Thermal Analysis of a Casson Boundary Layer Flow over a Penetrable Stretching Porous Wedge

IF 1.3 4区 数学 Q1 MATHEMATICS
Dur-e-Shehwar Sagheer, Mohammad Alqudah, Nawal A. Alshehri, M. Sabeel Khan, M. Asif Memon, R. Shehzad, Amsalu Fenta
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引用次数: 0

Abstract

This work aims to analyze the Casson thermal boundary layer flow over an expanding wedge in a porous medium with convective boundary conditions and ohmic heating. Moreover, the effects of porosity and viscous dissipation are studied in detail and included in the analysis. The importance of this study is due to its applications in biomedical engineering where the analysis of behavior of non-Newtonian blood flow in arteries and veins is desired. Within the context of blood flow, it is also applicable to many other fields, for instance, radiative therapy, MHD generators, soil machines, melt-spinning, and insulation processes. The modeled problem is a set of PDEs, which is nondimensionalized to derive a nonlinear boundary value problem (BVP). The obtained BVP is solved using the shooting technique, endowed with the order four Runge-Kutta and Newton methods. The impact of different parameters on the momentum and temperature fields is investigated along with two important parameters of physical significance, i.e., the Nusselt number and the surface drag force. Results are validated, and an excellent agreement is seen for the parameters of interest using MATLAB built-in function bvp4c. A significant finding is that by increasing the Casson liquid parameter, the velocity decreases as the wedge expands quicker than the free stream velocity at . However, the velocity increases for the case when . A decrease in the Darcy number increases the temperature profile. Furthermore, the convective parameter accelerated the heat transmission rate, and a rise in the Prandtl number thickens the thermal boundary layer. The findings of this investigation contribute to problems in fluid dynamics and heat transfer that involve studying the behavior of a non-Newtonian fluid with Casson rheological properties near a solid porous wedge surface.
可穿透拉伸多孔楔上卡松边界层流的热分析
本研究旨在分析多孔介质中膨胀楔上的卡松热边界层流动,该流动具有对流边界条件和欧姆加热。此外,还详细研究了多孔性和粘性耗散的影响,并将其纳入分析中。这项研究的重要性在于其在生物医学工程中的应用,因为生物医学工程需要分析动脉和静脉中的非牛顿血流行为。在血流方面,它也适用于许多其他领域,例如放射治疗、多流体发电机、土壤机械、熔融纺丝和绝缘过程。所模拟的问题是一组 PDEs,通过对其进行无维度化处理,得出一个非线性边界值问题(BVP)。所得到的 BVP 采用射击技术、四阶 Runge-Kutta 和牛顿方法进行求解。研究了不同参数对动量场和温度场的影响,以及两个重要的物理参数,即努塞尔特数和表面阻力。使用 MATLAB 内置函数 bvp4c 对结果进行了验证,结果与相关参数非常吻合。一个重要发现是,随着卡松液体参数的增加,速度会减小,因为在......时,楔形体的膨胀速度快于自由流速度。 然而,在......时,速度会增加。达西数减小会增加温度曲线。此外,对流参数加快了热传递速度,而普朗特数的增加则增厚了热边界层。这一研究结果有助于解决流体动力学和热传递问题,这些问题涉及研究具有卡松流变特性的非牛顿流体在固体多孔楔形表面附近的行为。
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来源期刊
Journal of Mathematics
Journal of Mathematics Mathematics-General Mathematics
CiteScore
2.50
自引率
14.30%
发文量
0
期刊介绍: Journal of Mathematics is a broad scope journal that publishes original research articles as well as review articles on all aspects of both pure and applied mathematics. As well as original research, Journal of Mathematics also publishes focused review articles that assess the state of the art, and identify upcoming challenges and promising solutions for the community.
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