Abstract
The safety of human-robot interaction is an essential requirement for designing collaborative robotics. Thus, this paper aims to design a novel variable stiffness actuator (VSA) that can provide safer physical human-robot interaction for collaborative robotics. VSA follows the idea of modular design, mainly including a variable stiffness module and a drive module. The variable stiffness module transmits the motion from the drive module in a roundabout manner, making the modularization of VSA possible. As the key component of the variable stiffness module, a stiffness adjustment mechanism with a symmetrical structure is applied to change the positions of a pair of pivots in two levers linearly and simultaneously, which can eliminate the additional bending moment caused by the asymmetric structure. The design of the double-deck grooves in the lever allows the pivot to move freely in the groove, avoiding the geometric constraint between the parts. Consequently, the VSA stiffness can change from zero to infinity as the pivot moves from one end of the groove to the other. To facilitate building a manipulator in the future, an expandable electrical system with a distributed structure is also proposed. Stiffness calibration and control experiments are performed to evaluate the physical performance of the designed VSA. Experiment results show that the VSA stiffness is close to the theoretical design stiffness. Furthermore, the VSA with a proportional-derivative feedback plus feedforward controller exhibits a fast response for stiffness regulation and a good performance for position tracking.
Highlights
Traditional manipulators are mostly used in industrial production, working in a structured environment on a given trajectory to complete specific tasks
2) It can eliminate the additional bending moment caused by the asymmetric structure and improve the reliability and stability of the variable stiffness actuator (VSA)
The stiffness adjustment scheme based on the symmetrical variable pivot principle that can eliminate the additional bending moment caused by the asymmetric structure is proposed, and the characteristics of this symmetrical stiffness adjustment scheme are analyzed systematically
Summary
Traditional manipulators are mostly used in industrial production, working in a structured environment on a given trajectory to complete specific tasks. Rigid manipulators based on active compliance control still present stiffness [5] when suffering sudden impacts or handling contact transients due to the control delay, which can cause damage to itself or surrounding environments. To address these issues, the flexible actuator with inherent compliance has received substantial attention in recent years and has been widely applied in robotics [6,7,8]. In addition to the advantages of series elastic actuator, VSA can increase the adaptability of manipulators by actively adjusting its own stiffness to meet different task requirements for improving performances [19] and exhibits advantages in terms of energy efficiency [20,21,22]
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