Nonlinear Multimaterial Architecture for Greater Soft Material's Toughness and Delaying Damage Propagation.

IF 6.4 2区 计算机科学 Q1 ROBOTICS
Soft Robotics Pub Date : 2023-10-01 Epub Date: 2023-05-12 DOI:10.1089/soro.2021.0205
Marwa ElDiwiny, Seppe Terryn, Svetlana Verbruggen, Bram Vanderborght
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Abstract

Designing soft robots that have greater toughness and better resistance to damage propagation while at the same time retaining their properties of compliance is fundamentally important for soft robotics applications. This study's main contribution is proposing a framework for nonlinear multimaterial architectural design of soft structures to increase their toughness and delay damage propagation. What are the limits when combining significantly different materials in one structure that will delay crack propagation while significantly maintaining postdamage toughness? Through this study, we observed that there is a very dynamic interplay when combining significantly different materials in one structure; this interplay could weaken or strengthen the multimaterial structure's toughness. In biological evolutionary terms, the Pangolin, Seashell, and Arapaima have found their answer for deflecting the crack and maintaining strength in their bodies. How does nature put these multimaterial structures together? Our research led us to find that the multimaterial toughness limits depend largely on the following parameters: components' relative morphology, architecture, spatial distribution, surface areas, and Young's Modulus. We found that a linear geometry, when it comes to morphology and/or architecture relative to surface area in multimaterial design, significantly reduces total toughness and fails to delay crack propagation. In contrast, incorporating geometric nonlinearities in both morphology and architecture significantly maintains higher total toughness even after damage, and significantly delays crack propagation. We believe that this study can open the door to further research and ultimately to promising and wide applications in soft robotics.

用于提高软材料韧性和延迟损伤传播的非线性多材料体系结构。
设计具有更大韧性和更好抵抗损伤传播的软机器人,同时保持其柔顺性,对于软机器人应用至关重要。本研究的主要贡献是为软结构的非线性多材料建筑设计提出了一个框架,以提高其韧性并延迟损伤传播。当在一个结构中组合显著不同的材料时,在显著保持损伤后韧性的同时,会延迟裂纹扩展,限制是什么?通过这项研究,我们观察到,当在一个结构中组合显著不同的材料时,存在非常动态的相互作用;这种相互作用可能会削弱或增强多材料结构的韧性。从生物学进化的角度来看,穿山甲、贝壳和阿拉派马已经找到了偏转裂缝和保持身体力量的答案。大自然是如何将这些多材料结构组合在一起的?我们的研究发现,多材料的韧性极限在很大程度上取决于以下参数:部件的相对形态、结构、空间分布、表面积和杨氏模量。我们发现,在多材料设计中,当涉及到相对于表面积的形态和/或结构时,线性几何形状会显著降低总韧性,并不能延迟裂纹扩展。相反,在形态和结构中结合几何非线性,即使在损伤后也能显著保持较高的总韧性,并显著延迟裂纹扩展。我们相信,这项研究可以为进一步的研究打开大门,并最终在软机器人领域获得有前景和广泛的应用。
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来源期刊
Soft Robotics
Soft Robotics ROBOTICS-
CiteScore
15.50
自引率
5.10%
发文量
128
期刊介绍: Soft Robotics (SoRo) stands as a premier robotics journal, showcasing top-tier, peer-reviewed research on the forefront of soft and deformable robotics. Encompassing flexible electronics, materials science, computer science, and biomechanics, it pioneers breakthroughs in robotic technology capable of safe interaction with living systems and navigating complex environments, natural or human-made. With a multidisciplinary approach, SoRo integrates advancements in biomedical engineering, biomechanics, mathematical modeling, biopolymer chemistry, computer science, and tissue engineering, offering comprehensive insights into constructing adaptable devices that can undergo significant changes in shape and size. This transformative technology finds critical applications in surgery, assistive healthcare devices, emergency search and rescue, space instrument repair, mine detection, and beyond.
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