Computational fluid dynamics (CFD) modeling of actual eroded wind turbine blades

IF 3.6 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY Wind Energy Science Pub Date : 2023-01-04 DOI:10.5194/wes-8-41-2023
K. Vimalakanthan, Harald van der Mijle Meijer, Iana Bakhmet, G. Schepers
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引用次数: 4

Abstract

Abstract. Leading edge erosion (LEE) is one of the most critical degradation mechanisms that occur with wind turbine blades (WTBs), generally starting from the tip section of the blade. A detailed understanding of the LEE process and the impact on aerodynamic performance due to the damaged leading edge (LE) is required to select the most appropriate leading edge protection (LEP) system and optimize blade maintenance. Providing accurate modeling tools is therefore essential. This paper presents a two-part study investigating computational fluid dynamics (CFD) modeling approaches for different orders of magnitudes in erosion damage. The first part details the flow transition modeling for eroded surfaces with roughness on the order of 0.1–0.2 mm, while the second part focuses on a novel study modeling high-resolution scanned LE surfaces from an actual blade with LEE damage on the order of 10–20 mm (approx. 1 % chord); 2D and 3D surface-resolved Reynolds-averaged Navier–Stokes (RANS) CFD models have been applied to investigate wind turbine blade sections in the Reynolds number (Re) range of 3–6 million. From the first part, the calibrated CFD model for modeling flow transition accounting for roughness shows good agreement of the aerodynamic forces for airfoils with leading-edge roughness heights on the order of 140–200 µm while showing poor agreement for smaller roughness heights on the order of 100 µm. Results from the second part of the study indicate that up to a 3.3 % reduction in annual energy production (AEP) can be expected when the LE shape is degraded by 0.8 % of the chord, based on the NREL5MW turbine. The results also suggest that under fully turbulent conditions, the degree of eroded LE shapes studied in this work show the minimal effect on the aerodynamic performances, which results in a negligible difference to AEP.
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实际侵蚀型风力发电机叶片的计算流体动力学(CFD)建模
摘要前缘侵蚀(LEE)是风力涡轮机叶片(WTBs)最关键的退化机制之一,通常从叶片的尖端部分开始。为了选择最合适的前缘保护(LEP)系统并优化叶片维护,需要详细了解LEE过程以及前缘损坏(LE)对气动性能的影响。因此,提供准确的建模工具是必不可少的。本文分两部分研究了不同数量级侵蚀损伤的计算流体力学(CFD)建模方法。第一部分详细介绍了粗糙度为0.1-0.2 mm的侵蚀表面的流动过渡建模,而第二部分则侧重于对实际叶片的高分辨率扫描LE表面进行建模,其中LEE损伤为10-20 mm(约20毫米)。1%和弦);二维和三维表面分辨Reynolds-average Navier-Stokes (RANS) CFD模型已被应用于研究雷诺数(Re)在3-6百万范围内的风力涡轮机叶片截面。从第一部分可以看出,校正后的考虑粗糙度的流动过渡CFD模型对前缘粗糙度高度为140-200 μ m的翼型气动力具有较好的一致性,而对较小的粗糙度高度为100 μ m的翼型气动力的一致性较差。研究第二部分的结果表明,基于NREL5MW涡轮机,当LE形状降低0.8%的弦值时,预计年发电量(AEP)将减少3.3%。结果还表明,在完全湍流条件下,本文研究的LE形状侵蚀程度对气动性能的影响最小,对AEP的影响可以忽略不计。
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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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
期刊最新文献
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