JUSTIFICATION OF DESIGNS TO INCREASE THE BEARING

Transport engineering Pub Date : 2023-05-11 DOI:10.30987/2782-5957-2023-5-60-68

D. Antipin, E. Lukashova, A. Boldyrev, F. Lozbinev

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Abstract

Domestic and international experience in increasing the bearing structure rigidity of vehicle bodies in the form of a reinforced shell with a cut-out is analyzed. Based on the analysis, approaches related to the reinforcement of the car underframe with additional longitudinal elements and bearing partitions are considered as promising. Options for installing one as well as with two partitions connected by longitudinal elements are considered. The first frequency of the body bending vibrations, the maximum stresses acting in the reinforced part of the structure, as well as the amount of mass gain associated with reinforcements are accepted as the criteria for choosing a rational design to increase the rigidity of the body bearing structure. The study object is the bearing structure of the sleeping passenger car body, 61-4517 model, produced by Tver Car Building Plant. Having analyzed the bearing structure of the car body, four variants of reinforcing the bearing system are proposed. For each of them, from four to ten structural designs are considered, differing in the type of profiles for their formation. The efficiency analysis within the accepted criteria is carried out by computer simulations using modern industrial software systems based on the finite element method. A detailed spatial and plate body model based on finite element is developed. Heavy equipment is included as some finite elements, as well as interior designs of the passenger car. The results obtained using the developed model are verified by the data of bench full-scale tests of the passenger car body. For each variant and design, the values of the first natural frequency of the body bending vibrations, maximum stresses arising in the structure under the action of regulatory forces, as well as the value of the mass gain of the bearing structure are obtained. The analysis of the obtained variants made it possible to find out the rational variant and its design, which provides an increase in the rigidity of the body bearing structure, a reduction in operating stresses with a minimal increase in the mass of the metal structure.

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增加轴承设计的合理性

分析了国内外以开孔加筋壳形式提高车身承载结构刚度的经验。在此基础上，提出了采用附加纵向单元和轴承隔板加固车底的方法。考虑了安装一个或两个由纵向元件连接的隔板的选择。车身弯曲振动的第一频率，作用于结构加固部分的最大应力，以及与加固相关的质量增益量，可以作为选择合理设计以增加车身承载结构刚度的标准。研究对象为特维尔汽车制造厂生产的61-4517型卧铺客车车身轴承结构。通过对车体承载结构的分析，提出了四种对承载系统进行加固的方法。对于每一个，从四到十种结构设计被考虑，不同类型的剖面为他们的地层。利用现代工业软件系统，以有限元法为基础，进行了在公认准则范围内的效率分析。建立了基于有限元的详细空间和板体模型。重型设备包括一些有限元素，以及乘用车的内部设计。利用所建立的模型所得到的结果，通过乘用车车体台架全尺寸试验数据进行了验证。对于每一种变型和设计，获得了车身弯曲振动的第一固有频率值、结构在调节力作用下产生的最大应力以及承载结构的质量增益值。通过对所获得的变量进行分析，可以找到合理的变量及其设计，从而增加车身轴承结构的刚度，减少操作应力，同时最小地增加金属结构的质量。

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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Transport engineering

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