Publication result detail

Application of a Total Pressure Sensor in Supersonic Flow for Shock Wave Analysis Under Low-Pressure Conditions

BÍLEK, M.; MAXA, J.; ŠABACKÁ, P.; BAYER, R.; BINAR, T.; BAČA, P.; VOTAVA, J.; TOBIÁŠ, M.; ŽÁK, M.

Original Title

Application of a Total Pressure Sensor in Supersonic Flow for Shock Wave Analysis Under Low-Pressure Conditions

English Title

Application of a Total Pressure Sensor in Supersonic Flow for Shock Wave Analysis Under Low-Pressure Conditions

Type

WoS Article

Original Abstract

This study examines the design and implementation of a sensor developed to measure total pressure in supersonic flow conditions using nitrogen as the working fluid. Using a combination of absolute and differential pressure sensors, the total pressure distribution downstream of a nozzle—where normal shock waves are generated—was characterized across a range of low-pressure regimes. The experimental results were employed to validate and calibrate computational fluid dynamics (CFD) models, particularly within pressure ranges approaching the limits of continuum mechanics. The validated analyses enabled a more detailed examination of shock-wave behavior under near-continuum conditions, with direct relevance to the operational environment of differentially pumped chambers in Environmental Scanning Electron Microscopy (ESEM). Furthermore, an entropy increase across the normal shock wave at low pressures was quantified, attributed to the extended molecular mean free path and local deviations from thermodynamic equilibrium.

English abstract

This study examines the design and implementation of a sensor developed to measure total pressure in supersonic flow conditions using nitrogen as the working fluid. Using a combination of absolute and differential pressure sensors, the total pressure distribution downstream of a nozzle—where normal shock waves are generated—was characterized across a range of low-pressure regimes. The experimental results were employed to validate and calibrate computational fluid dynamics (CFD) models, particularly within pressure ranges approaching the limits of continuum mechanics. The validated analyses enabled a more detailed examination of shock-wave behavior under near-continuum conditions, with direct relevance to the operational environment of differentially pumped chambers in Environmental Scanning Electron Microscopy (ESEM). Furthermore, an entropy increase across the normal shock wave at low pressures was quantified, attributed to the extended molecular mean free path and local deviations from thermodynamic equilibrium.

Keywords

Ansys Fluent; aperture; CFD; differentially pumped chamber; ESEM; low pressure; nozzle; pitot sensors; shock wave

Key words in English

Ansys Fluent; aperture; CFD; differentially pumped chamber; ESEM; low pressure; nozzle; pitot sensors; shock wave

Authors

BÍLEK, M.; MAXA, J.; ŠABACKÁ, P.; BAYER, R.; BINAR, T.; BAČA, P.; VOTAVA, J.; TOBIÁŠ, M.; ŽÁK, M.

Released

10.10.2025

Periodical

SENSORS

Volume

25

Number

20

State

Swiss Confederation

Pages from

1

Pages to

29

Pages count

29

URL

https://www.mdpi.com/1424-8220/25/20/6291

Full text in the Digital Library

http://hdl.handle.net/11012/255606

BibTex

@article{BUT199086,
  author="Michal {Bílek} and Jiří {Maxa} and Pavla {Šabacká} and Robert {Bayer} and Tomáš {Binar} and Petr {Bača} and  {} and  {} and  {}",
  title="Application of a Total Pressure Sensor in Supersonic Flow for Shock Wave Analysis Under Low-Pressure Conditions",
  journal="SENSORS",
  year="2025",
  volume="25",
  number="20",
  pages="29",
  doi="10.3390/s25206291",
  url="https://www.mdpi.com/1424-8220/25/20/6291"
}

Documents

sensors-25-06291-v2