Tim Giffney scite author profile

Abstract:The excellent compliance and large range of motion of soft actuators controlled by fluid pressure has lead to strong interest in applying devices of this type for biomimetic and human-robot interaction applications. However, in contrast to soft actuators fabricated from stretchable silicone materials, conventional technologies for position sensing are typically rigid or bulky and are not ideal for integration into soft robotic devices. Therefore, in order to facilitate the use of soft pneumatic actuators in applications where position sensing or closed loop control is required, a soft pneumatic bending actuator with an integrated carbon nanotube position sensor has been developed. The integrated carbon nanotube position sensor presented in this work is flexible and well suited to measuring the large displacements frequently encountered in soft robotics. The sensor is produced by a simple soft lithography process during the fabrication of the soft pneumatic actuator, with a greater than 30% resistance change between the relaxed state and the maximum displacement position. It is anticipated that integrated resistive position sensors using a similar design will be useful in a wide range of soft robotic systems.

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The Development of Highly Flexible Stretch Sensors for a Robotic Hand

Devaraj

Giffney

Petit

et al. 2018

Robotics

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Demand for highly compliant mechanical sensors for use in the fields of robotics and wearable electronics has been constantly rising in recent times. Carbon based materials, and especially, carbon nanotubes, have been widely studied as a candidate piezoresistive sensing medium in these devices due to their favorable structural morphology. In this paper three different carbon based materials, namely carbon black, graphene nano-platelets, and multi-walled carbon nanotubes, were utilized as large stretch sensors capable of measuring stretches over 250%. These stretch sensors can be used in robotic hands/arms to determine the angular position of joints. Analysis was also carried out to understand the effect of the morphologies of the carbon particles on the electromechanical response of the sensors. Sensors with gauge factors ranging from one to 1.75 for strain up to 200% were obtained. Among these sensors, the stretch sensors with carbon black/silicone composite were found to have the highest gauge factor while demonstrating acceptable hysteresis in most robotic hand applications. The highly flexible stretch sensors demonstrated in this work show high levels of compliance and conformance making them ideal candidates as sensors for soft robotics.

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Design and modeling of a continuously variable piezoelectric RF MEMS switch

Giffney

et al. 2014

Microsyst Technol

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A new photopolymer extrusion 5-axis 3D printer

Asif

Lee

Lin-Yip

et al. 2018

Additive Manufacturing

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Polymer electronic composites that heal by solvent vapour

et al. 2016

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A bimorph pneumatic bending actuator by control of fiber braiding angle

Wang

McDaid

Biglari-Abhari

et al. 2017

Sensors and Actuators A: Physical

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Printing of CNT/silicone rubber for a wearable flexible stretch sensor

Kurian

Giffney

Lee

et al. 2016

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Tim Giffney

Highly stretchable printed strain sensors using multi-walled carbon nanotube/silicone rubber composites

Soft Pneumatic Bending Actuator with Integrated Carbon Nanotube Displacement Sensor

The Development of Highly Flexible Stretch Sensors for a Robotic Hand

Design and modeling of a continuously variable piezoelectric RF MEMS switch

A new photopolymer extrusion 5-axis 3D printer

Polymer electronic composites that heal by solvent vapour

A bimorph pneumatic bending actuator by control of fiber braiding angle

Printing of CNT/silicone rubber for a wearable flexible stretch sensor

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