THERMAL MODES IN FORMATION OF CARBON NANOMATERIAL UNDER CONDITIONS OF HIGH-VOLTAGE ATMOSPHERIC PRESSURE DISCHARGE

被引:0
作者
Borisevich, K. O. [1 ]
Chernukho, A. P. [1 ]
Zhdanok, S. A. [1 ]
机构
[1] Adv Res & Technol LLC, 2a Tolbukhin Str,Room 7, Minsk 220012, BELARUS
来源
HIGH TEMPERATURE MATERIAL PROCESSES | 2019年 / 23卷 / 02期
关键词
carbon nanotubes; decomposition of hydrocarbons; high-voltage discharge of atmospheric pressure; carbon nanofibers; SYNGAS PRODUCTION; DECOMPOSITION; EFFICIENCY; CONVERSION; METHANE; PLASMA;
D O I
10.1615/HighTempMatProc.2019030532
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
This paper contains the results of an experimental study and simulation of physical and chemical processes of decomposition of a methane mixture with air in a high-voltage discharge plasma of atmospheric pressure. The results of comparison of the two-dimensional model of the process with experimental points are given for varying discharge parameters and the relative methane content in the working mixture. Under the conditions of a real experiment, the temperature profiles and concentration distributions of the reaction products in the discharge zone, as well as the evolution of the gas mixture composition in the course of conversion, were obtained by means of modeling. On the basis of the research carried out, conclusions were made about the influence of the thermal modes of the process on the formation of carbon nonmaterial.
引用
收藏
页码:121 / 155
页数:35
相关论文
共 20 条
[1]   SYNGAS PRODUCTION IN METHANE DECOMPOSITION IN THE PLASMA OF ATMOSPHERIC PRESSURE HIGH-VOLTAGE DISCHARGE [J].
Al-Mayman, Sulaiman, I ;
Al-Johani, Meshal S. ;
Borisevich, Kirill O. ;
Al-Musa, Abdullah A. ;
Al-Abbadi, Naif M. ;
Krauklis, Andrey, V ;
Stanovoi, Pavel G. .
HEAT TRANSFER RESEARCH, 2018, 49 (12) :1119-1129
[2]   SYNGAS PRODUCTION FROM PROPANE-BUTANE MIXTURES USING A HIGH-VOLTAGE ATMOSPHERIC PRESSURE DISCHARGE PLASMA [J].
Alenazey, Feraih Sh. ;
Al-Harbi, Ahmed A. ;
Chernukho, A. ;
Dmitrenko, Yu. ;
Migoun, A. ;
Zhdanok, S. .
HEAT TRANSFER RESEARCH, 2016, 47 (11) :1057-1072
[3]   Atmospheric pressure glow discharge in air used for ethanol conversion: experiment and modelling [J].
Arkhipenko, Valery I. ;
Kirillov, Andrey A. ;
Simonchik, Leanid V. ;
Safronau, Yauhen A. ;
Chernukho, Andrey P. ;
Migoun, Aleksey N. .
OPEN CHEMISTRY, 2015, 13 (01) :292-296
[4]   THERMOPHYSICAL CONDITIONS OF CARBON NANOMATERIAL FORMATION DURING DECOMPOSITION OF METHANE IN A HIGH-VOLTAGE ATMOSPHERIC PRESSURE DISCHARGE PLASMA [J].
Borisevich, K. O. ;
Chernukho, A. P. ;
Zhdanok, S. A. ;
Migoun, A. N. .
HIGH TEMPERATURE MATERIAL PROCESSES, 2018, 22 (04) :293-313
[5]  
Buyanov RA, 2005, CHEM SUSTAIN DEV, V13, P37
[6]   Simulation of perfluoromethane decomposition in an atmospheric-pressure microwave discharge [J].
Chernukho A.P. ;
Migun A.N. ;
Zhdanok S.A. ;
Rostaing J.C. ;
Perrin J. .
Journal of Engineering Physics and Thermophysics, 2005, 78 (2) :394-404
[7]   Nucleation in a catalytic nanodroplet and growth of nanowires [J].
Fisenko, S. P. ;
Borovik, F. N. .
TECHNICAL PHYSICS, 2009, 54 (02) :246-252
[8]  
Grabke H.J., 2002, MATER TEHNOL, V36, P297
[9]   Model of cellular instability of flames of ternary mixtures [J].
Konnov, AA .
COMBUSTION EXPLOSION AND SHOCK WAVES, 2005, 41 (05) :496-503
[10]  
Migoun A.N., 2005, THERMAL PHYS KINETIC
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