Analysis of Urban TITEN EV-2 Car Chassis Design on Dynamic Loading When Brakes

Q2 Engineering
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Abstract

In the race conditions of the Energy Saving Car Contest, urban concept vehicles must comply with the special rules that have been set, namely 'stop & go driving'. Therefore, the designed car must have the toughness to accelerate and decelerate safely. Chassis is a fundamental part of the vehicle that functions to support the overall load that works on the car, keeps the car's condition rigid, does not experience excessive deformation and is safe when used. For that chassis design planning must be considered. The selection of a strong but still lightweight material was carried out, using 6061 aluminum material. In this research, an analysis will be carried out on the design of the TITEN EV-2 car chassis. TITEN itself is the name of the Jember University research team that focuses on developing energy-efficient electric vehicles. In this study the analysis is focused on the chassis that experiences dynamic loading when braking with variations in the shape of the chassis profile, namely profiles in the shape of a square and hollow rectangle and the braking distance is varied. from 20m, 15m, 10m. By using the Finite Element Method (FEM), the strength analysis of the chassis structure design can be determined by looking at the maximum stress and total deformation acting on the chassis. From the simulation results, the rectangular hollow chassis profile has a mass of 7.6 kg which is lighter than the square hollow chassis which has a mass of 9.4 kg. Rectangular hollow chassis has a maximum stress that is superior to square hollow chassis at loading distances of 20 m and 15 m, but at a braking distance of 10 m, square hollow chassis is superior in terms of total deformation and maximum stress
城市TITEN EV-2轿车制动动载底盘设计分析
在节能车大赛的比赛条件下,城市概念车必须遵守已经制定的特殊规则,即“走走停停”。因此,所设计的汽车必须具有安全加速和减速的韧性。底盘是车辆的基本组成部分,其功能是支撑汽车上的整体负载,保持汽车的状态刚性,不会经历过度变形,并且在使用时是安全的。因此,必须考虑底盘设计规划。选择了一种坚固但仍然轻便的材料,使用6061铝材料。在本研究中,将对天腾EV-2汽车底盘的设计进行分析。TITEN本身是Jember大学研究团队的名字,该团队专注于开发节能电动汽车。在本研究中,重点分析了在不同的底盘轮廓形状,即不同的方形和空心矩形轮廓以及不同的制动距离下,底盘在制动时所承受的动载荷。从20米,15米,10米。利用有限元法,通过观察作用在底盘上的最大应力和总变形来确定底盘结构设计的强度分析。从仿真结果来看,矩形空心底盘轮廓的质量为7.6 kg,比方形空心底盘的质量9.4 kg轻。矩形空心底盘在加载距离为20 m和15 m时的最大应力优于方形空心底盘,但在制动距离为10 m时,方形空心底盘的总变形和最大应力均优于方形空心底盘
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