A thickened stochastic fields approach for turbulent combustion simulation
A thickened stochastic fields approach for turbulent combustion simulation
The Stochastic Fields approach is an effective way to implement transported Probability Density Function modelling into Large Eddy Simulation of turbulent combustion. In premixed turbulent combustion however, thin flame-like structures arise in the solution of the Stochastic Fields equations that require grid spacing much finer than the filter scale used for the Large Eddy Simulation. The conventional approach of using grid spacing equal to the filter scale yields substantial numerical error, whereas using grid spacing much finer than the filter length scale is computationally-unaffordable for most industrially-relevant combustion systems. A Thickened Stochastic Fields approach is developed in this study in order to provide physically-accurate and numerically-converged solutions of the Stochastic Fields equations with reduced compute time. The Thickened Stochastic Fields formulation bridges between the conventional Stochastic Fields and conventional Thickened-Flame approaches depending on the numerical grid spacing utilised. One-dimensional Stochastic Fields simulations of freely-propagating turbulent premixed flames are used in order to obtain criteria for the thickening factor required, as a function of relevant physical and numerical parameters, and to obtain a model for an efficiency function that accounts for the loss of resolved flame surface area caused by applying the thickening transformation to the Stochastic Fields equations. The Thickened Stochastic Fields formulation is tested by performing LES of a laboratory premixed Bunsen flame. The results demonstrate that the Thickened Stochastic Fields method produces accurate predictions even when using a grid spacing equal to the filter scale. The present development therefore facilitates the accurate application of the Stochastic Fields approach to industrially-relevant combustion systems.
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Picciani, M.A.
f4318820-e11c-4345-af24-23806ce825b9
Richardson, E.S.
a8357516-e871-40d8-8a53-de7847aa2d08
Navarro-martinez, S.
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Picciani, M.A.
f4318820-e11c-4345-af24-23806ce825b9
Richardson, E.S.
a8357516-e871-40d8-8a53-de7847aa2d08
Navarro-martinez, S.
a182c0e6-61af-4064-a9d8-4c0881ef943b
Picciani, M.A., Richardson, E.S. and Navarro-martinez, S.
(2018)
A thickened stochastic fields approach for turbulent combustion simulation.
Flow Turbulence and Combustion, .
(doi:10.1007/s10494-018-9954-y).
Abstract
The Stochastic Fields approach is an effective way to implement transported Probability Density Function modelling into Large Eddy Simulation of turbulent combustion. In premixed turbulent combustion however, thin flame-like structures arise in the solution of the Stochastic Fields equations that require grid spacing much finer than the filter scale used for the Large Eddy Simulation. The conventional approach of using grid spacing equal to the filter scale yields substantial numerical error, whereas using grid spacing much finer than the filter length scale is computationally-unaffordable for most industrially-relevant combustion systems. A Thickened Stochastic Fields approach is developed in this study in order to provide physically-accurate and numerically-converged solutions of the Stochastic Fields equations with reduced compute time. The Thickened Stochastic Fields formulation bridges between the conventional Stochastic Fields and conventional Thickened-Flame approaches depending on the numerical grid spacing utilised. One-dimensional Stochastic Fields simulations of freely-propagating turbulent premixed flames are used in order to obtain criteria for the thickening factor required, as a function of relevant physical and numerical parameters, and to obtain a model for an efficiency function that accounts for the loss of resolved flame surface area caused by applying the thickening transformation to the Stochastic Fields equations. The Thickened Stochastic Fields formulation is tested by performing LES of a laboratory premixed Bunsen flame. The results demonstrate that the Thickened Stochastic Fields method produces accurate predictions even when using a grid spacing equal to the filter scale. The present development therefore facilitates the accurate application of the Stochastic Fields approach to industrially-relevant combustion systems.
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Picciani 2018 Article A Thickened Stochastic Fields Appr
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Accepted/In Press date: 15 June 2018
e-pub ahead of print date: 14 August 2018
Identifiers
Local EPrints ID: 425385
URI: http://eprints.soton.ac.uk/id/eprint/425385
ISSN: 1386-6184
PURE UUID: 3b57d048-ea9b-4a45-8373-8a3d97c3df2d
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Date deposited: 17 Oct 2018 16:30
Last modified: 16 Mar 2024 04:05
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Author:
M.A. Picciani
Author:
S. Navarro-martinez
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