A Method for Designing Multi-Layer Sheet-Based Lightweight Funicular Structures

IF 1.1 Q3 ENGINEERING, CIVIL

Journal of the International Association for Shell and Spatial Structures Pub Date : 2022-12-01 DOI:10.20898/j.iass.2022.018

Yao Lu, Thamer Alsalem, M. Akbarzadeh

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引用次数: 2

Abstract

Multi-layer spatial structures usually take considerable external loads with a small material usage at all scales. Polyhedral graphic statics (PGS) provides a method to design multi-layer funicular polyhedral structures, and the structural forms are usually materialized as space frames. Our previous research shows that the intrinsic planarity of the polyhedral geometries can be harnessed for efficient fabrication and construction processes using flat-sheet materials. Sheet-based structures are advantageous over conventional space frame systems because sheets can provide more load paths and constrain the kinematic degrees of freedom of the nodes. Therefore, they are more capable of taking a wider variety of load cases compared to space frames. Moreover, sheet materials can be fabricated into complex shapes using CNC milling, laser cutting, water jet cutting, and CNC bending techniques. However, not all sheets are necessary as long as the load paths are preserved and the system does not have kinematic degrees of freedom. To find an efficient set of faces that satisfies the requirements, this paper first incorporates and adapts the matrix analysis method to calculate the kinematic degrees of freedom for sheet-based structures. Then, an iterative algorithm is devised to help find a reduced set of faces with zero kinematic degrees of freedom. To attest to the advantages of this method over bar-node construction, a comparative study is carried out using finite element analysis. The results show that, with the same material usage, the sheet-based system has improved performance than the framework system under a range of loading scenarios.

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基于多层薄板的轻型索道结构设计方法

多层空间结构通常承受相当大的外部载荷，在所有尺度上使用较小的材料。多面体图解静力学（PGS）为多层索多面体结构的设计提供了一种方法，其结构形式通常被物化为空间框架。我们之前的研究表明，多面体几何形状的固有平面性可以用于使用平板材料的高效制造和施工过程。基于薄板的结构相对于传统的空间框架系统是有利的，因为薄板可以提供更多的载荷路径并约束节点的运动自由度。因此，与空间框架相比，它们更有能力承受更广泛的载荷情况。此外，可以使用数控铣削、激光切割、水射流切割和数控弯曲技术将片材制造成复杂的形状。但是，并非所有图纸都是必需的，只要保留了载荷路径并且系统不具有运动自由度即可。为了找到一组满足要求的有效面，本文首先结合并采用矩阵分析方法来计算基于薄板的结构的运动自由度。然后，设计了一种迭代算法来帮助找到一组具有零运动自由度的简化面。为了证明该方法相对于钢筋节点构造的优势，采用有限元分析方法进行了对比研究。结果表明，在相同的材料使用情况下，在一系列负载场景下，基于片材的系统比框架系统的性能有所提高。

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

Journal of the International Association for Shell and Spatial Structures ENGINEERING, CIVIL-

CiteScore

1.40

自引率

0.00%

发文量

期刊介绍： The Association publishes an international journal, the Journal of the IASS, four times yearly, in print (ISSN 1028-365X) and on-line (ISSN 1996-9015). The months of publication are March, June, September and December. Occasional extra electronic-only issues are included in the on-line version. From this page you can access one or more issues -- a sample issue if you are not logged into the members-only portion of the site, or the current issue and several back issues if you are logged in as a member. For any issue that you can view, you can download articles as .pdf files.