SUAS: A Novel Soft Underwater Artificial Skin with Capacitive Transducers and Hyperelastic Membrane

Muscolo, Giovanni Gerardo; Moretti, Giacomo; Cannata, Giorgio

doi:10.1017/s0263574718001315

Cited by 15 publications

(10 citation statements)

References 38 publications

(75 reference statements)

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“…When these tactile sensors are employed to a manipulator in the form of an array, an understanding for shape recognition and localized impact forces can be realized more expansively [156]. Muscolo et al reported an electrostatic capacitive tactile sensor potentially effective for underwater use [157]. In this sensing mechanism, a semi-cylindrical surface of flexible conductive artificial skin is separated from an array of capacitive transducers using a high dielectric oil.…”

Section: Tactile Sensors For Uw Environmentmentioning

confidence: 99%

Soft Robotic Hands and Tactile Sensors for Underwater Robotics

2021

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Research in the field of underwater (UW) robotic applications is rapidly developing. The emergence of coupling the newest technologies on submersibles, different types of telecommunication devices, sensors, and soft robots is transforming the rigid approach to robotic design by providing solutions that bridge the gap between accuracy and adaptability in an environment where there is so much fluctuation in object targeting and environmental conditions. In this paper, we represent a review of the history, development, recent research endeavors, and projected outlook for the area of soft robotics technology pertaining to its use with tactile sensing in the UW environment.

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Section: Tactile Sensors For Uw Environmentmentioning

confidence: 99%

Soft Robotic Hands and Tactile Sensors for Underwater Robotics

2021

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“…where ψ is the strain energy function, c 1 and c 2 are constants, and I 1 and I 2 are, respectively, the first and the second invariant [25,28]. All of the simulations were performed with: c 1 = 0.25 MPa, c 2 = 0 MPa, density = 1000 kg/m 3 .…”

Section: Fem Analysis Of the Patucco Actuatormentioning

confidence: 99%

“…In this paper, the authors attempted to apply the RCC concept to a new linear variable stiffness pneumatic actuator, which was presented for the first time in [19], and named for convenience using the acronym PATuCCo (Pneumatic Actuator with Tunable-Compliance Constraint). To date, a large number of variable stiffness actuators have been developed but, in general, stiffness is controllable only in the same direction of the actuation [20][21][22][23][24][25]. In [19], the authors proposed a novel pneumatic actuator with tunable compliance that is able to modify the general stiffness of its internal constraints due to the use of rolling diaphragm seals for separating the actuator's chambers.…”

Section: Introductionmentioning

confidence: 99%

A New Soft RCC Device with Pneumatic Regulation

2020

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The work described in this paper aims at exploiting the characteristic of a special deformable actuator with rolling membranes to realize a device with defined Remote Center of Compliance (RCC). Starting from theoretical approaches to the definition of the RCC, the authors propose a novel and simple formulation that can be applied to the soft actuator to determine its RCC. The position of the device’s RCC was determined by creating an asymmetry on the geometry of the device along its axis, i.e., by imposing a longitudinal displacement to the piston with respect to the membranes’ rest condition. FEM simulations of the device behavior were carried out and a first formulation describing the placement of the RCC by varying the operating pressure was found. Finally, a comparison of the theoretical model and FEM results is presented, validating the proposed formulation.

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“…Robotics is a multidisciplinary research field, increasingly present in nowadays daily life. Robotics is modifying the classical design concepts, joining mechanics, electronics, and computer science knowledge, including life science considerations, resulting in the design of novel systems, which actively interact with the environment [1][2][3]. The design of such systems is innovative and includes many more aspects than classical systems design, e.g., variable stiffness actuators, soft robotics, dielectric elastomer actuators, artificial skins.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Balance of the Head in a Flexible Legged Robot for Efficient Biped Locomotion

et al. 2021

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In the biped robotics domain, head oscillations may be extremely harmful, especially if the robot is teleoperated, since vibrations strongly reduce the operator’s spatial awareness. In particular, undesired head oscillations occur in under-actuated robots, where springs and passive mechanisms are used to achieve a human-like motion. This paper proposes an approach to reduce the vibrations of a biped robot’s head; the proposed solution does not affect the dynamic locomotion properties, on which specific control logic could have been already tuned. The approach is tested on Rollo, a flexible-biped-wheeled robot, whose head vibrates throughout the robot locomotion. The two requirements, i.e., head vibration reduction and unchanged Rollo locomotion properties, are traduced in constraints to the robot possible modifications. Based on a 1D finite element model of the robot, tuned on experimental modal analysis, the undesired vibration causes are detected, and a solution for their reduction is proposed. Rollo’s head vibration amplitude is attenuated using a tuned vibration absorber, which achieves impressive performance in the robot. An archetype of the proposed vibration absorber is tailored designed on Rollo, without invasive changes to the robot structure. The proposed approach solves a significant problem in the biped robotic research community. The approach used to reduce the Rollo head oscillations may be utilized in other biped robot machines with or without flexible legs.

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SUAS: A Novel Soft Underwater Artificial Skin with Capacitive Transducers and Hyperelastic Membrane

Cited by 15 publications

References 38 publications

Soft Robotic Hands and Tactile Sensors for Underwater Robotics

Soft Robotic Hands and Tactile Sensors for Underwater Robotics

A New Soft RCC Device with Pneumatic Regulation

Dynamic Balance of the Head in a Flexible Legged Robot for Efficient Biped Locomotion

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