Comparison of free vortex wake and blade element momentum results against large-eddy simulation results for highly flexible turbines under challenging inflow conditions

IF 3.6 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY Wind Energy Science Pub Date : 2023-03-24 DOI:10.5194/wes-8-383-2023
K. Shaler, Benjamin Anderson, L. Martínez‐Tossas, E. Branlard, Nick Johnson
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引用次数: 1

Abstract

Abstract. Throughout wind energy development, there has been a push to increase wind turbine size due to the substantial economic benefits. However, increasing turbine size presents several challenges, both physically and computationally. Modeling large, highly flexible wind turbines requires highly accurate models to capture the complicated aeroelastic response due to large deflections and nonstraight blade geometries. Additionally, the development of floating offshore wind turbines requires modeling techniques that can predict large rotor and tower motion. Free vortex wake methods model such complex physics while remaining computationally tractable to perform key simulations necessary during the turbine design process. Recently, a free vortex wake model – cOnvecting LAgrangian Filaments (OLAF) – was added to the National Renewable Energy Laboratory's engineering tool OpenFAST to allow for the aerodynamic modeling of highly flexible turbines along with the aero-hydro-servo-elastic response capabilities of OpenFAST. In this work, free vortex wake and low-fidelity blade element momentum (BEM) results are compared to high-fidelity actuator-line computational fluid dynamics simulation results via the Simulator fOr Wind Farm Applications (SOWFA) method for a highly flexible downwind turbine for varying yaw misalignment, shear exponent, and turbulence intensity conditions. Through these comparisons, it was found that for all considered quantities of interest, SOWFA, OLAF, and BEM results compare well for steady inflow conditions with no yaw misalignment. For OLAF results, this strong agreement with the SOWFA results was consistent for all yaw misalignment values. The BEM results, however, deviated significantly more from the SOWFA results with increasing absolute yaw misalignment. Differences between OLAF and BEM results were dominated by the yaw misalignment angle, with varying shear exponent and turbulence intensity leading to more subtle differences. Overall, OLAF results were more consistent than BEM results when compared to SOWFA results under challenging inflow conditions.
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高柔性涡轮自由涡尾迹和叶片单元动量计算结果与大涡模拟结果的比较
摘要在整个风能开发过程中,由于其巨大的经济效益,一直在推动增加风力涡轮机的尺寸。然而,涡轮机尺寸的增加在物理和计算上都带来了一些挑战。建模大型、高度柔性的风力涡轮机需要高度精确的模型来捕捉由于大挠度和非直叶片几何形状而引起的复杂气动弹性响应。此外,浮动海上风力涡轮机的开发需要能够预测大型转子和塔架运动的建模技术。自由涡尾流方法对这种复杂的物理现象进行建模,同时保持计算的灵活性,以便在涡轮机设计过程中进行必要的关键模拟。最近,国家可再生能源实验室的工程工具OpenFAST中添加了一个自由涡流尾流模型——cOnvecting LAgrangian Filaments(OLAF),以实现高度柔性涡轮机的空气动力学建模以及OpenFAST的气动-液压伺服弹性响应能力。在这项工作中,通过风电场应用模拟器(SOWFA)方法,将自由涡流尾流和低保真度叶片单元动量(BEM)结果与高保真度执行器线计算流体动力学模拟结果进行了比较,该方法适用于高度柔性的下风机,用于不同的偏航偏差、剪切指数和湍流强度条件。通过这些比较,发现对于所有考虑的感兴趣的量,SOWFA、OLAF和BEM结果在没有偏航偏差的稳定流入条件下比较良好。对于OLAF结果,这种与SOWFA结果的强烈一致性对于所有偏航未对准值是一致的。然而,随着绝对偏航偏差的增加,BEM结果与SOWFA结果的偏差明显更大。OLAF和BEM结果之间的差异主要由偏航偏转角决定,不同的剪切指数和湍流强度会导致更细微的差异。总体而言,在具有挑战性的流入条件下,与SOWFA结果相比,OLAF结果比BEM结果更一致。
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
A digital twin solution for floating offshore wind turbines validated using a full-scale prototype Free-vortex models for wind turbine wakes under yaw misalignment – a validation study on far-wake effects Feedforward pitch control for a 15 MW wind turbine using a spinner-mounted single-beam lidar A new methodology for upscaling semi-submersible platforms for floating offshore wind turbines An analytical linear two-dimensional actuator disc model and comparisons with computational fluid dynamics (CFD) simulations
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