Elastic Inflatable Actuators for Soft Robotic Applications

• Published in: Advanced materials (Weinheim) Vol. 29; no. 43
• Main Authors: Gorissen, Benjamin, Reynaerts, Dominiek, Konishi, Satoshi, Yoshida, Kazuhiro, Kim, Joon‐Wan, De Volder, Michael
• Format: Journal Article
• Language: English
• Published: Germany Wiley Subscription Services, Inc 01.11.2017
• Subjects: Actuators; anisotropic structures; Automation; Configuration management; Fluid dynamics; hydraulic actuators; Inflatable structures; Materials science; microactuators; PDMS molding; pneumatic actuators; Pressurized fluids; Prostheses; Robot control; Robotics; Robots; Soft robotics; Telesurgery; PDMS molding; actuators; pneumatic actuators; anisotropic structures; hydraulic actuators; soft robotics; microactuators
• ISSN: 0935-9648; 1521-4095; 1521-4095
• DOI: 10.1002/adma.201604977

The 20th century's robotic systems have been made from stiff materials, and much of the developments have pursued ever more accurate and dynamic robots, which thrive in industrial automation, and will probably continue to do so for decades to come. However, the 21st century's robotic legacy may very well become that of soft robots. This emerging domain is characterized by continuous soft structures that simultaneously fulfill the role of robotic link and actuator, where prime focus is on design and fabrication of robotic hardware instead of software control. These robots are anticipated to take a prominent role in delicate tasks where classic robots fail, such as in minimally invasive surgery, active prosthetics, and automation tasks involving delicate irregular objects. Central to the development of these robots is the fabrication of soft actuators. This article reviews a particularly attractive type of soft actuators that are driven by pressurized fluids. These actuators have recently gained traction on the one hand due to the technology push from better simulation tools and new manufacturing technologies, and on the other hand by a market pull from applications. This paper provides an overview of the different advanced soft actuator configurations, their design, fabrication, and applications. The 21st century's robotic legacy may very well become that of soft robots, which show remarkable features superior to those of conventional robots in tasks requiring delicate manipulation and a high degree of maneuverability. This review discusses a particular type of soft actuators—elastic inflatable actuators—which are driven by pressurized fluids and allow for straightforward integration in soft robotics.