Dynamics of a hybrid vibro-impact oscillator: canonical formalism

TL;DR

This paper models the complex nonlinear dynamics of hybrid vibro-impact oscillators using canonical formalism, providing analytical insights into bifurcations and energy transitions relevant for vibration mitigation in engineering systems.

Contribution

It introduces a canonical transformation approach to analyze the transient dynamics and bifurcations of HVI oscillators, a regime previously difficult to describe analytically.

Findings

Analytical expressions for transition boundaries and frequency response curves.

Identification of 'maximum' and 'saddle' bifurcation mechanisms.

Complete agreement between theoretical predictions and numerical simulations.

Abstract

Hybrid vibro-impact (HVI) oscillations is a strongly nonlinear dynamical regime that involves both linear oscillations and collisions under periodic, impulsive, or stochastic excitation. This regime arises in various engineering systems, such as mechanical components under tight rigid constraints, seismic-induced sloshing in partially-filled liquid storage tanks, and more. The adaptive nonlinearity of the HVI oscillator is used by the HVI-nonlinear energy sink as an effective vibration mitigation solution for broad energy and frequency range. Due to the extreme nonlinearity of this regime, traditional analytical methods are inapplicable for the description of its transient dynamics. In the current work, we model the HVI oscillator by a forced particle in a truncated quadratic potential well with infinite depth. The slow flow dynamics of the system in the vicinity of primary resonance is described by canonical transformation to action-angle (AA) variables and the corresponding reduced resonance manifold (RM). Two types of bifurcation are examined. The former is associated with the transition between linear oscillations and the HVI-regime and vice versa, and the latter with reaching a chosen maximal transient energy level. The transition boundaries and frequency response curves are obtained analytically. Two underlying dynamical mechanisms that govern the occurrence of bifurcations are identified: the "maximum" and the "saddle" mechanisms. The latter, a potentially more dangerous scenario, involves abrupt transitions of the system's energy response from a relatively small value to the threshold energy level. Both mechanisms are universal for systems that undergo escape from a potential well. All theoretical results are in complete agreement with full-scale numerical simulations.