A comparison of dynamic inflow models for the blade element momentum method

IF 3.6 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY
S. Mancini, K. Boorsma, G. Schepers, F. Savenije
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引用次数: 3

Abstract

Abstract. With the increase in rotor sizes, the implementation of innovative pitch control strategies, and the first floating solutions entering the market, the importance of unsteady aerodynamic phenomena in the operation of modern offshore wind turbines has increased significantly. Including aerodynamic unsteadiness in blade element momentum (BEM) methods used to simulate wind turbine design envelopes requires specific sub-models. One of them is the dynamic inflow model, which attempts to reproduce the effects of the unsteady wake evolution on the rotor plane induction. Although several models have been proposed, the lack of a consistent and comprehensive comparison makes their relative performance in the simulation of large rotors still uncertain. More importantly, different dynamic inflow model predictions have never been compared for a standard fatigue load case, and thus it is not clear what their impact on the design loads estimated with BEM is. The present study contributes to filling these gaps by implementing all the main dynamic inflow models in a single solver and comparing their relative performance on a 220 m diameter offshore rotor design. Results are compared for simple prescribed blade pitch time histories in uniform inflow conditions first, verifying the predictions against a high-fidelity free-vortex-wake model and showing the benefit of new two-constant models. Then the effect of shed vorticity is investigated in detail, revealing its major contribution to the observed differences between BEM and free-vortex results. Finally, the simulation of a standard fatigue load case prescribing the same blade pitch and rotor speed time histories reveals that including a dynamic inflow model in BEM tends to increase the fatigue load predictions compared to a quasi-steady BEM approach, while the relative differences among the models are limited.
叶片单元动量法的动态入流模型比较
摘要随着转子尺寸的增大,创新螺距控制策略的实施,以及首批浮动解决方案进入市场,非定常气动现象在现代海上风力发电机运行中的重要性显著增加。包括气动非定常在内的叶片单元动量(BEM)方法用于模拟风力机设计包壳需要特定的子模型。其中一种是动态入流模型,它试图再现非定常尾迹演化对旋翼平面感应的影响。虽然已经提出了几种模型,但由于缺乏一致和全面的比较,使得它们在大型转子仿真中的相对性能仍然不确定。更重要的是,从未对标准疲劳载荷情况下的不同动态入流模型预测进行过比较,因此尚不清楚它们对边界元法估计的设计载荷的影响。本研究通过在单个求解器中实现所有主要的动态入流模型,并比较它们在直径220 m的海上转子设计上的相对性能,有助于填补这些空白。首先比较了在均匀入流条件下简单规定桨距时间历史的结果,用高保真的自由涡-尾迹模型验证了预测结果,并展示了新的双常数模型的优势。在此基础上,详细分析了流场涡量的影响,揭示了流场涡量对边界元法和自由涡结果差异的主要影响。最后,对相同桨距和转子转速时程的标准疲劳载荷情况进行了仿真,结果表明,与准稳态边界元法相比,在边界元法中加入动态入流模型倾向于提高疲劳载荷预测,而模型之间的相对差异是有限的。
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来源期刊
Wind Energy Science
Wind Energy Science GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY-
CiteScore
6.90
自引率
27.50%
发文量
115
审稿时长
28 weeks
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