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Evaluation of fuel additives for HCCI engines operated on fuel-rich methane/air mixtures: DME, DEE, and n-heptane

Kai Banke, Dominik Freund, Burak Atakan, Sebastian A. Kaiser

2023Applications in Energy and Combustion Science11 citationsDOIOpen Access PDF

Abstract

Piston engines can be operated with very fuel-rich fuel/air mixtures to simultaneously produce syngas, power, and heat – so-called “polygeneration”. In this context, the effects of methoxymethane (dimethyl ether, DME), ethoxyethane (diethyl ether, DEE), and n-heptane as additives in compression-ignition of fuel-rich methane/air mixtures were investigated in experiment and simulation. The experiments were performed in a single-cylinder octane-number test engine at a compression ratio of 10. Engine operating stability, auto-ignition behavior, and syngas production were examined. The simulations used a single zone model with detailed chemical kinetics. The method for pressure trace analysis was adapted to the very fuel-rich conditions examined in this study. The choice of additive does not significantly influence syngas production, but a distinct influence on auto-ignition was found. The most effective additive in terms of mass fraction was DEE which produced stable operation at around 20% by weight. While the use of DME and n-heptane resulted in similar heat release traces, DEE yielded more early heat release and less of a negative temperature coefficient (NTC) behavior. The widest stable operating range in terms of additive fraction was found for DME. A reaction path analysis showed that the effect on ignition is similar for all three additives: they react early in the compression stroke and lead to H-abstraction from CH4. Comparing heat release rates and calculated cylinder temperatures indicated that not only the additive's reactivity but also its heat capacity contributes to auto-ignition behavior.

Topics & Concepts

SyngasOctane ratingMethaneDimethyl etherChemistryCombustionMass fractionIgnition systemCarbureted compression ignition model engineOxygenateContext (archaeology)Materials scienceHomogeneous charge compression ignitionThermodynamicsMethanolOrganic chemistryCombustion chamberCatalysisPaleontologyPhysicsBiologyAdvanced Combustion Engine TechnologiesCombustion and flame dynamicsVehicle emissions and performance
Evaluation of fuel additives for HCCI engines operated on fuel-rich methane/air mixtures: DME, DEE, and n-heptane | Litcius