不同半径比的半圆诱导空腔中混合纳米流体的定向 MHD 对流和熵产生的热性能分析

Basma Souayeh
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Various wake parameters are considered in this research study, namely, the inclination angle of the cavity (<jats:italic>α</jats:italic>), the magnetic field inclination (<jats:italic>γ</jats:italic>), the Hartmann number (Ha), the Rayleigh number (Ra), the volume fraction of the hybrid nanofluid (<jats:italic>ϕ</jats:italic>) and the internal semicircles radii ratio (<jats:italic>β</jats:italic>). The major findings issued from the impact of these parameters on the fluid flow and heat transfer characteristics reveal that heat transfer and entropy generation are a decreasing function of the Hartmann parameter. Moreover, the total entropy generation is intensified by 85.23% from Ra = 10<jats:sup>3</jats:sup> to Ra = 10<jats:sup>6</jats:sup> for Ha = 10, by 85.818% for Ha = 50 and 83.813% for Ha = 100. Besides, the flow magnitude is found decreasing with increasing the radii ratio <jats:italic>β</jats:italic> of the semicircles. 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摘要

本研究以数值方法处理了磁场对充满混合纳米流体的方形空腔中自然对流和熵产生的影响,空腔底部和左侧壁上的两个等温加热半圆诱导了自然对流和熵产生。空腔由混合纳米流体(氧化钛/银-水)填充,并与外加磁场成不同的倾斜角。本研究中的模拟是通过用 FORTRAN 编程语言编写的自制代码执行的。为求解连续性、动量、能量和熵生成方程的耦合方程以及相关的边界条件,采用的数值方法是有限体积法和全多网格加速法。本研究考虑了多种唤醒参数,即空腔倾角 (α)、磁场倾角 (γ)、哈特曼数 (Ha)、瑞利数 (Ra)、混合纳米流体的体积分数 (ϕ) 和内部半圆半径比 (β)。这些参数对流体流动和传热特性的影响得出的主要结论表明,传热和熵的产生是哈特曼参数的递减函数。此外,当哈特曼参数为 10 时,从 Ra = 103 到 Ra = 106,总熵增大了 85.23%;当哈特曼参数为 50 时,总熵增大了 85.818%;当哈特曼参数为 100 时,总熵增大了 83.813%。此外,随着半圆半径比 β 的增大,流动幅度也在减小。研究还发现,在相关参数的极值(β = 1,j = 8%,Ra = 106)下,不同体积分数的混合纳米粒子的平均努塞尔特数对 Ra 的变化可获得最佳传热率。因此,本研究为研究界和工程师设计和优化热管理系统提供了有用的工具和参数研究,这些热管理系统可用于各种工业应用,如热交换器、核反应堆和能源系统。
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Thermal performance analysis of oriented MHD convective flow and entropy production of hybrid nanofluids in a cavity induced by semicircles at different radii ratios
The current study numerically treats the magnetic field impacts on the natural convection flow and entropy generation in a square cavity filled with hybrid nanofluid and induced by two isothermally heated semicircles at the bottom and left walls of the cavity. The cavity is filled by hybrid nanofluid (titanium oxide/silver‐water) and oriented under different inclination angles with the applied magnetic field. The simulations in this study were executed via a home‐made code written in the FORTRAN programing language. The numerical methodology considered to solve the coupled equations of continuity, momentum, energy, and entropy generation equations with the associated boundary conditions is the finite volume method and the full multigrid acceleration. Various wake parameters are considered in this research study, namely, the inclination angle of the cavity (α), the magnetic field inclination (γ), the Hartmann number (Ha), the Rayleigh number (Ra), the volume fraction of the hybrid nanofluid (ϕ) and the internal semicircles radii ratio (β). The major findings issued from the impact of these parameters on the fluid flow and heat transfer characteristics reveal that heat transfer and entropy generation are a decreasing function of the Hartmann parameter. Moreover, the total entropy generation is intensified by 85.23% from Ra = 103 to Ra = 106 for Ha = 10, by 85.818% for Ha = 50 and 83.813% for Ha = 100. Besides, the flow magnitude is found decreasing with increasing the radii ratio β of the semicircles. It is also found that optimal heat transfer rates deducted from the variation of average Nusselt number versus Ra for different volume fractions of the hybrid nanoparticles are obtained for the extreme values of the pertinent parameters (β = 1, ϕ = 8%, Ra = 106). Hence, the present work offers a useful tool and a parametric study for the research community and engineers on the design and optimization of thermal management systems used in a variety of industrial applications, such as heat exchangers, nuclear reactors, and energy systems.
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