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High-powered vehicles offer an advantage of superior fuel economy through use of regenerative braking and lowered transient emissions by reducing the operating portion of the engine to follow load as closely as in a conventional bus. A hybrid bus was designed and a prototype was developed. It has a parallel-type hybrid powertrain system and uses a 6-liter diesel engine which satisfy Euro-5 emission standard. 44-kW-electric motor, AMT (automated manual transmission) and Li-ion-type batteries were applied to this hybrid bus. Total 8 hybrid buses are test-running in 6 cities and the driving performances are monitored in terms of fuel efficiency, emission and convenience. This paper presents the performance, major component features and calibration procedures of hybrid powertrain systems. Test run monitoring result showed a benefit of fuel economy at least 36% by comparing to a conventional diesel-powered bus.

A reduced chemical kinetic mechanism for a gasoline surrogate was developed and validated in this study for CAI (Controlled Auto Ignition) combustion. The gasoline surrogate was modeled as a blend of iso-octane, n-heptane, and toluene. This reduced mechanism consisted of 44 species and 59 reactions, including main reaction paths of iso-octane, n-heptane, and toluene. The ignition delay times calculated from this mechanism showed a good agreement with previous experimental data from shock tube measurement. A rapid compression machine (RCM) was developed and used to measure the ignition delay times of gasoline and surrogate fuels in the temperature range of 890K ∼ 1000K. The RCM experimental results were also compared with the RCM simulation using the reduced mechanism. It was found that the chemical reaction started before the end of the compression process in the RCM experiment. And the ignition delay time of the suggested gasoline surrogate was similar to that of gasoline.