Development of a Practical Soil Constitutive Model Suitable for the Design of Offshore Wind Turbine Foundations in Sand Considering Cyclic Loading

开发适用于考虑循环荷载的沙地海上风力发电机基础设计的实用土壤本构模型

• 批准号: 2506453
• 金额: --
• 依托单位: University of Oxford
• 依托单位国家: 英国
• 项目类别: Studentship
• 财政年份: 2020
• 资助国家: 英国
• 起止时间: 2020 至 无数据
• 项目状态: 未结题
• 来源: https://gtr.ukri.org/projects?ref=studentship-2506453
• 关键词: Development; Practical; Soil; Constitutive; Model

Offshore wind turbines are subject to cycles of loading and unloading from their environment i.e. wind and waves. This cyclic loading can significantly weaken the foundations over time leading to a reduced loading capacity when compared with a static load of the same magnitude. Structures can fail due to the build-up of plastic strain in the soil over time through successive loading cycles. In addition, there are failure mechanisms caused by liquefaction (where pore water pressure builds up and soil friction de-creases). Through laboratory experiments this project will seek to develop a constitutive model of sandy soil under cyclic loading. This will provide a better understanding of the behaviour of sandy soils with cyclic loads applied. Therefore, it should be possible to improve the design of offshore wind turbine foundations. This is of particular significance to the UK as much of the seabed surrounding Britain has at least partial presence of sandy layers, with some areas comprised almost entirely of sandy soil e.g. southern North Sea. Improvements in the design of offshore wind turbine foundations should lead to material and cost savings, helping to drive down the levelised cost of energy.The project methodology will be focussed around gathering results from cyclic triaxial tests. Triaxial tests are a standard industry test used to measure the mechanical response of a soil sample to prescribed stress and/or strain boundary conditions. The cyclic triaxial tests will apply computer controlled cyclic loads to a range of samples prepared with different initial densities and stress histories. The samples will be prepared in the lab, as opposed to testing cored samples from the field due to the tendency of sandy soils to break apart when loads are released. The results will be used to develop and calibrate a constitutive soil model, which will seek to improve the currently available models' shortcomings with respect to cyclic loading. Sandy soils are complex and therefore difficult to define fully with a constitutive model. Existing models prioritise modelling either static or cyclic loads at the expense of reducing accuracy with respect to the other load type. This project is novel in seeking to combine both cyclic and static loads into a single constitutive model.This project is part of the Wind and Marine Energy Systems and Structures (WAMESS) Centre for Doctoral Training and falls within the EPSRC Wind Power, Ground Engineering and Energy research areas. This project will be run in partnership with Fugro, making use of their large commercial soil testing laboratory in Wallingford (near Oxford). The project will work in tandem with another doctoral project of a similar aim, but more focussed on mathematical and computational modelling aspects.

海上风力涡轮机经受从其环境（即风和波浪）加载和卸载的循环。与相同量级的静态荷载相比，这种循环荷载会随着时间的推移显著削弱地基，导致荷载能力降低。随着时间的推移，通过连续的加载循环，土壤中的塑性应变会逐渐积累，从而导致结构失效。此外，还有液化引起的破坏机制（孔隙水压力增加，土壤摩擦力减小）。通过室内试验，本项目将寻求开发循环荷载下桑迪的本构模型。这将提供一个更好的了解桑迪的行为与循环荷载的应用。因此，应该有可能改进海上风力涡轮机基础的设计。这对英国特别重要，因为英国周围的大部分海底至少部分存在桑迪层，有些地区几乎完全由桑迪土壤组成，例如北海南部。海上风力涡轮机基础设计的改进应能节省材料和成本，有助于降低能源成本。该项目方法将集中于收集循环三轴试验的结果。三轴试验是一种标准的工业试验，用于测量土壤样品对规定应力和/或应变边界条件的机械响应。循环三轴试验将计算机控制的循环载荷施加到一系列以不同初始密度和应力历史制备的样品上。由于桑迪在释放荷载时易于破裂，因此将在实验室中制备样品，而不是在现场测试取芯样品。研究结果将被用来开发和校准本构土模型，这将寻求改善目前可用的模型的缺点方面的循环荷载。桑迪是一种复杂的土，因此很难用一个本构模型完全定义。现有的模型优先考虑静态或循环载荷的建模，以降低其他载荷类型的精度为代价。该项目是将循环荷载和静态荷载结合到一个本构模型中的一个创新项目。该项目是风能和海洋能源系统与结构（WAMESS）博士培训中心的一部分，福尔斯EPSRC风能，地面工程和能源研究领域。该项目将与Fugro合作，利用他们在沃灵福德（牛津附近）的大型商业土壤测试实验室。该项目将与另一个类似目标的博士项目一起工作，但更侧重于数学和计算建模方面。