Prediction of Slip Velocity at the Interface of Open-Cell Metal Foam Using 3D Printed Foams

IF 2.5 Q3 CHEMISTRY, PHYSICAL

Colloids and Interfaces Pub Date : 2022-12-12 DOI:10.3390/colloids6040080

Khairul Azhar Mustapha, F. Shikh Anuar, Fatimah Al-Zahrah Mohd Saat

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引用次数: 2

Abstract

An open-cell metal foam gains a lot of interest from researchers due to its unique porous structure, which provides high surface area and good tortuosity, as well as being lightweight. However, the same structure also induces a massive pressure drop which requires an optimum design to suit applications, for example, a partially filled setup or staggered design. Thus, better attention to the slip velocity at the interface between the porous structure and non-porous region is required to maximize its potential, especially in thermal fluid applications. This study proposed a slip velocity model of an open-cell metal foam by using a reverse engineering method and 3D printing technology. A series of experiments and a dimensionless analysis using the Buckingham-Pi theorem were used to compute the slip velocity model. Results show that the pressure drop increases with decreasing pore size. However, the blockage ratio effects would be more significant on the pressure drop with foams of smaller pore sizes. The proposed slip velocity model for an open-cell metal foam agrees with the experimental data, where the predicted values fall within measurement uncertainty.

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利用3D打印泡沫材料预测开孔金属泡沫界面的滑移速度

开孔金属泡沫由于其独特的多孔结构而引起了研究人员的极大兴趣，该结构提供了高表面积和良好的弯曲度，并且重量轻。然而，相同的结构也会引起巨大的压降，这需要优化设计来适应应用，例如，部分填充设置或交错设计。因此，需要更好地关注多孔结构和非多孔区域之间界面处的滑动速度，以最大限度地发挥其潜力，特别是在热流体应用中。本研究采用逆向工程方法和3D打印技术，建立了开孔金属泡沫的滑移速度模型。使用白金汉-皮定理进行了一系列实验和无量纲分析，以计算滑动速度模型。结果表明，压降随孔径的减小而增大。然而，对于孔径较小的泡沫，堵塞率效应对压降的影响更为显著。所提出的开孔金属泡沫的滑移速度模型与实验数据一致，预测值在测量不确定度范围内。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Colloids and Interfaces CHEMISTRY, PHYSICAL-

CiteScore

3.90

自引率

4.20%

发文量

审稿时长

10 weeks