Active combustion control : modeling, design and implementation

Continuous combustion systems common in propulsion and power generation applications are susceptible to thermoacoustic instability, which occurs under lean burn conditions close to the flammability where most emissions and efficiency benefits are achieved, and near stoichiometry where often high power density can be realized. This instability is undesirable because the accompanying large pressure and heat release rate oscillations lead to high levels of acoustic noise and vibration as well as structural damage. Active control is one approach using which such instabilities can be mitigated. Over the past five to ten years, it has been shown conclusively through several lab-scale studies that active control is highly successful in suppressing the pressure oscillations. This success has set the stage for transition of the technology from laboratories to large-scale applications in propulsion and power generation. This thesis provides some of the building blocks for enabling this transition. The first building block concerns the modeling of hydrodynamics and its interactions with the other components that contribute to combustion dynamics. The second is the impact of active control on emissions even while suppressing the pressure instability. The third is the evaluation of model-based active controllers in realistic combustors with configurations that include swirl, large convective delays and unknown changes in the operating conditions. The above three building blocks are investigated in the thesis experimentally in three different configurations. The first is a 2D backward facing step combustor, constructed at MIT, with the goal of investigating the flame-vortex interactions and the impact of active control on emissions. The second is a dump combustor, constructed at University of Maryland, so as to reproduce more realistic ramjet conditions. The third is an industrial swirl-stabilized combustor, constructed at University of Cambridge, to mimic realistic industrial gas combustor configurations which typically include large convective time delays, swirl, and on-line changes in the operating conditions. Results obtained from these three configurations show that through an understanding of the underlying physics and reduced-order modeling, one can design an appropriate actuation,

[1]  Robert W. Schefer,et al.  Hydrogen enrichment for improved lean flame stability , 2003 .

[2]  Domenic A. Santavicca,et al.  Measurement of equivalence ratio fluctuation and its effect on heat release during unstable combustion , 2000 .

[3]  Earl H. Dowell,et al.  System Identii Cation and Proper Orthogonal Decomposition Method Applied to Unsteady Aerodynamics , 2022 .

[4]  Katsunori Hanamura,et al.  A study of super-adiabatic combustion engine , 1997 .

[5]  Ann P. Dowling,et al.  PRACTICAL ACTIVE CONTROL-SYSTEM FOR COMBUSTION OSCILLATIONS , 1990 .

[6]  Yedidia Neumeier,et al.  A procedure for real-time mode decomposition, observation, and prediction for active control of combustion instabilities , 1997, Proceedings of the 1997 IEEE International Conference on Control Applications.

[7]  M. Mungal,et al.  Mixing, structure and scaling of the jet in crossflow , 1998, Journal of Fluid Mechanics.

[8]  L. Rayleigh,et al.  The theory of sound , 1894 .

[9]  Jeffrey M. Cohen,et al.  Experimental investigation of near-blowout instabilities in a lean, premixed step combustor , 1996 .

[10]  Brent Jerome Brunell A system identification approach to active control of thermoacoustic instabilities , 2000 .

[11]  Anuradha M. Annaswamy,et al.  A model-based self-tuning controller for kinetically controlled combustion instability , 2002, Proceedings of the 2002 American Control Conference (IEEE Cat. No.CH37301).

[12]  Kenneth J. Wilson,et al.  Multistep dump combustor design to reduce combustion instabilities , 1990 .

[13]  Bogusz Bienkiewicz,et al.  Application of autoregressive modeling in proper orthogonal decomposition of building wind pressure , 1997 .

[14]  Jeffrey M. Cohen,et al.  The effect of fuel/air mixing on actuation authority in an active combustion instability control system , 2001 .

[15]  A. Sinha,et al.  State-feedback control of longitudinal combustion instabilities , 1992 .

[16]  Kenneth J. Wilson,et al.  Scale-Up Experiments on Liquid-Fueled Active Combustion Control , 1998 .

[17]  Anuradha M. Annaswamy,et al.  Optimal control of a swirl-stabilized spray combustor using system identification approach , 2003 .

[18]  Jacob Brouwer,et al.  Active control for gas turbine combustors , 1991 .

[19]  E. Gutmark,et al.  Closed-loop control in a flame and a dump combustor , 1993, IEEE Control Systems.

[20]  Ø. Skreiberg,et al.  A comparison of low-NOx burners for combustion of methane and hydrogen mixtures , 2002 .

[21]  Habib N. Najm,et al.  Modeling Pulsating Combustion Due To Flow-Flame Interactions In Vortex-Stabilized Pre-mixed Flames , 1993 .

[22]  A. Annaswamy,et al.  Response of a laminar premixed flame to flow oscillations: A kinematic model and thermoacoustic instability results , 1996 .

[23]  Anuradha M. Annaswamy,et al.  Combustion Instability Active Control Using Periodic Fuel Injection , 2002 .

[24]  Andrzej Banaszuk,et al.  Adaptive control of combustion instability using extremum-seeking , 2000, Proceedings of the 2000 American Control Conference. ACC (IEEE Cat. No.00CH36334).

[25]  A. Annaswamy,et al.  Stability and emissions control using air injection and H2 addition in premixed combustion , 2005 .

[26]  J. Tuzson,et al.  Reducing Gas Turbine Emissions Through Hydrogen-Enhanced, Steam-Injected Combustion , 1996 .

[27]  Anuradha M. Annaswamy,et al.  Heat release dynamics modeling of kinetically controlled burning , 2002 .

[28]  George A. Richards,et al.  Thermal Pulse Combustion , 1993 .

[29]  A. Annaswamy,et al.  A Model-Based Active Control Design for Thermoacoustic Instability , 1998 .

[30]  Anuradha M. Annaswamy,et al.  Self-tuning regulators for combustion oscillations , 2003, Proceedings of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[31]  D. A. Santavicca,et al.  Mechanism of Combustion Instability in a Lean Premixed Dump Combustor , 1999 .

[32]  Tim Lieuwen,et al.  The Role of Unmixedness and Chemical Kinetics in Driving Combustion Instabilities in Lean Premixed Combustors , 1998 .

[33]  T. Tsotsis,et al.  Strain-rate effects on hydrogen-enhanced lean premixed combustion , 2001 .

[34]  S. Candel,et al.  Suppression of combustion instabilities by active control , 1987 .

[35]  Jeffrey M. Cohen,et al.  Active Control of Combustion Instability in a Liquid–Fueled Low–NOx Combustor , 1998 .

[36]  E. A. Gillies Low-dimensional control of the circular cylinder wake , 1998, Journal of Fluid Mechanics.

[37]  Anuradha M. Annaswamy,et al.  Thermoacoustic instability: model-based optimal control designs and experimental validation , 2000, IEEE Trans. Control. Syst. Technol..

[38]  Sungbae Park Modeling of combustion instability at different Damkohler conditions , 2001 .

[39]  Anuradha M. Annaswamy,et al.  Advanced Closed-Loop Control on an Atmospheric Gaseous Lean-Premixed Combustor , 2004 .

[40]  T. Lieuwen,et al.  A Mechanism of Combustion Instability in Lean Premixed Gas Turbine Combustors , 2001 .

[41]  Prashant G. Mehta,et al.  Fuel control of a ducted bluffbody flame , 2003, 42nd IEEE International Conference on Decision and Control (IEEE Cat. No.03CH37475).

[42]  E. Sachs,et al.  Trust-region proper orthogonal decomposition for flow control , 2000 .

[43]  Christian Oliver Paschereit,et al.  Role of Coherent Structures in Acoustic Combustion Control , 1998 .

[44]  M. Q. McQuay,et al.  An experimental study on the effect of pressure and strain rate on CH chemiluminescence of premixed fuel-lean methane/air flames , 2001 .

[45]  Christopher M. Boggs,et al.  Influence of H2 on the response of lean premixed CH4 flames to high strained flows , 2003 .