Frozen Equilibrium and EGR Effects on Radical-Initiated H2 Combustion Kinetics in Low-Compression D.I. Engines Using Pistons with Micro-Chambers

Using hydrogen as a fuel, this chemical-kinetics study qualitatively examines the phenomenon of "frozen equilibrium" in Stratified Charge Radical Ignition (SCRI) engines with direct injection (DI) and exhaust gas recirculation (EGR). In such engines, this phenomenon is believed to preserve select highly reactive species formed in the side chambers (called micro-chambers) embedded inside the piston bowl so that these species can be carried-over to enhance autoignition in the next engine cycle. In turn this enhancement makes possible ignition and combustion at compression ratios that are markedly lower than those considered "standard" (for a given fuel), resulting in reduced emissions. Analysis is based on a detailed chemical-kinetics mechanism that includes NO x production and makes use of up to 19 species and 58 reactions. Along with detailed versions of the momentum and energy equations, this mechanism is simultaneously solved within the two separate but interactively connected open systems representing the individual main chamber and micro-chamber combustion processes. Part of the aim of the present study is to identify several of the engine processes and dominant chemical-kinetics sub-mechanisms responsible for the much lower compression ratios and reduced NO, emissions in SCRI-DI engines with EGR.

[1]  D. Blank,et al.  Qualitative Flow Field Studies of Combustion in I.C. Engines Using a Simplified Sonex Bowl-in-Piston Geometry , 2001 .

[2]  N. N. Semenov,et al.  Some problems in chemical kinetics and reactivity , 1958 .

[3]  Peter Van Blarigan,et al.  Development of a Hydrogen Fueled Internal Combustion Engine Designed for Single Speed/Power Operation , 1996 .

[4]  D. Blank,et al.  NOx Reduction Kinetics Mechanisms and Radical-Induced Autoignition Potential of EGR in I.C. Engines Using Methanol and Hydrogen , 2001 .

[5]  M. Wegener,et al.  Visualization and analysis of bow shocks in a superorbital expansion tube , 1996 .

[6]  L. Gussak,et al.  The Role of Chemical Activity and Turbulence Intensity in Prechamber-Torch Organization of Combustion of a Stationary Flow of a Fuel-Air Mixture , 1983 .

[7]  Donald C. Siegla,et al.  High Chemical Activity of Incomplete Combustion Products and a Method of Prechamber Torch Ignition for Avalanche Activation of Combustion in Internal Combustion Engines , 1975 .

[8]  Paul E. Sojka,et al.  Autoignition of H2-air - The effect of NOx addition , 1989 .

[9]  B. S. Petukhov Heat Transfer and Friction in Turbulent Pipe Flow with Variable Physical Properties , 1970 .

[10]  Yukiyasu Tanaka,et al.  A Study on Gasoline Engine Combustion by Observation of Intermediate Reactive Products during Combustion , 1979 .

[11]  J Alan Adams Heat Transfer Analysis of the NAHBE Piston Cap , 1977 .

[12]  C. J. Jachimowski,et al.  Shock-tube study of the initiation process in the hydrogen-oxygen reaction , 1971 .

[13]  Jiang Lu,et al.  A Preliminary Study of Chemically Enhanced Autoignition in an Internal Combustion Engine , 1994 .

[14]  T. Shih,et al.  HYPERGOLIC COMBUSTION MODEL FOR FOUR-STROKE HEAT-BARRIER PISTON ENGINES , 1990 .

[15]  R. Hanson,et al.  Survey of Rate Constants in the N/H/O System , 1984 .

[16]  D. Blank,et al.  Flame Quenching in the Micro-Chamber Passages of I .C. Engines with Regular-Symmetric Sonex Piston Geometry , 2001 .

[17]  C. G. Broyden A Class of Methods for Solving Nonlinear Simultaneous Equations , 1965 .

[18]  A. Grillo,et al.  Rate coefficients for H2 + NO2 = HNO2 + H derived from shock tube investigations of H2O2NO2 ignition , 1978 .

[19]  Charles K. Westbrook,et al.  Hydrogen Oxidation Kinetics in Gaseous Detonations , 1982 .