Structural Weight and Stiffness Optimization of a Midibus Using the Reinforcement and Response Surface Optimization (RSO) Method in Static Condition

IF 0.8 Q3 ENGINEERING, MULTIDISCIPLINARY

Modelling and Simulation in Engineering Pub Date : 2022-02-01 DOI:10.1155/2022/6812744

Hailemichael Solomon Addisu, Ermias G Koricho

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引用次数: 1

Abstract

Midibuses are medium-sized buses widely used for transportation purposes in Asia and Africa. However, most midibuses are locally built and indirectly regulated through inspecting the end product (finished bus) during licensing for the public transport business in Ethiopia. Due to lack of engineering analysis and testing, low stiffness and overweight of midibus were compromised. This research was aimed at analyzing and optimizing the midibus structure using the reinforcement and response surface optimization (RSO) method for pure bending and torsion loading cases. Results show that the maximum deformation occurred at the roof section of the original structure during both loading cases. Furthermore, the reinforcement design was found by replacing the cross section and layouts of structural members and adding reinforcements for the most suitable location of the original structure. Response surface optimization with the multiobjective genetic algorithm (MOGA) method in ANSYS DesignXplorer was performed on the reinforced structure to maximize the bending and torsional stiffness with reduced weight. The bending stiffness of the reinforced and optimized structure increased by 41.65% (1911.4 N/m) and 10.02% (651.7 N/m), respectively. In addition, the torsional rigidity or stiffness of the bus structure was improved by 12.56% (173.31 Nm/deg) via reinforcement design. Moreover, the torsional stiffness of the optimized (RSO) model was increased by 3.29% (51.07 Nm/deg). Reinforcement design was effectively reduced by 5.23% of the structure’s weight. Moreover, the RSO method has also decreased the weight of the reinforced structure by 2.64%.

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静态条件下基于响应面优化法的中型客车结构重量和刚度优化

中型客车是在亚洲和非洲广泛用于运输目的的中型客车。然而，大多数中型巴士都是在当地建造的，并通过在埃塞俄比亚公共交通业务许可期间检查最终产品(成品巴士)来间接监管。由于缺乏工程分析和试验，中型客车的低刚度和超重受到了损害。本研究旨在利用钢筋响应面优化(RSO)方法分析和优化纯弯曲和扭转荷载情况下的中型客车结构。结果表明:在两种荷载作用下，原结构的顶板部分变形最大;通过更换结构构件的截面和布置，在原结构最合适的位置加筋，进行了配筋设计。利用ANSYS DesignXplorer软件中的多目标遗传算法(MOGA)对加固结构进行响应面优化，以在减轻重量的同时最大限度地提高弯曲刚度和扭转刚度。加固后和优化后结构的抗弯刚度分别提高41.65% (1911.4 N/m)和10.02% (651.7 N/m)。此外，通过加固设计，客车结构的抗扭刚度或刚度提高了12.56% (173.31 Nm/deg)。优化后的模型抗扭刚度提高了3.29% (51.07 Nm/deg)。配筋设计有效减轻了5.23%的结构自重。此外，RSO法还使加固结构的自重降低了2.64%。

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

Modelling and Simulation in Engineering ENGINEERING, MULTIDISCIPLINARY-

CiteScore

2.70

自引率

3.10%

发文量

审稿时长

18 weeks

期刊介绍： Modelling and Simulation in Engineering aims at providing a forum for the discussion of formalisms, methodologies and simulation tools that are intended to support the new, broader interpretation of Engineering. Competitive pressures of Global Economy have had a profound effect on the manufacturing in Europe, Japan and the USA with much of the production being outsourced. In this context the traditional interpretation of engineering profession linked to the actual manufacturing needs to be broadened to include the integration of outsourced components and the consideration of logistic, economical and human factors in the design of engineering products and services.