Ecological optimisation of an irreversible regenerative intercooled Brayton heat engine with direct heat loss

International Journal of Ambient Energy

Volumn 26, Issue 2, 2005, Pages 81-92

  Tyagi, S K ^a   Kaushik, S C ^a  

^a INDIAN INSTITUTE OF TECHNOLOGY DELHI   (India)

Author keywords

[No Author keywords available]

Indexed keywords

CAPACITANCE; ECOLOGY; HEAT EXCHANGERS; HEAT LOSSES; HEAT TRANSFER; NUCLEAR ENERGY; OPTIMIZATION; POWER GENERATION;

HEAT CAPACITANCE RATES; HEAT SOURCES; NUCLEAR POWER GENERATION; THERMAL EFFICIENCY;

HEAT ENGINES;

EID: 17444402904     PISSN: 01430750     EISSN: 21628246     Source Type: Journal    
DOI: 10.1080/01430750.2005.9674976     Document Type: Article

References (35)

1. Leff, H. S., 1987. “Thermal efficiency at maximum power output:New results for old engines”. American Journal of Physics, 55:602–610.
2. Curzon, F. L., and Alhborn, B., 1975. “Efficiency of Carnot heat engine at maximum power output”. American Journal of Physics, 43:22–24.
3. Bejan, A., 1988. “Theory of heat transfer Irreversible power plants”. International Journal of heat mass transfer, 31:1211–1219.
4. Wu, C., and Kiang, R. L., 1990. “Work and power optimization of a finite time Brayton cycle”. International Journal of Ambient Energy, 11 (No. 3):129–136.
5. Wu, C., and Kiang, R. S., 1991. “Power performance of a nonisentropic Brayton cycle”. Journal of Engineering Gas Turbines Power, 113:501–504.
6. Ibrahim, O. M., Klein, S. A., and Mitchell, J. W., 1991. “Optimum heat power cycles for specified boundary conditions”. Journal of Engineering Gas Turbines Power, 113:514–521.
7. Wu, C., and Kiang, R. L., 1992. “Finite time thermodynamic analysis of a finite time Carnot heat engine with internal irreversibility”. Energy, 17:1173–1178.
8. Wu, C., Chen, L., and Sun, F., 1996. “Performance of regenerative Brayton heat engine”. Energy, 21:71–76.
9. Cheng, C. Y., and Chen, C. K., 1996. “Power optimization of an endoreversible regenerative Brayton cycle”. Energy, 21:241–247.
10. Chen, L., and Sun, F., 1995. “New formula for performance analysis of a real irreversible recuperative closed Brayton cycle”. Proceedings of CSPE-JSME-ASME International Conference, Power Engineering, I May 22–26 Nos. 96–99, Shanghai, China
11. Chen, L., Ni, N., Cheng, G., and Sun, F., 1996. “Finite time thermodynamic performance of a closed regenerated Brayton cycle coupled to variable-temperature heat reservoirs”. ”. In Proceedings of International Conference on Marine Engineering 3Shanghai, China November 4–8,.7.1–3.7.7
12. Chen, L., Sun, F., and Wu, C., 1997. “Performance analysis of an irreversible Brayton heat engines”. Journal of the Institute of Energy, 70:2–8.
13. Chen, L., Sun, F., Wu, C., and Kiang, R. L., 1997. “Theoretical analysis of the performance of a regenerated closed Brayton cycle with internal irreversibilities”. Energy Conversion and Management, 38:871–877.
14. Chen, L., Wu, C., Sun, F., and Gong, J., 1999. “Progress in Finite time thermodynamics”. In Recent Advances in Finite Time Thermodynamics. Edited by:Wu, C., Chen, L., and Chen, J., 1–35. New York:Nova Science Publishers. In Editors
15. Chen, L., Ni, N., Cheng, G., Sun, F., and Wu, C., 1999. “Performance analysis for a real closed regenerated Brayton cycle via methods of finite time thermodynamics”. International Journal of Ambient Energy, 20 (No. 2):95–104.
16. Kaushik, S. C., Singh, N., and Tyagi, S. K., 1999. “Thermodynamic evaluation of a modified steam regenerative Brayton cycle for solar thermal power generation”. SESI-Journal, 9:63–75.
17. Göktun, S., and Yavuz, H., 1999. “Thermal of a regenerative Brayton cycle with isothermal heat addition”. Energy Conversion and Management, 40:1259–1266.
18. Tyagi, S. K., June 2000. “Finite time thermodynamics and second law evaluation of thermal energy conversion systems”. ”. In Ph. D. Thesis June, Meerut:C. C. S. University. (India)
19. Tyagi, S. K., Kaushik, S. C., and Tyagi, B. K., November 30 to December 2 2000. “Thermodynamic valuation of a regenerative closed cycle Brayton heat engine with isothermal heat addition”. ”. In NREC-2000 November 30 to December 2, 419–424. at IIT, Bombay, India
20. Erbay, L. B., Göktun, S., and Yavuz, H., 2001. “Optimal design of the regenerative gas turbine engine with isothermal heat addition”. Applied Energy, 68:249–264.
21. Kaushik, S. C., and Tyagi, S. K., 2002. “Finite time thermodynamic analysis of a nonisentropic regenerative Brayton heat engine”. International Journal of Solar Energy, 22:141–151.
22. Kaushik, S. C., Tyagi, S. K., and Singhal, M. K., 2003. “Parametric study of an irreversible regenerative closed cycle Brayton heat engine with isothermal heat addition”. Energy Conversion and Management, 44:2013–2025.
23. Sahin, B., Kodal, A., and Kayai, S. S., 1998. “A comparative performance analysis of irreversible regenerative reheating Joule-Brayton engines under maximum power density and maximum power condition”. Journal of Physics D:Applied Physics, 31:1225–1231.
24. Chen, L., Zheng, J., Sun, F., and Wu, C., 2001. “Power density optimization for an irreversible regenerated closed Brayton cycle”. Physica Scripta, 64:184–191.
25. Chen, L., Zheng, J., Sun, F., and Wu, C., 2001. “Power density optimization for an irreversible closed Brayton cycle”. Open Systems and Information Dynamics, 8:241–260.
26. Zheng, J., Chen, L., Sun, F., and Wu, C., 2001. “Power density analysis of an endoreversible closed Brayton cycle”. International Journal of Ambient Energy, 22 (No. 2):95–104.
27. Chen, L., Zheng, J., Sun, F., and Wu, C., 2002. “Performance comparison of an endoreversible closed variable-temperature heat reservoir Brayton cycle under maximum power density and maximum power conditions”. Energy Conversion and Management, 43:33–43.
28. Cheng, C. Y., and Chen, C. K., 2000. “Maximum power of an endoreversible intercooled Brayton cycle”. International Journal of Energy Research, 24:485–494.
29. Wang, W., Chen, L., Sun, F., and Wu, C., 2003. “Performance analysis of and irreversible variable temperature heat reservoir closed intercooled regenerated Brayton cycle”. Energy Conversion and Management, 44:2713–2732.
30. Angulo-Brown, F., 1991. “An ecological optimization criterion for finite time heat engine”. Journal of Applied Physics, 59 (No. 1):7465–7469.
31. Yan, Z., 1991. Comment on “An ecological optimization criterion for finite time heat engine”. Journal of Applied Physics, 59:7465–7469. Journal of Applied Physics, 73, 1993, pp. 3583
32. Cheng, C. Y., and Chen, C. K., 1997. “Ecological optimization of an irreversible Carnot heat engine”. Journal of Physics D:Applied Physics, 30:1602–1609.
33. Cheng, C. Y., and Chen, C. K., 1998. “Ecological optimization of an endoreversible Brayton heat engine”. Energy Conversion and Management, 39:33–44.
34. Cheng, C. Y., and Chen, C. K., 1999. “Ecological optimization of an irreversible Brayton heat engine”. Journal of Physics D:Applied Physics, 32:350–357.
35. Tyagi, S. K., and Kaushik, S. C., 2003. “Ecological optimization and parametric study of an irreversible regenerative Brayton heat engine with isothermal heat addition”. Entropy, 5:377–390.