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Flow Turbulence and Renewable Energy

湍流和可再生能源

基本信息

批准号：
203025-2012
负责人：
Ting, David
金额：
$ 1.46万
依托单位：
University of Windsor
依托单位国家：
加拿大
项目类别：
Discovery Grants Program - Individual
财政年份：
2014
资助国家：
加拿大
起止时间：
2014-01-01 至 2015-12-31
项目状态：
已结题

来源：
https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=546221
关键词：
Flow Turbulence Renewable Energy

项目摘要

Renewable energies such as wind and solar are verily at the mercy of the environmental turbulent wind that they are subject to. Strong and steady wind can furnish abundant clean energy via the promising wind turbines. The roles of flow fluctuations, however, are less obvious. Flow turbulence may break down the well-organized vortical flow structures of the wake, and hence, possibly mitigate the adverse effects of the wake on the downstream wind turbines. In fact, some turbulent flow can delay the aerodynamic stall and improve airfoil performance. On the other hand, pronounced fluctuations in the wind can lead to significant structural fatigue along with reduced wind power capturing. Similarly, the structures housing solar panels need to withstand the wind loads, among which the fluctuating drag and lift are of primal importance. While wind may be undesirable from the standpoint of structural integrity, it is needed to keep the solar panel cool, especially on a hot summer afternoon, to capitalize higher energy conversion efficiency. Overcoming these and other practical challenges requires both engineering ingenuities and improved fundamental understanding of the ever-perplexing, omnipresent flow turbulence. At the fundamental level, clean, isotropic turbulence remains a critical element which demands better understanding. Extreme diligence both in experimentation and in data reduction, along with improved analyses, are necessary in enhancing progress along this path. The proposed research consists of coupled parallel fundamental-application approaches specifically aimed at continuous improvement of the aforementioned clean energy technologies and progressive revelation of engineering turbulence.

风能和太阳能等可再生能源确实受到环境湍流的影响。强劲而稳定的风可以通过有前途的风力发电机提供丰富的清洁能源。然而，流量波动的作用不太明显。湍流可以破坏尾流的良好组织的涡流结构，并且因此可能减轻尾流对下游风力涡轮机的不利影响。事实上，一些湍流可以延迟气动失速，改善翼型性能。另一方面，风的显著波动可导致显著的结构疲劳，沿着降低的风能捕获。同样，太阳能电池板的结构需要承受风荷载，其中脉动阻力和升力是最重要的。虽然从结构完整性的角度来看，风可能是不期望的，但需要保持太阳能电池板凉爽，特别是在炎热的夏季下午，以利用更高的能量转换效率。克服这些和其他实际挑战需要工程的独创性和不断复杂的，无处不在的流动湍流的基本理解。在基本层面上，干净的，各向同性的湍流仍然是一个关键因素，需要更好的理解。极端勤奋的实验和数据减少，沿着与改进的分析，是必要的，在提高进步沿着这条path.The拟议的研究包括耦合平行的基本应用方法，专门针对上述清洁能源技术的不断改进和工程湍流的逐步启示。