Understanding the Mechanics of complex topology of the 3D printed Anthill architecture

IF 2.9 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Oxford open materials science Pub Date : 2022-05-11 DOI:10.1093/oxfmat/itac003

B. Kushwaha, Avinash Kumar, Rushikesh S. Ambekar, V. Arya, Solomon Demiss Negedu, Deep Bakshi, E. Olu, R. S. Ayyagari, Varinder Pal, K. K. Sadasivuni, N. Pugno, Chirodeep Bakli, C. Tiwary

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引用次数: 4

Abstract

The present work aimed to investigate the deformation behavior of complex ant mound architectures under compression. We have used the cement casting method to extract four different ant nest morphologies. These casted cement structures were digitalized using a 3D micro-computer tomography (CT) scan. The digitized structures were simulated under different loading conditions using Finite Element Methods (FEM). In order to supplement the numerical understanding, the digital architectures were 3D printed and experimentally tested under uniaxial loading conditions. Ants produce a variety of complex architectures for adapting to the surrounding environment and ants’ needs. Ant mound consists of at least one pillar with a broad base tapered towards its tip. Anthill architectures have unique topological features. Mechanical strength of ant mould can be 600 times enhanced by tuning topology. Thickness and angle of pillars have huge effect on load-bearing property The branched structures can endure larger stress and deform in the process under a volumetric pressure application, making them sacrificial units for extreme disasters like floods and earthquakes. The 3D printing experiments and Finite Element Methods simulations are needed to tackle the complex ant mound architectures and appear in good agreement, suggesting a robust design and thus the possibility of constructing anthill-inspired civil buildings with a tree-trunk-like geometry.

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了解3D打印蚁丘结构的复杂拓扑结构

本文旨在研究复杂蚁丘结构在压缩作用下的变形行为。我们使用水泥浇铸法提取了四种不同的蚁巢形态。这些浇铸水泥结构使用三维微计算机断层扫描(CT)进行数字化。采用有限元方法对数字化结构进行了不同载荷条件下的数值模拟。为了补充数值理解，对数字结构进行了3D打印，并在单轴载荷条件下进行了实验测试。蚂蚁为了适应周围环境和蚂蚁的需要，产生了各种复杂的结构。蚁丘由至少一根柱子组成，其底部宽阔，向其尖端逐渐变细。蚁丘建筑具有独特的拓扑特征。通过调整拓扑结构，可使蚁模的机械强度提高600倍。柱的厚度和角度对承重性能影响巨大，分支结构在体压作用下承受较大的应力和变形，是洪水、地震等极端灾害的牺牲单元。需要3D打印实验和有限元方法模拟来解决复杂的蚁丘结构，并出现良好的协议，这表明一个稳健的设计，从而有可能建造具有树干状几何形状的蚁丘启发的民用建筑。

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来源期刊

Oxford open materials science

CiteScore

3.60

自引率

0.00%

发文量

审稿时长

7 weeks