@wikipedia
One of the cubic equations of real gas state defining the Compressibility factor
as a function of
Gas pressure and Gas temperature :
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| Z^3 - (1-B) \, Z^2 +(A-2B-3B^2) \, Z -(AB-B^2-B^3) = 0 |
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| A=\frac{a \, \alpha \, p}{ R^2 \, T^2}
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| B=\frac{b \, p}{ R \, T}
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| a = 0.45724 \cdot \frac{R^2 \, T_c^2}{p_c}
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| b = 0.07780 \cdot \frac{R \, T_c}{p_c}
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| \alpha = \left( 1 + \kappa \, (1-T_r^{0.5}) \right)^2
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| \kappa = 0.37464 + 1.54226 \, \omega -0.26992 \, \omega^2
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where
Once compressibility Z-factor
is known the
gas density can be calculated as:
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\rho(p, T) = \frac{1}{Z(p,T)} \cdot \frac{M}{R} \cdot \frac{p}{T} |
where
See also
Natural Science / Physics / Thermodynamics / Real Gas / Real Gas EOS @model