A numerical assessment of the novel concept of crevice containment in a rapid compression machine

Abstract Rapid compression machines (RCMs) typically incorporate creviced pistons to suppress the formation of the roll-up vortex. The use of a creviced piston, however, can enhance other multi-dimensional effects inside the RCM due to the crevice zone being at lower temperature than the main reaction chamber. In this work, such undesirable effects of a creviced piston are highlighted through computational fluid dynamics simulations of n -heptane ignition in RCM. Specifically, the results show that in an RCM with a creviced piston, additional flow of mass takes place from the main combustion chamber to the crevice zone during the first-stage of the two-stage ignition. This phenomenon is not captured by the zero-dimensional modeling approaches that are currently adopted. Consequently, a novel approach of ‘crevice containment’ is introduced and computationally evaluated in this paper. In order to avoid the undesirable effects of creviced piston, the crevice zone is separated from the main reaction chamber at the end of compression. The results with ‘crevice containment’ show significant improvement in the fidelity of zero-dimensional modeling in terms of predicting the overall ignition delay and pressure rise in the first-stage of ignition. Although the implementation of ‘crevice containment’ requires a modification in RCM design, in practice there are significant advantages to be gained through a reduction in the rate of pressure drop in the RCM combustion chamber and a quantitative improvement in the data obtained from the species sampling experiments.

[1]  Simone Hochgreb,et al.  Rapid Compression Machines: Heat Transfer and Suppression of Corner Vortex , 1998 .

[2]  Peter Gray,et al.  Rapid compression studies on spontaneous ignition of isopropyl nitrate Part II: Rapid sampling, intermediate stages and reaction mechanisms , 1980 .

[3]  Chih-Jen Sung,et al.  A RAPID COMPRESSION MACHINE FOR CHEMICAL KINETICS STUDIES AT ELEVATED PRESSURES AND TEMPERATURES , 2007 .

[4]  John M. Simmie,et al.  CFD studies of a twin-piston rapid compression machine , 2005 .

[5]  M. Ribaucour,et al.  Comparison of oxidation and autoignition of the two primary reference fuels by rapid compression , 1996 .

[6]  K. F. Knoche,et al.  Development of thermokinetic models for autoignition in a CFD Code: Experimental validation and application of the results to rapid compression studies , 1992 .

[7]  R. J. Kee,et al.  Chemkin-II : A Fortran Chemical Kinetics Package for the Analysis of Gas Phase Chemical Kinetics , 1991 .

[8]  L.H.S. Roblee,et al.  A technique for sampling reaction intermediates in a rapid compression machine , 1961 .

[9]  J F Griffiths,et al.  Temperature fields during the development of autoignition in a rapid compression machine. , 2001, Faraday discussions.

[10]  R. Minetti,et al.  Temperature Distribution Induced by Pre-lgnition Reactions in a Rapid Compression Machine , 1996 .

[11]  Chih-Jen Sung,et al.  Autoignition of Toluene and Benzene at Elevated Pressures in a Rapid Compression Machine , 2007 .

[12]  Richard A. Yetter,et al.  Autoignition of H2/CO at elevated pressures in a rapid compression machine , 2006 .

[13]  L. Gasnot,et al.  Instantaneous temperature measurement in a rapid-compression machine using laser Rayleigh scattering , 1995 .

[14]  Shigeyuki Tanaka,et al.  A reduced chemical kinetic model for HCCI combustion of primary reference fuels in a rapid compression machine , 2003 .

[15]  William J. Pitz,et al.  Ignition of Isomers of Pentane: An Experimental and Kinetic Modeling Study , 2000 .

[16]  John M. Simmie,et al.  The influence of fuel structure on combustion as demonstrated by the isomers of heptane: a rapid compression machine study , 2005 .

[17]  Chih-Jen Sung,et al.  Aerodynamics inside a rapid compression machine , 2006 .

[18]  Benjamin J. Whitaker,et al.  Temperature fields during the development of combustion in a rapid compression machine , 2001 .

[19]  Benjamin J. Whitaker,et al.  The relationship of knock during controlled autoignition to temperature inhomogeneities and fuel reactivity , 2002 .

[20]  Heinz Pitsch,et al.  Effects of strain rate on high-pressure nonpremixed n-heptane autoignition in counterflow , 2004 .

[21]  Chih-Jen Sung,et al.  CFD modeling of two-stage ignition in a rapid compression machine: Assessment of zero-dimensional approach , 2010 .

[22]  D. J. Rose,et al.  Novel features of end-gas autoignition revealed by computational fluid dynamics , 1992 .

[23]  Chih-Jen Sung,et al.  Computational fluid dynamics modeling of hydrogen ignition in a rapid compression machine , 2008 .