Difference between revisions of "Dranchuk correlation"

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__TOC__
 
__TOC__
  
=== Brief ===
+
== Dranchuk gas compressibility factor correlation ==
[[Liquid loading]] is a phenomenon when the gas phase does't provide sufficient transport energy to lift the liquids out of the well.
 
  
In '''1969''' Turner et al. published an empirical correlation defining the [[Liquid loading]] gas velocity.
+
[[Dranchuk correlation]] is the fitting equation of the classic '''Standing and Katz''' <ref name=Standing&Katz /> [[gas compressibility factor]] correlation.
  
[[File: Liquid Loading.png|x400px|Liquid Loading|right]]
+
== Math & Physics ==
 +
:<math> z =  1 +
 +
\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) \rho^5_r
 +
+A_{10}\ \left(1+A_{11}\ \rho^2_r\right)\ \frac{\rho^2_r}{T^3_{pr}}
 +
\ e^{(-A_{11}\ \rho^2_r)}
 +
</math><ref name= Dranchuk/>
  
=== Math & Physics ===
+
where:
    A1 = 0.3265
 
    A2 = –1.0700
 
    A3 = –0.5339
 
    A4 = 0.01569
 
    A5 = –0.05165
 
    A6 = 0.5475
 
    A7 = –0.7361
 
    A8 = 0.1844
 
    A9 = 0.1056
 
    A10 = 0.6134
 
    A11 = 0.7210
 
:<math> z =  1+ (A_1+frac{A_2-\T_pr})
 
  
1.593\ \sigma^{1/4}\ \frac{({\rho_L-\rho_g})^{1/4}}{\rho_g^{1/2}}</math><ref name=Turner/>
+
:<math>  \rho_r = \frac{0.27\ P_{pr}}{{z\ T_{pr}}} </math>
  
The minimum gas rate to remove the liquid equation:
+
:<math> P_{pr} = \frac{P}{P_{pc}}</math>
:<math> q_g = 3.067\ \frac{P\ v_g\ A}{T\ z} </math>
 
  
=== Discussion ===
+
:<math>  T_{pr} \frac{T}{T_{pc}}</math>
To avoid the [[Liquid loading]] the gas velocity should be above the [[Liquid loading]] velocity.
 
  
The higher the gas rate the higher the gas velocity.
 
  
The lower the wellhead flowing pressure the higher the gas rate.
+
A1 = 0.3265<br/>
 +
A2 = –1.0700<br/>
 +
A3 = –0.5339<br/>
 +
A4 = 0.01569<br/>
 +
A5 = –0.05165<br/>
 +
A6 = 0.5475<br/>
 +
A7 = –0.7361<br/>
 +
A8 = 0.1844<br/>
 +
A9 = 0.1056<br/>
 +
A10 = 0.6134<br/>
 +
A11 = 0.7210<br/>
  
The bigger the tubing ID the higher the gas rate.
+
== Discussion  ==
 +
Why the [[Dranchuk correlation]]?
  
In case when the gas rate is limited by the [[Reservoirs|Reservoir]] deliverability smaller tubing ID will increase the gas velocity.
+
{{Quote| text = It's classics! | source = www.pengtools.com}}
  
=== Nomenclature ===
+
== Workflow  ==
:<math> A </math> = flow area, ft^2
+
To solve the [[Dranchuk correlation| Dranchuk]] equation use the iterative secant method.
:<math> P </math> = flowing wellhead pressure, psia
 
:<math> q_g </math> = gas rate, MMscf/d
 
:<math> \rho_g </math> = gas density, lbm/ft3
 
:<math> \rho_L </math> = liquid density, lbm/ft3
 
:<math> \sigma </math> = surface tension, dyne/cm (ref values: 60 - water, 20 - condensate) <ref name=Turner/>
 
:<math> T </math> = flowing temperature, °R
 
:<math> v_g </math> = gas velocity, ft/sec
 
:<math> z </math> = gas compressibility factor at flowing P & T, dimensionless
 
  
=== References ===
+
To find the pseudo critical properties from the gas specific gravity <ref name=Standing&Katz />:
 +
 
 +
:<math>  P_{pc} =  ( 4.6+0.1\ SG_g-0.258\ SG^2_g ) \times 10.1325 \times 14.7</math>
 +
 
 +
:<math>  T_{pc} =  ( 99.3+180\ SG_g-6.94\ SG^2_g ) \times 1.8 </math>
 +
 
 +
== Application range ==
 +
 
 +
:<math>  0.2 \le P_{pr} < 30 ; 1.0 < T_{pr} \le 3.0 </math><ref name= Dranchuk/>
 +
 
 +
and
 +
 
 +
:<math>  P_{pr} < 1.0 ; 0.7 < T_{pr} \le 1.0</math><ref name= Dranchuk/>
 +
 
 +
== Nomenclature ==
 +
:<math> A_1..A_{11} </math> = coefficients
 +
:<math> \rho_r </math> = reduced density, dimensionless
 +
:<math> P </math> = pressure, psia
 +
:<math> P_{pc} </math> = pseudo critical pressure, psia
 +
:<math> P_{pr} </math> = pseudoreduced pressure, dimensionless
 +
:<math> SG_g </math> = gas specific gravity, dimensionless
 +
:<math> T </math> = temperature, °R
 +
:<math> T_{pc} </math> = pseudo critical temperature, °R
 +
:<math> T_{pr} </math> = pseudoreduced temperature, dimensionless
 +
:<math> z </math> = gas compressibility factor, dimensionless
 +
 
 +
== References ==
 
<references>
 
<references>
  
<ref name=Turner>{{cite journal
+
<ref name=Standing&Katz>{{cite journal
  |last1= Turner |first1=R. G.
+
  |last1= Standing |first1=M. B.
  |last2= Hubbard |first2=M. G.
+
  |last2= Katz |first2=D. L.
  |last3= Dukler |first2=A. E.
+
|title=Density of Natural Gases
  |title=Analysis and Prediction of Minimum Flow Rate for the Continuous Removal of Liquids from Gas Wells
+
|journal=Transactions of the AIME
  |journal=Journal of Petroleum Technology
+
|publisher=Society of Petroleum Engineers
  |number=SPE-2198-PA
+
|number=SPE-942140-G
  |date=Nov 1969
+
|date=December 1942
  |pages=1475–1482
+
|volume=146
  |url=https://www.scribd.com/doc/269398353/Friction-Factors-for-Pipe-Flow-MoodyLFpaper1944
+
|url=https://www.onepetro.org/journal-paper/SPE-942140-G
 +
|url-access=registration
 +
}}</ref>
 +
 
 +
<ref name= Dranchuk >{{cite journal
 +
|last1= Dranchuk |first1=P. M.
 +
  |last2= Abou-Kassem |first2=H.
 +
  |title=Calculation of Z Factors For Natural Gases Using Equations of State
 +
  |journal=The Journal of Canadian Petroleum
 +
  |number=PETSOC-75-03-03
 +
  |date=July 1975
 +
  |volume=14
 +
  |url=https://www.onepetro.org/journal-paper/PETSOC-75-03-03
 
  |url-access=registration  
 
  |url-access=registration  
 
}}</ref>
 
}}</ref>
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[[Category:pengtools]]
 
[[Category:pengtools]]
 
[[Category:PVT]]
 
[[Category:PVT]]
 +
 +
 +
{{#seo:
 +
|title=Dranchuk gas compressibility factor correlation
 +
|titlemode= replace
 +
|keywords=Dranchuk correlation
 +
|description=Dranchuk correlation is the fitting equation of the classic Standing and Katz gas compressibility factor correlation.
 +
}}

Latest revision as of 21:29, 23 November 2023

Dranchuk gas compressibility factor correlation

Dranchuk correlation is the fitting equation of the classic Standing and Katz [1] gas compressibility factor correlation.

Math & Physics

 z =  1 +
\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) \rho^5_r
+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}}


A1 = 0.3265
A2 = –1.0700
A3 = –0.5339
A4 = 0.01569
A5 = –0.05165
A6 = 0.5475
A7 = –0.7361
A8 = 0.1844
A9 = 0.1056
A10 = 0.6134
A11 = 0.7210

Discussion

Why the Dranchuk correlation?

It's classics!
— www.pengtools.com

Workflow

To solve the Dranchuk equation use the iterative secant method.

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

  P_{pc} =  ( 4.6+0.1\ SG_g-0.258\ SG^2_g ) \times 10.1325 \times 14.7
  T_{pc} =  ( 99.3+180\ SG_g-6.94\ SG^2_g ) \times 1.8

Application range

  0.2 \le P_{pr} < 30 ; 1.0 < T_{pr} \le 3.0 [2]

and

  P_{pr} < 1.0 ; 0.7 < T_{pr} \le 1.0[2]

Nomenclature

 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

References

  1. 1.0 1.1 Standing, M. B.; Katz, D. L. (December 1942). "Density of Natural Gases"Free registration required. Transactions of the AIME. Society of Petroleum Engineers. 146 (SPE-942140-G). 
  2. 2.0 2.1 2.2 Dranchuk, P. M.; Abou-Kassem, H. (July 1975). "Calculation of Z Factors For Natural Gases Using Equations of State"Free registration required. The Journal of Canadian Petroleum. 14 (PETSOC-75-03-03).