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Visualization of low-density gas-dynamic objects in full-scale processes modelling on small experimental plants. / Zarvin, A. E.; Yaskin, A. S.; Dubrovin, K. A. et al.

In: Vacuum, Vol. 191, 110409, 09.2021.

Research output: Contribution to journalArticlepeer-review

Harvard

Zarvin, AE, Yaskin, AS, Dubrovin, KA & Kalyada, VV 2021, 'Visualization of low-density gas-dynamic objects in full-scale processes modelling on small experimental plants', Vacuum, vol. 191, 110409. https://doi.org/10.1016/j.vacuum.2021.110409

APA

Zarvin, A. E., Yaskin, A. S., Dubrovin, K. A., & Kalyada, V. V. (2021). Visualization of low-density gas-dynamic objects in full-scale processes modelling on small experimental plants. Vacuum, 191, [110409]. https://doi.org/10.1016/j.vacuum.2021.110409

Vancouver

Zarvin AE, Yaskin AS, Dubrovin KA, Kalyada VV. Visualization of low-density gas-dynamic objects in full-scale processes modelling on small experimental plants. Vacuum. 2021 Sept;191:110409. doi: 10.1016/j.vacuum.2021.110409

Author

Zarvin, A. E. ; Yaskin, A. S. ; Dubrovin, K. A. et al. / Visualization of low-density gas-dynamic objects in full-scale processes modelling on small experimental plants. In: Vacuum. 2021 ; Vol. 191.

BibTeX

@article{f0b89def02cf42b0b2dfecb880f8763e,
title = "Visualization of low-density gas-dynamic objects in full-scale processes modelling on small experimental plants",
abstract = "The developed and tested visualisation method of supersonic under-expanded gas jets expanding from sonic and supersonic nozzles (or nozzle blocks) into a rarefied medium (deep vacuum) with the background gas pressure range from 3 mPa to 1 Pa was presented. It was based on the use of a well-focused electron beam whose energy was on the order of 10 keV for glow initiation in a local volume of stationary gas jet. The radiation of the excited gas was read by the recorder (modern scanner) and converted into a digital code. The local gas density was determined using special calibration procedures and software. The flow field was scanned by a special device when moving the nozzle pre-chamber by a stepper motor with a coordinate mechanism relative to a stationary electron beam crossing the gas object perpendicular to its axis. Using optical lenses, luminescence from a localised jet volume was focused to the input aperture of a scanner. High-quality focusing of the electron beam along the investigated section of the gas flow and the dimensions of the scanning unit, exceeding the investigated size of the jet, provide registration of a section image of a gas flow along or across the flow axis with sufficient resolution. The advantages and practical perspectives of the method were reviewed based on the results of the visualisation of complex supersonic jets escaping from a block of several supersonic nozzles. The reliability of the information obtained is provided by control measurements of the local gas density distribution along the axis of the supersonic nitrogen flow expanding from the sonic nozzle in comparison with the available theoretical and experimental data.",
keywords = "Visualisation, Supersonic flow, Supersonic nozzle, Scanner, Electron beam, ELECTRON-BEAM, DIFFUSIVE SEPARATION, PLASMA CHEMISTRY, FLOW, JET, DISCHARGE, PROBE",
author = "Zarvin, {A. E.} and Yaskin, {A. S.} and Dubrovin, {K. A.} and Kalyada, {V. V.}",
note = "The study was conducted using the shared equipment at the Applied Physics Centre at NSU's Physics Department with the financial support of the RFBR (grant no. 20-01-00332) and the Ministry of science and higher education of the Russian Federation (project number FSUS-2020-0039).",
year = "2021",
month = sep,
doi = "10.1016/j.vacuum.2021.110409",
language = "English",
volume = "191",
journal = "Vacuum",
issn = "0042-207X",
publisher = "Elsevier Ltd",

}

RIS

TY - JOUR

T1 - Visualization of low-density gas-dynamic objects in full-scale processes modelling on small experimental plants

AU - Zarvin, A. E.

AU - Yaskin, A. S.

AU - Dubrovin, K. A.

AU - Kalyada, V. V.

N1 - The study was conducted using the shared equipment at the Applied Physics Centre at NSU's Physics Department with the financial support of the RFBR (grant no. 20-01-00332) and the Ministry of science and higher education of the Russian Federation (project number FSUS-2020-0039).

PY - 2021/9

Y1 - 2021/9

N2 - The developed and tested visualisation method of supersonic under-expanded gas jets expanding from sonic and supersonic nozzles (or nozzle blocks) into a rarefied medium (deep vacuum) with the background gas pressure range from 3 mPa to 1 Pa was presented. It was based on the use of a well-focused electron beam whose energy was on the order of 10 keV for glow initiation in a local volume of stationary gas jet. The radiation of the excited gas was read by the recorder (modern scanner) and converted into a digital code. The local gas density was determined using special calibration procedures and software. The flow field was scanned by a special device when moving the nozzle pre-chamber by a stepper motor with a coordinate mechanism relative to a stationary electron beam crossing the gas object perpendicular to its axis. Using optical lenses, luminescence from a localised jet volume was focused to the input aperture of a scanner. High-quality focusing of the electron beam along the investigated section of the gas flow and the dimensions of the scanning unit, exceeding the investigated size of the jet, provide registration of a section image of a gas flow along or across the flow axis with sufficient resolution. The advantages and practical perspectives of the method were reviewed based on the results of the visualisation of complex supersonic jets escaping from a block of several supersonic nozzles. The reliability of the information obtained is provided by control measurements of the local gas density distribution along the axis of the supersonic nitrogen flow expanding from the sonic nozzle in comparison with the available theoretical and experimental data.

AB - The developed and tested visualisation method of supersonic under-expanded gas jets expanding from sonic and supersonic nozzles (or nozzle blocks) into a rarefied medium (deep vacuum) with the background gas pressure range from 3 mPa to 1 Pa was presented. It was based on the use of a well-focused electron beam whose energy was on the order of 10 keV for glow initiation in a local volume of stationary gas jet. The radiation of the excited gas was read by the recorder (modern scanner) and converted into a digital code. The local gas density was determined using special calibration procedures and software. The flow field was scanned by a special device when moving the nozzle pre-chamber by a stepper motor with a coordinate mechanism relative to a stationary electron beam crossing the gas object perpendicular to its axis. Using optical lenses, luminescence from a localised jet volume was focused to the input aperture of a scanner. High-quality focusing of the electron beam along the investigated section of the gas flow and the dimensions of the scanning unit, exceeding the investigated size of the jet, provide registration of a section image of a gas flow along or across the flow axis with sufficient resolution. The advantages and practical perspectives of the method were reviewed based on the results of the visualisation of complex supersonic jets escaping from a block of several supersonic nozzles. The reliability of the information obtained is provided by control measurements of the local gas density distribution along the axis of the supersonic nitrogen flow expanding from the sonic nozzle in comparison with the available theoretical and experimental data.

KW - Visualisation

KW - Supersonic flow

KW - Supersonic nozzle

KW - Scanner

KW - Electron beam

KW - ELECTRON-BEAM

KW - DIFFUSIVE SEPARATION

KW - PLASMA CHEMISTRY

KW - FLOW

KW - JET

KW - DISCHARGE

KW - PROBE

UR - https://www.mendeley.com/catalogue/8cbb6ae8-bbf7-368e-af64-3651b4195f1c/

U2 - 10.1016/j.vacuum.2021.110409

DO - 10.1016/j.vacuum.2021.110409

M3 - Article

VL - 191

JO - Vacuum

JF - Vacuum

SN - 0042-207X

M1 - 110409

ER -

ID: 34691987