A robotic device using gecko-inspired adhesives can grasp and manipulate large objects in microgravity

Jiang, Hao; Hawkes, Elliot W.; Fuller, Christine; Estrada, Matthew A.; Suresh, Srinivasan A.; Abcouwer, Neil; Han, Amy Kyungwon; Wang, Yunlong; Ploch, Christopher J.; Parness, Aaron; Cutkosky, Mark R.

doi:10.1126/scirobotics.aan4545

Cited by 210 publications

(138 citation statements)

References 42 publications

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“…This unique adhesive capability of geckos has led to the development of advanced adhesives, including dry adhesives, which unlike chemical adhesives, leave no residue [3]. Such dry adhesives generally have micro-nano array structures, and are expected to be suitable for robotic end-effectors [4][5][6][7]. At present, there are generally two main types of materials being researched as materials for gecko-inspired dry adhesives [8]: Synthetic polymers [5,9,10] and vertically-aligned carbon nanotubes (VACNTs) [11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Effect of Hydrogen Concentration on the Growth of Carbon Nanotube Arrays for Gecko-Inspired Adhesive Applications

Duan

et al. 2017

Coatings

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Vertically-aligned carbon nanotubes (VACNTs) have extraordinary structural and mechanical properties, and have been considered as potential candidates for creating dry adhesives inspired by adhesive structures in nature. Catalytic chemical vapor deposition is widely used to grow VACNTs; however, the influential mechanism of VACNT preparation parameters (such as H 2 concentration) on its adhesion property is not clear, making accurate control over the structure of VACNTs adhesive an ongoing challenge. In this article, we use electron beam-deposited SiO 2 /Al 2 O 3 as a support layer, Fe as catalyst, and C 2 H 4 /H 2 gas mixtures as a feed gas to prepare VACNTs, while varying the ratio of the reducing atmosphere (H 2 ) from 0% to 35%. VACNTs synthesized at a 15% H 2 concentration (5 mm × 5 mm in size) can support a maximal weight of 856 g, which indicates a macroscopic shear adhesive strength of 34 N/cm 2 . We propose a hydrogen-concentration-dependent model for the shear adhesive performance of VACNTs. By adjusting the amount of hydrogen present during the reaction, the morphology and quality of the prepared VACNTs can be precisely controlled, which significantly influences its shear adhesive performance. These results are advantageous for the application of carbon nanotubes as dry adhesives.

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Section: Introductionmentioning

confidence: 99%

Effect of Hydrogen Concentration on the Growth of Carbon Nanotube Arrays for Gecko-Inspired Adhesive Applications

Duan

et al. 2017

Coatings

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“…Achieving the ability to climb walls with agile motions has long been a challenge in the field of robotics (1)(2)(3). Although a number of rigid wallclimbing robots have been developed with good performances in applications such as inspection, surveillance, and cleaning (4-28), they generally rely on complicated mechanisms composed of rigid actuators (such as electromagnetic or electrostatic motors) and transmission components (such as pulleys, wheels, or belts).…”

Section: Introductionmentioning

confidence: 99%

Soft wall-climbing robots

et al. 2018

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Existing robots capable of climbing walls mostly rely on rigid actuators such as electric motors, but soft wall-climbing robots based on muscle-like actuators have not yet been achieved. Here, we report a tethered soft robot capable of climbing walls made of wood, paper, and glass at 90°with a speed of up to 0.75 body length per second and multimodal locomotion, including climbing, crawling, and turning. This soft wallclimbing robot is enabled by (i) dielectric-elastomer artificial muscles that generate fast periodic deformation of the soft robotic body, (ii) electroadhesive feet that give spatiotemporally controlled adhesion of different parts of the robot on the wall, and (iii) a control strategy that synchronizes the body deformation and feet electroadhesion for stable climbing. We further demonstrate that our soft robot could carry a camera to take videos in a vertical tunnel, change its body height to navigate through a confined space, and follow a labyrinth-like planar trajectory. Our soft robot mimicked the vertical climbing capability and the agile adaptive motions exhibited by soft organisms.

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“…Most space debris comes from abandoned rocket bodies, defunct satellites, their exploded fragments, space rocks, and out-of-control spacecraft, which are typically called non-cooperative objects [2]. The development of space robotic technologies for dealing with non-cooperative objects has attracted substantial interest [3].…”

Section: Introductionmentioning

confidence: 99%

“…For dealing with this class of objects, two main strategies are employed: One is to use flexible capturing theories and methods, including tether nets [18], [19], tether grippers [20], [21], robotic capsules [22] and robotic tentacles [23]; the other is to capture objects using robotic arms with customized capture effectors, of which end-effectors are the most important tools as they can directly determine the success of tasks [24]. An innovative strategy is proposed for adhering directly to the surfaces of objects and an electro-adhesive gripper [17] and a gecko-inspired adhesive gripper [3] are d e v el o pe d f o r ca p t u ri n g n o n -g ra sp a bl e o b je cts. [22] is proposed for capturing asteroids.…”

Section: Introductionmentioning

confidence: 99%

Effective Capture of Nongraspable Objects for Space Robots Using Geometric Cage Pairs

Zhang

Liu

Feng

et al. 2020

IEEE/ASME Trans. Mechatron.

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Capture and removal of space debris is challenging in robotic on-orbit servicing (OOS) activities. A large portion of space debris does not possess any graspable features, which makes conventional grippers inapplicable. To handle such non-graspable objects, a space robotic capture system is presented. A dual-arm space robot simulator that has the advantages of miniaturization and scalability is designed for ground tests. Inspired by robotic caging, we propose a novel capture method that uses a series of hollow-shaped end-effector pairs to cage the antipodal pairs of non-graspable objects. To apply the caging-pair method steadily, space robots need exerting a squeezing action on objects, which can be characterized by the motion and force manipulation of two robotic arms in the assigned directions. Based on the velocity and force manipulability transmission ratios, a caging compatibility index is proposed to describe the capturing ability in this manner. Via the optimization of the desired caging compatibility index, an effective algorithm is proposed to plan near-optimal joint configurations for pre-grasping cages. Finally, both simulation studies and experimental tests are conducted to evaluate the performance of the proposed capture method. Index Terms-Non-graspable objects, space robot simulator, caging-pair method, caging compatibility index. R ! ! q q w J v J J Mv k J T Mv E k k k = t k J

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A robotic device using gecko-inspired adhesives can grasp and manipulate large objects in microgravity

Cited by 210 publications

References 42 publications

Effect of Hydrogen Concentration on the Growth of Carbon Nanotube Arrays for Gecko-Inspired Adhesive Applications

Effect of Hydrogen Concentration on the Growth of Carbon Nanotube Arrays for Gecko-Inspired Adhesive Applications

Soft wall-climbing robots

Effective Capture of Nongraspable Objects for Space Robots Using Geometric Cage Pairs

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