Two-Dimensional Isothermal and Newtonian Flow in Complex Geometries

IF 1 4区数学

Applied Mathematics-A Journal of Chinese Universities Series B Pub Date : 2021-02-26 DOI:10.4236/AM.2021.122008

Rômulo D. C. Santos, S. Gama

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引用次数: 0

Abstract

In this paper, we investigate the thermal and turbulent behaviour of incompressible Newtonian flow, by numerical simulation, combining two physical phenomena, namely, the heat-transfer by mixed convection and the onset of turbulence, around different isothermal complex geometries, using the immersed boundary method coupled with the virtual physical model, in order to model the presence of the isothermal body. Boundary conditions of the Dirichlet and Neumann type are implemented. For turbulence modelling, the Smagorinsky and Spalart-Allmaras models are used, for Reynolds and Richardson numbers ranging up to 5000 and 5, respectively. This work confirms that, downstream of the immersed body, the recirculation: 1) increases with the increase in the number of Reynolds, keeping the number of Richardson constant, and 2) decreases with the increase in the number of Richardson, preserving the number of Reynolds constant. It also confirms the generation of thermal plumes moving upwards. For Reynolds numbers in the order of a few hundred and Richardson numbers around 5, it is observed, for tandem cylinders, the vortex wake being established in the downstream region. Interactions within the vortex wake, with the shear layer separated from the downstream cylinder, create two vortices near the downstream cylinder. The shear layer separating from the upstream cylinder creates a vortex behind the downstream cylinder.

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复杂几何中的二维等温流和牛顿流

在本文中，我们研究了不可压缩牛顿流的热和湍流行为，通过数值模拟，结合两种物理现象，即混合对流换热和湍流的开始，围绕不同的等温复杂几何形状，使用浸入边界法与虚拟物理模型相结合，以模拟等温体的存在。实现了Dirichlet型和Neumann型边界条件。对于湍流建模，使用Smagorinsky和Spalart-Allmaras模型，雷诺兹和理查德森数分别高达5000和5。本工作证实，在沉体下游，再循环:1)随着雷诺数的增加而增加，保持理查德森数不变;2)随着理查德森数的增加而减少，保持雷诺数不变。它还证实了向上移动的热羽流的产生。当雷诺数为几百数量级，理查德森数为5左右时，可以观察到，对于串联柱，在下游区域建立了涡尾迹。随着剪切层与下游圆柱体分离，旋涡尾流内部的相互作用在下游圆柱体附近形成了两个涡。与上游圆筒分离的剪切层在下游圆筒后面形成一个漩涡。

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

Applied Mathematics-A Journal of Chinese Universities Series B MATHEMATICS, APPLIED-

自引率

10.00%

发文量

期刊介绍： Applied Mathematics promotes the integration of mathematics with other scientific disciplines, expanding its fields of study and promoting the development of relevant interdisciplinary subjects. The journal mainly publishes original research papers that apply mathematical concepts, theories and methods to other subjects such as physics, chemistry, biology, information science, energy, environmental science, economics, and finance. In addition, it also reports the latest developments and trends in which mathematics interacts with other disciplines. Readers include professors and students, professionals in applied mathematics, and engineers at research institutes and in industry. Applied Mathematics - A Journal of Chinese Universities has been an English-language quarterly since 1993. The English edition, abbreviated as Series B, has different contents than this Chinese edition, Series A.