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The effects of port fuel injection (PFI) timing and targeting on air/fuel (A/F) control, exhaust emissions, and combustion stability at retarded spark timing were investigated on a 2.0L I-4 engine with production injectors (300-350 micron SMD droplet spray). Timings were fully closed valve injection (CVI) or fully open valve injection (OVI), and selected targetings were towards the valve or port floor. An “ideal” pre-vaporized, pre-mixed fuel system was also tested to provide a baseline with which to isolate PFI fuel preparation effects. The key findings were: Transient A/F excursions with PFI were minimized over the full temperature range with OVI timing and valve targeting. The X-tau modeled film mass for OVI/valve target was 50% less than CVI/valve target and 30% less than OVI/port target with a cold engine (20° C). When fully warm (90° C), the A/F response of CVI/valve target improved to near that of OVI.

This study was performed to quantify the effects of injector targeting and fuel volatility on transient A/F excursions and fuel film mass in a port fuel injected (PFI) engine. Two injector targeting positions as well as injection timing and four different fuels were studied. Warm-up tests were performed with the throttle ramped between two positions over a one second interval to provide smooth changes in airflow and injected fuel. The exhaust A/F was recorded for each transient and fit using the X-τ model to estimate the change in the liquid fuel stored in the port and cylinder due to the throttle ramp. The change in fuel stored in the films was: ∼20% less with valve targeting ∼30% less with IVO injection timing 50-100% higher for hesitation fuel

Spark retard is desirable for decreasing cold start hydrocarbon emissions and lighting off the catalyst more rapidly. The focus of this work is to better understand the nature of the HC emissions as spark is retarded and investigate the location of the oxidation (in-cylinder or in the exhaust port and manifold). Fast FID measurements were taken in the exhaust port of a single cylinder research engine during cold, retarded spark engine operation (1200 rpm, 2.5 bar IMEP, 20 °C fluids). At moderate spark retard both Fast FID (exhaust port) and exhaust plenum HC levels decreased due to reduced crevice volume fraction at the end of burn, and increased in-cylinder burn up. In contrast, at large spark retard the port HC's increased dramatically while the exhaust plenum levels continued to fall to near zero. This is thought to be due to the onset of incomplete in-cylinder combustion along with increased exhaust port and manifold after-burning caused by the increasing exhaust gas temperatures.