B. Sundaram scite author profile

Highlights• Stochastic MMC-LES and MMC-RANS are implemented into OpenFOAM.• Code architecture is based on layered template classes and abstract submodels.• Mass consistency of the hybrid Eulerian and Lagrangian schemes is demonstrated.• Numerical convergence with increasing stochastic particles is demonstrated.• Numerical convergence with increasing aerosol species sections is demonstrated. AbstractComputational models for combustion must account for complex and inherently interconnected physical processes including dispersion, mixing, chemical reactions, particulate nucleation and growth and, critically, the interactions of these with turbulence. The development of affordable and accurate models that are widely applicable is a work in progress. Stochastic multiple mapping conditioning (MMC) is a fast-emerging approach that has been successfully applied to non-premixed, premixed and partially premixed flames as well to the modelling of liquid and solid particulate synthesis. The method solves the conventional PDF transport equation but incorporates an additional constraint in that the mixing is localised in a reference space. This paper describes the numerical implementation of stochastic MMC in an OpenFOAM compatible code called mmcFoam. The model concepts and equations along with alternative submodels, code structure and numerical schemes are explained. A focus is placed on validation of the computational methods in particular demonstrating numerical convergence and mass consistency of the hybrid Eulerian/Lagrangian A C C E P T E D M A N U S C R I P T schemes. Four validation cases are selected including a combustion direct numerical simulation (DNS) case, two combustion experimental jet flame cases and a non-combusting particulate synthesis case. The results show that the total mass and mass distribution of Eulerian and Lagrangian schemes are consistent and confirm that the solutions numerically converge with increasing number of stochastic computational particles and sections for describing particulate size distribution.

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Prediction of NO in premixed high-pressure lean methane flames with a MMC-partially stirred reactor

Sundaram

Klimenko

Cleary

et al. 2015

Proceedings of the Combustion Institute

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A direct approach to generalised multiple mapping conditioning for selected turbulent diffusion flame cases

Sundaram

Klimenko

Cleary

et al. 2016

Combustion Theory and Modelling

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A PDF approach to thin premixed flamelets using multiple mapping conditioning

Sundaram

Klimenko

2017

Proceedings of the Combustion Institute

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Awareness without Neural Networks: Achieving Self-Aware AI via Evolutionary and Adversarial Processes

Greenwood¹,

Sundaram²,

Muirhead³

et al. 2020

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B. Sundaram

A stochastic multiple mapping conditioning computational model in OpenFOAM for turbulent combustion

Prediction of NO in premixed high-pressure lean methane flames with a MMC-partially stirred reactor

A direct approach to generalised multiple mapping conditioning for selected turbulent diffusion flame cases

A PDF approach to thin premixed flamelets using multiple mapping conditioning

Awareness without Neural Networks: Achieving Self-Aware AI via Evolutionary and Adversarial Processes

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