Robotic knitcrete: computational design and fabrication of a pedestrian bridge using robotic shotcrete on a 3D-Knitted formwork

IF 2.2 Q2 CONSTRUCTION & BUILDING TECHNOLOGY

Frontiers in Built Environment Pub Date : 2023-12-07 DOI:10.3389/fbuil.2023.1269000

Philipp Rennen, Stefan Gantner, G. Dielemans, Lazlo Bleker, Nikoletta Christidi, Robin Dörrie, Majid Hojjat, Inka Mai, Karam Mawas, Dirk Lowke, Pierluigi D’Acunto, K. Dörfler, N. Hack, Mariana Popescu

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引用次数: 0

Abstract

The research project presented here aims to develop a design-informed manufacturing process for complex concrete shell structures in additive manufacturing and thus overcome limitations of traditional construction methods such as formwork- and labor intensity. To achieve this, an effort was made to merge the two technologies of CNC knitted stay-in-place formwork, known as KnitCrete, and robotically applied shotcrete, known as Shotcrete 3D Printing (SC3DP), and thereby reduce their respective limitations. The proposed workflow unites both digital fabrication methods into a seamless process that additionally integrates computational form finding, robotically applied fiber reinforcement, CNC post processing and geometric quality verification to ensure precision and efficiency. As part of a cross-university, research-based teaching format, this concept was implemented in the construction of a full-scale pedestrian bridge, which served as a demonstrator to evaluate the capabilities and limitations of the process. While overcoming some challenges during the process, the successful prove of concept shows a significant leap in digital fabrication of complex concrete geometry, reducing reliance on labor-intensive methods. The results shown in this paper make this fabrication approach a promising starting point for further developments in additive manufacturing in the construction sector.

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机器人针织混凝土：在三维针织模板上使用机器人喷射混凝土计算设计和建造一座人行天桥

本研究项目旨在为复杂的混凝土外壳结构在增材制造中开发一种基于设计的制造工艺，从而克服传统施工方法的限制，如模板和劳动强度。为了实现这一目标，我们努力将CNC针织原地模板(称为KnitCrete)和机器人喷射混凝土(称为喷射混凝土3D打印(SC3DP))这两种技术结合起来，从而减少了它们各自的局限性。所提出的工作流程将两种数字制造方法结合成一个无缝的过程，另外还集成了计算形式查找、机器人应用纤维增强、CNC后处理和几何质量验证，以确保精度和效率。作为跨大学研究型教学形式的一部分，这一概念在一座全尺寸人行天桥的建设中得到了实施，作为评估该过程的能力和局限性的示范。在克服过程中的一些挑战的同时，概念的成功证明表明了复杂混凝土几何形状的数字化制造的重大飞跃，减少了对劳动密集型方法的依赖。本文所示的结果使这种制造方法成为建筑领域增材制造进一步发展的一个有希望的起点。

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

Frontiers in Built Environment Social Sciences-Urban Studies

CiteScore

4.80

自引率

6.70%

发文量

266