Nonlinear Dynamics Analysis of Electric Energy Regeneration Device Based on Vibration Energy Recovery

An electric energy regeneration device using two one-way clutches is proposed to extend the range of electric vehicles. Under the influence of nonlinear factors, the system will be unstable. To solve this problem, considering the time-varying meshing stiffness, meshing damping, backlash and transmission error, and the reserve clearance of the one-way clutch, a multiple-DOF nonlinear dynamic model is established. The Runge-Kutta method is used to calculate the nonlinear differential equation. The response chart, kinematic phase diagram, Poincare map, and bifurcation diagram are used to analyze the influence of excitation frequency, reserve clearance, and transmission error. The results show that as the meshing frequency changes, the system response changes from period-doubling bifurcation to chaotic motion. In addition, the influence law of parameters on the damping characteristics of the device is revealed.