DSMC and R13 modeling of the adiabatic surface

Mohammadzadeh, Alireza; Rana, Anirudh Singh

doi:10.1016/j.ijthermalsci.2015.10.007

Cited by 24 publications

(7 citation statements)

References 31 publications

(50 reference statements)

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“…From the pressure contours in figures (10)(11)(12) variations in pressure along the flow direction is similar for all ER larger than 2. The pressure changes in the transverse direction are more pronounced in the vicinity of the step, with regions of higher pressure near the walls and pressure reducing sharply away from the wall.…”

Section: Pressure Fieldmentioning

confidence: 75%

“…As known, the density of air decreases gradually as altitude increases, and the rarefaction effects become more evident near outer space as the flow changes from near continuum to free molecular regime. As the degree of rarefaction rises, the continuum solvers which use Navier-Stokes equations lose their credibility [12], whereas the Boltzmann equation can aptly describe the behavior of gas flow at every degree of rarefaction [12]. The Boltzmann equation is given as [13], [14]:…”

Section: Dsmc Methodmentioning

confidence: 99%

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DSMC Simulation of Rarefied Gas Flow over a Backward- Facing Step: Effect of Expansion ratio

Nabapure¹,

Guha²,

Murthy³

2019

Preprint

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Numerical simulations have been performed to study the effect of expansion ratio on the hypersonic rarefied flow past a backward-facing step. The Direct Simulation Monte Carlo (DSMC) method is used for the present study. An opensource solver named dsmcFoam has been used for this purpose. The solver has been validated with well-established results from the literature and good agreement is found among them. Simulations have been carried out for expansion ratios (ER) of 2,4,6,8,10 in the transition regime. The different flow field properties such as velocity, pressure and temperature have been studied. The profiles have found to be influenced by the compressibility and rarefaction effects. Limiting case of ER=8 and above has no influence on the flow field properties.

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Section: Pressure Fieldmentioning

confidence: 75%

Section: Dsmc Methodmentioning

confidence: 99%

DSMC Simulation of Rarefied Gas Flow over a Backward- Facing Step: Effect of Expansion ratio

Nabapure¹,

Guha²,

Murthy³

2019

Preprint

View full text Add to dashboard Cite

show abstract

“…This gas-surface interaction model can be described by keeping the particle velocity magnitude invariant and the velocity direction of the reflected particle set based on isotropic scattering boundary conditions in the half unite sphere. We discuss this problem first in the spherical coordinate system   1 2 , , [13,18]. The three velocity components on the inner cylinder for adiabatic case reflected by: …”

Section: Direct Simulation Monte Carlo (Dsmc) Methodsmentioning

confidence: 99%

Thermoacoustic waves in pulsed Pirani sensor MEMS. Numerical Investigation

et al. 2018

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Abstract. The transient heat transfer process is studied in rarefied gas confined between two stationary concentric cylinders. The inner cylinder (filament) is subjected to a periodically heating-cooling cycle. The energy transfer is modeled with continuous model based on Navier-Sockes Fourier equations of motion and energy transfer and with a statistical DSMC model. Numerical results for the temperature, thermodynamic pressure and pressure difference between thermodynamic pressure and radial stress tensor component are obtained for different circular frequencies of heating cooling cycle of filament and for different filament radii. The pressure variation at the end of any local heating stage of heating-cooling cycle is close to the value of equilibrium thermodynamic pressure. The results are applicable in designing the pulsed Pirani sensors.

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“…This gas-surface interaction model can be described by keeping the particle velocity magnitude invariant and the velocity direction of the reflected particle set based on isotropic scattering boundary conditions in the half unite sphere. We discuss this problem first in the spherical coordinate system , , c 0, , 0, 2 2 [13,18]. The three velocity components on the inner cylinder for adiabatic case reflected by:…”

Section: Direct Simulation Monte Carlo (Dsmc) Methodsmentioning

confidence: 99%

Numerical simulation of the pulsed Pirani gauges

Gospodinov

Dankov

Roussinov

et al. 2017

AIP Conference Proceedings

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Abstract. The transient heat transfer process is studied in rarefied gas confined between two stationary concentric cylinders. The inner cylinder (filament) is subjected to a periodically heating-cooling cycle. The energy transfer is modeled with a continuous model based on Navier-Stokes-Fourier (NSF) equations of motion and energy transfer and with a statistical Direct Simulation Monte Carlo Method (DSMC). Numerical results for the temperature, thermodynamic pressure and pressure difference between thermodynamic pressure and radial stress tensor component are obtained for different circular frequencies of heating cooling cycle of filament and for different filament radii. The pressure variation at the end of any local heating stage of heating-cooling cycle is close to the value of equilibrium thermodynamic pressure. The results are applicable in designing the pulsed Pirani gauges.

show abstract

DSMC and R13 modeling of the adiabatic surface

Cited by 24 publications

References 31 publications

DSMC Simulation of Rarefied Gas Flow over a Backward- Facing Step: Effect of Expansion ratio

DSMC Simulation of Rarefied Gas Flow over a Backward- Facing Step: Effect of Expansion ratio

Thermoacoustic waves in pulsed Pirani sensor MEMS. Numerical Investigation

Numerical simulation of the pulsed Pirani gauges

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