User:RaoulV/Isentropic exponent

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Isentropic exponent

The isentropic exponent or isentropic expansion coefficient $k$ is a dimensionless number that relates a relative change in specific volume of a fluid to a corresponding relative change in pressure, during an isentropic expansion or compression.

The isentropic exponent $k$ is defined by ^[1]:

k=-{\frac {V}{p}}{\partial p \over \partial V}|_{s=cte}={\frac {\rho }{p}}{\partial p \over \partial \rho }|_{s=cte}\,\!

(1)

If $k$ is constant along an isentropic path, then the pressure and specific volume of the gas along this path are related by

pV^{k}=cte\,\!

(2)

Relation to other thermodynamic quantities[edit]

symbol	quantity
$k$	isentropic exponent
$\gamma$	heat capacity ratio
$V$	specific volume
$\rho$	density
$p$	pressure
$s$	entropy
$u_{s}$	velocity of sound

The isentropic exponent is related to the velocity of sound by :

k={\frac {\rho }{p}}u_{s}^{2}\,\!

(4)

Ideal gas[edit]

For an ideal gas the isentropic exponent is equal to the heat capacity ratio $\gamma$

\gamma ={\frac {C_{p}}{C_{V}}}\,\!

(3)

As a consequence, it is always larger than one.

Real gases, liquids and vapor-liquid mixtures[edit]

For a real gas, $k$ varies with temperature and pressure and is different from $\gamma$ . The difference becomes larger as the fluid deviates more from an ideal gas (for instance at higher pressures, close to the saturation pressure, in the 2-phase region, in the liquid state).

In the two-phase region, k can be lower than 1.

Application in fluid flow[edit]

If the isentropic exponent is constant along an isentropic path from the valve inlet to the valve throat, the mass flux at the throat can be calculated from :

q_{m}={\sqrt {p_{0}\rho _{0}}}{\sqrt {k({\frac {2}{k+1}})^{\frac {k+1}{k-1}}}}\,\!

(5)

To apply this equation without conversion factors, use consistent units (pressure in Pa, density in kg/m3, mass flux in kg/m2s).

This equation is used in the calculation of the capacity or required size of relief valves ^[2] ^[3].

Examples[edit]

Values of k can be calculated by using an equation of state.

In the table below, some values of $k$ and $\gamma$ are given for water (calculated with the IAPWS-97 equation of state). Water was selected because a very accurate equation of state is available. Similar differences between $k$ and $\gamma$ exist for other fluids, even at lower pressures (the critical pressure of water is much higher than that of most hydrocarbons).

temperature	pressure	isentropic exponent	heat capacity ratio
(°C)	(bar a)	$k$	$\gamma$
101	1	1.317	1.337
180	10	1.219	1.406
270	50	1.267	1.670
311	100	1.237	2.297

References[edit]

^ Thermodynamic Property Relations
^ ISO 4126-1 Safety devices for protection against excessive pressure
^ API 5210-1, Sizing and Selection of Pressure-Relieving Devices

External links[edit]

IAPWS-97

Category:Thermodynamics Category:Physical quantities Category:Ratios

[1] Thermodynamic Property Relations

[2] ISO 4126-1 Safety devices for protection against excessive pressure

[3] API 5210-1, Sizing and Selection of Pressure-Relieving Devices

[1]

[2]

[3]