The effect of injection parameters and boost pressure on diesel-propane dual fuel low temperature combustion in a single-cylinder research engine

Abstract

Diesel-ignited propane dual fuel low temperature combustion was characterized in a single-cylinder research engine (SCRE) at constant values of indicated mean effective pressure (IMEP of 5.1bar), engine speed (1500rpm), and propane energy substitution (PES=80%). The effects of three important engine parameters (start of injection (SOI) of diesel fuel, common-rail pressure (Prail) for diesel injection, and boost pressure (Pin)) on engine performance, combustion, and emissions were examined. As SOI was advanced from 355 absolute crank angle degrees (CAD) (or 5° BTDC) to 280 CAD for constant Prail=500bar and Pin=1.5bar, the apparent heat release rate (AHRR) profiles changed from a two-stage, “diesel-like” combustion process to a smooth, “Gaussian-like,” single-stage combustion process, that was representative of more homogeneous combustion. In addition, with SOI advancement, the combustion phasing (CA50) was initially advanced but eventually occurred later for very early SOIs. Indicated-specific emissions of oxides of nitrogen (ISNOx) were reduced to about 0.12g/kWh for SOIs advanced beyond 310 CAD while maintaining high indicated fuel conversion efficiencies (IFCEs). While smoke emissions were below 0.1 FSN for all conditions tested in this study, indicated-specific hydrocarbon (ISHC) and carbon monoxide (ISCO) emissions were high at both very early and very late SOIs. Efficiency-emissions tradeoffs indicated an “optimal” SOI of 310 CAD under these conditions, which was chosen for further studies at different Prail and Pin. Decreasing Prail from 1300bar to 200bar at Pin=1.5bar led to a steep increase in ISNOx emissions for Prail below 400bar; however IFCE and smoke were relatively invariant with Prail. Boost pressure effects were then quantified at Prail=500bar. As Pin was increased from 1.1bar to 1.8bar, the ignition delay decreased and the AHRR profiles continued to exhibit single-stage combustion, albeit with different rates and peak magnitudes. Moreover, with increasing Pin, the IFCE and ISCO increased while ISNOx and ISHC decreased slightly. Finally, the impact of SOI, Prail, and Pin variations on engine stability (i.e., COV of IMEP), maximum pressure rise rates (MPRRs), and combustion duration were also characterized.