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Combustion Science and Technology Volume 18, 1978 - Issue 3-4
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Original Articles

Heat Transfer From Normally Impinging Flames

J. K. KILHAM Department of Fuel and Combustion Science, University of Leeds, Leeds, Yorkshire, England
&
M. R. I. PURVIS Department of Fuel and Combustion Science, University of Leeds, Leeds, Yorkshire, England
Pages 81-90 | Received 18 Aug 1977, Accepted 23 Jan 1978, Published online: 16 May 2007

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Read on this site (5)

Subhash Chander & Anjan Ray. (2006) Influence of Burner Geometry on Heat Transfer Characteristics of Methane/Air Flame Impinging on Flat Surface. Experimental Heat Transfer 19:1, pages 15-38.
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Rémi Loubat, Philippe Reulet, Bruno Estebe & Pierre Millan. (2004) Heat flux characterisation in hot jet and flame/wall interaction by IHCP resolution coupled with infrared measurements. Quantitative InfraRed Thermography Journal 1:2, pages 205-228.
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C. E. BAUKAL & B. GEBHART. (1995) A Review of Flame Impingement Heat Transfer Studies Part 2: Measurements. Combustion Science and Technology 104:4-6, pages 359-385.
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C. E. BAUKAL & B. GEBHART. (1995) A Review of Flame Impingement Heat Transfer Studies Part 1: Experimental Conditions. Combustion Science and Technology 104:4-6, pages 339-357.
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M. FAIRWEATHER, J. K. KILHAM & A. MOHEBI-ASHTIANI. (1983) Stagnation Point Heat Transfer from Turbulent Methane-Air Flames. Combustion Science and Technology 35:5-6, pages 225-238.
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Articles from other publishers (27)

Xinchun Tian, Deyny L. Mendivelso-Perez, Souvik Banerjee, Emily A. Smith & Ludovico Cademartiri. (2019) Self-Limiting Processes in the Flame-Based Fabrication of Superhydrophobic Surfaces from Silicones. ACS Applied Materials & Interfaces 11:32, pages 29231-29241.
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Ritesh Kumar Parida, Anil R. Kadam, Vijaykumar Hindasageri & M. Vasudeva. 2019. Numerical Heat Transfer and Fluid Flow. Numerical Heat Transfer and Fluid Flow 385 391 .
Vinay C. Raj, Pramod Kuntikana, S. Sreedhara & S.V. Prabhu. (2018) Separation of heat transfer components from impinging methane diffusion flames. International Journal of Heat and Mass Transfer 126, pages 123-138.
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Pramod Kuntikana & S.V. Prabhu. (2018) Heat transfer investigations on methane-air premixed flame jet exiting from a circular nozzle and impinging over semi-cylindrical surfaces. International Journal of Thermal Sciences 128, pages 105-123.
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Keunseon Sim, Byeonggyu Jeong, Yongho Lee & Keeman Lee. (2014) A Study on Combustion and Heat Transfer in Premixed Impinging Flames of Syngas(H 2 /CO)/Air Part II: Heat Transfer Characteristics . Transactions of the Korean hydrogen and new energy society 25:1, pages 59-71.
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Jay Karan. 2012. The John Zink Hamworthy Combustion Handbook, Second Edition. The John Zink Hamworthy Combustion Handbook, Second Edition 159 205 .
L.L. Dong, C.S. Cheung & C.W. Leung. (2011) Combustion optimization of a port-array inverse diffusion flame jet. Energy 36:5, pages 2834-2846.
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H.S. Zhen, C.W. Leung & C.S. Cheung. (2011) Emission of impinging swirling and non-swirling inverse diffusion flames. Applied Energy 88:5, pages 1629-1634.
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Subhash Chander & Anjan Ray. (2011) Experimental and numerical study on the occurrence of off-stagnation peak in heat flux for laminar methane/air flame impinging on a flat surface. International Journal of Heat and Mass Transfer 54:5-6, pages 1179-1186.
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M.J. Remie, G. Särner, M.F.G. Cremers, A. Omrane, K.R.A.M. Schreel, L.E.M. Aldén & L.P.H. de Goey. (2008) Heat-transfer distribution for an impinging laminar flame jet to a flat plate. International Journal of Heat and Mass Transfer 51:11-12, pages 3144-3152.
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M.J. Remie, G. Särner, M.F.G. Cremers, A. Omrane, K.R.A.M. Schreel, M. Aldén & L.P.H. de Goey. (2008) Extended heat-transfer relation for an impinging laminar flame jet to a flat plate. International Journal of Heat and Mass Transfer 51:7-8, pages 1854-1865.
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L.L. Dong, C.S. Cheung & C.W. Leung. (2007) Heat transfer characteristics of an impinging inverse diffusion flame jet – Part I: Free flame structure. International Journal of Heat and Mass Transfer 50:25-26, pages 5108-5123.
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Subhash Chander & Anjan Ray. (2005) Flame impingement heat transfer: A review. Energy Conversion and Management 46:18-19, pages 2803-2837.
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Shuhn-Shyurng Hou & Yung-Chang Ko. (2005) Influence of oblique angle and heating height on flame structure, temperature field and efficiency of an impinging laminar jet flame. Energy Conversion and Management 46:6, pages 941-958.
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Shuhn-Shyurng Hou & Yung-Chang Ko. (2004) Effects of heating height on flame appearance, temperature field and efficiency of an impinging laminar jet flame used in domestic gas stoves. Energy Conversion and Management 45:9-10, pages 1583-1595.
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Meng Xian, Pan Wen-xia, Zhang Wen-hong & Wu Cheng-kang. (2001) Heat Flux Characterization of DC Laminar-plasma Jets Impinging on a Flat Plate at Atmospheric Pressure. Plasma Science and Technology 3:5, pages 953-958.
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C.E Baukal & B Gebhart. (1998) Heat transfer from oxygen-enhanced/natural gas flames impinging normal to a plane surface. Experimental Thermal and Fluid Science 16:3, pages 247-259.
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C.E. Baukal & B. Gebhart. (1997) Surface condition effects on flame impingement heat transfer. Experimental Thermal and Fluid Science 15:4, pages 323-335.
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Charles E. Baukal & Benjamin Gebhart. (1996) A review of semi-analytical solutions for flame impingement heat transfer. International Journal of Heat and Mass Transfer 39:14, pages 2989-3002.
Crossref
R. Viskanta. (1993) Heat transfer to impinging isothermal gas and flame jets. Experimental Thermal and Fluid Science 6:2, pages 111-134.
Crossref
M. Fairweather, J.K. Kilham & S. Nawaz. (1984) Stagnation point heat transfer from laminar, high temperature methane flames. International Journal of Heat and Fluid Flow 5:1, pages 21-27.
Crossref
G.K. Hargrave & J.K. Kilham. 1984. First U.K. National Conference on Heat Transfer. First U.K. National Conference on Heat Transfer 1025 1034 .
A.O. Hemeson, M.E. Horsley, M.R.I. Purvis & A.S. Tariq. 1984. First U.K. National Conference on Heat Transfer. First U.K. National Conference on Heat Transfer 969 978 .
Ferrers R. S. Clark. (2003) Ignition of poly(methyl methacrylate) slabs using a small flame. Journal of Polymer Science: Polymer Chemistry Edition 21:8, pages 2323-2334.
Crossref
P. Gateau, D. Puechberty, G. Gouesbet & M. Ledoux. (1980) A study of the boundary layer over a flat plate in an oxygen-natural gas flame. Combustion and Flame 38, pages 121-141.
Crossref
G. L. Borman. 1980. Combustion Modeling in Reciprocating Engines. Combustion Modeling in Reciprocating Engines 165 191 .
H. Z. You & G. M. Faeth. (2004) Ceiling heat transfer during fire plume and fire impingement. Fire and Materials 3:3, pages 140-147.
Crossref

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