Beatrice Offshore Wind Project, Wind Turbine Generator Foundation Design

A. MacLeay, T. Hodgson
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Abstract

The Beatrice Offshore Wind project comprises the development of 84 number 7MW turbines located in the Moray Firth in the North of Scotland. It is one of the most northerly and exposed sites globally and also the deepest site for fixed foundations for offshore wind. The paper describes the design challenges and how they were addressed. The solutions are likely to be of interest to anyone else developing a deep water offshore wind project, especially with variable soil conditions and a significant water depth range. The Beatrice WTG foundations were completed as an EPCI project with close integration between the EPCI contractor, designer, fabrication and installation teams. Across the site water depths ranged from 35-68m, however, this range was reduced when a small number of outliers were discounted. The final range was 38-55m. There was also a significant variation in soil conditions across the site and this created significant challenges when attempting to standardise the design. Global analysis of the selected structures under wind and wave conditions was performed using Sequential Coupled Analysis (SCA) with BHawC and ANSYS ASAS software packages. The analysis was performed by passing information between the turbine supplier and the substructure designer to produce coupled wind and wave loading on the integrated jacket, WTG and tower system. The jackets are the largest ever designed and installed for offshore wind. The solution developed was a 4 legged pre-piled jacket. The design was split up in to 5 clusters to address the water depth range. Associated with this a pile stick up range of 2-6m was adopted. No scour protection was used. The top half of the jacket, transition piece and much of the secondary steelwork was standardised across the site. The base dimension for the jacket and pile diameter was also standardised across the site to allow for re-use of a pre-piling template. The final foundations were installed in 2018. The grouted connection between the jacket and the pre-piles includes the first application offshore of Masterflow 9800 grout. Control of early age cycling was a key consideration in design of the jacket to pile interface. Piles were designed in accordance with the Imperial College Pile ‘ICP’ effective-stress pile design approaches for offshore foundations.
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Beatrice海上风电项目,风力发电机基础设计
Beatrice海上风电项目包括位于苏格兰北部马里湾的84台7兆瓦涡轮机的开发。它是全球最北端和最暴露的地点之一,也是海上风电固定基础最深的地点。本文描述了设计挑战以及如何解决这些挑战。这些解决方案可能会引起其他开发深水海上风电项目的人的兴趣,特别是在土壤条件多变和水深范围较大的情况下。Beatrice WTG地基作为EPCI项目完成,EPCI承包商、设计师、制造和安装团队紧密结合。整个场地的水深范围为35-68米,然而,当排除少数异常值时,这个范围会缩小。最终射程为38-55米。整个场地的土壤条件也有很大的变化,这在试图标准化设计时带来了巨大的挑战。采用BHawC和ANSYS ASAS软件包对所选结构进行了风浪条件下的全局分析。分析是通过在涡轮机供应商和子结构设计人员之间传递信息来进行的,以产生集成护套、WTG和塔系统上的耦合风浪载荷。这些夹克是有史以来为海上风电设计和安装的最大的夹克。最终的解决方案是一件四条腿的预堆夹克。设计分为5个集群,以解决水深范围问题。与此相配套的桩桩起桩范围为2-6m。没有使用防冲刷保护。夹套的上半部分、过渡件和大部分二次钢结构在整个现场进行了标准化。护套的基本尺寸和桩直径也在整个场地进行了标准化,以便重新使用预桩模板。最后的基础于2018年安装。套管和预桩之间的灌浆连接包括Masterflow 9800灌浆的首次海上应用。早期循环控制是套桩界面设计中需要重点考虑的问题。桩的设计是根据帝国理工学院桩' ICP '有效应力桩设计方法的海上基础。
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