Advanced search
Publication Cover
Combustion Science and Technology Volume 176, 2004 - Issue 7
Submit an article Journal homepage
585
Views
28
CrossRef citations to date
0
Altmetric
Original Articles

NONCATALYTIC PARTIAL OXIDATION OF METHANE INTO SYNGAS OVER A WIDE TEMPERATURE RANGE

ALEXANDER A. KONNOV Department of Mechanical Engineering, Brussels, Belgium
,
JIAN NING ZHU Centre for Fuels and Energy, Perth, Australia
,
JOHN H. BROMLY Centre for Fuels and Energy, Perth, Australia
&
DONG-KE ZHANG Centre for Fuels and Energy, Perth, Australia
Pages 1093-1116 | Received 01 Jul 2003, Accepted 01 Nov 2003, Published online: 11 Aug 2010

Citations (28)

Keep up to date with the latest research on this topic with citation updates for this article.

Subscribe to citation updates

Read on this site (4)

Yefei Liu, Qi Zhang & Tiefeng Wang. (2017) Detailed Chemistry Modeling of Partial Combustion of Natural Gas for Coproducing Acetylene and Syngas. Combustion Science and Technology 189:5, pages 908-922.
Read now
Monika Zajemska, Dorota Musiał & Anna Poskart. (2014) Application of CHEMKIN and COMSOL Programs in the Calculations of Chemical Composition of Natural Gas Combustion Products. Combustion Science and Technology 186:2, pages 153-172.
Read now
A. A. Konnov, G. Puig Álvarez, I. V. Rybitskaya & J. De Ruyck. (2008) The Effects of Enrichment by Carbon Monoxide on Adiabatic Burning Velocity and Nitric Oxide Formation in Methane Flames. Combustion Science and Technology 181:1, pages 117-135.
Read now
Tanh Le Cong & Philippe Dagaut. (2008) Experimental and Detailed Kinetic Modeling of the Oxidation of Methane and Methane/Syngas Mixtures and Effect of Carbon Dioxide Addition. Combustion Science and Technology 180:10-11, pages 2046-2091.
Read now

Articles from other publishers (24)

Uri Zamir, Joshua H. Baraban, Peter Fjodorow & Igor Rahinov. (2024) Intracavity laser absorption spectroscopy: Performance and advantages for energy science. Applications in Energy and Combustion Science 17, pages 100251.
Crossref
Iren A. Makaryan, Eugene A. Salgansky, Vladimir S. Arutyunov & Igor V. Sedov. (2023) Non-Catalytic Partial Oxidation of Hydrocarbon Gases to Syngas and Hydrogen: A Systematic Review. Energies 16:6, pages 2916.
Crossref
Sirui Tong, Bin Miao, Lan Zhang & Siew Hwa Chan. (2022) Decarbonizing Natural Gas: A Review of Catalytic Decomposition and Carbon Formation Mechanisms. Energies 15:7, pages 2573.
Crossref
Igor V. Zagaynov. (2021) Active Components of Catalysts of Methane Conversion to Synthesis Gas: Brief Perspectives. Energy & Fuels 35:11, pages 9124-9136.
Crossref
Te-Chun Chu, Zachary J. Buras, Patrick Oßwald, Mengjie Liu, Mark Jacob Goldman & William H. Green. (2019) Modeling of aromatics formation in fuel-rich methane oxy-combustion with an automatically generated pressure-dependent mechanism. Physical Chemistry Chemical Physics 21:2, pages 813-832.
Crossref
Chao'en Li, Benny Kuan, Woo Jin Lee, Nick Burke & Jim Patel. (2018) The non-catalytic partial oxidation of methane in a flow tube reactor using indirect induction heating – An experimental and kinetic modelling study. Chemical Engineering Science 187, pages 189-199.
Crossref
Soumya Gudiyella, Zachary J. Buras, Te-Chun Chu, Istvan Lengyel, Sreekanth Pannala & William H. Green. (2018) Modeling Study of High Temperature Pyrolysis of Natural Gas. Industrial & Engineering Chemistry Research 57:22, pages 7404-7420.
Crossref
Alexey Fomin, Tatyana Zavlev, Vladimir A. Alekseev, Igor Rahinov, Sergey Cheskis & Alexander A. Konnov. (2016) Experimental and modelling study of 1CH2 in premixed very rich methane flames. Combustion and Flame 171, pages 198-210.
Crossref
Markus Köhler, Patrick Oßwald, Hongbin Xu, Trupti Kathrotia, Christian Hasse & Uwe Riedel. (2016) Speciation data for fuel-rich methane oxy-combustion and reforming under prototypical partial oxidation conditions. Chemical Engineering Science 139, pages 249-260.
Crossref
Alexey Fomin, Tatyana Zavlev, Vladimir A. Alekseev, Alexander A. Konnov, Igor Rahinov & Sergey Cheskis. (2015) Intracavity Laser Absorption Spectroscopy Study of HCO Radicals during Methane to Hydrogen Conversion in Very Rich Flames. Energy & Fuels 29:9, pages 6146-6154.
Crossref
Chao’en Li, Nick Burke, Karl Gerdes & Jim Patel. (2013) The undiluted, non-catalytic partial oxidation of methane in a flow tube reactor – An experimental study using indirect induction heating. Fuel 109, pages 409-416.
Crossref
Ajay Pratap Singh & Michael Nikolaou. (2013) Control of a process with unmeasured disturbances that change its steady-state gain sign. Journal of Process Control 23:3, pages 294-305.
Crossref
Wenyuan Guo, Yanzeng Wu, Liang Dong, Caixia Chen & Fuchen Wang. (2012) Simulation of non-catalytic partial oxidation and scale-up of natural gas reformer. Fuel Processing Technology 98, pages 45-50.
Crossref
J. Zhang, V. Burklé-Vitzthum, P.M. Marquaire, G. Wild & J.M. Commenge. (2011) Direct conversion of methane in formaldehyde at very short residence time. Chemical Engineering Science 66:24, pages 6331-6340.
Crossref
Yefei Liu & Tiefeng Wang. (2011) Analysis of the Autoignition Process under the Industrial Partial Oxidation Conditions Using Detailed Kinetic Modeling. Industrial & Engineering Chemistry Research 50:10, pages 6009-6016.
Crossref
Felix Weinberg, Fred Carleton, Raphael Houdmont, Derek Dunn-Rankin & Sunny Karnani. (2011) Syngas formation in methane flames and carbon monoxide release during quenching. Combustion and Flame 158:2, pages 273-280.
Crossref
Sanghyun Han, Jungsoo Park, Soonho Song & Kwang Min Chun. (2010) Experimental and numerical study of detailed reaction mechanism optimization for syngas (H2 + CO) production by non-catalytic partial oxidation of methane in a flow reactor. International Journal of Hydrogen Energy 35:16, pages 8762-8771.
Crossref
J.M.C. Pereira, M.A.A. Mendes, D. Trimis & J.C.F. Pereira. (2010) Quasi-1D and 3D TPOX porous media diffuser reformer model. Fuel 89:8, pages 1928-1935.
Crossref
Su Cao, Dezheng Wang & Tiefeng Wang. (2010) Simulation of partial oxidation of natural gas with detailed chemistry: Influence of addition of H2, C2H6 and C3H8. Chemical Engineering Science 65:8, pages 2608-2618.
Crossref
Xinwen Zhou, Caixia Chen & Fuchen Wang. (2010) Modeling of non-catalytic partial oxidation of natural gas under conditions found in industrial reformers. Chemical Engineering and Processing: Process Intensification 49:1, pages 59-64.
Crossref
A.A. Konnov. (2009) Implementation of the NCN pathway of prompt-NO formation in the detailed reaction mechanism. Combustion and Flame 156:11, pages 2093-2105.
Crossref
Christian Lund Rasmussen, Anja Egede Rasmussen & Peter Glarborg. (2008) Sensitizing effects of NOx on CH4 oxidation at high pressure. Combustion and Flame 154:3, pages 529-545.
Crossref
T. Le Cong, P. Dagaut & G. Dayma. (2008) Oxidation of Natural Gas, Natural Gas/Syngas Mixtures, and Effect of Burnt Gas Recirculation: Experimental and Detailed Kinetic Modeling. Journal of Engineering for Gas Turbines and Power 130:4.
Crossref
Alexander A. Konnov, Fred J. Barnes, John H. Bromly, Jian Ning Zhu & Dong-ke Zhang. (2005) The pseudo-catalytic promotion of nitric oxide oxidation by ethane at low temperatures. Combustion and Flame 141:3, pages 191-199.
Crossref

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.