Global Dynamics of a Vibro-Impact Energy Harvester

In this paper, we consider a two-sided vibro-impact energy harvester described as a forced cylindrical capsule inclined at a horizontal angle, and the motion of the ball inside the capsule follows from the impacts with the capsule ends and gravity. Two distinct cases of dynamical behavior are investigated: the nondissipative and dissipative cases, where the dissipation is given by a restitution coefficient of impacts. We show that the dynamics of the system are described by the use of a 2D implicit map written in terms of the variables' energy and time when the ball leaves the moving capsule ends. More precisely, in the nondissipative case, we analytically show that this map is area-preserving and the existence of invariant curves for some rotation number with Markoff constant type is proved according to Moser's twist theorem in high energy. The existence of invariant curves implies that the kinetic energy of the ball is always bounded, and hence, the structure of system is not destroyed by the impacts of the ball. Furthermore, by numerical analysis we also show that the dynamical behavior of this system is regular, mainly containing periodic points, invariant curves and Aubry-Mather sets. After introducing dissipation, the dissipation destroys the regular dynamical behavior of the nondissipative case, and a periodic point with low energy is generated.

Automated summary

This paper investigates a two-sided vibro-impact energy harvester described as a forced cylindrical capsule inclined at a horizontal angle. Two cases of dynamical behavior are considered: nondissipative and dissipative cases. It is found that the dynamics of the system can be described using a 2D implicit map, and the existence of invariant curves and bounded kinetic energy are proven in the nondissipative case. By introducing dissipation, the regular dynamical behavior is destroyed and a periodic point with low energy is generated.