Buckling-Controlled Member for Improving the Ductile Behavior of Double-Layer Latticed Space Structures

Q1 Arts and Humanities

International Journal of Space Structures Pub Date : 2023-04-17 DOI:10.1177/09560599231161447

M. Kheirollahi, M. Chenaghlou, K. Abedi

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引用次数: 1

Abstract

In this paper, a new buckling-controlled member (BCM) is introduced for use in space structures. This member is composed of four components; namely: the encasing, joints, core, and adjustable nuts. The core is intended to act as a structural element to resist the axial loads by its yielding under compression loading. The steel encasing is supposed to confine the steel core. Adjustable steel nuts on the steel core act as lateral bracings and are responsible for lateral load transmission between the encasing and core. The joints at the two ends of the supports of the member. Six experimental tests have been performed under compression load to show the efficiency of the new member. The test results reveal that the proposed member can provide the needed ductility and can delay the brittle buckling of the members. Also, the BCM is capable of considering buckling modes and controlling the plastic range. The experimental and numerical results have also been compared. Additional numerical evaluations have been carried out using finite element models, in which the effects of different parameters of the member have been investigated. The obtained results showed that the arrangement of inner elements is the main factor affecting ductility and postponing the buckling of the members. In the end, the effects of the BCMs on the overall behavior of four double-layer space structures have been studied. The obtained results of analyses indicated that the BCMs can enhance the strength and ductility of space structures, thereby reducing the risk of collapse. Also, the seismic collapse of the space structure was postponed.

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改善双层网架空间结构延性的屈曲控制构件

本文介绍了一种用于空间结构的新型屈曲控制构件。该成员由四个组成部分组成；即：外壳、接头、芯和可调节螺母。堆芯旨在作为一个结构元件，通过其在压缩载荷下的屈服来抵抗轴向载荷。钢外壳应该限制钢芯。钢芯上的可调节钢螺母充当横向支撑，并负责外壳和芯之间的横向载荷传递。构件支撑两端的接头。在压缩载荷下进行了六次实验测试，以显示新构件的效率。试验结果表明，所提出的构件可以提供所需的延性，并可以延缓构件的脆性屈曲。此外，车身控制模块能够考虑屈曲模式并控制塑性范围。并对实验结果和数值结果进行了比较。使用有限元模型进行了额外的数值评估，其中研究了构件不同参数的影响。结果表明，内部构件的布置是影响构件延性和延缓构件屈曲的主要因素。最后，研究了BCM对四种双层空间结构整体性能的影响。分析结果表明，BCM可以提高空间结构的强度和延性，从而降低倒塌风险。此外，空间结构的地震倒塌被推迟。

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

International Journal of Space Structures Arts and Humanities-Conservation

CiteScore

2.00

自引率

0.00%

发文量

期刊介绍： The aim of the journal is to provide an international forum for the interchange of information on all aspects of analysis, design and construction of space structures. The scope of the journal encompasses structures such as single-, double- and multi-layer grids, barrel vaults, domes, towers, folded plates, radar dishes, tensegrity structures, stressed skin assemblies, foldable structures, pneumatic systems and cable arrangements. No limitation on the type of material is imposed and the scope includes structures constructed in steel, aluminium, timber, concrete, plastics, paperboard and fabric.