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Collaborative Research: Empowering Next Generation Offshore Wind Farms Through Systematic Characterization of Floating Wind Turbine Array Dynamics

合作研究：通过浮式风力涡轮机阵列动力学的系统表征来增强下一代海上风电场的能力

基本信息

批准号：
2034111
负责人：
Dennice Gayme
金额：
$ 33.81万
依托单位：
Johns Hopkins University
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2021
资助国家：
美国
起止时间：
2021-06-01 至 2024-05-31
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=2034111&HistoricalAwards=false
关键词：
Collaborative Research Empowering Next Generation

项目摘要

Higher and more consistent wind speeds, along with the abundance of available area, make offshore wind a promising pathway to increasing the percentage of US electricity supplied by renewable energy sources, such as utility scale wind farms. The depth of the water in many locations, e.g., off the west coast of the US, and the ability to place installations further from shore, where they are less controversial, make floating platforms an appealing choice for future installations. While onshore wind farms are well established, far less is known about how interactions between the ocean environment (e.g., waves) and turbine motions and their wakes affect power output efficiency and turbine wear in floating wind farms. This grant will support research that employs laboratory experiments and high-fidelity computer simulations that will enable more robust and realistic predictions of wind plant power output. The data to be generated in this project can be leveraged to make design and control changes to increase efficiency and resilience of floating wind farms. These advances will help pave the way to more installed wind power that increases the use of clean, renewable technologies, thereby decreasing the carbon footprint of our energy system. The construction and operation of large-scale power plants will also help create and sustain a vibrant new US wind energy economy. The project will train graduate students in the broad interdisciplinary tools of wind energy science. Broader community outreach will be achieved through curriculum developed for public entities (e.g., museums) and summer programs for K-12 students.This project will develop state-of-the art laboratory experiments and numerical simulation tools to measure, analyze and characterize the coupled wind, wave, wake and platform dynamics affecting the power output and local turbine properties in floating wind farms. The new knowledge and data developed through these studies will be exploited to create a suite of dynamical systems modeling, estimation and analysis tools that will provide better predictions of critical wind farm properties such as power output and turbine loading. The data will be interrogated using dynamical systems tools such as proper orthogonal decomposition and dynamic (Koopman) mode decomposition that enable us to infer important system properties for further analysis, model validation and to develop estimation techniques as the building blocks for future real-time estimation and control algorithms. The outcomes of this work include: (1) New system characterization approaches that couple laboratory and simulation tools to systematically explore how the coupled wind, wave, turbine wake and platform dynamics affect the wind farm properties over a broad range of interacting spatial and temporal scales; (2) A suite of physics-informed models that describe the dynamics of the interactions most relevant to operation, design and control of floating wind farms; and (3) Estimation approaches that exploit the data and modeling tools, while taking into account the sensing and actuation approaches that can be implemented within real-time control paradigms.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

更高和更稳定的风速，加上丰富的可用面积，使海上风电成为提高美国可再生能源（如公用事业规模的风力发电场）供电比例的有希望的途径。许多地方的水深，例如美国西海岸，以及远离海岸放置设备的能力，在那里他们的争议较少，使浮动平台成为未来安装的一个有吸引力的选择。虽然陆上风力发电场已经建立，但人们对海洋环境（例如海浪）与涡轮机运动及其尾迹之间的相互作用如何影响浮动风力发电场的功率输出效率和涡轮机磨损知之甚少。这笔拨款将支持采用实验室实验和高保真计算机模拟的研究，这将使风力发电厂的功率输出得到更可靠、更现实的预测。该项目生成的数据可用于设计和控制变更，以提高浮动风力发电场的效率和弹性。这些进步将有助于为更多安装风能铺平道路，从而增加清洁、可再生技术的使用，从而减少我们能源系统的碳足迹。大型发电厂的建设和运营也将有助于创造和维持一个充满活力的新美国风能经济。该项目将在风能科学的广泛跨学科工具方面培训研究生。更广泛的社区外展将通过为公共实体（如博物馆）开发的课程和K-12学生的暑期课程来实现。该项目将开发最先进的实验室实验和数值模拟工具，以测量、分析和表征影响浮式风电场功率输出和本地涡轮机性能的耦合风、波、尾流和平台动力学。通过这些研究开发的新知识和数据将用于创建一套动力系统建模，估计和分析工具，这些工具将提供更好的关键风电场特性预测，如功率输出和涡轮机负载。数据将使用动态系统工具进行查询，例如适当的正交分解和动态（Koopman）模式分解，这使我们能够推断出重要的系统属性，以便进一步分析，模型验证并开发估计技术，作为未来实时估计和控制算法的构建块。本工作的成果包括：(1)新的系统表征方法，结合实验室和模拟工具，系统地探索风、波、涡轮尾流和平台动力学如何在广泛的相互作用的空间和时间尺度上影响风电场的特性；(2)一套物理模型，描述了与浮动风电场的运行、设计和控制最相关的相互作用的动力学；(3)利用数据和建模工具的估计方法，同时考虑到可以在实时控制范例中实现的传感和驱动方法。该奖项反映了美国国家科学基金会的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。