Experimental and simulation study on a rooftop vertical-axis wind turbine

IF 1.5 Q2 ENGINEERING, MULTIDISCIPLINARY Open Engineering Pub Date : 2023-01-01 DOI:10.1515/eng-2022-0465

Malek Ali, A. Gherissi, Y. Altaharwah

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Abstract

Abstract In this study, a small vertical-axis wind turbine (VAWT) was successfully designed and tested to produce electrical energy using renewable wind energy after being installed on the roof of buildings. The VAWT was constructed according to the existing wind source in the Tabuk region in Saudi Arabia. The use of VAWT on roofs is a sustainable solution for producing clean electricity and contributing to a portion of the local electricity consumption. A rooftop wind turbine test was performed to determine the behavior and output of a VAWT under non-constant wind speeds under natural conditions. To verify the resistance of the shear stress and pressure, a computational fluid dynamics (CFD) simulation on the airfoil was conducted. The experimental test results showed that the VAWT can reach its rated power at 9 m/s. The minimum wind speed needed for power production was 3 m/s. The maximum power coefficient obtained during testing was approximately 0.45 at a tip speed ratio of around 1.94. The simulation mesh is constructed with Ansys mesh. Two dimensional (2-D) mapped face meshing, fine, high smoothing mesh was constructed with 50 division numbers and a bias factor of about 150. The grid with 15,000 cells generated the same results as the higher number of cell grids. The simulation equivalent force was about 2.8 N for a single blade, such as 8.5 N in total, which presents an error of about 3%. The CFD simulation and experimental tests on existing forces confirm that the VAWT structure’s resistance can be guaranteed at high wind speeds.

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屋顶垂直轴风力发电机的试验与仿真研究

摘要在本研究中，成功设计并测试了一种小型垂直轴风力涡轮机（VAWT），该涡轮机安装在建筑物的屋顶上后，可利用可再生风能发电。VAWT是根据沙特阿拉伯塔布克地区现有的风力来源建造的。在屋顶上使用VAWT是生产清洁电力的可持续解决方案，并有助于当地的一部分电力消耗。进行了屋顶风力涡轮机测试，以确定VAWT在自然条件下非恒定风速下的行为和输出。为了验证剪切应力和压力的阻力，对翼型进行了计算流体动力学（CFD）模拟。实验测试结果表明，VAWT可以在9 m/s。发电所需的最低风速为3 m/s。在约1.94的叶尖速比下，测试期间获得的最大功率系数约为0.45。仿真网格是使用Ansys网格构建的。二维（2-D）映射面网格，精细，高平滑网格是用50个分割数和大约150的偏置因子构建的。具有15000个单元的网格生成的结果与较高数量的单元网格相同。模拟等效力约为2.8 N表示单个叶片，例如8.5 总共N，这呈现出大约3%的误差。CFD模拟和现有力的实验测试证实，VAWT结构在高风速下的阻力是可以保证的。

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

Open Engineering ENGINEERING, MULTIDISCIPLINARY-

CiteScore

3.90

自引率

0.00%

发文量

审稿时长

30 weeks

期刊介绍： Open Engineering publishes research results of wide interest in emerging interdisciplinary and traditional engineering fields, including: electrical and computer engineering, civil and environmental engineering, mechanical and aerospace engineering, material science and engineering. The journal is designed to facilitate the exchange of innovative and interdisciplinary ideas between researchers from different countries. Open Engineering is a peer-reviewed, English language journal. Researchers from non-English speaking regions are provided with free language correction by scientists who are native speakers. Additionally, each published article is widely promoted to researchers working in the same field.