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聚合物夹层复合材料力学性能的计算分析

Computational Analysis of Mechanical Properties in Polymeric Sandwich Composite Materials.

作者信息

Kohar Robert, Miskolci Jaroslav, Pompas Lukas, Kucera Lubos, Stevko Peter, Petru Michal, Mishra Rajesh Kumar

机构信息

Department of Design and Machine Elements, Faculty of Mechanical Engineering, University of Žilina, Univerzitna 8215/1, 02401 Žilina, Slovakia.

Vision Consulting, s.r.o., Československej Armády 732, 93521 Tlmače, Slovakia.

出版信息

Polymers (Basel). 2024 Mar 1;16(5):673. doi: 10.3390/polym16050673.

DOI:10.3390/polym16050673
PMID:38475355
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10935142/
Abstract

This article focuses on the computational analysis of sandwich composite materials based on polypropylene, polyester, glass, and cotton fibers. In the automotive components prepared from these fiber materials, the various components are used in different proportions. Through the manufacturing process, isotropic materials become somewhat anisotropic. Part of this article is aimed at obtaining input values of material characteristics for calculations using finite element analysis (FEM) and the comparison of experimental results with FEM-based material models created using the Digimat 2023.1 software. This article analyzes the modeling of two-phase as well as multiphase composite materials. This work focuses on calculations using FEM according to the test defined in the PR375 standard for loading the finished product in the luggage compartment of a car. The defined methodology enables the application of the FEM-based calculation directly to the product design in the initial phase of research. The construction and production of expensive prototypes and the subsequent production of automotive parts is replaced by computer-based simulation. This procedure makes it possible to simulate several optimization cycles over a relatively shorter time. From the results of computational simulations, it is clear that materials based on PP/PET/glass fibers show a much higher modulus of elasticity than materials created using cotton, i.e., materials of the PP/PET/cotton type. In order to achieve a high strength and stiffness, it is, therefore, appropriate to use glass fibers in the composite materials used for such applications.

摘要

本文着重于对基于聚丙烯、聚酯、玻璃和棉纤维的三明治复合材料进行计算分析。在由这些纤维材料制备的汽车部件中,各种部件以不同比例使用。通过制造过程,各向同性材料会变得有些各向异性。本文部分内容旨在获取材料特性的输入值,以便使用有限元分析(FEM)进行计算,并将实验结果与使用Digimat 2023.1软件创建的基于FEM的材料模型进行比较。本文分析了两相以及多相复合材料的建模。这项工作着重于根据PR375标准中定义的测试,使用FEM对汽车行李厢中成品的加载进行计算。所定义的方法能够在研究的初始阶段将基于FEM的计算直接应用于产品设计。基于计算机的模拟取代了昂贵原型的构建和生产以及随后汽车零部件的生产。该程序使得在相对较短的时间内模拟多个优化周期成为可能。从计算模拟结果可以明显看出,基于PP/PET/玻璃纤维的材料比使用棉制成的材料,即PP/PET/棉类型的材料,具有更高的弹性模量。因此,为了获得高强度和刚度,在用于此类应用的复合材料中使用玻璃纤维是合适的。

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2
From aviation to automotive - a study on material selection and its implication on cost and weight efficient structural composite and sandwich designs.从航空到汽车——关于材料选择及其对成本和重量高效的结构复合材料与夹层结构设计影响的研究。
Heliyon. 2020 Mar 31;6(3):e03716. doi: 10.1016/j.heliyon.2020.e03716. eCollection 2020 Mar.
3
Novel Smart Textiles.
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4
Fracture Toughness Analysis of Epoxy-Recycled Rubber-Based Composite Reinforced with Graphene Nanoplatelets for Structural Applications in Automotive and Aeronautics.用于汽车和航空结构应用的石墨烯纳米片增强环氧再生橡胶基复合材料的断裂韧性分析
Polymers (Basel). 2020 Feb 14;12(2):448. doi: 10.3390/polym12020448.
5
Development of a cost model for the production of carbon fibres.碳纤维生产成本模型的开发。
Heliyon. 2019 Oct 23;5(10):e02698. doi: 10.1016/j.heliyon.2019.e02698. eCollection 2019 Oct.
6
Polypropylene and tire powder composite for use in automotive industry.用于汽车工业的聚丙烯与轮胎粉复合材料。
Heliyon. 2019 Sep 7;5(9):e02405. doi: 10.1016/j.heliyon.2019.e02405. eCollection 2019 Sep.