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Zachary Metz_ 浮动式海上风力涡轮机系泊解决方案中的岩土工程挑战.pdf

上传人: Fl****zo 编号:718554 2025-06-22 26页 4.69MB

1、Geotechnical Challenges in Mooring Solutions for Floating Offshore Wind Turbines Presented byZach MetzBerger GeosciencesOceanology International12-14 March 2024London,ExcelBergerGeosciences,2024IntroductionOffshore wind energy market grew by 15%in 2022,reaching 52.7 GW capacityFloating offshore wind

2、 capacity projected to exceed 10 GW by 2030 globallyU.S.aims to reduce floating wind energy costs by over 70%by 2035Technological,investment,and policy decisions critical for industrys next five yearsImage Source:Bauer NREL(2017)BergerGeosciences,2024IntroductionInstalling FOWTs comes with complex g

3、eotechnical challengesOther considerations include stability,harsh marine environment,and maintenanceImage Sources:Bauer NREL(2020);EDP RenewablesBergerGeosciences,2024Need for Thorough Geotechnical InvestigationImage Source:Modified from TDI-Brooks,2021BergerGeosciences,2024Need for Thorough Geotec

4、hnical InvestigationResults are used to design and analyze the effects of:Anchor DesignAerodynamic LoadingHydrodynamic LoadingImage Source:Clement et al.(2021)BergerGeosciences,2024Soil(Seabed)ConditionsImage Sources:Offshore Wind Design ASBergerGeosciences,2024Soil(Seabed)ConditionsSoil stiffness c

5、ould also influence the anchorage performance of the FOWTFor anchor piles,the soil-pile stiffness can be expressed using p-y,t-z,and q-z curves Image Source:Malek&Islam,2010BergerGeosciences,2024Soil(Seabed)ConditionsPermeability of the soil can influence the drainage conditions below the seabedThis

6、 could influence the installation depth of suction caisson anchorsImage Source:GeminiBergerGeosciences,2024Anchor Selection1.Gravity-Base Anchor2.Pile Anchor3.Drag-Embedded Anchor4.Suction-type Anchor5.Torpedo-Embedded Anchor6.Anchor PlatesImage Source:Modified from Vryhof,2018BergerGeosciences,2024

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本文主要讨论了浮动式海上风力涡轮机(FOWTs)的系泊解决方案所面临的地质技术挑战。关键点如下: 1. 市场增长:2022年,海上风电市场增长了15%,总容量达到52.7GW;预计到2030年,全球浮动海上风电容量将超过10GW。 2. 技术挑战:安装FOWTs涉及复杂的地质技术问题,包括稳定性、恶劣的海洋环境等。 3. 地质调查:需要进行彻底的地质调查,以设计和分析锚设计、气动力学负载和流体动力学负载的影响。 4. 海床条件:海床土壤的刚度和渗透性会影响系泊性能和锚的安装深度。 5. 锚的选择:介绍了多种锚类型,包括重力基础锚、桩锚、拖曳嵌入式锚等。 6. 安装方法:讨论了不同类型的锚板安装方法及常见的系泊配置。 7. 案例研究:举例挪威的Hywind Tampen、苏格兰的Kincardine海上风电场等,说明面临的地质技术挑战。 8. 解决方案与建议:文章提出了潜在的解决方案和推荐措施。 9. 结论:强调了技术、投资和政策决策对未来五年行业发展的关键作用。 核心数据引用:美国计划到2035年将浮动风电成本降低70%以上。
"2030全球浮式风电展望如何?" "海底条件如何影响浮式风电稳定性?" "浮式风电场的未来维护挑战有哪些?"
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