A CFD STUDY ON WIND ASSISTED PROPULSION TECHNOLOGY FOR COMMERCIAL SHIPPING

Wind Propulsion 2021 Pub Date : 2021-09-16 DOI:10.3940/rina.win.2021.07

W. C. P. Hopes, D. R. Pearson, J. Buckingham

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Abstract

Wind assisted propulsion has the potential to significantly reduce emissions from global shipping, with a range of technologies available including wing sails, kites, Flettner Rotors, and Suction Aerofoils such as Turbosails. Despite this, there are only a few studies publicly available on the performance of Suction Aerofoils, which operate on the same principle as a traditional sail but use boundary layer suction to develop high lift coefficients. Therefore, a CFD study was carried out in Numeca FINE/Marine software to determine values for the lift and drag coefficients over a range of angles of attack and suction levels. Supplementary studies also investigated the effects of introducing an endplate to reduce end vortices, and the effect of a ship side on the wind speed incident on the Suction Aerofoil. The plots of lift and drag coefficients developed in this paper were used to inform the BMT-led VTAS project [1], as well as contributing to wider knowledge on wind assisted propulsion for shipping. Throughout the study, Suction Aerofoils continued to show promise as an effective means of auxiliary propulsion for ships, and their use should be encouraged as part of the range of solutions to tackle the pressing issue of climate change.

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商用船舶风助推进技术CFD研究

风力辅助推进技术有可能显著减少全球航运业的排放，包括翼帆、风筝、Flettner rotor和吸力翼型(如turboails)。尽管如此，关于吸力翼型性能的公开研究很少，它的工作原理与传统风帆相同，但利用边界层吸力来获得高升力系数。因此，在Numeca FINE/Marine软件中进行了CFD研究，以确定在攻角和吸力水平范围内的升力和阻力系数值。补充研究还研究了引入端板以减少端涡的影响，以及船侧对吸力翼型风速入射的影响。本文开发的升力和阻力系数图被用于bmt主导的VTAS项目[1]，并有助于更广泛地了解船舶风辅助推进。在整个研究过程中，吸式翼型作为一种有效的船舶辅助推进手段继续显示出前景，应该鼓励将其作为解决气候变化紧迫问题的一系列解决方案的一部分。

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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Wind Propulsion 2021

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