Journal of South China University of Technology(Natural Science) >

2025 , Vol. 53 >Issue 9: 149 - 162

DOI: https://doi.org/10.12141/j.issn.1000-565X.240534

Energy,Power & Electrical Engineering

Experimental Study on Thermal Performance of Phase Change Heat Transfer Module with Roll Bond Aluminum Vapor Chambers

  • GAN Yunhua ,
  • XIE Yuheng ,
  • LIU Fengming ,
  • LIAO Yuepeng ,
  • LI Yong
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  • 1.School of Electric Power Engineering,South China University of Technology,Guangzhou 510640,Guangdong,China
    2.Guangxi Free Trade Zone Jianju Technology Co. ,Ltd. ,Qinzhou 535000,Guangxi,China
    3.School of Mechanical and Automotive Engineering,South China University of Technology,Guangzhou 510640,Guangdong,China
甘云华(1979—),男,教授,博士生导师,主要从事微通道传热研究。E-mail: ganyh@scut.edu.cn

Received date: 2024-11-04

  Online published: 2025-04-02

Supported by

the Guangxi Key R & D Program(2024AB08167)

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Abstract

For the thermal management of high power consumption modules in 5G communication base stations, this study proposed a phase change heat transfer module with roll bond aluminum vapor chamber, in which the evaporation chamber of the module is interconnected with the flow channels of all vapor chambers. By constructing a performance testing platform, experimental studies were conducted to investigate the heat transfer performance of the module under different filling ratios. The impacts of the boiling state and the flow distribution of the working fluid on both temperature uniformity and heat dissipation efficiency of the module were analyzed. Additionally, the variation in surface temperature distribution of the heat source under different lateral inclination angles was also explored. The research results indicate that under the condition of an input power not exceeding 400 W, as the filling ratio increases, the total thermal resistance of the phase change heat transfer module initially decreases and then increases, reaching its minimum at a filling ratio of 15.0% with the lowest total thermal resistance being 0.211 6 ℃/W. Appropriately reducing the filling ratio induces boiling of the liquid working fluid at the bottom of the vapor chambers, thereby promoting the balanced distribution of gaseous working fluid among different vapor chambers and enhancing both the heat dissipation efficiency and temperature uniformity of the phase change heat transfer module. At input powers of 350 W and 400 W respectively, reducing the filling ratio from 30.0% to 15.0% leads to a decrease in the standard deviation of temperatures among the vapor chambers by 40.92% and 34.04%, resulting in a significant improvement in temperature uniformity. When the tilt angle of the phase change heat transfer module changes, the liquid level in the evaporation chamber shifts, leading to uneven temperature distribution on the heat source surface. This adverse effect becomes more pronounced with increasing inclination. At a tilt angle of 10.0° (under the same power conditions), the maximum temperature difference on the heat source surface increases to more than 11.7 times that under horizontal placement.

Key words: communication base station; aluminum vapor chamber; working fluid; filling ratio; thermal performance

Cite this article

GAN Yunhua , XIE Yuheng , LIU Fengming , LIAO Yuepeng , LI Yong . Experimental Study on Thermal Performance of Phase Change Heat Transfer Module with Roll Bond Aluminum Vapor Chambers[J]. Journal of South China University of Technology(Natural Science), 2025 , 53(9) : 149 -162 . DOI: 10.12141/j.issn.1000-565X.240534

References

[1] FANG Y, QI X T, ZHANG S,et al .Research on abnormal energy consumption monitoring of base station equipment based on lightGBM[C]∥ Proceedings of 2023 IEEE the 23rd International Conference on Communication Technology.Wuxi:IEEE,2023:794-798.
[2] FENG H J, CHEN L G, XIE Z H,et al .Constructal design for “+” shaped high conductivity pathways over a square body[J].International Journal of Heat and Mass Transfer201591:162-169.
[3] LI J, LI X P, ZHOU G H,et al .Development and evaluation of a supersized aluminum flat plate heat pipe for natural cooling of high power telecommunication equipment[J].Applied Thermal Engineering2021184:116278/1-16.
[4] XUE Q L, XIA G D, ZHOU W B .Experimental investigation on the optimization of different filling ratios for large-size flat plate heat pipe array[J].Applied Thermal Engineering2024236:121857/1-14.
[5] 陈恭,汤勇,张仕伟,等 .超薄均热板的研究现状及发展趋势[J].机械工程学报202258(12):197-212.
  CHEN Gong, TANG Yong, ZHANG Shiwei,et al .Development status and perspective trend of ultrathin vapor chamber[J].Journal of Mechanical Engineering202258(12): 197-212.
[6] LUO Y H, TANG Y F, ZHANG X T,et al .A novel composite vapor chamber for battery thermal management system[J].Energy Conversion and Management2022254:115293/ 1-15.
[7] LIU W Y, JIA Z K, LUO Y Q,et al .Experimental investigation on thermal management of cylindrical Li-ion battery pack based on vapor chamber combined with fin structure[J].Applied Thermal Engineering2019162:114272/1-9.
[8] KIM J S, SHIN D H, YOU S M,et al .Thermal performance of aluminum vapor chamber for EV battery thermal management[J].Applied Thermal Engineering2021185:116337/1-12.
[9] CHENG J P, SHUAI S L, TANG Z G,et al .Thermal performance of a lithium-ion battery thermal management system with vapor chamber and minichannel cold plate [J].Applied Thermal Engineering2023222:119694/1-13.
[10] 田中轩,王长宏,郑焕培,等 .LED平板热管散热系统的性能分析[J].化工学报201768(S1):155-161.
  TIAN Zhongxuan, WANG Changhong, ZHENG Huanpei,et al .Heat transfer characteristic of flat plate heat pipe cooling system for LED[J].CIESC Journal201768(S1):155-161.
[11] LU Z M, BAI P F, HUANG B,et al .Experimental investigation on the thermal performance of three-dimensional vapor chamber for LED automotive headlamps[J].Applied Thermal Engineering2019157:113478/1-8.
[12] TANG Y, LIN L, ZHANG S W,et al .Thermal mana-gement of high-power LEDs based on integrated heat sink with vapor chamber[J].Energy Conversion and Management2017151:1-10.
[13] WANG J C .Thermoelectric transformation and illuminative performance analysis of a novel LED-MGVC device [J].International Communications in Heat and Mass Transfer201348:80-85.
[14] ZHANG C, GE X L, LIN C X,et al .Optimization and analysis of thermal conductivity structure for IGBT module embedded with the vapor chamber[J].IEEE Transactions on Components,Packaging and Manufacturing Technology,202313(6):798-807.
[15] 毛春林,刘汉敏,孙健,等 .芯片封装均温板壳体的传热特性研究[J].制冷学报202243(1):138-144.
  MAO Chunlin, LIU Hanmin, SUN Jian,et al .Research on heat transfer characteristics of vapor chamber integrated heat spreader for chip package[J].Journal of Refrigeration202243(1):138-144.
[16] WANG G, YANG Y Q, YU W,et al .Performance of an air-cooled photovoltaic/thermal system using micro heat pipe array[J].Applied Thermal Engineering2022217:119184/ 1-14.
[17] 韩新月,吕丫丫 .基于均热板冷却的聚光光伏和温差电热联产系统的动态性能分析[J].江苏大学学报(自然科学版)202344(4):467-474,489.
  HAN Xinyue, Yaya LYU .Dynamic performance analysis of concentrated photovoltaic/thermoeletric hybrid system based on vapor chambers cooling[J].Journal of Jiangsu University(Natural Science Edition)202344(4):467-474,489.
[18] ZHANG M, LIU Z L, MA G Y .The experimental and numerical investigation of a grooved vapor chamber[J].Applied Thermal Engineering200929(2/3):422-430.
[19] NAPHON P, WIRIYASART S .Study on the vapor chamber with refrigerant R-141b as working fluid for HDD cooling[J].International Communications in Heat and Mass Transfer201239(9):1449-1452.
[20] WIRIYASART S, NAPHON P .Fill ratio effects on vapor chamber thermal resistance with different configuration structures[J].International Journal of Heat and Mass Transfer2018127:164-171.
[21] LI R, GAN Y H, LUO Q L,et al .Numerical analysis on thermal hydraulic characteristics of mesh-type ultra-thin vapor chambers[J].Applied Thermal Engineering2024236: 121648/1-15.
[22] 李勇,徐沛恳,杨世凡,等 .吹胀型铝质均热板的传热性能[J].华南理工大学学报(自然科学版)202048(2):34-41.
  LI Yong, XU Peiken, YANG Shifan,et al .Thermal performance of roll bond aluminum vapor chamber[J].Journal of South China University of Technology (Natural Science Edition)202048(2):34-41.
[23] DENG L Q, LI Y, XU P K,et al .Fabrication and thermal performance of a novel roll-bond flat thermosyphon [J].Applied Thermal Engineering2020181:115959/1-15.
[24] CHU W X, SHEN Y W, WANG C C .Enhancement on heat transfer of a passive heat sink with closed thermosiphon loop[J].Applied Thermal Engineering2021183:116243/1-15.
[25] TAN Z T, DUAN K W, XIU W H,et al .Enhancement mechanism on heat and mass transfer of tall fin with cycloid thermosyphon loop[J].International Journal of Heat and Mass Transfer2022198:123432/1-11.
[26] DENG L Q, LI Y, XIN Z F,et al .Thermal study of the natural air cooling using roll bond flat heat pipe as plate fin under multi-heat source condition[J].International Journal of Thermal Sciences2023183:107834/1-13.
[27] MARIAPPAN S, RAJENDRAN J, NOH N M,et al .Energy efficiency in CMOS power amplifier designs for ultralow power mobile wireless communication systems[J].Turkish Journal of Electrical Engineering and Computer Sciences202028(1):1-16.
[28] JI X B, LI H C, XU J L,et al .Integrated flat heat pipe with a porous network wick for high-heat-flux electronic devices[J].Experimental Thermal and Fluid Science201785: 119-131.
[29] ONG K S, HAW P L, LAI K C,et al .Vapor chamber with hollow condenser tube heat sink [C]∥ Proceedings of the 2nd International Symposium on Green and Sustainable Technology.Perak:AIP,2017:020018/1-20.
[30] WANG H W, BAI P F, ZHOU H L,et al .An integrated heat pipe coupling the vapor chamber and two cylindrical heat pipes with high anti-gravity thermal performance[J].Applied Thermal Engineering2019159:113816/1-10.
[31] GAN K, LI R L, ZHENG Y,et al .Development and experimental study of a 3-dimensional enhanced heat pipe radiator for cooling high-power electronic devices[J].Applied Thermal Engineering2024238:121924/1-9.
[32] CHEN Y T, KANG S W, HUNG Y H,et al .Feasibility study of an aluminum vapor chamber with radial grooved and sintered powders wick structures[J].Applied Thermal Engineering201351(1/2):864-870.
[33] NAPHON P, WIRIYASART S, WONGWISES S .Thermal cooling enhancement techniques for electronic components[J].International Communications in Heat and Mass Transfer201561:140-145.
[34] YIN L F, LI J C, WANG Z,et al .Experimental study on the heat transfer performance of vapor chamber with uniform/gradient wicks[J].Case Studies in Thermal Engineering202566: 105801/1-16.
[35] QIN S Y, LIU Y J, JI R Y,et al .Effect of compact thermosyphon height on boiling curve and thermal performance:a visualization analysis[J].Applied Thermal Engineering2024240:122142/1-15.
[36] LI J, TIAN W K, LV L C .A thermosyphon heat pipe cooler for high power LEDs cooling[J].Heat and Mass Transfer201652(8):1541-1548.
[37] WAN Y, QIAN J J, ZHU Y F,et al .Experimental study of composite heat pipe radiator in thermal management of electronic components[J].Energies202417(12):2863/1-14.
[38] MINAZZO E M, ROUAZE G, MARCINICHEN J B,et al .Thermal testing of arrays of PHP finned plates for enhanced air-cooling of electronics [C]∥ Proceedings of 2023 the 22nd IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems.Orlando:IEEE,2023:1-5.
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