The homogeneous charge, compression ignition (HCCI) engine has advantages in terms of efficiency and reduced emissions in comparison to conventional internal combustion engines. One of the distinguishing characteristics of an HCCI engine is that the ignition is controlled by the chemical kinetics, unlike the diesel or spark ignition engines, for which ignition time can be controlled externally by the fuel injection or spark time. As a consequence of being controlled by chemical kinetics, the HCCI ignition time can vary significantly with changes in the operating conditions, and this variation can limit the practical range of operation of the engine. Using a single-zone combustion model and established reaction rate mechanisms, the influences of the compression ratio, intake temperature, equivalence ratio, engine speed, and exhaust gas recirculation on the ignition time of two fuels, normal heptane and iso-octane, were studied. The model simulated the environment in the engine combustion chamber by assuming adiabatic compression and expansion. The sensitivity of the ignition time to changes in operating conditions was found to be dependent on the type of fuel. The results indicate that the use of fuels with a characteristics two-stage ignition (e.g., n -heptane) exacerbates the problem of ignition control compared with the use of fuels with a single-stage ignition (e.g., iso-octane).
[1]
William J. Pitz,et al.
Oxidation of automotive primary reference fuels at elevated pressures
,
1999
.
[2]
William J. Pitz,et al.
Extents of alkane combustion during rapid compression leading to single and two stage ignition
,
1996
.
[3]
Charles K. Westbrook,et al.
Hydrocarbon ignition: Automatic generation of reaction mechanisms and applications to modeling of engine knock
,
1992
.
[4]
C. Westbrook,et al.
A Comprehensive Modeling Study of n-Heptane Oxidation
,
1998
.
[5]
Robert J. Kee,et al.
CHEMKIN-III: A FORTRAN chemical kinetics package for the analysis of gas-phase chemical and plasma kinetics
,
1996
.