Design and Control of a Series-Parallel Elastic Actuator for a Weight-Bearing Exoskeleton Robot

Weight-bearing exoskeletons are robots that need to carry loads and interact with humans frequently. Therefore, the actuators of these exoskeletons are supposed to be capable of outputting sufficient force with high compliance and little weight. A series-parallel elastic actuator (SPEA) is designed, in this work, to meet the demanding requirements of an exoskeleton robot called PALExo. A gas spring is installed in parallel with an electric cylinder to adjust the force output range of the actuator according to the needs of the exoskeleton. A series elastic module (SEM) is installed in series with the electric cylinder and gas spring to improve the compliance of the actuator, the stiffness of which is variable to adapt to the different stiffness requirements of the exoskeleton's legs in the standing phase and swinging phase. A force controller combining dynamic compensation and a cascade control with an inner velocity loop and a disturbance observer is designed for the SPEA. The performance of the force controller is verified by experiments and the results demonstrate that the controller has good adaptability to the stiffness of the SEM.

Automated summary

In this work, a series-parallel elastic actuator (SPEA) is designed to meet the demanding requirements of a weight-bearing exoskeleton robot called PALExo. The actuator consists of an electric cylinder, gas spring, and series elastic module (SEM) to provide sufficient force output with high compliance and adaptability to different stiffness requirements. The performance of the force controller is verified by experiments, demonstrating good adaptability to varying SEM stiffness.