铜
微观结构
传热
材料科学
多孔性
压力降
制作
沸腾
复合材料
传热系数
管(容器)
气泡
强化传热
热交换器
热的
沉积(地质)
下降(电信)
管式炉
体积流量
沸点
流量(数学)
化学工程
核沸腾
枝晶(数学)
氧化铜
临界热流密度
冶金
强化传热
形态学(生物学)
散热片
联轴节(管道)
多孔介质
作者
Shuang Cao,Yang Zhang,H. Z. Liu,Liang Zhang,W. Liu,Xuehong Wu
摘要
To investigate the influence of porous structure morphology on enhanced flow boiling heat transfer in tubes, two types of porous-structured tubes were fabricated using 100-mesh copper powder particles with distinct morphologies through a sintering-electrochemical deposition coupling technique: dendritic copper powder surface-enhanced tube (D-SET) and spherical copper powder surface-enhanced tube (S-SET). Experimental studies demonstrate that D-SET exhibits exceptional heat transfer performance. Its maximum heat transfer coefficient reaches 16.26 kW/(m2 K), which is 1.10 times that of the S-SET. Comparative results show that the performance evaluation criterion (PEC) of the D-SET surface is 12% higher than that of the S-SET. The maximum PEC of D-SET reaches 2.72, exceeding the value of the spherical surface. The performance enhancement is attributed to the branched microstructures formed by dendritic copper powder. These structures improve bubble dynamics and delay dryout, which strengthens phase-change heat transfer. Although the pressure drop increases by 12.3%, the D-SET surface still shows superior overall thermal performance. The results confirm that copper powder morphology plays a key role in controlling surface heat transfer. They also offer guidance for the design and application of microstructured surfaces in high-efficiency thermal management systems.
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