Parametric FEA modelling of offshore wind turbine support structures: Towards scaling-up and CAPEX reduction

Maria Martinez-Luengo, Athanasios Kolios, Lin Wang
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引用次数: 19

Abstract

Parametric Finite Element Analysis (FEA) modelling is a powerful design tool often used for offshore wind. It is so effective because key design parameters (KDPs) can be modified directly within the python code, to assess their effect on the structure’s integrity, saving time and resources. A parametric FEA model of offshore wind turbine (OWT) support structures (consisting of monopile (MP), soil-structure interaction, transition piece (TP), grouted connection (GC) and tower) has been developed and validated. Furthermore, the different KDPs that impact on the design and scaling-up of OWT support structures were identified. The aim of the analyses is determining how different geometry variations will affect the structural integrity of the unit and if these could contribute to the turbine’s scale-up by either modifying the structure’s modal properties, improving its structural integrity, or reducing capital expenditure (CAPEX). To do so, three design cases, assessing different KDPs, have been developed and presented. Case A investigated how the TP’s and GC’s length influences the structural integrity. Case B evaluated the effect of size and number of stoppers in the TP, keeping a constant volume of steel; and Case C assessed the structure’s response to scour development. It is expected that this paper will provide useful information in the conceptual design and scale-up of OWT support structures, helping in the understanding of how KDPs can affect not only the structure’s health, but also its CAPEX.

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海上风力涡轮机支撑结构的参数化有限元建模:朝着扩大规模和降低资本支出的方向发展
参数化有限元分析(FEA)建模是一种强大的海上风电设计工具。它是如此有效,因为关键设计参数(kdp)可以直接在python代码中修改,以评估它们对结构完整性的影响,节省时间和资源。建立并验证了海上风力发电机(OWT)支撑结构(包括单桩、土-结构相互作用、过渡件、注浆连接和塔架)的参数化有限元模型。此外,本文还确定了影响OWT支持结构设计和规模的不同kdp。分析的目的是确定不同的几何形状变化将如何影响机组的结构完整性,以及这些变化是否可以通过改变结构的模态特性、提高结构完整性或降低资本支出(CAPEX)来促进涡轮机的规模扩大。为此,我们编制了三个设计案例,评估不同的发展发展计划。病例A研究了TP和GC的长度如何影响结构完整性。案例B评估了TP中塞的大小和数量的影响,保持恒定的钢体积;案例C评估了结构对冲刷发展的响应。预计本文将为OWT支持结构的概念设计和规模扩展提供有用的信息,帮助理解kdp如何不仅影响结构的健康,而且影响其资本支出。
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