Advancement of Electroadhesion Technology for Intelligent and Self‐Reliant Robotic Applications

Rajagopalan, Pandey; Muthu, Manikandan; Liu, Yulu; Luo, Jikui; Wang, Xiaozhi; Wan, Chaoying

doi:10.1002/aisy.202200064

Cited by 20 publications

(18 citation statements)

References 183 publications

(299 reference statements)

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“…[1,29] Other physical parameters, such as surface conditions and roughness can also influence the normal force. [18] Thus, we performed experimental characterization of the EA generated force (Figure 4b). The tensile machine lowers the gripper onto the flat surface and a voltage is applied from 0 to 5 kV with a step increment of 0.5 kV.…”

Section: Grasping Force Characterizationmentioning

confidence: 99%

“…The higher surface roughness in a rigid state makes the contact area between the device and the manipulated object lower than in a soft state. [18] Contrary to EA-based grippers, GJ-based grippers can grasp objects that are powdered, moistened, and porous. [11] In this study, we chose different gripper design and material composition from already existing devices.…”

Section: Grasping Force Characterizationmentioning

confidence: 99%

“…Electroadhesion (EA) instead is an adhesive technology that leverages the shear force generated by electrostatic forces. [18] Electroadhesive pads have been combined with different actuation technologies, such as dielectric elastomer actuation, [1] soft pneumatic actuation, [19] layer jamming, [20] and Fin-Ray structured actuation [21] . The enhanced shear force makes EA-based grippers capable of delicately grasping both flat and fragile objects without squeezing or breaking them.…”

Section: Introductionmentioning

confidence: 99%

“…[1,[22][23][24][25][26] While the adhesive force of EA pads can be tuned by regulating electrical input, EA effectiveness is highly dependent on the environmental and surface conditions of the object being grasped. [18] In particular electroadhesion is less effective for objects that are greasy, rough, or wet. [2] An additional challenge of soft grippers that rely on electroadhesion is the residual electrostatic charge that remains for a few seconds after removing the voltage and can result in difficult release of light objects.…”

Section: Introductionmentioning

confidence: 99%

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A Soft Gripper with Granular Jamming and Electroadhesive Properties

Piskarev¹,

Devincenti²,

Ramachandran³

et al. 2022

Preprint

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In recent years, there has been a growing interest in the development of universal soft grippers that can handle objects of varying form factors (including flat objects), surface condition (including moistened or oily objects), and mechanical properties (deformable and fragile). Yet, there is no single gripper that can gently grip objects with such a wide range of properties. In this paper, we present a soft gripper that combines granular jamming (GJ) and electroadhesion (EA) to gently grasp and release a large set of diverse objects. The gripper can operate in GJ mode only, in EA mode only, or in a combination mode that simultaneously activates GJ and EA. In GJ mode, the gripper can grasp objects with different surface properties, lift objects 38 times its own weight using negative pressure, and release objects by applying positive pressure, but has difficulty in handling flat and fragile objects. In EA mode, the gripper can manipulate flat and fragile objects but encounters difficulties with different surface properties such as oily or moistened. In the combination mode, the gripper can generates grasping forces up to 35% higher than in the GJ mode for all object sizes and certain shapes such as a cylinder.

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Section: Grasping Force Characterizationmentioning

confidence: 99%

Section: Grasping Force Characterizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A Soft Gripper with Granular Jamming and Electroadhesive Properties

Piskarev¹,

Devincenti²,

Ramachandran³

et al. 2022

Preprint

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“…The basic structure of our gripper is the same as that of existing pad-based electroadhesive grippers [7], [8], [9], [10]; it consists of a pad with embedded interdigital electrodes and a controller that applies high voltages to the electrodes. The pad adheres to a sheet of paper via electrostatic force when a high voltage is applied to the electrodes [7], [11], [12], [13]. Thus, the gripper enables a robot to grip a sheet of paper with a simple control of its hand.…”

Section: Introductionmentioning

confidence: 99%

An Electroadhesive Paper Gripper With Application to a Document-Sorting Robot

2022

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Robotic process automation (RPA) is automating various job processes in many offices. However, most existing RPA systems automate only processes that are performed on computers. It is highly desirable to develop physical RPA systems that incorporate real robots to automate physical job processes. When developing physical RPA systems, handling paper is particularly important because many physical office jobs involve handling paper documents. However, it is not easy for robots to handle paper because paper is fragile. To address this issue, we propose an electroadhesive paper gripper in this study. The use of electroadhesion enables a robot to handle paper in a simple, non-destructive, and quiet manner. We provide (1) a mechanism for lifting a sheet of paper without accurate control of robot hands, (2) a mechanism for a small gripper to hold a large sheet of paper without bending it, and (3) a method for quickly releasing a sheet of paper. Furthermore, we apply the proposed paper gripper to a document-sorting robot. The robot that we have developed automatically arranges a given stack of paper documents in a predetermined order (e.g., alphabetical or numerical). Experimental results show the validity of the paper gripper and the sorting robot.INDEX TERMS Automatic document-sorting robot, electroadhesive paper gripper, physical robots in offices, robotic process automation (RPA).

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Switchable Adhesion of Hydrogels to Plant and Animal Tissues

Borden,

Nader,

Burni

et al. 2024

Advanced Science

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The ability to “switch on” adhesion between a thin hydrogel and a biological tissue can be useful in biomedical applications such as surgery. One way to accomplish this is with an electric field, a phenomenon termed electroadhesion (EA). Here, it is shown that cationic gels can be adhered by EA to tissues across all of biology. This includes tissues from animals, including humans and other mammals; birds; fish; reptiles (e.g., lizards); amphibians (e.g., frogs), and invertebrates (e.g., shrimp, worms). Gels can also be adhered to soft tissues from plants, including fruit (e.g., plums) and vegetables (e.g; carrot). In all cases, EA is induced by a low electric field (DC, 10 V) applied for a short time (20 s). After the field is removed, the adhesion persists. The adhesion can also be reversed by applying the field with opposite polarity. In mammals, EA is strong for many tissues (e.g., arteries, muscles, and cornea), but not others (e.g., adipose, brain). Tissues with anisotropic structure show anisotropic adhesion strength by EA. The higher the concentration of anionic polymers in a tissue, the stronger its adhesion to cationic gels. This underscores that EA is mediated by the electrophoresis of chain segments across the gel‐tissue interface.

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Advancement of Electroadhesion Technology for Intelligent and Self‐Reliant Robotic Applications

Cited by 20 publications

References 183 publications

A Soft Gripper with Granular Jamming and Electroadhesive Properties

A Soft Gripper with Granular Jamming and Electroadhesive Properties

An Electroadhesive Paper Gripper With Application to a Document-Sorting Robot

Switchable Adhesion of Hydrogels to Plant and Animal Tissues

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