散热片
材料科学
热阻
沸腾
热的
传热
电子设备和系统的热管理
核工程
计算机冷却
热力学
结温
机械工程
工作(物理)
热撒布器
水冷
传热系数
主动冷却
机械
被动冷却
沉浸式(数学)
自由冷却
复合材料
炸薯条
热流密度
气泡
沸点
散热膏
电子设备冷却
消散
温度测量
热容率
核沸腾
热导率
大功率led的热管理
作者
Bin Li,Long Pan,Anqi Liu,Jingyang Hao,Bingyang Cao
标识
DOI:10.1016/j.tsep.2026.104495
摘要
• Experimental investigation of two-phase immersion cooling for data center applications. • A multi-scale structured heat sink is developed to enhance cooling of high-power chips. • High-speed imaging reveals bubble dynamics and the mechanism behind boiling enhancement. • Integrated vapor chamber and enhanced heat sink design lowers peak temperature and thermal gradient. Two-phase immersion cooling (TPIC) is positioned to become a critical thermal management solution for next-generation high-power chips. However, maintaining temperature uniformity remains challenging, with case temperatures often exceeding 70 °C under high power loads. This study introduces an integrated multi-scale structured heat sink, incorporating a vapor chamber (VC) as a heat spreader, to replace conventional cooling solutions. Experimental results demonstrate that this hybrid design achieves superior thermal performance: at a power input of 600 W, the maximum case temperature remains stable below 65 °C, with system thermal resistance below 0.026 °C/W. High-speed visualization reveals enhanced boiling dynamics achieved through multiscale surface engineering. Micro/nano-structured coatings promote vapor nucleation, while macro-scale pin–fin arrays augment the heat transfer area. This synergistic design significantly improves temperature uniformity, reducing the maximum temperature difference across the chip by 75 % (from 14.3 °C to 3.8 °C). Compared to baseline, the proposed architecture lowers the mean temperature by 22.1 %, and reduces the average thermal resistance by 6.4 %. This work presents a viable strategy for efficient thermal management of kilowatt-class chips, supporting the advancement of next-generation high-power computing systems.
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