TY - JOUR
T1 - Towards self-healing actuators:a preliminary concept
AU - Terryn, Seppe
AU - Brancart, Joost
AU - Mathijssen, Glenn
AU - Verstraten, Tom
AU - Van Assche, Guy
AU - Vanderborght, Bram
PY - 2016/5/16
Y1 - 2016/5/16
N2 - Natural organisms have a unique property not yet available in robotics, i.e., a self-healing (SH) ability. This powerful biological healing function has inspired chemists to impart similar properties to synthetic materials to create “SH materials.” Recent developments in SH polymers led us to investigate the potential of using these materials in robotics. This paper presents an innovative approach of using SH polymers, based on the reversible Diels–Alder (DA) reaction, in a compliant actuator. Using DA polymers, a sacrificial SH mechanical fuse (SH-MF) is designed, developed, and validated by placing it in a cable-driven robotic system. The fuse is designed as weakest element and will sacrificially fail if a damaging overload occurs, protecting the compliant element and other components of the system. The experimental results showed that this SH-MF could be healed at a relatively low temperature, recovering the initial mechanical properties. This first working prototype indicates the feasibility to use SH materials in robotics. “SH robotics” will lead to more sustainable and lighter systems, and eventually to more efficient designs.
AB - Natural organisms have a unique property not yet available in robotics, i.e., a self-healing (SH) ability. This powerful biological healing function has inspired chemists to impart similar properties to synthetic materials to create “SH materials.” Recent developments in SH polymers led us to investigate the potential of using these materials in robotics. This paper presents an innovative approach of using SH polymers, based on the reversible Diels–Alder (DA) reaction, in a compliant actuator. Using DA polymers, a sacrificial SH mechanical fuse (SH-MF) is designed, developed, and validated by placing it in a cable-driven robotic system. The fuse is designed as weakest element and will sacrificially fail if a damaging overload occurs, protecting the compliant element and other components of the system. The experimental results showed that this SH-MF could be healed at a relatively low temperature, recovering the initial mechanical properties. This first working prototype indicates the feasibility to use SH materials in robotics. “SH robotics” will lead to more sustainable and lighter systems, and eventually to more efficient designs.
KW - Self-healing materials
KW - Diels-Alder polymers
KW - Compliant actuators
KW - Robotics
U2 - 10.1109/TRO.2016.2558201
DO - 10.1109/TRO.2016.2558201
M3 - Article
VL - 32
SP - 736
EP - 743
JO - IEEE Transactions on Robotics
JF - IEEE Transactions on Robotics
SN - 1552-3098
IS - 3
M1 - 1552-3098
ER -