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Large-Eddy Simulation and Analysis of Turbulent Flows in a Motored Spark-Ignition Engine ANSYS Incorporated

SAE Technical Papers (1906-current) Available online

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Format:
Conference/Event
Author/Creator:
Patil, Patil, author.
Contributor:
Hussein, Ahmed
Liang, Long
Meeks, Ellen
Naik, Chitralkumar
Puduppakkam, Karthik
Wang, Yue
Conference Name:
WCX World Congress Experience (2018-04-10 : Detroit, Michigan, United States)
Language:
English
Physical Description:
1 online resource
Place of Publication:
Warrendale, PA SAE International 2018
Summary:
AbstractAdvanced research in Spark-ignition (SI) engines has been focused on dilute-combustion concepts. For example, exhaust-gas recirculation is used to lower both fuel consumption and pollutant emissions while maintaining or enhancing engine performance, durability and reliability. These advancements achieve higher engine efficiency but may deteriorate combustion stability. One symptom of instability is a large cycle-to-cycle variation (CCV) in the in-cylinder flow and combustion metrics. Large-eddy simulation (LES) is a computational fluid dynamics (CFD) method that may be used to quantify CCV through numerical prediction of the turbulent flow and combustion processes in the engine over many engine cycles.In this study, we focus on evaluating the capability of LES to predict the in-cylinder flows and gas exchange processes in a motored SI engine installed with a transparent combustion chamber (TCC), comparing with recently published data. Numerical simulations are performed using the commercial CFD software, ANSYS Forte, employing a classical Smagorinsky sub-grid-scale (SGS) model for the LES approach. Two important aspects of the model, namely the coefficient of sub-grid viscosity used in the Smagorinsky model, and the numerical scheme for discretizing the convection term in the momentum transport equation, are evaluated.Simulations are performed for 20 consecutive enginecyclesafter the simulation setup is validated by the predicted in-cylinder pressure, trapped mass, and temperature data. LES-predicted phase-averaged-mean and root-mean-square (RMS) velocity fields are compared with high-speed particle image velocimetry (PIV) data. The comparison and analysis are performed at two crank angles, representing intakeand compression strokes, and on two different planes for measurement in the engine combustion chamber. Aproperorthogonal decomposition (POD) technique is applied to quantify CCV in both the LES results and the PIV data, toprovide a quantitative assessment of the predictions fromLES. The flow field statistics predicted by the LES-Smagorinsky model match well with experimental results.Based on these simulation results, optimal practices for the use of Smagorinsky model with respect to the numerical schemes are summarized
Notes:
Vendor supplied data
Publisher Number:
2018-01-0202
Access Restriction:
Restricted for use by site license

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