Handbook of Turbomachinery, Second Edition

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44. L. L. Pater, E. Crowther, and W. Rice, ‘‘Flow Regime Definition for Flow Between Corotating Disks,’’ ASME Trans. J. Fluids Eng., 96: 29–34 (1974). 45. M. E. Crawford and W. Rice, ‘‘Calculated Design Data for the Multiple-Disk Pump Using Incompressible Fluid,’’ ASME Trans. J. Eng. Power, 96: 274–282 (1974). 46. M. J. Lawn and W. Rice, ‘‘Calculated Design Data for the Multiple-Disk Turbine Using Incompressible Fluid,’’ ASME Trans. J. Fluids Eng., 96: 252– 258 (1974). 47. A. M. Grabovskii, ‘‘Use of Disc Pumps for Handling Viscous Liquids,’’ Izv. Vyssh. Ucheb Zaved, Stroi i Arkhit, 2: 117–121 (1974). 48. C. E. Basset, Jr., ‘‘An Integral Solution for Compressible Flow Through Disc Turbines,’’ 10th Intersociety Energy Conversion and Engineering Conference, Newark, DE, Aug. 18–22 (1975). 49. U. M. Barske, ‘‘Investigations on the Pumping Effect of Rotating Discs,’’ Proc. 1975, Inst. Mech. Engineers, 189: 36/75. 50. S. Murata, M. Yutaka, and I. Yoshiyuki, ‘‘A Study on a Disk Friction Pump,’’ Bull. JSME, 19: 168–178 (1976). 51. R. Steidel and H. Weiss, ‘‘Performance Test of a Bladeless Turbine for Geothermal Applications,’’ Lawrence Livermore Laboratory, Report No. UCID-17068, March 24 (1976). 52. W. Rice, D. F. Jankowski, and C. R. Truman, ‘‘Bulk-Parameter Analysis for Two-Phase Through-flow Between Parallel Corotating Disks,’’ Proceedings, 1976 Heat Transfer and Fluid Mechanics Institute, University of California, Davis, June 21–23 (1976). 53. P. W. Garrison, D. W. Harvey, and I. Catton, ‘‘Laminar Compressible Flow Between Rotating Disks,’’ ASME J. Fluids Eng., September: 382–389 (1976). 54. S. Murata, M. Yutaka, and I. Yoshiyiki, et al., ‘‘A Study on Disk Friction Pump. Part 2, Experiments on Flow Through Corotating Disks and Pump Performance,’’ Bull. JSME, 19: 1160–1171 (1976). 55. D. Nendl, ‘‘Dreidimensionale laminare Instabilita¨ten bei ebenen Wa¨nden,’’ Z. Ange w. Math. Mech., 56: T211–213 (1976). 56. E. Bakke and F. Kreith, ‘‘Disk Pump Performance in Turbulent Flow,’’ ASME J. Fluids Eng., ASME Paper No. 77-WA/FE-26. 57. C. R. Truman, W. Rice, and D. F. Jankowski, ‘‘Laminar Throughflow of Varying-Quality Steam Between Corotating Disks,’’ ASME Trans. J. Fluids Eng., 100: 194–200 (1978). 58. Von G. A. Euteneuer and M. Piesche, ‘‘Betriebsverhalten einer Reibungsturbine bei turbulentem Stromfeld und viskosem, inkompressiblem Medium im Spaltelement,’’ Forsch. Ing.-Wes., 44: 79–84 (1978). 59. V. I. Misyura, ‘‘Determination of Hydraulic Losses in a Disc Pump,’’ Izv. VUZ., Aviat. Tekh., 22: 39–43 (1979). 60. C. R. Truman, W. Rice, and D. F. Jankowski, ‘‘Laminar Throughflow of a Fluid Containing Particles Between Corotating Disks,’’ ASME Trans. J. Fluids Eng., 101: 87–92 (1979). Copyright © 2003 Marcel Dekker, Inc.
61. M. Piesche, ‘‘Investigation of the Flow and Temperature Field of a Viscous Fluid in an Element of a Shear-Force Pump,’’ 6th Conference on Fluid Machinery, Budapest, pp. 836–846 (1979). 62. K.-O. Felsch and M. Piesche, ‘‘Zum Betriebsverhalten einer Reibungsturbine und deren Einsatz als Wa¨rmetauscher,’’ Stro¨mungs-mech. Stro¨mungs-maschin., 27: 1–19 (1979). 63. A. B. Davydov and A. N. Sherstyuk, ‘‘Experimental Research on a Disc Microturbine,’’ Russ. Eng. J., 60: 26–28 (1980). 64. J. H. Morris, ‘‘Performance of Multiple-Disk-Rotor Pumps with Varied Interdisk Spacings,’’ David W. Taylor Naval Ship R and D Center, Bethesda, MD, U.S. Navy Report Number DTNSRDC-80/008, August (1980). 65. M. Piesche, ‘‘Berechnung der kompressiblen, laminaren Unter schallstro¨mung in einer Tesla-Turbine,’’ Stro¨mungsmech. Stro¨mungsmachin., 28: 25–31 (1980). 66. A. Gusev and F. H. Bark, ‘‘Stability of Rotation-Modified Plane Poiseuille Flow,’’ Phys. Fluids, 23: 2171–2177 (1980). 67. M. Piesche and U. Mu¨ller, ‘‘Uber den Wa¨rmetransport im Spatelement einer Reibungspumpe,’’ Acta Mech., 35: 173–186 (1980). 68. M. Ravindran and K. Arasu, ‘‘Some Performance Studies on a Multiple Disk Pump,’’ Proceedings Tenth Natl. Conf. on Fluid Mechanics and Fluid Power, Jamshedpur, India, Dec. 27–29, Paper A3, pp. 43–49 (1981). 69. K. O. Felsch and M. Piesche, ‘‘Ein Beitrag zur Berechnung der Stro¨mung in einer Tesla-Trubine bei temperaturabha¨ngiger Za¨higkeit des Fo¨rdermediums,’’ Ing. Arch., 50: 121–129 (1981). 70. K. O. Felsch and M. Piesche, ‘‘Berechnung der Spaltstro¨mung in einer Reibungspumpe bei temperatureabha¨ngiger Viskosita¨t zur Fo¨rderung hochviskoser Flu¨ssigkeiten,’’ Acta Mech., 38: 19–30 (1981). 71. M. Piesche and K. O. Felsch, ‘‘Kompressible Unterschall-stro¨mungen in Reibungsverdichtern,’’ Acta Mech., 41: 99–107 (1981). 72. M. Piesche, ‘‘Betriebseigen-schaften konventioneller laufradgit-ter radialer Baurt im Vergleich mit Spaltelementen von Reibungs-pumpen,’’ Stro¨mungsmech. Stro¨mungsmaschin., 31: 1–21 (1982). 73. C. R. Truman, ‘‘Turbulent Source Flow Between Stationary and Rotating Disks,’’ Ph.D. Dissertation, Department of Mechanical and Aerospace Engineering, Arizona State University, August (1983). 74. Z. Tadmor, P. S. Mehta, L. N. Valsamis, and J.-C. Yang, ‘‘Corotating Disk Pumps for Viscous Liquids,’’ Ind. Eng. Chem. Proc. Des. Dev., 24: 311–320 (1985). 75. J. W. Chew, ‘‘Computation of Flow and Heat Transfer in Rotating Disc Systems,’’ 2nd ASME-JSME Thermal Engineering Conference, Hawaii, March (1987). 76. C. R. Truman and S. A. Shirazi, ‘‘Prediction of Turbulent Source Flow Between Corotating Disks with an Anisotropic Two-Equation Turbulence Model,’’ ASME International Gas Turbine Conference, Anaheim, CA, May 31–June 4 (1987). Copyright © 2003 Marcel Dekker, Inc.
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Page 11: 26. E. Bakke, ‘‘Theoretical and

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