{"title":"Going beyond BEM with BEM: an insight into dynamic inflow effects on floating wind turbines","authors":"F. Papi, J. Jonkman, A. Robertson, A. Bianchini","doi":"10.5194/wes-9-1069-2024","DOIUrl":null,"url":null,"abstract":"Abstract. Blade element momentum (BEM) theory is the backbone of many industry-standard wind turbine aerodynamic models. To be applied to a broader set of engineering problems, BEM models have been extended since their inception and now include several empirical corrections. These models have benefitted from decades of development and refinement and have been extensively used and validated, proving their adequacy in predicting aerodynamic forces of horizontal-axis wind turbine rotors in most scenarios. However, the analysis of floating offshore wind turbines (FOWTs) introduces new sets of challenges, especially if new-generation large and flexible machines are considered. In fact, due to the combined action of wind and waves and their interaction with the turbine structure and control system, these machines are subject to unsteady motion and thus unsteady inflow on the wind turbine's blades, which could put BEM models to the test. Consensus has not been reached on the accuracy limits of BEM in these conditions. This study contributes to the ongoing research on the topic by systematically comparing four different aerodynamic models, ranging from BEM to computational fluid dynamics, in an attempt to shed light on the unsteady aerodynamic phenomena that are at stake in FOWTs and whether BEM is able to model them appropriately. Simulations are performed on the UNAFLOW 1:75 scale rotor during imposed harmonic surge and pitch motion. Experimental results are available for these conditions and are used for baseline validation. The rotor is analyzed in both rated operating conditions and low wind speeds, where unsteady aerodynamic effects are expected to be more pronounced. Results show that BEM, despite its simplicity, can adequately model the aerodynamics of FOWTs in most conditions if augmented with a dynamic inflow model.\n","PeriodicalId":509667,"journal":{"name":"Wind Energy Science","volume":"14 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-05-03","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Wind Energy Science","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.5194/wes-9-1069-2024","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Abstract. Blade element momentum (BEM) theory is the backbone of many industry-standard wind turbine aerodynamic models. To be applied to a broader set of engineering problems, BEM models have been extended since their inception and now include several empirical corrections. These models have benefitted from decades of development and refinement and have been extensively used and validated, proving their adequacy in predicting aerodynamic forces of horizontal-axis wind turbine rotors in most scenarios. However, the analysis of floating offshore wind turbines (FOWTs) introduces new sets of challenges, especially if new-generation large and flexible machines are considered. In fact, due to the combined action of wind and waves and their interaction with the turbine structure and control system, these machines are subject to unsteady motion and thus unsteady inflow on the wind turbine's blades, which could put BEM models to the test. Consensus has not been reached on the accuracy limits of BEM in these conditions. This study contributes to the ongoing research on the topic by systematically comparing four different aerodynamic models, ranging from BEM to computational fluid dynamics, in an attempt to shed light on the unsteady aerodynamic phenomena that are at stake in FOWTs and whether BEM is able to model them appropriately. Simulations are performed on the UNAFLOW 1:75 scale rotor during imposed harmonic surge and pitch motion. Experimental results are available for these conditions and are used for baseline validation. The rotor is analyzed in both rated operating conditions and low wind speeds, where unsteady aerodynamic effects are expected to be more pronounced. Results show that BEM, despite its simplicity, can adequately model the aerodynamics of FOWTs in most conditions if augmented with a dynamic inflow model.
摘要叶片元素动量(BEM)理论是许多行业标准风力涡轮机空气动力学模型的基础。为了应用于更广泛的工程问题,BEM 模型从一开始就进行了扩展,现在已包括若干经验修正。这些模型得益于数十年的发展和完善,已被广泛使用和验证,证明其足以预测大多数情况下水平轴风力涡轮机转子的空气动力。然而,浮式海上风力涡轮机(FOWT)的分析引入了一系列新的挑战,尤其是在考虑到新一代大型灵活机器的情况下。事实上,由于风和浪的共同作用,以及它们与涡轮机结构和控制系统的相互作用,这些机器会出现不稳定运动,从而导致风力涡轮机叶片上出现不稳定流入,这对 BEM 模型提出了考验。关于 BEM 在这些条件下的精度极限,目前尚未达成共识。本研究系统地比较了从 BEM 到计算流体力学等四种不同的空气动力学模型,试图揭示风力涡轮机中的不稳定空气动力学现象,以及 BEM 是否能够对其进行适当建模,从而为正在进行的相关研究做出贡献。对 UNAFLOW 1:75 比例的转子在外加谐波激增和俯仰运动时进行了模拟。这些条件下的实验结果可用于基线验证。在额定运行条件和低风速条件下对转子进行了分析,在低风速条件下,不稳定气动效应预计会更加明显。结果表明,尽管 BEM 很简单,但如果辅以动态流入模型,它可以在大多数条件下对 FOWT 的空气动力学进行充分建模。