磁场影响下对流辐射散热片优化设计及性能有限元分析

IF 1 Q3 ENGINEERING, MULTIDISCIPLINARY
M. Sobamowo
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引用次数: 6

摘要

本文采用有限元法对磁场作用下的对流辐射散热片进行了优化设计尺寸和性能分析。用拉普拉斯变换对线性化模型的精确解析解验证了数值解的正确性。研究了变导热对流辐射翅片的最佳尺寸,并给出了图形。利用数值解分析了对流、辐射、磁参数以及Biot数对散热片热性能的影响。结果表明,随着非线性导热系数项的增大,翅片的最佳长度和热几何参数均增大。进一步的分析还表明,随着Biot数、对流、辐射和磁参数的增加,翅片的换热速率增加,从而提高了翅片的效率。此外,还建立了热稳定性值对各种多沸换热模式的影响。通过Galerkin有限元法确定了在不同的多沸腾传热模式下,为了保证溶液的稳定性和避免数值扩散,热几何参数不能超过一定的值。希望本文的研究能加深对固体翅片在各种因素和设计考虑下的热响应的认识。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimum Design and Performance Analyses of Convective-Radiative Cooling Fin under the Influence of Magnetic Field Using Finite Element Method
In this study, the optimum design dimensions and performance analyses of convective-radiative cooling fin subjected to magnetic field are presented using finite element method. The numerical solutions are verified by the exact analytical solution for the linearized models using Laplace transform. The optimum dimensions for the optimum performance of the convection-radiative fin with variable thermal conductivity are investigated and presented graphically. Also, the effects of convective, radiative, and magnetic parameters as well as Biot number on the thermal performance of the cooling fin are analyzed using the numerical solutions. From the results, it is established that the optimum length of the fin and the thermogeometric parameter increases as the nonlinear thermal conductivity term increases. Further analyses also reveal that as the Biot number, convective, radiative, and magnetic parameters, increases, the rate of heat transfer from the fin increases and consequently improves the efficiency of the fin. Additionally, effects of the thermal stability values for the various multiboiling heat transfer modes are established. It is established that, in order to ensure stability and avoid numerical diffusion of the solution by the Galerkin finite element method, the thermogeometric parameter must not exceed some certain values for the different multiboiling heat transfer modes. It is hope that the present study will enhance the understanding of thermal response of solid fin under various factors and fin design considerations.
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来源期刊
Journal of Optimization
Journal of Optimization ENGINEERING, MULTIDISCIPLINARY-
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