Detailed Simulations of Stratified Ignition and Combustion Processes in a Spray-Guided Gasoline Engine using the SparkCIMM/G-Equation Modeling Framework

Recently, high-speed optical imaging data for a single operating point of a spray-guided gasoline engine has, along with the flamelet model and the G-equation theory, enabled the development of the new spark-ignition model SparkCIMM. Within its framework, detailed chemistry flamelet models capture t...

Full description

Saved in:
Bibliographic Details
Published in:SAE International Journal of Engines 2012, Vol.5 (2), p.141-161, Article 2012-01-0132
Main Authors: Dahms, Rainer N, Drake, Michael C, Grover, Ronald O, Solomon, Arun S, Fansler, Todd D
Format: Article
Language:English
Subjects:
Chemical mixtures
Combustion
Computational fluid dynamics
Engines
Enthalpy
Equivalence ratio
Extinguishing
Flame propagation
Flames
Gasoline engines
Ignition
Phase velocity
Simulation
Spark ignition
Species diffusion
Turbulence
Turbulence models
Turbulent flames
Citations: Items that this one cites
Items that cite this one
Online Access:Request full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Recently, high-speed optical imaging data for a single operating point of a spray-guided gasoline engine has, along with the flamelet model and the G-equation theory, enabled the development of the new spark-ignition model SparkCIMM. Within its framework, detailed chemistry flamelet models capture the experimental feature of multiple localized ignition events along the excessively stretched and restriking spark channel, as well as the observations of non-spherical highly corrugated early turbulent flame fronts. The developed flamelet models account for the substantial turbulent fluctuations in equivalence ratio and enthalpy present under spray-guided conditions. A non-unity Lewis number formulation captures the deficient species diffusion into the highly curved flame reaction zone. Previously, these diffusion processes were shown to have a significant effect on the early flame development in spray-guided engines due to, initially, locally rich and highly diluted low turbulent Damköhler number mixtures. Localized flame extinction phenomena are captured by corresponding flamelet criteria. In this paper, the theoretical-numerical SparkCIMM/G-equation framework is applied to three different spray-guided engine operating conditions. These conditions vary substantially in engine speed, load, EGR rate, and in injection and spark-ignition timings. Accurate wall temperatures, flow fields and mixture property conditions at ignition timing were obtained by multiple 3D detailed intake simulations. Swirl numbers, trapped masses, pressure traces before spark advance, and the integral heat release were aimed to be in agreement with experimental data. Spray model parameters were optimized by comparison to spray-rig experiments. Providing such a proper setup for each operating point, the simulation results show excellent agreement with local and cylinder-averaged experimental data. The simulation captures the effects of the operating-point-dependent varying mixture pathways of the spark channel and the propagating flame on ignition and combustion. Turbulent mixture property fluctuations in equivalence ratio, enthalpy, flame stretch, and scalar dissipation are successfully reproduced.
ISSN:1946-3936
1946-3944
1946-3944
DOI:10.4271/2012-01-0132