通过流体-结构-海底综合模型试验研究海上风力涡轮机单桩基础的应变响应

IF 4.6 2区 工程技术 Q1 ENGINEERING, CIVIL
Jinyong Guo , Bo Han , Zhenlin Ma , Bo-nan Zhang , Meng Guo , Ben He
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引用次数: 0

摘要

在服役期间,海上风力涡轮机(OWT)必须承受风、波浪和洋流的多重流体载荷。而风力涡轮机的动态特性受到风力涡轮机结构、地基和流体环境之间耦合效应的影响。因此,我们制作了一个几何比例为 1:100 的 NERL-5MW 风机完整模型,并在风洞-水流-地基综合实验系统中进行了一系列模型试验。在实际流体条件下,首次研究了 OWT 单桩基础的应变响应特性。首次研究了真实流体条件下 OWT 单桩基础的应变响应特性。实验结果表明,加载状态、加载强度和 OWT 工作状态对单桩的动态应变响应有显著影响。在复杂流体载荷的耦合效应下,波浪效应增强了单桩基础顶部区域的应变响应,这是由于地基变形放大了作用在 OWT 上部的风载荷效应。此外,随着荷载强度的增加,空气动力荷载对 OWT 动态响应的主导作用变得更加明显。因此,作用在顶部的空气动力荷载的影响与作用在地基上的水动力荷载的影响之间的耦合效应不容忽视。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Research on the strain response of offshore wind turbine monopile foundation through integrated fluid-structure-seabed model test
During the service period, the offshore wind turbine (OWT) must withstand multiple fluid loads of wind, waves and ocean currents. While the dynamic characteristics of OWT are affected by the coupling effect between the wind turbine structure, foundation, and fluid environment. Therefore, a complete model with geometrical scaling of 1:100 of the NERL-5MW wind turbine was manufactured and a series of model tests were conducted in the integrated Wind Tunnel-Flume-Foundation experimental system. The strain response characteristics of the monopile foundation were studied for the first time while the OWT under real fluid conditions. The strain response characteristics of OWT monopile foundation in the real fluid were studied for the first time. The experimental results revealed that the loading state, load intensity, and OWT operating state have significant effects on the dynamic strain response of the monopile. Under the coupling effect of complex fluid loads, the effect of waves enhances the strain response in the top region of the monopile foundation, which is attributed to the fact that the deformation of the foundation has amplified the effect of wind load acting on the upper part of OWT. Moreover, the dominant role of aerodynamic loads on the dynamic response of the OWT becomes more pronounced as the load intensity increases. Therefore, coupling effect between the influence of aerodynamic loads acting on the top and the impact of the hydrodynamic load acting on the foundation cannot be ignored.
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来源期刊
Ocean Engineering
Ocean Engineering 工程技术-工程:大洋
CiteScore
7.30
自引率
34.00%
发文量
2379
审稿时长
8.1 months
期刊介绍: Ocean Engineering provides a medium for the publication of original research and development work in the field of ocean engineering. Ocean Engineering seeks papers in the following topics.
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