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Simulation of Wind Turbine Sites Increases Power Yield and Reduces Risk
技术
- 分析与建模 - 数字孪生/模拟
- 传感器 - 流量计
适用行业
- 电网
- 可再生能源
适用功能
- 产品研发
用例
- 数字孪生
- 虚拟现实
挑战
陆上风电场的开发需要详细了解盛行风况如何与当地地形和潜在的风力涡轮机安装相互作用。目前使用的许多软件程序不太适合复杂的陆上地形,其中大气稳定性、林业和涡轮机相互作用等因素起着重要作用。准确预测环境条件和唤醒条件下的风速、风切变、风转向和湍流强度等风况对于智能项目设计至关重要。挑战在于找到一种解决方案,能够准确地模拟这些复杂的风气候并优化涡轮机的放置,以最大限度地提高能源产量并最大限度地降低风险。
关于客户
SSE 是英国和爱尔兰最大的可再生能源发电商,拥有重要的风能投资组合。该公司参与陆上风电场的开发,需要详细了解盛行风况如何与当地地形和潜在的风力涡轮机安装相互作用。 SSE 需要一种能够准确模拟复杂风气候并优化涡轮机放置的解决方案,以最大限度地提高能源产量并最大限度地降低风险。
解决方案
SSE 与 ANSYS ACE 咨询和支持团队合作,将 ANSYS CFX 与 WindModeller 部署到内部 HPC 集群上。该解决方案经过 SSE 投资组合中超过 25 个陆上开发和运营风电项目的验证。带有 WindModeller 的 ANSYS CFX 现在已成为 SSE 风电场开发工具集的重要组成部分。 WindModeller 用于能源生产评估、场地适宜性分析、涡轮机定位和涡轮机模型选择。它还可用于计算风资源并评估特定涡轮机类型的场地适宜性,确保场地湍流条件不会对涡轮机寿命产生不利影响。
运营影响
数量效益
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