Hierarchical Structures Computational Design and Digital 3d Printing

IF 1.1 Q3 ENGINEERING, CIVIL
Luis Borunda, Jesús Anaya
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引用次数: 0

Abstract

Current advances in construction automation, especially in large-scale additive manufacturing, highlight the vast potential for robots in architecture. Robotic construction is unique in its potential to reproduce highly complex structures. To advance the question of how rapid prototyping techniques are adopted in large-scale 3D printing of forms and structures, this paper presents computational methods for the design and robotic construction of cellular membranes. This research presents a comprehensive morphological model of structurally differentiated cellular membranes based on the theoretical biology model of hierarchical structures found in natural cellular solids, and, more specifically, in trabecular bone. The morphological model originates from a system of forces in equilibrium; therefore, it presents the geometric homology of a static tensional system. This research offers a methodology for the design and manufacture of meso- to large-scale triangulated geometric configurations by discrete design methods that are suitable for the robotic fused deposition of lattices and their architectural implementation in the automated manufacturing of shell structures. First, this paper explores how a form can be digitally created by geometrically emulating a given static system of forces in space. Second, inspired by the complex mechanical behavior of cancellous bone, we apply hierarchical principles found in bone remodeling to characterize discrete units that conform to continuous trabecular-like lattices. We study the geometry, limitations, opportunities for optimization, and mechanical characteristics of the lattice. The computational design methods and additive manufacturing techniques are tested in the design and construction hierarchical structures.
分层结构、计算设计和数字3d打印
目前在建筑自动化方面的进展,特别是在大规模增材制造方面,突出了机器人在建筑领域的巨大潜力。机器人建筑在复制高度复杂结构方面具有独特的潜力。为了解决快速原型技术如何应用于大规模3D打印形式和结构的问题,本文提出了细胞膜设计和机器人施工的计算方法。本研究基于在天然细胞固体中,更具体地说,在小梁骨中发现的分层结构的理论生物学模型,提出了结构分化细胞膜的综合形态学模型。形态模型来源于平衡力系统;因此,给出了静态张拉系统的几何同调性。本研究为设计和制造中尺度到大尺度的三角几何结构提供了一种方法,该方法适用于机器人熔接沉积晶格及其在壳结构自动化制造中的建筑实现。首先,本文探讨了如何通过几何模拟空间中给定的静态力系统来数字创建形式。其次,受松质骨复杂力学行为的启发,我们应用骨重塑中发现的分层原则来表征符合连续小梁样晶格的离散单元。我们研究几何,限制,优化的机会,和晶格的机械特性。计算设计方法和增材制造技术在分层结构的设计和建造中得到了验证。
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
CiteScore
1.40
自引率
0.00%
发文量
17
期刊介绍: The Association publishes an international journal, the Journal of the IASS, four times yearly, in print (ISSN 1028-365X) and on-line (ISSN 1996-9015). The months of publication are March, June, September and December. Occasional extra electronic-only issues are included in the on-line version. From this page you can access one or more issues -- a sample issue if you are not logged into the members-only portion of the site, or the current issue and several back issues if you are logged in as a member. For any issue that you can view, you can download articles as .pdf files.
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