Effect of Fouling on the Performance of an Instream Turbine

Q3 Engineering

International Marine Energy Journal Pub Date : 2022-12-19 DOI:10.36688/imej.5.229-237

R. Starzmann, N. Kaufmann, P. Jeffcoate, Ray Pieroway, M. Guerra, A. Hay

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引用次数: 1

Abstract

As the tidal energy industry starts to mature towards commercial projects a key focus is on reliable power performance. As for any marine application, fouling poses a potential performance reduction risk for instream turbine deployments. SCHOTTEL HYDRO have developed their current commercial SCHOTTEL Instream Turbines. Four drivetrains with 6.3m rotors were deployed on the surface platform PLAT-I by Sustainable Marine Energy. One of PLAT-Is key features is access to the turbines for inspection and maintenance in situ. The system has undergone sea testing from 2017 to 2021 in Scotland and Nova Scotia (Canada). This paper presents the hydrodynamic rotor performance reduction due to fouling based on full-scale experimental results. An in-house blade element momentum model is used to quantify the changes of the hydrodynamic forces in terms of lift and drag for the hydrofoils used. Furthermore, the effect of fouling on the downstream wake was quantified in the field. The performance reduction due to fouling is significant and leads to a power drop of up to 43%, whereas the thrust is reduced by 25%. This is also reflected in a reduction of the turbine’s downstream wake as a “fouled” rotor extracts less energy from the flow. Modifications of the polar data, used for semi-empirical performance predictions, are able to predict the effect of fouling on the rotor performance. In general, the results derived from the testing prove the significance of access to the turbines in order to avoid reduction in the turbines’ performance due to fouling.

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污垢对入流式水轮机性能的影响

随着潮汐能行业开始向商业项目成熟，关键关注点是可靠的电力性能。对于任何船舶应用，结垢都会对内流涡轮机部署造成潜在的性能降低风险。肖特HYDRO已经开发出了目前商业化的肖特内流涡轮机。可持续海洋能源公司在PLAT-I水面平台上部署了四个6.3米转子的动力传动系统。PLAT的关键功能之一是可进入涡轮机进行现场检查和维护。2017年至2021年，该系统在苏格兰和新斯科舍省（加拿大）进行了海上测试。本文在全尺寸实验结果的基础上，介绍了由于结垢而导致的流体动力学转子性能下降。内部叶片单元动量模型用于量化所用水翼在升力和阻力方面的水动力变化。此外，现场对结垢对下游尾流的影响进行了量化。结垢导致的性能显著下降，导致功率下降高达43%，而推力下降了25%。这也反映在涡轮机下游尾流的减少上，因为“被污染”的转子从气流中提取的能量较少。用于半经验性能预测的极性数据的修改能够预测结垢对转子性能的影响。一般来说，测试结果证明了进入涡轮机的重要性，以避免因结垢而降低涡轮机的性能。

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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