Abstract
With the diversification of robots, modularization of robots has been attracting attention. In our previous study, we developed a robot that mimics the principle of human joint drive using a straight-fiber-type pneumatic rubber artificial muscle (“artificial muscle”) and a magnetorheological fluid brake (“MR brake”). The variable viscoelastic joints have been modularized. Therefore, this paper evaluates the basic characteristics of the developed Joint Module, characterizes the variable viscoelastic joint, and compares it with existing modules. As basic characteristics, we confirmed that the Joint Module has a variable viscoelastic element by experimentally verifying the joint angle, stiffness, viscosity, and tracking performance of the generated torque to the command value. As a characteristic evaluation, we verified the change in motion and response to external disturbances due to differences in driving methods through simulations and experiments and proved the strength of the variable viscoelastic joint against external disturbances, which is a characteristic of variable viscoelastic joints. Based on the results of the basic characterization and the characterization of the variable viscoelastic drive joint, we discussed what kind of device the Joint Module is suitable to be applied to and clarified the position of the variable viscoelastic joint as an actuator system.
Highlights
The time lag characteristics of artificial muscles were reduced by accumulating the potential in advance using the MR brake when using the instantaneous motion method
In the static loading experiment, we looked at how a Joint Module with an arbitrary crash
In the static loading experiment, we looked at how a Joint Module with an arbitrary angular command behaves when a static load is applied
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. A wide range of robots have been developed in recent years [1–3]. Robots are used in a variety of fields, including factory production lines, human power assistance, and human-to-human communication. In contrast, are not widely used in many fields due to their limited versatility and high cost. We believe that robot modularization is an effective way to enable robots to be used in a broader range of applications
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