Spines and Inclines: Bioinspired Spines on an Insect-Scale Robot Facilitate Locomotion on Rough and Inclined Terrain.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Alyssa M Hernandez, Perrin E Schiebel, Jennifer Shum, Robert J Wood
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引用次数: 0

Abstract

To navigate complex terrains, insects use diverse tarsal structures (adhesive pads, claws, spines) to reliably attach to and locomote across substrates. This includes surfaces of variable roughness and inclination, which often require reliable transitions from ambulatory to scansorial locomotion. Using bioinspired physical models as a means for comparative research, our study specifically focused on the diversity of tarsal spines, which facilitate locomotion via frictional engagement and shear force generation. For spine designs, we took inspiration from ground beetles (Family Carabidae), which is a largely terrestrial group known for their quick locomotion. Evaluating four different species, we found that the hind legs host linear rows of rigid spines along the entire tarsus. By taking morphometric measurements of the spines, we highlighted parameters of interest (e.g., spine angle and aspect ratio) in order to test their relationship to shear forces sustained during terrain interactions. We systematically evaluated these parameters using spines cut from stainless steel shim attached to a small acrylic sled loaded with various weights. The sled was placed on 3D-printed models of rough terrain, randomly generated using fractal Brownian motion, while a motorized pulley system applied force to the spines. A force sensor measured the reaction force on the terrain, recording shear force before failure occurred. Initial shear tests highlighted the importance of spine angle, with bioinspired anisotropic designs producing higher shear forces. Using this data, we placed the best (50○ angle) and worst (90○ angle) performing spines on the legs of our insect-scale ambulatory robot physical model. We then tested the robot on various surfaces at 0, 10 and 20○ inclines, seeing similar success with the more bioinspired spines.

刺与斜面:昆虫级机器人上的生物启发刺有助于在崎岖和倾斜的地形上行走。
为了在复杂的地形上航行,昆虫利用各种跗关节结构(粘垫、爪、刺)可靠地附着在基质上并在基质上运动。这包括粗糙度和倾斜度各异的表面,而这些表面通常需要可靠地从伏地运动过渡到扫描运动。利用生物启发物理模型作为比较研究的手段,我们的研究特别关注跗骨棘的多样性,它通过摩擦啮合和产生剪切力来促进运动。在刺的设计方面,我们从地甲虫(甲壳虫科)中汲取了灵感,地甲虫主要是以快速运动著称的陆生类群。在对四个不同物种进行评估后,我们发现它们的后腿在整个跗节上都有一排线性的硬刺。通过对棘刺的形态测量,我们突出了感兴趣的参数(如棘刺角度和长宽比),以检验它们与地形相互作用时所承受的剪切力之间的关系。我们使用从不锈钢垫片上切割下来的脊柱系统地评估了这些参数,这些垫片连接在一个装有不同重量的小型丙烯酸雪橇上。雪橇被放置在利用分形布朗运动随机生成的粗糙地形 3D 打印模型上,同时电动滑轮系统对棘刺施力。力传感器测量地形上的反作用力,记录发生故障前的剪切力。最初的剪切测试强调了脊柱角度的重要性,生物启发各向异性设计产生的剪切力更大。利用这些数据,我们将性能最好(50°)和最差(90°)的脊柱放置在昆虫尺度可移动机器人物理模型的腿上。然后,我们在倾斜度为 0、10 和 20 ○ 的各种表面上对机器人进行了测试,结果显示,生物启发较多的棘刺取得了类似的成功。
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
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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