Assessing the effect of mass transfer on the formation of HC and CO emissions in HCCI engines, using a multi-zone model

Energy Conversion and Management

Volumn 50, Issue 5, 2009, Pages 1192-1201

  Komninos, N P ^a  

^a NATIONAL TECHNICAL UNIVERSITY OF ATHENS   (Greece)

Author keywords

CO; Emissions formation; HCCI; Hydrocarbons; Mass transfer; Multi zone model

Indexed keywords

COMBUSTION; COMPUTATIONAL FLUID DYNAMICS; GRAFTING (CHEMICAL); HYDROCARBONS; MASS TRANSFER; SMOKE; SYNTHESIS (CHEMICAL); THERMOCHEMISTRY;

CHEMICAL KINETICS; CLOSED CYCLES; CO; CO EMISSIONS; CO PRODUCTIONS; COMBUSTION SIMULATIONS; CYLINDER WALLS; EMISSIONS FORMATION; HCCI; HCCI ENGINES; HEAT RELEASE; MULTI-ZONE MODEL; OPERATING CONDITIONS; PARTIAL OXIDATIONS; SIMULATION RESULTS; SUB-MODELS;

CARBON MONOXIDE;

EID: 62649139063     PISSN: 01968904     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enconman.2009.01.026     Document Type: Article

References (30)

1. Alkidas A.C. Combustion advancements in gasoline engines. Energy Convers Manage 48 (2007) 2751-2761
2. Soylu S. Examination of combustion characteristics and phasing strategies of a natural gas HCCI engine. Energy Convers Manage 46 (2005) 101-119
3. Peucheret S., Wyszynski M.L., Lehre R.S., Golunski S., and Xu H. Use of catalytic reforming to aid natural gas HCCI combustion in engines: experimental and modeling results of open-loop fuel reforming. Hydrogen Energy 30 (2005) 1583-1594
4. Bhave A., Kraft M., Montorosi L., and Mauss F. Sources of CO emissions in an HCCI engine: a numerical analysis. Combust Flame 144 (2005) 634-637
5. Christensen M, Johansson B, Einewall P. Homogeneous charge compression ignition (HCCI) using isooctane, ethanol and natural gas - a comparison with spark ignition operation. SAE paper no. 972874; 1997.
6. Christensen M, Johansson B, Amneus P, Mauss F. Supercharged homogeneous charge compression ignition. SAE paper no. 980787; 1998.
7. Hultqvist A, Christensen M, Johansson B, Franke A, Richter M, Alden M. A study of the homogeneous charge compression ignition combustion process by chemiluminescence imaging. SAE paper no. 1999-01-3680; 1999.
8. Hultqvist A, Endgar U, Johansson B, Klingmann J. Reacting boundary layers in a homogeneous charge compression ignition (HCCI) engine. SAE paper no. 2001-01-1032; 2001.
9. Easley WL, Agarwal A, Lavoie GA. Modeling of HCCI combustion and emissions using detailed chemistry. SAE paper no. 2001-01-1029; 2001.
10. Jia M., and Xie M. Numerical simulation of homogeneous charge compression ignition combustion using a multi-dimensional model. Proc Inst Mech Eng, J Automobile Eng 221 Part D (2007) 465-480
11. Ogink R, Golovitchev V. Gasoline HCCI modeling: an engine cycle simulation code with a multi-zone combustion model. SAE paper no. 2002-01-1745; 2002.
12. Xu H, Liu M, Gharahbaghi S, Richardson S, Wyszynski M, Megaritis T. Modelling of HCCI engines: comparison of single-zone, multi-zone and test data. SAE paper no. 2005-01-2123; 2005.
13. Aceves SM, Flowers DL, Westbrook CK, Smith JR, Pitz W, Dibble RW, et al. A multi-zone model for prediction of HCCI combustion and emissions. SAE paper no. 2000-01-0327; 2000.
14. Aceves SM, Martinez-Friaz J, Flowers DL, Smith JR, Dibble RW, Wright JF, et al. A decoupled model of detailed fluid mechanics followed by detailed chemical kinetics for prediction of iso-octane HCCI combustion. SAE paper no. 2001-01-3612; 2001.
15. Flowers DL, Aceves SM, Martinez-Frias J, Hessel RP, Dibble RW. Effect of mixing on hydrocarbon and carbon monoxide emissions prediction for isooctane HCCI engine combustion using a multi-zone detailed kinetics solver. SAE paper no. 2003-01-1821; 2003.
16. Komninos NP, Hountalas DT, Kouremenos DA. Development of a new multi-zone model for the description of physical processes in HCCI engines. SAE paper no. 2004-01-0562; 2004.
17. Komninos NP, Hountalas DT, Kouremenos DA. Description of in-cylinder combustion processes in HCCI engines using a multi-zone model. SAE paper no. 2005-01-0171; 2005.
18. Komninos N.P., Hountalas D.T., and Rakopoulos D.A. A parametric investigation of hydrogen HCCI combustion using a multi-zone model approach. Energy Convers Manage 48 (2007) 2934-2941
19. Jia M, Zhao Xie M, Peng Z. A comparative study of multi-zone combustion models for HCCI engines. SAE paper no. 2008-01-0064; 2008.
20. Kongsereeparp P, Checkel MD. Investigating the effects of reformed fuel blending in a methane- or n-heptane-HCCI engine using a multi-zone model. SAE paper no. 2007-01-0205; 2007.
21. Kongsereeparp P, Checkel MD. Novel method of setting initial conditions for multi-zone HCCI combustion modeling. SAE paper no. 2007-01-0674; 2007.
22. Mixture composition; 2008. .
23. Annand W.J.D. Heat transfer in the cylinders of reciprocating internal combustion engines. Proc Inst Mech Eng 177 (1963) 973-990
24. Incropera F.P., and DeWitt D.P. Introduction to heat transfer. 3rd ed. (1996), John Wiley & Sons, New York
25. Yang J., and Martin J.K. Approximate solution - one-dimensional energy equation for transient, compressible, low Mach number turbulent boundary layer flows. Trans ASME, J Heat Transfer 111 (1989) 619-624
26. Kong S, Ayoub N, Reitz RD. Modeling combustion in compression ignition homogeneous charge engines. SAE paper no. 920512; 1992.
27. Reitz RD. Assessment of wall heat transfer models for premixed-charge engine combustion computations. SAE paper no. 910267; 1991.
28. Chemical reactions for isooctane; 2008. .
29. 2O formation in HCCI engines. SAE paper no. 2005-01-0126; 2005.
30. Heywood J.B. Internal combustion engine fundamentals (1988), McGraw Hill, New York