The paper focuses on a preliminary study of an easy-to-customize capacitive soft sensor to measure forces that can enable soft robot features like sensitive skins or permits dexterous object manipulation thanks to the perception of the grasping force. The prototype has been realized overlapping five different layers choose among commercial and easy to find materials. The sensor is completely composed by customized or self-produced parts. The stack definition involves compatibility test to define the correct combination of layers and adhesives. An evaluation of the behavior has been performed applying weights in the range [20–5800] g finding a mean sensitivity of 0.143 pF/kg over an initial value C0 of 3.151 pF. The sensor prototype showed good performance in term of sensitivity and hysteresis in the defined application range. Dielectric viscoelastic phenomena and decreasing repeatability have been observed in the upper part of the measuring range. The sensor proposed shows promising characteristics encouraging future developments.
Preliminary Study of a Capacitive Force Sensor for Soft Robotic Applications / Bellitti, P.; Caporaso, T.; Grazioso, S.; Lanzotti, A.; Sardini, E.; Serpelloni, M.. - (2023), pp. 1247-1255. (Intervento presentato al convegno International Joint Conference on Mechanics, Design Engineering and Advanced Manufacturing, JCM 2022 tenutosi a ita nel 2022) [10.1007/978-3-031-15928-2_109].
Preliminary Study of a Capacitive Force Sensor for Soft Robotic Applications
Caporaso T.Secondo
;Grazioso S.;Lanzotti A.;
2023
Abstract
The paper focuses on a preliminary study of an easy-to-customize capacitive soft sensor to measure forces that can enable soft robot features like sensitive skins or permits dexterous object manipulation thanks to the perception of the grasping force. The prototype has been realized overlapping five different layers choose among commercial and easy to find materials. The sensor is completely composed by customized or self-produced parts. The stack definition involves compatibility test to define the correct combination of layers and adhesives. An evaluation of the behavior has been performed applying weights in the range [20–5800] g finding a mean sensitivity of 0.143 pF/kg over an initial value C0 of 3.151 pF. The sensor prototype showed good performance in term of sensitivity and hysteresis in the defined application range. Dielectric viscoelastic phenomena and decreasing repeatability have been observed in the upper part of the measuring range. The sensor proposed shows promising characteristics encouraging future developments.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
