Dranchuk correlation

z = 1-z+ \left(A_1 +\frac{A_2}{T_{pr}} +\frac{A_3}{T^3_{pr}} +\frac{A_4}{T^4_{pr}} +\frac{A_5}{T^5_{pr}} \right)\ \rho_r+ \left(A_6 +\frac{A_7}{T_{pr}} +\frac{A_8}{T^2_{pr}} \right)\ \rho^2_r -A_9\ \left(\frac{A_7}{T_{pr}}+\frac{A_8}{T^2_{pr}}\right) +A_{10}\ \left(1+A_{11}\ \rho^2_r\right)\ \frac{\rho^2_r}{T^3_{pr}} \ e^{(-A_{11}\ \rho^2_r)}

^[2]

where

\rho_r = \frac{0.27\ P_{pr}}{{z\ T_{pr}}}

P_{pr} = \frac{P}{P_{pc}}

T_{pr} = \frac{T}{T_{pc}}

To solve the Dranchuk equation use the iterative secant method.

To find the pseudo critical properties given the gas specific gravity^[1]:

P_{pc} = 4.6+0.1\ SG_g-0.258\ SG^2_g

T_{pc} = 99.3+180\ SG_g-6.94\ SG^2_g

Application range:

0.2 \ll P_pr < 30 ; 1.0 < T_pr \ll 3.0

&

P_pr < 1.0 ; 0.7 < T_pr \ll 1.0

A_1..A_{11}

coefficients

\rho_r

= reduced density, dimensionless

P

= Pressure, psia

P_{pc}

= pseudo critical pressure, psia

P_{pr}

= pseudoreduced pressure, dimensionless

SG_g

= gas specific gravity, dimensionless

T

= temperature, °R

T_{pc}

= pseudo critical temperature, °R

T_{pr}

= pseudoreduced temperature, dimensionless

z

= gas compressibility factor, dimensionless

↑ ^1.0 ^1.1 Standing, M. B.; Katz, D. L. (December 1942). "Density of Natural Gases". Transactions of the AIME. Society of Petroleum Engineers. 146 (SPE-942140-G).
↑ Dranchuk, P. M.; Abou-Kassem, H. (July 1975). "Calculation of Z Factors For Natural Gases Using Equations of State". The Journal of Canadian Petroleum. 14 (PETSOC-75-03-03).

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