CFD Analysis and Wind Tunnel Testing of Human Powered Vehicle Drag Coefficients

Volume 2: Fluid Applications and Systems; Fluid Measurement and Instrumentation Pub Date : 2021-08-10 DOI:10.1115/fedsm2021-65393

T. Estrada, K. Anderson, Ivan Gundersen, Chuck Johnston

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Abstract

This paper presents results of Computational Fluid Dynamics (CFD) modeling and experimental wind tunnel testing to predict the drag coefficient for a Human Powered Vehicle (HPV) entered in the World Human Powered Speed Challenge (WHPSC). Herein, a comparison of CFD to wind tunnel test data is presented for ten different HPV designs. The current study reveals that streamlining the nose cone, tail cone, and wheel housing allows for a reduction of drag forces in critical areas, and a reduced drag coefficient. This allows for a selection to be made during the design phase, prior to manufacturing. Drag coefficients were found to be in the range of 0.133 < CD < 0.273, depending on the type of HPV considered. Wind tunnel testing was performed on scale models of the HPV showing agreement to the CFD results on average to within 16%. The wind tunnel testing showed a 7.7% decrease in drag coefficient from the baseline HPV of 2019 to the baseline HPV of 2020. Thus, the wind tunnel data supported by CFD analysis was used to assist in the design of the HPV.

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人力动力车辆阻力系数CFD分析及风洞试验

本文介绍了一辆参加世界人类动力速度挑战赛(WHPSC)的人类动力汽车(HPV)的计算流体力学(CFD)建模和风洞试验结果。本文对10种不同的HPV设计进行了CFD与风洞试验数据的比较。目前的研究表明，流线型的前锥、尾锥和轮壳可以减少关键区域的阻力，并降低阻力系数。这允许在设计阶段进行选择，在制造之前。阻力系数的范围为0.133 < CD < 0.273，取决于所考虑的HPV类型。在HPV的比例模型上进行风洞测试，结果显示与CFD结果的一致性平均在16%以内。风洞测试显示，从2019年的基线HPV到2020年的基线HPV，阻力系数下降了7.7%。因此，利用CFD分析支持的风洞数据来辅助HPV的设计。

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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Volume 2: Fluid Applications and Systems; Fluid Measurement and Instrumentation

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