In-Crease: Less Concrete More Paper

Q2 Engineering
E. Lloret-Fritschi, Joseph Choma, F. Scotto, A. Szabo, F. Gramazio, M. Kohler, R. Flatt
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Abstract

Concrete is one of the most used materials after water. Largely owing to this, its environmental impact is substantial, although its embodied carbon per unit volume or mass is low when compared to most alternatives. This, along with the broad availability, good strength, durability and versatility of concrete means that it will remain a material of choice, although more efficient ways of using it must be found. Structurally optimized building components are a means to do this as they can save about 50% material. Unfortunately, however, such elements are presently too expensive to produce owing to them requiring non-standard formwork. It is an objective of digital fabrication to propose solutions to this issue. In this con-text, Digital Casting Systems (DCS) have advanced material control strategies for setting-on-demand in digital concrete processing. Thereby, the formwork pressure is reduced to a minimum, which opens possibilities of rethinking formworks as systems that are dynamically shaping, millimetre thin or weakly supporting the material cast inside. In this paper we present a brief overview of millimetre thin formworks and summarize the first realization of concrete elements that utilizes the mechanics of paper folding to make millimetre thin formworks up to 2.5 meters high. Such formworks could initially be flat packed, erected into shape, and eventually peeled-off and recycled in established material streams. This would reduce waste and transport cost, while offering a surface finish that meets the expectations for exposed concrete surfaces.
增加:减少混凝土,增加纸张
混凝土是仅次于水的最常用材料之一。主要是由于这一点,它对环境的影响是巨大的,尽管与大多数替代品相比,其单位体积或质量的含碳量较低。这一点,加上混凝土的广泛可用性、良好的强度、耐用性和多功能性,意味着它仍然是一种可供选择的材料,尽管必须找到更有效的使用方法。结构优化的建筑构件是实现这一目标的一种手段,因为它们可以节省约50%的材料。然而,不幸的是,由于这些元件需要非标准模板,因此目前生产成本太高。提出解决这一问题的方案是数字制造的目标。在本文中,数字浇注系统(DCS)具有先进的材料控制策略,可在数字混凝土加工中按需设置。因此,模板压力降至最低,这为将模板重新思考为动态成型、毫米薄或弱支撑内部浇注材料的系统提供了可能性。在本文中,我们简要介绍了毫米薄模板,并总结了利用折纸力学制作高达2.5米的毫米薄模板的混凝土构件的首次实现。这种模板最初可以扁平包装,成型,最终剥离并在既定的材料流中回收。这将减少浪费和运输成本,同时提供符合暴露混凝土表面预期的表面光洁度。
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
RILEM Technical Letters
RILEM Technical Letters Materials Science-Materials Science (all)
CiteScore
5.00
自引率
0.00%
发文量
13
审稿时长
10 weeks
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