MyCera。菌丝生长在数字制造粘土结构中的应用

IF 1.6 0 ARCHITECTURE

International Journal of Architectural Computing Pub Date : 2022-03-01 DOI:10.1177/14780771221082248

Julian Jauk, Lukas Gosch, H. Vašatko, Ingolf Christian, Anita S. Klaus, M. Stavrić

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引用次数: 3

摘要

在本文中，我们将展示一个数字工作流程，其中包括菌丝体等活材料，并使结构设计的创建成为可能。我们的跨学科研究将数字制造与菌丝生长的使用相结合，从而实现微观尺度上的纤维连接。我们开发了一种结构，该结构使用材料通知的工具路径进行基于浆料的挤出，这是建立在比较材料特性和生长观察的实验基础上的。随后，通过使用菌丝体作为智能定向纤维增强材料，3D打印的未烧制粘土构件的抗拉强度得到了提高。在活状态下组装粘土-菌丝复合材料允许结构内部的力传递连接。这种复合材料具有结构特性，为其在建筑行业的应用开辟了可能性。它允许设计和高效制造为这种复合材料定制的轻质陶瓷结构，这是使用传统陶瓷制造方法无法实现的。

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MyCera. Application of mycelial growth within digitally manufactured clay structures

In this paper we will demonstrate a digital workflow that includes a living material such as mycelium and makes the creation of structural designs possible. Our interdisciplinary research combines digital manufacturing with the use of mycelial growth, which enables fibre connections on a microscopic scale. We developed a structure that uses material informed toolpaths for paste-based extrusion, which are built on the foundation of experiments that compare material properties and growth observations. Subsequently, the tensile strength of 3D printed unfired clay elements was increased by using mycelium as an intelligently oriented fibre reinforcement. Assembling clay-mycelium composites in a living state allows force-transmitting connections within the structure. This composite has exhibited structural properties that open up the possibility of its implementation in the building industry. It allows the design and efficient manufacturing of lightweight ceramic constructions customised to this composite, which would not have been possible using conventional ceramics fabrication methods.

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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