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

制冷剂在毛细管内闪蒸流动的特性 被引量:2

Characteristic of Flashing Flow of Refrigerant in a Capillary
在线阅读 下载PDF
导出
摘要 针对制冷剂在毛细管中闪蒸流动过程出现的热力学不平衡现象 ,基于毛细管内的“综合成核”理论 ,建立了气泡密度模型和气泡成长模型以及闪蒸流动数学模型 .计算出反映毛细管内制冷剂闪蒸流动过程特性的重要参数———气化欠压 ,并对计算结果进行了理论分析 .结果表明 :随着质量流量的增加和入口温度的降低 ,气化欠压增大 . Aiming at the non-equilibrium phenomenon existing in flashing flow of refrigerant in a capillary, bubble number density model,bubble growing model and flashing flow model are established based on the 'combined nucleation' theory. Underpressure,an important parameter reflecting characteristic of flasing flow of refrigerant in capillary,was calculated,and the results were analyzed theoretically. The results show that underpressure increases with the increase of the mass flow rate of refrigerant and also increases with the decrease of inlet temperature.
作者 曹小林 吴业正 朱瑞琪 晏刚
机构地区 西安交通大学能源与动力工程学院
出处 《西安交通大学学报》 EI CAS CSCD 北大核心 2002年第11期1114-1116,共3页 Journal of Xi'an Jiaotong University
基金 国家自然科学基金资助项目(5 0 0 76 0 36 )
关键词 制冷剂 毛细管 闪蒸流动 热力学不平衡 气泡密度模型 气泡成长模型 气化欠压 capillary flash flow nucleation model
分类号 TK123 [动力工程及工程热物理—工程热物理] TB612 [一般工业技术—制冷工程]
  • 相关文献

参考文献4

  • 1Alamgir M,Lienhard J H.Correlation of pressure undershoot during hot-water depressurization [J].ASME J of Heat Transfer,1981,103(1):52~55.
  • 2Kocamustafaogullari G,Chen I Y,Ishii M.Correlation for nucleation site density and its effect on interfacial area [J].Int J of Heat Mass Transfer,1982,25:567~578.
  • 3吴业正,朱瑞琪,曹小林,晏刚.毛细管内制冷剂的综合成核理论与模型[J].西安交通大学学报,2002,36(7):661-664. 被引量:11
  • 4Becker R.The kinetic treatment of nuclear formation in super-saturated vapors[J].Ann Physics,1935,24:719~752.

二级参考文献1

  • 1李瑞阳.制冷剂通过毛细管时热力学非平衡两相流的研究[M].上海:上海机械学院,1989..

共引文献10

同被引文献17

  • 1[1]ESCANES F,PERE-SEGARRA C D,OLIVA A.Numerical simulation of capillary-tube expansion devices[J].Int.J.Refrigeration,1995,18(2):113~122.
  • 2[2]BITTLE R R,PATE M B.A theoretical model for predicting adiabatic capillary tube performance with alternative refrigerants[J].ASHRAE Transactions,1996,102 (2):52~64.
  • 3[3]BANSAL P K,RUPASINGHE A S.An homogeneous model for adiabatic capillary tubes[J].Applied Thermal Engineering,1998,18(3~4):207~219.
  • 4[4]CHUNG M.A numerical procedure for simulation of Fanno flows of refrigerants of refrigerant mixtures in capillary tubes[J].ASHRAE Transactions,1998,104(2):1031~1042.
  • 5[5]SAMI S M,TRIBES C.Numerical prediction of capillary tube behavior with pure and binary alternation refrigerants[J].Applied Thermal Engineering,1998,18 (6):491~502.
  • 6[6]WONGWISES S,PIROMPAK W.Flow characteristics of pure refrigerants and refrigerant mixtures in adiabatic capillary tubes[J].Applied Thermal Engineering,2001,21:845~861.
  • 7[12]COOPER L,et al.Simple selection method for capillary derived from physical flow conditions[J].Refrigerating Engineering,1957,65(7):37~41.
  • 8[13]MIKOL E P.Adiabaric single and two-phase flow in small bore tubes[J].ASHRAE J.,1963,5(11):139~145.
  • 9[14]KUEHL S J.Modeling of Steady Flows of R22 Through Capillary Tubes[J].ASHRAE Trans,1991,(1):139~145.
  • 10[17]CHEN Z H.et al.A correlation for metastable flow of refrigerant-12through capillary tubes[J].ASHRAE Trans,1990,96(1):550 ~ 554.

引证文献2

二级引证文献1

西安交通大学学报
2002年 第11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