%0 Journal Article %1 hergart1999modeling %A Hergart, Christian %A Peters, Norbert %D 1999 %J SAE Technical Paper %K nrev %T Modeling the Combustion in a Small-Bore Diesel Engine Using a Method Based on Representative Interactive Flamelets %V 1999-01-3550 %X A model based on Representative Interactive Flamelets (RIF) for simulating ignition, combustion and emissions formation in a DI diesel engine has been applied to describe the combustion process in the Ford DIATA engine. Equipped with a common-rail injection system the four-valve, turbocharged engine with a displacement of 300 cc per cylinder represents a modern HSDI small-bore diesel engine. The RIF-model offers a way of decoupling the turbulent time scales from those associated with the chemistry. The turbulent flow field was solved using the three-dimensional CFD-code KIVA 3V and the chemistry was solved in a one-dimensional flamelet code rendering profiles of species mass fractions as a function of the mixture fraction, which is a conserved scalar. This decoupling enabled a detailed reaction mechanism comprising 118 species and 557 elementary reactions to be employed without imposing a significant penalty on the computational time. Model predictions of crank angle resolved in-cylinder pressure and NOx emissions are compared with experimental data taken from a single-cylinder test engine varying injection timing and EGR. The agreement between simulations and experiments is found to be very good.

@article{hergart1999modeling, abstract = {A model based on Representative Interactive Flamelets (RIF) for simulating ignition, combustion and emissions formation in a DI diesel engine has been applied to describe the combustion process in the Ford DIATA engine. Equipped with a common-rail injection system the four-valve, turbocharged engine with a displacement of 300 cc per cylinder represents a modern HSDI small-bore diesel engine. The RIF-model offers a way of decoupling the turbulent time scales from those associated with the chemistry. The turbulent flow field was solved using the three-dimensional CFD-code KIVA 3V and the chemistry was solved in a one-dimensional flamelet code rendering profiles of species mass fractions as a function of the mixture fraction, which is a conserved scalar. This decoupling enabled a detailed reaction mechanism comprising 118 species and 557 elementary reactions to be employed without imposing a significant penalty on the computational time. Model predictions of crank angle resolved in-cylinder pressure and NOx emissions are compared with experimental data taken from a single-cylinder test engine varying injection timing and EGR. The agreement between simulations and experiments is found to be very good. }, added-at = {2013-03-21T15:13:41.000+0100}, author = {Hergart, Christian and Peters, Norbert}, biburl = {https://www.bibsonomy.org/bibtex/2417d1e640f1ac34b900c6aef90bfb1cf/itv}, interhash = {35aa6157049e8b586df5505e3734c2b0}, intrahash = {417d1e640f1ac34b900c6aef90bfb1cf}, journal = {SAE Technical Paper}, keywords = {nrev}, timestamp = {2014-07-31T07:46:38.000+0200}, title = {Modeling the Combustion in a Small-Bore Diesel Engine Using a Method Based on Representative Interactive Flamelets}, volume = {1999-01-3550}, year = 1999 }