Adjacent combustion heat release and emissions over various load ranges in a premixed direct injection diesel engine: A comparison between gasoline and ethanol port injection

In a premixed diesel engine, supplementary fuels (gasoline and ethanol) are individually premixed by port fuel injection prior to induction and combustion in the main diesel-injected combustion chamber. This study compared emissions and heat release patterns adjacent to the combustion stroke of a premixed diesel engine. A single-cylinder direct injection diesel engine was examined by varying the ratios of the supplementary fuel to diesel quantity to meet the set loads. The engine's target speed was 1600 rpm, and the brake mean effective pressures of 2, 5, and 7 bar were loads representing low-, medium-, and high-load operations, respectively. Results show that the gasoline premixture yielded higher thermal efficiency than the ethanol premixture. When the quantity of gasoline supplementary fuel increased, the thermal efficiency increased, whereas the opposite trend was observed with ethanol. The combustion phasing was delayed by increasing both supplementary fuel ratios. Quantities of nitrogen oxides, smoke, and total unburned hydrocarbon were reduced, and carbon monoxide increased with the elevated quantity of port-injected fuel. The ethanolediesel dual fuel is advantageous regarding smoke opacity, but it suffers from nitrogen oxides trade-off.(c) 2021 Elsevier Ltd. All rights reserved.

Automated summary

This study compared the emissions and heat release patterns of a premixed diesel engine using gasoline and ethanol as supplementary fuels. The results showed that gasoline premixture had higher thermal efficiency, while ethanol premixture had lower thermal efficiency. Increasing the ratio of supplementary fuel delayed the combustion phasing and reduced the quantities of nitrogen oxides, smoke, and total unburned hydrocarbon, but increased carbon monoxide emissions. Ethanol-diesel dual fuel had advantages in terms of smoke opacity but had a nitrogen oxides trade-off.