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Title: Final Report: Utilizing Alternative Fuel Ignition Properties to Improve SI and CI Engine Efficiency

Abstract

Experimental and modeling studies were completed to explore leveraging physical and chemical fuel properties for improved thermal efficiency of internal combustion engines. Fundamental studies of the ignition chemistry of ethanol and iso-octane blends and constant volume spray chamber studies of gasoline and diesel sprays supported the core research effort which used several reciprocating engine platforms. Single cylinder spark ignition (SI) engine studies were carried out to characterize the impact of ethanol/gasoline, syngas (H2 and CO)/gasoline and other oxygenate/gasoline blends on engine performance. The results of the single-cylinder engine experiments and other data from the literature were used to train a GT Power model and to develop a knock criteria based on reaction chemistry. The models were used to interpret the experimental results and project future performance. Studies were also carried out using a state of the art, direct injection (DI) turbocharged multi- cylinder engine with piezo-actuated fuel injectors to demonstrate the promising spray and spark timing strategies from single-cylinder engine studies on the multi-cylinder engine. Key outcomes and conclusions of the studies were: 1. Efficiency benefits of ethanol and gasoline fuel blends were consistent and substantial (e.g. 5-8% absolute improvement in gross indicated thermal efficiency (GITE)). 2. The best ethanol/gasolinemore » blend (based on maximum thermal efficiency) was determined by the engine hardware and limits based on component protection (e.g. peak in-cylinder pressure or maximum turbocharger inlet temperature) – and not by knock limits. Blends with <50% ethanol delivered significant thermal efficiency gains with conventional SI hardware while maintain good safety integrity to the engine hardware. 3. Other compositions of fuel blends including syngas (H2 and CO) and other dilution strategies provided significant efficiency gains as well (e.g. 5% absolute improvement in ITE). 4. When the combination of engine and fuel system is not knock limited, multiple fuel injection events maintain thermal efficiency while improving engine-out emissions (e.g. CO, UHC, and particulate number).« less

Authors:
ORCiD logo [1];  [2];  [2];  [2];  [3]
  1. Univ. of Michigan, Ann Arbor, MI (United States). Dept. of Mechanical Engineering
  2. Univ. of Michigan, Ann Arbor, MI (United States)
  3. Robert Bosch LLC, Farmington Hills, MI (United States)
Publication Date:
Research Org.:
Univ. of Michigan, Ann Arbor, MI (United States)
Sponsoring Org.:
USDOE Office of Energy Efficiency and Renewable Energy (EERE), Vehicle Technologies Office (EE-3V); Robert Bosch LLC, Farmington Hills, MI (United States)
OSTI Identifier:
1420264
Report Number(s):
DOE-UMICH-6831
DOE Contract Number:  
EE0006831; FOA‐0000988
Resource Type:
Technical Report
Country of Publication:
United States
Language:
English
Subject:
33 ADVANCED PROPULSION SYSTEMS

Citation Formats

Wooldridge, Margaret, Boehman, Andre, Lavoie, George, Middleton, Robert, and Fatouraie, Mohammad. Final Report: Utilizing Alternative Fuel Ignition Properties to Improve SI and CI Engine Efficiency. United States: N. p., 2017. Web. doi:10.2172/1420264.
Wooldridge, Margaret, Boehman, Andre, Lavoie, George, Middleton, Robert, & Fatouraie, Mohammad. Final Report: Utilizing Alternative Fuel Ignition Properties to Improve SI and CI Engine Efficiency. United States. https://doi.org/10.2172/1420264
Wooldridge, Margaret, Boehman, Andre, Lavoie, George, Middleton, Robert, and Fatouraie, Mohammad. 2017. "Final Report: Utilizing Alternative Fuel Ignition Properties to Improve SI and CI Engine Efficiency". United States. https://doi.org/10.2172/1420264. https://www.osti.gov/servlets/purl/1420264.
@article{osti_1420264,
title = {Final Report: Utilizing Alternative Fuel Ignition Properties to Improve SI and CI Engine Efficiency},
author = {Wooldridge, Margaret and Boehman, Andre and Lavoie, George and Middleton, Robert and Fatouraie, Mohammad},
abstractNote = {Experimental and modeling studies were completed to explore leveraging physical and chemical fuel properties for improved thermal efficiency of internal combustion engines. Fundamental studies of the ignition chemistry of ethanol and iso-octane blends and constant volume spray chamber studies of gasoline and diesel sprays supported the core research effort which used several reciprocating engine platforms. Single cylinder spark ignition (SI) engine studies were carried out to characterize the impact of ethanol/gasoline, syngas (H2 and CO)/gasoline and other oxygenate/gasoline blends on engine performance. The results of the single-cylinder engine experiments and other data from the literature were used to train a GT Power model and to develop a knock criteria based on reaction chemistry. The models were used to interpret the experimental results and project future performance. Studies were also carried out using a state of the art, direct injection (DI) turbocharged multi- cylinder engine with piezo-actuated fuel injectors to demonstrate the promising spray and spark timing strategies from single-cylinder engine studies on the multi-cylinder engine. Key outcomes and conclusions of the studies were: 1. Efficiency benefits of ethanol and gasoline fuel blends were consistent and substantial (e.g. 5-8% absolute improvement in gross indicated thermal efficiency (GITE)). 2. The best ethanol/gasoline blend (based on maximum thermal efficiency) was determined by the engine hardware and limits based on component protection (e.g. peak in-cylinder pressure or maximum turbocharger inlet temperature) – and not by knock limits. Blends with <50% ethanol delivered significant thermal efficiency gains with conventional SI hardware while maintain good safety integrity to the engine hardware. 3. Other compositions of fuel blends including syngas (H2 and CO) and other dilution strategies provided significant efficiency gains as well (e.g. 5% absolute improvement in ITE). 4. When the combination of engine and fuel system is not knock limited, multiple fuel injection events maintain thermal efficiency while improving engine-out emissions (e.g. CO, UHC, and particulate number).},
doi = {10.2172/1420264},
url = {https://www.osti.gov/biblio/1420264}, journal = {},
number = ,
volume = ,
place = {United States},
year = {Thu Nov 30 00:00:00 EST 2017},
month = {Thu Nov 30 00:00:00 EST 2017}
}