Shock-induced tipping in a thermoacoustic system

TL;DR

This paper experimentally demonstrates shock-induced tipping in a thermoacoustic Rijke tube, showing how sudden power shocks can cause the system to transition from quiescence to oscillation, with modeling linking the shock to heat transfer dynamics.

Contribution

First experimental demonstration of shock-induced tipping in a thermoacoustic system, with a modified model explaining the shock's effect on system stability.

Findings

Shock in power supply causes transition to oscillations.

System's tipping depends on shock magnitude and grid temperature.

Model links heat transfer shock to state transition.

Abstract

Tipping refers to the transition of a system from one state to another. In this study, we focus on shock-induced tipping, which occurs due to a sudden and large disturbance in a control parameter, which is referred to as the shock. This shock drives the system from one dynamical state to another. We present the first experimental demonstration of shock-induced tipping using a prototypical thermoacoustic system, the horizontal Rijke tube. In a thermoacoustic system, unsteady heat release and sound waves interact through positive feedback, leading to self-sustained, high-amplitude oscillations known as limit cycles. The system transitions from a quiescent state to a state of self-sustained oscillations when a shock is introduced in the power supplied to the heat source (an electrically heated grid). This shock is created by abruptly increasing the voltage supplied to the grid, which takes the system into a bistable region. To explain the underlying mechanism linking the shock in the supplied power to the observed tipping behaviour, we model the system by modifying the governing equations of the Rijke tube to incorporate the heat transfer properties of the grid. We demonstrate that the shock in the supplied power manifests as a shock in the grid temperature, causing the system to fall into the basin of attraction of an alternate stable state. The tipping event depends on the magnitude of the shock and the temperature of the grid. Understanding the mechanisms underlying shock-induced tipping is crucial for developing systems with improved safety and reliability.