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多孔细径微肋管内CO_2流动蒸发换热特性的研究 被引量:1

FLOW BOILING OF SUB-CRITICAL CO_2 IN EXTRUDED MINI-CHANNELS WITH MICRO-FINS
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摘要 对亚临界二氧化碳在带有微肋的微细通道内的蒸发换热特性进行了实验研究.实验段为长0.6 m,内径1.7 mm的八孔带0.16 mm高微肋的铝制扁管。实验中参数的变化为:蒸发温度1~15℃,质量流速100~300 kg/m^2s,热流密度1.67~8.33 kW/m^2,干度0.1~0.9.实验结果表明,二氧化碳在带有微肋的微细通道中的蒸发换热系数高于其在光滑微细通道内的换热。二氧化碳的流动蒸发换热系数主要受热流密度和蒸发温度的影响,基本上是换热系数随热流密度及蒸发温度的增加而增加,但同时临界干度前移及滞后,而质量流速对换热系数的影响较弱;压力损失随质量流速和热流密度的增加以及蒸发温度的降低而增加. The flow boiling characteristics of sub-critical CO_2 in mini-channels with micro-fins was investigated experimentally.Tested was a 0.6 m long multi-port extruded aluminum tube that had 8 flow-channels of 1.7 mm ID with micro-fins of 0.16 mm height.The tube was set in horizontal orientation and heated by direct current.Heat transfer and pressure drop were measured for 100~300 kg/m^2s mass fluxes,1~15℃evaporating temperatures,1.67~8.33 kW/m^2 heat fluxes,and 0.1~0.9 vapor qualities.The test results showed that the heat transfer coefficient of CO_2 in mini-channels with micro-fins was higher than that in smooth mini-channels.Such coefficient was mainly affected by heat flux and evaporating temperature,it increased with increasing the heat flux and the evaporating temperature,but at the same time the dry-out occurred earlier with the former and later with the latter.The mass flux has less effect on the heat transfer coefficient.The pressure drop increased with increasing the mass flux and the heat flux,but decreasing the evaporating temperature.
作者 吴晓敏 汤英杰 李辉 王维城
机构地区 清华大学热能工程系热科学与动力工程教育部重点实验室
出处 《工程热物理学报》 EI CAS CSCD 北大核心 2007年第z2期9-12,共4页 Journal of Engineering Thermophysics
基金 教育部科学技术重大项目资助(No.306001) 国家高技术研究发展计划(863计划)项目(No.2006AA05Z416)
关键词 二氧化碳 流动蒸发 多孔细径微肋管 强化传热 carbon dioxide flow boiling mini-channels with micro-fins enhanced heat transfer
分类号 TK124 [动力工程及工程热物理—工程热物理]
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参考文献4

  • 1[1]J Pettersen.Flow Vaporation of CO2 in Microchannels Tubes.Experimental Thermal and Fluid Science,2004,28(2-3):111-121
  • 2[2]Rin Yun,Yongchan Kim,Min Soo Kim,et al.Boiling Heat Transfer and Dryout Phenomenon of CO2 in a Horizontal Smooth Tube.Int.J.of Heat and Mass Transfer,2003,46(13):2353-2361
  • 3[3]Zhao Yuan,Molki Majid.Predicting Flow Boiling Heat Transfer of CO2 in Microchannels.In:Proceedings of 2001 ASME International Mechanical Engineering Congress and Exposition.New York,2001.205-210
  • 4吴晓敏,赵红艺,王维城,井亮,张亮.CO_2在细径管内蒸发换热的实验研究[J].工程热物理学报,2005,26(5):823-825. 被引量:8

二级参考文献5

  • 1J Pettersen, R Rieberer, S T Munkejord. Heat Transfer and Pressure Drop Characteristics of Evaporating Carbon Dioxide in Microchannel Tubes. In: Proceedings of the 4th IIR-Gustav Lorentzen Conference on Natural Working Fluids at Purdue. 2000. 324-332.
  • 2J Pettersen. Flow vaporation of CO2 in Microchannels Tubes. Experimental Thermal and Fluid Science, 2004,28:111-121.
  • 3Rin Yun, Yongchan Kim, Min Soo Kim, et al. Boiling Heat Transfer and Dryout Phenomenon of CO2 in a Horizontal Smooth Tube. Int. J. of Heat and Mass Transfer,2003, 46:2353 -2361.
  • 4Liu Z, Winterton R H S. A General Correlation for Saturated and Subcooled Flow Boiling in Tubes and Annuli,Based on a Nucleate Pool Boiling Equation. International Journal of Heat and Mass Transfer, 1991, 34:2759-2766.
  • 5Kandlikar S G. A General Correlation for Saturated Twophase Flow Boiling Heat Transfer Inside Horizontal and Vertical Tubes. ASME Journal of Heat Transfer, 1990,112:219-228.

共引文献7

同被引文献12

  • 1吴晓敏,赵红艺,王维城,井亮,张亮.CO_2在细径管内蒸发换热的实验研究[J].工程热物理学报,2005,26(5):823-825. 被引量:8
  • 2Yoon S H, Cho E S, Hwang Y W, et al. Characteristics of evaporative heat transfer and pressure drop of carbon dioxide and correlation development [J]. International Journal of Refrigeration, 2004, 27 (2) : 111-119.
  • 3Thome JR, E1 Hajal J. Flow boiling heat transfer to carbon dioxide: general prediction method [J]. International Journal of Refrigeration, 2004, 27 (3): 294-301.
  • 4Thome J R, Ribatski G. State-of-the-art review of flow boiling and two-phase flow of CO2 in macro- and micro-channels [J]. International Journal of Refrigeration, 2005, 28 (8): 1149-1168.
  • 5HuaiX, KoyamaS, ZhaoTS, etal. Anexperimental study of flow boilingcharacteristics ofcarbon dioxide in multiportmini-channels [J]. Applied Thermal Engineering, 2004, 24: 1443-1463.
  • 6Ozawa M, Ami T, Ishihara I, et al. Flow pattern and boiling heat transfer of CO2 in horizontal small-bore tubes [J]. International Journal of MultiphaseFlow, 2009, 35: 699-709.
  • 7YunR, KimY. Critical quality prediction for saturated flow boiling of C02 in horizontal smaU diameter tubes [J].International Journal of Heat Mass Transfer, 2003, 46: 2527-2535.
  • 8Choi K I, Pamitran A S, Oh J. Two-phase flow heat transfer of CO2 vaporization in smooth horizontal minichannels [J]. International Journal of Refrigeration, 2007, 30 (5): 767-777.
  • 9Kim M H, Bullard C W. Development of a micro-channel evaporator model for a CO2 air-conditioning system [J]. Energy, 200l, 26 ( 1 0) : 931-948.
  • 10Derevich I V, Smirnova E G. Semiempirical model of carbon dioxide boiling in tubes [J]. Theoretical Foundations of Chemical Engineering, 2006, 40 (3): 270-280.

引证文献1

二级引证文献3

工程热物理学报
2007年 第z2期

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