Experimental Investigation of Effects of Split Diesel-Pilot Injection on Emissions From Ammonia-Diesel Dual Fuel Engine

NH₃ has been investigated for its use as an alternative fuel including for use in internal combustion engines. In NH₃ combustion, emissions of unburned NH₃ with toxicity and N₂O as a combustion product with high global warming potential (GWP) are important issues. However, few researchers have investigated NH₃ and N₂O emissions from NH₃ assisted diesel engines operated using NH₃–diesel dual fuel. We investigate a combustion strategy to reduce these emissions with a single-cylinder diesel engine mixed NH₃ gas into the intake air. We found that an early diesel pilot injection reduced unburned NH₃ and N₂O emissions while HC and CO emissions increased. It was also reported that NH₃ and diesel fuel work as low and high reactivity fuel for reactivity controlled compression ignition combustion (RCCI), respectively. Our previous study reports the aspects of RCCI on NH₃–diesel dual fuel engine to some extent. The injection timing of diesel fuel and the quantity of NH₃ govern the emissions and performance on RCCI combustion. These effects need to be investigated to manipulate the RCCI combustion and reduce emissions. This paper reports the efficiency and emissions for the diesel pilot injection timing sweep at various NH₃ supply quantities and the effects of a split injection on the emissions and a combustion phase. In addition, we estimated the reduction in GHG emissions using a NH₃–diesel dual fuel engine, which applied the early diesel pilot injection, compared with the diesel only operation, considering the N₂O GWP.