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Experimental Heat Transfer
A Journal of Thermal Energy Generation, Transport, Storage, and Conversion
Volume 19, 2006 - Issue 1
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Original Articles

Influence of Burner Geometry on Heat Transfer Characteristics of Methane/Air Flame Impinging on Flat Surface

Subhash Chander Department of Mechanical Engineering, Indian Institute of Technology, New Delhi, Delhi, India
&
Anjan Ray Department of Mechanical Engineering, Indian Institute of Technology, New Delhi, Delhi, India
Pages 15-38 | Received 02 Feb 2005, Accepted 26 Apr 2005, Published online: 20 Aug 2006

Citations (39)

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Read on this site (1)

C. Saha, R. Ganguly & A. Datta. (2008) Heat Transfer and Emission Characteristics of Impinging Rich Methane and Ethylene Jet Flames. Experimental Heat Transfer 21:3, pages 169-187.
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Articles from other publishers (38)

Jinpeng Hua, Jianfeng Pan, Feiyang Li, Baowei Fan, Zhongjia Li & Abiodun Oluwaleke Ojo. (2023) Heat transfer characteristics of premixed methane-air flame jet impinging on a hemispherical surface. Fuel 343, pages 127698.
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Kadali Dinesh, Parampreet Singh, Jithin E. V.V. Ratna Kishore & Subhash Chander. (2022) Impingement Heating Characteristics of Domestic Gas Burner Flames. Heat and Mass Transfer 59:6, pages 1093-1107.
Crossref
Kishore Ranganath Ramakrishnan, Shoaib Ahmed & Srinath V. Ekkad. (2022) Characterization of Transient Wall Heat Load for a Low NOx Lean Premixed Swirl Stabilized Can Combustor Under Reacting Conditions. Journal of Thermal Science and Engineering Applications 14:2.
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Saúl Laguillo, José Salvador Ochoa, Eduardo Tizné, Antonio Pina, Javier Ballester & Alfredo Ortiz. (2021) CO emissions and temperature analysis from an experimental and numerical study of partially premixed methane flames impinging onto a cooking pot. Journal of Natural Gas Science and Engineering 88, pages 103771.
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Feiyang Li, Jianfeng Pan, Chenxin Zhang, Evans K. Quaye & Xia Shao. (2021) Structure and Combustion Characteristics of Methane/Air Premixed Flame under the Action of Wall. Energy Engineering 118:4, pages 1135-1154.
Crossref
H.S. Zhen, Z.W. Wang, X.Y. Liu, Z.L. Wei, C.W. Leung & Z.H. Huang. (2021) A study on impingement heat transfer characteristics of partially premixed flames on double-concentric-pipe burner. Fuel 284, pages 119018.
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Girish Sapra & Subhash Chander. (2020) Effect of operating and geometrical parameters of tangential entry type dual swirling flame burner on impingement heat transfer. Applied Thermal Engineering 181, pages 115936.
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Ritesh Kumar Parida, Vasudeva Madav & Vijaykumar Hindasageri. (2020) Analytical solution to transient inverse heat conduction problem using Green’s function. Journal of Thermal Analysis and Calorimetry 141:6, pages 2391-2404.
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Liang Zhong, Gaofeng Wang, Yifan Xia, Guohan Cai, Shuai Liu, Ling Li, Yu Yu & Junmei Zheng. (2019) Investigation of heating characteristics of domestic gas cookers via a methodology of infrared thermography. Heat and Mass Transfer 55:12, pages 3561-3574.
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H.S. Zhen, L. Zhang, Z.L. Wei, Z.B. Chen & Z.H. Huang. (2019) A numerical study of the heat transfer of an impinging round-jet methane Bunsen flame. Fuel 251, pages 730-738.
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Pramod Kuntikana & S. V. Prabhu. (2018) Impinging premixed methane-air flame jet of tube burner: thermal performance analysis for varied equivalence ratios. Heat and Mass Transfer 55:5, pages 1301-1315.
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Farnaz Beygi-Khosroshahi, Ehsan Houshfar, Vahid Yousefi-Asli & Mehdi Ashjaee. (2019) Experimental investigation on heat transfer characteristics of partially premixed round methane-air impinging flame jet using Mach-Zehnder interferometry. International Journal of Thermal Sciences 137, pages 601-615.
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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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D. Höser & Ph. Rudolf von Rohr. (2018) Experimental heat transfer study of confined flame jet impinging on a flat surface. Experimental Thermal and Fluid Science 91, pages 166-174.
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Pramod Kuntikana & S.V. Prabhu. (2017) Effect of mixture composition on heat transfer characteristics of impinging methane-air flame jets of tube burners equipped with twisted tapes. International Journal of Thermal Sciences 111, pages 409-422.
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Pramod Kuntikana & S.V. Prabhu. (2016) Heat transfer characteristics of premixed methane–air flame jet impinging obliquely onto a flat surface. International Journal of Heat and Mass Transfer 101, pages 133-146.
Crossref
Pramod Kuntikana & S.V. Prabhu. (2016) Air jet impingement technique for thermal characterisation of premixed methane–air impinging flame jets. Applied Thermal Engineering 99, pages 905-918.
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Pramod Kuntikana & S.V. Prabhu. (2016) Isothermal air jet and premixed flame jet impingement: Heat transfer characterisation and comparison. International Journal of Thermal Sciences 100, pages 401-415.
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Anil R. Kadam, Abdul Raouf Tajik & Vijaykumar Hindasageri. (2016) Heat transfer distribution of impinging flame and air jets – A comparative study. Applied Thermal Engineering 92, pages 42-49.
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Vijaykumar Hindasageri, Rajendra P. Vedula & Siddini V. Prabhu. (2015) Heat transfer distribution of swirling flame jet impinging on a flat plate using twisted tapes. International Journal of Heat and Mass Transfer 91, pages 1128-1139.
Crossref
Vijaykumar Hindasageri, Rajendra P. Vedula & Siddini V. Prabhu. (2015) Heat transfer distribution for three interacting methane–air premixed impinging flame jets. International Journal of Heat and Mass Transfer 88, pages 914-925.
Crossref
Vijaykumar Hindasageri, Pramod Kuntikana, Rajendra P. Vedula & Siddini V. Prabhu. (2015) An experimental and numerical investigation of heat transfer distribution of perforated plate burner flames impinging on a flat plate. International Journal of Thermal Sciences 94, pages 156-169.
Crossref
Abdul Raouf Tajik, Pramod Kuntikana, Siddini V. Prabhu & Vijaykumar Hindasageri. (2015) Effect of preheated mixture on heat transfer characteristics of impinging methane–air premixed flame jet. International Journal of Heat and Mass Transfer 86, pages 550-562.
Crossref
Satpal Singh & Subhash Chander. (2015) Heat transfer characteristics of dual swirling flame impinging on a flat surface. International Journal of Thermal Sciences 89, pages 1-12.
Crossref
Vijaykumar Hindasageri, Rajendra P. Vedula & Siddini V. Prabhu. (2014) Heat transfer distribution for impinging methane–air premixed flame jets. Applied Thermal Engineering 73:1, pages 461-473.
Crossref
Satpal Singh & Subhash Chander. (2014) Heat transfer characteristics of dual flame with outer swirling and inner non-swirling flame impinging on a flat surface. International Journal of Heat and Mass Transfer 77, pages 995-1007.
Crossref
Vijaykumar Hindasageri, Rajendra P. Vedula & Siddini V. Prabhu. (2014) A novel method of estimation of adiabatic wall temperature for impinging premixed flame jets. International Journal of Heat and Mass Transfer 77, pages 185-193.
Crossref
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.
Crossref
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 I: Characteristics of Combustion . Transactions of the Korean hydrogen and new energy society 25:1, pages 47-58.
Crossref
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.
Crossref
H.B. Li, H.S. Zhen, C.W. Leung & C.S. Cheung. (2011) Nozzle effect on heat transfer and CO emission of impinging premixed flames. International Journal of Heat and Mass Transfer 54:1-3, pages 625-635.
Crossref
Mohamed Salem, Susanne Staude, Ulf Bergmann & Burak Atakan. (2010) Heat flux measurements in stagnation point methane/air flames with thermographic phosphors. Experiments in Fluids 49:4, pages 797-807.
Crossref
H.B. Li, H.S. Zhen, C.W. Leung & C.S. Cheung. (2010) Effects of plate temperature on heat transfer and emissions of impinging flames. International Journal of Heat and Mass Transfer 53:19-20, pages 4176-4184.
Crossref
Ho-Chuan Lin, Tsarng-Sheng Cheng, Bi-Chian Chen, Chun-Chin Ho & Yei -Chin Chao. (2009) A comprehensive study of two interactive parallel premixed methane flames on lean combustion. Proceedings of the Combustion Institute 32:1, pages 995-1002.
Crossref
Subhash Chander & Anjan Ray. (2008) An experimental and numerical study of stagnation point heat transfer for methane/air laminar flame impinging on a flat surface. International Journal of Heat and Mass Transfer 51:13-14, pages 3595-3607.
Crossref
Subhash Chander & Anjan Ray. (2007) Heat transfer characteristics of laminar methane/air flame impinging normal to a cylindrical surface. Experimental Thermal and Fluid Science 32:2, pages 707-721.
Crossref
Xi Jiang, Hua Zhao & Kai H. Luo. (2007) Direct Numerical Simulation of a Non-Premixed Impinging Jet Flame. Journal of Heat Transfer 129:8, pages 951-957.
Crossref
Subhash Chander & Anjan Ray. (2007) Heat transfer characteristics of three interacting methane/air flame jets impinging on a flat surface. International Journal of Heat and Mass Transfer 50:3-4, pages 640-653.
Crossref

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