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Numerical Investigation into the Formation of CO and Oxygenated and Nonoxygenated Hydrocarbon Emissions from Isooctane- and Ethanol-Fueled HCCI Engines

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dc.contributor.author Komninos, NP en
dc.contributor.author Rakopoulos, CD en
dc.date.accessioned 2014-03-01T02:00:31Z
dc.date.available 2014-03-01T02:00:31Z
dc.date.issued 2010 en
dc.identifier.issn 0887-0624 en
dc.identifier.uri https://dspace.lib.ntua.gr/xmlui/handle/123456789/29113
dc.subject.classification Energy & Fuels en
dc.subject.classification Engineering, Chemical en
dc.subject.other COMPRESSION IGNITION COMBUSTION en
dc.subject.other FLAME IONIZATION DETECTOR en
dc.subject.other DI DIESEL-ENGINE en
dc.subject.other MULTIZONE MODEL en
dc.subject.other EXHAUST EMISSIONS en
dc.subject.other PORT INJECTION en
dc.subject.other BIO-DIESEL en
dc.subject.other BLENDS en
dc.subject.other PERFORMANCE en
dc.subject.other OPERATION en
dc.title Numerical Investigation into the Formation of CO and Oxygenated and Nonoxygenated Hydrocarbon Emissions from Isooctane- and Ethanol-Fueled HCCI Engines en
heal.type journalArticle en
heal.language English en
heal.publicationDate 2010 en
heal.abstract The present study focuses on the investigation of the formation of CO and unburned oxygenated and nonoxygenated hydrocarbon emissions from HCCI engines fueled with neat ethanol and neat isooctane. This is achieved with the use of a multizone model, which describes the essential features of HCCI combustion, that is, heat and mass transfer within the combustion chamber, both of which are modeled using phenomenological submodels. These mechanisms affect the formation of the main HCCI engine pollutants, namely, unburned hydrocarbons and carbon monoxide. Combustion is simulated using chemical kinetics coupled to oxidation mechanisms for isooctane and ethanol. These mechanisms also describe the decomposition of the original fuel into intermediate hydrocarbons and carbon monoxide. A validation of the model for both fuels is given for various load cases. In the numerical investigation, the formation of CO is described for the corresponding experimental cases and the essential features of the transition from CO production due to bulk quenching and to CO production due to postcombustion partial HC oxidation are shown. Additionally, the formation of HC emissions is described including both oxygenated and nonoxygenated compounds. This distinction was found to be necessary since both fuels include oxygenated species in the exhaust gases, the relative amount of which depends on load conditions and the fuel used. The fraction of oxygenated compounds to total unburned HC is high for ethanol at all loads, primarily due to the presence of ethanol, acetaldehyde and formaldehyde, in descending order of importance. The relative proportion of oxygenates in total unburned HC in the case of isooctane was found to depend on load. These findings raised questions regarding the assessment of unburned hydrocarbon emissions using conventional measuring devices, such as the FID. For this reason the relative error in the FID measurement was estimated, using the simulated HC composition results and the FID relative response of each of the species constituting the HC. en
heal.publisher AMER CHEMICAL SOC en
heal.journalName ENERGY & FUELS en
dc.identifier.isi ISI:000276563100023 en
dc.identifier.volume 24 en
dc.identifier.spage 1655 en
dc.identifier.epage 1667 en


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