汽车前桥台架试验强度对标分析及其改进

doi:10.16731/j.cnki.1671-3133.2018.01.010

现代制造工程 ›› 2018, Vol. 448 ›› Issue (1): 48-53.doi: 10.16731/j.cnki.1671-3133.2018.01.010

汽车前桥台架试验强度对标分析及其改进

徐玉萍,方姣

华东交通大学交通运输与物流学院,南昌 330013

收稿日期:2017-02-13 出版日期:2018-01-20 发布日期:2018-07-24
作者简介:徐玉萍,硕士,副教授,主要研究方向为交通运输。E-mail:xuyuping19733@163.com

Strength analysis and improvement of truck front axle based on bench test

Xu Yuping,Fang Jiao

School of Transportation and Logistics,East China Jiaotong University,Nanchang 330013,China

Received:2017-02-13 Online:2018-01-20 Published:2018-07-24

摘要/Abstract

摘要： 前桥是载货汽车最重要的承重部件,需要承受不同方向的载荷和转矩。为了校核某新型前桥设计的安全性和可靠性,分别对该前桥在垂向跳动工况、制动工况、转弯工况以及转弯制动工况的受力进行力学分析,获取不同工况下的载荷。采用HyperMesh软件建立前桥有限元分析模型,并且基于理论分析的载荷,对其进行强度分析,分析结果表明其在4种典型工况下的最大应力值分别为379.0、490.9、267.0、533.5 MPa,均小于材料屈服强度,其中在制动工况和转弯工况时的安全系数均小于目标安全系数1.2,不满足设计要求。基于4种典型工况对前桥进行台架试验,获取测试点的应变数据,采用Ncode软件将其转换成应力值。台架试验强度对标结果表明其与有限元分析结果相接近,误差率均小于10 %。为了减小应力集中,将板簧支座与前梁过渡连接处修改得更加平滑,改进方案的分析结果表明其在4种典型工况的最大应力值分别降低了21.3 %、17.0 %、28.4 %和17.3 %,并且改进之后前桥在转弯工况和转弯制动工况的安全系数均大于1.2,满足设计要求。

关键词: 前桥, 力学分析, 有限元, 强度, 台架试验

Abstract: The front axle is one of the most important parts of truck bearing,which bears loading and torque in different directions.Aiming at checking a new front axle design safety and reliability,the front axle was mechanics analysed and the loading was obtained in the condition of bump,brake,steer and steer-brake.The front axle strength was analysed based on theoretical analysis loading and finite element method by adopting HyperMesh,the result showed that the maximum stress were 379.0,490.9,267.0 and 533.5 MPa in the condition of bump,brake,steer and steer-brake,they were less than yield strength,but safety coefficients of brake and steer-brake condition were less than 1.2,they could not meet the design requirements.Bench test was carried out on the front axle based on four typical working condition,the test point strain datas were obtained,and they were converted to stress by adopting Ncode software.The bench test results showed that test values were close to finite element analysis values,their error rate were less than 10 %.The analysis results showed that the maximum stress were respectively reduced by 21.3 %,17.0 %,28.4 % and 17.3 % in the four typical working condition by smoothing the connections of spring seat and the front beam.The safety coefficients of brake and steer-brake condition were more than 1.2 after optimization,they could meet the design requirements.

Key words: front axle, mechanics analysis, finite element, strength, bench test

中图分类号:

TH16

徐玉萍,方姣. 汽车前桥台架试验强度对标分析及其改进[J]. 现代制造工程, 2018, 448(1): 48-53.

Xu Yuping,Fang Jiao. Strength analysis and improvement of truck front axle based on bench test[J]. Modern Manufacturing Engineering, 2018, 448(1): 48-53.

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汽车前桥台架试验强度对标分析及其改进

Strength analysis and improvement of truck front axle based on bench test

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