[1] 陈晓屏. 微型低温制冷技术的现状和发展趋势 [J].红外与激光工程 , 2008, 37(1): 45-49. CHEN Xiaoping. Status and trends of the cryocooler in IRFPA detector[J]. Infrared and Laser Engineering, 2008, 37(1): 45-49.

    陈晓屏. 微型低温制冷技术的现状和发展趋势 [J].红外与激光工程 , 2008, 37(1): 45-49. CHEN Xiaoping. Status and trends of the cryocooler in IRFPA detector[J]. Infrared and Laser Engineering, 2008, 37(1): 45-49.

[2] Maytal BZ. Performance of ideal flow regulated Joule-Thomson cryocooler[J]. Cryogenics, 1994, 34(9): 723-726

    Maytal BZ. Performance of ideal flow regulated Joule-Thomson cryocooler[J]. Cryogenics, 1994, 34(9): 723-726

[3] CHOU FC, PAI CF, CHIEN SB, et al. Preliminary experimental and numerical study of transient characteristics for a Joule-Thomson cryocooler[J]. Cryogenics, 1995, 35(5): 311-316.

    CHOU FC, PAI CF, CHIEN SB, et al. Preliminary experimental and numerical study of transient characteristics for a Joule-Thomson cryocooler[J]. Cryogenics, 1995, 35(5): 311-316.

[4] XUE H, Ng KC, WANG JB. Performance evaluation of the recuperative heat exchanger in a miniature Joule=Thomson cooler[J]. Applied Thermal Engineering, 2001, 21(18): 1829-1844.

    XUE H, Ng KC, WANG JB. Performance evaluation of the recuperative heat exchanger in a miniature Joule=Thomson cooler[J]. Applied Thermal Engineering, 2001, 21(18): 1829-1844.

[5] NgKC, XUE H, WANG JB. Experimental and numerical study on a miniature Joule-Thomson cooler for steady-state characteristics[J]. International Journal of Heat & Mass Transfer, 2002, 45(3): 609-618.

    NgKC, XUE H, WANG JB. Experimental and numerical study on a miniature Joule-Thomson cooler for steady-state characteristics[J]. International Journal of Heat & Mass Transfer, 2002, 45(3): 609-618.

[6] CHUA H T, WANG X L, TEO H Y. A numerical study of the Hampson-type miniature Joule–Thomson cryocooler[J]. International Journal of Heat & Mass Transfer, 2006, 49(3-4): 582-593.

    CHUA H T, WANG X L, TEO H Y. A numerical study of the Hampson-type miniature Joule–Thomson cryocooler[J]. International Journal of Heat & Mass Transfer, 2006, 49(3-4): 582-593.

[7] HONG Y J, Park S J, Choi Y D. A Numerical Study on Operating Characteristics of a Miniature Joule-Thomson Refrigerator[J]. Progress in Superconductivity & Cryogenics, 2010, 12(4): 41-45.

    HONG Y J, Park S J, Choi Y D. A Numerical Study on Operating Characteristics of a Miniature Joule-Thomson Refrigerator[J]. Progress in Superconductivity & Cryogenics, 2010, 12(4): 41-45.

[8] Lerou PPPM, Veenstra T T, Burger J F, et al. Optimization of counterflow heat exchanger geometry through minimization of entropy generation[J]. Cryogenics, 2005, 45: 659-669.

    Lerou PPPM, Veenstra T T, Burger J F, et al. Optimization of counterflow heat exchanger geometry through minimization of entropy generation[J]. Cryogenics, 2005, 45: 659-669.

[9] Gupta P K, Kush P K, Tiwari A. Design and optimization of coil finned-tube heat exchangers for cryogenic applications[J]. Cryogenics, 2007, 47(5-6): 322-332.

    Gupta P K, Kush P K, Tiwari A. Design and optimization of coil finned-tube heat exchangers for cryogenic applications[J]. Cryogenics, 2007, 47(5-6): 322-332.

[10] CAO J, HOU Y, WANG W B, et al. Transient modeling and influence of operating parameters on thermodynamic performance of miniature Joule-Thomson cryocooler[J]. Applied Thermal Engineering, 2018(143): 1093-1100.

    CAO J, HOU Y, WANG W B, et al. Transient modeling and influence of operating parameters on thermodynamic performance of miniature Joule-Thomson cryocooler[J]. Applied Thermal Engineering, 2018(143): 1093-1100.

[11] Timmerhaus K D, Flynn T M. Cryogenic Process Engineering[M]. New York: Plenum Press, 1989.

    Timmerhaus K D, Flynn T M. Cryogenic Process Engineering[M]. New York: Plenum Press, 1989.