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添加剂数字铸造:从实验室到工业领域。

Additive Digital Casting: From Lab to Industry.

作者信息

Lloret-Fritschi Ena, Quadranti Elia, Scotto Fabio, Fuhrimann Lukas, Demoulin Thibault, Mantellato Sara, Unteregger Lukas, Burger Joris, Pileggi Rafael G, Gramazio Fabio, Kohler Matthias, Flatt Robert J

机构信息

Group of Physical Chemistry of Building Materials, Institute for Building Materials, 8093 Zurich, Switzerland.

Institute for Technology in Architecture, Gramazio Kohler Research, 8093 Zurich, Switzerland.

出版信息

Materials (Basel). 2022 May 11;15(10):3468. doi: 10.3390/ma15103468.

DOI:10.3390/ma15103468
PMID:35629496
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9145986/
Abstract

Concrete construction harms our environment, making it urgent to develop new methods for building with less materials. Structurally efficient shapes are, however, often expensive to produce, because they require non-standard formworks, thus, standard structures, which use more material than is often needed, remain cheaper. Digital fabrication has the potential to change this paradigm. One method is Digital Casting Systems (DCS), where the hydration of self-compacting concrete is controlled on the fly during production, shortening the required setting time and reducing hydrostatic pressure on the formwork to a minimum. This enables a productivity increase for standard concrete production. More importantly, though, it enables a rethinking of formworks, as the process requires only cheap thin formworks, thus, unlocking the possibility to produce optimised structural members with less bulk material and lower environmental cost. While DCS has already proven effective in building structural members, this process faces the challenge of moving into industry. This paper covers the next steps in doing so. First, we present the benchmark and expectations set by the industry. Second, we consider how we comply with these requirements and convert our fast-setting self-compacting mortar mix into a coarser one. Third, we present the next generation of our digital processing system, which moves closer to the industrial requirements in terms of size and the control system. Finally, two prototypes demonstrate how DSC: (a) increases standard bulk production by 50% and (b) can be cast into ultra-thin formworks. We discuss the results and the short-term industrial concerns for efficiency and robustness, which must be addressed for such a system to be fully implemented in industry.

摘要

混凝土建筑对环境造成危害,因此迫切需要开发使用更少材料的新型建筑方法。然而,结构高效的形状通常生产成本高昂,因为它们需要非标准模板,所以,使用材料多于实际所需的标准结构仍然更便宜。数字制造有潜力改变这一模式。一种方法是数字铸造系统(DCS),在生产过程中实时控制自密实混凝土的水化,缩短所需的凝结时间,并将模板上的静水压力降至最低。这提高了标准混凝土生产的效率。不过,更重要的是,它促使人们重新思考模板,因为该工艺只需要便宜的薄模板,从而开启了用更少的散装材料和更低的环境成本生产优化结构构件的可能性。虽然DCS已在建筑结构构件方面证明有效,但这一工艺面临着进入工业领域的挑战。本文涵盖了这样做的后续步骤。首先,我们介绍行业设定的基准和期望。其次,我们考虑如何满足这些要求,并将我们的快凝自密实砂浆混合物转换为更粗的混合物。第三,我们展示了我们下一代数字处理系统,该系统在尺寸和控制系统方面更接近工业要求。最后,两个原型展示了DSC如何:(a)将标准批量生产提高50%,以及(b)可以浇筑到超薄模板中。我们讨论了结果以及短期内工业界对效率和稳健性的担忧,要使这样一个系统在工业中全面实施,必须解决这些问题。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e2a7/9145986/80af8318b7b8/materials-15-03468-g015.jpg
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本文引用的文献

1
Overcoming Environmental Stress Cracking of FDM 3D Printed Formwork for Counter-Pressure Casting of Concrete.克服用于混凝土反压铸造的熔融沉积成型3D打印模板的环境应力开裂
3D Print Addit Manuf. 2022 Apr 1;9(2):122-131. doi: 10.1089/3dp.2021.0006. Epub 2022 Apr 11.
2
Eco-Friendly, Set-on-Demand Digital Concrete.环保型按需定制数字混凝土。
3D Print Addit Manuf. 2022 Feb 1;9(1):3-11. doi: 10.1089/3dp.2020.0350. Epub 2022 Feb 10.