PERFORMANCE OF LEAN BURN AND STOICHIOMETRIC GAS COMPRESSION ENGINES
COVER STORY GAS ENGINES
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KeywordsHeat Release Rate Expansion Ratio Heat Rejection Laminar Flame Speed Charge Temperature
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- McCarthy, J.: Air Regulations Impacting the Natural Gas Industry – 2009 Air Quality Regulatory Update. 2009 Gas Machinery Conference, Atlanta, GA, October 2009Google Scholar
- Digital Analysis of Reaction Systems (DARS): http://www.diganars.com/
- Hoyermann, K.; Mauss, F.; Zeuch, T.: A detailed chemical reaction mechanism for the oxidation of hydrocarbons and its application to the analysis of benzene formation in fuel-rich premixed laminar acetylene and propene flames. In: Phys. Chem. Chem. Phys., 2004, No. 6, pp. 3824 – 3835Google Scholar
- Bosholm, J.; Sheldon, V.: Caterpiller G3516B with Ultra Lean Burn Technology, Contract Gas Compression Fleet Experience. Gas Machinery Research Council Conference, Atlanta, Georgia, 2009Google Scholar
- Leprince, T.: Oxidation Catalysts for Natural Gas Engines – Development and Experience. Motortech 3rd International Gas Engines Conference, Celle, Germany, April 2005Google Scholar
- Nuss-Warren, S.; Toema, M.; Chapman, K.: Variations in Long-Term Emissions Data from NSCR-Equipped Natural Gas-Fueled Engine. In: Proceedings of the ASME Internal Combustion Engine Division 2009 Spring Technical Conference, ICES2009, May 3-6, 2009Google Scholar
- Tice, J.: Exhaust Gas Aftertreatment: Catalyst Systems A GMC Short Course. Gas Machinery Conference, Atlanta, GA, October 2009Google Scholar
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