Analysis of velocity and pressure vector distribution fields in a three-dimensional plane around a wind power plant

IF 0.3 Q4 PHYSICS, MULTIDISCIPLINARY

Bulletin of the University of Karaganda-Physics Pub Date : 2022-09-30 DOI:10.31489/2022ph3/108-114

A. Bakhtybekova, N. Tanasheva, N. Shuyushbayeva, L. Minkov, N. Botpaev

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引用次数: 1

Abstract

To date, there has been an increase in demand for electric energy obtained from clean renewable energy sources. One of them is wind power. Based on this, the development and research of new types of efficient wind turbines that start working at low wind speeds is an urgent issue. Wind turbines operating based on the Magnus effect have proven their effectiveness. However, the authors of this work, for the first time, to eliminate the problem in the form of an electric drive for the promotion of cylindrical blades added a deflector element to the end of the cylinders. Before creating an experimental setup, it is necessary to numerically investigate the aerodynamics around the wind wheel. For this purpose, numerical simulation of wind wheel aerodynamics has been carried out using the highly efficient Ansys Fluent program. A three-dimensional geometry has been created in Design Modeler. A mathematical model grid with a grid number of 47329 consisting of tetragonal cells is constructed. The Realizable k-ε is chosen as the turbulence model. A thorough analysis of the velocity vector distribution fields for flow and pressure velocities in the three-dimensional plane around the wind wheel at air flow velocities of 5.10 and 15 m/s is carried out.

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风力发电厂周围三维平面速度和压力矢量分布场分析

迄今为止，对从清洁可再生能源获得的电能的需求有所增加。其中之一就是风力发电。基于此，开发和研究在低风速下开始工作的新型高效风力涡轮机是一个迫切的问题。基于马格努斯效应运行的风力涡轮机已经证明了它们的有效性。然而，这项工作的作者，第一次，以消除问题的形式，为促进圆柱叶片的电力驱动增加了一个偏转元件到气缸的末端。在建立实验装置之前，有必要对风轮周围的空气动力学进行数值研究。为此，利用高效的Ansys Fluent程序对风轮空气动力学进行了数值模拟。在Design Modeler中创建了三维几何体。构造了网格号为47329的由四边形单元组成的数学模型网格。选择可实现的k-ε作为湍流模型。对风速为5.10 m/s和15 m/s时，风轮周围三维平面内的流场和压力速度矢量分布场进行了深入分析。

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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Bulletin of the University of Karaganda-Physics PHYSICS, MULTIDISCIPLINARY-

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