The Effect of Heating Direction on Flow Boiling Heat Transfer of R134a in Microchannels 被引量：2

The Effect of Heating Direction on Flow Boiling Heat Transfer of R134a in Microchannels

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摘要 This paper presents effects of heating directions on heat transfer performance of R134 a flow boiling in micro-channel heat sink. The heat sink has 30 parallel rectangular channels with cross-sectional dimensions of 500mm width 500mm depth and 30 mm length. The experimental operation condition ranges of the heat flux and the mass flux were 13.48 to 82.25 W/cm^2 and 373.3 to 1244.4 kg/m^2 s respectively. The vapor quality ranged from 0.07 to 0.93. The heat transfer coefficients of top heating and bottom heating both were up to 25 k W/m^2 K. Two dominate transfer mechanisms of nucleate boiling and convection boiling were observed according to boiling curves. The experimental results indicated that the heat transfer coefficient of bottom heating was 13.9% higher than top heating in low heat flux, while in high heat flux, the heat transfer coefficient of bottom heating was 9.9%.higher than the top heating, because bubbles were harder to divorce the heating wall. And a modified correlation was provided to predict heat transfer of top heating. This paper presents effects of heating directions on heat transfer performance of R134 a flow boiling in micro-channel heat sink. The heat sink has 30 parallel rectangular channels with cross-sectional dimensions of 500mm width 500mm depth and 30 mm length. The experimental operation condition ranges of the heat flux and the mass flux were 13.48 to 82.25 W/cm^2 and 373.3 to 1244.4 kg/m^2 s respectively. The vapor quality ranged from 0.07 to 0.93. The heat transfer coefficients of top heating and bottom heating both were up to 25 k W/m^2 K. Two dominate transfer mechanisms of nucleate boiling and convection boiling were observed according to boiling curves. The experimental results indicated that the heat transfer coefficient of bottom heating was 13.9% higher than top heating in low heat flux, while in high heat flux, the heat transfer coefficient of bottom heating was 9.9%.higher than the top heating, because bubbles were harder to divorce the heating wall. And a modified correlation was provided to predict heat transfer of top heating.

作者 XU Mingchen JIA Li DANG Chao PENG Qi

机构地区 Institute of Thermal Engineering Beijing Key Laboratory of Flow and Heat Transfer of Phase Changing in Micro and Small Scale

出处《Journal of Thermal Science》 SCIE EI CAS CSCD 2017年第2期166-174,共9页 热科学学报（英文版）

基金 supported by the National Natural Science Foundation of China(No.51376019)

关键词流动沸腾传热内加热微通道 R134A 换热性能通道宽度截面尺寸质量流量 top heating, bottom heating, flow boiling, micro-channels, R134a, correlation

分类号 TK124 [动力工程及工程热物理—工程热物理] TQ021.3 [化学工程]

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参考文献1

1LI Xuejiao,JIA Li.The Investigation on Flow Boiling Heat Transfer of R134a in Micro-channels[J].Journal of Thermal Science,2015,24(5):452-462. 被引量：3

二级参考文献33

1Mertens, R. G., Chow, L., Sundaram, K. B., Cregger, R. B., Rini, D. E, Turek, L., Saarloos, B. A., (2007), Spray Cooling of IGBT Devices, Journal of Electronic Packag- ing, Vol. 129, No. 3, pp. 316-323.
2Bhunia, A., Chandrasekaran, S., Chen, C. L., (2007), Performance Improvement of a Power Conversion Mod- ule by Liquid Micro-jet Impingement Cooling, Journal of Components and Packaging Technologies, Vol. 30, No. 2, pp. 309-316.
3Pautsch, A. G, Gowda, A., Stevanovic, L., Beanpre, R., (2009), Double-Sided Microchannel Cooling of a Power Electronics Module Using Power Overlay, Proceedings of ASME 2009 InterPACK Conference collocated with the ASME 2009 Summer Heat Transfer Conference and the ASME 2009 3rd International Conference on Energy Sustainability, San Francisco, California, USA, July 19-23, pp.427-436.
4Mudawar, I., Bharathan, D., Kelly, K., Narumanchi, S., (2009), Two-phase Spray Cooling of Hybrid Vehicle Electronics, Joumal of Components and Packaging Technologies, Vol. 32, No. 2, pp. 501-512.
5Rahimo, M., Kopta, A., Eicher, S., Schlapbach, U., Lind- er, S., (2004), Switching-Self-Clamping-Mode" SSCM', a Breakthrough in SOA Performance for High Voltage IGBTs and Diodes, Proceedings of the 16th International Symposium on Power Semiconductor Devices and ICs (ISPSD 10), Kitakyushu, Japan, May 24-27, pp. 437-440.
6Hitachi, T., Gohara, H. and Nagaune, F., (2012), Direct Liquid Cooling IGBT Module for Automotive Applica- tions, Power Semiconductor Contributing in Energy and Environment Region, Vol. 58, No. 2, pp. 55.
7Campbell, J. B., Tolbert, L. M., Ayers, C. W., Ozpineci, B., Lowe, K. T. , (2007), Two-phase Cooling Method Using the R134a Refrigerant to Cool Power Electronic Devices, Journal of Industry Applications, Vol. 4, No. 33, pp. 648-656.
8Kim, D. W., Rahim, E., Bar-Cohen, A., Han, B., (2010), Direct Submount Cooling of High-power LEDs, Journal of Components and Packaging Technologies, Vol. 33, No. 4, pp. 698-712.
9Bar-Cohen, A., Rahim, E., (2009), Modeling and Predic- tion of Two-phase Microgap Channel Heat Transfer Cha- racteristics, Journal of Heat Transfer Engineering, Vol. 30, No. 8, pp. 601-625.
10do Nascimento, F. J., Le~o, H. L. S. L., Ribatski, G., (2013), An Experimental Study on Flow Boiling Heat Transfer of R134a in a Microchannel-based Heat Sink, Journal of Experimental Thermal and Fluid Science, Vol. 45, pp. 117-127.

共引文献2

1YANG Qi,MIAO Jianyin,ZHAO Jingquan,HUANG Yanpei,FU Weichun,SHEN Xiaobin.Flow Boiling of Ammonia in a Diamond-Made MicroChannel Heat Sink for High Heat Flux Hotspots[J].Journal of Thermal Science,2020,29(5):1333-1344. 被引量：5
2王泽嵩,刘金平,周易,朱文杰,陈建勋,刘凯.泵驱动的制冷剂相变冷板冷却系统实验研究[J].制冷学报,2024,45(1):36-45.

同被引文献2

1LI Xuejiao,JIA Li.The Investigation on Flow Boiling Heat Transfer of R134a in Micro-channels[J].Journal of Thermal Science,2015,24(5):452-462. 被引量：3
2HUANG Qian,JIA Li,DANG Chao,YANG Lixin.Experimental Study on Flow Boiling of Deionized Water in a Horizontal Long Small Channel[J].Journal of Thermal Science,2018,27(2):157-166. 被引量：3

引证文献2

1YANG Qi,MIAO Jianyin,ZHAO Jingquan,HUANG Yanpei,FU Weichun,SHEN Xiaobin.Flow Boiling of Ammonia in a Diamond-Made MicroChannel Heat Sink for High Heat Flux Hotspots[J].Journal of Thermal Science,2020,29(5):1333-1344. 被引量：5
2ZHANG Zhiqiang,JIA Li,DANG Chao.A Review on Flow Boiling of the Fluid with Lower Boiling Point in Micro-Channels[J].Journal of Thermal Science,2024,33(1):1-17.

二级引证文献5

1ZHOU Jinzhi,CAO Xiaoling,ZHANG Nan,YUAN Yanping,ZHAO Xudong,HARDY David.Micro-Channel Heat Sink:A Review[J].Journal of Thermal Science,2020,29(6):1431-1462. 被引量：10
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3杜建宇,唐睿,张晓宇,杨宇驰,张铁宾,吕佩珏,郑德印,杨宇东,张驰,姬峰,余怀强,张锦文,王玮.基于金刚石的先进热管理技术研究进展[J].电子与封装,2023,23(3):63-76.
4冯旭瑞,韦欣怡,张建军,郑宇亭,陈良贤,刘金龙,李成明,魏俊俊.歧管式全金刚石微通道表面终端及换热性能[J].金属热处理,2023,48(10):50-58.
5邓世博,夏永琪,吴明涛,岳晓斌,雷大江.金刚石基材料及其表面微通道制备技术在高效散热中的应用[J].金刚石与磨料磨具工程,2024,44(3):286-296.

1李宗堂,刘国维,黄鸿鼎.环隙内流动沸腾传热特性的研究[J].化工学报,1990,41(5):540-545. 被引量：1
2刘国维,李宗堂,黄鸿鼎.环隙内流动沸腾传热的计算[J].化学工程,1990,18(2):49-53.
3尹俊,刘伟,常春梅.翅片空冷器内外侧流体流动数值模拟与特性分析[J].石油化工设备,2012,41(6):37-40. 被引量：2
4邱运仁,陈卫萍,思勤.添加剂稀溶液的流动沸腾传热模型[J].中南工业大学学报,2000,31(5):433-436. 被引量：1
5刘均洪,柳和生,涂开亮.高粘假塑性流体流动沸腾传热研究[J].辽宁化工,1995,24(4):44-46.
6刘均洪,柳和生,丁海德.流动沸腾传热的影响因素分析[J].青岛化工学院学报（自然科学版）,1995,16(2):118-121. 被引量：1
7杨军,吴云英.流动沸腾传热的新模型[J].高校化学工程学报,1997,11(3):255-260. 被引量：2
8LI Xuejiao,JIA Li.The Investigation on Flow Boiling Heat Transfer of R134a in Micro-channels[J].Journal of Thermal Science,2015,24(5):452-462. 被引量：3
9刘均洪,叶林,任建勋,柳和生.垂直管内高粘假塑性流体流动沸腾传热[J].化学工程,1995,23(6):42-45. 被引量：1
10吴云英,杨伟,葛根哈斯.缝宽2mm的矩形通道内流动沸腾传热的计算与关联[J].化工学报,1996,47(3):367-370.

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