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1. Relative Effects of Velocity- and Mixture-Coupling in a Thermoacoustically Unstable, Partially-Premixed Flame

   Karmarkar, A.; Boxx, I.; O'Connor, J. (January 2021, ASME Turbo Expo)

   null (Ed.)

   Combustion instability, which is the result of a coupling between combustor acoustic modes and unsteady flame heat release rate, is a severely limiting factor in the operability and performance of modern gas turbine engines. This coupling can occur through different coupling pathways, such as flow field fluctuations or equivalence ratio fluctuations. In realistic combustor systems, there are complex hydrodynamic and thermo-chemical processes involved, which can lead to multiple coupling pathways. In order to understand and predict the mechanisms that govern the onset of combustion instability in real gas turbine engines, we consider the influences that each of these coupling pathways can have on the stability and dynamics of a partially-premixed, swirl-stabilized flame. In this study, we use a model gas turbine combustor with two concentric swirling nozzles of air, separated by a ring of fuel injectors, operating at an elevated pressure of 5 bar. The flow split between the two streams is systematically varied to observe the impact on the flow and flame dynamics. High-speed stereoscopic particle image velocimetry, OH planar laser-induced fluorescence, and acetone planar laser-induced fluorescence are used to obtain information about the velocity field, flame, and fuel-flow behavior, respectively. Depending on the flow conditions, a thermoacoustic oscillation mode or a hydrodynamic mode, identified as the precessing vortex core, is present. The focus of this study is to characterize the mixture coupling processes in this partially-premixed flame as well as the impact that the velocity oscillations have on mixture coupling. Our results show that, for this combustor system, changing the flow split between the two concentric nozzles can alter the dominant harmonic oscillation modes in the system, which can significantly impact the dispersion of fuel into air, thereby modulating the local equivalence ratio of the flame. This insight can be used to design instability control mechanisms in real gas turbine engines. 

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2. Relative Effects of Velocity- and Mixture-Coupling in a Thermoacoustically Unstable, Partially Premixed Flame

   https://doi.org/10.1115/1.4052262  

   Karmarkar, Ashwini; Boxx, Isaac; O'Connor, Jacqueline (January 2022, Journal of Engineering for Gas Turbines and Power)

   Abstract Combustion instability, which is the result of a coupling between combustor acoustic modes and unsteady flame heat release rate, is a severely limiting factor in the operability and performance of modern gas turbine engines. This coupling can occur through different pathways, such as flow-field fluctuations or equivalence ratio fluctuations. In realistic combustor systems, there are complex hydrodynamic and thermo-chemical processes involved, which can lead to multiple coupling pathways. In order to understand and predict the mechanisms that govern the onset of combustion instability in real gas turbine engines, we consider the influences that each of these coupling pathways can have on the stability and dynamics of a partially premixed, swirl-stabilized flame. In this study, we use a model gas turbine combustor with two concentric swirling nozzles of air, separated by a ring of fuel injectors, operating at an elevated pressure of 5 bar. The flow split between the two streams is systematically varied to observe the impact on the flow and flame dynamics. High-speed stereoscopic particle image velocimetry, OH planar laser-induced fluorescence, and acetone planar laser-induced fluorescence are used to obtain information about the velocity field, flame, and fuel-flow behavior, respectively. Depending on the flow conditions, a thermoacoustic oscillation mode or a hydrodynamic mode, identified as the precessing vortex core, is present. The focus of this study is to characterize the mixture coupling processes in this partially premixed flame as well as the impact that the velocity oscillations have on mixture coupling. Our results show that, for this combustor system, changing the flow split between the two concentric nozzles can alter the dominant harmonic oscillation modes in the system, which can significantly impact the dispersion of fuel into air, thereby modulating the local equivalence ratio of the flame. This insight can be used to design instability control mechanisms in real gas turbine engines. 

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3. The Effects of Exit Boundary Condition on Precessing Vortex Core Dynamics

   Mason, Danielle; Clees, Sean; Frederick, Mark; O'Connor, Jacqueline (June 2019, ASME Turbo Expo)

   Many industrial combustion systems, especially power generation gas turbines, use fuel-lean combustion to reduce NOx emissions. However, these systems are highly susceptible to combustion instability, the coupling between combustor acoustics and heat release rate oscillations of the flame. It has been shown in previous work by the authors that a precessing vortex core (PVC) can suppress shear layer receptivity to external perturbations, reducing the potential for thermoacoustic coupling. The goal of this study is to understand the effect of combustor exit boundary condition on the flow structure of a swirling jet to increase fundamental understanding of how combustor design impacts PVC dynamics. The swirling jet is generated with a radial-entry, variable-angle swirler, and a quartz cylinder is fixed on the dump plane for confinement. Combustor exit constriction plates of different diameters are used to determine the impact of exit boundary condition on the flow field. Particle image velocimetry (PIV) is used to capture the velocity field inside the combustor. Spectral proper orthogonal decomposition, a frequency-resolved eigenvalue decomposition that can identify energetic structures in the flow, is implemented to identify the PVC at each condition in both energy and frequency space. We find that exit boundary diameter affects both the structure of the flow and the dynamics of the PVC. Higher levels of constriction (smaller diameters) force the downstream stagnation point of the vortex breakdown bubble upstream, resulting in greater divergence of the swirling jet. Further, as the exit diameter decreases, the PVC becomes less energetic and less spatially defined. Despite these changes in the base flow and PVC coherence, the PVC frequency is not altered by the exit boundary constriction. These trends will help inform our understanding of the impact of boundary conditions on both static and dynamic flame stability. 

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4. Effect of centerbody temperature on blowoff limits of a swirl-stabilized flame.

   Clark, Caleb; Torres_Hernandez, Cristopher; Markle, Shayla; Colborn, Jennifer; O'Connor, Jacqueline (March 2024, Combustion Institute)

   Swirl-stabilized flames are used in many gas turbine combustor configurations due to their enhanced static stability. The effects of combustor geometry, fuel composition, and bulk velocity on flame stability in swirling flows are well studied, but the effects of centerbody temperature have not been rigorously considered. The purpose of this study is to understand the impact of centerbody temperature on flame shape and dynamics. A newly instrumented variable-angle swirl-stabilized combustor was used to perform a repeatability study, and blowoff equivalence ratio was measured at centerbody temperatures ranging from 150 to 350°C and bulk velocities ranging from 16 to 55 m/s. Blowoff equivalence ratio generally decreases with centerbody temperature. Two structures were observed during blowoff: a cone shape and flame chugging. Blowoff equivalence ratio was consistently lower when the cone structure occurred, though the mechanism that excites these behaviors is still under investigation. 

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5. Effect of Diluents on Flame Stability in Constant Flame Speed Mixtures for Piloted, Swirl-Stabilized Flames

   Rodriguez_Camacho, Javier; O'Connor, Jacqueline (March 2024, Combustion Institute)

   This study considers the effect of exhaust gas recirculation diluents on the static and dynamic stability of a swirl-stabilized flame in a model gas turbine combustor. The test matrix is designed such that the unstretched laminar flame speed of the mixture is maintained constant as the diluent level and composition is varied. Results show that the constant flame speed test matrices exhibit similar flame stability and shape. This can be attributed to the similar stretched flame properties that these conditions exhibit when the unstretched laminar flame speed is matched. 

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