Difference between revisions of "Beggs and Brill correlation"
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[[Beggs and Brill correlation |Beggs and Brill]] is the default [[VLP]] correlation in [[:Category:sPipe|sPipe]]. | [[Beggs and Brill correlation |Beggs and Brill]] is the default [[VLP]] correlation in [[:Category:sPipe|sPipe]]. | ||
− | [[File: Beggs and Brill.png|thumb|500px|link=https://www.pengtools.com|Beggs and Brill in sPipe Vs GAP |right]] | + | [[File: Beggs and Brill.png|thumb|500px|link=https://www.pengtools.com/sPipe?paramsToken=cc8af4bdd85a3d7da86119d5367742e2|Beggs and Brill in sPipe Vs GAP |right]] |
== Math & Physics == | == Math & Physics == | ||
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== Nomenclature == | == Nomenclature == | ||
+ | :<math> A </math> = correlation variable, dimensionless | ||
:<math> A_p </math> = flow area, ft2 | :<math> A_p </math> = flow area, ft2 | ||
− | |||
:<math> B </math> = formation factor, bbl/stb | :<math> B </math> = formation factor, bbl/stb | ||
− | :<math> C </math> = | + | :<math> C </math> = correlation variable, dimensionless |
+ | :<math> C_L </math> = non-slip liquid holdup factor, dimensionless | ||
:<math> D </math> = pipe diameter, ft | :<math> D </math> = pipe diameter, ft | ||
+ | :<math> G </math> = total flux weight, lb<sub>m</sub>/ft<sup>2</sup>/sec | ||
:<math> h </math> = depth, ft | :<math> h </math> = depth, ft | ||
− | |||
:<math> H_L </math> = liquid holdup factor, dimensionless | :<math> H_L </math> = liquid holdup factor, dimensionless | ||
+ | :<math> H_{L(0)} </math> = liquid holdup factor when flow is horizontal, dimensionless | ||
:<math> f </math> = friction factor, dimensionless | :<math> f </math> = friction factor, dimensionless | ||
+ | :<math> f' </math> = corrected friction factor, dimensionless | ||
:<math> GLR </math> = gas-liquid ratio, scf/bbl | :<math> GLR </math> = gas-liquid ratio, scf/bbl | ||
− | :<math> | + | :<math> L_1, L_2, L_3, L_4 </math> = correlation variables, dimensionless |
− | + | :<math> N_FR </math> = Froude number, dimensionless | |
− | |||
− | :<math> | ||
:<math> N_LV </math> = liquid velocity number, dimensionless | :<math> N_LV </math> = liquid velocity number, dimensionless | ||
:<math> p </math> = pressure, psia | :<math> p </math> = pressure, psia | ||
:<math> q_c </math> = conversion constant equal to 32.174049, lb<sub>m</sub>ft / lb<sub>f</sub>sec<sup>2</sup> | :<math> q_c </math> = conversion constant equal to 32.174049, lb<sub>m</sub>ft / lb<sub>f</sub>sec<sup>2</sup> | ||
− | :<math> q </math> = | + | :<math> q </math> = flow rate, bbl/d - liquid, scf/d - gas |
:<math> Re </math> = Reynolds number, dimensionless | :<math> Re </math> = Reynolds number, dimensionless | ||
:<math> R_s </math> = solution gas-oil ratio, scf/stb | :<math> R_s </math> = solution gas-oil ratio, scf/stb | ||
+ | :<math> S </math> = correlation variable, dimensionless | ||
:<math> SG </math> = specific gravity, dimensionless | :<math> SG </math> = specific gravity, dimensionless | ||
:<math> T </math> = temperature, °R or °K, follow the subscript | :<math> T </math> = temperature, °R or °K, follow the subscript | ||
:<math> v </math> = velocity, ft/sec | :<math> v </math> = velocity, ft/sec | ||
− | :<math> | + | :<math> WCUT </math> = watercut, fraction |
+ | :<math> y </math> = correlation variable, dimensionless | ||
:<math> z </math> = gas compressibility factor, dimensionless | :<math> z </math> = gas compressibility factor, dimensionless | ||
Line 156: | Line 159: | ||
:<math> \mu </math> = viscosity, cp | :<math> \mu </math> = viscosity, cp | ||
:<math> \rho </math> = density, lb<sub>m</sub>/ft<sup>3</sup> | :<math> \rho </math> = density, lb<sub>m</sub>/ft<sup>3</sup> | ||
− | :<math> \bar \rho </math> = integrated average density at flowing conditions, lb<sub>m</sub>/ft<sup> | + | :<math> \bar \rho </math> = integrated average density at flowing conditions, lb<sub>m</sub>/ft<sup>3</sup> |
:<math> \sigma </math> = surface tension of liquid-air interface, dynes/cm (ref. values: 72 - water, 35 - oil) | :<math> \sigma </math> = surface tension of liquid-air interface, dynes/cm (ref. values: 72 - water, 35 - oil) | ||
− | :<math> \psi </math> = | + | :<math> \psi </math> = inclination correction factor, dimensionless |
+ | :<math> \theta </math> = inclination angle, ° from horizontal | ||
===Subscripts=== | ===Subscripts=== | ||
Line 166: | Line 170: | ||
L = liquid<BR/> | L = liquid<BR/> | ||
m = gas/liquid mixture<BR/> | m = gas/liquid mixture<BR/> | ||
+ | ns = non-slip<BR/> | ||
o = oil<BR/> | o = oil<BR/> | ||
R = °R<BR/> | R = °R<BR/> | ||
Line 191: | Line 196: | ||
<ref name=BB1991>{{cite book | <ref name=BB1991>{{cite book | ||
− | |last1= | + | |last1= Brill |first1=J. P. |
− | |last2= | + | |last2=Beggs|first2=H. D. |
− | + | |title=Two-Phase Flow In Pipes | |
− | + | |edition=6 | |
− | |title= | + | |date=1991 |
− | |edition= | + | |publisher=U. of Tulsa Tulsa |
− | |date= | + | |place=Oklahoma |
− | |publisher= | + | |url=https://www.scribd.com/document/130564301/Twophase-Flow-in-Pipes-Beggs-Amp-Brill |
− | |place= | + | |url-access=subscription |
− | | | ||
}}</ref> | }}</ref> | ||
Line 241: | Line 245: | ||
[[Category:pengtools]] | [[Category:pengtools]] | ||
− | [[Category: | + | [[Category:sPipe]] |
+ | |||
+ | |||
+ | {{#seo: | ||
+ | |title=Beggs and Brill correlation | ||
+ | |titlemode= replace | ||
+ | |keywords=brill wiki, Beggs and Brill, correlation, equation, pipe pressure drop, pipeline sizing, flow rate, fluids flow, Reynolds number, liquid hold up | ||
+ | |description=Beggs and Brill correlation used in pressure drop pipe calculator for pipeline sizing | ||
+ | }} |
Latest revision as of 18:10, 3 November 2018
Contents
Brief
Beggs and Brill is an empirical two-phase flow correlation published in 1972 [1].
It distinguish between 4 flow regimes.
Beggs and Brill is the default VLP correlation in sPipe.
Math & Physics
Fluid flow energy balance
where
Friction factor
No slip Reynolds two phase number:
Colebrook–White [3] equation for the Darcy's friction factor:
Corrected two phase friction factor:
where
and
with constraint:
Discussion
Why Beggs and Brill?
The best correlation for the horizontal flow.— pengtools.com
Flow Diagram
Workflow HL
Determine the flow pattern:
Calculate
- with the constraint [2]
C Uphill:
C Downhill:
- ALL: [2]
- with the restriction [2]
Finally:
- SEGREGATED, INTERMITTENT, DISTRIBUTED:
- TRANSITION:
where:
Modifications
1. Force approach gas at low CL. If CL<0.001 Then f'=f.
2. Force approach to single phase fluid. If HL>1 Then HL=1.
3. Use calculated water density instead of the constant value of 62.4 lbm/ft3.
Nomenclature
- = correlation variable, dimensionless
- = flow area, ft2
- = formation factor, bbl/stb
- = correlation variable, dimensionless
- = non-slip liquid holdup factor, dimensionless
- = pipe diameter, ft
- = total flux weight, lbm/ft2/sec
- = depth, ft
- = liquid holdup factor, dimensionless
- = liquid holdup factor when flow is horizontal, dimensionless
- = friction factor, dimensionless
- = corrected friction factor, dimensionless
- = gas-liquid ratio, scf/bbl
- = correlation variables, dimensionless
- = Froude number, dimensionless
- = liquid velocity number, dimensionless
- = pressure, psia
- = conversion constant equal to 32.174049, lbmft / lbfsec2
- = flow rate, bbl/d - liquid, scf/d - gas
- = Reynolds number, dimensionless
- = solution gas-oil ratio, scf/stb
- = correlation variable, dimensionless
- = specific gravity, dimensionless
- = temperature, °R or °K, follow the subscript
- = velocity, ft/sec
- = watercut, fraction
- = correlation variable, dimensionless
- = gas compressibility factor, dimensionless
Greek symbols
- = absolute roughness, ft
- = viscosity, cp
- = density, lbm/ft3
- = integrated average density at flowing conditions, lbm/ft3
- = surface tension of liquid-air interface, dynes/cm (ref. values: 72 - water, 35 - oil)
- = inclination correction factor, dimensionless
- = inclination angle, ° from horizontal
Subscripts
g = gas
K = °K
L = liquid
m = gas/liquid mixture
ns = non-slip
o = oil
R = °R
SL = superficial liquid
SG = superficial gas
w = water
References
- ↑ 1.0 1.1 1.2 1.3 Beggs, H. D.; Brill, J. P. (May 1973). "A Study of Two-Phase Flow in Inclined Pipes". Journal of Petroleum Technology. AIME. 255 (SPE-4007-PA).
- ↑ 2.00 2.01 2.02 2.03 2.04 2.05 2.06 2.07 2.08 2.09 2.10 2.11 2.12 2.13 2.14 2.15 2.16 2.17 2.18 2.19 2.20 2.21 2.22 2.23 2.24 2.25 2.26 Brill, J. P.; Beggs, H. D. (1991). Two-Phase Flow In Pipes (6 ed.). Oklahoma: U. of Tulsa Tulsa.
- ↑ Colebrook, C. F. (1938–1939). "Turbulent Flow in Pipes, With Particular Reference to the Transition Region Between the Smooth and Rough Pipe Laws". Journal of the Institution of Civil Engineers. London, England. 11: 133–156.
- ↑ Moody, L. F. (1944). "Friction factors for pipe flow". Transactions of the ASME. 66 (8): 671–684.
- ↑ 5.0 5.1 5.2 5.3 5.4 5.5 5.6 Lyons, W.C. (1996). Standard handbook of petroleum and natural gas engineering. 2. Houston, TX: Gulf Professional Publishing. ISBN 0-88415-643-5.