Control Co-Design Studies for a 22 MW Semisubmersible Floating Wind Turbine Platform

Journal of Physics: Conference Series Pub Date : 2024-06-01 DOI:10.1088/1742-6596/2767/8/082020

D. Zalkind, P. Bortolotti

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Abstract

We present a control co-design software framework that can be used to optimize floating wind turbines and their controllers. Because this framework has many options for design variables, constraints, and merit figures, along with modeling fidelity levels, we seek to demonstrate best practices for using the tool while designing a floating platform for the new 22 MW offshore reference wind turbine developed within the International Energy Agency Wind Technology Commercialization Programme 55 on Reference Wind Turbines and Farms. During these studies, we evaluate the use of different simulation fidelity levels, the effect of using different load cases for controller tuning, and the difference between sequential and simultaneous control co-design solutions. Based on these efforts, we suggest using an algorithm that performs an initial search of the design space before optimization. We find that solving smaller optimization problems, in a sequential manner, leads to more reliable outcomes in fewer iterations than larger, simultaneous control co-design solutions. However a simultaneous CCD solution produces a platform with a 2% lower mass than the sequential CCD outcome.

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22 兆瓦半潜式浮动风力涡轮机平台的控制协同设计研究

我们介绍了一种控制协同设计软件框架，可用于优化浮动风力涡轮机及其控制器。由于该框架在设计变量、约束条件和优点数字以及建模保真度方面有许多选项，因此我们在为国际能源机构风能技术商业化计划 55（参考风力涡轮机和风电场）中开发的新型 22 兆瓦海上参考风力涡轮机设计浮动平台时，试图展示使用该工具的最佳实践。在这些研究中，我们评估了不同模拟保真度的使用情况、使用不同负载情况进行控制器调整的效果，以及顺序控制和同步控制协同设计解决方案之间的差异。基于这些努力，我们建议使用一种算法，在优化之前对设计空间进行初始搜索。我们发现，与较大的同步控制协同设计方案相比，以顺序方式解决较小的优化问题，能以较少的迭代次数获得更可靠的结果。然而，同步控制协同设计方案产生的平台质量比顺序控制协同设计方案的结果低 2%。

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

Journal of Physics: Conference Series

CiteScore

1.20

自引率

0.00%

发文量