Hydrocarbon storage modeling for diesel oxidation catalysts

Chemical Engineering Science

Volumn 63, Issue 21, 2008, Pages 5179-5192

  Sampara, Chaitanya S ^a   Bissett, Edward J ^b   Assanis, Dennis ^a  

^a The Department of Civil and Environmental Engineering   (United States)

^b GENERAL MOTORS CORPORATION   (United States)

Author keywords

Diesel engine cold start emissions; Diesel oxidation catalysts; Hydrocarbon adsorption desorption kinetics; Zeolites

Indexed keywords

ADSORPTION; CATALYSIS; CHEMICAL OXYGEN DEMAND; CONCENTRATION (PROCESS); DESORPTION; ENGINEERING RESEARCH; HYDROCARBONS; IGNITION; ORGANIC COMPOUNDS; PRECIOUS METALS; RATE CONSTANTS; SILICATE MINERALS; STARTING; ZEOLITES;

ADSORPTION TIME; ADSORPTION-DESORPTION PROCESSES; CHEMISTRY RESEARCH; COLD-START; DIESEL ENGINE COLD-START EMISSIONS; DIESEL OXIDATION CATALYST; DIESEL OXIDATION CATALYSTS; EQUILIBRIUM DATA; FULL SCALE; GLOBAL KINETICS; HC EMISSIONS; HYDROCARBON ADSORPTION-DESORPTION KINETICS; LANGMUIR ISOTHERM; NOBLE METALS; OXIDATION-KINETICS; REACTOR MODELLING; RING OPERATOR; STEADY STATES; STORAGE COMPONENT; STORAGE MODEL;

OXIDATION;

EID: 53349166335     PISSN: 00092509     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ces.2008.06.021     Document Type: Article

References (24)

1. Adams K.M., Cavataio J.V., Sale T., Rimkus W.A., and Hammerle R.H. Laboratory screening of diesel oxidation catalysts and a validation with vehicle testing: the importance of hydrocarbon storage. Society of Automotive Engineers (SAE) (1996) 962049
2. Banno, Y., Tanaka, Y., Hihara, T., Nagata, M., 2004. Pre-filter diesel oxidation catalyst development for DOC-CSF system. Society of Automotive Engineers (SAE), 2004-01-1430.
3. Corma A. Inorganic solid acids and their use in acid-catalyzed hydrocarbon reactions. Chemical Reviews 95 (1995) 559
4. Czaplewski K.F., Reitz T.L., Kim Y.J., and Snurr R.Q. One-dimensional zeolites as hydrocarbon traps. Microporous and Mesoporous Materials 56 (2002) 55
5. Fuller E.N., Schettler P.D., and Giddings C.J. A new method for prediction of binary gas-phase diffusion coefficients. Industrial & Engineering Chemistry 58 5 (1966) 19
6. Goralski Jr., C.T., Chanko, T., Lupescu, J., Ganti, G., 2000. Experimental and modeling investigation of catalyzed hydrocarbon trap performance. Society of Automotive Engineers (SAE), 2000-01-0654.
7. Heywood, J.B., 1988. Internal Combustion Engine Fundamentals. McGraw-Hill International Editions, ISBN: 0-07-100499-8.
8. Kamijo M., Kamikubo M., Akama H., and Matsushita K. Study of an oxidation catalyst system for diesel emission control utilizing HC adsorption. Japanese Society of Automotive Engineers (JSAE) Review 22 (2001) 277
9. x storage-reduction catalyst. Catalysis Today 96 (2004) 171
10. Koltsakis, G.C., Stamatelos, A.M., 2000. Modeling of hydrocarbon trap systems. Society of Automotive Engineers (SAE), 2000-01-0655.
11. Kryl D., Kočí P., Kubíček M., Marek M., Maunula T., and Härkönen M. Catalytic converters for automobile diesel engines with adsorption of hydrocarbons on zeolites. Industrial & Engineering Chemistry Research 44 (2005) 9524
12. Lafyatis D.S., Ansell G.P., Bennett S.C., Frost J.C., Millington P.J., Rajaram R.R., Walker A.P., and Ballinger T.H. Ambient temperature light-off for automobile emission control. Applied Catalysis B-Environmental 18 (1998) 123
13. Mitsuishi, S., Mori, K., Nishizawa, K., Yamamoto, S., 1999. Emission reduction technologies for turbocharged engines. Society of Automotive Engineers (SAE), 1999-01-3629.
14. Nishizawa, K., Momoshima, S., Koga, M., 2000. Nissan's gasoline SULEV technology. Society of Automotive Engineers (SAE), 2000-01-1583.
15. Oh S.H., and Cavendish J.C. Transients of monolith catalytic converters: response to step changes in feedstream temperature as related to controlling automobile emissions. Industrial & Engineering Chemistry Product Research and Development 21 (1982) 29
16. Oh S.H., Bissett E.J., and Battison P.A. Mathematical modeling of electrically heated monolith converters: model formulation, numerical methods, and experimental verification. Industrial & Engineering Chemistry Research 32 (1993) 1560
17. Otto K., Montreuil C.N., Todor O., McCabe R.W., and Gandhi H.S. Adsorption of hydrocarbons and other exhaust components on silicate. Industrial & Engineering Chemistry Research 30 (1991) 2333
18. Poling B.E., Prausnitz J.M., and O'Connell J.P. The properties of gases and liquids (2002), McGraw-Hill, New York ISBN: 0-07-011682-2
19. Sampara C.S., Bissett E.J., Chmielewski M., and Assanis D. Global kinetics for platinum diesel oxidation catalysts. Industrial & Engineering Chemistry Research 46 (2007) 7993
20. Sampara C.S., Bissett E.J., and Chmielewski M. Global kinetics for a commercial diesel oxidation catalyst with two exhaust hydrocarbons. Industrial & Engineering Chemistry Research 47 (2008) 311-322
21. Tanaka Y., Hihara T., Nagata M., Azuma N., and Ueno A. Modeling of diesel oxidation catalyst. Industrial & Engineering Chemistry Research 44 (2005) 8205
22. x reduction by hydrocarbon under diesel transient conditions in consideration of hydrocarbon adsorption and desorption process. Catalysis Today 69 (2001) 209
23. In: Weitkamp J., and Puppe L. (Eds). Catalysis and Zeolites (1999), Springer, Berlin ISBN 3-540-63650-1
24. Yamamoto, S., Matsushita, K., Etoh, S., Takaya, M., 2000. In-line hydrocarbon (HC) adsorber system for reducing cold-start emissions. Society of Automotive Engineers (SAE), 2000-01-0892.