SPREADSHEETS SERIES No. 0015SB

Horizontal Separator with Inlet Nozzle with 90° Elbow (Gas - Oil)

Process Calculation

( Enter values only in yellow cells)

DATA INPUT

Gas Standard Volumetric Flow, Qs =

MMSCFPD

API Gravity of Condensate, GsL =

Standard Pressure, Ps =

psia

Specific Gravity of Gas, GsG =

Standard Temperature, Ts =

°F

Liquid Flow Rate, QL =

BPD

TsR =

°R

Operating Pressure, Po =

psig

Compressibility Factor @ ToR (Z) =

psia

Operating Temperature, To =

°F

Compressibility Factor @ TsR (Zs) =

ToR =

°R

Fluid Retention time (operation), Tr1 =

min

With Mesh

Fluid Retention time alarm high, Tr2 =

min

Longest side of a rectangular mesh =

Fluid Retention time alarm low, Tr3 =

min

Mesh thickness =

in.

With Alarm

The velocity of the gas in the outlet nozzle, VGN =

ft/s

(Considering Maximum Allowable: 60-90 ft/s)

The condensate exit velocity, VLN =

ft/s

(Considering Maximum Allowable: 3 ft/s)

INTERMEDIATE CALCULATIONS

Vessel Length tan-tan, L =

Assuming a length L seam-to-seam of a container. The common lengths starting

Adjust L as necessary. An L/D ratio between 2.5 and 6 is

with 2.25 m (7.5 feet) and increase in increments of 75 cm (2.5 ft).

satisfactory.

Vessel Effective Length, Leff =

It corresponds to the distance between the inlet nozzle and the gas outlet.

Relationship L/D =

P ≤ 250 psig

use

2.5

≤

3.0

As per operating pressure an initial value of L

250 < P ≤ 500 psig

use

3.0

≤

4.0

P > 500 psig

use

4.0

≤

6.0

Selected Vessel Diameter, D =

Selected Vessel Radius, R =

Height measured from the bottom

Cross sectional areas by circular segment

Height the liquid in the vessel hLLLL-botton, h5 =

Cross sectional area between LLLL-botton, A5 =

ft²

The recommended minimum distance from the low-low level of liquid LLLL to the liquid outlet nozzle is 0.75 ft (9 in.)

hLLL-botton =

Cross sectional area, hLLL-LLLL (emergency) by Volume, A4v =

ft²

hLLL-LLLL (emergency), h4 =

Cross sectional area, hLLL-LLLL (emergency) by h4, A4 =

ft²

A4 ≥ A4v

hHLL-botton =

Cross sectional area, hHLL-LLL (Operation) by Volume, A3v =

ft²

hHLL-LLL (operation), h3 =

Cross sectional area, hHLL-LLL (Operation) by h3, A3 =

ft²

A3 ≥ A3v

hHHLL-botton =

Cross sectional area, hHHLL-HLL (emergency) by Volume, A2v =

ft²

hHHLL-HLL (emergency), h2 =

Cross sectional area, hHHLL-HLL (emergency) by h2, A2 =

ft²

A2 ≥ A2v

htop-botton =

Cross sectional Gas Area Calculation, AG =

ft²

Height the gas in the vessel htop-HHLL, h1 =

Area of Gas by h1, A1 =

ft²

A1 ≥ AG

For horizontal drum with mesh the minimum vapor space should

be dimensioned for ho + mesh thickness + 300 mm (12 in.)

Total Area of Vessel by sum of cross sectional area, A =

ft²

or 20% of the diameter of the drum, whatever is greater.

Total Cross Sectional Area of Vessel πR², A =

ft²

For horizontal drum without mesh the minimum vapor space

should be dimensioned for 300 mm (12 in.) or 20% of the

diameter of the drum, whatever is greater.

Fulfill minimum vapor space in the vessel htop-HHLL, h1 =

CALCULATIONS

Specific Gravity, GS =

GS =

141.5

°API+131.5

Liquid Density, ρL =

lbs/ft³

ρL = GS x ρwater

Air Density, ρair =

lbs/ft³

ρair =

P x PM

R x ToR x Z

Gas density: ρG =

lbs/ft³

ρG = GS x ρair

Condensate Mass Flow: WL =

lbs/s

WL =

QL x ρL x 5.61

24x3600

Operation Gas Flow, QG =

ft³/s

QG =

Ps x Qs x ToR x Z

P x TsR x Zs x 24 x 3600

Gas Mass Flow: WG =

lbs/s

WG = QG x ρG

Relationship L/D =

Relationship L/D (NOTE: minimum allowable L = 7.5 feet)

K =

0.40

2.5

≤

4.0

K =

0.50

4.0

≤

6.0

K =

0.50

(L)

6.0

LBASE

(NOTE: maximum allowable K = 0.7)

Where:

LBASE

6 x D

Gas Speed Calculation, VG =

ft/s

VG =

K x

(

ρL - ρG

)

ρG

Cross Sectional Gas Area Calculation, AG =

ft²

AG =

Liquid Flow Rate Calculation, QL =

ft³/s

QL =

ΡL

Mixture density, ρMIX =

lbs/ft³

ρmix =

WL + WG

QL + QG

Speed in Nozzle, for the mixture VM =

ft/s

VMIX =

(Maximum Allowable: 30 ft/s)

ft/s

(ρMIX)¹ʹ²

Inlet Nozzle Diameter, dI =

in.

dI =

(

4(QL+QG)

)

Selected Inlet Nozzle Diameter, dI =

in.

π x VMIX

Gas Outlet Nozzle Diameter, dG =

in.

dG =

(

4QG

)

Selected Gas Outlet Nozzle Diameter, dG =

in.

π x VG

Liquid Outlet Nozzle Diameter, dL =

in.

dL =

(

4QL

)

Selected Liquid Outlet Nozzle Diameter, dL =

in.

π x VL

hLLLL-botton, h5 =

The minimum distance from the low-low level of liquid LLLL to the liquid outlet nozzle

is 0.75 ft (9 in.)

Wet perimeter angle Ø5 =

Rad

Ø5 =

2 acos

(

1 -

hLLLL-botton

)

Cross sectional area between hLLLL-botton, A5 =

ft²

A5 =

[

D²

(

Ø5

sen Ø5

)

]

Liquid retention volume between hLLL-LLLL, Vr3 =

ft³

Vr3 = 60 x QL x Tr3

Cross sectional area, hLLL-LLLL (emergency) by Volume, A4v =

ft²

A4 = Vr3/Leff

hLLL-botton =

Wet perimeter angle Ø4 =

Rad

Ø4 =

2 acos

(

1 -

hLLL-botton

)

Cross sectional area, hLLL-LLLL (emergency) by h4, A4 =

ft²

A4 =

[

D²

(

Ø4

sen Ø4

)

]

Retention Time, Tr1

Fluid Retention time (operation), Tr1 =

min.

For Crude ºAPI ≥ 40 ® Tr1 = 1½ min

For Crude 25 < ºAPI < 40 ® Tr1 = 3 min

For Crude ºAPI ≤ 25 ® Tr1 = 5 min

Liquid retention volume in Operation, Vr1 =

ft³

Vr1 = 60 x QL x Tr1

Cross sectional area, hHLL-LLL (Operation) by Volume, A3v =

ft²

A3 = Vr1/Leff

hHLL-botton =

Wet perimeter angle Ø3 =

Rad

Ø3 =

2 acos

(

1 -

hHLL-botton

)

Cross sectional area, hHLL-LLL (Operation) by h3, A3 =

ft²

A3 =

[

D²

(

Ø3

sen Ø3

)

]

A4 - A5

Liquid retention volume between hHHLL-HLL, Vr2 =

ft³

Vr2 = 60 x QL x Tr2

Cross sectional area, hHHLL-HLL (emergency) by Volume, A2v =

ft²

A2 = Vr2/Leff

hHHLL-botton =

Wet perimeter angle Ø2 =

Rad

Ø2 =

2 acos

(

1 -

hHHLL-botton

)

Cross sectional area, hHHLL-HLL (emergency) by h2, A2 =

ft²

A2 =

[

D²

(

Ø2

sen Ø2

)

]

A3 - A4 - A5

htop-botton =

For horizontal drum with mesh the minimum vapor space should be dimensioned for ho + mesh thickness + 300 mm (12 in.) or 20% of the diameter of the drum, whatever is greater.

Height the gas in the vessel htop-HHLL, h1 =

For horizontal drum without mesh the minimum vapor space should be dimensioned for 300 mm (12 in.) or 20% of the diameter of the drum, whatever is greater.

The minimum distance between the Mesh and the gas outlet nozzle ho should be adequate to prevent maldistribution of the flow through the mesh. The minimum distance for this purpose is presented in the following equation:

The min. dist. between the Mesh & the gas outlet nozzle, ho =

ho =

FDmesh - dG

where:

ho = Minimum distance from the top of the mesh to the gas outlet nozzle, mm (in.),

DMesh = Longest side of a rectangular mesh, mm (ft),

dG = Outlet nozzle diameter mm (in),

F =Factor whose value depends on the units used 1 (SI Units) y 12 (US Customary Units).

Wet perimeter angle Ø1 =

Rad

Ø1 =

2 acos

(

1 -

htop-botton

)

Cross sectional area of Gas by h1, A1 =

ft²

A1 =

[

D²

(

Ø1

sen Ø1

)

]

A2 - A3 - A4 - A5

Horizontal Separator with Inlet nozzle with 90° Elbow (Gas - Oil)

Schematic Drawing

DIMENSIONS

Vessel Inner Diameter, D =

Vessel Length, L tan-tan =

Selected Inlet Nozzle Diameter, dI =

in.

Selected Gas Outlet Nozzle Diameter, dG =

in.

Selected Liquid Outlet Nozzle Diameter, dL =

in.

h/D

The minimum distance between the Mesh

Height the gas in the vessel htop-HHLL, h1 =

and the gas outlet nozzle, ho =

Height the liquid in the vessel hHHLL-HLL (emergency), h2 =

Height the liquid in the vessel hHLL-LLL (operation), h3 =

Height the liquid in the vessel hLLL-LLLL (emergency), h4 =

Height the liquid in the vessel hLLLL-botton, h5 =

NOTES:

For horizontal drum with mesh the minimum vapor space should be dimensioned for ho (see note 6) + 300 mm (12 in.) or 20% of the diameter of the drum, whatever is greater. For horizontal drum without mesh the minimum vapor space should be dimensioned for 300 mm (12 in.) or 20% of the diameter of the drum, whatever is greater.

If applicable: five minutes of liquid flow between HHLL and HLL (same for LLLL and LLL). If it does not apply, there is only HLL and LLL.

Height between HLL and LLL depends on the retention minutes based on the flow of liquid feed.

The minimum distance considering the dimensions of the center to the end of the elbow of 90° depending on the nominal size of the pipe.

For the inlet nozzle section, a 90° elbow can be used at each end of the drum. These entries should point to the nearest cap.

The minimum distance between the Mesh and the gas outlet nozzle should be adequate to prevent maldistribution of the flow through the mesh. The minimum distance for this purpose is presented in the following equation:

ho =

F DMESH - dG

where:
ho = Minimum distance from the top of the mesh to the gas outlet nozzle, mm (in.),
DMesh = Longest side of a rectangular mesh, mm (ft),
dG = Outlet nozzle diameter mm (in)
F =Factor whose value depends on the units used 1 (SI Units) y 12 (US Customary Units)."

The minimum distance from the low-low level of liquid LLLL to the liquid outlet nozzle is 230 mm (9 in.)

Shock plates should be installed, facing the entrance nozzles, 90° elbow type, to protect the wall of the drum. The recommended dimensions for such plates are:
NOZZLE DIAMETER            PLATE DIAMETER
Up to 100 mm (4 in.)       Double the diameter of the nozzle.
≥ 150 mm (6 in.)               1.5 times the diameter of the nozzle.

Discussion and References

Horizontal Separator with Inlet nozzle with 90° Elbow (Gas - Oil)

Process Calculation

Reference Books

1. Campbell, John M., “Gas Conditioning and Processing” (1976).

2. Kerns, G.D., “New Charts Speed Drum Sizing", HYDRO. PROC. 39 (7). (July, 1960).

3. Lobdell, W. R., y L. M. Ayers, “Separators Cut Weight, Cost for Gas–Production Equipment, (March 10, 1975).

4. Perry, Robert H., y Cecil H. Chilton, “Chemical Engineers’ Handbook,” Fifth Edition, McGraw–Hill, (1973).

5. Scheiman, A.D., “Horizontal Vapor–Liquid Separators”, HYDRO. PROC. 43(5), (May, 1964).

6. Watkins, R.N., “Sizing Separators and Accumulators,” HYDRO. PROC. 46(11), (Nov. 1967).

7. Svrcek. W.Y, Monmery, W.D., “Design two phase separators within the right limits”, Chemical Engineering Progress, Octubre 1993.

8. Gas Processor Suppliers Association (GPSA) Engineering Data Book, Vol 1, Section 7 “Separators and Filter”. Tenth Edition, 1987.

9. Ven Te Chow, "Open Channel Hydraulics" (1959).

Density Calculation of Condensate: ρL (lbs/ft³)

Specific Gravity:

GS =

141.5

°API+131.5

Liquid Density:

ρL = GS x ρwater

Where:

ρwater = 62.4 lb/ft³

Density Gas Calculation: ρG (lbs/ft³)

Air Density: ρ_AIR_{@ Operating Temperature, °F}

ρair =

PxPM

RxTxZ

Where:

P = absolute pressure (PSIA)

P = Operating Pressure, Po + 14.7 (PSIA)

MW = Molecular Weight - air (28.97 lbm / lbmol)

R = universal gas constant (10.73 lbm/lbmol°R)

T = absolute temperature (°R)

T = To + 460 °R

Z = compressibility factor

Gas density: ρG (lbs/ft³)

ρG= GS x ρair

Condensate Mass Flow: WL (lbs/s)

WL =

QL x ρ_L x 5.61

24x3600

Where:

QL = Liquid Flow Rate, BPD

ρL = Liquid Density, lbs/ft³

Operation Gas Flow, Q_G (ft³/s)

QG =

Ps x Qs x ToR x Z

P x TsR x Zs x 24 x 3600

Where:

Ps = 14.7 PSIA

Qs = Gas Standard Volumetric Flow, MMSCFPD

ToR = To + 460, °R

Z = compressibility factor @ ToR

P = Po +14.7, PSIA

TsR = Ts + 460, °R

Zs = compressibility factor @ TsR

Gas Mass Flow: WG, (lbs/s)

WG = QG x r_G

Where:

QG = Gas Flow Rate, ft³/s

ρG = Gas Density, lbs/ft³

According to the operating pressure, select and an initial value of L/D ratio.

P ≤ 250 psig

use

2.5

≤

3.0

250 < P ≤ 500 psig

use

3.0

≤

4.0

P > 500 psig

use

4.0

≤

6.0

Assume an initial length (L) of 7.5 feet

Assuming a length L seam-to-seam of a container. The common lengths starting with 2.25 m (7.5 feet) and increase in increments of 75 cm (2.5 ft).

According to the initial value of L/D ratio and initial length L, select an initial value of D and K

The values for the constant K have been determined from the equipment in operation.

K =

0.40

2.5

≤

4.0

K =

0.50

4.0

≤

6.0

K =

0.50

(L)

6.0

LBASE

(NOTE: maximum allowable K = 0.7)

Where:

LBASE

6 x D

Effective length (Leff)

It corresponds to the distance between the inlet nozzle and the gas outlet, which is the horizontal distance traveled by a drop of liquid from the inlet nozzle, until it is fully decanted and joined to the liquid retained in the container, without be carried away by the vapor phase that comes out of the gas outlet nozzle.

Gas Speed Calculation, VG (ft/s)

VG =

K x

(

ρL - ρG

)

ρG

Cross Sectional Area Gas Calculation, A (ft²)

AG =

Liquid Flow Rate Calculation, Q_L (ft/s)

QL =

ΡL

Mixture density, ρ_MIX

ρMIX =

WL + WG

QL + QG

Allowable Speed in Nozzle, for the mixture (Maximum Allowable: 30 ft/s)

VMIX =

(ρMIX)¹ʹ²

Inlet Nozzle Diameter, dI

dI =

(

4(QL+QG)

)

π x VMIX

Gas Outlet Nozzle Diameter, d_G

Considering V_GN = 60-90 ft/s

dG =

(

4QG

)

π x VGN

Liquid Outlet Nozzle Diameter, d_L

Considering V_LN = 3 ft/s

dL =

(

4QL

)

π x VLN

Calculation D

h5 calculation

The minimum distance from the low-low level of liquid LLLL to the liquid outlet nozzle (h5) is 0.75 ft minimum (9 in).

Wet perimeter angle Ø5

Ø5 =

2 acos

(

1 -

hLLLL-botton

)

Cross sectional area hLLLL-botton, A5

A5 =

[

D²

(

Ø5

sen Ø5

)

]

h4 & h3 calculation

The liquid retention volume per operator response time when an alarm is triggered (either high or low), between the HHLL and the LLLL, is obtained by multiplying the liquid feed flow by the assumed response time, (Tr2) which is estimated at 5 min (300 s) from HLL to HHLL and (Tr3) of 5 min more (300 s), from LLL to LLLL:

h4 calculation

Vr3 = 60 x QL x Tr3

and

A4v = Vr3/Leff

To know the height of the volume, it is necessary to know the height of the corresponding circular element using the following equations:

Wet perimeter angle Ø4

Ø4 =

2 acos

(

1 -

hLLL-botton

)

Cross sectional area, hLLL-LLLL (emergency) by h4

A4 =

[

D²

(

Ø4

sen Ø4

)

]

Then we must iterate by looking for the value of h4* that makes A4 equal or slightly larger than A4v.

(*) The value of h4 obtained is measured from the bottom of the vessel. You must subtract the heights of the previous circular segments to get the height of A4.

h2 calculation

Vr2 = 60 x QL x Tr2

and

A2v = Vr2/Leff

To know the height of the volume, it is necessary to know the height of the corresponding circular element using the following equations:

Wet perimeter angle Ø2

Ø2 =

2 acos

(

1 -

hHHLL-botton

)

Cross sectional area, hHHLL-HLL (emergency) by h2, A2

A2 =

[

D²

(

Ø2

sen Ø2

)

]

A3 - A4 - A5

Then we must iterate by looking for the value of h2* that makes A2 equal or slightly larger than A2v.

(*) The value of h2 obtained is measured from the bottom of the container. You must subtract the heights of the previous area segments to get the height of A2.

h3 calculation

Height between HLL and LLL (h3) depends on the retention minutes based on the flow of liquid feed.
The liquid operation retention volume, between the HLL and the LLL (h3), is obtained by multiplying the liquid feed flow by the retention time Tr1:

Vr1 = 60 x QL x Tr1

and

A3v = Vr1/Leff

Retention Time, Tr1

For Crude ºAPI ≥ 40 ® Tr1 = 1½ min

For Crude 25 < ºAPI < 40 ® Tr1 = 3 min

For Crude ºAPI ≤ 25 ® Tr1 = 5 min

To know the height of the volume, it is necessary to know the height of the corresponding circular element using the following equations:

Wet perimeter angle Ø3

Ø3 =

2 acos

(

1 -

hHLL-botton

)

Cross sectional area, hHLL-LLL (Operation) by h3, A3

A3 =

[

D²

(

Ø3

sen Ø3

)

]

A4 - A5

Then we must iterate by looking for the value of h3* that makes A3 equal or slightly larger than A3v.

(*) The value of h3 obtained is measured from the bottom of the container. You must subtract the heights of the previous area segments to get the height of A3.

Calculation h1

Cross Sectional Area Gas Calculation, A (ft²)

AG =

To know the height of the volume, it is necessary to know the height of the corresponding circular element using the following equations:

Wet perimeter angle Ø1

Ø1 =

2 acos

(

1 -

htop-botton

)

Cross Sectional Area of Gas by h1

A1 =

[

D²

(

Ø1

sen Ø1

)

]

A2 - A3 - A4 - A5

Then we must iterate by looking for the value of h1* that makes A1 equal or slightly larger than AG.

(*) The value of h1 obtained is measured from the bottom of the container. You must subtract the heights of the previous area segments to get the height of A1.

Minimum height required for h1

For horizontal drum with mesh the minimum vapor space should be dimensioned for ho + mesh thickness + 300 mm (12 in.) or 20% of the diameter of the drum, whatever is greater.

For horizontal drum without mesh the minimum vapor space should be dimensioned for 300 mm (12 in.) or 20% of the diameter of the drum, whatever is greater.

ho =

FDmesh - dG

where:

ho = Minimum distance from the top of the mesh to the gas outlet nozzle, mm (in.),

DMesh = Longest side of a rectangular mesh, mm (ft),

dG = Outlet nozzle diameter mm (in),

F =Factor whose value depends on the units used 1 (SI Units) y 12 (US Customary Units).

Vessel Diamenter, D

D = h1 + h2 + h3 + h4 + h5