Thermal dissipation of two-step combustible tangent hyperbolic fluid with quadratic Boussinesq approximation and convective cooling

Results in Materials Pub Date : 2024-03-28 DOI:10.1016/j.rinma.2024.100565

A.D. Ohaegbue , S.O. Salawu , R.A. Oderinu , E.O. Fatunmbi , A.O. Akindele

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Abstract

This study explores thermal criticality and dissipation involving a two-step reaction in a hyperbolic tangential fluid flow and quadratic Boussinesq approximation to model the complex internal heat transfer mechanisms during combustion. Subject to suitable convective boundary conditions, the transformed energy and momentum equations are numerically solved using Galerkin approximation integration coupled with a weighted residual scheme. The outcomes are disseminated using a variety of graphs to illustrate for parametric sensitivities of the thermal and velocity profiles. Based on the results, it is discovered that increases in the Frank-Kamenetskii parameter, Brinkman number, Weissenberg number, activation energy, activation ratio term, and second step term all aid in the complete combustion of hydrocarbons. Monitoring all terms that stimulate internal heat generation is essential to avoid system blow-ups.

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采用二次布辛斯基近似和对流冷却的两步可燃切线双曲流体的热耗散

本研究探讨了涉及双曲切向流体流中两步反应的热临界和耗散问题，并采用二次布森斯克近似法来模拟燃烧过程中复杂的内部传热机制。在合适的对流边界条件下，利用加勒金近似积分和加权残差方案对转换后的能量和动量方程进行数值求解。研究结果通过各种图表来说明热量和速度曲线的参数敏感性。根据结果发现，增加弗兰克-卡缅涅茨基参数、布林克曼数、魏森伯格数、活化能、活化比率项和第二步项都有助于碳氢化合物的完全燃烧。要避免系统爆炸，就必须监测所有刺激内部发热的项。

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来源期刊

Results in Materials

CiteScore

5.30

自引率

0.00%

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