Difference between revisions of "Vogel's IPR"

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(Vogel's Inflow Performance Relationship)
(Combination single phase liquid and Vogel's IPR)
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===Combination single phase liquid and [[Vogel's IPR]]===
 
===Combination single phase liquid and [[Vogel's IPR]]===
[[File:Constant PI and Vogel's IPR.png|400px| Combination Constant PI and Vogel's IPR<ref name=KermitBrown1984 />]]
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[[File:Constant PI and Vogel's IPR.png|300px| Combination Constant PI and Vogel's IPR<ref name=KermitBrown1984 />]]
  
 
== Why [[Vogel's IPR]]?  ==
 
== Why [[Vogel's IPR]]?  ==

Revision as of 08:35, 5 April 2019

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 for the oil wells in the PQplot.

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

Combination single phase liquid and Vogel's IPR

Combination Constant PI and Vogel's IPR[2]

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]

IPR calculator software

Nomenclature

 B = formation volume factor, bbl/stb
 J_D = dimensionless productivity index, dimensionless
 kh = permeability times thickness, md*ft
 \bar{P} = average reservoir pressure, psia
 P_{\bar{P}} = average reservoir pseudopressure, psia2/cP
 P_{wf} = well flowing pressure, psia
 P_{P_{wf}} = average well flowing pseudopressure, psia2/cP
 q = flowing rate, stb/d
 q_g = gas rate, MMscfd
 T = temperature, °R

Greek symbols

 \mu = viscosity, cp

References

  1. 1.0 1.1 Vogel, J. V. (1968). "Inflow Performance Relationships for Solution-Gas Drive Wells". Journal of Petroleum Technology. 20 (SPE-1476-PA). 
  2. 2.0 2.1 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. 

See also

141.2 derivation
Darcy's law
JD
Production Potential