Development of a two zone turbulence model and its application to the cycle-simulation

Sjerić, Momir; Kozarac, Darko; Tomić, Rudolf

doi:10.2298/tsci130103030s

Cited by 14 publications

(7 citation statements)

References 15 publications

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“…Schematic of a ECFM-3Z model computational cell (Colin and Benkenida, 2004). the turbulent kinetic energy of the unburned zone assuming the homogeneous and isotropic turbulent flow field (Ramos, 1989;Sjerić et al, 2014).…”

Section: Fractal Combustion Modelmentioning

confidence: 99%

“…Although the cycle-simulation results of turbulent kinetic energy depended on the initial conditions specified at the IVC (Intake Valve Closure), very good agreement of turbulent kinetic energy over different engine operating conditions was obtained (Sjerić et al, 2012). The extension of the developed single zone turbulence model into a two zone model during the combustion process is presented and described in (Sjerić et al, 2014). The research presented in this paper aims to eliminate the necessity for specifying the initial conditions of turbulence at IVC and to close the loop in the turbulence simulation model by extending the calculation to the gas exchange process.…”

Section: Introductionmentioning

confidence: 99%

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Cycle-simulation turbulence modelling of IC engines

Sjerić

Kozarac

Ormuž

2016

Int.J Automot. Technol.

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Numerical simulations of IC engines are of high interest for automotive engineers worldwide. The simulation models should be as fast as possible, low-computational effort and predictive tool. The correct prediction of turbulence level inside the combustion chamber of spark ignition engines is the most important factor influencing to the engine working cycle. This paper presents a development of the k-ε turbulence model applied to the commercial cycle-simulation software with the high emphasis on the intake part. The validation was performed on two engine geometries with the variation of engine speed and load comparing the cycle-simulation results of the turbulent kinetic energy and in-cylinder temperature with 3-D CFD results. In order to apply the cycle-simulation turbulence model for the simulation of entire engine map, the parameterization model of turbulence constants was proposed. The parameterized turbulence model was optimized using NLPQL optimization algorithm where the single set of turbulence model parameters for each engine was found. A good agreement of the turbulent kinetic energy during the expansion was achieved when the turbulence affects the flame front propagation and combustion rate as well.

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Section: Fractal Combustion Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Cycle-simulation turbulence modelling of IC engines

Sjerić

Kozarac

Ormuž

2016

Int.J Automot. Technol.

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“…Such approaches feature a good compromise between accuracy and computational effort [7]. They are not as fast as ANN based models [8] but can ensure acceptable fastrunning characteristics [9] and several levels of detail can be implemented for augmenting predictive capabilities [10,11]. Data recorded on optically accessible units can ensure a solid starting point for model development and validation, as they feature high spatial resolution [12,13].…”

Section: Introductionmentioning

confidence: 99%

Towards better correlation between optical and commercial spark ignition engines through quasi-dimensional modeling of cycle-to-cycle variability

2022

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Internal combustion engines are still the main choice when considering propulsion technology in the transport sector. Spark ignition (SI) units offer the advantage of good efficiency with simpler after-treatment systems. Lean operation is a promising strategy that would further improve efficiency, but requires mitigation of cycle-to-cycle variability (CCV). Within this context, and given the increasing trend of using simulation based evaluations during engine development, the current work investigated combustion in an optical SI engine through measurements and quasi-dimensional simulation. The possibility of visualizing in-cylinder processes provides unique insight, but also introduces complications with respect to commercial engines. For this reason, quasi-dimensional simulation was applied so as to better understand the factors that induce CCV. For the specific case of the investigated engine, cycle-to-cycle measured exhaust air-fuel ratio was found to be directly correlated to variations of engine output. Several routes of incorporating these effects into simulations were evaluated. Introducing a random component in the period of laminar-turbulent flame transition was found to ensure good grounds for simulating peak pressure variability. Indicated mean effective pressure (IMEP) on the other hand was found to depend less on the initial stages of combustion and was strongly correlated to aforementioned variability of exhaust air-fuel ratio.

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“…For the study specific modifications and extensions of the available fractal combustion model are made. For the modelling of in-cylinder turbulence a new turbulence model is implemented [26,27], while the combustion process is simulated by the modified fractal model that includes an ignition sub-model, a sub-model for transition from laminar to turbulent flame and a two zone turbulence sub-model. The early flame kernel growth is modelled by a newly [28] commonly used in 3D-CFD simulations.…”

Section: Introductionmentioning

confidence: 99%

“…In this study, the cyclic variability of combustion in SI engines is produced by a predefined perturbation of the turbulence intake production parameter, by a perturbation of the flow direction at the spark plug and by a perturbation of the stratification of air equivalence ratio from cycle-to-cycle, simulating the fluctuations of in-cylinder turbulence level, fluid motion and stratification of fuel, respectively. Since the combustion and turbulence models have already been described in previous publications [26,27], the description of the numerical model in this paper will be limited to the quasi-dimensional ignition model and to the methodology of inducing CCV in the simulations.…”

Section: Introductionmentioning

confidence: 99%