Pseudo-bistability of viscoelastic shells

Viscoelastic shells subjected to a pressure loading exhibit rich and complex time-dependent responses. Here we focus on the phenomenon of pseudo-bistability, i.e. a viscoelastic shell can stay inverted when pressure is removed, and snap to its natural shape after a delay time. We model and explain the mechanism of pseudo-bistability with a viscoelastic shell model. It combines the small strain, moderate rotation shell theory with the standard linear solid as the viscoelastic constitutive law, and is applicable to shells with arbitrary axisymmetric shapes. As a case study, we investigate the pseudo-bistable behaviour of viscoelastic ellipsoidal shells. Using the proposed model, we successfully predict buckling of a viscoelastic ellipsoidal shell into its inverted configuration when subjected to an instantaneous pressure, creeping when the pressure is held, staying inverted after the pressure is removed, and eventually snapping back after a delay time. The stability transition of the shell from a monostable, temporarily bistable and eventually back to the monostable state is captured by examining the evolution of the instantaneous pressure-volume change relation at different time of the holding and releasing process. A systematic parametric study is conducted to investigate the effect of geometry, viscoelastic properties and loading history on the pseudo-bistable behaviour.This article is part of the theme issue 'Probing and dynamics of shock sensitive shells'.

Automated summary

Viscoelastic shells under pressure loading can exhibit pseudo-bistability, where they stay inverted after pressure removal and snap back to their natural shape after a delay time. We have developed a viscoelastic shell model that combines small strain, moderate rotation shell theory with a standard linear solid constitutive law, and is applicable to shells with arbitrary axisymmetric shapes. Using this model, we successfully predict the pseudo-bistable behavior of viscoelastic ellipsoidal shells and study the effect of geometry, viscoelastic properties, and loading history.