Difference between revisions of "Gilbert choke equation"

Latest revision as of 19:10, 8 November 2024

By Mikhail Tuzovskiy on 20241108191031

Brief

The most common formula used for multiphase flow through surface chokes developed by Gilbert in 1954^[1].

Gilbert developed his empirical equation from field data in California^[2].

Math and Physics

P_{wh}=\frac{435 \times GLR^{0.546}}{D^{1.89}} \times q

Note that the equation is independent of the downstream pressure and assumes that the downstream pressure is less than 70% of the upstream pressure, i.e. the flow is "critical" i.e. fluid reach sonic velocity in the throat of the choke^[3].

Example

Given data

Oil rate = 600 bbl/d, GLR=400 scf/bbl, D=22/64 in, Line pressure = 180 psia

Calculate the well head pressure?

Solution

P_{wh}=\frac{435 \times 0.4^{0.546}}{22^{1.89}} \times 600 = 460 psig = 460 +14.7 = 474.7 psia

Validity check 180/474.7=0.38 < 0.7 OK

Nomenclature

D

= choke beam diametr, 64th of an inch

GLR

= gas liquid ratio, Mscf/bbl or 10^3 scf/bbl

P_{wh}

= well head pressure, psig

q

= liquid flow rate, bbl/d

References

↑ Gilbert, W.E. (1954). Flowing and Gas-Lift Well Performance. Drilling and Production Practice API. p. 143.
↑ 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.
↑ Economides, M.J.; Hill, A.D.; Economides, C.E.; Zhu, D. (2013). Petroleum Production Systems (2 ed.). Westford, Massachusetts: Prentice Hall. ISBN 978-0-13-703158-0.

[Gilbert-1] Gilbert, W.E. (1954). Flowing and Gas-Lift Well Performance. Drilling and Production Practice API. p. 143.

[KermitBrown1984-2] 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.

[Economides-3] Economides, M.J.; Hill, A.D.; Economides, C.E.; Zhu, D. (2013). Petroleum Production Systems (2 ed.). Westford, Massachusetts: Prentice Hall. ISBN 978-0-13-703158-0.

[1]

[2]

[3]

@@ Line 1: / Line 1: @@
+<div style='text-align: right;'>By Mikhail Tuzovskiy on {{REVISIONTIMESTAMP}}</div>
 __TOC__
 ==Brief==
-The most common used formula for multiphase flow through surface chokes by Gilbert <ref name=KermitBrown1984/>.
+The most common formula used for multiphase flow through surface chokes developed by '''Gilbert''' in 1954<ref name=Gilbert/>.
-Echometer is used to measure the fluid level in the wells.
+Gilbert developed his empirical equation from field data in California<ref name=KermitBrown1984/>.
-Fluid level is used to calculate and monitor the bottom hole pressure of the wells.
+==Math and Physics==
+:<math>P_{wh}=\frac{435 \times GLR^{0.546}}{D^{1.89}} \times q</math>
-==Math and Physics==
+Note that the equation is independent of the downstream pressure and assumes that the downstream pressure is less than 70% of the upstream pressure, i.e. the flow is "critical" i.e. fluid reach sonic velocity in the throat of the choke<ref name=Economides/>.
-:<math>P_{wh}=\frac{435/ GLR^0.546}{D^1.89}/q</math>
+==Example==
+===Given data===
+Oil rate = 600 bbl/d, GLR=400 scf/bbl, D=22/64 in, Line pressure = 180 psia
-===Flowing well fluids segregation===
+Calculate the well head pressure?
-When the well is flowing with the pump this is how fluids segregate in the well bore:
-*Oil, gas and water are produced through the tubing from the reservoir to the surface
-*Gas is in the annulus from the surface to the fluid level, Hd
-*Oil and gas are between the fluid level Hd, and the pump setting depth, Hd
-*Water, oil and gas are between pump, Hd and the top of the perforations, Hperfs
-*Water is in the rathole
-===Equation to calculate the BHP from the fluid level===
+===Solution===
-:<math>P_{wf}=P_{ann}+\frac{(H_{perfs}-H_{pump})(SG_o(1-WCUT)+SG_w WCUT)+(H_{pump}-H_d)SG_o}{10.32}</math>
+:<math>P_{wh}=\frac{435 \times 0.4^{0.546}}{22^{1.89}} \times 600 = 460 psig = 460 +14.7 = 474.7 psia</math>
-Note that for the deviated wells TVD depths should be used.
+Validity check 180/474.7=0.38 < 0.7 OK
 ==Nomenclature==
-:<math>g</math> = 9.81, m/s^2
+:<math>D</math> = choke beam diametr, 64th of an inch
-:<math>h</math> = depth, m
+:<math>GLR</math> = gas liquid ratio, Mscf/bbl or 10^3 scf/bbl
-:<math>H_d</math> = fluid level, m
+:<math>P_{wh}</math> = well head pressure, psig
-:<math>H_{perfs}</math> = top of the perforations, m
+:<math>q</math> = liquid flow rate, bbl/d
-:<math>H_{pump}</math> = pump setting depth, m
-:<math>P</math> = pressure, atm
-:<math>P_{ann}</math> = annulus presssure, atm
-:<math>P_{wf}</math> = well flowing bottomhole pressure, atm
-:<math>\rho</math> = density, kg/m^3
-:<math>SG_o</math> = oil specific gravity, dimensionless
-:<math>SG_w</math> = water specific gravity, dimensionless
-:<math>WCUT</math> = well water cut, fraction
 == References ==
 <references>
+<ref name= Gilbert>{{cite book
+ |last1= Gilbert |first1= W.E.
+ |title=Flowing and Gas-Lift Well Performance
+ |journal=Drilling and Production Practice API
+ |date=1954
+ |page=143
+}}</ref>
 <ref name= KermitBrown1984 >{{cite book
   |last1= Brown |first1= Kermit
@@ Line 46: / Line 44: @@
   |place=Tulsa, Oklahoma
 }}</ref>
+<ref name=Economides>{{cite book
+ |last1= Economides |first1=M.J.
+ |last2= Hill |first2=A.D.
+ |last3= Economides |first3=C.E.
+ |last4= Zhu |first4=D.
+ |title=Petroleum Production Systems
+ |edition=2
+ |date=2013
+ |publisher=Prentice Hall
+ |place=Westford, Massachusetts
+ |isbn=978-0-13-703158-0
+}}</ref>
 </references>

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