Foamwork: Challenges and strategies in using mineral foam 3D printing for a lightweight composite concrete slab

IF 1.6 0 ARCHITECTURE

International Journal of Architectural Computing Pub Date : 2023-05-17 DOI:10.1177/14780771231174526

P. Bedarf, A. Szabo, Enrico Scoccimarro, B. Dillenburger

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引用次数: 2

Abstract

This paper presents an innovative design and fabrication workflow for a lightweight composite slab prototype that combines mineral foam 3D printing (F3DP) and concrete casting. Non-standardized concrete elements that are geometrically optimized for resource efficiency often result in complex shapes that are difficult to manufacture. This paper extends the research in earlier studies, showing that F3DP can address this challenge. F3DP is used to construct 24 stay-in-place formwork elements for a lightweight, resource-efficient ribbed concrete element with a 2 × 1.3 m footprint. This advancement highlights the improved robotic F3DP setup, computational design techniques for geometry and print path generation, and strategies to achieve near-net-shape fabrication. The resulting prototype shows how complex geometries that were previously cost-prohibitive can be produced efficiently. Discussing the findings, challenges, and future improvements offers useful perspectives and supports the development of this resourceful and sustainable construction technique.

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泡沫:使用矿物泡沫3D打印轻质复合混凝土板的挑战和策略

本文提出了一种结合矿物泡沫3D打印（F3DP）和混凝土浇筑的轻质复合板原型的创新设计和制造流程。为提高资源效率而进行几何优化的非标准化混凝土元件通常会导致难以制造的复杂形状。本文扩展了早期研究中的研究，表明F3DP可以应对这一挑战。F3DP用于建造24个原位模板元件，用于占地面积为2×1.3米的轻质、资源高效的带肋混凝土元件。这一进展突出了改进的机器人F3DP设置、几何结构和打印路径生成的计算设计技术，以及实现近净形状制造的策略。由此产生的原型展示了如何有效地生产以前成本高昂的复杂几何形状。讨论这些发现、挑战和未来的改进提供了有用的视角，并支持这种足智多谋和可持续的建筑技术的发展。

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 Architectural Computing ARCHITECTURE-

CiteScore

3.20

自引率

17.60%

发文量