Performance Optimization for Cycloidal Hydrokinetic Turbine With Augmentation Duct for Harvesting Riverine Energy

Yijie Wang, Ang Li, G. Jensen, Jun Chen, Haiyan Zhang
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Abstract

With the increased demand for developing renewable energy, hydro energy has attracted more attention since it is reliable and easy to acquire. In this area, the cycloidal turbine has been recently studied and applied to ocean energy for its stable and efficient output. Compared to the ordinary vertical/horizontal axis turbine with fixed pitch angle blades (e.g., Darrieus turbine), the cycloidal turbine can maximize the extracted power efficiency by keeping the optimized angle of attack for the blades. Meanwhile, the cycloidal turbine provides a potential solution to solve the problems of self-starting and seasonal flow variations. Introducing an augmentation duct is considered as a method to further increase the incoming flow velocity of the turbine. Inspired by the design of the wind tunnel, a convergent-divergent design of the augmentation duct is developed. One is noted that the dimensions of the augmentation duct are essential to the performance of the duct. In this study, a convergent-divergent augmentation duct is developed based on a 3-blade cycloidal hydro-turbine, operated at a 2 m/s river. Computational fluid dynamic (CFD) analysis with sliding unstructured mesh is applied to investigate the extent how the dimensions of the duct affect the flow velocity to the turbine as well as the extracted power efficiency.
带增强风道的摆线水轮机集能性能优化
随着可再生能源发展需求的增加,水能以其可靠、易获取的特点受到越来越多的关注。在这一领域,摆线水轮机由于其稳定高效的输出,近年来得到了研究和应用。相对于普通的定桨角叶片的垂直/水平轴涡轮(如达瑞乌斯涡轮),摆线涡轮可以通过保持叶片的最佳攻角来最大化提取功率效率。同时,摆线水轮机为解决自启动和季节性流量变化问题提供了一种潜在的解决方案。引入增强风道被认为是进一步提高涡轮来流速度的一种方法。受风洞设计的启发,提出了一种收敛发散型的增强风管设计。值得注意的是,增强风管的尺寸对风管的性能至关重要。本文研究了一种以三叶摆线水轮机为基础,在2m /s水流下运行的会聚-发散型增压器。采用滑动非结构网格计算流体动力学(CFD)分析,研究了风道尺寸对进入涡轮的流速和提取功率效率的影响程度。
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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