散热片
材料科学
金属泡沫
热导率
强化传热
铜
合金
复合材料
传热
铝
热的
热撒布器
相变材料
热流密度
热传导
热阻
导电体
性能增强
鳍
热管
液态金属
热能储存
熔点
机械工程
强化传热
相(物质)
传热系数
金属
冶金
作者
Le Lyu,Hao Gu,Suting Li,Wei Yu,Yunxiu Ren,Xiangdong Liu
标识
DOI:10.1016/j.csite.2025.107046
摘要
The low thermal conductivity of phase change materials (PCMs) severely limits the performance of PCM-based heat sinks under high heat flux conditions. To address this, this study introduces a novel hybrid enhancement strategy that couples high-conductivity plate heat-pipe fins with copper foam, thereby creating synergistic vertical and multidirectional heat transfer pathways. An experimental platform with visualization was established to evaluate three heat sink configurations, aluminum (Al) alloy fins, heat-pipe fins, and heat-pipe fins with copper foam, under heat fluxes ranging from 4.2 to 7.0 kW/m 2 . Results show that the integration of heat-pipe fins and copper foam reduces the maximum internal temperature difference by 25% compared with Al alloy fins, and prolongs the time to reach the set point temperature ( SPT ) by 1.25 times during the pre-sensible heating stage and by 2.2 times during the melting stage. These findings demonstrate that the combined design not only enhances thermal conductivity but also promotes uniform phase transition, offering an effective solution to improving thermal management strategy for aerospace electronics, data center cooling, and electric vehicle battery systems.
科研通智能强力驱动
Strongly Powered by AbleSci AI