Shock Wave in van der Waals Gas
-
Andriy A. Avramenko
und
Nataliya P. Dmitrenko
Abstract
In this work, an analytical analysis of the dynamics of a van der Waals gas flow passing through a direct shock wave was performed. For this purpose, modified Rankine-Hugoniot conditions were used. The influence of parameters α and β of the van der Waals model and the pressure jump in the shock adiabat was analyzed. Relations for the velocity jump in flow were obtained, and the influence of parameters α and β on the velocity jump was revealed. Calculations made it possible to estimate the limits of applicability of the van der Waals model, within which it adequately describes the physics of the process under consideration.
Nomenclature
- a
-
speed of sound, m/s
-
isobaric heat capacity, J/K
-
isochoric heat capacity, J/K
- h
-
specific enthalpy, J/kg
- k
-
isentropic expansion exponent
- p
-
pressure, Pa
- R
-
individual (specific) gas constant, J/kg · K
- S
-
entropy J/K
- T
-
temperature, K
- u
-
internal energy, J/kg
- V
-
flow velocity, m/s
- v
-
specific volume, m3/kg
- λ
-
velocity coefficient
- ρ
-
density, kg/m3
Greek symbols
- α
-
constant of the van der Waals model
- β
-
constant of the van der Waals model
Dimensionless numbers
-
Mach number
Subscripts
- 1
-
parameters before the shock wave
- 2
-
parameters after the shock wave
References
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© 2022 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- Research Articles
- Internal Variables as a Tool for Extending Navier-Stokes Equations
- Shock Wave in van der Waals Gas
- Effect of Cross-Sectional Geometry on Hydrothermal Behavior of Microchannel Heat Sink
- Power Density Analysis and Multi-Objective Optimization for an Irreversible Dual Cycle
- Energy and Entropy in Open and Irreversible Chemical Reaction–Diffusion Systems with Asymptotic Stability
Artikel in diesem Heft
- Frontmatter
- Research Articles
- Internal Variables as a Tool for Extending Navier-Stokes Equations
- Shock Wave in van der Waals Gas
- Effect of Cross-Sectional Geometry on Hydrothermal Behavior of Microchannel Heat Sink
- Power Density Analysis and Multi-Objective Optimization for an Irreversible Dual Cycle
- Energy and Entropy in Open and Irreversible Chemical Reaction–Diffusion Systems with Asymptotic Stability
