Bifurcation analysis is conducted on experimental data obtained from a simple setup comprising of ducted, laminar premixed conical flames to investigate the features of nonlinear thermoacoustic oscillations. It is observed that as the bifurcation parameter is varied, the system undergoes series of bifurcations leading to characteristically different nonlinear oscillations. Through the application of nonlinear time series analysis on pressure and flame (CH* chemiluminescence ) intensity time traces, these oscillations are characterised as periodic, aperiodic or chaotic oscillations and subsequently the nature of the obtained bifurcations is explained based on dynamical systems theory. Nonlinear interaction between the flames and the acoustic modes of the duct is clearly reflected in the high speed flame images acquired simultaneously with pressure and flame intensity measurements. Copyright © 2011 by ASME.

R. I. Sujith

Department of Aerospace Engineering

Bifurcation analysis

BIFURCATION PARAMETER

CHAOTIC OSCILLATION

Experimental data

Experimental studies

FLAME IMAGES

FLAME INTENSITY

Laboratory scale

LAMINAR PREMIXED

Nonlinear interactions

Nonlinear oscillation

NONLINEAR TIME-SERIES ANALYSIS

THERMOACOUSTIC OSCILLATIONS

THERMOACOUSTIC SYSTEMS

TIME TRACE

combustion

Exhibitions

PLASMA OSCILLATIONS

Thermoacoustics

time series analysis

Turbines

Bifurcation (mathematics)

IIT Madras is a public technical and research university located in Chennai, Tamil Nadu. Founded in 1959, it is recognised as an Institute of National Importance.

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IIT Madras

Experimental Studies of Bifurcations Leading to Chaos in a Laboratory Scale Thermoacoustic System

Proceedings of the ASME Turbo Expo

This experimental study focuses on characterizing the nonlinear combustion dynamics prior to blowout in a partially premixed combustor with a swirl-stabilized burner. Experiments were performed by varying the global equivalence ratio from 0.92 to 0.33. The acquired time-series data of pressure fluctuations were analyzed using nonlinear time-series analysis. When the combustor was operated at an equivalence ratio of 0.92, broadband lowamplitude pressure oscillations called combustion noise were observed. As the equivalence ratio is decreased to 0.62, the oscillations change their characteristics from low-amplitude broadband oscillations to high-amplitude discrete tones, and the combustor undergoes limit-cycle oscillations. A sharp peak is observed in the amplitude spectra of the acoustic pressure oscillations at this stage. On reducing the equivalence ratio to 0.42 and lower, the periodic motion is interrupted by occasional irregular bursts and the system switches back and forth between the noisy (periodic) and quiet (aperiodic) zones. In the dynamical systems theory parlance, this irregular switching between periodic and aperiodic behaviors is termed intermittency. On reducing the equivalence ratio further, the system reaches blowout condition. Intermittency can be used as the signature prior to flame blowout. The dynamical patterns and inherent nonlinearity during the transition from chaotic behavior to intermittent burst oscillations prior to blowout are shown qualitatively by drawing phase portraits, return maps, and recurrence plots. © 2015 by Gireeshkumaran Thampi. Published by the American Institute of Aeronautics and Astronautics, Inc., with permission.

Journal of Propulsion and Power

Intermittent burst oscillations: Signature prior to flame blowout in a turbulent swirl-stabilized combustor

Nonlinear Dynamics and Chaos

Combustion Theory and Modelling

Nonlinear/chaotic behaviour in thermo-acoustic instability

Journal of Fluid Mechanics

A unified framework for nonlinear combustion instability analysis based on the flame describing function

14th AIAA/CEAS Aeroacoustics Conference (29th AIAA Aeroacoustics Conference)

Subcritical thermoacoustic instabilities in a premixed combustor

Combustion Instabilities In Gas Turbine Engines

Combustion Instabilities: Basic Concepts

Experimental studies of bifurcations leading to chaos in a laboratory scale thermoacoustic system