A microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation
Conventional grippers fall behind their human counterparts as they do not have integrated sensing capabilities. Piezoresistive and capacitive sensors are popular choices because of their design and sensitivity, but they cannot measure pressure and slip simultaneously. It is imperative to measure sli...
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sg-ntu-dr.10356-1569832022-04-29T02:49:28Z A microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation Accoto, Dino Donadio, Alessandro Yang, Sibo Ankit Mathews, Nripan School of Materials Science and Engineering School of Mechanical and Aerospace Engineering Robotics Research Centre Energy Research Institute @ NTU (ERI@N) Engineering::Mechanical engineering Slip Sensor Pressure Sensor Conventional grippers fall behind their human counterparts as they do not have integrated sensing capabilities. Piezoresistive and capacitive sensors are popular choices because of their design and sensitivity, but they cannot measure pressure and slip simultaneously. It is imperative to measure slip and pressure concurrently. We demonstrate a dual slip-pressure sensor based on a thermal approach. The sensor comprises two concentric microfabricated heaters maintained at constant temperature. An elastic dome, with embedded liquid metal droplets, is placed on top of concentric heaters. Heat transfer between sensor and the object in contact occurs through the elastic dome. This heat transfer causes changes in the power absorbed by the sensor to maintain its temperature and allows for measurement of pressure while identifying slip events. Liquid metal droplets contribute to enhanced thermal conductivity (0.37 W/m-K) and reduced specific heat (0.86 kJ/kg-K) of the polymer without compromising on mechanical properties (Young's modulus-0.5 MPa). For pressure monitoring, sensor measures change in power ratio against increase in applied force, demonstrating a highly linear performance, with a high sensitivity of 0.0356 N-1 (pressure only) and 0.0189 N-1 (slip with simultaneous pressure applied). The sensor discriminates between different contact types with a 96% accuracy. Response time of the sensor (60-75 ms) matches the measured response time in human skin. The sensor does not get affected by mechanical vibrations paving way for easy integration with robotic manipulators and prosthetics. Ministry of Education (MOE) Nanyang Technological University This work was supported by Nanyang Technological University with the NTU-SUG grant (9069) ‘‘Building blocks for next generation soft robots’’ and Ministry of Education (MOE) Tier 1 grant (MOE2018-T1-002-179). 2022-04-29T02:49:22Z 2022-04-29T02:49:22Z 2021 Journal Article Accoto, D., Donadio, A., Yang, S., Ankit & Mathews, N. (2021). A microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation. Soft Robotics. https://dx.doi.org/10.1089/soro.2020.0199 2169-5172 https://hdl.handle.net/10356/156983 10.1089/soro.2020.0199 34097537 en NTU-SUG grant (9069) MOE2018-T1-002-179 Soft Robotics © 2021 Mary Ann Liebert, Inc. All rights reserved. |
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Engineering::Mechanical engineering Slip Sensor Pressure Sensor Accoto, Dino Donadio, Alessandro Yang, Sibo Ankit Mathews, Nripan A microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation |
| description |
Conventional grippers fall behind their human counterparts as they do not have integrated sensing capabilities. Piezoresistive and capacitive sensors are popular choices because of their design and sensitivity, but they cannot measure pressure and slip simultaneously. It is imperative to measure slip and pressure concurrently. We demonstrate a dual slip-pressure sensor based on a thermal approach. The sensor comprises two concentric microfabricated heaters maintained at constant temperature. An elastic dome, with embedded liquid metal droplets, is placed on top of concentric heaters. Heat transfer between sensor and the object in contact occurs through the elastic dome. This heat transfer causes changes in the power absorbed by the sensor to maintain its temperature and allows for measurement of pressure while identifying slip events. Liquid metal droplets contribute to enhanced thermal conductivity (0.37 W/m-K) and reduced specific heat (0.86 kJ/kg-K) of the polymer without compromising on mechanical properties (Young's modulus-0.5 MPa). For pressure monitoring, sensor measures change in power ratio against increase in applied force, demonstrating a highly linear performance, with a high sensitivity of 0.0356 N-1 (pressure only) and 0.0189 N-1 (slip with simultaneous pressure applied). The sensor discriminates between different contact types with a 96% accuracy. Response time of the sensor (60-75 ms) matches the measured response time in human skin. The sensor does not get affected by mechanical vibrations paving way for easy integration with robotic manipulators and prosthetics. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Accoto, Dino Donadio, Alessandro Yang, Sibo Ankit Mathews, Nripan |
| format |
Article |
| author |
Accoto, Dino Donadio, Alessandro Yang, Sibo Ankit Mathews, Nripan |
| author_sort |
Accoto, Dino |
| title |
A microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation |
| title_short |
A microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation |
| title_full |
A microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation |
| title_fullStr |
A microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation |
| title_full_unstemmed |
A microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation |
| title_sort |
microfabricated dual slip-pressure sensor with compliant polymer-liquid metal nanocomposite for robotic manipulation |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/156983 |
| _version_ |
1734310194757763072 |