Soft Hybrid Wave Spring Actuators
Soft continuum manipulators, inspired by squid tentacles and elephant trunks, show promise in allowing robots to safely interact with complex environments. One ongoing problem for these manipulators is torsional stiffness, as continuum manipulators are naturally compliant and cannot actively resist torsional strain. A hybrid actuator that combines molded silicone actuators with 3D printed flexible wave springs is used to overcome this problem. It is shown that the inclusion of the 3D printed wave spring increases actuator torsional stiffness by up to a factor of 10. Further investigation of these structures is performed using both experimentation and simulation. Finally, this hybrid actuator design is used to create a nine‐degree‐of‐freedom soft continuum manipulator, which is used to perform a cantilevered pick‐and‐place task impossible for a traditional soft manipulator of similar size.
- Location
-
Deutsche Nationalbibliothek Frankfurt am Main
- Extent
-
Online-Ressource
- Language
-
Englisch
- Bibliographic citation
-
Soft Hybrid Wave Spring Actuators ; volume:2 ; number:1 ; year:2020 ; extent:8
Advanced intelligent systems ; 2, Heft 1 (2020) (gesamt 8)
- Creator
-
Skorina, Erik H.
Onal, Cagdas D.
- DOI
-
10.1002/aisy.201900097
- URN
-
urn:nbn:de:101:1-2022063007515115306298
- Rights
-
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
- Last update
-
15.08.2025, 7:27 AM CEST
Data provider
Deutsche Nationalbibliothek. If you have any questions about the object, please contact the data provider.
Associated
- Skorina, Erik H.
- Onal, Cagdas D.
Other Objects (12)
Spring toy-inspired soft robots with electrohydraulic actuators
Hybrid magnetorheological elastomers enable versatile soft actuators
Biodegradable Electrohydraulic Soft Actuators
Cellulose‐Based Soft Actuators
Untethered soft actuators for soft standalone robotics
Self-sustainable autonomous soft actuators
Bioinspired Structures for Soft Actuators
Flexible Actuators for Soft Robotics
Earthworm‐Inspired Multi‐Material, Adaptive Strain‐Limiting, Hybrid Actuators for Soft Robots
Design of a soft bionic elbow exoskeleton based on shape memory alloy spring actuators
3D nanofabricated soft microrobots with super-compliant picoforce springs as onboard sensors and actuators
Soft Actuators for Soft Robotic Applications: A Review
Spring toy-inspired soft robots with electrohydraulic actuators
Hybrid magnetorheological elastomers enable versatile soft actuators
Biodegradable Electrohydraulic Soft Actuators
Cellulose‐Based Soft Actuators
Untethered soft actuators for soft standalone robotics
Self-sustainable autonomous soft actuators
Bioinspired Structures for Soft Actuators
Flexible Actuators for Soft Robotics
Earthworm‐Inspired Multi‐Material, Adaptive Strain‐Limiting, Hybrid Actuators for Soft Robots
Design of a soft bionic elbow exoskeleton based on shape memory alloy spring actuators
3D nanofabricated soft microrobots with super-compliant picoforce springs as onboard sensors and actuators
Soft Actuators for Soft Robotic Applications: A Review
Spring toy-inspired soft robots with electrohydraulic actuators
Hybrid magnetorheological elastomers enable versatile soft actuators
Biodegradable Electrohydraulic Soft Actuators
Cellulose‐Based Soft Actuators
Untethered soft actuators for soft standalone robotics
Self-sustainable autonomous soft actuators
Bioinspired Structures for Soft Actuators
Flexible Actuators for Soft Robotics
Earthworm‐Inspired Multi‐Material, Adaptive Strain‐Limiting, Hybrid Actuators for Soft Robots
Design of a soft bionic elbow exoskeleton based on shape memory alloy spring actuators
3D nanofabricated soft microrobots with super-compliant picoforce springs as onboard sensors and actuators