Development of a Test Rig for Axial Strains Measurement in Automobile Wheel

Samuel Onoriode Igbudu, David Abimbola Fadare
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Abstract

In automobile wheel application, a test rig is vital and used to simulate conditions of the wheel in service in order to affirm the safety and reliability of the wheel. The present work designed a test rig for measuring axial strains in automobile wheel. The wheel used was a five-arm wheel (6JX14H2; ET 42) and Tyre (175 × 65 R 14). Experimental (EXP) test was carried out, with a radial load of 4750 N and inflation pressure of 0.3 MPa, to measure the axil strains which were converted to maximum principal strain values and, compared with data from Finite Element Analysis (FEA) using Creo-Element/Pro 5.0 at wheel’s contact angles of 90 degree (FEA 90 deg), 40 degree (FEA 40 deg) and 30.25 degree (FEA 30.25 deg), respectively. Results show that at the wheel’s point of contact with the ground, maximum principal strain values were highest at the inboard bead seat with a value of about 5.69 × 10-4 mm/mm, followed by the values at the well of about 5.66 × 10-4 mm/mm. The value at the outboard bead seat was least at about 2.22 × 10-4 mm/mm, which was due to the presence of spikes at this location that tends to resist imposed radial loads. However, the highest mean maximum principal strain values at the locations of inboard, well and outboard, were about 2.11 × 10-4 mm/mm, 3.78 × 10-4 mm/mm and .99 × 10-4 mm/mm, respectively. With the highest single value of about 5.69 × 10-4 mm/mm, the inboard bead seat was the most strained location of the wheel. Overall results showed that all values of maximum principal strains were below the threshold value of about 1 × 10-2 mm/mm. The values obtained for EXP and FEA could be said to be in close agreement when compared with the threshold value. With this in mind, the rig is recommended for use in related experimental procedures.
汽车车轮轴向应变测量试验台的研制
在汽车车轮的应用中,试验台是至关重要的,它用来模拟车轮在使用中的状况,以确认车轮的安全性和可靠性。设计了一种汽车车轮轴向应变试验装置。所用车轮为五臂轮(6JX14H2;ET 42)和泰尔(175 × 65 R 14)。在径向载荷为4750 N、充气压力为0.3 MPa的条件下,采用Creo-Element/Pro 5.0软件分别测量车轮接触角为90°(FEA 90°)、40°(FEA 40°)和30.25°(FEA 30.25°)时的轴向应变,并将轴向应变转换为最大主应变值,与有限元分析(FEA)数据进行比较。结果表明:在车轮与地面接触点处,最大主应变值在内侧头座处最大,约为5.69 × 10-4 mm/mm,其次是井处,约为5.66 × 10-4 mm/mm;该值至少为2.22 × 10-4 mm/mm,这是由于该位置存在尖峰,倾向于抵抗施加的径向载荷。在井内、井外三个位置,最大主应变平均值分别为2.11 × 10-4 mm/mm、3.78 × 10-4 mm/mm和0.99 × 10-4 mm/mm。单次应变值最高,约为5.69 × 10-4 mm/mm,是车轮受力最大的位置。总体结果表明,最大主应变值均低于1 × 10-2 mm/mm的阈值。与阈值相比,EXP和FEA得到的值可以说是非常一致的。考虑到这一点,建议在相关实验程序中使用该钻机。
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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