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High-load HCCI operation is typically limited by rapid pressure-rise rates (PRR) and engine knock caused by an overly rapid heat-release rate (HRR). Exhaust gas recirculation (EGR) is commonly used in HCCI engines, and it is often stated in the literature that charge dilution with EGR (or high levels of retained residuals) is beneficial for reducing the PRR to allow higher loads without knock. However, EGR/retained-residuals affect other operating parameters such as combustion phasing, which can in turn influence the PRR independently from any effect of the EGR gases themselves. Because of the multiple effects of EGR, its direct benefit for reducing the PRR is not well understood. In this work, the effects of EGR on the PRR were isolated by controlling the combustion phasing independently from the EGR addition by adjusting the intake temperature. The experiments were conducted using gasoline as the fuel at a 1200 rpm operating condition.

HCCI-combustion with direct injection of gasoline using a standard GDI-injector is investigated in this work. The test engine is a 6-cylinder heavy-duty diesel engine with one cylinder operating in HCCI-mode. Exhaust gases from one of the diesel cylinders serve as simulated EGR. Electric heaters are used to raise the inlet temperature when no EGR is applied. The piston bowl is modified to match the hollow-cone spray better than the original re-entrant piston. Spray imaging outside the engine shows the characteristics of the fuel spray. Injection timing sweeps show that a homogeneous charge is created when the injection is performed in the middle of the intake stroke for a moderate fuel/air-equivalence ratio of 0.29. This leads to low emissions of NOx and Smoke. Using a homogeneous mixture when the fuel/air-equivalence ratio is reduced to 0.20 leads to low combustion efficiency with associated high levels of CO and HC emissions.

Combustion phasing is one important issue that must be addressed for HCCI operation. The intake temperature can be adjusted to achieve ignition at the desired crank angle. However, heat-transfer during induction will make the effective intake temperature different from the temperature measured in the runner. Also, depending on the engine speed and port configuration, dynamic flow effects cause various degrees of charge heating. Additionally, residuals from the previous cycle can have significant influence on the charge temperature at the beginning of the compression stroke. Finally, direct injection of fuel will influence the charge temperature since heat is needed for vaporization. This study investigates these effects in a systematic manner with a combination of experiment and cycle simulation using WAVE from Ricardo.

The injector in a DI diesel engine has been modified to allow rotation. The injector speed was varied within ± 4,000 rpm in the current study over 13 testpoints. Air swirl levels tested are 1.5 and 2.8. Rotating the injector adds a free parameter to the combustion system and enables lowest possible smoke emission from each given loadpoint. Smoke reduction up to 74% has been encountered. The mean reduction over all 10 testpoints with a swirl ratio of 1.5 is 55%. Increasing the air-swirl level decreases the smoke level with static injector. The further smoke reduction with counter-swirl rotation is significant albeit not as large as for the lower swirl case. A relationship between the injector speed and effective swirl ratio at TDC is strongly supported by the results and maximum spray stagnation onto the piston bowl wall explains the maximum smoke level when rotating co-swirl. Both counter-swirl rotation and increased air-swirl decreases the ignition delay.