At a commercial scale tidal stream turbines are likely to be installed in multi-device arrays to maximise power output from a tidal site. This paper demonstrates a computationally efficient method for predicting the performance of an array. The approach parameterises the turbine by deriving momentum source terms using blade element (BE) theory. The source terms are added to Reynolds-averaged Navier-Stokes (RANS) momentum equations. The RANS+BE method is similar to blade element momentum (BEM) theory but can predict the flow field as well as the performance of the rotor. This investigation first verifies the RANS+BE method against BEM theory and shows good agreement, although tip-losses still need to be included. Secondly, it compares the RANS+BE approach to a parameterisation based on a uniform resistance coefficient, over a range of ambient turbulence values and thrust coefficients. The RANS+BE method generates increased azimuthal velocities in the near wake compared to the uniform approach. Finally the investigation compares results of a model of an infinitely wide array of turbines with five rows. The RANS+BE model can predict the performance of each turbine. and shows more rapid wake velocity recovery within the array. The investigation provides a detailed insight into the applicability of wake modelling techniques for the configuration of tidal stream turbine arrays.
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机译:在商业规模的潮汐流涡轮机中,可能安装在多器件阵列中,以最大化来自潮汐网站的功率输出。本文展示了用于预测阵列性能的计算有效方法。该方法通过使用刀片元素(BE)理论来通过推导动量源术语参加涡轮机。源术语被添加到reynolds平均的navier-stokes(RAN)动量方程。 RAN + BE方法类似于刀片元素动量(BEM)理论,但可以预测流场以及转子的性能。这项调查首先验证了RAN +是对BEM理论的方法,并表现出良好的一致性,尽管仍然需要包括尖端损失。其次,它将RAN +与基于均匀电阻系数的参数化进行比较,在一系列环境湍流值和推力系数范围内。与均匀的方法相比,RAN +是方法在接近尾迹中产生增加的方位角速度。最后,调查比较了五行的无限跨越涡轮机模型的结果。 RAN +是模型可以预测每个涡轮机的性能。并在阵列内显示更快速的唤醒速度恢复。该研究详细了解唤醒模拟技术对潮汐流涡轮机阵列的配置的适用性。
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