Enthalpy and Exergy Transfers of  High Pressure Switching Expansion Reduction

doi:10.1007/s12204-012-1228-6

上海交通大学学报（英文版） ›› 2012, Vol. 17 ›› Issue (1): 45-052.doi: 10.1007/s12204-012-1228-6

Enthalpy and Exergy Transfers of High Pressure Switching Expansion Reduction

LUO Yu-xi (罗语溪), WANG Xuan-yin (王宣银), LEI Jun-bo (雷军波)

(State Key Laboratory of Fluid Power Transmission and Control, Zhejiang University, Hangzhou 310027, China)

收稿日期:2011-01-24 出版日期:2012-02-29 发布日期:2012-03-21
通讯作者: LUO Yu-xi (罗语溪), E-mail:luoyuc@163.com

Enthalpy and Exergy Transfers of High Pressure Switching Expansion Reduction

LUO Yu-xi (罗语溪), WANG Xuan-yin (王宣银), LEI Jun-bo (雷军波)

(State Key Laboratory of Fluid Power Transmission and Control, Zhejiang University, Hangzhou 310027, China)

Received:2011-01-24 Online:2012-02-29 Published:2012-03-21
Contact: LUO Yu-xi (罗语溪), E-mail:luoyuc@163.com

摘要/Abstract

摘要： Abstract: The energy balance, air internal energy, enthalpy and exergy transfers of high pressure switching expansion reduction (SER) are comparatively analyzed in this paper to give a better understanding about the exergy analysis and its difference between energy conversion analyses for the pneumatics. In SER, the exergy transfer efficiency is much lower than the enthalpy efficiency. The enthalpy efficiency is primarily related to the initial pressure of supply tanks, and the exergy efficiency is primarily related to the pressure reduction ratios. Heat transfers increase the internal energy, enthalpy and exergy of air; the influence on exergy is relatively small. The total enthalpy in SER decreases as the air temperature decreases in the expansion process of the air. And exergy loss is primarily related to the irreversible process of isenthalpic throttling but not energy conversion. Based on the analyses, to improve the exergy efficiency of the pneumatics, the pressure reduction without power output should be avoided.

关键词: enthalpy, exergy, energy balance, efficiency, pressure reduction

Abstract: Abstract: The energy balance, air internal energy, enthalpy and exergy transfers of high pressure switching expansion reduction (SER) are comparatively analyzed in this paper to give a better understanding about the exergy analysis and its difference between energy conversion analyses for the pneumatics. In SER, the exergy transfer efficiency is much lower than the enthalpy efficiency. The enthalpy efficiency is primarily related to the initial pressure of supply tanks, and the exergy efficiency is primarily related to the pressure reduction ratios. Heat transfers increase the internal energy, enthalpy and exergy of air; the influence on exergy is relatively small. The total enthalpy in SER decreases as the air temperature decreases in the expansion process of the air. And exergy loss is primarily related to the irreversible process of isenthalpic throttling but not energy conversion. Based on the analyses, to improve the exergy efficiency of the pneumatics, the pressure reduction without power output should be avoided.

Key words: enthalpy, exergy, energy balance, efficiency, pressure reduction

中图分类号:

TP271.3

LUO Yu-xi (罗语溪), WANG Xuan-yin (王宣银), LEI Jun-bo (雷军波). Enthalpy and Exergy Transfers of High Pressure Switching Expansion Reduction[J]. 上海交通大学学报（英文版）, 2012, 17(1): 45-052.

LUO Yu-xi (罗语溪), WANG Xuan-yin (王宣银), LEI Jun-bo (雷军波). Enthalpy and Exergy Transfers of High Pressure Switching Expansion Reduction[J]. Journal of shanghai Jiaotong University (Science), 2012, 17(1): 45-052.

参考文献

[1] Chen Ying, Xu Hong, Tao Guo-liang, et al. Research and progress of the
compressed air power vehicle [J]. Chinese Journal of Mechanical
Engineering, 2002, 38(11): 7-11 (in Chinese).

[2] Cavallo A. Controllable and affordable utility-scale
electricity from intermittent wind resources and compressed air
energy storage (CAES) [J]. Energy, 2007, 32(2): 120-127.

[3] Sciubba E. Beyond thermoeconomics? The concept of extended
exergy accounting and its application to the analysis and design of
thermal systems [J]. Exergy, an International Journal, 2001,
1(2): 68-84.

[4] Rosen M A. Energy-and exergy-based comparison of coal-fired
and nuclear steam power plants [J]. Exergy, an International
Journal, 2001, 1(3): 180-192.

[5] Ahern J E. The exergy method of energy systems analysis [M].
New York: John Wiley and Sons, 1980.

[6] Baehr H D. Thermodynamics---An introduction to the
fundamentals and technical applications [M]. Berlin:
Springer-Verlag, 1981 (in German).

[7] Van Wylen G J, Sonntag R E. Fundamentals of classical
thermodynamics [M]. New York: John Wiley and Sons, 1985.

[8] Setoguchi T, Santhakumar S, Maeda H, et al. A review of
impulse turbines for wave energy conversion [J]. Renewable
Energy, 2001, 23(2): 261-292

[9] Pan R, Wypych P W. Pressure drop and slug velocity in
low-velocity pneumatic conveying of bulk solids [J]. Powder
Technology, 1997, 94(2): 123-132.

[10] Cai M, Kaeashima K, Kagawa T. Power assessment of flowing
compressed air [J]. Journal of Fluids Enginnering, 2006,
128(2): 402-405.

[11] Cai M, Kagawa T. Design and application of air power meter
in compressed air systems [C]// 2nd International Symposium on
Environmentally Conscious Design and Inverse Manufacturing
(EcoDesign'01). Tokyo: IEEE, 2001: 208-212.

[12] Szargut J, Morris D R, Steward F R. Exergy analysis of
thermal, chemical, and metallurgical processes [M]. New York:
Hemisphere Publishing, 1988.

[13] Kotas T J. The exergy method of thermal plant analysis
[M]. Stoneham, MA: Butterworth Publishers, 1985.

[14] Luo Y, Wang X. Exergy analysis on throttle reduction
efficiency based on real gas equations [J]. Energy, 2010,
35(1): 181-187.

[15] Jin Ying-zi, Li Jun, Bao Gang, et al. The effect and
determination of the overall coefficient of heat transfer in
pneumatic charging and discharching system [J]. Journal of
Harbin Institute of Technology, 1998, 30(1): 15-19 (in
Chinese).

[16] Zheng Zhi, Wang Shu-li, Wang Bang-hua. Exergy analysis in
the pressure reduction process at the city gas gate stations [J].
Natural Gas Industry, 2009, 29(5): 104-106 (in Chinese).

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