Analysis of Wind Turbine Wake Dynamics by a Gaussian-Core Vortex Lattice Technique

Dynamics Pub Date : 2024-02-01 DOI:10.3390/dynamics4010006

Apurva Baruah, Fernando Ponta

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引用次数: 0

Abstract

The development and deployment of the next generation of wind energy systems calls for simulation tools that model the entire wind farm while balancing accuracy and computational cost. A full-system wind farm simulation must consider the atmospheric inflow, the wakes and consequent response of the multiple turbines, and the implementation of the appropriate farm-collective control strategies that optimize the entire wind farm’s output. In this article, we present a novel vortex lattice model that enables the effective representation of the complex vortex wake dynamics of the turbines in a farm subject to transient inflow conditions. This work extends the capabilities of our multi-physics suite, CODEF, to include the capability to simulate the wakes and the high-fidelity aeroelastic response of multiple turbines in a wind farm. Herein, we compare the results of our GVLM technique with the LiDAR measurements obtained at Sandia National Laboratories’ SWiFT facility. The comparison shows remarkable similarities between the simulation and field measurements of the wake velocity. These similarities demonstrate our model’s capabilities in capturing the entire wake of a wind turbine at a significantly reduced computational cost as compared to other techniques.

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利用高斯核心涡流晶格技术分析风力涡轮机的风浪动力学特性

下一代风能系统的开发和部署需要既能模拟整个风电场，又能兼顾精度和计算成本的模拟工具。全系统风电场仿真必须考虑大气流入、多个涡轮机的摆动和随之而来的响应，以及实施适当的风电场集合控制策略，以优化整个风电场的输出。在这篇文章中，我们介绍了一种新型涡流网格模型，该模型可有效表示风电场中涡轮机在瞬态流入条件下的复杂涡流尾流动态。这项工作扩展了我们的多物理场套件 CODEF 的功能，使其能够模拟风电场中多个涡轮机的涡流和高保真气动弹性响应。在此，我们将 GVLM 技术的结果与桑迪亚国家实验室 SWiFT 设施获得的激光雷达测量结果进行了比较。比较结果表明，模拟结果与现场测量的尾流速度非常相似。这些相似性表明，与其他技术相比，我们的模型能够捕捉风力涡轮机的整个尾流，而且计算成本大大降低。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Dynamics

CiteScore

1.20

自引率

0.00%

发文量