Examination of Initialization and Geometric Details on the Results of CFD Simulations of Diesel Engines

Computational fluid dynamic simulations using the AVL FIRE and KIVA 3V codes were performed to examine commonly accepted techniques and assumptions used when simulating direct injection diesel engines. Simulations of a steady-state impulse swirl meter validated the commonly used practice of evaluating the swirl ratio of diesel engines by integrating the valve flow and torque history over discrete valve lift values. The results indicate the simulations capture the complex interactions occurring in the ports, cylinder, and honeycomb cell impulse swirl meter. Geometric details of engines due to valve recesses in the cylinder head and piston cannot be reproduced axisymmetrically. The commonly adopted axisymmetric assumption for an engine with a centrally located injector was tested by comparing the swirl and emissions history for a noncombusting and a double injection low temperature combustion case with varying geometric fidelity. Consideration of the detailed engine geometry including valve recesses in the piston altered the swirl history such that the peak swirl ratio at TDC decreased by approximately 10% compared with the simplified no-recess geometry. An analog to the detailed geometry of the full 3D geometry was included in the axisymmetric geometry by including a groove in the cylinder head of the mesh. The corresponding emissions predictions of the combusting cases showed greater sensitivity to the altered swirl history as the air-fuel ratio was decreased.

[1]  J. Robert,et al.  CHEMKIN-II: A FORTRAN Chemical Kinetics Package for the Analysis of Gas-Phase Chemical Kinetics , 1989 .

[2]  Paul C. Miles,et al.  The effect of swirl ratio and fuel injection parameters on CO emission and fuel conversion efficiency for high-dilution, low-temperature combustion in an automotive diesel engine. , 2006 .

[3]  R. Reitz,et al.  Turbulence Modeling of Internal Combustion Engines Using RNG κ-ε Models , 1995 .

[4]  Rolf D. Reitz,et al.  An Improved Spray Model for Reducing Numerical Parameter Dependencies in Diesel Engine CFD Simulations , 2008 .

[5]  Rolf D. Reitz,et al.  MODELING SUBGRID-SCALE MIXING OF VAPOR IN DIESEL SPRAYS USING JET THEORY , 2010 .

[6]  R. Reitz,et al.  Development and Validation of a Reduced Reaction Mechanism for HCCI Engine Simulations , 2004 .

[7]  Paul C. Miles,et al.  The influence of swirl ratio on turbulent flow structure in a motored HSDI diesel engine : A combined experimental and numerical study , 2004 .

[8]  R. Reitz,et al.  MODELING SPRAY ATOMIZATION WITH THE KELVIN-HELMHOLTZ/RAYLEIGH-TAYLOR HYBRID MODEL , 1999 .

[9]  Russell P. Durrett,et al.  Multiple-Event Fuel Injection Investigations in a Highly-Dilute Diesel Low Temperature Combustion Regime , 2009 .

[10]  M. L. Monaghan,et al.  Air Motion and Its Effect on Diesel Performance and Emissions , 1981 .

[11]  Paul C. Miles,et al.  In-Cylinder PIV Measurements in an Optical Light-Duty Diesel at LTC Conditions. , 2008 .

[12]  B. Johansson,et al.  Comparison Between In-Cylinder PIV Measurements, CFD Simulations and Steady-Flow Impulse Torque Swirl Meter Measurements , 2003 .

[13]  Rolf D. Reitz,et al.  Examination of Initialization and Geometric Details on the Results of CFD Simulations of Diesel Engines , 2009 .

[14]  Rolf D. Reitz,et al.  The application of a multicomponent droplet vaporization model to gasoline direct injection engines , 2003 .

[15]  Rolf D. Reitz,et al.  Investigation of Mixing and Temperature Effects on HC/CO Emissions for Highly Dilute Low Temperature Combustion in a Light Duty Diesel Engine , 2007 .