1. Introduction - Firenze University Press

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LV large value, maximum difference between real and approximated supplies NDi positive differences between the real and approximated supplies over time-interval i, W m -2 NI number of time-intervals NTS number of Time Slices PDi positive differences between the real and approximated supplies over time-interval i, W m -2 RSi real supply irradiation over time-interval i, W m -2 SDi supply difference over time-interval i, W m -2 t time, h TA ambient air temperature, °C TC average internal fluid temperature, °C tend ending time of the heat demand, h ti time period boundary of time-interval i, h Tin inlet temperature for collectors, °C Tout outlet temperature for collectors, °C TS Time Slice TS supply temperature of streams, °C TSi Time Slice boundary, h tstart starting time of the heat demand, h TT target temperature of streams, °C yi binary variable, selection as to whether the time period boundary is a TS boundary z objective function zI first-stage objective function zII second-stage objective function tolerance, % 0 optical efficiency of the collector, % efficiency of the collector, % C Acknowledgements Financial support is gratefully acknowledged from the EC FP7 project "Intensified Heat Transfer Technologies for Enhanced Heat Recovery - INTHEAT", Grant Agreement No. 262205 and Társadalmi Megújulás Operatív Program (TÁMOP-4.2.2/B-10/1-2010-0025). References [1] Gude VG, Nirmalakhandan N, Deng S. Desalination using solar energy: Towards sustainability. Energy 2011; 36: 78 – 85. [2] Chaabene M, Annabi M. Dynamic thermal model for predicting solar plant adequate energy management. Energy Conversion and Management 1998; 39: 349 – 355. [3] GeoModel Solar s.r.o. ; 2011 [Accessed 28/9/2011]. [4] KGA Associates, ; 2011 [Accessed 28/9/2011]. 311
[5] Erdil E, Ilkan M, Egelioglu F. An experimental study on energy generation with a photovoltaic (PV)– solar thermal hybrid system. Energy 2008; 33: 1241– 1245. [6] Mawire A, McPherson M, van den Heetkamp RRJ. Simulated energy and exergy analyses of the charging of an oil–pebble bed thermal energy storage system for a solar cooker. Solar Energy Materials & Solar Cells 2008; 92: 1668–1676. [7] Kemp IC, Deakin AW. The Cascade Analysis for Energy and Process Integration of Batch Processes, Part 1: Calculation of Energy Targets. Chem Eng & D 1989; 67: 495-509. [8] Klemeš J, Linnhoff B, Kotjabasakis E, Zhelev TK, Gremouti I, Kaliventzeff B, et al. Design and Operation of Energy Efficient Batch Processes, EC Project EURO BATCH Final Report, EC Brussels; 1994. [9] Zhao XG, O’Neill BK, Roach JR, Wood RM, Heat integration for batch processes Part 1: Process Scheduling Based on Cascade Analysis. Trans IChemE 1998; 76: 685 – 699. [10] Zhao XG, O’Neill BK, Roach JR, Wood RM. Heat integration for batch processes Part 2: Heat Exchanger Network Design. Trans IChemE 1998; 76: 700 – 710. [11] Adonyi R, Romero J, Puigjaner L, Friedler F. Incorporating heat integration in batch process scheduling. Applied Thermal Engineering 2003; 23: 1743–1762. [12] Pourali O, Amidpour M, Rashtchian D., Time decomposition in batch process integration, Chemical Engineering and Processing 2006; 45: 14 – 21. [13] Majozi T. Minimization of energy use in multipurpose batch plants using heat storage: an aspect of cleaner production. Journal of Cleaner Production, 2009; 17: 945 – 950. [14] Foo DCY, Chew YH, Lee CT. Minimum units targeting and network evolution for batch heat exchanger network, Applied Thermal Engineering, 2008; 28: 2089-2099. [15] Varbanov P, Klemeš J. 2010, Total Sites Integrating Renewables with Extended Heat Transfer and Recovery. Heat Transfer Engineering, 31(9), 733-741. [16] Friedler F. Process integration, modelling and optimisation for energy saving and pollution reduction, Chemical Engineering Transactions 2009; 18: 1-26. [17] Friedler F. Process integration, modelling and optimisation for energy saving and pollution reduction. Applied Thermal Engineering 2010; 30: 2270-2280. [18] Muster-Slawitsch B, Weiss W, Schnitzer H, Brunner C. The green brewery concept e Energy efficiency and the use of renewable energy sources in breweries. Applied Thermal Engineering 2011, 31, 2123-2134. [19] Ludig S, Haller M, Schmid E, Bauer N. Fluctuating renewables in a long-term climate change mitigation strategy. Energy 2011, 36 (11) 6674-6685 [20] European Commission, [Accessed: 23/08/2011]. [21] Xi C, Hongxing Y, Lin L, Jinggang W, Liu W. Experimental studies on a ground coupled heat pump with solar thermal collectors for space heating. Energy 2011; 36: 5292 – 5300. [22] Atkins MJ, Walmsley MRW, Morrison AS. Integration of solar thermal for improved energy efficiency in low-temperature-pinch industrial processes. Energy2010; 35: 1867 – 1873. [23] Townsend DW, Linnhoff B. Heat and power networks in process design. Part II: Design procedure for equipment selection and process matching. AIChE Journal 1983; 29(5): 748- 771. [24] Linnhoff B, Townsend DW, Boland D., Hewitt GF, Thomas BEA, Guy AR, Marsland RH. A user guide on process integration for the efficient use of energy. IChemE, Rugby UK;1982, last edition 1994. [25] Klemeš J, Dhole VR, Raissi K, Perry SJ, Puigjaner L. Targeting and Design Methodology for Reduction of Fuel, Power and CO2 on Total Sites. Appl Therm Eng 1997; 17: 993 – 1003. 312
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Proceedings e report 90
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ECOS 2012 : the 25 th International
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Advisory Committee (Track Organizer
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The 25 th ECOS Conference 1987-2012
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VOLUME VI CONTENT VI. 1 CARBON CAPT
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-----------------------------------
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» Personal transportation energy c
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» Excess enthalpies of second gene
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VOLUME IV IV . 1 - FLUID DYNAMICS A
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» Exergy analysis and genetic algo
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» Optimal lighting control strateg
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» Stability and limit cycles in an
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PROCEEDINGS OF ECOS 2012 - THE 25 T
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Fig. 2. The exergy destruction of M
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ineffectiveness of the catalyst, in
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[ P EXmth EX SNG] ESR F where EXm
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Fuel inputkW 728221 203771 237719 3
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Not only at desined Rc (the ratio o
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4. DISCUSSION The graphic exergy an
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Figure 9(a) illustrates the energy
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Engineering Technical Conferences &
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generally there are four kinds of m
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However, even under the off-design
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Fig. 3. 600MW supercritical coal-fi
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CO2 rich loading(molCO2/molMEA) 0.4
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Net efficiency (%) 40.28 30.29 26.4
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Fig. 11. Schematic diagram of heat
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28.67%. In addition, through heat i
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Applied Thermal Engineering 2010;30
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Abstract: PROCEEDINGS OF ECOS 2012
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Fig. 1. Solution diagram of „four
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K ~ K 1 eK 1a p K 1a iK mK
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Oxygen recovery rate, % 105 95 85 7
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Calculated optimal compressor press
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The net amount of the flue gas leav
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Figure 3. Idea for lignite drying b
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Energy efficiency, % 34,00 33,00 32
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points efficiency increase related
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Figure A1b. Thermoflex flow sheet o
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Figure A3a. Thermoflex flow sheet o
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Figure A4. Thermoflex flow sheet of
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2.1. Life Cycle Assessment 2.1.1. G
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these factors. A sensitivity analys
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methane slip contributes to 13% of
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As can be seen in Fig. 5 the impact
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References [1] Eurobserv’er, The
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in which CO2 is separated from H2,
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dimensions of water droplets and wa
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Temperature (°C) 8 7 6 5 4 3 2 1 0
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4. Conclusions In the present paper
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penalty, but without separate captu
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0.5 - 0.7 kg/kg, resulting typicall
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3.3 - Utilising waste heat All exis
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4.5 - Suomusjärvi olivine deposits
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material will change from a few % t
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Fig. 5 Schematic diagram of the PFB
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8. Combined SO2 capture and CO2 min
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Fig. 10 Carbonate- (left) and sulph
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[13] Ekdahl, E., Idman, H. Statemen
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HEAT Fig. 1. Scheme and main reacti
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(raw) materials pre-heating and AS
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Fig 3- Aspen Plus® model 110
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Table 4. Elemental and XRD analysis
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the ÅA CSM route. The content of M
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moisture - 0,2237 ash - 0,0876 LHV
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2.2 CFB plant For the current momen
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The CO2 emission factor which indic
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The CO2 emission factor calculated
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Appendix A Fig A.1. Simulation mode
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(b) Fig. A.2. Simulation model of C
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Table A.1. Calculated parameters at
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References [1] Pfaff I., Oexmann J.
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with a CC installation could be avo
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2.3. Basic CHP plant indices. The b
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3. Off-design calculations The main
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Fig. 6. CHP plant efficiency Fig. 7
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amount of steam delivered to the he
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[5] Lukowicz H., Mroncz M.: Analysi
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water removal is feasible by coolin
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Figure 2. Sketch of the suggested P
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a b Figure 5. a) Exergy balance of
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The basis of comparison of each met
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Figure 7a. Impact of S/CATR on PCU
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However, more energy duty is requir
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3.1. JACOBIAN-ASPEN Interface ASPEN
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Fig. 3. Triple Pressure Bottoming S
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As seen from Table 1, the mass flow
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4. Conclusion Fig. 5. Partial Emiss
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[19] Yantovski E., Shokotov M., Sho
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investigation and the developing of
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University of L’Aquila and German
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hydrogen combustion technology at d
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eversibility of a pre-treated synth
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Fig. 1. TG curves collected for spe
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(see Fig 5). Carbon dioxide uptake
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period is reduced to the first 15 c
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CO2 capture capacity up to 150 th c
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the way for biogas utilisation is t
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projectand is described in the foll
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4. Pilot plant tests In order to de
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Concerning the absorption reaction,
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with Regeneration (AwR), consists i
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[25] Aspen Plus 2004.1. Cambridge,
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systems for fuel drying waste strea
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heated in a heat exchanger placed i
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Fig. 2. Lower heating value of fuel
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Acknowledgements The results presen
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large amount of CO2 [1,5-7]. APCr a
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N 1 i ( x x i n 1 m ) 2.3. Carbon
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DTA analysis of the untreated APCrs
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Table 4. Relative Error (%) of the
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CaO HCl CaCl H O 193kJ / mol (
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[1] M. Fernández Bertos, S.J.R. Si
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2. Process development 2.1. Backgro
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to dissolve the chloride salts prec
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The remaining 25% (5 ml/min) of the
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Table 6. Experimental conversions o
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p p 1 1. 5 p H 1 1. 5 2O p mi
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Calculating from the Aspen Plus mod
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[11] Mattila, H.-P., Experimental s
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Mg2SiO4(s) + 2CO2(g) →2MgCO3(s) +
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(Mg/Fe) of the mineral rock, Mg-sil
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Figure 2. Effect of Mg/Fe ratio of
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Figure 4 shows that an increase in
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Figure 5. Process flow diagram of M
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2. Only cold utility is needed belo
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extraction process at 400 °C (~ 62
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Table A2. Extraction equations and
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[13] Teir S, Kuusik R, Fogelholm CJ
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In the area of coal technologies al
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Tabel 1. Characteristics quantities
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N m eT 4a ~ T cp T4a 1 ( K
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Auxiliary power rate of ASU, % 40 4
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Page 291 and 292: 2. Numerical model The purpose of t
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Page 295 and 296: Table 4 - Results of the optimizati
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Page 299 and 300: 1. Define the studied system (in th
Page 301 and 302: cycle) or a lignin extraction plant
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Page 305 and 306: Table 5. Key data for the four ener
Page 307 and 308: Global CO 2 emissions [ktonnes/yr]
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Page 317 and 318: 2.2.2. Pinch analysis Pinch analysi
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Page 323 and 324: Application of the approach led to
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Page 329 and 330: 2.5. Selecting the number of TSs Se
Page 331 and 332: A) Time Slices for solar thermal en
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Page 335 and 336: cTSs demand TS solar TSs 0 2 4 6 8
Page 337: In the presented paper a framework
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Page 345 and 346: were decreased by 10°C.All scenari
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Page 349 and 350: 3.2.2. Input data and assumptions A
Page 351 and 352: Fig.7 shows the operation forecast
Page 353 and 354: [13] TERMIS Operation User Guide, 7
Page 355 and 356: Polygeneration is a term used to de
Page 357 and 358: The increase in energy utilization
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Page 361 and 362: 6. Extensions to core methodology 6
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Page 365 and 366: laterites. Ore Geology Reviews, v.
Page 367 and 368: Abstract: PROCEEDINGS OF ECOS 2012
Page 369 and 370: gasification [15], hybrid biomass g
Page 371 and 372: the second reactor. In this unit, s
Page 373 and 374: The variables effect was evaluated
Page 375 and 376: atio, as well as the shift-syngas f
Page 377 and 378: Fig. 4. Effect of operating tempera
Page 379 and 380: SDG has slight effect on the syngas
Page 381: [26.] Castle WF. Air separation and
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1. Introduction - Firenze University Press

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