Numerical Analysis of Momentum, Heat and Mass Transfer Between a Nitrogen Plasma Jet and B2o3 Particles Injected in An Axisymmetric Reactor
Abstract
For thermal plasma processing of solid particles (including processes like plasma spraying, spheroidizing, decomposition, melting or fuming of fine particles, synthesis of ultrafine particles, etc.) injection and mixing, i.e. momentum, heat and mass transfer between solid particles and plasma flow is of great importance for the quality of the product. There are numerous effects involved in plasma-particle interactions. Effects have different ranges of influence in particular plasma process or reactor. This paper present the results of a numerical analysis of the evaporation and decomposition of B2O3 powder (with particle diameter less than 100 mu m) injected in a nitrogen plasma axisymmetric, shielded reactor. This analysis serves as a basis for the optimization of the plasma reactor parameters, used for the plasma synthesis of BN ultrafine powder or boron powder production when B2O3 powder is used as a precursor. The computed fields of stream function and plasma temperature, particle ...trajectories and some parameters (plasma and particle temperature, particle Re, Nu and Kn* numbers, influence of evaporation and noncontinuum effects on momentum heat and mass transfer and instantaneous particle diameter) along particle trajectories are presented and discussed.
Keywords:
nitrogen plasma / B2O3 particles / particle evaporation / numerical analysis / transfer plasma particlesSource:
High Temperature Material Processes, 2010, 14, 4, 353-365Funding / projects:
- Scientific Fund of the Republic of Serbia
DOI: 10.1615/HighTempMatProc.v14.i4.50
ISSN: 1093-3611
WoS: 000208292500005
Scopus: 2-s2.0-84870385492
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VinčaTY - JOUR AU - Stefanović, Predrag Lj. AU - Cvetinović, Dejan AU - Pavlović, Pavle B. AU - Kostić, Života PY - 2010 UR - https://vinar.vin.bg.ac.rs/handle/123456789/2561 AB - For thermal plasma processing of solid particles (including processes like plasma spraying, spheroidizing, decomposition, melting or fuming of fine particles, synthesis of ultrafine particles, etc.) injection and mixing, i.e. momentum, heat and mass transfer between solid particles and plasma flow is of great importance for the quality of the product. There are numerous effects involved in plasma-particle interactions. Effects have different ranges of influence in particular plasma process or reactor. This paper present the results of a numerical analysis of the evaporation and decomposition of B2O3 powder (with particle diameter less than 100 mu m) injected in a nitrogen plasma axisymmetric, shielded reactor. This analysis serves as a basis for the optimization of the plasma reactor parameters, used for the plasma synthesis of BN ultrafine powder or boron powder production when B2O3 powder is used as a precursor. The computed fields of stream function and plasma temperature, particle trajectories and some parameters (plasma and particle temperature, particle Re, Nu and Kn* numbers, influence of evaporation and noncontinuum effects on momentum heat and mass transfer and instantaneous particle diameter) along particle trajectories are presented and discussed. T2 - High Temperature Material Processes T1 - Numerical Analysis of Momentum, Heat and Mass Transfer Between a Nitrogen Plasma Jet and B2o3 Particles Injected in An Axisymmetric Reactor VL - 14 IS - 4 SP - 353 EP - 365 DO - 10.1615/HighTempMatProc.v14.i4.50 ER -
@article{ author = "Stefanović, Predrag Lj. and Cvetinović, Dejan and Pavlović, Pavle B. and Kostić, Života", year = "2010", abstract = "For thermal plasma processing of solid particles (including processes like plasma spraying, spheroidizing, decomposition, melting or fuming of fine particles, synthesis of ultrafine particles, etc.) injection and mixing, i.e. momentum, heat and mass transfer between solid particles and plasma flow is of great importance for the quality of the product. There are numerous effects involved in plasma-particle interactions. Effects have different ranges of influence in particular plasma process or reactor. This paper present the results of a numerical analysis of the evaporation and decomposition of B2O3 powder (with particle diameter less than 100 mu m) injected in a nitrogen plasma axisymmetric, shielded reactor. This analysis serves as a basis for the optimization of the plasma reactor parameters, used for the plasma synthesis of BN ultrafine powder or boron powder production when B2O3 powder is used as a precursor. The computed fields of stream function and plasma temperature, particle trajectories and some parameters (plasma and particle temperature, particle Re, Nu and Kn* numbers, influence of evaporation and noncontinuum effects on momentum heat and mass transfer and instantaneous particle diameter) along particle trajectories are presented and discussed.", journal = "High Temperature Material Processes", title = "Numerical Analysis of Momentum, Heat and Mass Transfer Between a Nitrogen Plasma Jet and B2o3 Particles Injected in An Axisymmetric Reactor", volume = "14", number = "4", pages = "353-365", doi = "10.1615/HighTempMatProc.v14.i4.50" }
Stefanović, P. Lj., Cvetinović, D., Pavlović, P. B.,& Kostić, Ž.. (2010). Numerical Analysis of Momentum, Heat and Mass Transfer Between a Nitrogen Plasma Jet and B2o3 Particles Injected in An Axisymmetric Reactor. in High Temperature Material Processes, 14(4), 353-365. https://doi.org/10.1615/HighTempMatProc.v14.i4.50
Stefanović PL, Cvetinović D, Pavlović PB, Kostić Ž. Numerical Analysis of Momentum, Heat and Mass Transfer Between a Nitrogen Plasma Jet and B2o3 Particles Injected in An Axisymmetric Reactor. in High Temperature Material Processes. 2010;14(4):353-365. doi:10.1615/HighTempMatProc.v14.i4.50 .
Stefanović, Predrag Lj., Cvetinović, Dejan, Pavlović, Pavle B., Kostić, Života, "Numerical Analysis of Momentum, Heat and Mass Transfer Between a Nitrogen Plasma Jet and B2o3 Particles Injected in An Axisymmetric Reactor" in High Temperature Material Processes, 14, no. 4 (2010):353-365, https://doi.org/10.1615/HighTempMatProc.v14.i4.50 . .