单相浸没式液冷系统的流动传热特性实验研究OA
Experimental study on flow and heat transfer characteristics of Single-Phase Immersion Liquid Cooling systems
为解决数据中心的能耗问题,本文基于实验平台对单相浸没式液冷(Single-Phase Immersion Liquid Cooling,SPILC)系统进行研究,分析了冷却液体积流量和模拟芯片功率对 SPILC系统性能的影响机制.研究结果表明:与出水口区域相比,位于进水口区域的芯片传热受器件排布位置的影响更大;随着冷却液流量增大,芯片壳温先升高后降低;存在一个临界流量,超过该流量后,继续增大流量也不会明显改善 SPILC系统的性能;随着功率增大,芯片壳温显著升高,且在较低流量下,温度升高的幅度更大;当流量不超过4.0 L/min时,芯片功率对系统压降几乎没有影响;芯片总功率较低时,冷却液流量对SPILC系统能效影响很大,但这种影响随着芯片功率增大而大幅减弱.
To address the energy consumption issue in data centers,this study investigates the Single-Phase Immersion Liquid Cooling(SPILC)system by an experimental platform.The influential mechanisms of the coolant flow rate and chip power on the SPILC performance are analyzed.The results indicate that the heat transfer of chips located at inlet regions is more influenced by board layout than that of the chips at the outlet region.Moreover,the chip case temperature shows a trend of slight increase followed by a decrease as the flow rate increases.There exists a critical flow rate beyond which further increase does not significantly improve the SPILC performance.Additionally,the chip case temperature rises significantly with increasing power,and lower flow rates result in greater temperature increases.When the flow rate does not exceed 4.0 L/min,the chip power has almost no effect on the system pressure drop.Moreover,the influence of the flow rate on the power usage effectiveness of SPILC systems is significant when the total chip power is low,but this effect is greatly weakened as the chip power increases.
徐世杰;黄永平;张程宾
东南大学 能源与环境学院,南京 210096东南大学 能源与环境学院,南京 210096东南大学 能源与环境学院,南京 210096
通用工业技术
传热单相浸没式液冷数据中心能耗芯片壳温芯片功率冷却液
heat transferSingle-Phase Immersion Liquid Cooling(SPILC)data centerenergy consumptionchip case temperaturechip powercoolant
《实验流体力学》 2026 (2)
72-80,9
国家重点研发计划项目(2021YFB3803203)
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