Combustor Design Optimization Using Co-Kriging of Steady and Unsteady Turbulent Combustion

Abstract: In the gas turbine industry, computational fluid dynamics (CFD) simulations are often used to predict and visualize the complex reacting flow dynamics, combustion environment and emissions performance of a combustor at the design stage. Given the complexity involved in obtaining accurate flow predictions and due to the expensive nature of simulations, conventional techniques for CFD based combustor design optimization are often ruled out, primarily due to the limits on available computing resources and time. T… Show more

“…The test combustor modeled for this study is the one used by Keller et al [8] in an experimental study of mechanisms of instabilities in turbulent combustion and also used in [3] for developing combustor design strategies. It consists of an oblong rectangular cross-section to model the essential features of planar flow with a profiled backward-facing step designed to act as a flame holder.…”

“…1. 2D computational domain of the combustor with a flame-stabilizer step (All dimensions in mm) [3,8] The main parameters employed in the commercial CFD package ANSYS FLUENT 12.1 are detailed in Table 1. The solver used is pressure based and employs a second-order discretization scheme for space.…”

“…This is mainly to keep the overall computation cost lower [10] and within practical time frames. An investigation into spatial grid dependent accuracy of the CFD solution was carried out in [3] using five grid cell count refinements (mesh1: 11000, mesh2: 46000, mesh3: 190,000, mesh4: 420,000 and mesh5: 800,000) to evaluate a converged reactive solution. Eight processes were used in parallel on a cluster of Intel quad core processors with 2.8GHz clock rate.…”

“…Thus, the strategy employed during combustor design and development has a direct impact on the achievability of design targets within practical time limits. Due to the latest advances in computing power and higher accuracy CFD codes, high-fidelity combustion CFD is now becoming an important and regular part of a combustor design strategy [3]. Since a large number of high-fidelity CFD analyses are generally required during the combustor development phase, there is a need for a computationally efficient strategy where the search algorithm is not coupled directly to expensive CFD simulations.…”

“…Previous studies [3][4][5] based on this methodology acknowledged that Kriging model based combustor design strategies could yield acceptable designs within a manageable timeframe by reducing the total 2 Copyright © 2013 by ASME number of required high-fidelity CFD analyses. Yet, successful combustor design and optimization still largely depends on the total number of design variables, and objective and constraint functions involved.…”

Efficient Strategy for Low NOx Combustor Design in the Spatial Domain Using Multi-Fidelity Solutions

“…The test combustor modeled for this study is the one used by Keller et al [8] in an experimental study of mechanisms of instabilities in turbulent combustion and also used in [3] for developing combustor design strategies. It consists of an oblong rectangular cross-section to model the essential features of planar flow with a profiled backward-facing step designed to act as a flame holder.…”

“…1. 2D computational domain of the combustor with a flame-stabilizer step (All dimensions in mm) [3,8] The main parameters employed in the commercial CFD package ANSYS FLUENT 12.1 are detailed in Table 1. The solver used is pressure based and employs a second-order discretization scheme for space.…”

“…This is mainly to keep the overall computation cost lower [10] and within practical time frames. An investigation into spatial grid dependent accuracy of the CFD solution was carried out in [3] using five grid cell count refinements (mesh1: 11000, mesh2: 46000, mesh3: 190,000, mesh4: 420,000 and mesh5: 800,000) to evaluate a converged reactive solution. Eight processes were used in parallel on a cluster of Intel quad core processors with 2.8GHz clock rate.…”

“…Thus, the strategy employed during combustor design and development has a direct impact on the achievability of design targets within practical time limits. Due to the latest advances in computing power and higher accuracy CFD codes, high-fidelity combustion CFD is now becoming an important and regular part of a combustor design strategy [3]. Since a large number of high-fidelity CFD analyses are generally required during the combustor development phase, there is a need for a computationally efficient strategy where the search algorithm is not coupled directly to expensive CFD simulations.…”

“…Previous studies [3][4][5] based on this methodology acknowledged that Kriging model based combustor design strategies could yield acceptable designs within a manageable timeframe by reducing the total 2 Copyright © 2013 by ASME number of required high-fidelity CFD analyses. Yet, successful combustor design and optimization still largely depends on the total number of design variables, and objective and constraint functions involved.…”

Efficient Strategy for Low NOx Combustor Design in the Spatial Domain Using Multi-Fidelity Solutions

Uncertainty Management Using Sequential Parameter Optimization

Multi-fidelity information fusion based on prediction of kriging