Finding a weak solution of the heat diffusion differential equation for turbulent flow by Galerkin's variation method using p-version finite elements

IF 2.8 Q2 MECHANICS

Journal of Applied and Computational Mechanics Pub Date : 2021-01-01 DOI:10.32973/jcam.2021.008

I. Páczelt

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引用次数: 0

Abstract

The stochastic turbulence model developed by Professor Czibere provides a means of clarifying the flow conditions in pipes and of describing the heat evolution caused by shear stresses in the fluid. An important part of the theory is a consideration of the heat transfer-diffusion caused by heat generation. Most of the heat is generated around the pipe wall. One part of the heat enters its environment through the wall of the tube (heat transfer), the other part spreads in the form of diffusion in the liquid, increasing its temperature. The heat conduction differential equation related to the model contains the characteristics describing the turbulent flow, which decisively influence the resulting temperature field, appear. A weak solution of the boundary value problem is provided by Bubnov-Galerkin’s variational principle. The axially symmetric domain analyzed is discretized by a geometrically graded mesh of a high degree of p-version finite elements, this method is capable of describing substantial changes in the temperature gradient in the boundary layer. The novelty of this paper is the application of the p-version finite element method to the heat diffusion problem using Czibere’s turbulence model. Since the material properties depend on temperature, the problem is nonlinear, therefore its solution can be obtained by iteration. The temperature states of the pipes are analyzed for a variety of technical parameters, and useful suggestions are proposed for engineering designs.

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利用p型有限元，用伽辽金变分法求湍流热扩散微分方程的弱解

Czibere教授开发的随机湍流模型提供了一种澄清管道流动条件和描述流体中剪切应力引起的热演化的方法。该理论的一个重要部分是考虑由热产生引起的热传递-扩散。大部分热量是在管壁周围产生的。一部分热量通过管壁进入环境(传热)，另一部分以扩散的形式在液体中传播，使其温度升高。与该模型相关的热传导微分方程包含了描述湍流的特征，这些特征对得到的温度场有决定性的影响。利用布布诺夫-伽辽金变分原理给出了边值问题的弱解。所分析的轴对称区域采用高度p型有限元几何梯度网格进行离散化，该方法能够描述边界层温度梯度的实质性变化。本文的新颖之处在于将p型有限元法应用于Czibere湍流模型的热扩散问题。由于材料的性质与温度有关，该问题是非线性的，因此可以通过迭代求解。分析了各种技术参数下管道的温度状态，并对工程设计提出了有益的建议。

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

Journal of Applied and Computational Mechanics MECHANICS-

CiteScore

6.90

自引率

3.20%

发文量

审稿时长

8 weeks

期刊介绍： The Journal of Applied and Computational Mechanics aims to provide a medium for dissemination of innovative and consequential papers on mathematical and computational methods in theoretical as well as applied mechanics. Manuscripts submitted to the journal undergo a blind peer reviewing procedure conducted by the editorial board. The Journal of Applied and Computational Mechanics devoted to the all fields of solid and fluid mechanics. The journal also welcomes papers that are related to the recent technological advances such as biomechanics, electro-mechanics, advanced materials and micor/nano-mechanics. The scope of the journal includes, but is not limited to, the following topic areas: -Theoretical and experimental mechanics- Dynamic systems & control- Nonlinear dynamics and chaos- Boundary layer theory- Turbulence and hydrodynamic stability- Multiphase flows- Heat and mass transfer- Micro/Nano-mechanics- Structural optimization- Smart materials and applications- Composite materials- Hydro- and aerodynamics- Fluid-structure interaction- Gas dynamics