Natural Convection Heat Transfer and Entropy Generation Analysis in Saltbox Roof under Summer Conditions

FUOYE Journal of Engineering and Technology Pub Date : 2022-06-30 DOI:10.46792/fuoyejet.v7i2.722

Tobechukwu E. Ogwumike, O. T. Olakoyejo, Fisayo T. Oloruntoba, Abdulsobur A. Musah, M. Oyekeye, O. Oluwatusin, A. Oluwo, A. Adelaja

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Abstract

This study investigates numerically the 2D laminar natural convection in a Saltbox roof type geometry under summer climate conditions as obtained in Africa, particularly Nigeria using ANSYS FLUENT to model the boundary conditions. The effects of Rayleigh number (Ra) within the range of 103-107 and pitch angles (top and base) on heat transfer, the flow structure, temperature distribution and entropy generation within the geometry were analysed. Results show that the flow is nearly symmetric at lower Ra, while for higher Ra, the flow becomes asymmetric. The Nusselt number (Nu) has a proportional relationship with the top pitch angle and an inverse relationship with the base pitch angle when the Rayleigh number is fixed. The effect of the Ra on the Nu is insignificant at lower Ra, but becomes noticeable at higher Ra. The total entropy generation increases with an increase in top pitch angle and a decrease in base pitch angles, at fixed Rayleigh numbers. The physical implication is that, for a Saltbox roof type geometry, at fixed Ra, the best convective heat transfer process is achieved by lowering the base pitch angle and increasing the top pitch angle.

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夏季条件下盐箱屋面自然对流换热及熵产分析

本文利用ANSYS FLUENT对非洲特别是尼日利亚夏季气候条件下的Saltbox顶板型几何结构中的二维层流自然对流进行了数值研究。分析了在103 ~ 107范围内瑞利数(Ra)和俯仰角(顶部和底部)对几何范围内传热、流动结构、温度分布和熵产的影响。结果表明:低Ra时，流动近似对称，高Ra时，流动不对称。瑞利数一定时，努塞尔数(Nu)与顶螺距角成正比关系，与底螺距角成反比关系。Ra对Nu的影响在低Ra时不显著，但在高Ra时明显。在一定的瑞利数下，总熵产随着顶俯仰角的增大和底俯仰角的减小而增大。物理意义是，对于Saltbox顶板型几何形状，在固定Ra下，减小基底节距角和增大顶节距角可以获得最佳的对流换热过程。

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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FUOYE Journal of Engineering and Technology

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