Assessment of combustion and exhaust emissions in a common-rail diesel engine fueled with methane and hydrogen/methane mixtures under different compression ratio

This study investigates the potential usage of the methane and hydrogen enriched methane in a turbocharged common-rail direct injection diesel engine. Methane and hydrogen/methane mixtures are sent through the air intake manifold of the engine. The engine is operated at four different loads and thre...

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Bibliographic Details
Published in:International journal of hydrogen energy 2020-01, Vol.45 (4), p.3263-3283
Main Authors: Sanli, Ali, Yılmaz, Ilker Turgut, Gümüş, Metin
Format: Article
Language:English
Subjects:
Combustion
Common rail
Compression ratio
Emission
Hydrogen
Methane
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Summary:This study investigates the potential usage of the methane and hydrogen enriched methane in a turbocharged common-rail direct injection diesel engine. Methane and hydrogen/methane mixtures are sent through the air intake manifold of the engine. The engine is operated at four different loads and three different compression ratios. Results are compared amongst single diesel and dual-fuel operations at different compression ratios and load conditions. Compared to diesel, dual-fuel operations mostly generate higher and advanced peak in-cylinder gas pressure, more combustion noise, late pilot injection and start of combustion, advanced combustion center, substantial variations at ignition delay and combustion duration, a significant increase in cyclic variations at low and medium loads, and earlier heat release. Hydrogen enrichment decreases evidently specific fuel consumption. Concerning emissions, compared to diesel operation, dual-fuel operations produce higher total hydrocarbon (THC) and nitrogen oxides (NOx) but lower carbon dioxide (CO2). Hydrogen substitutions decrease THC and CO2 emissions of methane dual-fuel operations approximately between 9-29% and 1–32%, respectively. Smoke emission of dual-fuel operations is less than that of diesel at low and medium loads, whereas it sharply increases at high load. Knocking occurs at high compression ratio and load conditions with dual-fuel operations and dramatically increases with increasing hydrogen ratio. Decreasing the compression ratio notably reduces the combustion noise as well as some emissions, such as NOx, CO2 and smoke, for entire load ranges of dual-fuel and diesel operations. [Display omitted] •Methane and hydrogen mixtures are fumigated in a common-rail diesel engine.•Hydrogen enrichment leads to lower fuel consumption, CO2 and THC emissions.•NOx, smoke and CO2 for dual-fuel operations decrease significantly with reducing CR.•Ignition delay for dual-fuel operations reduces at medium and high loads.•Cyclic variations in dual-fuel operations increase compared to diesel.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2019.11.222