垂直轴风力发电机叶片动态失速发展的时间尺度

IF 2.8 Q2 MECHANICS
Sébastien Le Fouest, Daniel Fernex, K. Mulleners
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引用次数: 1

摘要

垂直轴风力涡轮机是风能技术多样化的理想选择,但其气动复杂性限制了其工业应用。为了提高垂直轴风力涡轮机的效率和寿命,我们需要数据驱动的模型和控制策略,考虑到非定常流发展中后续事件的时间和持续时间。在这里,我们的目标是描述导致垂直轴风力涡轮机叶片动态失速的事件链,并量化涡轮机运行条件对各个流动发展阶段持续时间的影响。我们提出了一个风力涡轮机模型的时间分辨流动和非定常负载测量经历动态失速在一个大范围的叶尖速度比。采用适当的正交分解方法识别优势流动结构,并区分出附着流动、剪切层生长、涡旋形成、逆风失速、顺风失速和流动再附着六个特征失速阶段。各个阶段的时间和持续时间的最佳特征是无量纲对流时间。动态失速阶段也是基于气动力测量确定的。大部分气动工作是在剪切层生长和涡形成阶段完成的,这突出了控制垂直轴风力机动态失速的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Time scales of dynamic stall development on a vertical-axis wind turbine blade
Abstract Vertical-axis wind turbines are excellent candidates to diversify wind energy technology, but their aerodynamic complexity limits industrial deployment. To improve the efficiency and lifespan of vertical-axis wind turbines, we desire data-driven models and control strategies that take into account the timing and duration of subsequent events in the unsteady flow development. Here, we aim to characterise the chain of events that leads to dynamic stall on a vertical-axis wind turbine blade and to quantify the influence of the turbine operation conditions on the duration of the individual flow development stages. We present time-resolved flow and unsteady load measurements of a wind turbine model undergoing dynamic stall for a wide range of tip-speed ratios. Proper orthogonal decomposition is used to identify dominant flow structures and to distinguish six characteristic stall stages: the attached flow, shear-layer growth, vortex formation, upwind stall, downwind stall and flow reattachment stage. The timing and duration of the individual stages are best characterised by the non-dimensional convective time. Dynamic stall stages are also identified based on aerodynamic force measurements. Most of the aerodynamic work is done during the shear-layer growth and the vortex formation stage which underlines the importance of managing dynamic stall on vertical-axis wind turbines.
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来源期刊
CiteScore
2.40
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