In-cylinder flame luminosity measured from a stratified lean gasoline direct injection engine

Joonho Jeon; N. Bock; W. F. Northrop

doi:10.1016/j.rineng.2019.100005

In-cylinder flame luminosity measured from a stratified lean gasoline direct injection engine

Joonho Jeon, N. Bock, W. F. Northrop

Mechanical Engineering

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8 Scopus citations

Abstract

In-cylinder flame luminosity has been used to diagnose combustion process and the formation of soot emissions in compression-ignition engines. Increased soot particle emissions from spark-ignited gasoline direct injection (GDI)engines, especially those with stratified fuel-air mixtures, requires investigation of responsible anomalous flame behavior. In this work, spatiotemporal in-cylinder flame luminosity is reported from a lean stratified operating condition in a modern GDI engine. Significant fuel mass injected near top dead center led to detectable piston-top pool fires that have previously correlated to significant soot particle emissions. The demonstrated result shows that measuring in-cylinder flame luminosity is a viable tool for identifying soot-causing flames in GDI engines.

Original language	English (US)
Article number	100005
Journal	Results in Engineering
Volume	1
DOIs	https://doi.org/10.1016/j.rineng.2019.100005
State	Published - Mar 2019

Bibliographical note

Funding Information:
This material is based upon work supported by the Department of Energy, Office of Energy Efficiency and Renewable Energy (EERE) , under Award Number DE-EE0007217 .

Publisher Copyright:
© 2019 The Author(s)

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title = "In-cylinder flame luminosity measured from a stratified lean gasoline direct injection engine",

abstract = "In-cylinder flame luminosity has been used to diagnose combustion process and the formation of soot emissions in compression-ignition engines. Increased soot particle emissions from spark-ignited gasoline direct injection (GDI)engines, especially those with stratified fuel-air mixtures, requires investigation of responsible anomalous flame behavior. In this work, spatiotemporal in-cylinder flame luminosity is reported from a lean stratified operating condition in a modern GDI engine. Significant fuel mass injected near top dead center led to detectable piston-top pool fires that have previously correlated to significant soot particle emissions. The demonstrated result shows that measuring in-cylinder flame luminosity is a viable tool for identifying soot-causing flames in GDI engines.",

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AU - Northrop, W. F.

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N2 - In-cylinder flame luminosity has been used to diagnose combustion process and the formation of soot emissions in compression-ignition engines. Increased soot particle emissions from spark-ignited gasoline direct injection (GDI)engines, especially those with stratified fuel-air mixtures, requires investigation of responsible anomalous flame behavior. In this work, spatiotemporal in-cylinder flame luminosity is reported from a lean stratified operating condition in a modern GDI engine. Significant fuel mass injected near top dead center led to detectable piston-top pool fires that have previously correlated to significant soot particle emissions. The demonstrated result shows that measuring in-cylinder flame luminosity is a viable tool for identifying soot-causing flames in GDI engines.

AB - In-cylinder flame luminosity has been used to diagnose combustion process and the formation of soot emissions in compression-ignition engines. Increased soot particle emissions from spark-ignited gasoline direct injection (GDI)engines, especially those with stratified fuel-air mixtures, requires investigation of responsible anomalous flame behavior. In this work, spatiotemporal in-cylinder flame luminosity is reported from a lean stratified operating condition in a modern GDI engine. Significant fuel mass injected near top dead center led to detectable piston-top pool fires that have previously correlated to significant soot particle emissions. The demonstrated result shows that measuring in-cylinder flame luminosity is a viable tool for identifying soot-causing flames in GDI engines.

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In-cylinder flame luminosity measured from a stratified lean gasoline direct injection engine

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