Performance Analysis of a Crossflow Vortex Turbine for a Gravitational Water Vortex Power Plant

Q3 Chemical Engineering
Abel Alfeuz, Fadzlita Tamiri, Farm Yan Yan, Wan Khairul Muzammil, Melvin Gan Jet Hong, Dayang Salyani Abang Mahmod, Nuramalina Bohari, Mohd Azlan Ismail
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引用次数: 0

Abstract

The micro hydro system is the most favorable renewable energy source to supply electricity for rural areas. The Gravitational Water Vortex Power Plant (GWVPP) is one of the micro hydro systems that is suitable for very low-head hydropower sites. GWVPP consists of three major parts: electromechanical components, civil structures, and electric distribution. The micro hydro turbine in GWVPP is called a vortex hydro turbine and is used to convert induced vortex flow to mechanical energy coupled with a generator to produce electricity. This paper investigates crossflow vortex turbine performance using Computational Fluid Dynamics (CFD) software and experimental work. The CFD results provide qualitative and quantitative comprising velocity distribution, water vortex profile, and water vortex height. The optimum hydraulic performance in the water vortex was observed and determined for different turbine positions. The vortex crossflow turbine was placed 0.05 m from the bottom surface of the basin at the highest vortex tangential velocity. A 0.05 m turbine position was chosen for the turbine installations as it creates a high-velocity profile. The comparative performance was conducted on the vortex crossflow blade with different inlet blade angle designs at a range of 400 – 700. The experimental analysis was conducted at rotational speeds of 30 rpm – 70 rpm to determine its efficiency performance. The optimum design for the crossflow blade was at 500 with an operational speed of 50 rpm, which exhibited torque and power output at 0.27±0.02 m and 1.49±0.08 m respectively with an efficiency recorded at 18.98%.
用于重力水涡流发电厂的横流涡轮性能分析
微型水力发电系统是为农村地区供电的最有利的可再生能源。重力水涡流发电站(GWVPP)是微型水力发电系统中的一种,适用于水头很低的水电站。GWVPP 由三大部分组成:机电部件、土建结构和配电装置。GWVPP 中的微型水轮机称为涡流水轮机,用于将诱导涡流转化为机械能,并与发电机耦合发电。本文利用计算流体动力学(CFD)软件和实验工作研究了横流涡轮机的性能。CFD 结果提供了定性和定量的速度分布、水漩涡剖面和水漩涡高度。观察并确定了不同涡轮位置下水涡的最佳水力性能。涡旋横流水轮机放置在距水池底面 0.05 米处,涡旋切向速度最大。选择 0.05 米的涡轮位置安装涡轮是因为它能产生高速剖面。在 400 - 700 的范围内,对具有不同入口叶片角度设计的涡旋横流叶片进行了性能比较。实验分析在 30 rpm - 70 rpm 的转速下进行,以确定其效率性能。横流叶片的最佳设计为 500,运行速度为 50 rpm,其扭矩和功率输出分别为 0.27±0.02 m 和 1.49±0.08 m,效率为 18.98%。
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来源期刊
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
2.40
自引率
0.00%
发文量
176
期刊介绍: This journal welcomes high-quality original contributions on experimental, computational, and physical aspects of fluid mechanics and thermal sciences relevant to engineering or the environment, multiphase and microscale flows, microscale electronic and mechanical systems; medical and biological systems; and thermal and flow control in both the internal and external environment.
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