Difference between revisions of "Lee correlation"

Revision as of 11:56, 5 October 2020

Lee correlation is the empirical correlation for the gas viscosity published in 1966.

Lee gas viscosity correlation at T=340F in the PVT software at pengtools.com

\mu_g = \frac{K\ e^{(X\ \rho_g^Y)}}{10000}

^[1]

where

K = \frac{(9.4+0.02\ M_g)\ T^{1.5}}{(209+19M_g+T)}

X = 3.5+\frac{986}{T}+0.001M_g

Y = 2.4-0.2\ X

M_g = 28.967\ SG_g

\rho_g = \frac{1}{62.428} \times \frac{28.967\ SG_g\ p}{z\ 10.732\ T}

560 \le T < 800

100 < P \le 8000

\rho_g

= gas density, g/cm3

\mu_g

= gas viscosity, cp

M_g

= gas molecular weight, dimensionless

p

= pressure, psia

SG_g

= gas specific gravity, dimensionless

T

= temperature, °R

z

= gas compressibility factor, dimensionless

↑ Lee, A. B.; Gonzalez, M. H.; Eakin, B. E. (1966). "The Viscosity of Natural Gases". Journal of Petroleum Technology (SPE-1340-PA).

@@ Line 1: / Line 1: @@
 __TOC__
-=== Lee gas viscosity correlation ===
+== Lee gas viscosity correlation ==
 [[Lee correlation]] is the empirical correlation for the gas viscosity published in '''1966'''.
@@ Line 7: / Line 7: @@
 [[File:LeeSample.png|thumb|right|400px|link=https://www.pengtools.com/pvtCalculator|Lee gas viscosity correlation at T=340F in the PVT software at pengtools.com|right]]
-=== Math & Physics ===
+== Math & Physics ==
 :<math> \mu_g = \frac{K\ e^{(X\ \rho_g^Y)}}{10000} </math><ref name= Lee/>
@@ Line 22: / Line 22: @@
 :<math>  \rho_g =  \frac{1}{62.428} \times \frac{28.967\ SG_g\ p}{z\ 10.732\ T}</math>
-=== Discussion  ===
+== Application range ==
-Why the [[Lee correlation]]?
-=== Application range ===
 :<math>  560 \le T < 800 </math>
@@ Line 31: / Line 28: @@
 :<math> 100 < P \le 8000</math>
-=== Nomenclature ===
+== Nomenclature ==
 :<math> \rho_g </math> = gas density, g/cm3
 :<math> \mu_g </math> = gas viscosity, cp