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Combustion Science and Technology Volume 60, 1988 - Issue 1-3
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Original Articles

Laminar Burning Velocities of Stoichiometric Mixtures of Methane with Propane and Ethane Additives

P. G. HILL Department of Mechanical Engineering. The University of British Columbia., Vancouver, B.C., Canada. V6T 1W5
&
J. HUNG Department of Mechanical Engineering. The University of British Columbia., Vancouver, B.C., Canada. V6T 1W5
Pages 7-30 | Received 19 May 1987, Accepted 08 Mar 1988, Published online: 27 Apr 2007

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PHILIPPE DAGAUT, JEAN-CLAUDE BOETTNER & MICHEL CATHONNET. (1991) Methane Oxidation: Experimental and Kinetic Modeling Study. Combustion Science and Technology 77:1-3, pages 127-148.
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. 2012. Lees' Loss Prevention in the Process Industries. Lees' Loss Prevention in the Process Industries 3129 3580 .
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. 2005. Lees' Loss Prevention in the Process Industries. Lees' Loss Prevention in the Process Industries 201 250 .
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A Turbiez, A El Bakali, J.F Pauwels, A Rida & P Meunier. (2004) Experimental study of a low pressure stoichiometric premixed methane, methane/ethane, methane/ethane/propane and synthetic natural gas flames. Fuel 83:7-8, pages 933-941.
Crossref
A El Bakali, P Dagaut, L Pillier, P Desgroux, J.-F Pauwels, A Rida & P Meunier. (2004) Experimental and modeling study of the oxidation of natural gas in a premixed flame, shock tube, and jet-stirred reactor. Combustion and Flame 137:1-2, pages 109-128.
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D.P. Mishra. (2003) Effects of initial temperature on the structure of laminar CH4?air premixed flames?. Fuel 82:12, pages 1471-1475.
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R. Stone, A. Clarke & P. Beckwith. (1998) Correlations for the Laminar-Burning Velocity of Methane/Diluent/Air Mixtures Obtained in Free-Fall Experiments. Combustion and Flame 114:3-4, pages 546-555.
Crossref
A.A. Evans. (1994) Deflagrations in spherical vessels: A comparison among four approximate burning velocity formulae. Combustion and Flame 97:3-4, pages 429-434.
Crossref

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