Abstract
This paper presents a numerical investigation of the separate effects of post-injection characteristics in a heavy-duty turbocharged direct injection diesel engine under pure diesel combustion (PDC) and diesel-syngas combustion (DSC) operating conditions. Converge CFD code was used coupled with a detailed n-heptane/toluene/PAH chemical kinetic mechanism (consists of 71 species and 360 reactions) for diesel-syngas dual-fuel combustion simulation. A total of 36 strategies based on the post-injection characteristics (post-injection timing, fuel quantity, spraying pressure, and main-post dwell time) on the combustion characteristics, exhaust gas emissions, and engine performance under PDC and DSC conditions were investigated. Numerical achievements revealed that 40% substitution of diesel fuel with syngas significantly decreased particulate matter emission and enhanced the indicated thermal efficiency (ITE), compared to the baseline PDC case. However, carbon monoxide noticeably increased. In addition, retarding the post-injection timing prolonged the combustion duration and also reduced the nitrogen oxides emissions and ITE. By increasing the post-injection quantity up to 15%, the combustion process deteriorated, and carbon-based emissions such as particulate matter, carbon monoxide, and unburnt hydro-carbon in the exhaust gases increased under PDC and DSC conditions. Furthermore, increasing post-injection pressure (PIP) from 1000 to 1450 bar under both PDC and DSC conditions led to higher flame temperature, and as a result, the heat release rate peak point and temperature peak point for the second combustion event increased. However, at a PIP of 1600 bar, the ITE deteriorated under PDC and DSC operating cases.
Highlights
The considerable increase in the number of vehicles simultaneous with population growth caused a significant increase in fossil fuels consumption as well as greenhouse gases
The main purpose of this numerical research was to investigate the effects of syngas addition and post-injection characteristics on the combustion, engine-out emissions, and performance in a heavy-duty DI diesel engine
Regarding engine performance, at MIT of 18 CA BTDC, indicated thermal efficiency (ITE) enhanced by nearly 1.9% and 3.9% under pure diesel combustion (PDC) and diesel-syngas combustion (DSC) operating conditions compared to the baseline cases, respectively. iv
Summary
The considerable increase in the number of vehicles simultaneous with population growth caused a significant increase in fossil fuels consumption as well as greenhouse gases. For this reason, demands for compression ignition engines due to lower fuel consumption and CO/CO2 emissions compared to gas and gasoline engines has been increased [1]. Diesel engines produce substantial amounts of NOx and PM emissions due to the formation of regions with high temperatures as well as high equivalence ratios during combustion [2]. Diesel engines have many problems regarding exhaust gas emissions that violate environmental laws
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