Dynamic modeling of a sliding ring on an elastic rod with incremental potential formulation

TL;DR

This paper introduces a reduced-order, variational method for simulating the dynamic interaction of a sliding ring on an elastic rod, improving efficiency and realism in engineering and animation applications.

Contribution

It develops a novel barrier and frictional functional based on incremental potential theory, enabling accurate, implicit time-stepping simulation of ring-rod interactions with fewer discretization elements.

Findings

Validated against analytical solutions in simple cases

Successfully applied to complex engineering scenarios

Enhanced realism in visual effects and design optimization

Abstract

Mechanical interactions between rigid rings and flexible cables find broad application in both daily life (hanging clothes) and engineering systems (closing a tether-net). A reduced-order method for the dynamic analysis of sliding rings on a deformable one-dimensional (1D) rod-like object is proposed. In contrast to the conventional approach of discretizing joint rings into multiple nodes and edges for contact detection and numerical simulation, a single point is used to reduce the order of the model. To ensure that the sliding ring and flexible rod do not deviate from their desired positions, a new barrier function is formulated using the incremental potential theory. Subsequently, the interaction between tangent frictional forces is obtained through a delayed dissipative approach. The proposed barrier functional and the associated frictional functional are C2 continuous, hence the nonlinear elastodynamic system can be solved variationally by an implicit time-stepping scheme. The numerical framework is initially applied to simple examples where the analytical solutions are available for validation. Then, multiple complex practical engineering examples are considered to showcase the effectiveness of the proposed method. The simplified ring-to-rod interaction model has the capacity to enhance the realism of visual effects in image animations, while simultaneously facilitating the optimization of designs for space debris removal systems.