矿物复合材料:使用泡沫3D打印的混凝土原地模板

Patrick Bedarf, Cristian Calvo-Barentin, Dinorah Martinez Schulte, Ayça Şenol, Etienne Jeoffroy, Benjamin Dillenburger
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引用次数: 2

摘要

优化混凝土构件的形状对于减少材料消耗和总重量,同时提高其功能性能具有重要意义。然而,由此产生的非标准几何形状是困难的,浪费与传统的模板策略制造。本文介绍了一种新的制造方法,即矿物泡沫3D打印(F3DP),用于定制非标准、材料高效、轻质混凝土构件的模板。许多创新的模板研究表明,原地模板可以帮助减少浪费和材料消耗,同时增加建筑组件的功能。泡沫特别适合这种应用,因为它们的高强度重量比,耐热性和良好的可加工性。F3DP允许无浪费生产几何复杂的模板元件,没有长时间的交货时间和生产专用工具。本文介绍了材料系统和机器人F3DP设置,并进行了两个实验案例研究:穿孔立面板和拱形梁板。两个案例都使用混凝土作为结构材料,并策略性地放置定制打印的泡沫元素。在第一次初步研究中,可以实现高达50%的混凝土节约和超过60%的重量减轻。这是与标准解决方案(如空心板)的竞争,但相比之下,也允许非标准元素几何形状。额外的功能,如编程穿孔、吸声和隔热,可以通过固定模板添加。此外,还讨论了F3DP在可持续建筑过程中的挑战和未来发展。需要进一步的研究来验证这些发现。然而,考虑到建筑行业对资源高效、低碳解决方案的迫切需求,这项工作是对下一代高性能建筑部件的重要贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mineral composites: stay-in-place formwork for concrete using foam 3D printing

Optimizing the shape of concrete construction elements is significant in reducing their material consumption and total weight while improving their functional performance. However, the resulting non-standard geometries are difficult and wasteful to fabricate with conventional formwork strategies. This paper presents the novel fabrication method of mineral foam 3D printing (F3DP) of bespoke lost formwork for non-standard, material-efficient, lightweight concrete elements. Many innovative formwork studies have shown that stay-in-place formwork can help to reduce waste and material consumption while adding functionality to building components. Foams are particularly suitable for this application because of their high strength-to-weight ratio, thermal resistance, and good machinability. F3DP allows the waste-free production of geometrically complex formwork elements without long lead times and production-specific tooling. This paper presents the material system and robotic F3DP setup with two experimental case studies: a perforated facade panel and an arched beam slab. Both cases use concrete as structural material and strategically placed custom-printed foam elements. In this first preliminary study, concrete savings of up to 50% and weight reduction of more than 60% could be achieved. This is competitive with standardized solutions such as hollow-core slabs but, in contrast, allows also for non-standard element geometries. Additional functionality, such as programmed perforation, acoustic absorption, and thermal insulation, could be added through the stay-in-place formwork. Moreover, the challenges and future developments of F3DP for sustainable building processes are discussed. Further studies are required to verify the findings. However, considering the urgent need for resource-efficient, low embodied-carbon solutions in the construction industry, this work is an important contribution to the next generation of high-performance building components.

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