Dynamic heating and thermal destruction conditions of quartz particles in polydisperse plasma flow of RF-ICP torch system

L MIAO; Yu M GRISHIN

doi:10.1088/2058-6272/abad1a

Plasma Science and Technology > 2020 > 22(11): 115505. > DOI: 10.1088/2058-6272/abad1a

L MIAO, Yu M GRISHIN. Dynamic heating and thermal destruction conditions of quartz particles in polydisperse plasma flow of RF-ICP torch system[J]. Plasma Science and Technology, 2020, 22(11): 115505. DOI: 10.1088/2058-6272/abad1a

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Dynamic heating and thermal destruction conditions of quartz particles in polydisperse plasma flow of RF-ICP torch system

Department of Thermophysics, Moscow State Technical University N E Bauman, Moscow 105005, Russia

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Received Date: March 24, 2020
Revised Date: August 04, 2020
Accepted Date: August 05, 2020

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Abstract

Abstract

Numerical simulation of turbulent mixing process of polydisperse quartz particle (particle size distribution in the range of 0.1–0.4 mm) flow with Ar and Ar-H₂ plasma generated by radio frequency inductively coupled plasma (RF-ICP) torch has been made. An approximate two-stage approach has been proposed to calculate the spatial–temporal distributions of temperature and resulting thermal stress in quartz particles during dynamic heating in polydisperse plasma flow. The influence of working gas compositions, particle size distributions, injection angle and flow rate of carrier gas on the thermal destruction conditions of quartz particles has been determined under different particle feed rates. It is found that all the solid quartz particles (0.1–0.4 mm) could be thermal destructed without overheating in RF-ICP torch system, when the hydrogen volume fraction in working gases is more than 1.5%–2% and particle feed rate is in a certain range. The values of the maximum and minimum feed rates have been determined under different hydrogen volume fractions. An optimal particle injection angle and flow rate of carrier gas is found around 50°–60° and 160–220 slpm, under which the value of maximum equivalent thermal stress in quartz particles is highest.
- RF-ICP torch,
- dynamic heating,
- thermal destruction,
- hydrogen volume fraction,
- optimal injection conditions

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References (50)

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