Difference between revisions of "Vogel's IPR"

Latest revision as of 05:29, 3 January 2023

1 Vogel's Inflow Performance Relationship
2 Math and Physics
- 2.1 Vogel's IPR equation
- 2.2 Darcy's law + Vogel's IPR
3 Discussion
4 Vogel's IPR calculation workflow
- 4.1 1. Calculate the Productivity Index, J:
- 4.2 2. Calculate the flowing rates, q_o:
5 Vogel's IPR calculation example
6 Nomenclature
- 6.1 Greek symbols
- 6.2 Subscripts
7 References
8 See also

By Mikhail Tuzovskiy on 20230103052908

Vogel's Inflow Performance Relationship

Vogel's IPR^[1]

Vogel's IPR is an empirical two-phase (oil + gas) inflow performance relationship correlation published in 1968 ^[1].

Vogel's IPR is based on computer simulations to several solution gas drive reservoirs for different fluid and reservoir relative permeability properties.

Vogel's IPR is the default IPR correlation to calculate oil wells performance in the PQplot nodal analysis software which is available online at petroleum engineering site www.pengtools.com.

Math and Physics

Vogel's IPR equation

\frac{q_o}{q_{o_{max}}} = 1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2

^[1]

Darcy's law + Vogel's IPR

Combination single phase liquid constant PI equation and Vogel's IPR:

^[2]

q_{ob} = J (\bar{P} - P_b)

^[2] , oil flow rate at the bubble point.

q_{o_{max}} = q_{ob} + \frac{J P_b}{1.8}

^[3] , maximum oil rate or absolute open flow (AOF).

q_o = q_{ob} + (q_{o_{max}} - q_{ob}) \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right )

^[2] , oil rate at given flowing bottomhole pressure.

J = \frac{q_o}{\bar{P}-P_b + \frac{P_b}{1.8} \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right ) }

^[2] , productivity index for test below the bubble point pressure.

Discussion

Why Vogel's IPR?

Vogel's IPR solution has been found to be very good and is widely used in prediction of IPR curves.
— Kermit Brown et al^[2]

Vogel's IPR calculation workflow

1. Calculate the Productivity Index, J:

1.1 J from the flow test:

Test is above the bubble point:

J=\frac{q_{o_{test}}}{\bar{P}-P_{wf}}

Test is below the bubble point:

J = \frac{q_{o_{test}}}{\bar{P}-P_b + \frac{P_b}{1.8} \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right ) }

1.2 J from kh and JD:

J = \frac{kh\ J_D}{141.2 B \mu}

1.3 J from kh and skin:

J = \frac{kh\ \frac{1}{1 / 0.13 + S}}{141.2 B \mu}

2. Calculate the flowing rates, q_o:

For each P_wf from $\bar{P}$ to 0:

2.1 Calculate oil flow rate at the bubble point:

q_{ob} = J (\bar{P} - P_b)

2.2 Calculate maximum oil rate:

q_{o_{max}} = q_{ob} + \frac{J P_b}{1.8}

2.3 Calculate oil rate at given flowing bottomhole pressure, P_wf:

q_o = q_{ob} + (q_{o_{max}} - q_{ob}) \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right )

Vogel's IPR calculation example

Figure.1 Vogel's IPR calculation example

Following the example problem #6, page 15 ^[2]:

Given:

\bar{P}

=4200 psi

J=2 b/d/psi

P_b=3000 psi

Calculate:

(1) q_ob

(2) q_max

(3) q for P_wf=1500 psi

Solution:

(1)

q_{ob} = J (\bar{P} - P_b) = 2 \times (4200 - 3000) = 2400\ b/d

(2)

q_{o_{max}} = q_{ob} + \frac{J P_b}{1.8} = 2400 + \frac{2 \times 3000}{1.8} = 2400 + 3333 = 5733\ b/d

(3 )

q_o = q_{ob} + (q_{o_{max}} - q_{ob}) \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right )

q_o = 2400 + (5733 - 2400) \left (1-0.2 \frac{1500}{4200} - 0.8 \left ( \frac{1500}{4200} \right )^2 \right )

q_o = 2400 + 3333 \times 0.7 = 4733\ b/d

With the help of the PQplot software, other values of flowing pressure has been assumed, and the corresponding values of flow rate were determined. From these, the IPR cure was plotted (Fig.1).

The PQplot model from this example is available online by the following link: Vogel's IPR calculation example

Nomenclature

B

= formation volume factor, bbl/stb

J

= productivity index, stb/d/psia

J_D

= dimensionless productivity index, dimensionless

kh

= permeability times thickness, md*ft

P

= pressure, psia

\bar{P}

= average reservoir pressure, psia

q

= flowing rate, stb/d

S

= skin factor, dimensionless

Greek symbols

\mu

= viscosity, cp

Subscripts

b = at bubble point pressure

max = maximum

o = oil

test = well test

wf = well flowing bottomhole pressure

References

↑ ^1.0 ^1.1 ^1.2 Vogel, J. V. (1968). "Inflow Performance Relationships for Solution-Gas Drive Wells". Journal of Petroleum Technology. 20 (SPE-1476-PA).
↑ ^2.0 ^2.1 ^2.2 ^2.3 ^2.4 ^2.5 Brown, Kermit (1984). The Technology of Artificial Lift Methods. Volume 4. Production Optimization of Oil and Gas Wells by Nodal System Analysis. Tulsa, Oklahoma: PennWellBookss.
↑ Neely, A.B. (1976). Use of IPR Curves. Houston, Texas: Shell Oil Co.

@@ Line 1: / Line 1: @@
 __TOC__
+<div style='text-align: right;'>By Mikhail Tuzovskiy on {{REVISIONTIMESTAMP}}</div>
 ==Vogel's Inflow Performance Relationship==
 [[File:Vogel's.png|thumb|right|300px| Vogel's IPR<ref name=Vogel />]]
@@ Line 24: / Line 25: @@
 :<math> q_o = q_{ob} + (q_{o_{max}} - q_{ob})  \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right )</math><ref name=KermitBrown1984 /> , oil rate at given flowing bottomhole pressure.
-:<math> J = \frac{q_o}{\bar{P}-P_b + \frac{P-b}{1.8} \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right ) } </math><ref name=KermitBrown1984 /> , productivity index for test below the bubble point pressure.
+:<math> J = \frac{q_o}{\bar{P}-P_b + \frac{P_b}{1.8} \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right ) } </math><ref name=KermitBrown1984 /> , productivity index for test below the bubble point pressure.
 ==Discussion ==
@@ Line 38: / Line 39: @@
 ::<math>J=\frac{q_{o_{test}}}{\bar{P}-P_{wf}}</math>
 ::* Test is below the bubble point:
-::<math> J = \frac{q_{o_{test}}}{\bar{P}-P_b + \frac{P-b}{1.8} \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right ) }</math>
+::<math> J = \frac{q_{o_{test}}}{\bar{P}-P_b + \frac{P_b}{1.8} \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right ) }</math>
 :1.2 J from kh and [[JD]]:
 :: <math>J = \frac{kh\ J_D}{141.2 B \mu}</math>
 :1.3 J from kh  and skin:
-:: <math>J = \frac{kh\ \frac{1}{1 / 0.13 + s}}{141.2 B \mu}</math>
+:: <math>J = \frac{kh\ \frac{1}{1 / 0.13 + S}}{141.2 B \mu}</math>
 ===2. Calculate the flowing rates, q<sub>o</sub>:===
@@ Line 52: / Line 53: @@
 :2.3 Calculate oil rate at given flowing bottomhole pressure, P<sub>wf</sub>:
 ::<math> q_o = q_{ob} + (q_{o_{max}} - q_{ob})  \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right )</math>
+==[[Vogel's IPR]] calculation example==
+[[File:Vogel's IPR calculation example.png|thumb|right|400px| Figure.1 [https://www.pengtools.com/pqPlot?paramsToken=e9d7a7fc72e7264858153a4a9099bcf7 Vogel's IPR calculation example]]]
+Following the example problem #6, page 15 <ref name=KermitBrown1984 />:
+===Given:===
+:<math>\bar{P}</math>=4200 psi
+:J=2 b/d/psi
+:P<sub>b</sub>=3000 psi
+===Calculate:===
+:(1) q<sub>ob</sub>
+:(2) q<sub>max</sub>
+:(3) q for P<sub>wf</sub>=1500 psi
+===Solution:===
+:(1) <math> q_{ob} = J (\bar{P} - P_b) = 2 \times (4200 - 3000) = 2400\ b/d</math>
+:(2) <math> q_{o_{max}} = q_{ob} + \frac{J P_b}{1.8} = 2400 + \frac{2 \times 3000}{1.8} = 2400 + 3333 = 5733\ b/d</math>
+:(3 )<math> q_o = q_{ob} + (q_{o_{max}} - q_{ob})  \left (1-0.2 \frac{P_{wf}}{\bar{P}} - 0.8 \left ( \frac{P_{wf}}{\bar{P}} \right )^2 \right ) </math>
+::<math> q_o = 2400 + (5733 - 2400)  \left (1-0.2 \frac{1500}{4200} - 0.8 \left ( \frac{1500}{4200} \right )^2 \right )</math>
+::<math> q_o = 2400 + 3333 \times 0.7 = 4733\ b/d</math>
+With the help of the [[:Category:PQplot|PQplot]] software, other values of flowing pressure has been assumed, and the corresponding values of flow rate were determined. From these, the IPR cure was plotted ('''Fig.1''').
+The  [[:Category:PQplot|PQplot]] model from this example is available online by the following link: [https://www.pengtools.com/pqPlot?paramsToken=e9d7a7fc72e7264858153a4a9099bcf7 Vogel's IPR calculation example]
 == Nomenclature  ==
 :<math> B </math> = formation volume factor, bbl/stb
+:<math> J </math> = productivity index, stb/d/psia
 :<math> J_D </math> = dimensionless productivity index, dimensionless
 :<math> kh</math> = permeability times thickness, md*ft
+:<math> P </math> = pressure, psia
 :<math> \bar{P} </math> = average reservoir pressure, psia
-:<math> P_{\bar{P}} </math> = average reservoir pseudopressure, psia<sup>2</sup>/cP
-:<math> P_{wf} </math> = well flowing pressure, psia
-:<math> P_{P_{wf}} </math> = average well flowing pseudopressure, psia<sup>2</sup>/cP
 :<math> q </math> = flowing rate, stb/d
-:<math> q_g </math> = gas rate, MMscfd
+:<math> S </math> = skin factor, dimensionless
-:<math> T </math> = temperature, °R
 ===Greek symbols===
@@ Line 69: / Line 91: @@
 :<math> \mu </math> = viscosity, cp
-=== References ===
+===Subscripts===
+:b = at bubble point pressure<BR/>
+:max = maximum<BR/>
+:o = oil<BR/>
+:test = well test<BR/>
+:wf = well flowing bottomhole pressure<BR/>
+== References ==
 <references>
 <ref name=Vogel>{{cite journal
@@ Line 101: / Line 131: @@
 ==See also==
 :[[IPR]]<BR/>
-:[[141.2 derivation]]<BR/>
+:[[3 Phase IPR]]<BR/>
 :[[Darcy's law]]<BR/>
 :[[JD]]<BR/>
-:[[Production Potential]]
+:[[141.2 derivation]]<BR/>
 {{#seo:

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Difference between revisions of "Vogel's IPR"

Latest revision as of 05:29, 3 January 2023

Contents

Vogel's Inflow Performance Relationship