Wall Climbing Robot Using Electrostatic Adhesion Force Generated by Flexible Interdigital Electrodes

Liu, Rong; Chen, Rui; Shen, Hua; Zhang, Rong

doi:10.5772/54634

Cited by 75 publications

(64 citation statements)

References 14 publications

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“…Intuitively, one expect this approach to be accurate when the interaction force between the surfaces is long-range, and a similar approach has been used for the attraction resulting from capillary bridges [23,24] and also in an earlier study of electroadhesion [13][14][15]. Using (16) and (17) we have:…”

Section: Mean-field Theory Of Electroadhesionmentioning

confidence: 98%

Electroadhesion for soft adhesive pads and robotics: theory and numerical results

Persson

Guo

2019

Soft Matter

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Soft adhesive pads are needed for many robotics applications, and one approach is based on electroadhesion. Here we present a general analytic model and numerical results for electroadhesion for soft solids with arbitrary time-dependent applied voltage, and arbitrary dielectric response of the solids, and including surface roughness. We consider the simplest coplanar-plate-capacitor model with a periodic array of conducting strips located close to the surface of the adhesive pad, and discuss the optimum geometrical arrangement to obtain the maximal electroadhesion force. For surfaces with roughness the (non-contact) gap between the solids will strongly influence the electroadhesion, and we show how the electroadhesion force can be calculated using a contact mechanics theory for elastic solids. The theory and models we present can be used to optimize the design of adhesive pads for robotics application.

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Section: Mean-field Theory Of Electroadhesionmentioning

confidence: 98%

Electroadhesion for soft adhesive pads and robotics: theory and numerical results

Persson

Guo

2019

Soft Matter

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“…In parallel with bioinspired adhesion strategies, engineered methods, such as vacuum tracks (15,16), permanent magnetic and electromagnetic mechanisms (17,18), and electroadhesive pads (19)(20)(21), have proven to be successful surface attachment options. It is often the case that the adhesion type determines the size and design complexity of the robot; for example, vacuum track-based suction mechanisms (15,16) or electromagnetic mechanisms (17,18) require the robots to use heavy on-board components that increase their overall mass and reduce maneuverability.…”

Section: Introductionmentioning

confidence: 99%

Inverted and vertical climbing of a quadrupedal microrobot using electroadhesion

et al. 2018

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The ability to climb greatly increases the reachable workspace of terrestrial robots, improving their utility for inspection and exploration tasks. This is particularly desirable for small (millimeter-scale) legged robots operating in confined environments. This paper presents a 1.48-gram and 4.5-centimeter-long tethered quadrupedal microrobot, the Harvard Ambulatory MicroRobot with Electroadhesion (HAMR-E). The design of HAMR-E enables precise leg motions and voltage-controlled electroadhesion for repeatable and reliable climbing of inverted and vertical surfaces. The innovations that enable this behavior are an integrated leg structure with electroadhesive pads and passive alignment ankles and a parametric tripedal crawling gait. At a relatively low adhesion voltage of 250 volts, HAMR-E achieves speeds up to 1.2 (4.6) millimeters per second and can ambulate for a maximum of 215 (162) steps during vertical (inverted) locomotion. Furthermore, HAMR-E still retains the ability for high-speed locomotion at 140 millimeters per second on horizontal surfaces. As a demonstration of its potential for industrial applications, such as in situ inspection of high-value assets, we show that HAMR-E is capable of achieving open-loop, inverted locomotion inside a curved portion of a commercial jet engine.

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“…Wall climbing robots, which are a special operation mechanism in extreme environment generally adhere to walls by virtue of negative suckers, permanent magnets, or bio-inspired adhesion [1][2][3][4][5][6]. However, magnetic adhesion fails for wall surfaces under long-term vibrations, such as diagonal cable bridge towers and viaduct bridge piers.…”

Section: Introductionmentioning

confidence: 99%

Grasping Claws of Bionic Climbing Robot for Rough Wall Surface: Modeling and Analysis

Jiang

Fei

2017

Applied Sciences

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Aiming at the inspection of rough stone and concrete wall surfaces, a grasping module of cross-arranged claw is designed. It can attach onto rough wall surfaces by hooking or grasping walls. First, based on the interaction mechanism of hooks and rough wall surfaces, the hook structures in claw tips are developed. Then, the size of the hook tip is calculated and the failure mode is analyzed. The effectiveness and reliability of the mechanism are verified through simulation and finite element analysis. Afterwards, the prototype of the grasping module of claw is established to carry out grasping experiment on vibrating walls. Finally, the experimental results demonstrate that the proposed cross-arranged claw is able to stably grasp static wall surfaces and perform well in grasping vibrating walls, with certain anti-rollover capability. This research lays a foundation for future researches on wall climbing robots with vibrating rough wall surfaces.

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Wall Climbing Robot Using Electrostatic Adhesion Force Generated by Flexible Interdigital Electrodes

Cited by 75 publications

References 14 publications

Electroadhesion for soft adhesive pads and robotics: theory and numerical results

Electroadhesion for soft adhesive pads and robotics: theory and numerical results

Inverted and vertical climbing of a quadrupedal microrobot using electroadhesion

Grasping Claws of Bionic Climbing Robot for Rough Wall Surface: Modeling and Analysis

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