Effects of Ignition and Injection Perturbation under Lean and Dilute GDI Engine Operation

Thomas Wallner; James M. Sevik; Riccardo Scarcelli; Brian C. Kaul; Robert M. Wagner

doi:10.4271/2015-01-1871

Effects of Ignition and Injection Perturbation under Lean and Dilute GDI Engine Operation

Thomas Wallner
, James M. Sevik
, Riccardo Scarcelli
, Brian C. Kaul
, Robert M. Wagner

Combustion and Fuel Science Research

Research output: Contribution to journal › Conference article › peer-review

8 Scopus citations

Abstract

Turbocharged gasoline direct injection (GDI) engines are quickly becoming more prominent in light-duty automotive applications because of their potential improvements in efficiency and fuel economy. While EGR dilute and lean operation serve as potential pathways to further improve efficiencies and emissions in GDI engines, they also pose challenges for stable engine operation. Tests were performed on a single-cylinder research engine that is representative of current automotive-style GDI engines. Baseline cases were performed under steady-state operating conditions where combustion phasing and dilution were varied to determine the effects on indicated efficiency and combustion stability. Sensitivity studies were then carried out by introducing binary low-high perturbation of spark timing and injection duration on a cycle-by-cycle basis under EGR dilute and lean operation to determine dominant feedback mechanisms. Ignition perturbation was phased early/late of MBT timing, and injection perturbation was set fuel rich/lean of the given air-fuel ratio. COV_IMEP was used to define acceptable operation limits when comparing different perturbation cases. Overall results suggests that combustion phasing is very important for dilute operation while the impact of perturbation is reduced due to increased burn duration compared to the stoichiometric baseline without EGR. Lean operation was found to be very sensitive to injection perturbation, with the effect of perturbations amplified by next-cycle feedback. Due to the longer timescale EGR operation was shown to be less sensitive to next-cycle changes in fueling.

Original language	English
Journal	SAE Technical Papers
Volume	2015-September
Issue number	September
DOIs	https://doi.org/10.4271/2015-01-1871
State	Published - Sep 1 2015
Event	JSAE/SAE 2015 International Powertrains, Fuels and Lubricants Meeting, FFL 2015 - Kyoto, Japan Duration: Sep 1 2015 → Sep 4 2015

Funding

This research is funded by DOE's Vehicle Technologies Program, Office of Energy Efficiency and Renewable Energy. The authors would like to express their gratitude to Gurpreet Singh and Leo Breton, program managers at DOE, for their support. The research engine used to run these experiments was provided by Ford Motor Company. Special thanks to Brad Boyer and Steven Wooldridge and their team from Ford Motor Company for their guidance and support. This research is funded by DOE's Vehicle Technologies Program, Office of Energy Efficiency and Renewable Energy. The authors would like to express their gratitude to Gurpreet Singh and Leo Breton, program managers at DOE, for their support. The research engine used to run these experiments was provided by Ford Motor Company. Special thanks to Brad Boyer and Steven Wooldridge and their team from Ford Motor Company for their guidance and support.

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10.4271/2015-01-1871

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title = "Effects of Ignition and Injection Perturbation under Lean and Dilute GDI Engine Operation",

abstract = "Turbocharged gasoline direct injection (GDI) engines are quickly becoming more prominent in light-duty automotive applications because of their potential improvements in efficiency and fuel economy. While EGR dilute and lean operation serve as potential pathways to further improve efficiencies and emissions in GDI engines, they also pose challenges for stable engine operation. Tests were performed on a single-cylinder research engine that is representative of current automotive-style GDI engines. Baseline cases were performed under steady-state operating conditions where combustion phasing and dilution were varied to determine the effects on indicated efficiency and combustion stability. Sensitivity studies were then carried out by introducing binary low-high perturbation of spark timing and injection duration on a cycle-by-cycle basis under EGR dilute and lean operation to determine dominant feedback mechanisms. Ignition perturbation was phased early/late of MBT timing, and injection perturbation was set fuel rich/lean of the given air-fuel ratio. COVIMEP was used to define acceptable operation limits when comparing different perturbation cases. Overall results suggests that combustion phasing is very important for dilute operation while the impact of perturbation is reduced due to increased burn duration compared to the stoichiometric baseline without EGR. Lean operation was found to be very sensitive to injection perturbation, with the effect of perturbations amplified by next-cycle feedback. Due to the longer timescale EGR operation was shown to be less sensitive to next-cycle changes in fueling.",

author = "Thomas Wallner and Sevik, \{James M.\} and Riccardo Scarcelli and Kaul, \{Brian C.\} and Wagner, \{Robert M.\}",

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AU - Sevik, James M.

AU - Scarcelli, Riccardo

AU - Kaul, Brian C.

AU - Wagner, Robert M.

PY - 2015/9/1

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N2 - Turbocharged gasoline direct injection (GDI) engines are quickly becoming more prominent in light-duty automotive applications because of their potential improvements in efficiency and fuel economy. While EGR dilute and lean operation serve as potential pathways to further improve efficiencies and emissions in GDI engines, they also pose challenges for stable engine operation. Tests were performed on a single-cylinder research engine that is representative of current automotive-style GDI engines. Baseline cases were performed under steady-state operating conditions where combustion phasing and dilution were varied to determine the effects on indicated efficiency and combustion stability. Sensitivity studies were then carried out by introducing binary low-high perturbation of spark timing and injection duration on a cycle-by-cycle basis under EGR dilute and lean operation to determine dominant feedback mechanisms. Ignition perturbation was phased early/late of MBT timing, and injection perturbation was set fuel rich/lean of the given air-fuel ratio. COVIMEP was used to define acceptable operation limits when comparing different perturbation cases. Overall results suggests that combustion phasing is very important for dilute operation while the impact of perturbation is reduced due to increased burn duration compared to the stoichiometric baseline without EGR. Lean operation was found to be very sensitive to injection perturbation, with the effect of perturbations amplified by next-cycle feedback. Due to the longer timescale EGR operation was shown to be less sensitive to next-cycle changes in fueling.

AB - Turbocharged gasoline direct injection (GDI) engines are quickly becoming more prominent in light-duty automotive applications because of their potential improvements in efficiency and fuel economy. While EGR dilute and lean operation serve as potential pathways to further improve efficiencies and emissions in GDI engines, they also pose challenges for stable engine operation. Tests were performed on a single-cylinder research engine that is representative of current automotive-style GDI engines. Baseline cases were performed under steady-state operating conditions where combustion phasing and dilution were varied to determine the effects on indicated efficiency and combustion stability. Sensitivity studies were then carried out by introducing binary low-high perturbation of spark timing and injection duration on a cycle-by-cycle basis under EGR dilute and lean operation to determine dominant feedback mechanisms. Ignition perturbation was phased early/late of MBT timing, and injection perturbation was set fuel rich/lean of the given air-fuel ratio. COVIMEP was used to define acceptable operation limits when comparing different perturbation cases. Overall results suggests that combustion phasing is very important for dilute operation while the impact of perturbation is reduced due to increased burn duration compared to the stoichiometric baseline without EGR. Lean operation was found to be very sensitive to injection perturbation, with the effect of perturbations amplified by next-cycle feedback. Due to the longer timescale EGR operation was shown to be less sensitive to next-cycle changes in fueling.

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AN - SCOPUS:85018328009

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VL - 2015-September

JO - SAE Technical Papers

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Y2 - 1 September 2015 through 4 September 2015

ER -

Effects of Ignition and Injection Perturbation under Lean and Dilute GDI Engine Operation

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