Citations (27)
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J. R. LINNA & S. HOCHGREB. (1995) Analytical Scaling Model for Hydrocarbon Emissions From Fuel Absorption in Oil Layers in Spark Ignition Engines. Combustion Science and Technology 109:1-6, pages 205-226.
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Wei Shyy & T. C. Adamson$suffix/text()$suffix/text(). (1983) Analysis of Hydrocarbon Emissions From Conventional Spark-Ignition Engines. Combustion Science and Technology 33:5-6, pages 245-260.
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F. FENDELL, S. FINK & P. FELDMAN. (1983) A Note on Unburned Hydrocarbon Emissions from Automotive Engines. Combustion Science and Technology 30:1-6, pages 47-57.
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E. W. KAISER, J. A. LORUSSO, G. A. LAVOIE & A. A. ADAMCZYK. (1982) The Effect of Oil Layers on the Hydrocarbon Emissions from Spark-Ignited Engines. Combustion Science and Technology 28:1-2, pages 69-73.
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Articles from other publishers (23)
P. A. Lakshminarayanan & Yogesh V. AghavP. A. Lakshminarayanan & Yogesh V. Aghav. 2022. Modelling Diesel Combustion. Modelling Diesel Combustion
199
223
.
Garima Kushwaha, Samir Saraswati & Bireswar Paul PhD. Effect of Ethanol-Gasoline Blends on Adsorption/Desorption Process in SI Engine. Effect of Ethanol-Gasoline Blends on Adsorption/Desorption Process in SI Engine.
Garima Kushwaha & Samir Saraswati. Effect of Different Fuels on the Unburned HC Emission from SI Engine: A Theoretical Study. Effect of Different Fuels on the Unburned HC Emission from SI Engine: A Theoretical Study.
M. N. A. M. Yusoff, N. W. M. Zulkifli, B. M. Masum & H. H. Masjuki. (2015) Feasibility of bioethanol and biobutanol as transportation fuel in spark-ignition engine: a review. RSC Adv. 5:121, pages 100184-100211.
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P. A. Lakshminarayanan & Yoghesh V. AghavP. A. Lakshminarayanan & Yogesh V. Aghav. 2010. Modelling Diesel Combustion. Modelling Diesel Combustion
147
166
.
V. M. Salazar & J. B. Ghandhi. Discussion of the Role of Fuel-Oil Diffusion in the Hydrocarbon Emissions from a Small Engine. Discussion of the Role of Fuel-Oil Diffusion in the Hydrocarbon Emissions from a Small Engine.
S Yu & K Min. (2005) Effects of the oil and liquid fuel film on hydrocarbon emissions in spark ignition engines. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering 216:9, pages 759-771.
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S. Diana, V. Giglio, B. Iorio & G. Police. A Model Based Evaluation of Emissions for Manifold Injected SI Engines. A Model Based Evaluation of Emissions for Manifold Injected SI Engines.
K. Min & W. K. Cheng. (1998) Oil Layer as Source of Hydrocarbon Emissions in SI Engines. Journal of Engineering for Gas Turbines and Power 120:3, pages 669-677.
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Simone Hochgreb. 1998. Handbook of Air Pollution From Internal Combustion Engines. Handbook of Air Pollution From Internal Combustion Engines
118
170
.
Kent Frølund & Jesper Schramm. Simulation of HC-Emissions from SI-Engines - A Parametric Study. Simulation of HC-Emissions from SI-Engines - A Parametric Study.
A Thomson, C. D. Radcliffe & C. M. Taylor. (2005) The influence of piston ring tribology on the diffusion of fuel through oil films. Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology 211:3, pages 223-233.
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J. R. Sodré & D. A. Yates. An Improved Model for Spark Ignition Engine Exhaust Hydrocarbons. An Improved Model for Spark Ignition Engine Exhaust Hydrocarbons.
D J Boam, I C Finlay, T W Biddulph, T A Ma, R Lee, S H Richardson, J Bloomfleld, J A Green, S Wallace, W A Woods & P Brown. (2016) The Sources of Unburnt Hydrocarbon Emissions from Spark Ignition Engines during Cold Starts and Warm-Up. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering 208:1, pages 1-11.
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Junya Tanaka & Koji Korematsu. Study on Oxidation Processes of Unburnt HC in Exhaust System of Spark Ignition Engines. Study on Oxidation Processes of Unburnt HC in Exhaust System of Spark Ignition Engines.
F. H. Trinker, J. Cheng & G. C. Davis. A Feedgas HC Emission Model for SI Engines Including Partial Burn Effects. A Feedgas HC Emission Model for SI Engines Including Partial Burn Effects.
Hiroyuki Nagaki & Koji Korematsu. Effect of Sulfur Dioxide Added to Induction Air on Wear of Diesel Engine. Effect of Sulfur Dioxide Added to Induction Air on Wear of Diesel Engine.
Scott Seegmiller. Examination of Hydrocarbon Emission Mechanisms in a Flame Propagation Engine Model. Examination of Hydrocarbon Emission Mechanisms in a Flame Propagation Engine Model.
Hiroyuki Nagaki & Koji Korematsu. Relation Between Diffusion Process of Sulfur Oxides in Exhaust Gas into Oil Film and Wear of Cylinder Liner and Piston Rings in Diesel Engines. Relation Between Diffusion Process of Sulfur Oxides in Exhaust Gas into Oil Film and Wear of Cylinder Liner and Piston Rings in Diesel Engines.
Andrew A. Adamczyk & Raymond A. Kach. (1985) A combustion bomb study of fuel-oil solubility and HC emissions from oil layers. Symposium (International) on Combustion 20:1, pages 37-43.
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A. C. Alkidas. Hydrocarbon Emissions from a Single-Cylinder, Divided-Chamber Diesel Engine. Hydrocarbon Emissions from a Single-Cylinder, Divided-Chamber Diesel Engine.
J. C. Dent & P. A. Lakshminarayanan. A Model for Absorption and Desorption of Fuel Vapour by Cylinder Lubricating Oil Films and Its Contribution to Hydrocarbon Emissions. A Model for Absorption and Desorption of Fuel Vapour by Cylinder Lubricating Oil Films and Its Contribution to Hydrocarbon Emissions.
Thompson M. Sloane & Andrew Y. Schoene. (1983) Combutational studies of end-wall flame quenching at low pressure: The effects of heterogeneous radical recombination and crevices. Combustion and Flame 49:1-3, pages 109-122.
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