Comparative turbulent three-dimensional Navier–Stokes hydrodynamic analysis and performance assessment of oscillating wings for renewable energy applications

Jernej Drofelnik , M. Sergio Campobasso
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引用次数: 19

Abstract

Oscillating wings can extract energy from an oncoming water or air stream, and first large-scale marine demonstrators are being tested. Oscillating wing hydrodynamics is highly unsteady, may feature dynamic stall and leading edge vortex shedding, and is significantly three-dimensional due to finite-wing effects. Understanding the interaction of these phenomena is essential for maximizing power generation efficiency. Much of the knowledge on oscillating wing hydrodynamics stemmed from two-dimensional low-Reynolds number computational fluid dynamics studies and laboratory testing; real installations, however, will feature Reynolds numbers higher than 1 million and unavoidable finite-wing-induced losses. This study investigates the impact of flow three-dimensionality on the hydrodynamics and the efficiency of a realistic aspect ratio 10 device in a stream with Reynolds number of 1.5 million. The improvements achievable by using endplates to reduce finite-wing-induced losses are also analyzed. Three-dimensional time-dependent Navier–Stokes simulations using the shear stress transport turbulence model and a 30-million-cell grid are performed. Detailed comparative hydrodynamic analyses of the finite and the infinite wings reveal that flow three-dimensionality reduces the power generation efficiency of the finite wing with sharp tips and that with endplates by about 17% and 12% respectively. Presented analyses suggest approaches to further reducing these power losses.

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可再生能源应用中振荡翼的比较湍流三维Navier-Stokes水动力分析和性能评估
摆动的翅膀可以从迎面而来的水或气流中提取能量,第一次大规模的海洋演示正在测试中。振荡翼流体动力学是高度非定常的,可能具有动态失速和前缘涡脱落的特征,并且由于有限翼效应而具有明显的三维性。了解这些现象之间的相互作用对于最大限度地提高发电效率至关重要。振荡翼流体力学的大部分知识来源于二维低雷诺数计算流体动力学研究和实验室测试;然而,在实际安装中,雷诺数将高于100万,并且不可避免地会造成有限翼损失。本文研究了在雷诺数为150万的流场中,流动三维对实际展弦比为10的装置的流体力学和效率的影响。文中还分析了采用端板减少有限翼致损失所能达到的改进效果。三维时间依赖的Navier-Stokes模拟使用剪切应力传输湍流模型和3000万单元网格进行。对有限翼和无限翼进行了详细的流体力学对比分析,结果表明,流动三维化使尖尖有限翼和端板有限翼的发电效率分别降低了17%和12%左右。提出的分析建议了进一步减少这些功率损耗的方法。
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