Man's future is in space. Just as on Earth, the turbine engine will continue to supply his most advanced energy needs. REFERENCES [1] Potter, J.H. (1972) The Gas Turbine Cycle, ASME Winter Annual Meeting, New York. [2] Cummins, Jr., C. Lyle (1976) Internal Fire (Carnot Press) pp. 184-197. [3] Keller, C. (1978) Forty Years of Experience on Closed Cycle Gas Turbines, Annals of Nuclear Energy, Vol. 5, pp. 405-422. [4] Bammert, K. & Groschup, G. (1976) Status Report on Closed-Cycle Power Plants in the Federal Republic of Germany, ASME Gas Turbine Conference, 76-GT-54. [5] Keller, C. & Frutschi, H. (1972) Closed Cycle Plants—Conventional and Nuclear-Design, Application, Operation, Sawyer's Gas Turbine Engineering Handbook, 2nd Edition, Vol. II, Chapter 20. [6] Pietsch, A. (1972) Closed Cycle Gas Turbine Engine in Small Size Applications, Sawyer's Gas Turbine Engineering Handbook, 2nd Edition, Vol. II, Chapter 21. [7] McDonald, C.F. (1985) Large Closed-Cycle Gas Turbine Plants, Sawyer's Gas Turbine Engineering Handbook, 3rd Edition, Vol. II, Chapter 8. [8] McCormick, J.E. & Redding, T.E. (1967) 3 Kilowatt Recuperated Closed Brayton Cycle Electrical Power System, IECEC, 67-GT-20. [9] NASA, Design and Fabrication of the Brayton Rotating Unit, NASA CR-1870. [10] Harper, A.D., Pietsch, A. & Trimble, S. (1985) Brayton Cycle Space Power Systems, IECEC, 859443. [11] Pietsch, A. (1985) Closed Cycle Gas Turbines 50MW and Smaller, Sawyer's Gas Turbine Handbook, 3rd Edition, Vol. II, Chapter 9. [12] NASA (1978) Mini-BRU/BIPS 1300 Watte Dynamic Power Conversion System Development, NASA CR-159440, October. [13] McCormick, J.E. & Gable, R.D. (1978) Brayton Isotope Power System—The Versatile Dynamic Power Converter, IECEC, 789383, pp. 1717-1720.
RkJQdWJsaXNoZXIy MTU5NjU0Mg==