Optimization of modular Truss-Z by minimum-mass design under equivalent stress constraint

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2018-01-01 DOI:10.12989/SSS.2018.21.6.715
M. Zawidzki, L. Jankowski
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引用次数: 7

Abstract

Truss-Z (TZ) is an Extremely Modular System (EMS). Such systems allow for creation of structurally sound free-form structures, are comprised of as few types of modules as possible, and are not constrained by a regular tessellation of space. Their objective is to create spatial structures in given environments connecting given terminals without self-intersections and obstacle-intersections. TZ is a skeletal modular system for creating free-form pedestrian ramps and ramp networks. The previous research on TZ focused on global discrete geometric optimization of the spatial configuration of modules. This paper reports on the first attempts at structural optimization of the module for a single-branch TZ. The internal topology and the sizing of module beams are subject to optimization. An important challenge is that the module is to be universal: it must be designed for the worst case scenario, as defined by the module position within a TZ branch and the geometric configuration of the branch itself. There are four variations of each module, and the number of unique TZ configurations grows exponentially with the branch length. The aim is to obtain minimum-mass modules with the von Mises equivalent stress constrained under certain design load. The resulting modules are further evaluated also in terms of the typical structural criterion of compliance.
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等效应力约束下模块化桁架z的最小质量优化
Truss-Z (TZ)是一种极模块化系统(EMS)。这样的系统允许创建结构合理的自由形式结构,由尽可能少的模块类型组成,并且不受空间的规则镶嵌的限制。他们的目标是在给定的环境中创建空间结构,连接给定的终端,没有自交和障碍交。TZ是一个骨架模块化系统,用于创建自由形式的行人坡道和坡道网络。以往的研究主要集中在模块空间构型的全局离散几何优化上。本文报道了单支路TZ模块结构优化的首次尝试。内部拓扑结构和模块梁的尺寸都需要优化。一个重要的挑战是模块是通用的:它必须设计为最坏的情况,由模块在TZ分支中的位置和分支本身的几何配置定义。每个模块有四种变体,并且唯一TZ配置的数量随着分支长度呈指数增长。目的是获得在一定设计载荷约束下具有von Mises等效应力约束的最小质量模组。所得到的模块还将根据典型的遵从性结构标准进行进一步评估。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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