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Combustion Science and Technology Volume 103, 1994 - Issue 1-6
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Original Articles

The Effects of Load Height on the Emissions from a Natural Gas-Fired Domestic Cooktop Burner

P. J. ASHMAN Department of Fuel Technology, School of Chemical Engineering and Industrial Chemistry, University of New South Wales, Sydney, NSW2052, Australia
,
R. JUNUS Department of Fuel Technology, School of Chemical Engineering and Industrial Chemistry, University of New South Wales, Sydney, NSW2052, Australia
,
J. F. STUBINGTON Department of Fuel Technology, School of Chemical Engineering and Industrial Chemistry, University of New South Wales, Sydney, NSW2052, Australia
&
G. D. SERGEANT Department of Fuel Technology, School of Chemical Engineering and Industrial Chemistry, University of New South Wales, Sydney, NSW2052, Australia
Pages 283-298 | Received 09 Mar 1994, Accepted 02 Aug 1994, Published online: 17 Apr 2007

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Ayten Yilmaz Wagner, Hans Livbjerg, Per Gravers Kristensen & Peter Glarborg. (2010) Particle Emissions from Domestic Gas Cookers. Combustion Science and Technology 182:10, pages 1511-1527.
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Mehdi Karzar Jeddi, Siamak Kazemzadeh Hannani & Bijan Farhanieh. (2004) STUDY OF MIXED-CONVECTION HEAT TRANSFER FROM AN IMPINGING JET TO A SOLID WALL USING A FINITE-ELEMENT METHOD—APPLICATION TO COOKTOP MODELING. Numerical Heat Transfer, Part B: Fundamentals 46:4, pages 387-397.
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Rosita Junus, JohnF. Stubington, GeoffreyD. Sergeant & Ibrahim Tas. (2000) Emissions and efficiency of a prototype natural gas‐fired domestic cooktop burner with insert. International Journal of Environmental Studies 57:2, pages 189-205.
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P. J. Ashman & B. S. Haynes. (1996) Formaldehyde Formation in Small Gas Burners. Combustion Science and Technology 116-117:1-6, pages 359-373.
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Articles from other publishers (33)

S. Rahul Kashyap, Santanu Pramanik & R.V. Ravikrishna. (2024) A review of energy-efficient domestic cookstoves. Applied Thermal Engineering 236, pages 121510.
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Wei Zhang, Yunzhe Wang, Jianyou Wang, Zihan Zhang & Zhaoliang Wang. (2023) Reducing kitchen gas consumption by designing a heat gathering shield with guide rings for a domestic gas stove. Energy and Buildings 296, pages 113384.
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Wenxue Gao, Yingjie Hu, Rongsong Yan, Wentao Yan, Mingchang Yang, Qingwei Miao, Lin Yang & Yan Wang. (2023) Comprehensive Review on Thermal Performance Enhancement of Domestic Gas Stoves. ACS Omega 8:30, pages 26663-26684.
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Kishan Dash & Sikata Samantaray. 2023. Recent Advances in Thermal Sciences and Engineering. Recent Advances in Thermal Sciences and Engineering 437 445 .
Yan Zhao, Vince McDonell & Scott Samuelsen. (2022) Residential Fuel Transition and Fuel Interchangeability in Current Self-Aspirating Combustion Applications: Historical Development and Future Expectations. Energies 15:10, pages 3547.
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Sai Sri Laxman Jangala, Venkat Siva Prasad Kakumani, Naga Sai Vunnam & P.S. Rama Sreekanth. (2022) A novel brass metal burner design for conventional LPG stove with convergent holes and swirl flow. Materials Today: Proceedings 56, pages 1068-1074.
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Jianyou Wang, Wei Zhang, Tao Yang, Yunzu Yu, Chuang Liu & Bin Li. (2022) Numerical and experimental investigation on heat transfer enhancement by adding fins on the pot in a domestic gas stove. Energy 239, pages 122439.
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Akanksha Mathur, Rohit Singh Lather, Vinit Chauhan, Rahul Sharma & Tushar Mehta. 2022. Computational and Experimental Methods in Mechanical Engineering. Computational and Experimental Methods in Mechanical Engineering 33 42 .
Amitava Datta, Mithun Das & Ranjan Ganguly. (2021) Design, Development, and Technological Advancements in Gas Burners for Domestic Cook Stoves: A Review. Transactions of the Indian National Academy of Engineering 6:3, pages 569-593.
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Gaurav Dwivedi, Pankaj P. Gohil & Arun Kumar Behura. (2021) Numerical investigation of thermodynamic parameters for performance evaluation of cooking gas stove burner by appending of flame shield. Materials Today: Proceedings 46, pages 5696-5702.
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Mithun Das. 2021. Advances in Thermal Engineering, Manufacturing, and Production Management. Advances in Thermal Engineering, Manufacturing, and Production Management 77 85 .
Guofeng Shen, Subinuer Ainiwaer, Yaqi Zhu, Shuxiu Zheng, Weiying Hou, Huizhong Shen, Yilin Chen, Xilong Wang, Hefa Cheng & Shu Tao. (2020) Quantifying source contributions for indoor CO2 and gas pollutants based on the highly resolved sensor data. Environmental Pollution 267, pages 115493.
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Mithun Das, Ranjan Ganguly, Amitava Datta, Meenam M. Verma & Ashis K. Bera. (2020) Computational Fluid Dynamic Analyses of Flow and Combustion in a Domestic Liquefied Petroleum Gas Cookstove Burner—Part II: Burning Characteristics and Overall Performance. Journal of Thermal Science and Engineering Applications 12:3.
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Dhananjay Singh Yadav & Bireswar Paul. 2020. Advances in Mechanical Engineering. Advances in Mechanical Engineering 921 930 .
Youngbo Won, Michael Waring & Donghyun Rim. (2019) Understanding the Spatial Heterogeneity of Indoor OH and HO 2 due to Photolysis of HONO Using Computational Fluid Dynamics Simulation . Environmental Science & Technology 53:24, pages 14470-14478.
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H E Saad, M Kamal & A Adel. (2019) Thermal and combustion characteristics of a double ring burner with different swirling flow patterns. IOP Conference Series: Materials Science and Engineering 610:1, pages 012042.
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Zhiguang Chen, Yangjun Zhang, Chaokui Qin & Pengfei Duan. (2019) Combustion performance of domestic gas cookers with swirling strip-port and normal round-port on various natural gas compositions. Case Studies in Thermal Engineering 13, pages 100366.
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Premananda Pradhan & Purna Chandra Mishra. (2018) Performance evaluation of novel surface flame self-aspirated porous radiant burners for cooking applications. Sādhanā 43:11.
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Ashraf Kotb & Hany Saad. (2018) Case study for co and counter swirling domestic burners. Case Studies in Thermal Engineering 11, pages 98-104.
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Guofeng Shen, Michael D. Hays, Kirk R. Smith, Craig Williams, Jerroll W. Faircloth & James J. Jetter. (2018) Evaluating the Performance of Household Liquefied Petroleum Gas Cookstoves. Environmental Science & Technology 52:2, pages 904-915.
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İ. Bedii Özdemir. (2017) Use of Computational Combustion in the Development and Design of Energy-Efficient Household Cooker-Top Burners. Journal of Energy Resources Technology 139:2.
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İ. Bedii Özdemir & Murat Kantaş. (2016) Investigation of partially-premixed combustion in a household cooker-top burner. Fuel Processing Technology 151, pages 107-116.
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Wojciech Jerzak & Monika Kuźnia. (2016) Experimental study of impact of swirl number as well as oxygen and carbon dioxide content in natural gas combustion air on flame flashback and blow-off. Journal of Natural Gas Science and Engineering 29, pages 46-54.
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Chih-Yung Wu, Kun-Ho Chen & Shou Yin Yang. (2014) Experimental study of porous metal burners for domestic stove applications. Energy Conversion and Management 77, pages 380-388.
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Shuhn-Shyurng Hou & Ching-Hung Chou. (2013) Parametric Study of High-Efficiency and Low-Emission Gas Burners. Advances in Materials Science and Engineering 2013, pages 1-7.
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Z. Zhao, T.T. Wong & C.W. Leung. (2008) Influences of material properties on thermal design of impinging flame jets. Materials & Design 29:1, pages 28-33.
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Shuhn-Shyurng Hou, Chien-Ying Lee & Ta-Hui Lin. (2007) Efficiency and emissions of a new domestic gas burner with a swirling flame. Energy Conversion and Management 48:5, pages 1401-1410.
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A.S. Langman, G.J. Nathan, J. Mi & P.J. Ashman. (2007) The influence of geometric nozzle profile on the global properties of a turbulent diffusion flame. Proceedings of the Combustion Institute 31:1, pages 1599-1607.
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H.B. Li, T.T. Wong, C.W. Leung & S.D. Probert. (2006) Thermal performances and CO emissions of gas-fired cooker-top burners. Applied Energy 83:12, pages 1326-1338.
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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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Z. Zhao, T.T. Wong & C.W. Leung. (2004) Impinging premixed butane/air circular laminar flame jet––influence of impingement plate on heat transfer characteristics. International Journal of Heat and Mass Transfer 47:23, pages 5021-5031.
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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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Yung-Chang Ko & Ta-Hui Lin. (2003) Emissions and efficiency of a domestic gas stove burning natural gases with various compositions. Energy Conversion and Management 44:19, pages 3001-3014.
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