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LES Combustion Modeling for Diesel Engine Simulations

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Title: LES Combustion Modeling for Diesel Engine Simulations


1
LES Combustion Modeling for Diesel Engine
Simulations
  • Bing Hu
  • Professor Christopher J. Rutland
  • Sponsors DOE, Caterpillar

2
Background
  • Motivation
  • Better predictive power LES is potentially
    capable of capturing highly transient effects and
    more flow structures
  • New analysis capability LES is more sensitive to
    initial and boundary conditions than RANS such
    that it is better suitable for studying cyclic
    variations and sensitivity to design parameters.
  • Primary components
  • Turbulence model a one-equation non-viscosity
    model called dynamic structure model for subgrid
    scale stresses
  • Scalar mixing models a dynamic structure model
    for subgrid scale scalar flux and a zero-equation
    model for scalar dissipation
  • Combustion model a flamelet time scale model

3
Large Eddy Simulations
  • Spatial filtering
  • Filtering of non-linear terms in Navier-Stokes
    equations results in subgrid scale terms needed
    to be modeling
  • Dynamical structure model
  • one equation model
  • k sub-grid turbulent kinetic energy
  • Cij dynamically determined tensor coefficient
  • Smagorinsky model
  • use eddy viscosity

4
Flamelet Time Scale Combustion Model
  • Overview
  • Flamelet mixture fraction approach each species
    is a function of mixture fraction and stretch
    rate , this functional dependence is solved
    using a 1-D flamelet code prior to the CFD
    computation
  • Use probability density function (PDF) to obtain
    mean values
  • Modification for slow chemistry using a time
    scale
  • Additional features
  • PDF of mixture fraction is constructed from its
    first and second moment which are solved from LES
    transport equations
  • LES sub-grid model for scalar dissipation helps
    to construct PDF of stretch rate

5
Jet Flame Tests (Sandia Jet Flames)
  • Sandia piloted flames are simulated to validate
    models
  • A coarse grid is used 15cm x 15cm x 60cm, about
    230,000 cells
  • Instantaneous temperature fields are presented
    below
  • Black curves represent stoichiometric mixture
    fraction
  • Reynolds number at fuel jet for flame D 22,400
  • Reynolds number at fuel jet for flame E 33,600

flame E Significant local extinctions result in
lower temperature
flame D A Relatively stable flame
6
Engine Test Case (Caterpillar Diesel Engine)
  • Cylinder bore X stroke (mm) 137.6 X 165.1
  • Displacement volume (L) 2.44
  • Compression ratio 15.1
  • Engine speed (rpm) 1600
  • Load
    75
  • START OF INJECTION -9 ATDC
  • Duration of injection (degree) 21

Mixture fraction
Mixture fraction variance
7
Summary and Future Work
  • A flamelet time scale combustion model was
    integrated with LES dynamical structure
    turbulence and scalar mixing models
  • Model results agreed well with experiments of jet
    flames and a diesel engine
  • More accurate spray models are to be integrated
    with LES turbulence and scalar mixing models
  • More precise initial and inflow conditions are to
    be generated for LES simulations
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