Effects of Detailed Tire Geometry and Wheel Rotation on the Aerodynamic Performance of Deflectors

Q3 Engineering
Akihiro Nakata, Satoshi Okamoto, Yosuke Morikawa, Takuji Nakashima
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引用次数: 0

Abstract

Wheels and tires account for approximately 25% of the overall aerodynamic drag on a vehicle. Though researchers have investigated the accurate representation of rotating tires and wheels in aerodynamic simulations, they primarily focused on the differences in the tire or wheel geometry; few studies have investigated the effects of front-tire deflectors located at the bottom of passenger car bumpers. In other that deflectors can effectively reduce drag without significantly affecting design or packaging, deflector performance should be predicted at the early stages of product development. This study accordingly clarified the simulation conditions for full-vehicle aerodynamics necessary to accurately predict the performance of front-tire deflectors by simulating two different deflector configurations under four conditions comprising different degrees of tire geometry detail and wheel rotation methods. The simulation results were subsequently compared with wind tunnel test results, indicating that the numerical simulation using the least accurate tire geometry detail could not accurately predict the performance differences according to deflector configuration. However, the differences between the drag coefficients and airflow characteristics for each deflector were predicted more accurately by improving the tire geometry detail. The prediction accuracy was further improved by using the sliding mesh method instead of the boundary condition method to model the wheel rotation. Therefore, it was concluded that the detail tire geometry and wheel rotation method are important factors for improving the accuracy of front-tire deflector performance prediction.
详细的轮胎几何形状和车轮旋转对偏转器气动性能的影响
车轮和轮胎约占车辆整体空气动力阻力的25%。尽管研究人员已经在空气动力学模拟中研究了旋转轮胎和车轮的准确表示,但他们主要关注的是轮胎或车轮几何形状的差异;很少有研究对位于轿车保险杠底部的前轮胎偏转器的影响进行研究。在其他偏转板可以有效地减少阻力,而不会显著影响设计或包装,偏转板的性能应该在产品开发的早期阶段进行预测。本研究通过对轮胎几何细节和车轮转动方式不同程度的四种工况下的两种不同偏转板构型进行仿真,明确了准确预测前轮胎偏转板性能所需的整车空气动力学仿真条件。将仿真结果与风洞试验结果进行了比较,结果表明,采用最不精确的轮胎几何细节进行的数值模拟不能准确预测不同偏转板配置下的性能差异。然而,通过改进轮胎几何细节,可以更准确地预测每个偏转板的阻力系数和气流特性之间的差异。采用滑动网格法代替边界条件法对车轮转动进行建模,进一步提高了预测精度。因此,详细的轮胎几何形状和车轮转动方法是提高前轮胎偏导性能预测精度的重要因素。
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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来源期刊
International Journal of Automotive Engineering
International Journal of Automotive Engineering Engineering-Safety, Risk, Reliability and Quality
CiteScore
1.10
自引率
0.00%
发文量
16
期刊介绍: The IJAE aims to cover all the main areas of automotive engineering. -Heat engine -Power transmission -Vehicle dynamics -Vehicle development -Vibration , noise , ride comfort -Heat , fluid -Materials -Social system -Common infrastructure -Other means of mobility -EV , HV systems -Electronics and control -Transportation systems -Autonomous vehicle technology -Information & Communication Technology -Information security -Safety -Human engineering -Environment , energy , resources -Production , manufacture
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