Optimum Design of Extra-Large Wind Turbine Monopile Covering Multiple Conditions

Day 2 Wed, September 28, 2022 Pub Date : 2022-09-19 DOI:10.5957/smc-2022-081

Matteo Bucchini, Zhiyong Yang, R. Basu, Aimin Wang, W. Lee, G. Baxter, R. Sielski, Raffaele Frontera, Gabriele Degrassi

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Abstract

Offshore wind energy is developing rapidly in the United States, particularly off the East coast, which has an extensive continental shelf and where the water depths are such that monopile wind turbines founded directly on the seabed are the most attractive. In a previous paper, the authors demonstrated how the design of a monopole for a 15-MW turbine can be optimized to survive hurricane conditions using several commercially available design tools. This paper extends the study to address multiple loading conditions, including operational working conditions. To do that, different optimizations were run in parallel to find a global solution for multidisciplinary optimization. In the previous study, three independent design tools were used: Wind-plant Integrated System Design and Engineering Model (WISDEM) which was developed by the National Renewable Energy Laboratory (NREL), ANSYS Workbench, a finite element analysis program commonly used in the industry, and the ModeFRONTIER integration platform. To simulate the additional loading conditions, the OpenFAST software from NREL is now included in the workflow to estimate the loads in the different conditions examined.

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超大型风力机多工况单桩优化设计

海上风能在美国发展迅速，特别是在东海岸，那里有广阔的大陆架，水深使得直接建在海床上的单桩风力涡轮机最具吸引力。在之前的一篇论文中，作者展示了如何使用几种商业上可用的设计工具来优化15mw涡轮机的单极子设计，使其在飓风条件下存活下来。本文将研究扩展到包括操作工况在内的多种加载条件。为此，并行运行不同的优化，以找到多学科优化的全局解决方案。在之前的研究中，使用了三种独立的设计工具:由国家可再生能源实验室(NREL)开发的风电场集成系统设计与工程模型(WISDEM)、行业常用的有限元分析程序ANSYS Workbench和ModeFRONTIER集成平台。为了模拟额外的负载条件，NREL的OpenFAST软件现在包含在工作流程中，以估计不同条件下的负载。

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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Day 2 Wed, September 28, 2022

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