMENTS FOR QUANTUM TECHNO-<br />
LOGIES<br />
Ziad Melhem<br />
Oxford Instruments NanoScience, United Kingdom<br />
Thu-Mo-Or29-06 10:00<br />
Hub- and Site-cooling of MRI magnets using a mobile<br />
cryogenic system<br />
Anders Mortensen, Santhosh Kumar Gandla, et al.<br />
Siemens Magnet Technology, United Kingdom<br />
Thu-Mo-Or29-07 10:15<br />
Cryogenics Engineering for Superconducting Magnets at<br />
DEMACO<br />
Rossi Mendez, Ruud van der Woude, et al.<br />
DEMACO, Noord-Scharwoude, the Netherlands<br />
Thu<br />
153
Thu<br />
Oral Session 30 08:45 - 10:30 Emerald Room<br />
Nb 3Sn, BSCCO & MgB 2 Conductors<br />
Session Chairs: Gen Nishijima and Wilfried Goldacker<br />
Thu-Mo-Or30-01 08:45<br />
Nb3Sn strand designs and heat treatments for high field<br />
magnet applications<br />
Michael Field, Hanping Miao and Jeff Parrell<br />
Bruker OST, USA<br />
Thu-Mo-Or30-02 09:00<br />
Advanced tube type Nb3Sn conductor and its applications<br />
in Hyper Tech<br />
Xuan Peng, Matt Rindfleisch, Michael Tomsic, et al.<br />
Hyper Tech Research Inc., USA<br />
Thu-Mo-Or30-03 09:15<br />
Effect of strand diameter, magnetic field and injection<br />
length on the current entrance length of internal tin<br />
strand<br />
Chao Zhou, Arend Nijhuis, Christiaan Reurslag, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Thu-Mo-Or30-04 09:30<br />
Development of Nb3Sn strands and Rutherford Cables<br />
for 16 T Accelerators Magnets<br />
Emanuela Barzi, Pei Li, Daniele Turrioni, et al.<br />
Fermilab, USA<br />
Thu-Mo-Or30-05 09:45<br />
Recent Progress of Application-Oriented DI-BSCCO<br />
Wires<br />
Takayoshi Nakashima, Shin-ichi Kobayashi, et al.<br />
Sumitomo Electric Industries, Ltd., Japan<br />
Thu-Mo-Or30-06 10:00<br />
Present status of Bi-2212 conductor technology<br />
David Larbalestier, Eric Hellstrom, et al.<br />
National High Magnetic Field Laboratory, Tallahassee, USA<br />
Thu-Mo-Or30-07 10:15<br />
MgB2 cables from wires made PIT and IMD process.<br />
Pavol Kováč, Lubomír Kopera, Tibor Melišek, et al.<br />
Institute of Electrical Engineering of SAS, Slovakia<br />
154
Oral Session 31 11:00 - 12:45 Auditorium<br />
HTS Insert and Model Magnets<br />
Session Chairs: Xavier Chaud and Hubertus Weijers<br />
Thu-Mo-Or31-01 11:00<br />
Electromagnetic Design of HTS insert for NMR Magnet in<br />
Consideration of Screening Currents<br />
Yi Li, Lei Wang, Xuchen Zhu and Qiuliang Wang<br />
Intitute of Electrical Engineering, CAS, China<br />
Thu-Mo-Or31-02 11:15<br />
HTS Accelerator Magnet Dipole Assembly and Cold Test<br />
by CERN for EuCARD2<br />
Glyn Kirby, Jeroen van Nugteren, Hugo Bajas, et al.<br />
CERN, Geneva, Switzerland<br />
Thu-Mo-Or31-03 11:30<br />
Design, Construction and Operation of a 13 T 52 mm No-<br />
Insulation REBCO Insert for a 20 T All-Superconducting<br />
User Magnet<br />
Kwangmin Kim, Thomas Painter, Van Griffin, et al.<br />
National High Magnetic Field Laboratory, Tallahassee, USA<br />
Thu-Mo-Or31-04 11:45<br />
Compact, high field coils made with strong, rectangular<br />
Bi2212 superconductor wire<br />
Alexander Otto<br />
Solid Material Solutions, LLC, USA<br />
Thu-Mo-Or31-05 12:00<br />
High Field Coil Technology with Bi-2212 Round Wire<br />
Ulf Trociewitz, Tim Cross, S Imam Hossain, et al.<br />
NHMFL, Tallahassee, FL, USA<br />
Thu-Mo-Or31-06 12:15<br />
Performance of two-ply four-filaments Gd123 tape coil<br />
Satoshi Awaji, Tatsunori Okada, et al.<br />
HFLSM, IMR, Tohoku University, Japan<br />
Thu-Mo-Or31-07 12:30<br />
Characterisation of HTS insulated coil for high field insert<br />
Tara Benkel, Xavier Chaud, Arnaud Badel, et al.<br />
CNRS, France<br />
Thu<br />
155
Thu<br />
Oral Session 32 11:00 - 12:45 Emerald Room<br />
Joints for HTS and MgB2 & other Materials for<br />
Magnets<br />
Session Chairs: Reinhard Heller and Mike Sumption<br />
Thu-Mo-Or32-01 11:00<br />
Measurement of persistent current Gd123 coil for superconducting<br />
joint fabricated by CJMB method<br />
Xinzhe Jin, Yoshinori Yanagisawa, et al.<br />
Muroran Institute of Technology, Japan<br />
Thu-Mo-Or32-02 11:15<br />
10 kA joints for Multi-Tape HTS Cables<br />
Jaakko Samuel Murtomäki, Glyn Kirby, et al.<br />
Tampere University of Technology, Finland<br />
Thu-Mo-Or32-03 11:30<br />
Contact resistance between REBCO tapes coated with a<br />
thin resistive layer<br />
Jun Lu, Jeremy Levitan and Ke Han<br />
NHMFL, Tallahassee, FL, USA<br />
Thu-Mo-Or32-04 11:45<br />
Superconducting HTS joints for connecting strong<br />
Bi2212 wires<br />
Alexander Otto<br />
Solid Material Solutions, LLC, USA<br />
Thu-Mo-Or32-05 12:00<br />
Progress Report on Superconducting Joint Technique<br />
for the Development of MgB2 MRI magnet<br />
Young-gyun Kim, Haigun Lee, Jung-bin Song, et al.<br />
Dep. of Materials Sci.&Eng., Korea University, Korea<br />
Thu-Mo-Or32-06 12:15<br />
Open Material Property Library With Native Simulation<br />
Tool Integrations (OpMaST)<br />
Antti Aleksis Stenvall, Jeroen van Nugteren, et al.<br />
Tampere University of Technology, Tampere, Finland<br />
Thu-Mo-Or32-07 12:30<br />
High Modulus Reinforcement Materials<br />
Ke Han and Yan Xin<br />
NHMFL-FSU, Tallahassee, FL, USA<br />
156
Oral Session 33 11:00 - 12:45 G102-103<br />
Multiphysics Design and Analysis for Different<br />
Magnet Applications<br />
Session Chairs: Antti Aleksis Stenvall and Naoyuki Amemiya<br />
Thu-Mo-Or33-01 11:00<br />
Coupled electro-magnetic, thermal, mechanical analysis<br />
of a quench in the high luminosity LHC Nb3Sn quadrupole<br />
magnet<br />
Heng Pan, Emmanuele Ravaioli, Daniel Cheng, et al.<br />
LBNL, Berkeley, CA, USA<br />
Thu-Mo-Or33-02 11:15<br />
Errors and optics study of a permanent magnet quadrupole<br />
system<br />
Francesco Schillaci, Mario Maggiore, et al.<br />
Inst. of Physics Czech Academy of Science, Czech Republic<br />
Thu-Mo-Or33-03 11:30<br />
Coupling of Mechanical and Magneto-Thermal Models of<br />
Superconducting Magnet by Means of Mesh Based Interpolation<br />
Michal Maciejewski, Bernhard Auchmann, et al.<br />
Technical University of Lodz, Poland<br />
Thu-Mo-Or33-04 11:45<br />
An Engineering Perspective on Ultra High-Field Magnets<br />
Andrew Twin, David Warren, Joe Brown, et al.<br />
Oxford Instruments, United Kingdom<br />
Thu-Mo-Or33-05 12:00<br />
Multiphysics FEA Led Design of Bi-2212 Round Wire<br />
Prototype Coils<br />
Ernesto Bosque, Youngjae Kim, et al.<br />
NHMFL-ASC, Tallahassee, FL, USA<br />
Thu-Mo-Or33-06 12:15<br />
Ultimate Forces of the Grenoble Hybrid Magnet<br />
Hans Schneider-muntau, Benjamin Vincent, et al.<br />
CS&T Company, France<br />
Thu-Mo-Or33-07 12:30<br />
LEDET-ANSYS coupled modeling of transients in superconducting<br />
magnets<br />
Lucas Brower, Emmanuele Ravaioli, et al.<br />
LBNL, Berkeley, CA, USA<br />
Thu<br />
157
Thu<br />
Poster Session 4<br />
Session Chairs: Marco Breschi and Doan Nguyen<br />
Poster Session 4.01 13:45 - 15:30 Posters Area<br />
Accelerator Magnets<br />
Thu-Af-Po4.01-01 [01]<br />
Analysis of the Training Behaviour of the MICE Spectrometer<br />
Solenoid<br />
Holger Witte, Heng Pan, Soren Prestemon, et al.<br />
BNL, Brookhaven National Laboratory, USA<br />
Thu-Af-Po4.01-02 [02]<br />
Conductor Cost Optimized Idealized Dipole Cross-Sections<br />
for Accelerator Applications<br />
Jeroen van Nugteren, Felix Josef Wolf, et al.<br />
TU Bergakademie Freiberg, Germany<br />
Thu-Af-Po4.01-03 [03]<br />
Comparative Study of Magnetic Characteristics between<br />
Air-Core and Iron-Core High-temperature Superconducting<br />
Quadruple Magnet<br />
Jeyull Lee, Junseong Kim, Zhan Zhang, et al.<br />
Yonsei University, Korea<br />
Thu-Af-Po4.01-04 [04]<br />
Applied metrology in the production of superconducting<br />
model magnets for particle accelerators<br />
Jose Ferradas Troitino, Patrick Bestmann, et al.<br />
CIEMAT, Spain<br />
Thu-Af-Po4.01-05 [05]<br />
Design, Assembly and Use of a Device to Eliminate Earth<br />
Faults Caused by Foreign Metallic Debris in the LHC<br />
Main Dipole Circuit<br />
Mateusz Jakub Bednarek, Andrzej Siemko, et al.<br />
CERN, Geneva, Switzerland<br />
Thu-Af-Po4.01-06 [06]<br />
Study of a Sextupole Round Coil Superferric Magnet<br />
Samuele Mariotto, J. Rysti, Massimo Sorbi, et al.<br />
University of Milan, INFN Milan, Italy<br />
Thu-Af-Po4.01-07 [07]<br />
A Study on the Sextupole Design with Iron Yoke inside<br />
Solenoids for 56 GHz ECR Ion Source<br />
Shaoqing Wei, Zhan Zhang and Sangjin Lee<br />
Uiduk University, Korea<br />
158
Thu-Af-Po4.01-08 [08]<br />
Construction and Testing of Curved ReBCO Coils<br />
Stephen Kahn, Michael Anerella, Alan Dudas, et al.<br />
Muons, Inc., Batavia, USA<br />
Thu-Af-Po4.01-09 [09]<br />
Fabrication and Measurement of New Inflector for g-2<br />
Steve Krave, Vladimir Kashikhin and Karie Badgley<br />
Fermilab, USA<br />
Thu-Af-Po4.01-10 [10]<br />
Development of 7 T superconducting solenoid magnet<br />
for Electron Beam Ion Source<br />
Su-hun Kim, Se-hee Lee and Seyong Choi<br />
Kyungpook National University, Korea<br />
Thu-Af-Po4.01-11 [11]<br />
A Study of Irradiation Effects on Thermal Characteristics<br />
of COMET Pion Capture Solenoid<br />
Ye Yang, Kenichi Sasaki, Tatsushi Nakamoto, et al.<br />
Kyushu University, Japan<br />
Thu-Af-Po4.01-12 [12]<br />
Prototype Design of the Dipole for EMuS at CSNS<br />
Yuan Chen, Hantao Jing, Zhilong Hou, Zian Zhu, et al.<br />
Institute of High Energy Physics, CAS, China<br />
Thu-Af-Po4.01-13 [13]<br />
Design, fabrication and test of a 2 T superconducting dipole<br />
prototype by using tilted solenoids<br />
Yuquan Chen, Wei Wu, Yu Liang, Beimin Wu, et al.<br />
IMP, CAS, China<br />
Thu-Af-Po4.01-14 [14]<br />
Design of a cosine-theta dipole magnet considering influence<br />
of shielding-current-induced field on field quality<br />
Yusuke Sogabe and Naoyuki Amemiya<br />
Kyoto University, Japan<br />
Poster Session 4.02 13:45 - 15:30 Posters Area<br />
Fusion Magnets: Design and Analysis<br />
Thu<br />
Thu-Af-Po4.02-01 [15]<br />
LAMINAR SUPERCONDUCTING WINDINGS<br />
Evgeny Klimenko<br />
SSC RF TRINITI, Moscow, Russia<br />
Thu-Af-Po4.02-02 [16]<br />
Development of a 2D simplified tool for the analysis of<br />
the cooling of the ITER TF winding pack<br />
Francesca Cau, Ruggero Forte, Alfredo Portone, et al.<br />
Fusion for Energy, F4E, Barcelona, Spain<br />
159
Thu<br />
Thu-Af-Po4.02-03 [17]<br />
An Electromagnetic and Structural Finite Element Model<br />
of the ITER TF Coils<br />
Gabriele D'amico, Cornelis Jong, et al.<br />
Fusion for Energy,F4E, Barcelona, Spain<br />
Thu-Af-Po4.02-04 [18]<br />
Nonlinear multiscale structural analysis of a superconducting<br />
coil and support structure for the helical fusion<br />
reactor<br />
Hitoshi Tamura, Takuya Goto, Nagato Yanagi, et al.<br />
National Institute for Fusion Science, Japan<br />
Thu-Af-Po4.02-05 [19]<br />
Thermo-hydraulic analysis of the KSTAR PF cryogenic<br />
loop using SUPERMAGNET CODE<br />
Hyunjung Lee, Sangjun Oh, Jung Laurent, et al.<br />
National Fusion Research Institute, Korea<br />
Thu-Af-Po4.02-06 [20]<br />
Optimization of structural performance of the toroidal<br />
field coil system of a tokamak<br />
Ilia Ivashov and Anatoly Panin<br />
Forschungszentrum Jülich GmbH, Germany<br />
Thu-Af-Po4.02-07 [21]<br />
Analysis of a protected Loss Of Flow Accident (LOFA) in<br />
the ITER TF coil cooling circuit<br />
Laura Savoldi, Roberto Bonifetto, et al.<br />
Politecnico di Torino, Italy<br />
Thu-Af-Po4.02-08 [22]<br />
Status of CEA magnets design methods and tools and<br />
application to EU demo magnets design<br />
Louis Zani, Benoit Lacroix, Alexandre Torre, et al.<br />
CEA-IRFM, France<br />
Thu-Af-Po4.02-09 [23]<br />
DEMO Central Solenoid Design Based on the Use of HTS<br />
Sections at Highest Magnetic Field<br />
Rainer Wesche, Xabier Sarasola, Kamil Sedlak, et al.<br />
EPFL – SPC, Lausanne, Switzerland<br />
Thu-Af-Po4.02-10 [24]<br />
Thermohydraulic analyses on CEA concept of TF and CS<br />
coils for EU-DEMO<br />
Roser Vallcorba, Benoît Lacroix, et al.<br />
CEA Saclay, France<br />
Thu-Af-Po4.02-11 [25]<br />
A momentum-preserved node concept for thermohydraulic<br />
analysis of fusion magnet<br />
Sangjun Oh, Hyunjung Lee and Dong Keun Oh<br />
NFRI, Korea<br />
160
Thu-Af-Po4.02-12 [26]<br />
Further development of fusion enabling systems in Russia:<br />
suggestions on superconductors and current leads<br />
for DEMO-FNS facility.<br />
Sergey Lelekhov, Boris Kuteev, Vitaly Vysotsky, et al.<br />
Russian ITER Center, Russia<br />
Thu-Af-Po4.02-13 [27]<br />
Parametric analyses of JT-60SA TF coil in cold test facility<br />
with SUPERMAGNET code<br />
Sylvie Nicollet, Alexandre Torre, et al.<br />
CEA, France<br />
Thu-Af-Po4.02-14 [28]<br />
On a full 3D thermal structural Finite Element Model of<br />
the JT-60SA toroidal field coils<br />
Valerio Tomarchio and Manfred Wanner<br />
Fusion for Energy, F4E, Barcelona, Spain<br />
Thu-Af-Po4.02-15 [29]<br />
Advanced mathematical model of ITER PF1 coil for manufacture<br />
quality control<br />
Victor Amoskov, Alexander Belov, et al.<br />
JSC "NIIEFA", Efremov Institute, Saint Petersburg, Russia<br />
Thu-Af-Po4.02-16 [30]<br />
Numerical modelling of the quench propagation phase in<br />
the JT-60SA TF coils tested in CTF<br />
Yawei Huang, Laurent Genini, Louis Zani, et al.<br />
CEA Saclay, France<br />
Thu-Af-Po4.02-17 [31]<br />
Numerical Simulation of Thermal Behavior In a No-insulation<br />
Toroidal Magnet<br />
Yi Zhang, Yuejin Tang, Li Ren and Ying Xu<br />
Huazhong University of Science and Technology, China<br />
Thu-Af-Po4.02-18 [32]<br />
Design, Construction and Testing of Reduced Insulation<br />
Solenoids for Fusion<br />
Yuhu Zhai<br />
Princeton Plasma Physics Laboratory, USA<br />
Thu-Af-Po4.02-19 [33]<br />
High Temperature Superconductors for Fusion Nuclear<br />
Science Spherical Tokamak<br />
Yuhu Zhai, Thomas Brown and Jonathan Menard<br />
Princeton Plasma Physics Laboratory, USA<br />
Thu<br />
161
Thu<br />
Poster Session 4.03 13:45 - 15:30 Posters Area<br />
Wigglers, Undulators and Fast Cycling Accelerator<br />
Magnets<br />
Thu-Af-Po4.03-01 [34]<br />
Full Scale Conduction Cooled Superconducting Undulator<br />
Coils – Training, Stability and Thermal Behavior<br />
Andreas Grau, Sara Casalbuoni, Nicole Glamann, et al.<br />
Karlsruhe Institute of Technology, Germany<br />
Thu-Af-Po4.03-02 [35]<br />
Testing of the superconducting magnets for the SIS100<br />
Anna Mierau, Egbert Fischer, Kaether Florian, et al.<br />
GSI, Darmstadt, Germany<br />
Thu-Af-Po4.03-03 [36]<br />
Low temperature Hall probe calibration system for the<br />
TPS cryogenic permanent magnet undulator<br />
Chin-Kang Yang, Wen-Hsuan Hsieh, Yung-Teng Yu, et al.<br />
Nat. Synchrotron Radiation Research Center, Korea<br />
Thu-Af-Po4.03-04 [37]<br />
Design of a Short Period Permanent Magnet Helical Undulator<br />
Cheng-ying Kuo, Cheng-hsing Chang, et al.<br />
National Synchrotron Radiation Research Center, Taiwan<br />
Thu-Af-Po4.03-05 [38]<br />
Constructing a permanent magnet phase shifter<br />
Chih-sheng Yang, Ting-yi Chung, Cheng-ying Kuo, et al.<br />
National Synchrotron Readation Research Center, Taiwan<br />
Thu-Af-Po4.03-06 [39]<br />
Design and magnetic measurements of a hybrid wiggler<br />
for SR research program at VEPP-4<br />
Grigory Baranov, Pavel Voblyy, Evgeny Levichev, et al.<br />
Budker Institute of Nuclear Physics, Novosibirsk, Russia<br />
Thu-Af-Po4.03-07 [40]<br />
Cable-in-Conduit Dipoles for the Ion Ring of JLEIC<br />
Jeff Breitschopf, Daniel Chavez, James Gerity, et al.<br />
Texas A&M University, USA<br />
Thu-Af-Po4.03-08 [41]<br />
Eddy currents analysis of dipole magnets of booster ring<br />
at HIAF project<br />
Qiang Hu, Qinggao Yao, Mingzhi Guan, et al.<br />
Institute of Modern Physics of CAS, China<br />
162
Thu-Af-Po4.03-09 [42]<br />
Improvement of Field Simulation Concept of Staggered<br />
Undulator with HTS YBCO Bulk<br />
S.D. Chen, C.A. Chiang, C.M. Yang, H.W. Luo, et al.<br />
National Synchrotron Radiation Research Center, Taiwan<br />
Thu-Af-Po4.03-10 [43]<br />
Fast Cycling Superconducting Quadrupole<br />
Sergey Kozub, Evgeny Kashtanov, Igor Bogdanov, et al.<br />
Institute for High Energy Physics, Russia<br />
Thu-Af-Po4.03-11 [44]<br />
Dynamic Behaviour of Laminated Magnets with Solid<br />
Tension Bars<br />
Thomas Zickler<br />
CERN, Geneva, Switzerland<br />
Thu-Af-Po4.03-12 [45]<br />
Test results of the first superconducting undulator prototype<br />
at the SSRF<br />
Jieping Xu, Yi Ding, Jian Cui, Ming Li, et al.<br />
Shanghai Institute of Applied Physics, CAS, China<br />
Poster Session 4.04 13:45 - 15:30 Posters Area<br />
Magnets for MRI<br />
Thu-Af-Po4.04-01 [46]<br />
The FuSuMaTech initiative: Synergy with Industry and<br />
Impact on the Future Superconducting Magnet Technology<br />
Antoine Dael, Glyn Kirby, David Mazur, et al.<br />
CEA, France<br />
Thu-Af-Po4.04-02 [47]<br />
Investigation of Temporal Stability of a Persistent Current<br />
Mode Prototype MgB2 Coil<br />
Byeong-ha Yoo, Haigun Lee, Jong Cheol Kim, et al.<br />
Dep. of Materials Sci.&Eng., Korea UniversitY, Korea<br />
Thu-Af-Po4.04-03 [48]<br />
A Tabletop Liquid-Helium-Free, Persistent-Mode 1.5-<br />
T/70-mm MgB2 Osteoporosis MRI: Two Magnet Design<br />
Options<br />
Dongkeun Park, Timing Qu, Min Cheol Ahn, et al.<br />
MIT, Francis Bitter Magnet Laboratory, USA<br />
Thu-Af-Po4.04-04 [49]<br />
Enlarged bore 11.74 T magnet for brain research application<br />
Gabriella Norcia, Alessio Capelluto, et al.<br />
ASG Superconductors S.p.A., Genova, Italy<br />
Thu<br />
163
Thu<br />
Thu-Af-Po4.04-05 [50]<br />
Auxiliary equipment commissioning of the 11.7 T MRI<br />
Iseult magnet<br />
Hervé Lannou, Philippe Bredy, Thierry Schild, et al.<br />
CEA, France<br />
Thu-Af-Po4.04-06 [51]<br />
Estimation method of optimal amount of overshooting<br />
current for temporally uniform magnetic field in a conduction-cooled<br />
ReBCO coil for MRI applications<br />
Hideaki Miura, Jun Miyazaki, Daisuke Miyagi, et al.<br />
Tohoku University, Japan<br />
Thu-Af-Po4.04-07 [52]<br />
Design and development of conduction cooled MgB2<br />
magnets for 1.5 and 3.0 T full body MRI systems<br />
Michael Tomsic, Dave Doll, Matt Rindfleisch, et al.<br />
Hyper Tech Research Inc., USA<br />
Thu-Af-Po4.04-08 [53]<br />
FEM Modelling Studies of 3 T Cryogen Free MRI Magnet<br />
based on MgB2 conductor<br />
Milan Majoros, Mike Sumption, Ted Collings, et al.<br />
Ohio State University, USA<br />
Thu-Af-Po4.04-09 [54]<br />
Walk-Through MRI: Affordable Technology for Well-Patient<br />
Cancer Screening<br />
Peter Mcintyre, Joshua Kellams, et al.<br />
Texas A&M University, USA<br />
Thu-Af-Po4.04-10 [55]<br />
Magnetic Field Stability Improvement of HTS-MRI Magnet<br />
under Power Supply Driven Operation with a Micro Current<br />
Trimming Control<br />
Takeshi Kawashima, Takayuki Yachida, et al.<br />
Kyoto University, Japan<br />
Thu-Af-Po4.04-11 [56]<br />
Performance test of 1.5 T cryogen free orthopedic MRI<br />
magnet<br />
Valeriy Lysenko, Anton Bagdinov, et al.<br />
Lebedev Physical Inst. of the Russian Ac. of Sci., Russia<br />
Thu-Af-Po4.04-12 [57]<br />
The trapped magnetic field of a joint-less second-generation<br />
high temperature superconducting coil.<br />
Yali Zheng<br />
Luoyang Normal University, China<br />
164
Thu-Af-Po4.04-13 [58]<br />
Design Options of a 3-T 900-mm Whole Body MRI Magnet<br />
with Selected Commercial MgB2 Wires<br />
Young-gyun Kim, Haigun Lee, Seungyong Hahn, et al.<br />
Dep. of Materials Sci.&Eng., Korea University, Seoul, Korea<br />
Poster Session 4.05 13:45 - 15:30 Posters Area<br />
Motors - IV<br />
Thu-Af-Po4.05-01 [59]<br />
Sensorless Control of Bearingless Permanent Magnet<br />
Synchronous Motor Based on MRAS<br />
Huangqiu Zhu, Yizhou Hua and Chenyin Zhao<br />
Jiangsu University, China<br />
Thu-Af-Po4.05-02 [60]<br />
Analysis of the Nonlinear Characteristics of Magnetic<br />
Circuit in a Balanced Armature Receiver<br />
Dan-Ping Xu, Sang-Moon Hwang, Yuan-Wu Jiang, et al.<br />
Pusan National University, Korea<br />
Thu-Af-Po4.05-03 [61]<br />
Analysis of Magnetic Stiffness in a Balanced Armature<br />
Receiver Considering the Effects of Soft Magnetic Material<br />
Saturation<br />
Dan-Ping Xu, Sang-Moon Hwang, Yuan-Wu Jiang, et al.<br />
Pusan National University, Korea<br />
Thu-Af-Po4.05-04 [62]<br />
Analysis of EMF Distortion in Magnetic Geared Machines<br />
Xiang Ren, Dawei Li and Ronghai Qu, China<br />
Huazhong University of Science & Technology<br />
Thu-Af-Po4.05-05 [63]<br />
Study on Vibration Characteristics of Permanent Magnet<br />
Synchronous Motor with Demagnetization of Permanentmagents<br />
Dong-woo Kang<br />
Keimyung University, Korea<br />
Thu-Af-Po4.05-06 [64]<br />
Research on demagnetization-resistant structure of synchronous<br />
motor performance using Nd-permanent magnets<br />
reduced heavy rare earth metals<br />
Dong-woo Kang<br />
Keimyung University, Korea<br />
Thu-Af-Po4.05-07 [65]<br />
Study on Design of a Novel Magnetic Field Modulation<br />
Linear Primary Permanent Magnet Synchronous Motor<br />
Fengge Zhang, Xiong Yang and Xiuping Wang<br />
Shenyang University of Technology,China<br />
Thu<br />
165
Thu<br />
Thu-Af-Po4.05-08 [66]<br />
Optimal desing of PMa-synRM for electric propulsion<br />
system considering wide operation range and demagnetization<br />
Sang-Yong Jung, Gyeong Jae Park and Jin-Seok Kim<br />
Sungkyunkwan University, Korea<br />
Thu-Af-Po4.05-09 [67]<br />
Characteristic Analysis of Permanent Magnet Synchronous<br />
Machine Considering Combination of Time Harmonics<br />
Sang-Yong Jung, Gyeong-Jae Park, Hyun Mi Kim, et al.<br />
Sungkyunkwan Univeristy, Korea<br />
Thu-Af-Po4.05-10 [68]<br />
Thermal limit curve calculation for squirrel cage<br />
induction motor based thermal equivalent circuit<br />
Jae-Jun Lee, Jae-Kwang Lee and Gang Seok Lee<br />
Hyundai Heavy Industries Co.,Ltd., Korea<br />
Thu-Af-Po4.05-11 [69]<br />
Design of a Non Rare Earth Spoke Type Permananet<br />
Magnet Motor for Considering Magnetization after<br />
Assembly<br />
Jung-ho Han, Jae-kwang Lee and Ju Lee<br />
LG Innotek, Korea<br />
Thu-Af-Po4.05-12 [70]<br />
A Novel Partitioned Stator Flux-Reversal Memory<br />
Machine<br />
Southeast University, China<br />
Thu-Af-Po4.05-13 [71]<br />
The Estimation of AC Loss Range for Variable Speed PM<br />
Motor Based on Monte Carlo Method<br />
Junquan Chen, Dong Wang, Xi,oqin Zheng, et al.<br />
Naval University of Engineering, Wuhan, China<br />
Thu-Af-Po4.05-14 [72]<br />
Analytical approach to maximize the torque density with<br />
size constraints for PMSM<br />
Kidoek Lee, Sehyun Rhyu and Jeongjong Lee<br />
Korea Electronics Technology Institute, Korea<br />
Thu-Af-Po4.05-15 [73]<br />
Torque Control of IPMSM considering actual controller<br />
and driving condition<br />
Ye Jun Oh, Kyoung-jin Joo, Gang Seok Lee, et al.<br />
Hanyang University, Korea<br />
166
Thu-Af-Po4.05-16 [74]<br />
Nonlinear Sensorless Control including Zero Speed of<br />
Permanent Magnet Synchronous Motor Drives<br />
Kyoung-jin Joo, Seung-joo Kim and Ju Lee<br />
Korea Testing Certification, Korea<br />
Thu-Af-Po4.05-17 [75]<br />
Influence of Stator Structure on the Static Characteristics<br />
in Axial Field Flux Switching Permanent Magnet Machine<br />
Li Hao, Mingyao Lin, Nian Li and Da Xu<br />
Southeast University, China<br />
Thu-Af-Po4.05-18 [76]<br />
A Multi-Tooth Axial Field Flux-Switching Hybrid Excitation<br />
Machine<br />
Li Hao, Mingyao Lin, Nian Li and Da Xu<br />
Southeast University, China<br />
Thu-Af-Po4.05-19 [77]<br />
Investigation of SMPM Motor with Segmented Eccentric<br />
Magnet Pole<br />
Libing Jing, Wubin Kong and Zhenghao Luo<br />
Thu-Af-Po4.05-20 [78]<br />
Comparative Analysis of Electromagnetic Characteristics<br />
for HTS Motor Considering PWM Schemes in Voltage<br />
Source Inverter<br />
Min Hyeok Kang, Eel-Hwan Kim, Sang Heon Chae, et al.<br />
Jeju National University, Korea<br />
Thu-Af-Po4.05-21 [79]<br />
A New Mover Separated Linear Magnetic-Field Modulated<br />
Motor With Improved Power Factor Using Auxiliary<br />
DC Exciting Windings<br />
Shiyuan Wang, Wenxiang Zhao and Jinghua Ji<br />
Jiangsu University, China<br />
Thu-Af-Po4.05-22 [80]<br />
Characteristic Analysis of Novel Outer Rotor Fan-type<br />
PMSM for Increasing Power Density<br />
Sooyoung Cho, Sang-hwan Ham and Ju Lee<br />
Hanyang University, Korea<br />
Thu-Af-Po4.05-23 [81]<br />
A Spoke-Type PM Vernier Machine with Multi Working<br />
Harmonics and Enhanced Flux Modulation Effect<br />
Tianjie Zou, Dawei Li and Ronghai Qu<br />
Huazhong University of Science and Technology, China<br />
Thu<br />
167
Thu<br />
Thu-Af-Po4.05-24 [82]<br />
Stress Analysis of Induction Motor Core Considering Rotational<br />
Magnetic Characteristics<br />
Tong Ben, Qingxin Yang, Rongge Yan, Lihua Zhu, et al.<br />
Hebei University of Technology, China<br />
Thu-Af-Po4.05-25 [83]<br />
Decoupling Control of Bearingless Permanent Magnet<br />
Synchronous Motor Using ANFIS Inverse System<br />
Huangqiu Zhu, Wei Du and Chenyin Zhao<br />
Jiangsu University, China<br />
Thu-Af-Po4.05-26 [84]<br />
Starting Control Strategy of Bearingless Permanent Magnet<br />
Synchronous Motor<br />
Wei Pan, Huangqiu Zhu, Xiaoyan Diao, et al.<br />
Jiangsu University, China<br />
Thu-Af-Po4.05-27 [85]<br />
Methodology of Incorporating Mechanical and Electromagnetic<br />
Characteristics Analysis for Separated Pole-<br />
Piece Type Ferrite Magnet Motor<br />
Won-ho Kim, Sung-gu Lee and Sung-hyuk Park<br />
Gachon University, Korea<br />
Thu-Af-Po4.05-28 [86]<br />
Structural Design Methodology of BLDC Motor Considering<br />
Response Time of Phase Current<br />
Wonseok Han, Sang-Yong Jung and Yong-Jae Kim<br />
Sungkyunkwan University, Korea<br />
Thu-Af-Po4.05-29 [87]<br />
Improvement of Reluctance Torque in Fault-Tolerant Permanent-Magnet<br />
Machines with Fractional-slot Concentrated-Windings<br />
Jinghua Ji, Xinxing Zhang and Wenxiang Zhao<br />
JiangSu University, China<br />
Thu-Af-Po4.05-30 [88]<br />
The Investigation of Cogging Torque Reduction Technologies<br />
Yc Kim and Ju Lee<br />
Hanyang University, Korea<br />
Thu-Af-Po4.05-31 [89]<br />
HEV Motor Comparison of IPMSM with Sintered Rare-<br />
Earth Mangnet and Bonded Dy Free Injection Magnet in<br />
the Same Size<br />
Yo Han Hwang, Jung Woo Park, Tae Hwan Kim, et al.<br />
Hanyang University, Korea<br />
168
Thu-Af-Po4.05-32 [90]<br />
A Study on the Auto-MTPT Algorithm to Make the Speedbased<br />
Current-map of IPMSM for Traction of Inwheel<br />
Yo Han Hwang, Gui Yeol Park, Jung Woo Park, et al.<br />
Hanyang University, Korea<br />
Thu-Af-Po4.05-33 [91]<br />
Direct Control of Bearingless Permanent Magnet Slice<br />
Motor Based on Flux Linkage Observer Using Phaselocked<br />
Loop<br />
Huangqiu Zhu, Zhuheng Zhao and Yuemei Qin<br />
[92]<br />
Thu-Af-Po4.05-34<br />
Quantitative Comparison of Embedded and Surfacemounted<br />
Magnetic Screws<br />
Zhijian Ling and Wenxiang Zhao<br />
Poster Session 4.06 13:45 - 15:30 Posters Area<br />
Generators<br />
Thu-Af-Po4.06-01 [93]<br />
Optimization of HTS coils for the design of a linear generator<br />
for maritime applications<br />
Adrian Gonzalez-parada and Marco Bianchetti<br />
University of Guanajuato, Mexico<br />
Thu-Af-Po4.06-02 [94]<br />
Core Loss Analysis of Permanent Magnet Linear Synchronous<br />
Generator with Slotless Stator<br />
Chang-Woo Kim, Jang-Young Choi, Min-Mo Koo, et al.<br />
Chungnam National University, Korea<br />
Thu-Af-Po4.06-03 [95]<br />
Optimization Design and Forecast Direct Control System<br />
Research on Bearingless Permanent Magnet Synchronous<br />
Generator<br />
Yamin Hu, Huangqiu Zhu and Chenyin Zhao<br />
Jiangsu University, China<br />
Thu-Af-Po4.06-04 [96]<br />
Improved Design and Characteristic Analysis of Permanent<br />
Magnet Synchronous Generator for Wind Power<br />
Generation with Fractional Slot and Integer Slot<br />
Gang-Hyeon Jang, Jang_Young Choi, et al.<br />
Chungnam National University, Korea<br />
Thu-Af-Po4.06-05 [97]<br />
Design and comparative analysis of MgB2 and YBCO<br />
wire-based superconducting wind power generators<br />
Gi-Dong Nam, Byeong-Soo Go, Hae-Jin Sung, et al.<br />
Changwon National University, Korea<br />
Thu<br />
169
Thu<br />
Thu-Af-Po4.06-06 [98]<br />
Electrical analysis for 15MW REBCO designed wind turbine<br />
generators<br />
Kiwook Yun, Masataka Iwakuma, Katsuhito Tamura, et al.<br />
Kyushu university<br />
Thu-Af-Po4.06-07 [99]<br />
Novel Control Strategy of Wave Energy Converter using<br />
Linear Permanent Magnet Synchronous Generator<br />
Ye Jun Oh, Ju Lee, Kyoung-jin Joo and Gang Seok Lee<br />
Hanyang University, Korea<br />
Thu-Af-Po4.06-08 [100]<br />
Design and Analysis of a Transverse Flux Hybrid Field<br />
Modulated Linear Generator for wave energy conversion<br />
Lei Huang, Minqiang Hu, Haitao Yu, Tao Xia, et al.<br />
Southeast University, China<br />
Thu-Af-Po4.06-09 [101]<br />
Research on an Asymmetric-primary Hybrid-excitation<br />
Maglev Axis-flux Generator for the Vertical Axis wind<br />
Turbine<br />
Lei Huang, Jing Liu and Weibo Zhong<br />
Southeast University, China<br />
Thu-Af-Po4.06-10 [102]<br />
A Two-dimensional Equivalent Mode of a Homopolar<br />
Synchronous Machine<br />
Jiangtao Yang, Caiyong Ye, Liang Xin and Wei Xu<br />
Thu-Af-Po4.06-11 [103]<br />
Heat load comparison of an HTS flux pump and a normal<br />
current lead in a module coil for a 12 MW wind power<br />
generator<br />
Oyunjargal Tuvdensuren, Tat Thang Le, et al.<br />
Changwon National University, Korea<br />
Thu-Af-Po4.06-12 [104]<br />
Magnetic field distribution prediction of a field-modulated<br />
tubular linear generator with quasi-Halbach magnetization<br />
for ocean wave energy conversion<br />
Tao Xia, Haitao Yu, Rong Guo, Xiaomei Liu, et al.<br />
School of Electrical Engineering, Southeast University, China<br />
Thu-Af-Po4.06-13 [105]<br />
Research on the linear tubular motor with multilayer<br />
flux-concentrating permanent magnets for direct-drive<br />
ocean wave conversion<br />
Tao Xia, Haitao Yu, Rong Guo, Xiaomei Liu, et al.<br />
School of Electrical Engineering, Southeast University, China<br />
170
Thu-Af-Po4.06-14 [106]<br />
Research on a field-modulated tubular linear generator<br />
with quasi-Halbach magnetization for ocean wave energy<br />
conversion<br />
Tao Xia, Haitao Yu, Rong Guo, Xiaomei Liu, et al.<br />
School of Electrical Engineering, Southeast University, China<br />
Thu-Af-Po4.06-15 [107]<br />
A Field Modulated Linear Permanent Magnet Generator<br />
for Direct-Drive Wave Energy Conversion<br />
Ningjun Feng, Haitao Yu, Rong Guo and Tao Xia<br />
Southeast University, China<br />
Thu-Af-Po4.06-16 [108]<br />
Design and Analysis of Marine Current Power Generation<br />
System Based on a Magnetic Gear<br />
Ningjun Feng, Haitao Yu, Rong Guo and Tao Xia<br />
Southeast University, China<br />
Thu-Af-Po4.06-17 [109]<br />
Design and thermal analysis of an HTS module coil for a<br />
12 MW wind power generator<br />
Tat Thang Le, Hae-jin Sung, Byeong-soo Go, et al.<br />
Changwon National University, Korea<br />
Poster Session 4.07 13:45 - 15:30 Posters Area<br />
Novel Applications<br />
Thu-Af-Po4.07-01 [110]<br />
Development of a low temperature superconducting<br />
magnet with MgB2 wire for a 10 kW DC induction furnace<br />
Chankyeong Lee, Jongho Choi, Sangho Cho, et al.<br />
Changwon National University, Korea<br />
Thu-Af-Po4.07-02 [111]<br />
Principle and realization of an electromagnetic pulse<br />
welding system with a dual-stage coil<br />
Fangxiong Deng, Quanliang Cao, Xiaotao Han, et al.<br />
China<br />
Thu-Af-Po4.07-03 [112]<br />
A Novel Design of Repetitive Transcranial Magnetic<br />
Stimulator with Monophasic and Biphasic Waveform<br />
Jinxin Zuo, Hongfa Ding and Xiao Fang<br />
Huazhong University of Science and Technology, China<br />
Thu-Af-Po4.07-04 [113]<br />
Design and Performance Study of a 1 MW Induction<br />
Heater with HTS DC magnet<br />
Ping Yang and Derong Qiu<br />
Shanghai Jiao Tong University, China<br />
Thu<br />
171
Thu<br />
Thu-Af-Po4.07-05 [114]<br />
A Method to Improve Forming Accuracy in Electromagnetic<br />
Forming of Sheet Metal Based on Field Shaper<br />
Qi Xiong, Hao Huang, Changzheng Deng, et al.<br />
China<br />
Thu-Af-Po4.07-06 [115]<br />
Polar transformed subdomain modeling for primary-segmented<br />
permanent magnet linear synchronous machine<br />
applied in tracked inspection robots<br />
Rong Guo, Haitao Yu, Xiaomei Liu, Weibo Zhong, et al.<br />
School of Electrical Engineering, Southeast University, China<br />
Thu-Af-Po4.07-07 [116]<br />
Development of Test Device for Aluminum Metal Melting<br />
by Electromagnetic Induction Heating Using HTS Coils<br />
Satoshi Fukui, Ryohei Ono, Jun Ogawa, Takao Sato, et al.<br />
Niigata University, Japan<br />
Thu-Af-Po4.07-08 [117]<br />
A high rotation speed big air-gap axial-flux eddy-current<br />
coupler for HTS flywheel energy storage system<br />
Wanjie Li and Guomin Zhang<br />
Institute of Electrical Engineering, CAS, China<br />
Thu-Af-Po4.07-09 [118]<br />
Improved Design of Klystron Beam Focusing System<br />
with Permanent Magnets<br />
Yasuhiro Fuwa and Yoshihisa Iwashita<br />
Kyoto University, Japan<br />
Thu-Af-Po4.07-10 [119]<br />
Analytical methodology for efficient design of pulsed<br />
electromagnetic blank holding system<br />
Zhipeng Lai, Quanliang Cao, Xiaotao Han, et al.<br />
Huazhong University of Science and Technology, China<br />
Thu-Af-Po4.07-11 [120]<br />
Excitation Effect Analysis of a Novel HTS Controllable<br />
Reactor with Orthogonally Configured Core Based on<br />
dynamic Inductance<br />
Zuoshuai Wang, Yuejin Tang, Li Ren, Sinian Yan, et al.<br />
Huazhong University of Science and Technology, China<br />
172
Poster Session 4.08 13:45 - 15:30 Posters Area<br />
ReBCO Conductors: Properties and Characterisation<br />
Thu-Af-Po4.08-01 [121]<br />
Pinning Force and critical properties in YBa2Cu3O7-δ<br />
Brahim Lmouden, Ahmed Taoufik, Ahmed Tirbiyine, et al.<br />
Ibn Zohr University, Faculty of Science, Agadir, Marocco<br />
Thu-Af-Po4.08-02 [122]<br />
Performance Degradation of YBCO Tapes after Suffering<br />
Lightning Impulse Current<br />
Daoyu Hu, Zhiyong Hong, Zhijian Jin and Zhuyong Li<br />
Shanghai Jiao Tong University, China<br />
Thu-Af-Po4.08-03 [123]<br />
The effect of compositional ratio of SmBCO coated conductor<br />
on the superconducting properties.<br />
Gwan-tae Kim, Ho-Sup Kim, Dong-Woo Ha, et al.<br />
Korea Electro-technology Research Institute, Korea<br />
Thu-Af-Po4.08-04 [124]<br />
Study on the Transport Current Properties for the 2G<br />
HTS Wire Under the Spray Cooling Method<br />
Ho Ik Du, Hyun Gi Jeong and Sung Chae Yang<br />
Chonbuk National University, Korea<br />
Thu-Af-Po4.08-05 [125]<br />
Temperature Evolution of Pinning Force in GdBaCuO<br />
Coated Conductors with Artificial Pinning Centers<br />
Igor Rudnev, Sergei Pokrovskii, et al.<br />
National Research Nuclear University MEPhI, Russia<br />
Thu-Af-Po4.08-06 [126]<br />
Transport properties of commercially available REBCO<br />
conductors at 4.2 K<br />
Kazuki Norimoto, Kiyosumi Tsuchiya, et al.<br />
Sophia University, Tokyo, Japan<br />
Thu-Af-Po4.08-07 [127]<br />
Bending-peeling method to measure interface strength<br />
of YBCO tape<br />
Peng Jin, Jiajun Liu, Lankai Li, Junsheng Cheng, et al.<br />
Tsinghua University, China<br />
Thu-Af-Po4.08-08 [128]<br />
Repair method of locally defective or damaged coated<br />
conductor using the superconducting patch<br />
Rock Kil Ko, No hyun Woo, Kim gwan Tae, et al.<br />
Korea Electrotechnology Research Institute, Korea<br />
Thu<br />
173
Thu<br />
Thu-Af-Po4.08-09 [129]<br />
Influence of picosecond and femtosecond laser impact<br />
on magnetic and transport characteristics of HTS tape<br />
Sergei Pokrovskii, Oleg Mavritskii, et al.<br />
National Research Nuclear University MEPhI, Russia<br />
Thu-Af-Po4.08-10 [130]<br />
Threshold value analysis of YBCO tapes under transient<br />
over-current impulse<br />
Shizhuo Liu, Dong Xia, Qingfeng Liu, et al.<br />
Institute of Electrical Engineering, CAS, China<br />
Thu-Af-Po4.08-11 [131]<br />
Enhancement of crystallinity and critical current properties<br />
of fluorine-free MOD processed YBCO films by introduction<br />
of oxyhalide Ba2Cu3O4X2 (X = Cl, Br)<br />
Takanori Motoki, Shuhei Ikeda, et al.<br />
Aoyama-Gakuin University, JST-ALCA, Japan<br />
Thu-Af-Po4.08-12 [132]<br />
Enhancement of in-field critical current density of Ba-<br />
ZrO3 added (Y, Gd)BCO coated conductors by reduced<br />
once-coat-layer-thickness in multi-coating TFA-MOD<br />
method<br />
Takumi Suzuki, Synsuke Oomura, et al.<br />
Kyushu University, Japan<br />
Thu-Af-Po4.08-13 [133]<br />
Effect of Background Magnetic Field on the Critical Current<br />
Degradation under Tensile Fatigue Loading for<br />
YBCO Tapes<br />
Xinsheng Yang, Chen Wei, Hy Zhang, Y Zhao, Qb Hao, et al.<br />
Southwest Jiaotong University, China<br />
Thu-Af-Po4.08-14 [134]<br />
The angular and Field Dependence of the Critical Current<br />
of commercial YBCO coated conductors<br />
Xiuchang Zhang, Jianzhao Geng, Chao Li, et al.<br />
University of Cambridge, United Kingdom<br />
Thu-Af-Po4.08-15 [135]<br />
Experimental Research on Out-of-plane Bending Characteristics<br />
of Critical Current for 2G Tapes<br />
Yinshun Wang<br />
North China Electric Power University, China<br />
Thu-Af-Po4.08-16 [136]<br />
Simulation of the delamination behaviors in the 2G HTS<br />
tape with consideration of thermal stress<br />
Yujie Duan, Yuanwen Gao and Youhe Zhou<br />
Key Lab. of Mechanics on Environment and Disaster, China<br />
174
Thu-Af-Po4.08-17 [137]<br />
Characterization of an internal cooling high temperature<br />
composite superconductor with REBCO for large scale<br />
energy storage applications<br />
Zhu Jiahui, Rao Shuangquan, Chen Panpan, et al.<br />
China Electric Power Research Institute, China<br />
Poster Session 4.09 13:45 - 15:30 Posters Area<br />
Quench Detection and Protection Systems<br />
Thu-Af-Po4.09-01 [138]<br />
An FPGA-based Quench Detector and Data Acquisition<br />
System for Superconducting Insertion Devices<br />
Chun-yi Wu, Chih-Yu Liao, Demi Lee, et al.<br />
National Synchrotron Radiation Research Center, Taiwan<br />
Thu-Af-Po4.09-02 [139]<br />
Quench Protection System for a 12-T dipole magnet<br />
Da Cheng, Tiina-Mari Salmi, Qingjin Xu, et al.<br />
IHEP, CAS, China<br />
Thu-Af-Po4.09-03 [140]<br />
Quench Protection of a Nb3Sn Superconducting Magnet<br />
System for a 45 GHz ECR Ion Source<br />
Emmanuele Ravaioli, Aurelio Hafalia, et al.<br />
LBNL, Berkeley, CA, USA<br />
Thu-Af-Po4.09-04 [141]<br />
New method for magnet protection systems based on a<br />
direct current derivative sensor<br />
Ernesto de Matteis, Daniel Calcoen, et al.<br />
Thu-Af-Po4.09-05 [142]<br />
Effects of metallic coatings on the thermal sensitivity of<br />
optical fiber sensors at cryogenic sensors<br />
Federico Scurti, Weston Straka, et al.<br />
North Carolina State University, USA<br />
Thu-Af-Po4.09-06 [143]<br />
Self-monitoring, SMART REBCO coated conductors<br />
Federico Scurti, Srivatsan Sathyamurthy, et al.<br />
North Carolina State University, USA<br />
Thu-Af-Po4.09-07 [144]<br />
Qualification of movement leading to quench in Nb3Sn<br />
coils by means of induced voltage, quench antenna and<br />
vibration measurements.<br />
Gerard Willering, Matthias Probst, et al.<br />
CERN, Geneva, Switzerland<br />
Thu<br />
175
Thu<br />
Thu-Af-Po4.09-08 [145]<br />
A novel quench detection method using radio frequency<br />
wave technology<br />
Hu Yanlan, Fu Peng and Zhu Congming<br />
Institute of Plasma Physics, CAS, China<br />
Thu-Af-Po4.09-09 [146]<br />
Design and Analysis of an Energy-Extraction System for<br />
High Current HTS Magnets<br />
Janne Ruuskanen, Jeroen van Nugteren, et al.<br />
Tampere University of Technology, Finland<br />
Thu-Af-Po4.09-10 [147]<br />
A fast 10 kA current switch for High Temperature Superconductor<br />
accelerator magnets<br />
Marco Statera, Francesco Broggi, Massimo Sorbi, et al.<br />
INFN Milano – LASA, Italy<br />
Thu-Af-Po4.09-11 [148]<br />
Study on the Quench Protection of the HTS magnet with<br />
iron core for a 1MW DC Induction Heater<br />
Ping Yang and Derong Qiu<br />
Shanghai Jiao Tong University, China<br />
Thu-Af-Po4.09-12 [149]<br />
24kA DC Energy Extraction Switch for LARP Magnet<br />
Testing at BNL<br />
Piyush Joshi, Paul Kovach, Michael Anerella, et al.<br />
BNL, Brookhaven National Laboratory, USA<br />
Thu-Af-Po4.09-13 [150]<br />
Partial isolation quench protection method for YBCO<br />
SMES magnet<br />
Qixing Sun<br />
University of Bath, Bath, United Kingdom<br />
Thu-Af-Po4.09-14 [151]<br />
Analytic Study of the Active Quench Detection Method<br />
for the HTS Magnet using Resonance circuit<br />
Seunghyun Song, Woo Seung Lee, Yojong Choi, et al.<br />
Electrical and Electronic Engin., Yonsei University, Korea<br />
Thu-Af-Po4.09-15 [152]<br />
Numerical and Experimental Evaluations of the Quench<br />
Detection Performance of NbTi/YBCO Hybrid Tape<br />
Shin Hasegawa, Satoshi Ito, et al.<br />
Tohoku University, Japan<br />
176
Thu-Af-Po4.09-16 [153]<br />
Quench Detection Performance of the Magnet Safety<br />
System for the inductively coupled KATRIN Source Magnets<br />
Woosik Gil, Guido Drexlin, Thomas Höhn, et al.<br />
KIT, Karlsruhe Institute of Technology, Germany<br />
Thu-Af-Po4.09-17 [154]<br />
Quench protection of an MgB2-based MDS magnet system<br />
Marc Dhallé, Chao Zhou, Giovanni Grasso, et al.<br />
University of Twente, Enschede, the Netherlands<br />
Thu-Af-Po4.09-18 [155]<br />
Experimental evaluation of computer-aided quench detection<br />
for the KSTAR CS Coil<br />
Yong Chu<br />
National Fusion Research Institute, Korea<br />
Thu-Af-Po4.09-19 [156]<br />
Quench and Recovery Characteristics of MgB2 Coil with<br />
Various Protection Schemes<br />
Young-gyun Kim, Haigun Lee, Yoon Hyuck Choi, et al.<br />
Dep. of Materials Sci.&Eng., Korea University, Korea<br />
Poster Session 4.10 13:45 - 15:30 Posters Area<br />
Magnetization and Field Quality<br />
Thu-Af-Po4.10-01<br />
[158]<br />
Reduction effect of irregular magnetic field due to<br />
screening-current in copper-plated mutifilamentary<br />
REBCO tape<br />
Atsushi Ishiyama, Yuichi Ozone, Hiroshi Ueda, et al.<br />
Waseda University, Yokyo, Japan<br />
Thu-Af-Po4.10-02 [159]<br />
Hall probe Calibration System Design for the Mu2e Solenoid<br />
Field Mapping System<br />
Charles Orozco, Jerzy Nogiec, Horst Friedsam, et al.<br />
FNAL, USA<br />
Thu-Af-Po4.10-03 [160]<br />
Novel Cavity Feature On Dipole Magnet Pole Face Improves<br />
Field Homogeneity While Reducing Coil Complexity<br />
Christopher Yeckel and Paul Holen<br />
Stangenes Industries, Palo Alto, USA<br />
Thu<br />
177
Thu<br />
Thu-Af-Po4.10-04 [161]<br />
Field Stabilization Method of the Persistent Current<br />
Mode Coil Made of 2G HTS tape at 77 K<br />
Derong Qiu, Zhuyong Li, Wei Wu, Zhen Huang, et al.<br />
Shanghai Jiao Tong University, China<br />
Thu-Af-Po4.10-05 [162]<br />
A field mapper for the determination of the multipole<br />
components of the curved HESR dipole magnets<br />
Jan Henry Hetzel, Jürgen Böker, Ulf Bechstedt, et al.<br />
Forschungszentrum Jülich GmbH, Germany<br />
Thu-Af-Po4.10-06 [163]<br />
Diffusion process of screening current in REBCO coil<br />
wound with copper-plated muti-filamentary REBCO tape<br />
Hiroshi Ueda, Atsushi Ishiyama, et al.<br />
Okayama University, Japan<br />
Thu-Af-Po4.10-07 [164]<br />
Influence of Soft Ferromagnetic Section on Trapped<br />
Field of High Temperature Superconducting Bulk Magnet<br />
used for linear motor application<br />
Junjie Tang, Jing Li, Guangtong Ma, Xiang Li, et al.<br />
Southwest Jiaotong University, China<br />
hu-Af-Po4.10-08 [165]<br />
Magnetic Field Measurement and Analysis of the<br />
CSNS/RCS Quadrupole Magnets<br />
Li Li<br />
Institute of High Energy Physics, China<br />
Thu-Af-Po4.10-09 [166]<br />
Waveform conditioning problems in high frequency<br />
magnetization of nanocrystalline alloys<br />
Long Chen, Wang Youhua, Hanyu Zhao, et al.<br />
Hebei University of Technology, China<br />
Thu-Af-Po4.10-10 [167]<br />
Numerical modelling of iron-pnictide bulk superconductor<br />
magnetization<br />
Mark Ainslie, Akiyasu Yamamoto, et al.<br />
University of Cambridge, United Kingdom<br />
Thu-Af-Po4.10-11 [168]<br />
Simulation of Screening Current Reduction Effect of External<br />
AC Magnetic Field on Multi-turn REBCO Pancake<br />
Coils<br />
So Noguchi, Ryosuke Miyao and Hajime Igarashi<br />
Hokkaido University/National High Magnetic Field Lab, Japan<br />
Thu-Af-Po4.10-12 [169]<br />
Mu2e Solenoid Field Mapping System Design<br />
Sandor Feher, James Grudzinski, Michael Lamm, et al.<br />
Fermi National Accelerator Laboratory, USA<br />
178
Thu-Af-Po4.10-13 [170]<br />
Numeric Analysis of the Rib geometry effect on multipole<br />
magnetic fields<br />
Seong Yeub Shim, Kalliopi Dermati, et al.<br />
GSI, Darmstadt, Germany<br />
Thu-Af-Po4.10-14 [171]<br />
Torque Maximization Method of Radial Magnetized Surface-Mounted<br />
PM Machine Having Sinusoidal Shaped<br />
Pole<br />
Shuangjiang Zhuang and Yang Shen<br />
Naval University of Engineering, China<br />
Thu-Af-Po4.10-15 [172]<br />
Field Mapping System for a 230 MeV Superconducting<br />
Cyclotron<br />
Ming Li, Yinlong Lv, Lei Cao, Tianjue Zhang, et al.<br />
China Institute of Atomic Energy, China<br />
Thu-Af-Po4.10-16 [173]<br />
A method based rotating coil to find magnetic center for<br />
series quadrupole magnets at IMP<br />
Jing Yang, Wenjie Yang, Qinggao Yao and Guozhu Cai<br />
Institute of Modern Physics, CAS, China<br />
Non-linear Magnetization Characteristic and Optimal Design<br />
of Iron-based superconducting Magnet for MRI<br />
Xiaoji Du, Jingye Zhang, Dong Zhang, et al.<br />
Institute of Electrical Engineering, CAS, China<br />
Thu-Af-Po4.10-18 [175]<br />
Influence of E-J characteristics of coated conductors<br />
and field ramp-up rates on the shielding-current-induced<br />
fields of magnets<br />
Yang Li, Yusuke Sogabe, Kikuchi Takashi, et al.<br />
Kyoto University, Japan<br />
Thu-Af-Po4.10-19 [176]<br />
Investigation on Optimal Third-order Harmonic Shaping<br />
Method for Parallel Magnetized Surface-Mounted PM Machine<br />
Yang Shen and Shuangjiang Zhuang<br />
Naval University of Engineering, China<br />
Thu-Af-Po4.10-20 [177]<br />
Feasibility Study on Mitigation of Screening Current-Induced<br />
Field in a Conduction-Cooled REBCO Magnet<br />
Young Jin Hwang, Jae Young Jang, et al.<br />
Korea Basic Science Institute, Korea<br />
Thu<br />
179
Thu<br />
Thu-Af-Po4.10-21 [178]<br />
Reduction of the screening current field in HTS coils<br />
wound by using Soldering-Stacked-Square (3S) REBCO<br />
wires<br />
Zhuyong Li, Fei Gu, Daoyu Hu, Timing Qu, et al.<br />
Jiaotong-universiteit van Shanghai, China<br />
Poster Session 4.11 13:45 - 15:30 Posters Area<br />
Novel Diagnostics<br />
Thu-Af-Po4.11-01 [179]<br />
New Bridge Temperature Sensor for Superconducting<br />
Magnets and other Cryogenic Applications<br />
Alexey Dudarev, Johan Bremer, Tim Mulder, et al.<br />
CERN, Geneva, Switzerland<br />
Thu-Af-Po4.11-02 [180]<br />
Locating Electrical Faults in Superconducting Accelerator<br />
Magnets<br />
Andrzej Stafiniak and Grzegorz Bezuik<br />
Wroclaw University of Technology, Poland<br />
Thu-Af-Po4.11-03 [181]<br />
A set of equipment for measuring and investigating the<br />
magnetic field at the reference magnet of the NICA<br />
booster<br />
Ivan Okunev, Alexander Batrakov, et al.<br />
BINP SB RAS, Russia<br />
Thu-Af-Po4.11-04 [182]<br />
Design of dipole magnet integral measurement system<br />
for HTPTF<br />
Jun Yang, Hui Liang, Wei Chen and Bin Qin<br />
Huazhong University of Science and Technology, China<br />
Thu-Af-Po4.11-05 [183]<br />
A device for characterizing the circumferential strain dependence<br />
of the critical current in MgB2 wires and tapes<br />
Mario Kazazi, Christophe Berriaud, et al.<br />
CEA, Saclay, France<br />
Thu-Af-Po4.11-06 [184]<br />
A Preliminary Design of a Test Facility for testing 20 kA<br />
Nb3Sn Cables in a Magnetic Field up to 15 T that is<br />
cooled using Small Cryogenic Coolers<br />
Michael Green and Heng Pan<br />
LBNL & FRIB/MSU, USA<br />
180
Thu-Af-Po4.11-07 [185]<br />
Conceptual Design of a Large Aperture Dipole for Testing<br />
of Cables and Insert Coils at High Field<br />
Pierluigi Bruzzone, Francesca Cau, et al.<br />
EPFL-SPC, Lausanne, Switzerland<br />
Thu-Af-Po4.11-08 [186]<br />
Electrical Field Generation by Hall Effect in High Field<br />
No-Insulation REBCO Pancake Coils<br />
So Noguchi, Seungyong Hahn and Atsushi Ishiyama<br />
Thu-Af-Po4.11-09 [187]<br />
Delamination Diagnostic Method of REBCO Tapes Using<br />
Ultrasonic Waves<br />
Takahiro Tomitsuka, Yuta Sakamaki, et al.<br />
Meiji University, Japan<br />
Thu-Af-Po4.11-10 [188]<br />
The Mu2e Solenoid Cold Mass Position Monitor System<br />
Sandor Feher, Horst Friedsam, Michael Lamm, et al.<br />
Fermi National Accelerator Laboratory, USA<br />
Thu-Af-Po4.11-11 [189]<br />
Accurate Measurement of the Superconducting Current<br />
in 2G HTS Coil with Rogowski coil in Cryogenic Environment<br />
Shuqian Huang and Wei Wang<br />
Sichuan University, Chengdu, China<br />
Thu-Af-Po4.11-12 [190]<br />
Design and manufacture of Solenoid center deviation<br />
measurement device<br />
Xi Wu<br />
Institute of High Energy Physics, China<br />
Thu-Af-Po4.11-13 [191]<br />
A multifunction test facility of cryogenic-electro-magneto-<br />
mechanical properties for superconducting<br />
wires/tapes under multi-fields<br />
Xingzhe Wang, Youhe Zhou and Mingzhi Guan<br />
Thu<br />
181
Thu<br />
Plenary Session 7 16:00 - 16:40 Auditorium<br />
Superconducting Generators for Wind Power<br />
Session Chairs: Hitoshi Kitaguchi and Mathias Noe<br />
Thu-Af-Pl7-01 16:00<br />
Development of a Superconductive Wind Power Generator<br />
within the EcoSwing project<br />
Juergen Kellers<br />
ECO 5 GmbH, Germany<br />
Plenary Session 8 16:40 - 17:20 Auditorium<br />
Magnets for High Energy Physics<br />
Session Chairs: Hitoshi Kitaguchi and Mathias Noe<br />
Thu-Af-Pl8-01 16:40<br />
High Field Accelerator Magnets: a Path to New Physics<br />
Luca Bottura<br />
CERN, Geneva, Switzerland<br />
Plenary Session 9 17:20 - 18:00 Auditorium<br />
Conference Closing<br />
Thu-Af-Pl9-01 17:20<br />
Best Posters Awards<br />
Arjan Verweij (Program Chair)<br />
CERN, Geneva, Switzerland<br />
Thu-Af-Pl9-02 17:30<br />
<strong>MT25</strong> Conference Data<br />
Thu-Af-Pl9-03 17:40<br />
Introduction to MT26 in Vancouver<br />
Thu-Af-Pl9-04 17:50<br />
Technical Visits, Banquet and Closing of <strong>MT25</strong><br />
182
Boat tour 18:00 – 19:30 Amsterdam<br />
Boat Tour from RAI Conference Center to Martime Museum.<br />
Departure from the backside of the convention center.<br />
Conference Banquet 19:30 – 22:00<br />
National Maritime Museum.<br />
Friday, September 1, 2017<br />
Technical visits<br />
Technical Visits, busses leave RAI Parking P6 at 8:30<br />
Visit 1<br />
Visit 2<br />
Visit 3<br />
Visit 4<br />
Visit 5<br />
NIKHEF, Amsterdam and 08:30 – 12:30<br />
Science Park in Amsterdam<br />
ESTEC, Noordwijk 08:30 – 13:00<br />
Philips Healthcare, Best 08:30 – 18:00<br />
DIFFER, Eindhoven<br />
HFML and FELIX 08:30 – 17:30<br />
at the Radboud University, Nijmegen<br />
University of Twente, Enschede 08:30 – 18:30<br />
Fri<br />
183
Author list (First authors only!)<br />
Aabid, Fouad<br />
Po2.10-04<br />
Abatal, Mohamed Po3.09-05<br />
Abdel-Maksoud, Walid Or4-04<br />
Abdyukhanov, Ildar Po3.09-06<br />
Abin, Dmitry<br />
Po1.03-01<br />
Adkins, Todd<br />
Or27-06<br />
Ahn, Hee-jae<br />
Or3-04<br />
Ahn, Ji-hun<br />
Po3.05-02, Po3.05-03, Po3.07-01<br />
Ahn, Min Cheol<br />
Po1.03-06, Po2.05-07<br />
Ahn, Hanwoong<br />
Po3.05-17<br />
Ai, Liwang<br />
Po1.05-04<br />
Ainslie, Mark<br />
Po4.10-10<br />
Akhmeteli, Andrey Po2.04-01<br />
Alafnan, Hamoud Po3.07-05<br />
Alazki, Hussain<br />
Po3.09-05<br />
Amann, John<br />
Po2.02-09<br />
Ambrosio, Giorgio Po1.01-04, Or23-05<br />
Amemiya, Naoyuki Or18-03<br />
Amoskov, Victor Po4.02-15<br />
Arbelaez, Diego<br />
Or7-03<br />
Auchmann, Bernhard Or7-06, Or33-03<br />
Avronsart, Julien Po3.09-07<br />
Awaji, Satoshi<br />
Or31-06<br />
Badcock, Rodney Po2.11-01<br />
Badgley, Karie<br />
Or16-01<br />
Baghdadi, Mehdi Po3.05-12<br />
Bagni, Tommaso Or9-05, Po3.11-13,<br />
Po3.11-14, Po3.11-15<br />
Baikalov, Andrei Or26.06<br />
Bainbridge, Alexander Or19-06<br />
Bajas, Hugo<br />
Po1.10-07, Or23-03<br />
Ball, Steven<br />
Po1.03-08<br />
Ballarino, Amalia Pl3-01, Or23-05<br />
Bang, Tae-kyoung Po3.08-16<br />
Banno, Nobuya<br />
Po1.08-09<br />
Baranov, Grigory Po4.03-06<br />
Barbier, Romain Po1.12-09<br />
Barzi, Emanuela<br />
Or30-04<br />
Bauer, Markus<br />
Or14-01, Or17-05<br />
Bednarek, Mateusz Jakub Po4.01-05<br />
Bellesia, Boris<br />
Po3.02-04<br />
Belyaev, Artem<br />
Po3.02-02<br />
Belyakov, Valery Po4.02-15<br />
Ben, Tong<br />
Po4.05-24<br />
Benkel, Tara<br />
Or31-07<br />
Bergen, Anne<br />
Or9-03<br />
Berriaud, Christophe Po1.10-04<br />
Berrospe-Juarez, Edgar Po3.12-03<br />
184
Bhattarai, Kabindra Or12-06<br />
Bian, Fangfang<br />
Po1.04-04, Po1.04-05<br />
Bielert, Erwin Roland Po1.02-06<br />
Bigot, Bernard<br />
Pl2-01<br />
Bilbao Gutierrez, Mikel Po2.09-12<br />
Bilyi, Dmytro<br />
Po3.06-02<br />
Bird, Mark<br />
Or2-03<br />
Birnkammer, Florian Po3.12-04<br />
Boebinger, Greg Pl5-01<br />
Boffo, Cristian<br />
Po1.02-04, Or10-01, Or25-05<br />
Bolei, Jia<br />
Po2.05-03<br />
Bonito Oliva, Alessandro Or13-01<br />
Bonne, François<br />
Po2.03-03<br />
Borisov, Vladimir Po2.01-10<br />
Bortot, Lorenzo<br />
Po2.10-09<br />
Bosque, Ernesto Or33-05<br />
Bottura, Luca<br />
Or1-07, Pl8-01<br />
Bourcey, Nicolas Po3.01-10<br />
Bragin, Alexey<br />
Or10-04<br />
Braidotti, Enrico Po1.12-04<br />
Breitschopf, Jeff Po4.03-07<br />
Breschi, Marco<br />
Po1.01-08, Po3.04-08, Po3.12-11<br />
Brindza, Paul<br />
Po1.02-09<br />
Brouwer, Lucas<br />
Po2.10-10<br />
Brower, Lucas<br />
Or33-07<br />
Bruzzone, Pierluigi Or22-05, Po4.11-07<br />
Bumby, Chris<br />
Or29-03<br />
Béard, Jérôme<br />
Or27-03<br />
Calzolaio, Ciro<br />
Po3.11-02<br />
Cao, Quanliang<br />
Po3.07-13, Po3.08-12<br />
Carrillo, David<br />
Or15-03<br />
Casalbuoni, Sara Or10-02<br />
Cau, Francesca<br />
Po4.02-02<br />
Chan, Wan Kan<br />
Or9-02, Po3.09-13<br />
Charifoulline, Zinour Po1.09-22<br />
Chavanne, Joel<br />
Or19-05<br />
Chen, Panpan<br />
Po1.10-11<br />
Chen, Yuan<br />
Po4.01-12<br />
Chen, Wei<br />
Po3.04-14<br />
Chen, Wenge<br />
Or2-02<br />
Chen, Yuquan<br />
Po4.01-13<br />
Chen, Junquan<br />
Po4.05-13<br />
Chen, Long<br />
Po4.10-09<br />
Chen, S.d.<br />
Po4.03-09<br />
Chen, Hao<br />
Po1.04-06, Po1.04-07, Po1.04-08,<br />
Po1.04-09, Po1.04-10, Po2.06-12,<br />
Po3.05-04, Po3.05-05<br />
Chen, Jingping<br />
Po1.08-05<br />
Chen, Qian<br />
Po1.04-26<br />
Chen, Chuan<br />
Po1.08-02<br />
185
Chen, Hung-chiao<br />
Chen, Meng<br />
Chen, Lei<br />
Chen, Yunyun<br />
Cheng, Da<br />
Cheng, Junsheng<br />
Cheng, Daniel<br />
Ching, T.W.<br />
Chiuchiolo, Antonella<br />
Chlachidze, Guram<br />
Cho, Sooyoung<br />
Cho, Suyeon<br />
Choi, Hyewon<br />
Choi, Kyeongdal<br />
Choi, Jongho<br />
Choi, Jang-young<br />
Choi, Yoon Hyuck<br />
Chu, Yun-liang<br />
Chu, Yong<br />
Chung, Yoon Do<br />
Ciazynski, Daniel<br />
Citadini, James<br />
Clarke, Neil<br />
Clayton, Nicholas<br />
Collings, Ted<br />
Consogno, Guido<br />
Coombs, Tim<br />
Cosson, Olivier<br />
Cui, Ying Min<br />
Cui, Chunyan<br />
Curreli, Sebi<br />
D'amico, Gabriele<br />
Dael, Antoine<br />
Dai, Qi<br />
Dai, Chao<br />
Dai, Rui<br />
Dai, Shaotao<br />
Dai, Yinming<br />
Daly, Michael<br />
Dao, Van Quan<br />
Davies, Timothy<br />
Davis, Sam<br />
De Matteis, Ernesto<br />
De Rijk, Gijs<br />
Decool, Patrick<br />
Degtyarenko, Pavel<br />
Demikhov, Timophey<br />
Den Ouden, Andries<br />
Deng, Le<br />
Deng, Fangxiong<br />
Po2.12-01<br />
Po3.08-10<br />
Po1.06-04, Po2.07-13<br />
Po3.05-25<br />
Po4.09-02<br />
Po2.05-05<br />
Or23-01<br />
Po1.05-07, Po3.05-19<br />
Or23-03<br />
Or23-02<br />
Po3.05-17, Po3.05-18, Po4.05-22<br />
Po1.07-13<br />
Po2.07-08<br />
Po2.06-19, Po3.12-09<br />
Or11-01<br />
Po3.08-04<br />
Po1.10-14<br />
Or10-03<br />
Po4.09-18<br />
Po2.11-11, Po2.12-07<br />
Po2.03-02<br />
Po2.02-07<br />
Po1.11-02<br />
Po3.10-18<br />
Po1.08-10<br />
Po1.09-09<br />
Po2.11-08<br />
Po2.02-15, Po2.04-13<br />
Po3.03-09<br />
Po1.05-02<br />
Po1.09-16<br />
Po4.02-03<br />
Po4.04-01<br />
Po2.12-10<br />
Po3.09-03, Po3.09-04<br />
Po2.10-06<br />
Po1.07-11<br />
Po3.03-10<br />
Or3-03<br />
Po1.07-14<br />
Po1.09-18<br />
Or4-01<br />
Po4.09-04<br />
Or1-01<br />
Po3.02-11<br />
Or17-04<br />
Or20-07<br />
Po1.09-03<br />
Po1.06-03<br />
Po4.07-02<br />
186
Deng, Changdong Or10-05<br />
Dhallé, Marc<br />
Or9-03, Po3.07-02, Po4.09-17<br />
Di Zenobio, Aldo Po1.09-02<br />
Diao, Xiaoyan<br />
Po1.05-08, Po2.06-37<br />
Difan, Zhou<br />
Or9-04<br />
Dijkstra, Dorus<br />
Po3.07-02<br />
Ding, Kaizhong<br />
Po1.09-12<br />
Ding, Hongfa<br />
Po1.12-13, Po1.12-18<br />
Ding, Yi<br />
Po4.03-12<br />
Ding, Tonghai<br />
Po1.12-11<br />
Dioguardi, Francesco Po1.11-03<br />
Dominguez Martinez, M.A. Or19-02<br />
Dong, Kun<br />
Po3.03-03, Po3.09-09<br />
Du, Yi<br />
Po2.06-39, Po2.06-40<br />
Du, Xiaoji<br />
Po4.10-17<br />
Du, Wei<br />
Po4.05-25<br />
Du, Ho Ik<br />
Po4.08-04<br />
Duan, Nana<br />
Po3.09-10<br />
Duan, Yujie<br />
Po4.08-16<br />
Dudarev, Alexey Po1.02-01, Po4.11-01<br />
Durante, Maria<br />
Po3.03-05<br />
Elshiekh, Mariam Po2.07-16<br />
Encheva, Anna<br />
Or13-06<br />
Enomoto, Shun<br />
Po2.01-09<br />
Fabbricatore, Pasquale Or1-06<br />
Fang, Chao<br />
Po3.10-01<br />
Fang, Xiao<br />
Po3.04-15<br />
Fang, Chunhua<br />
Po1.09-05<br />
Feher, Sandor<br />
Or25-06, Po4.10-12, Po4.11-10<br />
Felice, Helene<br />
Po2.01-03<br />
Feng, Ningjun<br />
Po4.06-15, Po4.06-16<br />
Ferradas Troitino, Jose Po4.01-04<br />
Field, Michael<br />
Or30-01<br />
Fietz, Walter H.<br />
Po2.08-12<br />
Fiscarelli, Lucio<br />
Po1.01-06, Po1.01-07<br />
Foussat, Arnaud Po1.01-01<br />
Fu, Shanshan<br />
Po2.08-07<br />
Fujishiro, Hiroyuki Po2.09-06<br />
Fujiyama, Sho<br />
Po2.03-08<br />
Fukui, Satoshi<br />
Po4.07-07<br />
Fukumoto, Yusuke Po2.07-28<br />
Fuwa, Yasuhiro<br />
Po3.10-19, Po4.07-09<br />
Gao, Yuting<br />
Po2.06-07<br />
Gao, Yuanwen<br />
Or3-01<br />
García-Matos, Jesús A. Or1-04<br />
Gastineau, Bernard Po1.02-03<br />
Gavrilin, Andrey<br />
Po1.10-01, Po2.04-01<br />
Ge, Meng<br />
Po1.04-24<br />
Geng, Jianzhao<br />
Po2.11-06, Po2.11-07<br />
Gil, Woosik<br />
Po4.09-16<br />
187
Gilgrass, Graham Or20-01<br />
Go, Byeong-soo<br />
Po3.06-01, Po3.08-02<br />
Gonzalez-Parada, Adrian Po4.06-01<br />
Gradt, Thomas<br />
Po3.10-17<br />
Grau, Andreas<br />
Po4.03-01<br />
Green, Michael<br />
Or24-06, Po4.11-06<br />
Grimley, Carolyn Po1.09-04<br />
Guan, Mingzhi<br />
Or15-05, Po2.09-13<br />
Guo, Siyu<br />
Po2.06-30<br />
Guo, Rong<br />
Po1.04-27, Po3.05-15, Po3.05-16,<br />
Po3.06-10, Po4.06-12, Po4.06-13,<br />
Po4.06-14, Po4.06-15, Po4.06-16,<br />
Po4.07-06<br />
Gupta, Ramesh<br />
Or25-03, Or28-05<br />
Gyuráki, Roland<br />
Or12-01<br />
Gömöry, Fedor<br />
Or18-06<br />
Hahn, Seungyong Or9-01<br />
Haifei, Ding<br />
Po2.06-08<br />
Han, Ke<br />
Po3.10-09, Or32-07<br />
Han, Wonseok<br />
Po3.05-22, Po4.05-28<br />
Han, Tae-hee<br />
Po2.07-25<br />
Han, Seunghak<br />
Po2.09-15<br />
Han, Houxiang<br />
Po3.02-08<br />
Han, Jung-ho<br />
Po4.05-11<br />
Hao, Li<br />
Po4.05-17, Po4.05-18<br />
Hasegawa, Shin<br />
Po4.09-15<br />
Heller, Reinhard<br />
Po1.09-15<br />
Hemmi, Tsutomu Po2.09-17, Po3.02-12<br />
Hetzel, Jan Henry Po4.10-05<br />
Higashikawa, Kohei Po2.08-06<br />
Hild, Romain<br />
Po2.10-12<br />
Hilton, David K.<br />
Or9-06<br />
Hishinuma, Yoshimitsu Po1.08-15<br />
Holik, Eddie<br />
Or23-06<br />
Holm, Mikael<br />
Po1.08-08<br />
Hou, Yanbing<br />
Po3.11-17<br />
Hu, Yamin<br />
Po4.06-03<br />
Hu, Qingyu<br />
Po3.11-09<br />
Hu, Xinning<br />
Or14-05<br />
Hu, Daoyu<br />
Po4.08-02<br />
Hu, Qiang<br />
Po2.09-14, Po4.03-08<br />
Huang, Xiongyi<br />
Po3.10-18<br />
Huang, Hailin<br />
Po2.06-11<br />
Huang, Wenmei<br />
Po2.10-14<br />
Huang, Yawei<br />
Po4.02-16<br />
Huang, Yalan<br />
Po1.06-09<br />
Huang, Zhen<br />
Po1.10-17<br />
Huang, Lantao<br />
Po1.07-08, Po1.07-09<br />
Huang, Shuqian<br />
Po4.11-11<br />
Huang, Yongheng Po1.12-12, Po1.12-13<br />
188
Huang, Lei<br />
Huang, Chen<br />
Huang, Jianfeng<br />
Huang, Taotao<br />
Huang, Yujie<br />
Hwang, Young Jin<br />
Hwang, Seonho<br />
Hwang, Yo Han<br />
Hyeon, Chang Ju<br />
Ide, Momoe<br />
Iguchi, Masahide<br />
Ikeda, Kenichi<br />
Ilyin, Y.<br />
Imagawa, Shinsaku<br />
Ishida, Keisuke<br />
Ishiyama, Atsushi<br />
Ito, Satoshi<br />
Ito, Tetsuya<br />
Ivashov, Ilia<br />
Iwai, Sadanori<br />
Izquierdo Bermudez, S.<br />
Jae Young, Jang<br />
Jang, Jae Young<br />
Jang, Gang-hyeon<br />
Jeon, Haeryong<br />
Jeong, Geochul<br />
Jeong, In-sung<br />
Ji, Jinghua<br />
Jia, Bolei<br />
Jiahui, Zhu<br />
Jiang, Jiaming<br />
Jiang, Junjie<br />
Jiang, Chengxi<br />
Jiang, Yapeng<br />
Jiang, Zhenan<br />
Jiang, Zhe<br />
Jimenez, Marc<br />
Jin, Shi<br />
Jin, Chang-sung<br />
Jin, Xinzhe<br />
Jin, Huan<br />
Jin, Peng<br />
Jing, Libing<br />
Jing, Shi<br />
Jo, Young-sik<br />
Jo, Hyun Chul<br />
Jo, Younjung<br />
Johnstone, Adam<br />
Po2.06-25, Po4.06-08, Po4.06-09<br />
Po2.07-04<br />
Or26-04<br />
Po1.02-05<br />
Po3.08-23<br />
Po2.12-08, Po4.10-20<br />
Po2.07-20<br />
Po4.05-31, Po4.05-32<br />
Po3.05-06, Po3.11-01<br />
Po1.10-10<br />
Po3.02-10<br />
Po2.06-18<br />
Or26-02<br />
Or13-03, Po2.08-08<br />
Po3.07-10<br />
Po4.10-01<br />
Or26-03<br />
Po3.12-15<br />
Po4.02-06<br />
Or18-05, Or20-04, Po3.03-06<br />
Po1.01-10, Or23-04<br />
Po2.10-08<br />
Po1.03-02<br />
Po3.08-04, Po4.06-04<br />
Po2.11-04<br />
Po2.06-09, Po2.10-05<br />
Po1.07-04<br />
Po4.05-29<br />
Po3.04-02<br />
Po4.08-17<br />
Po1.07-05, Po2.06-15, Po4.05-12<br />
Or24-02<br />
Po1.12-01<br />
Po3.12-17<br />
Or29-03<br />
Po2.07-29<br />
Po2.09-10<br />
Or8-06, Po3.06-04<br />
Po1.04-01, Po1.04-02<br />
Or32-01<br />
Po3.10-06<br />
Po4.08-07<br />
Po4.05-19<br />
Po1.06-05<br />
Po3.11-18<br />
Po2.01-04<br />
Po3.09-15<br />
Po1.11-01<br />
189
Joo, Kyoung-jin<br />
Po1.04-22, Po1.04-23, Po2.06-20,<br />
Po3.07-11, Po4.05-15, Po4.05-16,<br />
Po4.06-07<br />
Joshi, Piyush<br />
Or24-03, Po4.09-12<br />
Juchno, Mariusz Po1.01-09<br />
Jun, Hyun-woo<br />
Po1.07-03<br />
Jun, Byung-hyuk Or17-06<br />
Jung, Dong-hoon Po1.04-18, Po1.04-19<br />
Jung, Sang-yong Po1.04-33, Po4.05-08, Po4.05-09<br />
Jung, Soo-jin<br />
Po1.04-30<br />
Jung, Byung Ik<br />
Po2.07-02<br />
Juster, Francois-paul Po1.09-07<br />
Kahn, Stephen<br />
Po4.01-08<br />
Kai, Zhang<br />
Po1.01-12, Po3.01-13<br />
Kajikawa, Kazuhiro Po3.12-08<br />
Kajitani, Hideki<br />
Po3.02-07<br />
Kamada, Hiroharu Po1.06-01<br />
Kan, Changtao<br />
Po3.12-02<br />
Kang, Min Hyeok Po4.05-20<br />
Kang, Dong-woo Po4.05-05, Po4.05-06<br />
Kang, Wen<br />
Or10-05<br />
Kang, Hyoungku Po3.10-05, Po3.10-12<br />
Karashima, Tomoharu Po2.06-33<br />
Kario, Anna<br />
Or21-01<br />
Karpov, Sergey<br />
Po1.12-10<br />
Kato, Masahiro<br />
Po2.09-11<br />
Kawabata, Shuma Po3.12-12<br />
Kawashima, Takeshi Po4.04-10<br />
Kazazi, Mario<br />
Po4.11-05<br />
Kellers, Juergen<br />
Pl7-01<br />
Khodzhibagiyan, Hamlet Or16-05<br />
Kim, Seokbeom<br />
Po2.05-09, Po3.11-12<br />
Kim, Seokho<br />
Po1.11-04, Po3.11-05<br />
Kim, Su Yong<br />
Po1.06-08, Po2.06-31<br />
Kim, Junseong<br />
Po2.05-04<br />
Kim, Sung-kyu<br />
Po1.07-12<br />
Kim, Su-hun<br />
Po1.11-11, Po4.01-10<br />
Kim, Sung-jin<br />
Po1.04-32<br />
Kim, Kwangmin<br />
Po1.10-08, Or31-03<br />
Kim, Jun Beom<br />
Po2.07-12<br />
Kim, Myung Su<br />
Po1.09-14<br />
Kim, A-rong<br />
Po3.09-01<br />
Kim, Hee-jun<br />
Po3.08-14<br />
Kim, Woo-seok<br />
Po2.05-10, Po2.06-19, Po3.06-11<br />
Kim, Hyungjun<br />
Po1.09-10<br />
Kim, Hyung-wook Po3.11-04<br />
Kim, Chang-hyun Po3.07-11<br />
Kim, Won-ho<br />
Po1.04-38, Po1.04-39, Po4.05-27<br />
Kim, Jaemin<br />
Or25-04<br />
Kim, Ji Hyung<br />
Po1.04-14<br />
190
Kim, Young-gyun<br />
Kim, Chang-woo<br />
Kim, Jae-chul<br />
Kim, Ho Min<br />
Kim, Young Sun<br />
Kim, Gwan-tae<br />
Kim, Jin-seok<br />
Kim, Yc<br />
Kim, Jimin<br />
Kim, Jiman<br />
Kirby, Glyn<br />
Kiss, Takanobu<br />
Klimenko, Evgeny<br />
Ko, Rock Kil<br />
Ko, Rakkyung<br />
Koizumi, Norikiyo<br />
Kokkinos, Charilaos<br />
Kong, Yong<br />
Koratzinos, M<br />
Kosse, Jaap<br />
Kovacs, Chris<br />
Kováč, Pavol<br />
Koyanagi, Kei<br />
Kozub, Sergey<br />
Krave, Steve<br />
Kulenkampff, Tobias<br />
Kuo, Cheng-ying<br />
Kwon, Ik-soo<br />
Kühlkamp, Wouter<br />
Lackner, Friedrich<br />
Lai, Zhipeng<br />
Lannou, Hervé<br />
Larbalestier, David<br />
Le, Dinh-vuong<br />
Le, Tat Thang<br />
Le Coz, Quentin<br />
Lee, Onyou<br />
Lee, Hongseok<br />
Lee, Kidoek<br />
Lee, Sung Gu<br />
Lee, Hyunjung<br />
Lee, Jeong-in<br />
Lee, Tae-yong<br />
Lee, Shin-won<br />
Lee, Sang Heon<br />
Lee, Sang-taek<br />
Po1.10-15, Or32-05,<br />
Po4.04-13, Po4.09-19<br />
Po3.05-02, Po3.05-03,<br />
Po3.07-01, Po4.06-02<br />
Po2.07-11<br />
Po3.11-01<br />
Po2.12-03<br />
Po4.08-03<br />
Po1.04-16, Po2.06-16,<br />
Po2.06-17, Po2.07-11<br />
Po4.05-30<br />
Po3.11-06<br />
Po1.08-04, Po1.09-11<br />
Or1-01, Po2.01-05, Or31-02<br />
Or17-02<br />
Po4.02-01<br />
Po3.11-10, Po4.08-08<br />
Po1.05-06<br />
Or13-02, Po2.03-06<br />
Po3.01-02, Po3.01-03<br />
Po2.06-41<br />
Po3.01-09<br />
Po3.07-06<br />
Po1.08-01, Po2.08-01<br />
Or30-07<br />
Or5-06<br />
Po4.03-10<br />
Po4.01-09<br />
Po1.02-10<br />
Or10-03, Po2.12-01,<br />
Po4.03-03, Po4.03-04<br />
Po2.12-02<br />
Po4.09-17<br />
Po1.01-03<br />
Po4.07-10<br />
Po4.04-05<br />
Or30-06<br />
Or11-05<br />
Po4.06-17<br />
Po2.03-07<br />
Po3.10-12<br />
Po3.10-05<br />
Po3.05-08, Po3.05-09, Po4.05-14<br />
Po1.04-31, Po2.06-32<br />
Po4.02-05<br />
Po3.08-07<br />
Po1.04-33, Po1.04-34<br />
Po2.07-21<br />
Po3.10-14<br />
Po3.08-14<br />
191
Lee, Sanggap<br />
Lee, Bang-wook<br />
Lee, Jeyull<br />
Lee, Chankyeong<br />
Lee, Woo Seung<br />
Lee, Seyeon<br />
Lee, Jae-kwang<br />
Lee, Kang Won<br />
Lee, Jiho<br />
Lee, Jae-jun<br />
Lelekhov, Sergey<br />
Li, Zhuyong<br />
Li, Yang<br />
Li, Wenlong<br />
Li, Yafang<br />
Li, Jianwei<br />
Li, Yi<br />
Li, Wanjie<br />
Li, Zhenhua<br />
Li, Yan<br />
Li, Liang<br />
Li, Li<br />
Li, Dawei<br />
Li, Xiang<br />
Li, Rui<br />
Li, Chao<br />
Li, Nian<br />
Li, Junjie<br />
Li, Jian<br />
Li, Ming<br />
Li, Xiaoxiang<br />
Liang, Qing<br />
Liang, Ming<br />
Liang, Fei<br />
Liang, Xin<br />
Liang, Chen<br />
Liang, Siyuan<br />
Libeyre, Paul<br />
Lifeng, Bai<br />
Lim, Jongsuk<br />
Lim, Sung-hun<br />
Lim, Jae-woo<br />
Lin, Feng<br />
Lin, Andy<br />
Lin, Mengxuan<br />
Lin, Xiaodong<br />
Ling, Zhijian<br />
Liu, Jianhua<br />
Liu, Tong<br />
Or5-04<br />
Po2.12-02<br />
Po2.11-05, Po4.01-03<br />
Po4.07-01<br />
Po1.11-12, Po2.11-10<br />
Po2.05-10<br />
Po1.04-11, Po1.04-12,<br />
Po4.05-10, Po4.05-11<br />
Po2.12-03<br />
Po1.03-03<br />
Po1.04-12, Po4.05-10<br />
Po4.02-12<br />
Po2.08-15, Po4.10-21<br />
Po4.10-18<br />
Po1.04-28, Po3.05-19<br />
Po2.10-14<br />
Po3.07-07, Po3.07-08<br />
Or31-01<br />
Po4.07-08<br />
Or29-02<br />
Po2.08-14<br />
Or27-02<br />
Po4.10-08<br />
Po2.06-07, Po4.05-04<br />
Po2.06-35<br />
Po1.04-28<br />
Po2.07-03, Po2.11-07, Or16-06<br />
Po2.06-28<br />
Po1.11-06<br />
Po1.04-15<br />
Po4.10-15<br />
Po1.07-16<br />
Po1.11-10<br />
Po3.10-11<br />
Po2.10-03<br />
Po3.06-14<br />
Po2.07-05<br />
Po2.07-23<br />
Or13-05<br />
Po2.04-02<br />
Po1.04-17, Po1.04-18, Po1.04-19<br />
Po2.07-24<br />
Po3.08-06<br />
Po3.06-03<br />
Or6-05<br />
Po1.04-25<br />
Po3.07-14<br />
Po1.07-17, Po4.05-34<br />
Or5-05<br />
Po1.04-36<br />
192
Liu, Hongwei<br />
Liu, Kai<br />
Liu, Xiaomei<br />
Liu, Shizhuo<br />
Liu, Mengyu<br />
Liu, Qiang<br />
Liu, Yichen<br />
Liu, Xinbo<br />
Liu, Jie<br />
Liu, Chengcheng<br />
Liu, Yingzhen<br />
Liu, Ning<br />
Liu, Kun<br />
Liu, Jianwei<br />
Liu, Guangwei<br />
Liu, Aimin<br />
Liu, Yang<br />
Liu, Jing<br />
Liu, Guohai<br />
Lmouden, Brahim<br />
Lombardo, Vito<br />
Lorin, Clement<br />
Lou, Jiachuan<br />
Louzguiti, Alexandre<br />
Lu, Jun<br />
Lv, Yiliang<br />
Lysenko, Valeriy<br />
Ma, Lizhen<br />
Ma, Guangtong<br />
Ma, Tao<br />
Ma, Jun<br />
Maciejewski, Michal<br />
Madur, Arnaud<br />
Majoros, Milan<br />
Mao, Zhehua<br />
Marchevsky, Maxim<br />
Marinozzi, Vittorio<br />
Mariotto, Samuele<br />
Marjanovič, Jan<br />
Marshall, William<br />
Marteau, Fabrice<br />
Martovetsky, Nicolai<br />
Marushin, Egor<br />
Matsumoto, Akiyoshi<br />
Matsuo, Ryuta<br />
Mcintyre, Peter<br />
Melhem, Ziad<br />
Mendez, Rossi<br />
Po3.12-06<br />
Or8-02<br />
Po3.05-15, Po3.05-16<br />
Po4.08-10<br />
Po1.11-07<br />
Po2.06-29<br />
Po1.05-09<br />
Po2.06-38<br />
Po2.02-08<br />
Po2.06-04<br />
Or14-04<br />
Po3.08-12<br />
Po1.05-03<br />
Po1.08-03, Pl3-02<br />
Or8-03, Po2.10-06, Po3.06-04,<br />
Po3.06-05, Po3.06-06, Po3.12-05<br />
Po2.06-02<br />
Po2.04-06<br />
Po3.07-09<br />
Po2.06-10<br />
Po4.08-01<br />
Po1.08-12<br />
Or6-02, Po3.01-05<br />
Po2.06-14<br />
Or4-05<br />
Or32-03<br />
Po2.04-15<br />
Po4.04-11<br />
Po1.10-09<br />
Or8-01<br />
Po2.07-26<br />
Po1.03-04, Po2.03-04<br />
Or33-03<br />
Po2.01-01, Po3.08-01<br />
Po3.11-07, Po3.11-08, Po4.04-08<br />
Po3.09-16<br />
Or3-06<br />
Or6-04<br />
Po4.01-06<br />
Po1.12-04<br />
Or5-02<br />
Po2.02-05<br />
Or26-05<br />
Po3.02-06<br />
Po1.09-01<br />
Or24-05<br />
Po2.05-08, Po3.01-11, Or28-06,<br />
Po4.03-07, Po4.04-09<br />
Or29-05<br />
Or29-07<br />
193
Meng, Liao<br />
Mentink, Matthias<br />
Michael, Philip<br />
Mierau, Anna<br />
Milanese, Attilio<br />
Mitrofanova, Iuliia<br />
Miura, Osuke<br />
Miura, Hideaki<br />
Miyao, Ryosuke<br />
Miyazaki, Hiroshi<br />
Miyazoe, Akihisa<br />
Mizuno, Shinya<br />
Morozov, Ivan<br />
Mortensen, Anders<br />
Motoki, Takanori<br />
Muehle, Carsten<br />
Mulder, Tim<br />
Munilla, Javier<br />
Murakami, Akira<br />
Murakami, Haruyuki<br />
Muratore, Joseph F<br />
Murayama, Masamichi<br />
Murtomäki, Jaakko S.<br />
Musenich, Riccardo<br />
Nakamoto, Mio<br />
Nakamura, Kazuya<br />
Nakashima, Takayoshi<br />
Nam, Gi-dong<br />
Nam, Seokho<br />
Nazir, Aamir<br />
Neri, Martina<br />
Nguyen, Doan<br />
Ni, Dongsheng<br />
Nicollet, Sylvie<br />
Nikolo, Martin<br />
Nilsson, Emelie<br />
Nishijima, Gen<br />
Niu, Rongmei<br />
Noguchi, So<br />
Nomura, Shinichi<br />
Norcia, Gabriella<br />
Norimoto, Kazuki<br />
Noyes, Patrick<br />
Nunio, François<br />
Ogawa, Jun<br />
Oh, Se-young<br />
Oh, Ye Jun<br />
Oh, Sangjun<br />
Ohuchi, Norihito<br />
Po1.06-05<br />
Or12-04, Or15-06<br />
Or29-01<br />
Po4.03-02<br />
Or19-01<br />
Po1.11-05<br />
Po3.07-12<br />
Po4.04-06<br />
Po1.10-12, Po3.11-11, Po4.10-11<br />
Or20-04<br />
Po3.03-01<br />
Po1.06-07<br />
Po2.02-06<br />
Or29-06<br />
Po4.08-11<br />
Po2.02-02<br />
Or17-01, Or21-05<br />
Po3.04-04<br />
Po2.09-01<br />
Or4-02<br />
Po1.01-05<br />
Po1.12-08<br />
Or32-02<br />
Or11-03<br />
Po2.03-06<br />
Po2.03-08<br />
Or30-05<br />
Po4.06-05<br />
Po2.07-18, Po2.07-19<br />
Po2.06-01<br />
Po1.02-08<br />
Po2.04-03, Or27-01<br />
Po1.09-06<br />
Po4.02-13<br />
Po3.10-10<br />
Po2.01-02<br />
Or5-03<br />
Po3.10-13<br />
Po1.10-12, Po3.12-13,<br />
Po4.10-11, Po4.11-08<br />
Po3.04-12<br />
Po4.04-04<br />
Po4.08-06<br />
Or15-01<br />
Po2.09-03<br />
Po3.09-08, Po3.12-07<br />
Po3.05-18<br />
Po4.05-15, Po4.06-07<br />
Po4.02-11<br />
Po1.11-09<br />
194
Oki, Soichiro<br />
Po3.12-14<br />
Okunev, Ivan<br />
Po4.11-03<br />
Orozco, Charles<br />
Po4.10-02<br />
Osipov, Maxim<br />
Po1.05-05<br />
Otto, Alexander<br />
Po3.09-02, Or31-04, Or32-04<br />
Oya, Masayoshi<br />
Or20-05<br />
Ozeki, Hidemasa Or13-04<br />
P. Silva, Helder F. Po1.02-07<br />
Painter, Thomas Or31-03<br />
Pan, Yunhao<br />
Po1.09-21<br />
Pan, Wei<br />
Po1.04-37, Po4.05-26<br />
Pan, Xifeng<br />
Po1.08-02<br />
Pan, Heng<br />
Po2.09-05, Po2.10-07, Or33-01<br />
Pantoja, Andres<br />
Po2.11-01, Po2.11-02, Po2.11-03<br />
Papathanasiou, Dimitrios Po1.12-03<br />
Parizh, Michael<br />
Or20-02<br />
Park, Sang Ho<br />
Po3.06-11<br />
Park, Heecheol<br />
Po1.11-04<br />
Park, Dongkeun<br />
Po2.05-01, Po2.05-02, Po4.04-03<br />
Park, Gyeong-jae Po4.05-09<br />
Park, Gyeong Jae Po4.05-08<br />
Park, Sunghyuk<br />
Po1.04-39<br />
Park, Eui-jong<br />
Po3.07-03, Po3.07-04<br />
Park, Noa<br />
Po1.07-10<br />
Pasquet, Raphael Po3.08-13<br />
Patel, Jay<br />
Po1.04-13<br />
Pei, Xiaoze<br />
Po2.07-27<br />
Peijnenburg, Ton Or14-03<br />
Peluso, Bertrand Po3.02-03<br />
Peng, Xuan<br />
Or30-02<br />
Peng, Tao<br />
Po2.04-14, Or27-02<br />
Pengbo, Zhou<br />
Po2.12-09<br />
Pes, Chhon<br />
Po3.08-03<br />
Pi, Wei<br />
Po1.10-13, Po2.08-13<br />
Picker, Rüdiger<br />
Or25-02<br />
Piec, Zbigniew<br />
Po2.03-10<br />
Pierro, Federica<br />
Po2.08-03<br />
Pokrovskii, Sergei Po4.08-09<br />
Polli, Gian Mario Or4-03<br />
Pooke, Donald<br />
Po1.02-05<br />
Porhiel, Amaury<br />
Po1.02-02<br />
Post, Cornelius<br />
Po1.12-02<br />
Pradhan, Subrata Po3.09-12<br />
Prause, Burkhard Pl3-04<br />
Prestemon, Soren Or28-04<br />
Pugnat, Pierre<br />
Or2-01<br />
Pulikowski, Dariusz Po3.01-06<br />
Qian, Maofei<br />
Po2.02-12<br />
Qiao, Xin<br />
Po1.11-13<br />
Qin, Xing<br />
Po1.08-13<br />
195
Qin, Bin<br />
Po3.04-01<br />
Qin, Jinggang<br />
Po2.08-04, Po2.08-05, Po3.10-07<br />
Qin, Yuemei<br />
Po1.05-11, Po1.05-12, Po1.05-13,<br />
Po3.07-15, Po4.05-33<br />
Qiu, Qingquan<br />
Po2.07-17, Po3.08-11<br />
Qiu, Derong<br />
Po2.07-06, Po4.10-04<br />
Qiu, Li<br />
Or11-04, Po3.08-09<br />
Quach, Huu Luong Po3.05-06<br />
Quettier, Lionel<br />
Or20-03<br />
Radcliff, Kyle<br />
Po1.03-05<br />
Ravaioli, Emmanuele Or24-01, Or33-01, Po4.09-03<br />
Reccia, Luigi<br />
Po3.02-09<br />
Ren, Xiang<br />
Po4.05-04<br />
Ren, Yu<br />
Po1.11-14<br />
Ren, Li<br />
Po2.07-14, Po3.12-10<br />
Roccella, Selanna Po3.10-15<br />
Rochepault, Etienne Po1.01-02, Po3.01-07, Po3.01-08<br />
Rodriguez Mateos, Felix Or15-03<br />
Rossi, Lucio<br />
Or28-01<br />
Rottländer, Peter Po2.02-16<br />
Rudnev, Igor<br />
Po4.08-05<br />
Ruuskanen, Janne Po4.09-09<br />
Sabbatini, Lucia<br />
Po2.02-11<br />
Sagawa, Shintaro Po2.08-09<br />
Sakamoto, Hisaki Pl3-03<br />
Salmi, Tiina<br />
Or12-03<br />
Sang-yong, Jung Po2.06-16<br />
Sangyong, Park<br />
Po2.12-04<br />
Sarasola, Xabier Po2.03-09<br />
Savary, Frederic<br />
Or7-01<br />
Savoldi, Laura<br />
Po4.02-07<br />
Scheuerlein, Christian Po3.10-03<br />
Schillaci, Francesco Or19-03, Or22-03, Or33-02<br />
Schneider-Muntau, Hans Or33-06<br />
Scurti, Federico<br />
Or15-02, Po4.09-05, Po4.09-06<br />
Sedlak, Kamil<br />
Po2.03-05<br />
Selvamanickam, Venkat Or17-03<br />
Seo, Myung-ki<br />
Po2.06-26, Po2.06-27<br />
Seo, Sung-won<br />
Po3.06-12, Po3.06-13<br />
Seo, Sanghyeok<br />
Po2.06-26<br />
Seok, Jihoon<br />
Po3.11-05<br />
Sgobba, Stefano Po3.10-16<br />
Shen, Boyang<br />
Po3.12-01<br />
Shen, Yang<br />
Po4.10-19<br />
Shengqian, Jiang Po2.07-10<br />
Shi, Chaojie<br />
Or8-05, Po2.06-03<br />
Shi, Jiangtao<br />
Po1.12-05<br />
Shim, Seong Yeub Po4.10-13<br />
Shimoyama, Jun-ichi Po3.10-08<br />
196
Shin, Kyung-hun<br />
Shin, Hyung-seop<br />
Shin, Kanghwan<br />
Shizuya, Eiji<br />
Sogabe, Yusuke<br />
Sohn, Myung-hwan<br />
Soltner, Helmut<br />
Son, Hyun Hee<br />
Song, Honghai<br />
Song, Jung-bin<br />
Song, Seunghyun<br />
Sorbi, Massimo<br />
Speed, Jonathan David<br />
Stafiniak, Andrzej<br />
Statera, Marco<br />
Stenvall, Antti Aleksis<br />
Stepanov, Boris<br />
Storey, James<br />
Stoynev, Stoyan<br />
Strauss, Thomas<br />
Suetomi, Yu<br />
Sugano, Michinaka<br />
Sugimoto, Masahiro<br />
Sumption, Mike<br />
Sun, Eric<br />
Sun, Qixing<br />
Sun, Linyu<br />
Sun, Liangting<br />
Sun, Quqin<br />
Sun, Jiuce<br />
Sung, Hae-jin<br />
Sung-hun, Lim<br />
Suwa, Tomone<br />
Suzuki, Takumi<br />
Suzuki, Kento<br />
Ta, Wurui<br />
Takahashi, Keita<br />
Takahashi, Kohki<br />
Takao, Tomoaki<br />
Takayama, Teruou<br />
Takayanagi, Tomohiro<br />
Takeda, Yasuaki<br />
Tamura, Hitoshi<br />
Tang, Junjie<br />
Tang, Shixiang<br />
Tani, Norio<br />
Ten Kate, Herman<br />
Tock, Jean-Philippe<br />
Po2.06-21, Po2.06-22, Po2.06-23,<br />
Po2.06-24, Po3.05-10, Po3.05-11,<br />
Po3.06-08, Po3.06-09<br />
Po2.09-07<br />
Po2.05-06<br />
Or15-04<br />
Po3.12-19, Po4.01-14<br />
Po1.03-07<br />
Po4.10-05<br />
Po3.11-03<br />
Or18-04<br />
Po2.09-08<br />
Po3.09-11, Po4.09-14<br />
Or1-05<br />
Po2.02-10<br />
Po1.12-02, Po4.11-02<br />
Po4.09-10<br />
Or32-06<br />
Po3.02-05, Or26-05<br />
Po2.11-02<br />
Or23-02<br />
Po1.01-04, Or7-05, Po4.11-10<br />
Po1.10-16<br />
Or1-02, Po2.01-08<br />
Po1.08-07<br />
Or18-01, Or20-06, Or21-04<br />
Po1.10-05<br />
Po4.09-13<br />
Po2.04-12<br />
Or16-03<br />
Or3-05<br />
Or29-04<br />
Or14-02<br />
Po2.07-15<br />
Po1.08-11<br />
Po4.08-12<br />
Po2.01-06, Po3.03-02<br />
Or3-02<br />
Po2.09-09<br />
Po1.09-13<br />
Po3.11-16<br />
Po2.10-13<br />
Or10-06<br />
Po3.09-14<br />
Po4.02-04<br />
Po4.10-07<br />
Po1.09-05<br />
Po2.02-14<br />
Or25-01<br />
Or1-07<br />
197
Todesco, Ezio<br />
Or1-03<br />
Tomarchio, Valerio Po4.02-14<br />
Tomassetti, Giordano Po3.10-04<br />
Tominaga, Naoki Po2.10-11<br />
Tomita, Masaru<br />
Po1.06-06<br />
Tomitsuka, Takahiro Po4.11-09<br />
Tomkow, Lukasz Po2.01-07<br />
Tommasini, Davide Or28-02<br />
Tomsic, Michael<br />
Po4.04-07<br />
Tong, Yujin<br />
Or12-02<br />
Toral, Fernando<br />
Or1-04, Or6-03, Or19-02<br />
Toth, Jack<br />
Or27-05<br />
Trociewitz, Ulf<br />
Or31-05<br />
Trophime, Christophe Po2.10-01<br />
Tsoupas, Nicholaos Po3.04-10<br />
Tsurudome, Takehisa Po1.09-17<br />
Turtu', Simonetta Po2.08-10<br />
Tuvdensuren, Oyunjargal Po4.06-11<br />
Twin, Andrew<br />
Or33-04<br />
Ueda, Hiroshi<br />
Po4.10-06<br />
Ueki, Toru<br />
Po2.09-16<br />
Ueno, Takeshi<br />
Po2.05-11<br />
Uglietti, Davide<br />
Po2.08-02, Or22-06<br />
Usoskin, Alexander Or28-01<br />
Valesi, Giovanni<br />
Po1.09-08<br />
Valiyaparambil Abdulsalam, Anvar Or21-03, Or26-01<br />
Vallcorba, Roser Po4.02-10<br />
Vallerand, Cynthia Po2.02-04<br />
Vallone, Giorgio<br />
Or3-07, Po2.09-04<br />
Van Der Laan, Danko Or21-02<br />
Van Eck, Hans<br />
Or22-04<br />
Van Lieshout, Lou Po1.12-07<br />
Van Nugteren, Jeroen Po2.01-05, Or24-04,<br />
Or31-02, Po4.01-02<br />
Vannozzi, A.<br />
Po2.02-01<br />
Velev, Gueorgui<br />
Or7-05<br />
Verweij, Arjan<br />
Po1.09-22<br />
Vrankovic, Vjeran Po2.02-03, Po2.02-17<br />
Wang, Hongliang Po1.04-15<br />
Wang, Xiaorong<br />
Or6-05<br />
Wang, Xingzhe<br />
Or12-02, Po4.11-13<br />
Wang, Zhen<br />
Po3.07-16<br />
Wang, Bangzhu<br />
Po2.07-01<br />
Wang, Bao-sheng Po1.12-14<br />
Wang, Hao<br />
Po3.06-05<br />
Wang, Chengtao Po3.01-04<br />
Wang, Yawei<br />
Po3.12-18<br />
Wang, Yibai<br />
Po3.08-22<br />
Wang, Yinshun<br />
Po4.08-15<br />
Wang, Chuan<br />
Po3.04-03<br />
198
Wang, Zuoshuai<br />
Wang, Tao<br />
Wang, Shiyuan<br />
Wang, Tianlong<br />
Wang, Qiuliang<br />
Wang, Qingyan<br />
Wang, Wei<br />
Wang, Lei<br />
Warren, David<br />
Watanabe, Tomonori<br />
Wei, Shaoqing<br />
Weijers, H.w.<br />
Weiss, Jeremy<br />
Weng, Ling<br />
Wesche, Rainer<br />
Wijnen, Frans<br />
Willering, Gerard<br />
Witte, Holger<br />
Wolf, Felix Josef<br />
Won, Junhui<br />
Wong, Yongseng<br />
Wouters, Christina<br />
Wu, Wei<br />
Wu, Xi<br />
Wu, Yu<br />
Wu, Cheng<br />
Wu, Jiawei<br />
Wu, Wenye<br />
Wu, Beimin<br />
Wu, Chun-yi<br />
Xia, Dong<br />
Xia, Tao<br />
Xia, Zhong<br />
Xiao, Houxiu<br />
Xie, Jianfeng<br />
Xin, Liang<br />
Xiong, Qi<br />
Xu, Miaofu<br />
Xu, Meimei<br />
Xu, Yun<br />
Xu, Qingjin<br />
Xu, Da<br />
Xu, Wei<br />
Xu, Bo<br />
Xu, Shoufeng<br />
Xu, Aihua<br />
Xu, Jieping<br />
Xu, Dan-ping<br />
Po1.06-10, Po2.12-10, Po4.07-11<br />
Po3.03-07<br />
Po1.04-29, Po4.05-21<br />
Po3.08-11<br />
Po1.11-10, Po4.08-07<br />
Po2.12-05<br />
Po2.11-09, Po4.11-11<br />
Po3.03-04<br />
Po1.11-02<br />
Po3.08-17<br />
Po4.01-07<br />
Po2.04-05<br />
Po2.07-09<br />
Po2.12-06<br />
Po4.02-09<br />
Or2-04, Po2.04-04<br />
Po1.10-06, Or7-02,<br />
Or28-03, Po4.09-07<br />
Po4.01-01<br />
Po2.09-02<br />
Po1.04-22, Po1.04-23<br />
Po1.12-14<br />
Po2.02-03<br />
Or16-02<br />
Po4.11-12<br />
Po3.02-13, Or22-02<br />
Po3.10-02<br />
Po1.07-06<br />
Po3.05-20, Po3.05-21<br />
Po2.09-13<br />
Po4.09-01<br />
Po2.07-07<br />
Po4.06-12, Po4.06-13, Po4.06-14<br />
Po3.12-10<br />
Po2.04-06, Po2.04-07, Po2.04-08,<br />
Po2.04-09, Po2.04-10, Po2.04-11<br />
Po3.08-08<br />
Po4.06-10<br />
Or11-02, Po4.07-05<br />
Po1.11-08<br />
Po3.05-13, Po3.05-14<br />
Po1.12-15, Po1.12-16, Po1.12-17<br />
Or6-01<br />
Po1.04-03<br />
Po2.06-34, Po2.06-35, Po2.06-36<br />
Po3.05-01<br />
Po3.08-15<br />
Po2.03-01<br />
Po4.03-12<br />
Po2.10-02, Po4.05-02, Po4.05-03<br />
199
Yagai, Tsuyoshi<br />
Po2.08-11<br />
Yagotintsev, Konstantin Or18-02, Or21-06<br />
Yan, Sinian<br />
Po2.07-22<br />
Yan, Rongge<br />
Po2.12-06<br />
Yan Rongge, Yan Rongge Po3.08-21<br />
Yanagisawa, Yoshinori Po1.09-20, Or5-01<br />
Yang, Ping<br />
Po4.07-04, Po4.09-11<br />
Yang, Chin-kang Po4.03-03<br />
Yang, Chih-sheng Po4.03-05<br />
Yang, Wenjiang<br />
Po1.07-15<br />
Yang, Wenrong<br />
Po3.08-18<br />
Yang, Wenjie<br />
Po2.01-11, Po4.10-16<br />
Yang, Jing<br />
Po4.10-16<br />
Yang, Ye<br />
Po3.01-12, Po4.01-11<br />
Yang, Tongjun<br />
Or16-04<br />
Yang, Jiangtao<br />
Po4.06-10<br />
Yang, Hui<br />
Po2.06-15, Po4.05-12<br />
Yang, Xinsheng<br />
Po4.08-13<br />
Yang, Jun<br />
Po4.11-04<br />
Yang, Xiaorui<br />
Po3.08-19, Po3.08-20<br />
Yanlan, Hu<br />
Po4.09-08<br />
Yao, Tian<br />
Po1.04-35<br />
Ye, Caiyong<br />
Po3.06-14<br />
Yeckel, Christopher Po4.10-03<br />
Yin, Shijian<br />
Po3.09-13<br />
Yokoyama, Kazuya Po1.07-07<br />
Yoo, Byeong-ha<br />
Po4.04-02<br />
Yoon, Sangwon<br />
Po2.05-06<br />
Yoshida, Jun<br />
Po3.04-05<br />
Yoshimoto, Masahiro Po2.02-13<br />
Yoshiyuki, Iwata Pl4-01<br />
Yu, In-keun<br />
Or11-05<br />
Yu, Siyang<br />
Po3.06-06<br />
Yu, Hui<br />
Po1.07-02<br />
Yuan, Xi<br />
Po3.03-08<br />
Yun, Kiwook<br />
Po4.06-06<br />
Zani, Louis<br />
Po4.02-08<br />
Zanino, Roberto<br />
Or12-05<br />
Zhai, Yuhu<br />
Po4.02-18, Po4.02-19<br />
Zhang, Yue<br />
Or8-04, Or8-06<br />
Zhang, Jing<br />
Po3.06-07<br />
Zhang, Zhifeng<br />
Po2.07-30<br />
Zhang, Shaozhe<br />
Po3.04-11<br />
Zhang, Jingye<br />
Po1.06-02<br />
Zhang, Zhan<br />
Po1.01-11<br />
Zhang, Xinxing<br />
Po4.05-29<br />
Zhang, Xiuchang Po4.08-14<br />
Zhang, Fengge<br />
Po3.12-05, Po4.05-07<br />
Zhang, Yi<br />
Po4.02-17<br />
Zhang, Miao<br />
Po3.04-09<br />
200
Zhang, Dong<br />
Zhang, Tianjue<br />
Zhang, Hang<br />
Zhang, Yong<br />
Zhang, Ke<br />
Zhao, Anfeng<br />
Zhao, Yong<br />
Zhao, Zhangfei<br />
Zhao, Chenyin<br />
Zheng, Jinxing<br />
Zheng, Junqiang<br />
Zheng, Shijun<br />
Zheng, Yali<br />
Zherlitsyn, S.<br />
Zhihong, Liu<br />
Zhong, Weibo<br />
Zhou, Luncai<br />
Zhou, Chao<br />
Zhou, Jun<br />
Zhou, Huawei<br />
Zhou, Wei<br />
Zhu, Xuhui<br />
Zhu, Yingshun<br />
Zhu, Zixuan<br />
Zhu, Huangqiu<br />
Zhu, Jian<br />
Zhuang, Shuangjiang<br />
Zickler, Thomas<br />
Zlobin, Alexander<br />
Zou, Tianjie<br />
Zubko, Vasily<br />
Zuo, Jinxin<br />
Po1.07-01<br />
Po3.04-13, Po4.10-15<br />
Po3.08-05<br />
Po1.05-10, Po1.11-14<br />
Po1.08-06<br />
Po1.10-02, Po1.10-03<br />
Po1.08-14<br />
Po1.12-18, Po1.12-19<br />
Po1.05-01, Po2.06-05, Po2.06-06,<br />
Po4.05-01, Po4.06-03<br />
Or22-01<br />
Po1.04-20, Po1.04-21, Po3.05-07<br />
Po1.10-09<br />
Po3.06-15, Po4.04-12<br />
Or27-04<br />
Po3.04-06<br />
Po3.06-10<br />
Po3.04-07<br />
Or30-03<br />
Po1.12-06<br />
Po2.06-13<br />
Po3.12-16<br />
Po3.05-23, Po3.05-24<br />
Or19-04<br />
Po2.08-16, Po3.12-20<br />
Po1.05-01, Po1.05-12, Po1.05-13,<br />
Po2.06-05, Po2.06-06, Po2.06-08,<br />
Po3.07-15, Po4.05-01, Po4.05-25,<br />
Po4.05-33<br />
Po3.05-24<br />
Po4.10-14<br />
Po4.03-11<br />
Or7-04, Po3.01-01<br />
Po4.05-23<br />
Po1.09-19<br />
Po4.07-03<br />
201
NOTES<br />
202