RETRACTED:轮胎胎面特征建模

Q2 Engineering
M. D. Bolzon
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引用次数: 0

摘要

本研究详细调查了最近提出的轮胎旋转模拟方法的准确性,称为“MRFg”方法。以轿车型乘用车为研究对象,对不同胎面和轮辋进行了物理实验和计算流体力学(CFD)仿真。此外,还研究了风洞几何形状对方法精度的影响。实验数据包括阻力系数、前后升力系数、底盘和车门表面压力以及车轮周围各平面的尾迹测量。总的来说,采用了一套全面的验证数据。CFD模拟是瞬时的,其几何形状与实验几何形状非常接近,包括轮胎的变形。一般来说,MRFg方法预测不同胎面花纹对阻力系数的影响在4个计数以内。出现了一些异常值。MRFg方法可以很好地预测某些流场趋势和量级,但不能预测其他流场。纳入风洞几何结构显著提高了方法的准确性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
RETRACTED: Modeling Tire Tread Features
This study details an investigation into the accuracy of a recently proposed tire rotation simulation approach, termed the "MRFg" method. Physical experiments and computational fluid dynamics (CFD) simulations were conducted on a sedan-type passenger vehicle with various tire treads and rims. Furthermore, the effects of the wind tunnel geometry on the method's accuracy was investigated. The experimental data consisted of drag coefficients, front and rear lift coefficients, base and door surface pressures, and wake surveys at various planes around the wheels. Overall, a comprehensive set of validation data was taken. The CFD simulations were transient, and the geometry closely replicated the experimental geometry, including the tires' deformations. Generally, the MRFg method predicted the effects of the various tread patterns on the drag coefficient to within four counts. Some outliers occurred. The MRFg method predicted some of the flowfield trends and magnitudes very well, but not others. The inclusion of the wind tunnel geometry significantly increased the accuracy of the methodology.
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CiteScore
2.10
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