Book contents
- Frontmatter
- Summary Contents
- Detailed Contents
- Introduction
- Overview of the Book
- 1 Overview and Basic Equations
- 2 Decomposition and Evolution of Disturbances
- 3 Hydrodynamic Flow Stability I: Introduction
- 4 Hydrodynamic Flow Stability II: Common Combustor Flow Fields
- 5 Acoustic Wave Propagation I – Basic Concepts
- 6 Acoustic Wave Propagation II – Heat Release, Complex Geometry, and Mean Flow Effects
- 7 Flame–Flow Interactions
- 8 Ignition
- 9 Internal Flame Processes
- 10 Flame Stabilization, Flashback, Flameholding, and Blowoff
- 11 Forced Response I – Flamelet Dynamics
- 12 Forced Response II – Heat Release Dynamics
- Index
- Solutions
- References
6 - Acoustic Wave Propagation II – Heat Release, Complex Geometry, and Mean Flow Effects
Published online by Cambridge University Press: 05 October 2012
Book contents
- Frontmatter
- Summary Contents
- Detailed Contents
- Introduction
- Overview of the Book
- 1 Overview and Basic Equations
- 2 Decomposition and Evolution of Disturbances
- 3 Hydrodynamic Flow Stability I: Introduction
- 4 Hydrodynamic Flow Stability II: Common Combustor Flow Fields
- 5 Acoustic Wave Propagation I – Basic Concepts
- 6 Acoustic Wave Propagation II – Heat Release, Complex Geometry, and Mean Flow Effects
- 7 Flame–Flow Interactions
- 8 Ignition
- 9 Internal Flame Processes
- 10 Flame Stabilization, Flashback, Flameholding, and Blowoff
- 11 Forced Response I – Flamelet Dynamics
- 12 Forced Response II – Heat Release Dynamics
- Index
- Solutions
- References
Summary
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- Unsteady Combustor Physics , pp. 154 - 198Publisher: Cambridge University PressPrint publication year: 2012
References
A family of exact transient solutions for acoustic wave propagation in inhomogeneous, non-uniform area ductsJournal of Sound and Vibration 2001 240 705CrossRefGoogle Scholar
Effect of flow on the acoustic resonances of an open-ended ductThe Journal of the Acoustical Society of America 1975 58 788CrossRefGoogle Scholar
Damping and reflection coefficient measurements for an open pipe at low Mach and low Helmholtz numbersJournal of Fluid Mechanics 1993 256 499CrossRefGoogle Scholar
Exact solution for one-dimensional acoustic fields in ducts with polynomial mean temperature profilesJournal of Vibration and Acoustics 1998 120 965CrossRefGoogle Scholar
Ducts with axial temperature gradients: An approximate solution for sound transmission and generationJournal of Sound and Vibration 1977 51 55CrossRefGoogle Scholar
Sound generation and transmission in flow ducts with axial temperature gradientsJournal of Sound and Vibration 1978 57 261CrossRefGoogle Scholar
An exact solution for one-dimensional acoustic fields in ducts with an axial temperature gradientJournal of Sound and Vibration 1995 184 389CrossRefGoogle Scholar
Acoustic disturbance from gas non-uniformities convected through a nozzleJournal of Sound and Vibration 1977 55 225CrossRefGoogle Scholar
The generation of sound by density inhomogeneities in low Mach number nozzle flowsJournal of Fluid Mechanics 1975 605CrossRefGoogle Scholar
Phase prediction of the response of choked nozzles to entropy and acoustic disturbancesJournal of Sound and Vibration 2011 330 5184CrossRefGoogle Scholar
Fundamental mechanism of entropy noise in aero-engines: Experimental investigationJournal of Engineering for Gas Turbines and Power 2008 130CrossRefGoogle Scholar
Sound absorption caused by vorticity shedding, demonstrated with a jet flowJournal of Sound and Vibration 1980 70 389CrossRefGoogle Scholar
Sound absorption by a screen with a regular array of slitsJournal of Sound and Vibration 1992 156 387CrossRefGoogle Scholar
A theoretical study of non-linear damping by Helmholtz resonatorsJournal of Sound and Vibration 1970 13 347CrossRefGoogle Scholar
An experimental and theoretical investigation of a fuel system tuner for the suppression of combustion driven oscillations 2010 Georgia Institute of TechnologyGoogle Scholar
The acoustic impedance of a circular orifice in grazing mean flow: Comparison with theoryAcoustical Society of America Journal 2003 114 3076CrossRefGoogle ScholarPubMed
Wall shear stress caused by small amplitude perturbations of turbulent boundary-layer flow: an experimental investigationJournal of Fluid Mechanics 1977 83 433CrossRefGoogle Scholar
Analysis of acoustic wave interactions with turbulent premixed flamesProceedings of the Combustion Institute 2002 29 1817CrossRefGoogle Scholar
Theory of high frequency acoustic wave scattering by turbulent flamesCombustion and Flame 2001 126 11489CrossRefGoogle Scholar
Combustion roar of seven industrial burnersJournal of the Institute of Fuel 1976 49 135Google Scholar
Modeling and control of combustion dynamics in industrial gas turbinesASME Turbo Expo 2004: Power for Land, Sea, and Air 2004 ViennaASMEGoogle Scholar
Swirl control of combustion instabilities in a gas turbine combustorProceedings of the Combustion Institute 2002 29 155CrossRefGoogle Scholar
Large-eddy simulations of combustion instability in an axisymmetric ramjet combustorCombustion Science and Technology 1991 75 153CrossRefGoogle Scholar
One-dimensional analysis of liquid-fueled combustion instabilityJournal of Propulsion and Power 1991 7 953CrossRefGoogle Scholar
Thermoacoustic sources and instabilitiesModern Methods in Analytical Acoustics: Lecture Notes 1992 SpringerGoogle Scholar
Application of multipole expansions to sound generation from ducted unsteady combustion processesJournal of Sound and Vibration 2000 235 405CrossRefGoogle Scholar
Heat release timing in a nonpremixed Helmholtz pulse combustorCombustion and Flame 1995 100 1251CrossRefGoogle Scholar
Secondary fuel injection control of combustion instability in a ramjetCombustion Science and Technology 1994 100 1385Google Scholar
A review of active control of combustion instabilitiesProgress in Energy and Combustion Science 1993 19 1CrossRefGoogle Scholar
Combustion Instabilities in Gas Turbine Engines, Operational Experience, Fundamental Mechanisms, and ModelingProgress in Astronautics and Aeronautics 210 2005Google Scholar
Combustion instabilities coupled by pressure waves and their active controlTwenty-Fourth Symposium (International) on Combustion 1992 1277CrossRefGoogle Scholar
Sub-scale demonstration of the active feedback control of gas-turbine combustion instabilitiesJournal of Engineering for Gas Turbines and Power 2000 122 262CrossRefGoogle Scholar
2005 113
2005 1
Prediction of combustion dynamics in a staged premixed combustorASME Turbo Expo 2002: Power for Land, Sea, and Air 2002 AmsterdamASMEGoogle Scholar
Experimental investigation of limit-cycle oscillations in an unstable gas turbine combustorJournal of Propulsion and Power 2002 18 61CrossRefGoogle Scholar
Prediction of the stability of nonsteady motions in solidpropellant rocket motorsNonsteady Burning and Combustion Stability of Solid-Propellant 1992 143 719Google Scholar
Nonlinear behavior of acoustic waves in combustion chambersActa Astronautica 1976 3 9715Google Scholar
Triggering of longitudinal pressure oscillations in combustion chambers. I, Nonlinear gas dynamicsCombustion Science and Technology 1990 72 4183CrossRefGoogle Scholar
Nonlinear combustion instability in liquid-propellant rocket enginesProceedings of the 13th Symposium (International) on Combustion 1971 The Combustion InstituteGoogle Scholar
Application of a generalized instability model to a longitudinal mode combustion instability43rd AIAA/EMΣA/SAE/ASEE Joint Propulsion Conference & Exhibit 2007 Cincinnati, OHGoogle Scholar
Prediction of thermoacoustic limit cycles during premixed combustion using the modified Galerkin approach46th AIAA/EMΣA/SAE/ASEE Joint Propulsion Conference & Exhibit 2010 Nashville, TNGoogle Scholar
On the existence and stability of limit cycles. for longitudinal acoustic modes in a combustion chamberCombustion Science and Technology 1986 46 195CrossRefGoogle Scholar
The two-mode approximation to nonlinear acoustics in combustion chambers I. Exact solution for second order acousticsCombustion Science and Technology 1989 65 39CrossRefGoogle Scholar
Nonlinear longitudinal instability in rocket motors with concentrated combustionCombustion Science and Technology 1969 1 35CrossRefGoogle Scholar
Nonlinear combustion instability in liquid- propellant rocket enginesProceedings of the Combustion Institute 1970 13Google Scholar
Pulsed instabilities in solid-propellant rocketsJournal of Propulsion and Power 1995 11 657CrossRefGoogle Scholar
Non-linear growth and limiting amplitude of acoustic oscillations in combustion chambersCombustion Science and Technology 1971 3 1CrossRefGoogle Scholar
A theoretical study of nonlinear transverse combustion instability in liquid propellant rocket motors 1966 PhD thesisPrinceton UniversityGoogle Scholar
A theoretical study of nonlinear combustion instability in liquid-propellant rocket enginesAIAA Journal 1968 6 1966CrossRefGoogle Scholar
Nonlinear behavior of acoustic waves in combustion chambers–IIActa Astronautica 1976 3 735CrossRefGoogle Scholar
Nonlinear combustion instabilities in combustion chambers 1989 PhD ThesisPennsylvania State University, University ParkGoogle Scholar
On the existence and stability of limit cycles for transverse acoustic oscillations in a cylindrical combustion chamber. 1: Standing modesCombustion Science and Technology 1990 72 37CrossRefGoogle Scholar
Bifurcation of self-excited ducted laminar premixed flames. Paper # GT2011–46149ASME Journal of Gas Turbines and PowerASME Turbo Expo 2011Google Scholar
On the energy transfer between transverse acoustic modes in a cylindrical combustion chamberCombustion Science and Technology 1999 144 1CrossRefGoogle Scholar
Measurements of macrosonic standing waves in oscillating closed cavitiesThe Journal of the Acoustical Society of America 1998 104 623CrossRefGoogle Scholar
Periodic finite-amplitude oscillations in slowly converging nozzlesActa Astronautica 1968 13 481Google Scholar
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