Response Regimes in Equivalent Mechanical Model of Moderately Nonlinear Liquid Sloshing

TL;DR

This paper models non-stationary liquid sloshing in partially filled tanks using a reduced-order nonlinear system, predicting diverse response regimes that align with experimental and full-scale simulation results.

Contribution

It introduces a simplified nonlinear model of liquid sloshing that captures complex response regimes, linking it to nonlinear energy sink systems for analysis.

Findings

Multiple non-stationary response regimes predicted

Responses qualitatively match experimental and numerical data

Model offers a simplified yet effective approach to sloshing dynamics

Abstract

The paper considers non-stationary responses in reduced-order model of partially liquid-filled tank under external forcing. The model involves one common degree of freedom for the tank and the non-sloshing portion of the liquid, and the other one -- for the sloshing portion of the liquid. The coupling between these degrees of freedom is nonlinear, with the lowest-order potential dictated by symmetry considerations. Since the mass of the sloshing liquid in realistic conditions does not exceed 10% of the total mass of the system, the reduced-order model turns to be formally equivalent to well-studied oscillatory systems with nonlinear energy sinks (NES). Exploiting this analogy, and applying the methodology known from the studies of the systems with the NES, we predict a multitude of possible non-stationary responses in the considered model. These responses conform, at least on the qualitative level, to the responses observed in experimental sloshing settings, multi-modal theoretical models and full-scale numeric simulations.