期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

基于二维非绝热模型的脉管损失机理研究 被引量:2

Pulse tube losses mechanism based on a two-dimension non-adiabatic model
在线阅读 下载PDF
导出
摘要 基于CFD方法建立80~300 K温区脉管的二维非绝热模型,对不同体积脉管膨胀效率进行模拟计算。根据脉管内的温度分布特性,分析脉管体积与其热损失的内在联系。研究结果表明:脉管的最佳体积应取冷端扫气容积的10~11倍,而不是传统绝热模型给出的3~5倍,实际脉管管壁与气体间非绝热损失的存在使得脉管要达到较高的膨胀效率需采用更大的体积;脉管体积直接影响管壁和管内气体的温度分布,从而影响管壁与气体间的热损失以及气体自身温度不均匀产生的热损失;若对脉管进行一维或绝热假设忽略脉管热损失的影响,则会使脉管尺寸的设计值偏离实际最佳值。 A two-dimension non-adiabatic CFD model was proposed to study the relationship between the void volume and expansion efficiency of pulse tube at 80-300 K.The gas physical parameters were analyzed.The results show that the best ratio of pulse tube volume to cold head expansion volume is 10-11,which is much larger than that of 3-5 from an adiabatic model.Heat losses caused by the wall in a non-adiabatic pulse tube make it necessary to use a large volume to obtain high expansion efficiency.The pulse tube volume has a strong impact on both the wall and gas temperature distribution,which subsequently influences the pulse tube heat losses.Traditional one-dimension or non-adiabatic pulse tube models which neglect the thermal losses are inapplicable to pulse tube dimension design.
作者 植晓琴 邱利民 甘智华 俞益波 曹强
机构地区 浙江大学制冷与低温研究所
出处 《中南大学学报(自然科学版)》 EI CAS CSCD 北大核心 2012年第9期3672-3677,共6页 Journal of Central South University:Science and Technology
基金 国家杰出青年科学基金资助项目(50825601)
关键词 二维 非绝热 脉管体积 脉管效率 two-dimension non-adiabatic pulse tube volume expansion efficiency
分类号 TB651 [一般工业技术—制冷工程]
  • 相关文献

参考文献14

  • 1Radebaugh R. The development and application of cryocoolers since 1985[C]//Cryocoolers 12. New York: Kluwer Academic/Plenum Press, 2003: 858-870.
  • 2Radebaugh R. Thermodynamics of regenerative refrigerators[J] Generation of Low Temperature and It's Applications, 2003 1-20.
  • 3蒋彦龙,陈国邦.脉管制冷机中的直流流动[J].世界科技研究与发展,2006,28(5):62-68. 被引量:1
  • 4Shiraishi M, Murakami M, Nakano A. Visualization of secondary flow in an inclined double-inlet pulse tube refrigerat0r[C]// Cryocoolers 14. Colorado: ICC Press, 2007: 277-284.
  • 5YANG Lu-wei. Shuttle loss in pulse tubes[C]//Cryocoolers 11. New York: Kluwer Academic/Plenum Press, 2001 : 353-362.
  • 6YANG Lu-wei. Theoretical analysis of refrigeration and losses in a pulse tube[C]//Advances in Cryogenic Engineering. New York: AIP Press, 2000, 45: 175-182.
  • 7吴明,何雅玲,陶文铨,陈钟颀,潘雁频,王小军.最佳脉管长径比优化设计的理论分析及数值模拟[J].西安交通大学学报,2002,36(3):230-232. 被引量:5
  • 8党海政,梁惊涛,周远.高频微型同轴非金属脉冲管制冷机几何尺寸优化的实验研究[J].低温工程,2005(2):1-4. 被引量:1
  • 9Kirkconnell C S, Soloski S C, Price K D. Experiments on the effects of pulse tube geometry on PTR performance[C]// Cryocoolers 9. New York: Plenum Press, 1996: 285-293.
  • 10Junseok K, Sankwon J, Taekyoung K. Effects of pulse tube volume on dynamics of liner compressor and cooling performance in Stirling-type pulse tube refrigerator[J]. Cryogenics, 2010(50): 1-7.

二级参考文献30

  • 1蒋彦龙,陈国邦,Thummes Guenter.高性能G-M型单级脉管制冷机研究[J].南京航空航天大学学报,2004,36(4):496-499. 被引量:4
  • 2蒋彦龙,陈国邦,甘智华,G.Thummes.回热器流阻对脉管制冷机稳定性的影响[J].低温物理学报,2004,26(3):243-250. 被引量:3
  • 3蒋彦龙,陈国邦,THUMMES Guenter.回热器填料布置方式对脉管制冷特性影响实验研究[J].南京航空航天大学学报,2004,36(6):736-739. 被引量:2
  • 4许名尧.脉管制冷机的理论分析和新结构的研究[M].西安:西安交通大学能源动力工程学院,1997..
  • 5Peter J S, Radebaugh R,Zimmerman J E. Analytical model for the refrigeration power of the orifice pulse tube refrigerator. Internal Report,No. NIST1343, 1990.
  • 6肖家华.[D].北京:中国科学院物理研究所,1990.
  • 7Liang J, Ravex A,Rolland P. Study on pulse tube refrigeration. Cryogenics, 1996, 36: 87 ~ 106.
  • 8Radebaugh R, et al. Optimization of a pulse tube refrigerator for a fixed compressor swept volume. Cryocooler, 1988 ( 5 ): 113 ~ 117.
  • 9Lewis M, Kuriyama T, Xiao J H, et al. Effects of regenerator geometry on pulse tube refrigerator performance. Advances in Cryogenic Engieering, 1998, 43 B: 1999 ~ 2005.
  • 10Radebaugh R, Marquardt E, Bradley P. Development of a pulse tube refrigerator for millimeter array sensor cooling: Phase I, ALMA Memo #281, 1999.

共引文献4

同被引文献24

  • 1赵密广,梁惊涛,杨鲁伟,蔡京辉,侯小锋,周远.脉冲管制冷机中惯性管的数值模拟研究[J].工程热物理学报,2006,27(z1):29-32. 被引量:4
  • 2Radebaugh R. Cryocoolers: the state of the art and recent develop- ments[J]. Journal of Physics: Condensed Matter, 2009. 21(16): 164219.
  • 3Wang B, Gan Z H. A critical review of liquid helium temperature high frequency pulse tube cryocoolers for space applications[ J]. Pro- gress in Aerospace Sciences, 2013, 61 : 43-70.
  • 4De Waele A T A M. Basic operation of cryocoolers and related thermal machines[J]. Journal of Low Temperature Physics, 2011, 164(5- 6) : 179-236.
  • 5Ter Brake H T M, Wiegerinck G. Low-power cryocooler survey[ J]. Cryogenics, 2002,42 ( 11 ) : 705-718.
  • 6Gary J, Daney D E, Radebaugh R. A computational model for a re- generator[ M]. Proc. of the Third Cryocooler Conference, NBS Spe- cial Publication 698, 1985 : 199-211.
  • 7Gedeon D. Sage: Object-orlented software for cryocooler design[J]. Cry lers 8, 1995: 281-292.
  • 8Gedeon D. Sage User's Guide[ M]. Gedeon Associates, Athens, OH, 2011.
  • 9Ward B, Clark J, Swift G. Users Guide for DeltaEC ( Version 6.3) [ M]. Los Alamos National Laboratory, 2012.
  • 10Wang L Y, Zhou W J, Gan Z H. Performance Testing of Linear Com- pressors with RC Approach[ C]. Advances in Cryogenic Engineering, AIP Conf. Proc. 1434, 2012: 1624-1631.

引证文献2

二级引证文献1

中南大学学报(自然科学版)
2012年 第9期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部