This paper presents a computational study of the effects of

fuel and thermal stratifications on homogenous charge

compression ignition (HCCI) combustion process in a

personal car sized internal combustion engine. Stratified

HCCI conditions are generated using a negative valve overlap

(NVO) technique. The aims of this study are to improve the

understanding of the flow dynamics, the heat and mass

transfer process and the onset of auto-ignition in stratified

charges under different internal EGR rate and NVO

conditions. The fuel is ethanol supplied through port-fuel

injection; the fuel/air mixture is assumed to be homogenous

before discharging to the cylinder. Large eddy simulation

(LES) is used to resolve in detailed level the flow structures,

and the mixing and heat transfer between the residual gas and

fresh fuel/air mixtures in the intake and compression strokes.

Multi-Zone model based on a detailed chemical kinetic

mechanism is then used to simulate the onset of auto-ignition

in the combustion stroke near TDC, based on the mixtures

predicted in LES. It is found that for low and moderate EGR

rates (low and moderate NVO) the onset of ignition is more

sensitive to the temperature of the mixture than to the fuel

concentration. For the high EGR rate and large NVO case,

there is a preferred mixture and temperature at which the first

ignition occurs. Under similar operating conditions the

moderate NVO and EGR rate case is found to have the

earliest ignition, whereas the longest combustion duration is

found in the lowest EGR rate and the lowest NVO case.