Numerical investigation of free convection inside square wavy enclosure using response surface methodology

IF 2.8 Q2 THERMODYNAMICS Heat Transfer Pub Date : 2024-08-20 DOI:10.1002/htj.23155
Ahmed A. Fadhil, Itimad D. J. Azzawi, Samir Gh Yahya, Anees A. Khadom, Layth Abed Hasnawi Al-Rubaye
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Abstract

Free convection is commonly applied in various engineering fields such as solar energy, electronic devices, nuclear energy, and heat exchangers. A computational simulation was used to analyze the natural heat transfer through convection in a wavy cavity with squared shape that was filled with tap water and saturated metal foam to assess the influence of hump configuration (square, triangle, circular, down semicircular, and up semicircular) and magnetic fields (magnetohydrodynamics) on heat transfer rate. The bottom wavy wall of the enclosure exhibits a high temperature (Th), whereas the top and side walls maintain a low temperature (Tc). The present paper will examine how the bottom wall hump number (N), aspect ratio (L), geometry inclination angle (θ), Hartman number (Ha), magnetic field intensity inclination angle (ɤ) affects the heat transfer rate at various Rayleigh numbers. When the circular hump design is used with specific parameters, including ɛ = 0.85, L = 1.25, N = 4, Tc = 0°C, θ = 0°, Ha = 600 and ɤ = 45°, for different Ra values, it leads to increased heat transfer and notable improvements in heat transfer enhancement (ɸ) and energy enhancement (e). The enhancements were measured at 2.5 times for heat transfer enhancement and 8.9 times for energy enhancement. Moreover, the ideal case of the current study had Ha = 600, L = 1.25, Ra = 30 × 103, and θ = 0° compared to the baseline case. Simulations were accomplished using CFD. The results demonstrate that the primary goal of the research was achieved by optimizing the design, leading to a significant improvement in hydrothermal performance for both ɸ = 2.5 and e = 8.9.

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利用响应面方法对方形波浪围墙内的自由对流进行数值研究
自由对流通常应用于太阳能、电子设备、核能和热交换器等多个工程领域。计算模拟分析了在一个充满自来水和饱和金属泡沫的正方形波浪形空腔中通过对流进行的自然传热,以评估驼峰结构(正方形、三角形、圆形、下半圆形和上半圆形)和磁场(磁流体力学)对传热速率的影响。箱体底部波浪形壁面的温度较高 (Th),而顶部和侧壁的温度较低 (Tc)。本文将研究底壁驼峰数 (N)、长宽比 (L)、几何倾斜角 (θ)、哈特曼数 (Ha)、磁场强度倾斜角 (ɤ) 在不同雷利数下对传热速率的影响。在不同的 Ra 值下,当使用特定参数(包括 ɛ = 0.85、L = 1.25、N = 4、Tc = 0°C、θ = 0°、Ha = 600 和 ɤ = 45°)进行圆驼峰设计时,会导致传热增加,并显著提高传热增强(ɸ)和能量增强(e)。经测量,传热增强为 2.5 倍,能量增强为 8.9 倍。此外,与基线情况相比,本次研究的理想情况为 Ha = 600、L = 1.25、Ra = 30 × 103 和 θ = 0°。模拟使用 CFD 完成。结果表明,通过优化设计,ɸ = 2.5 和 e = 8.9 的水热性能都得到了显著改善,从而实现了研究的主要目标。
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
Heat Transfer
Heat Transfer THERMODYNAMICS-
CiteScore
6.30
自引率
19.40%
发文量
342
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