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KISSThe reciprocating flow in an Inertance Pulse Tube Cryocooler (IPTC) with the piston movement in a compression chamber was modeled numerically and analyzed. The numerical modeling on the axisymmetric two-dimensional thermal fluid motion was applied to ...
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RISS 인기검색어
Effect of Volume Ratio between the Back Space and Compression Space of Compressor on Cooling Performance in an Inertance Pulse Tube Cryocooler
한글로보기https://www.riss.kr/link?id=A108460845
- 저자
- 발행기관
- 학술지명
- 권호사항
-
발행연도
2022
-
작성언어
Korean
- 주제어
-
등재정보
KCI등재
-
자료형태
학술저널
-
수록면
223-231(9쪽)
- DOI식별코드
- 제공처
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
The reciprocating flow in an Inertance Pulse Tube Cryocooler (IPTC) with the piston movement in a compression chamber was modeled numerically and analyzed. The numerical modeling on the axisymmetric two-dimensional thermal fluid motion was applied to the reciprocating flow in an IPTC and compared the transient velocity field and temperature in the IPTC. The modeling of IPTC consists of the flow and heat transfer in the cylinder of compressor, a regenerator with a porous media, a pulse tube, 2 heat exchangers with a porous media, a long inertance, and a reservoir. The crevice between free piston and cylinder wall in the compressor was also modeled to consider the effect of leaked gas through the crevice during compression and expansion of cylinder volume. It is investigated the effect of volume ratio between the back space of piston and the compression space on the cooling performance or energy efficiency of IPTC was investigated with the temperature and flow distribution.
The reciprocating flow in an Inertance Pulse Tube Cryocooler (IPTC) with the piston movement in a compression chamber was modeled numerically and analyzed. The numerical modeling on the axisymmetric two-dimensional thermal fluid motion was applied to the reciprocating flow in an IPTC and compared the transient velocity field and temperature in the IPTC. The modeling of IPTC consists of the flow and heat transfer in the cylinder of compressor, a regenerator with a porous media, a pulse tube, 2 heat exchangers with a porous media, a long inertance, and a reservoir. The crevice between free piston and cylinder wall in the compressor was also modeled to consider the effect of leaked gas through the crevice during compression and expansion of cylinder volume. It is investigated the effect of volume ratio between the back space of piston and the compression space on the cooling performance or energy efficiency of IPTC was investigated with the temperature and flow distribution.
참고문헌 (Reference) 
1 Taylor, R. P., 985 : 1445-1453, 2008
2 한성현 ; 이경환 ; 최종욱 ; 김재수, "관성관 맥동관 극저온 냉동기의 유동 특성 모델링" 한국전산유체공학회 19 (19): 14-19, 2014
3 de Waele, A. T. A. M., "Thermodynamical aspects of pulse tubes" 37 (37): 313-324, 1997
4 de Boer, P. C. T., "Thermodynamic analysis of the basic pulse-tube refrigerator" 34 (34): 699-711, 1994
5 Kaiser, G., "Thermodynamic analysis of an ideal four valve pulse tube refrigerator" 36 (36): 527-533, 1996
6 Yuan, J., "Thermodynamic analysis of active valve pulse tube refrigerators" 39 : 283-292, 1999
7 Ju, Y. L., "Thermodynamic analysis of G–M type pulse tube coolers" 41 : 513-520, 2001
8 Bhatia, R. S., "Review of spacecraft cryogenic coolers" 39 (39): 329-346, 2002
9 Gifford, W. E., "Pulse tube refrigeration progress" 10 : 69-79, 1965
10 de Boer, P. C. T., "Performance of the Inertance Pulse Tube" 42 (42): 209-221, 2002
1 Taylor, R. P., 985 : 1445-1453, 2008
2 한성현 ; 이경환 ; 최종욱 ; 김재수, "관성관 맥동관 극저온 냉동기의 유동 특성 모델링" 한국전산유체공학회 19 (19): 14-19, 2014
3 de Waele, A. T. A. M., "Thermodynamical aspects of pulse tubes" 37 (37): 313-324, 1997
4 de Boer, P. C. T., "Thermodynamic analysis of the basic pulse-tube refrigerator" 34 (34): 699-711, 1994
5 Kaiser, G., "Thermodynamic analysis of an ideal four valve pulse tube refrigerator" 36 (36): 527-533, 1996
6 Yuan, J., "Thermodynamic analysis of active valve pulse tube refrigerators" 39 : 283-292, 1999
7 Ju, Y. L., "Thermodynamic analysis of G–M type pulse tube coolers" 41 : 513-520, 2001
8 Bhatia, R. S., "Review of spacecraft cryogenic coolers" 39 (39): 329-346, 2002
9 Gifford, W. E., "Pulse tube refrigeration progress" 10 : 69-79, 1965
10 de Boer, P. C. T., "Performance of the Inertance Pulse Tube" 42 (42): 209-221, 2002
11 이경환 ; 이주훈 ; 김재수, "Parametric Study on Performance of Inertance Pulse Tube Cryocooler" 한국항공우주학회 15 (15): 205-211, 2014
12 Jafarian, A., "Numerical simulation and performance optimization of a high capacity pulse tube cryocooler" 35 (35): 1204-1210, 2008
13 Wang, C., "Numerical modelling of an orifice pulse tube refrigerator" 32 (32): 785-790, 1992
14 Zhu, S., "Numerical method of inertance tube pulse tube refrigerator" 44 : 649-660, 2004
15 Kumar, P., "Numerical investigation of a 3D inertance pulse tube refrigerator from design prospective" 98 : 125-138, 2019
16 Lee, K. H., "Numerical analysis on distribution of temperature and flow velocity in an inertance pulse tube cryocooler" 2 (2): 89-93, 2015
17 Boroujerdi, A. A., "Numerical analysis of stirling type pulse tube cryocoolers" 51 (51): 521-529, 2011
18 Abraham, D., "Numerical analysis of inertance tube cryocooler with a modified reservoir" 278 : 2017
19 Wang, C., "Numerical analysis of double-inlet pulse tube refrigerator" 33 (33): 526-530, 1993
20 Choudhari, M. S., "Numerical Analysis of Inertance Pulse Tube Refrigerator" 1104-, 2021
21 Chaa, J. S., "Multi-dimensional flow effects in pulse tube refrigerators" 46 : 658-665, 2006
22 Panda, D., "Mathematical Modelling and Design Software for Pulse Tube Cryocoolers" National Institute of Technology 2016
23 Mikulin, E. I., "Low temperature expansion pulse tubes" 29 : 629-637, 1984
24 Liu, S., "Impact of coiled type inertance tube on performance of pulse tube refrigerator" 107 (107): 63-69, 2016
25 Lee, J. M., "Higher order pulse tube modeling" 345-353, 1997
26 Cai, J. H., "Experimental analysis of double-inlet principle in pulse tube refrigerators" 33 : 522-525, 1993
27 Radebaugh, R., "Development of the pulse tube refrigerator as an efficient and reliable cryocooler" 96 : 11-29, 2000
28 Potratz, S., "Design and Test of a High Capacity Pulse-Tube" University of Wisconsin System 2005
29 X. B. Zhang, "CFD study of a simple orifice pulse tube cooler" 47 : 315-321, 2007
30 Cha, J., "CFD Simulation of Multi-Dimensional Effects in Inertance Tube Pulse Tube Cryocoolers" Georgia Institute of Technology 2004
31 Longsworth, R. C., "An experimental investigation of pulse tube refrigeration heat pumping Rates" 12 : 608-618, 1967
32 Zhu, S. W., "A single stage double inlet refrigerator capable of reaching 42 K" 257-261, 1990
33 Xu, M. Y., "A pulse tube refrigerator below 2 K" 39 (39): 865-869, 1999
34 Kanao, K., "A miniature pulse tube refrigerator for temperature below 100 K" 34 : 167-170, 1994
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