An amplitude equation modeling the single-to-double crest wave transition in orbital shaken cylindrical containers

TL;DR

This paper develops an amplitude equation to model the transition from single to double crest waves in orbital shaken cylindrical containers, capturing super-harmonic effects observed experimentally.

Contribution

It introduces a novel weakly nonlinear amplitude equation for super-harmonic wave dynamics in orbital shaking, extending previous models to include double-crest transitions.

Findings

The amplitude equation accurately predicts the single-to-double crest transition.

The model aligns well with experimental observations in the literature.

Super-harmonic effects are significant in certain frequency ranges.

Abstract

The container motion along a planar circular trajectory at a constant angular velocity, i.e. orbital shaking, is of interest in several industrial applications, e.g. for fermentation processes or in cultivation of stem cells, where good mixing and efficient gas exchange are the main targets. Under these external forcing conditions, the free surface typically exhibits a primary steady state motion through a single-crest dynamics, whose wave amplitude, as a function of the external forcing parameters, shows a Duffing-like behaviour. However, previous experiments in lab-scale cylindrical containers have unveiled that, owing to the excitation of super-harmonics, diverse dynamics are observable in certain driving-frequency ranges. Among these super-harmonics, the double-crest dynamics is particularly relevant, as it displays a notably large amplitude response, that is strongly favored by the spatial structure of the external forcing. In the inviscid limit and with regards to circular cylindrical containers, we formalize here a weakly nonlinear analysis via multiple timescale method of the full hydrodynamic sloshing system, leading to an amplitude equation suitable to describe such a super-harmonic dynamics and the resulting single-to-double crest wave transition. The weakly nonlinear prediction is shown to be in fairly good agreement with previous experiments described in the literature. Lastly, we discuss how an analogous amplitude equation can be derived by solving asymptotically for the first super-harmonic of the forced Helmholtz-Duffing equation with small nonlinearities.