Numerical Analysis of the Combustion Process in Dual-Fuel Engines With Direct Injection of Natural Gas

Jud, Michael; Wieland, Christoph; Fink, Georg; Sattelmayer, Thomas

doi:10.1115/icef2018-9579

Cited by 7 publications

(2 citation statements)

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“…The combustion is calculated using the SAGE Detailed Chemical Kinetics Solver with reaction mechanism resulting from a combination of the GRI3.0 33 for methane and the Chalmers53 n-heptane mechanisms. The Chalmers 53 has been giving good results for methane-diesel HPDF in 34,35 and the GRI3.0 is validated in literature – giving satisfying results for the laminar burning velocity in ammonia combustion. 10,36…”

Section: Methodsmentioning

confidence: 75%

Investigation of ammonia and hydrogen as CO2-free fuels for heavy duty engines using a high pressure dual fuel combustion process

Frankl

Gleis

Karmann

et al. 2020

International Journal of Engine Research

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This work is a numerical study of the use of ammonia and hydrogen in a high-pressure-dual-fuel (HPDF) combustion. The main fuels (hydrogen and ammonia) are direct injected and ignited by a small amount of direct injected pilot fuel. The fuels are injected using a dual fuel injector from Woodward L’Orange, which can induce two fuels independently at high pressures up to 1800 bar for the pilot fuel and maximum 500 bar for the main. The numerical CFD-model gets validated for of hydrogen-HPDF with experimental data. Due to safety issues at the test rig it was not possible to use ammonia in the experiments, so it is modelled using the numerical model. It is assumed that the CFD-model also gives qualitative correct results for the use of ammonia as main fuel, so a parameter study of ammonia-HPDF is made. The results for the hydrogen-HPDF show, that hydrogen can be used in the engine without any further modifications. The combustion is very stable, and the hydrogen ignites almost immediately when it enters the combustion chamber. The results of the ammonia combustion indicate, that the HPDF combustion mode can handle ammonia effectively. It seems beneficial to inject the ammonia at higher pressures than hydrogen. Also pre-heating the ammonia can increase the combustion efficiency.

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Section: Methodsmentioning

confidence: 75%

Investigation of ammonia and hydrogen as CO2-free fuels for heavy duty engines using a high pressure dual fuel combustion process

Frankl

Gleis

Karmann

et al. 2020

International Journal of Engine Research

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show abstract

“…In order to further understand the combustion process for HPDI engines, numerous efforts have been performed to investigate the effects of various injection and air-exchange strategies on the engine performance and emission characteristics. ,− The combustion process of HPDI engines is more complicated than traditional diesel and gasoline engines. − To get better understanding of the combustion process, it is essential to well reveal the detailed in-cylinder combustion process. Optical diagnostics techniques have been playing a significant role in visualizing the engine flow, spray, combustion, and emission formation processes, which contributes to the development of fluid dynamics models (CFD) .…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Combustion Kinetics Process in a High-Pressure Direct Injection Natural Gas Marine Engine

Liu

et al. 2021

Energy Fuels

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The detailed combustion kinetic processes of a high-pressure direct injection (HPDI) natural gas (NG) marine engine was investigated in the present work. A postprocessing code was employed to visualize the characteristic reactions that determine the combustion process. To evaluate the effect of mixture stratification on the combustion process, various NG injection timings were employed and four representative combustion periods were selected, including the timings when 1% (CA1), 5% (CA5), 10% (CA10), and 50% (CA50) of the total fuel energy are released. A higher heat release rate (HRR) was generated with a more advanced NG start of injection (SOI) timing, which, however, had limited effects on the main representative exothermic reactions (REXRs) within the high heat release (HHR) region and the dominant formation reactions of CH 2 O and OH, which are known as the indicators of low heat release (LHR) and HHR, respectively. Besides, for different NG SOI timing simulation, the consumption of CH 4 was all dominated by reactions H + CH 4 = CH 3 + H 2 and OH + CH 4 = CH 3 + H 2 O and the dominated REXR of the LHR region was reaction CH 3 + O 2 = CH 3 O 2 . Furthermore, with an advanced NG injection timing, significant changes were observed for the reaction paths of CH 2 , CH 2 O, and HCO from the premixed-combustion phase (CA10) to the mixing-controlled combustion phase (CA50). The results of the present study are able to provide a theoretical fundamental for the practical control of the HPDI NG marine engine.

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Effects of equivalence and fuel ratios on combustion characteristics of an RCCI engine fueled with methane/n-heptane blend

Taqizadeh

Jahanian

Kani

2019

J Therm Anal Calorim

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Numerical Analysis of the Combustion Process in Dual-Fuel Engines With Direct Injection of Natural Gas

Cited by 7 publications

References 0 publications

Investigation of ammonia and hydrogen as CO2-free fuels for heavy duty engines using a high pressure dual fuel combustion process

Investigation of ammonia and hydrogen as CO2-free fuels for heavy duty engines using a high pressure dual fuel combustion process

Investigation of the Combustion Kinetics Process in a High-Pressure Direct Injection Natural Gas Marine Engine

Effects of equivalence and fuel ratios on combustion characteristics of an RCCI engine fueled with methane/n-heptane blend

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