Multiscale Simulation of a Novel Leaf-vein-inspired Gradient Porous Wick Structure 被引量：3

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摘要 With the rapid development of photoelectric products,their miniaturization and high integration have intensified the problem of heat dissipation.Vapor chamber is a special type of heat pipe that is a particularly effective heat spreader for electronics.In this paper,a novel Leaf-vein-inspired Gradient Porous(LGP)wick structure is designed macroscopically and the LGP design is verified using a general model.After that,the gradient porous design Model IGis selected for the subsequent mesoscopic modeling.Then a connected 2D random LGP wick model presenting porosity gradient is generated by the expanded quartet structure generation set method.Using the mesoscopic Lattice Boltzmann Method(LBM),the flow and heat transfer in the LGP wick model is analyzed.For verification,FLUENT based on the macroscopic finite volume method is used as a benchmark.Finally,the microscopic flow behaviors in the 2D random LGP wick model are analyzed using the LBM developed.Observing the entire flowing process from the inlet to outlet,it is possible to explain the mesoscopic and macroscopic phenomena well based on the microscopic flow behaviors.

作者 Yuanqiang Luo Wangyu Liu Jingren Gou

机构地区 School of Mechanical and Automotive Engineering

出处《Journal of Bionic Engineering》 SCIE EI CSCD 2019年第5期828-841,共14页 仿生工程学报（英文版）

基金 The authors gratefully acknowledge the financial support from the National Natural Science Foundation of China(Nos.51375169 and 11572128).

关键词 vapor chamber leaf-vein-inspired GRADIENT porous WICK STRUCTURE lattice BOLTZMANN method multiscale simulation bionic cooling

分类号 O17 [理学—基础数学]

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