On the power and control of a misaligned rotor – beyond the cosine law

Simone Tamaro, F. Campagnolo, C. Bottasso
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Abstract

Abstract. We present a new model to estimate the performance of a wind turbine operating in misaligned conditions. The model is based on the classic momentum and lifting-line theories, considering a misaligned rotor as a lifting wing of finite span, and accounts for the combined effects of both yaw and uptilt angles. Improving on the classical empirical cosine law in widespread use, the new model reveals the dependency of power not only on the misalignment angle, but also on some rotor design parameters and – crucially – on the way a rotor is governed when it is yawed out of the wind. We show how the model can be readily integrated with arbitrary control laws below, above, and around the rated wind speed. Additionally, the model also shows that a sheared inflow is responsible for the observed lack of symmetry for positive and negative misalignment angles. Notwithstanding its simplicity and insignificant computational cost, the new proposed approach is in excellent agreement with large eddy simulations (LESs) and wind tunnel experiments. Building on the new model, we derive the optimal control strategy for maximizing power on a misaligned rotor. Additionally, we maximize the total power of a cluster of two turbines by wake steering, improving on the solution based on the cosine law.
错位转子的功率和控制 - 超越余弦定律
摘要我们提出了一个新模型,用于估算在错位条件下运行的风力涡轮机的性能。该模型基于经典的动量和升力线理论,将错位转子视为有限跨度的升力翼,并考虑了偏航角和上倾角的综合影响。新模型对广泛使用的经典经验余弦定律进行了改进,揭示了功率不仅与错位角有关,还与一些转子设计参数有关,更重要的是与转子偏离风向时的控制方式有关。我们展示了如何将该模型与低于、高于和围绕额定风速的任意控制法则轻松整合。此外,该模型还表明,剪切流入是造成正负偏差角缺乏对称性的原因。尽管新方法简单且计算成本不高,但它与大涡流模拟(LES)和风洞试验非常吻合。在新模型的基础上,我们推导出了在错位转子上实现功率最大化的最优控制策略。此外,我们还通过唤醒转向使两个涡轮机组的总功率最大化,改进了基于余弦定律的解决方案。
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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