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微通道热沉耦合传热及优化设计

Coupling Heat Transfer Performance and Optimization Design for Microchannel Heat Sink
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摘要 利用多场耦合方法,研究微通道热沉传热性能及其优化设计方法。基于间断有限元算法,分析其影响因素,提出微通道几何结构的数学优化模型。数值模拟了35 mm×35 mm微通道热沉的温度和流场分布,分析不同几何结构参数与最优参数对微通道热沉的温度、压力降以及综合传热因子等参数的影响。结果表明优化后模型的综合传热性能提高了65.4%,充分证明优化模型的可靠性。 The heat transfer performance and the optimization design method of microchannel heat sink were investigated with multi-fields coupling method.Based on the discontinuous finite element algorithm,the affecting factors were analyzed,with the mathematical optimization model for microchannel geometry proposed.The temperature and the flow field distribution of 35mm×35mm microchannel heat sink were numerically simulated,with the effects of different geometric structure parameters and optimal parameters on the temperature,pressure drop and comprehensive heat transfer factor of microchannel heat sink analyzed.The results show that the comprehensive heat transfer performance of the optimized model is improved by 65.4%,which fully proves the reliability of the mathematical optimization model.
作者 段治健 杨富旗 马欣荣 DUAN Zhijian;YANG Fuqi;MA Xinrong(School of Mathematics and Statistics,Xianyang Normal University,Xianyang 712000,Shaanxi,China)
机构地区 咸阳师范学院数学与统计学院
出处 《咸阳师范学院学报》 2021年第4期1-6,共6页 Journal of Xianyang Normal University
基金 陕西省教育科学“十三五”规划课题(SGH18H356) 咸阳师范学院“青蓝人才”项目(XSYQL201901) 陕西省大学生创新创业训练计划项目(S202010722033,S202010722062)。
关键词 微通道热沉 耦合传热 优化 传热性能 间断有限元方法 microchannel heat sink coupling heat transfer optimization heat transfer performance discontinuous finite element method
分类号 TK01 [动力工程及工程热物理]
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  • 1Andrew Keogh. Micro-channel heat exchanger [J]. IEA Heat Pumps Newsletter, 2007,25 (3) : 15-17. 被引量:1
  • 2K Andrew. Mircochannel heat exchangers[J].IEA Heat Pump Centre Newsletter, 2007, 25 (3):15-17. 被引量:1
  • 3P Kennet, C M Claudi, N Stefan, et al. The advantage of brazed aluminum heat exchanger applied in HVAC 8~ R field[C] // The SAPA Shanghai 2008 Technical seminar. Shanghai, 2008. 被引量:1
  • 4Cho H, Cho K. Mass Flow Rate Distribution and Phase Separation of R-22 in Multi-Microchannel Tubes under Adiabatic Condition [J]. Microscale Thermophysical Engineering, 2004,8(2) : 129-139. 被引量:1
  • 5Sa Y C, Jang D Y, Ko Oh S K. Flow Maldistribution of Flat Tube Evaporator [C]//The 4th international Symposium on HVAC. Beijing, 2003. 被引量:1
  • 6Vishwomath Subramaniam. Design of air-cooled microchannel condensers for real-distributed air flow conditions[D]. Georgia institute of technology, 2004. 被引量:1
  • 7T kvlkarnic, C W Bullard. Design tradeoffs in microchannel heat exchanger[C] // University of Illinois at Urbana Champaign. ARCR TR-208, 2003. 被引量:1
  • 8S Jain, CW Bullard. Optimization of heat exchanger design parameters for hydrocarbon refrigerant system [C] // University of Illinois at Urhana Champaign. ARCR TR-233, 2003. 被引量:1
  • 9C B Sobhan, S V Garimella. A comparative analysis of studies on heat transfer and fluid flow in micro- channles[J]. Microscale Thermophys Eng, 2001 (5) 293-311. 被引量:1
  • 10K Man-Hoe, B W Clark. Air-side performance of brazed aluminum heat exchangers under dehumidif- ying conditions[J]. International Journal of Refrigeration, 2002 (25):924-934. 被引量:1

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咸阳师范学院学报
2021年 第4期

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