An Improved Combined Framework of Force Measurement With Friction Model for Harmonic Gear

Abstract

To obtain accurate output torque of robot joint for torque control, a built-in torque sensor is designed in this paper. In order to enhance the performance of harmonic gear, it is urgent to deal with the key issues in terms of the errors of sensing and positioning, torque ripple interference. To handle these aforementioned key issues, four pairs of symmetrically distributed strain gauges are pasted on the bottom of the flexspline. Then, a precise positioning method based on laser marking is proposed to improve the positioning accuracy of the strain gauges. Moreover, Kalman filter is utilized to reduce torque ripple interference in the output signal of the strain gauges. Additionally, the designed device is evaluated by experimental tests which is conducted on prototype trial production. Synchronously, the relationship between the flexspline torque and the joint output torque is verified and the polynomial is used to represent the relationship of the measured torque for the built-in torque sensor and the standard torque sensor in the static and dynamic conditions. Finally, a friction model is presented and identified. Comprehensive comparative experiments is performed the performance of the build-in torque sensor in terms of estimation accuracy and control and it shows that the designed built-in torque sensor with friction compensation can be improved ten times in comparison with that of without friction compensation in terms of steady state mean error and mean value of measurement error. What is more, this designed build-in torque sensor holds tremendous potential for making the compact and light weight motion joint module, especially for cooperative robot and robotic supernumerary limb.