The effect of a new catalyst system composed of traditional three way catalyst converter and adsorber-reduction catalysis converter on the emission characteristics and BSFC (Breake Specific Fuel Consumption- BSFC)of a lean burn gasoline engine operated were investigated in this paper under different schemes of catalyst converter arrangement and different speeds and loads. The results show that the position of Three Way Catalyst is before the NOx adsorber Catalyst was the best scheme of catalyst converter arrangement. Which has the highest converter efficiency of reduction NOx emission in lean burn gasoline engine. The effects of speed on the exhaust emission and BSFC were also related to the ratio of lean burn time to rich burn time and the absolute value of both time of the adsorber-reduction catalyst converter. The load of the engine was the main influential factor to the exhaust emission characteristics and BSFC of lean burn gasoline engine, and the more load of the engine was, the more NOx emission, the less NOx conversion rate (C_NOx) and the better BSFC were.

Hiromistu Ando, Kazunari Kuwahara. A Keynote on Future Combustion Engines. SAE Paper. 2001-01- 0248.

Wu Z W. Analysis Vehicle TWC Light-off Characteristics on AMESim Platform. TELKOMNIKA Indonesian Journal of Electrical Engineering. 2012; 11(2): 367-372.

J Stokes, TH Lake, MJ Christle. Improving the NOx/fuel economy tradeoff for gasoline engine with CCVS combustion system. SAE paper. 1994; 940482.

JE Parks, Vitaly Prikhodko, William Partridge, Jae-Soon Choi, Kevin Norman, Shean Huff, Paul Chambon. Lean Gasoline Engine Reductant Chemistry During Lean NOx Trap Regeneration. SAE Paper. 2010-01-2267.

Chen Tao, Xie Hui, Li Le, Yu Wei-fei, Zhang Song, Zhao Hua. Combustion Mode Transition between HCCI and SI in Load Transition. Journal of Tianjin University. 2012; 45(4): 367-372.

Grant Lumsden, David Eddleston, Richard Skyes. Comparing Lean Burn and EGR. SAE paper. 1997; 970505.

Ma Z, Wang X. Influence of Fuel Injection on Gasoline Engine Performance.TELKOMNIKA Telecommunication Computing Electronics and Control. 2012; 11(4): 367-372.

He Bangquan,Du Yinwei. Simulation of the Characteristics of Exhaust Gas Flow in the Exhaust System of a Compressed Natural Gas Engine Ignited Each Cylinder at the First Cycle During Start. Journal of Tianjin University (Science and Technology). 2013; 46(1): 87-94.

Gregory D, Marshall RA, Eves B, Dearth M, Hepburn JS, Brogan MS, Swallow D. Evolution of lean NOx-traps on PFI and DISI lean burn vehicles. SAE Paper.1999-01-3498.

W Strehlau, J Leyrer, ES Lox. Lean NOx catalysis to gasoline fueled European cars. Automotive Engineering. 1997; 105(2): 133-135.

Liu Lei, Li Zhijun, Yue Dongpeng, Zhang Hongyang, Chang Qing, Ma Xiaoqiang, Lin Manqun. Simulink-based Simulations of LNT System of Lean Burn Gasoline Engine. Journal of Tianjin University (Science and Technology). 2013; 46(12): 67-72.

Li Zhijun, Zhang Guangyu, Liu Shuliang. An Electronic Control System Development of Reducing NOx Emission in a Quasi_Homogeneous Lean Burn Gasoline Engine. Journal of Combustion Science And Technology. 2004; 10(5): 400-404.

Gieshoff J, Pfeifer M. Advanced Urea SCR Catalysts for Automotive Applications. SAE Paper. 2001-01-0514.

Matsumoto S. DeNOx catalyst for automotive lean-burn engine[J]. Catalysis today. 1996; 29(1): 43-45.

Gawade P, Alexander A M C, Silver R. Effect of Engine Exhaust Parameters on the Hydrothermal Stability of Hydrocarbon-Selective Catalytic Reduction (SCR) Catalysts for Lean-Burn Systems. Energy & Fuels. 2012; 26(12): 7084-7091.