空间红外探测用30 K单级脉管制冷机高能效研究
[4] Raab J, Tward E. Northrop grumman aerospace systems cryocooler overview[J]. Cryogenics, 2010, 50(9): 572-581.
[5] Duband L. Space cryocooler developments[J]. Physics Procedia, 2015, 67:1-10.
[6] Gan Z H, Fan B Y, Wu Y Z, et al. A two-stage Stirling-type pulse tube cryocooler with a cold inertance tube[J]. Cryogenics, 2010, 50:426-431.
[7] Kim Y, Park I, Jeong S. Experimental investigation of two-stage active magnetic regenerative refrigerator operating between 77 K and 20 K[J]. Cryogenics, 2013, 57:113-121.
[8] Ren J, Dai W, Luo E. Experimental investigation on a single-stage Stirling-type pulse tube cryocooler working below 30 K[C]. Cryocoolers 16. Springer US, 2011:51-55.
[9] Chen L, Zhu Q, Zhu W, et al. Research of Stirling-type multi-bypass pulse tube cryocoolers with temperatures below 20 K[J]. 2014, Advances in Cryogenic Engineering, 1573:982-987.
[10] Wang G P, Cai J H, Li N, et al. Development of a 0.5 W40 K pulse tube cryocooler for an infrared detector[C]. Cryocoolers 14. Boulder. 2007: 83-88.
[11] Yang L W, Xun Y Q, Thummes G, et al. Single-stage high frequency coaxial pulse tube cryocooler with base temperature below 30 K[J]. Cryogenics, 2010, 50:342-346.
[12] Chen L, Zhou Q, Jin H, et al. 386 mW20 K single-stage Stirling-type pulse tube cryocooler[J]. 2013, Cryogenics, 57:195-199.
[13] Burt W W, Chan C K. Demonstration of a high performance 35 K pulse tube cryocooler[C]. Cryocoolers 8. Springer US, 1995:313-319.
[14] Liu S S, Chen X, Zhang A K, et al. Investigation of the inertance tube of a pulse tube refrigerator operating at high temperature[J]. Energy, 2017, 123:378-385.
[15] Radebough R. Thermodynamics of regenerative refrigerators[J]. Generation of Low Temperature and It's Applications, 2003.
[16] HE Ya-Ling, GAO Fan, TAO Yu-Bing, et al. Numercal simulation of entire pulse tube refrigerators[J]Journal of XIAN Jiaotong University. (何雅玲, 高凡, 陶于兵, 等. 脉管制冷机的整机数值模拟. 西安交通大学学报) 2009, 43(3):1-9.
[17] W. S. G. Thermoacoustic engines[J]. Journal of the Acoustic Society of America, 1988, 84:1145-1180.
[18] Wakelang R S. Use of electrodynamic drivers in thermoacoustic refrigerators[J]. The Journal of the Acoustical Society of America, 2000, 107(2):827-832.
[19] Gan Z H, Wang L Y, Zhao S Y, et al. Acoustic impedance characteristic of linear compressors[J]. Journal of Zhejiang University-SCIENCE A, 2013, 14:494-503.
[20] Liu S S, Chen X, Zhang A K, et al. Investigation on phase shifter of a 10 W70 K inertance pulse tube refrigerator[J]. 2017, International Journal of Refrigeration, 74:448-455.
[21] Ward B, Clark J, Swift G. Design environment for low-amplitude thermoacoustic energy conversion[R]. 2016.
[22] LIU Shao-Shuai, ZHANG An-Kuo, CHEN Xi, et al. Effect of cooling ways of inertance tube on performance of pulse tube cryocooler[J]. CIESC Journal(刘少帅, 张安阔, 陈曦等. 惯性管盘绕方式对脉管制冷机性能的影响. 化工学报), 2016, 67:1791-1797.
[23] Liu S S, Chen X, Zhang A K, et al. Impact of coiled type inertance tube on performance of pulse tube refrigerator[J]. Applied Thermal Engineering, 2016, 107:63-69.
刘少帅, 蒋珍华, 张安阔, 唐振刚, 丁磊, 吴亦农. 空间红外探测用30 K单级脉管制冷机高能效研究[J]. 红外与毫米波学报, 2018, 37(4): 403. LIU Shao-Shuai, JIANG Zhen-Hua, ZHANG An-Kuo, TANG Zhen-Gang, DING Lei, WU Yi-Nong. Study on high energy efficiency 30 K sigle-stage pulse tube cryocooler for a space infrared detector[J]. Journal of Infrared and Millimeter Waves, 2018, 37(4): 403.