Design based on availability: Generative design and robotic fabrication workflow for non-standardized sheet metal with variable properties

Q1 Arts and Humanities

International Journal of Space Structures Pub Date : 2022-03-07 DOI:10.1177/09560599221081104

Seyed Mobin Moussavi, Hana Svatoš-Ražnjević, A. Körner, Y. Tahouni, A. Menges, J. Knippers

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引用次数: 3

Abstract

This paper presents the use of a computational design algorithm in combination with robotic fabrication and sensing to augment the design and construction process for non-standardized material. Although reusing reclaimed material can significantly reduce the environmental impact in building construction, current design processes are not set up for this shift in thinking. Contrary to conventional practices, designing within the constraints of available material means that geometry and topology cannot be fully pre-determined. This paper introduces a design methodology for corrugated shell structures from folded sheet metal of variable geometries and properties, in which the design goal adapts to available material. It follows a two-fold approach of digital algorithm development and scanning and physical prototyping for robotic fabrication. The scanned materials database is classified based on object geometry data and material properties; such as thickness, type of metal, and spring-back values for fabrication purposes. Together with a target surface, it is an input for a generative design algorithm consisting of surface generation and optimization. The surface generation tries to approximate the target through a translation of search algorithm results for object placement into a 2D mesh graph which is then linked to 3D particle spring based form-finding. The optimization consists of evaluation of structural, fabrication, and design criteria, with finally user selection. Robotic fabrication included object recognition, metal sheet folding and consideration of different metal spring back behavior. These methods were tested on a single curved arch surface and applied to a double curved cantilever canopy as a final demonstrator. The algorithm results showed a generation of different corrugated shell topologies based on iterated object placement. As a demonstrator, a part of the selected canopy was robotically fabricated from local industrial leftovers.

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基于可用性的设计:具有可变属性的非标准化钣金的生成设计和机器人制造工作流

本文将计算设计算法与机器人制造和传感相结合，以增强非标准化材料的设计和施工过程。尽管在建筑施工中重复使用再生材料可以显著减少对环境的影响，但目前的设计流程并没有为这种思维转变而设置。与传统做法相反，在可用材料的约束下进行设计意味着几何结构和拓扑结构不能完全预先确定。本文介绍了一种由几何形状和性能不同的折叠金属板制成的波纹壳结构的设计方法，其中设计目标与可用材料相适应。它遵循数字算法开发和机器人制造的扫描和物理原型的双重方法。扫描材料数据库基于对象几何数据和材料特性进行分类；例如厚度、金属类型和用于制造目的的回弹值。与目标曲面一起，它是由曲面生成和优化组成的生成设计算法的输入。表面生成试图通过将对象放置的搜索算法结果转换为2D网格图来近似目标，然后将2D网格图链接到基于3D粒子弹簧的形状查找。优化包括对结构、制造和设计标准的评估，以及最终的用户选择。机器人制造包括物体识别、金属板折叠和考虑不同金属回弹行为。这些方法在单个弯曲拱表面上进行了测试，并应用于双曲悬臂雨棚作为最终验证。算法结果显示了基于迭代对象放置的不同波纹壳拓扑的生成。作为一名演示者，所选遮篷的一部分是用当地工业废料机器人制造的。

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.