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Potential of ammonia spray configuration in ammonia-diesel dual-fuel direct injection compression ignition engine: Toward near zero carbon emissions

Ahmed Mohammed Elbanna, Jinhe Zhang, Shijie Mi, Xingcai Lü

2025International Journal of Engine Research5 citationsDOIOpen Access PDF

Abstract

Asymmetrical spray arrangement is an efficient method of enhancing combustion while mitigating NH 3 and N 2 O emissions in ammonia/diesel dual-fuel engines. Ammonia is regarded a potentially effective main fuel for decreasing CO 2 emissions due to its higher hydrogen concentration when compared to diesel fuel. In the present work, a little amount of pilot diesel ignites the direct-injected ammonia, which burns in a diffusion combustion regime. It has been found that the interaction between the diesel and ammonia sprays has a major effect on the combustion regimes and flame growth. Simultaneously, a computational CFD model has been constructed to investigate the interaction between spray and flame structure of ammonia/diesel plumes. Two configurations for ammonia spray have been introduced in order to facilitate efficient mixing and combustion process. The asymmetrical configuration eliminates two plumes oriented toward the walls and injects more ammonia into the center of combustion chamber. By presenting an asymmetrical spray configuration for ammonia, it is possible to reduce the allocation of rich ammonia pockets, bringing ammonia technology one step closer to reliability. Asymmetrical spray configuration leads to mitigate the inhibiting effect of ammonia spray on the diesel ignition while introducing ammonia more efficiently into the combustion chamber. Comparing to symmetrical spray configuration, asymmetrical spray confirmation reduces NH 3 emission by 57.5%, N 2 O by 23.4%.

Topics & Concepts

AmmoniaIgnition systemDual (grammatical number)Diesel fuelCarbureted compression ignition model engineAutomotive engineeringDiesel engineHomogeneous charge compression ignitionEnvironmental scienceExhaust gas recirculationCompression ratioZero emissionWaste managementCompression (physics)Materials scienceDiesel cycleThermodynamicsChemistryCombustionInternal combustion engineEngineeringPhysicsCombustion chamberComposite materialOrganic chemistryArtLiteratureAdvanced Combustion Engine TechnologiesCatalytic Processes in Materials ScienceVehicle emissions and performance
Potential of ammonia spray configuration in ammonia-diesel dual-fuel direct injection compression ignition engine: Toward near zero carbon emissions | Litcius