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Surface Production OperationsENPE 505
1
ENPE 505Lecture Notes #5
Separation SystemsHassan Hassanzadeh
Separation SystemsLearning Objectives
identify factor affecting separation process
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distinguish appropriate separation vessels perform separator sizing calculations for oil, gas
and water separation processes. carry out design calculations associated with
selection of gas cleaning equipments.
Separation SystemsProper separator design is important because a separation vessel is normally the initial processing vessel in any facility, and improper design of this process component can bottleneck and reduce the capacity of the entire facility.
Separators are classified as two-phase if they separate gas from the total liquid stream and three-phase if they also separate the liquid stream
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total liquid stream and three-phase if they also separate the liquid stream into its crude oil and water components.
Separators are sometimes called gas scrubbers when the ratio of gas rate to liquid rate is very high.
Factors affecting separator design
Characteristics of the flow stream will greatly affect the design and operation of a separator. The following factors must be determined before separator design:
1. Gas and liquid flow rates (minimum, average, and peak),2. Operating and design pressures and temperatures,3. Surging or slugging tendencies of the feed streams,
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3. Surging or slugging tendencies of the feed streams,4. Physical properties of the fluids such as density and compressibility factor.5. Designed degree of separation (e.g., removing 100% of particles greater than
10 microns),6. Presence of impurities (paraffin, sand, scale, etc.),7. Foaming tendencies of the crude oil,8. Corrosive tendencies of the liquids or gas.
Separation Systems (cont.)A separator is normally constructed in such a way that it has the following features:
1. A centrifugal inlet device for primary separation of the liquid and gas
2. Provides a large settling section of sufficient height or length to allow liquid droplets to settle out of the gas stream with adequate surge room for slugs of liquid.
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3. Equipped with a mist extractor or eliminator near the gas outlet to coalesce small particles of liquid that do not settle out by gravity.
4. Allows adequate controls consisting of level control, liquid dump valve, gas backpressure valve, safety relief valve, pressure gauge, gauge glass, instrument gas regulator, and piping.
1. Centrifugal action2. Gravity settling3. Impingement
Mechanical Separation
Other separatorsDouble-barrel horizontal separator
Possibility of large liquid slugshorizontal separator with a boot
7http://cgm-ing.com/twister/news/separation-goes-supersonic/
Venturi SeparatorsCentrifugal Separator or cylindrical cyclone separators (CCS)100 to 50,000 bbl/d2 to 12 in diameterBest suited for clean gas streamsNo moving partsLow maintenanceCompact, in terms of weight and spaceLow costDesign is rather sensitive to flow rateLarge pressure drop
Other separators (cont.)Filter separator
inch thick cylinder fiberglass surrounds the perforated metal cylinder. A micron fiber fabric layer is located on both sides of
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1. High gas and low liquid flow applications2. Horizontal or vertical3. Compressor inlet4. Final scrubber upstream of glycol contactor5. Removal of 100% of 1 particles to 99% of liquid particles
layer is located on both sides of the fiberglass.
Other separators (cont.)Scrubbers
A scrubber is a two-phase separator that is designed to recover liquids carried over from the gas outlets of
Separators are sometimes called gas scrubbers when the ratio of gas rate to liquid rate is very high.
9
to recover liquids carried over from the gas outlets of production separators or to catch liquids condensed due to cooling or pressure drop.Applications include upstream of mechanical equipment such as compressors, upstream of gas dehydration equipment.
Other separators (cont.)Slug Catcher
A "slug catcher," commonly used in gas gathering pipelines, is a special case of two-phase gas-liquid separator that is designed to handle large gas capacities and liquid slugs on a regular basis. Since the gathering systems are designed to handle primarily gas, the presence of liquid restricts flow and causes excessive pressure drop in the piping. Pigging is periodically used to sweep the lines of liquids. When the pigs sweep the liquid out of the gathering lines, large volumes of liquids must be handled by the downstream separation equipment. The separators used in this service are called slug catchers.
10http://www.tfes.com
Separator internalsInlet divertersInlet diverters serve to impart flow direction of the entering vapor/liquid stream and provide primary separation between the liquid and vapor.
Baffle diverter
Centrifugal diverter
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Elbow diverter
Separator internals (cont.)
In long horizontal vessels, usually located on floating structures, it may be necessary to install wave breakers. The waves may result from surges of liquids
Cyclone baffle
Tangential raceway
Wave Breakers
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necessary to install wave breakers. The waves may result from surges of liquids entering the vessel. Wave breakers are nothing more than perforated baffles or plates that are placed perpendicular to the flow located in the liquid collection section of the separator. These baffles dampen any wave action that may be caused by incoming fluids. The wave action in the vessel must be maintained so that liquid level controllers, level safety switches, and weirs perform properly on floating or compliant structures where internal waves may be set up by the motion of the foundation.
Separator internals (cont.)Defoaming PlatesFoam at the interface may occur when gas bubbles are liberated from the liquid. Foam can severely degrade the performance of a separator. This foam can be stabilized with the addition of chemicals at the inlet. Many times a more effective solution is to force the foam to pass through a series of inclined parallel plates or tubes.
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series of inclined parallel plates or tubes.
Vortex BreakerLiquid leaving a separator may form vortices or whirlpools, which can pull gas down into the liquid outlet. Therefore, horizontal separators are often equipped with vortex breakers, which prevent a vortex from developing when the liquid control valve is open.
These closely spaced plates or tubes provide additional surface area, which break up the foam and allow foam to collapse into the liquid layer
Separator internals (cont.)A stilling well, which is simply a slotted pipe fitting surrounding an internallevel control displacer, protects the displacer from currents, waves, and other disturbances that could cause the displacer to sense an incorrect level measurement.
Stilling Well
Sand jets and drainsIn horizontal separators one worry is the accumulation of sand and solids
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In horizontal separators one worry is the accumulation of sand and solidsat the bottom of the vessel. If allowed to build up, these solids will upsetthe separator operations by taking up vessel volume. In addition accumulation of such solid material promote corrosion. Generally, the solidssettle to the bottom and become well packed. To remove the solids, sand drains are opened in a controlled manner, and then high-pressure fluid, usually produced water, is pumped through the jets (20 ft/s) to agitate the solids and flush them down the drains. Drain and its associated jets, should be installed at intervals not exceeding 5 ft.
Mist extractorImpingement type is the most widely used mist eliminator. This type offers good balance between efficiency, operating range, pressure drop requirement, and installed cost. It consists of baffles, wire meshes, andmicro fiber pads.
When a fluid stream approaching a target (baffle or disc) droplets can be captured by target via any of the following mechanisms:
Inertial impaction: because of their mass, particles 1-10 microns in diameter in the gas stream have sufficient momentum to break through the gas streamlines and continue to move in a straight line until they impinge on the target.
Direct interception: Particles 0.3 to I microns do not have sufficient momentum to
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Direct interception: Particles 0.3 to I microns do not have sufficient momentum to break through the gas streamlines. Instead, they are carried around the target by the gas stream. However, if the streamline in which the particle is traveling happens to lie close enough to the target so that the distance from the particle centerline to the target is less than one-half the particle's diameter, the particle can touch the target and be collected. Interception effectiveness is a function of pore structure. The smaller thepores, the greater the media to intercept particles.
Diffusion: smaller particles, usually smaller than 0.3 microns in diameter, exhibit random Brownian motion caused by collisions with the gas molecules. This random motion will cause these small particles to strike the target and be collected, even if the gas velocity is zero. Typical velocity ranges from 1-4 ft/min.
Separation principlesImpingementGas entertained liquid particles strikes a surface such as baffle plate,or wire mesh. The gas flows around the flow obstruction, but the liquiddroplet impinge and collect on the surface
16Impingement technique can usually handle droplets down to a size of 5 microns
Mist extractors (cont.)10-40 micron in diameter liquid droplets10-15 mm H2O pressure drop
17
5-75 mm space between plates, and total depth of 150-300mm
Mist extractors (cont.)An "arch" plate type mist extractor
vane-type mist extractor made from angle iron
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knitted mesh mist eliminator
www.amistco.com
3-7 in in thickness and mesh density of 10-12 lb/ft3. constructed from wires of 0.1-0.28 mm with a void fraction of 0.95-0.99.
Mist extractors (cont.)
3-10 micron in diameter liquid droplets
wire-mesh mist extractor
19Dimensions for the placement of a wire-mesh mist extractor.[ H representsminimum height, and H, must be at least 1 foot (305mm).]
Mist extractors (cont.)Micro-fiber mist extractors use very small diameter fibers, usually lessthan 0.02 mm, to capture very small droplets. Gas and liquid flow ishorizontal and co-current. Because the micro-fiber unit is manufacturedfrom densely packed fiber, drainage by gravity inside the unit is limited.Much of the liquid is eventually pushed through the micro-fiber and drains downstream face. The surface area of a micro fiber mist extractor can be 3 to 150 times that of a wire mesh unit of equal volume.
20
Typical velocity ranges from 20-60 ft/min for impaction type and 1-4 ft/minfor diffusion type.
Mist extractors (cont.) Centrifugal mist extractorA coalescing pack mist extractor
21
These units can be more efficient than either wire-mesh or vanes and are least susceptible to plugging. However, they are not in common use in production operation because their removal efficiencies are sensitive to small change in flow rate. In addition, they require large pressure drop to create centrifugal forces.
Potential operating problemsFoamy crudePresence of impurities, other than water such as CO2, completion and workover fluids, and corrosion inhibitors, that are incompatible with the wellbore fluids. Foaming causes:
1. Difficulty in level control2. It can occupy much of the separator volume because large volume to
weight of foam decreasing separation efficiency.3. Entertainment of foam in oil and gas streams
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The foaming tendencies of a crude oil can be determined with laboratory tests (ASTM D892).Paraffin
Accumulation of paraffin in the liquid section and mesh pad mist extractors in the gas section.When paraffin is a problem, the use of plate type or centrifugal mist extractors should be considered. Manways, handholes, and nozzles should provided to allow steam, solvent, or other type of cleaning of the separator internals. The bulk temperature of the liquid should always be kept above the cloud point of the crud oil. The cloud point of a fluid is the temperature at which dissolved solids are no longer completely soluble, precipitating as a second phase giving the fluid a cloudy appearance
Potential operating problems (cont.)Sand productionSand production can be very problematic by causing cutout of valve trim, plugging of separator internals, and accumulation in the bottom of the separators.
Liquid carryoverLiquid carryover occurs when free liquid escapes with the gas phase. Liquid carryover can indicate high liquid level, damage to vessel internals, foam, improper design, plugged liquid outlets, or a flow rate exceeds the vessels design rate. It can be prevented by installation of level safety high sensor.
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design rate. It can be prevented by installation of level safety high sensor.
Gas blowbyGas blowby occurs when free gas escapes with the liquid phase and can be an indication of low liquid level, vortexing, or level control failure. It can be prevented by installation of level safety low. In addition, downstream process components should be equipped with a pressure safety high sensor and a pressure safety valve sized for gas carry through.Liquid slugsTwo-phase flow lines and pipelines tend to accumulate liquids in low spots in the lines. When the level of liquid in theses low spots rises high enough to block the gas flow, then the gas will push the liquid along the line as a slug.
Separation principles
rdF lpa23
6pi=
( )Q
hRRt io
22
=
pi
lp rddrv
4 2==
Centrifugal Separation
FaFd
Residence time = Centrifuge volume/flow rate
222
821
pgdgdd dvCAvCF pi ==
At equilibrium F =F
Drag force
24
gd
lp
Crd
dtdr
v
34
==At equilibrium Fd=Fa
( )lp
gdio
dCRR
t
3=
( )22
2223pi
l
gdiop h
QCRRd
=
To decrease the droplet size that can be removed, 1. Decrease Q (not feasible)2. Increase height3. Increase rotational speed
Centrifugal separation can usually handle droplets down to a size of 2 microns
Centrifugal force
Separation principles
( ) 36 pglg
gdF pi =
( ) ( )gd 4
Gravity Segregation
Fg
Fd22
8 pgdddvCF pi=
At equilibrium F =F
hfeed
25
( ) ( )g
gl
gd
glp KC
gdv
=
=
34
QLh
QV
t4
2pi==
At equilibrium Fd=Fg
To allow smaller droplet to settle we should maximize the diameter and L
Sounders-Brown equation
t
hv
dtdh
v ==
4hLvQ pi= ( )
gd
glp
CgdhLQ
pi
34
4
=
Gravity Segregation can usually handle droplets down to a size of 80 microns
Effect of Pressure and Temperature
1. Separator pressure, temperature and feed composition2. As the pressure increases, or the temperature decreases, there is a
greater oil liquid recovery, up to a point called the optimum, flash calculations will yield the optimum condition.
3. From practical point of view it may not be possible to operate at this optimum point because of the costs involved, operational problems, or enhanced storage system vapour losses.
26
enhanced storage system vapour losses.4. Generally, separator gas capacity increases with increasing pressure
and decreasing temperature. This is because of pressure and temperature effects on gas and liquid densities, actual volume and allowable velocity through separator.
5. Economic is the foremost concern in actual field operations6. Product sale specification must be considered (oil API, gas BTU/vol.)
Separator sizing and selection1. The design aspects encountered by a petroleum engineer only
involve choosing the correct separator size for a given field installation.
2. Separator sizing is essentially quoted in terms of gas and liquid capacities.
3. Other parameters such as pressure drop through separator, are specified for a given design by the manufacturer
27
( )g
glg Kv
=
specified for a given design by the manufacturer
Gas CapacityThe SoudersBrown equation is widely used for calculating gas capacity of oil/gas separators:
L = density of liquid at operating conditions, lbm/ft3 g = density of gas at operating conditions, lbm/ft3K = empirical factor, D is in ft,Qgsc is in MMSCFD ( )
( )g
glgsc TZ
KpDQ
+
=
4604.2 2
K Values Used for Selecting Separators (Sivalls, 1977)Separator type K Most commonly used K Vertical separators 0.060.35 0.117 with a mist extractor
0.167 without a mist extractorHorizontal separators 0.400.50 0.382 with a mist extractorSpherical - 0.35 with a mist extractorWire mesh mist eliminators 0.35
Separator sizing and selection
28
Wire mesh mist eliminators 0.35Bubble cap trayed columns 0.16 (24-in. spacing)Valve tray columns 0.18 (24-in. spacing)
The SoudersBrown equation can be used to calculate separator diameter
( )g
ggg
g
glg
v
QDDAAvQKv
pi
pi
4
,
4,,
2===
=
Separator sizing and selectionLiquid Capacity
The liquid capacity of a separator relates to the retention time through the settling volume:
t
VQ ll1440
=
QL = liquid capacity, bbl/dayVL = liquid settling volume, bbl t = retention time, min
VL = 0.1339D2h for vertical separators, in bblVL = 0.1339D2(L/2) for horizontal single-tube separators, in bblVL = 0.1339D2(L) for horizontal double-tube separators, in bbl
29
VL = 0.1339D (L) for horizontal double-tube separators, in bblVL = 0.0466D3(D/2)0.5 for spherical separators, in bblL and h are in ft
For a good separation, a sufficient retention time, t, must be provided. From field experience (Sivalls, 1977) Oil & gas separation t= 1 minHigh pressure oil-water-gas t=2-5 minLow pressure oil-water-gas t=5-10 min @ T>100 F
t=10-15 min @ 90 oFt=15-20 min @ 80 oFt=20-25 min @ 70 oFt=25-30 min @ 60 oF
Design considerations (Lockhart et al, 1986)1. For a horizontal or vertical separator L/D should be kept 3 to 83 to 8
due to consideration of fabrication cost, etc.2. For a vertical separator, the vapour-liquid interface (at which the
feed enters) should be at least 2 ft from the bottom and 4 ft from the top of the vessel. This implies a minimum vertical separator height (length) of 6 ft6 ft.
3. For a horizontal separator, the feed enters just above the vapour-liquid interface that may be off-centered to adjust for a gas (or
30
liquid interface that may be off-centered to adjust for a gas (or liquid) capacity as needed. The vapour-liquid interface, however, must be kept at least 10 inches from the bottom and 16 inches from the top of the vessel. This implies a minimum diameter of minimum diameter of 26 inches26 inches.
4. In practice these rules of thumbs may be violated for providing additional features. Therefore standard vertical separators less than 6 ft and horizontal separators of diameter 26 inches are available in the industry.
Design considerations (Lockhart et al, 1986)5. High-pressure separators are generally used for high
gas-oil ratio (gas and gas condensate) wells. In this case, the gas capacity of the separator is the limiting factor.
6. Low-pressure separators are generally used for low gas-oil ratio wells. In this case, the liquid capacity of the separator is the limiting factor.
31
the separator is the limiting factor.
7. The separator chosen must satisfy both the gas as well as liquid capacities.
8. As the GLR increases, the retention time decreases.
tQVtQGLRV
VVV
LL
LG
LG
=
=
= ,
( )GLRQV
ttQVtQGLRL
LL +==
1VG
Separator design using actual separator performance chart
The Sounders-Brown relationship provides only an approximate approach.
A better design can usually be made using actual manufacturers field test data that accounts for the
32
manufacturers field test data that accounts for the dependence of capacity on separator height (for vertical) or length (for horizontal).
Gas capacity of vertical LP separator
33After Sivalls
Gas capacity of vertical HP separator
34After Sivalls
Gas capacity of horizontal LP separator
35After Sivalls
Gas capacity of horizontal HP separator
36After Sivalls
Gas capacity of horizontal HP separator
37After Sivalls
Gas capacity of spherical separator
38After Sivalls
Liquid capacity of horizontal single-tube HP separator
39After Sivalls
Liquid capacity of horizontal single-tube HP separator
40After Sivalls
Arnold and Stewart approach
,
32 DFVACF pi ==
Design theory
In the gravity settling section of a separator, liquid droplets are removedusing the force of gravity. Liquid droplets, contained in the gas, settle ata terminal or "settling" velocity. At this velocity, the force of gravity onthe droplet or "negative buoyant force" equals the drag force exerted onthe droplet due to its movement through the continuous gas phase. Thedrag and buoyant forces on a droplet may be determined from the following equations:
41
6 ,
2DF
gVACF BgdDD
pi ==
VDFD '3pi=
'18
2
DVt
=
equations:
If the flow around the droplet is laminar (Re
Design theory (cont.)Unfortunately, for production facility designs it can be shown thatStokes' law does not govern, and the following more complete formulafor drag coefficient must be used
Vdmg0049.0Re =
dm in micron, g in lbm/ft3, V in ft/s, in cp
42
Equating drag and buoyant forces, the terminal settling velocity is given by (field units)
For CD = 0.34 0.0204dm
, dm in micron
V in ft/s, in cp
Design theory (cont.)Droplet size
From field experience, it appears that if 140 micron droplets are removed in the gravity settling section, the mist extractor will not become flooded and will be able to perform its job of removing those droplets between 10- and 140 micron diameter. Therefore, the gas capacity design equations are all based on 140 micron removal.
Retention timeDefined as the average time a molecule of liquid is retained in
43
molecule of liquid is retained in the vessel, assuming plug flow. The retention time is thus the volume of the liquid storage in the vessel divided by the liquid flow rate.
Liquid re-entrainment is a phenomenon caused by high gas velocity atthe gas-liquid interface of a separator. Momentum transfer from the gasto the liquid causes waves and ripples in the liquid, and then droplets arebroken away from the liquid phase.
Design theory (cont.)
367144421
421
,
222 ddDA
AQV g
gg =
=
==
pipi
2120 PdZTQV scg =
Assuming a horizontal vessel is full half of liquid . Gas velocity is given by: Horizontal separator design
Q in terms of ft/sec is given by:
where Qsc is in MMSCFD, d is in inches, p is in psia, and T is in oR.
PZTBg 02728.0=
PZTQBQQ scgsc 327.0
360024106
=
=
44
Pd
ttd
sc
eff
g
effg V
dVD
t
PdZTQL
VL
t242
,
120 2==
==
Set the residence time of the gas equal to the time required for the droplet to fall to the gas liquid interface
We have
Setting td=tg
Design theory (cont.)
l
effll Q
LdtQQQ
25 42105.6
36002462.5
==
=
Two-phase separators must be sized to provide some liquid retention time so the liquid can reach equilibrium with the gas. For a vessel 50% full of liquid, and with a specified liquid flow rate and retention time:
effeffeff Ld
LdLDVQ
Vt 23
22
1073.214442
142
1 ,
=
=
==
pipi
Ql is in BPD, Q is in ft3/sec.
Ld 242 60
sec.
45
l
effQLd
t2
6042
= in min. tQLd leff 42602
=
Seam-to-Seam LengthFor vessels sized on a gas capacity basis, some portion of the vessel length is required to distribute the flow evenly near the inlet diverter. Another portion of the vessel length is required for the mist extractor. The length of the vessel between the inlet diverter and the mist extractor with evenly distributed flow is the Leff. The seem to seam length may be estimated as the larger of the following:
Lss = Leff +d/12 or Lss = (4/3)Leff for gas capacityFor vessels sized based on a liquid capacity basis Lss = (4/3)Leff
Design theory (cont.)1. Equations described allow for various choices of diameter and length. For
each vessel design, a combination of Leff and d exists that will minimize the cost of the vessel.
2. It can be shown that the smaller the diameter, the less the vessel will weigh and thus the lower its cost. There is a point, however, where decreasing the diameter increases the possibility that high velocity in the gas flow will
Slenderness ratio (L/d)
46
the diameter increases the possibility that high velocity in the gas flow will create waves and re-entrain liquids at the gas-liquid interface.
3. Experience has shown that if the gas capacity governs and the length divided by the diameter, referred to as the "slenderness ratio," is greater than 4 or 5,re-entrainment could become a problem.
4. Most two-phase separators are designed for slenderness ratios between 3 and 4. Slenderness ratios outside the 3 to 4 range may be used, but the design should be checked to assure that re-entrainment will not occur
Horizontal separators sizing other than half fullGas capacity
47
Liquid capacity
If is known, can be determined from a chart in the next slide.
Gas and liquid capacity constraint design constant vs. liquid height of a cylinder for a horizontal separator other than 50% full of liquid ( field units).
Gas capacity
Liquid capacity
48
Design theory (cont.)
, ,
222 ddDAQV gg =
=
==
pipi
PZTBg 02728.0=
By setting the gas retention time equal to the time required for a droplet to settle to the liquid interface, the following equation may be derived
ZTB 02728.0=
Vertical separator-Gas capacity
49
,
18314444 , DA
AV g
gg =
=
==
PBg 02728.0=
PZTQBQQ scgsc 327.0
360024106
=
=
260 PdZTQV scg =
tg VV =
Design theory (cont.)Vertical separator-Liquid capacity
h in inch
ft3/sec
50
In vertical separators whose sizing is liquid dominated, it is common to choose slenderness ratios no greater than 4 to keep the height of the liquid collection section to a reasonable level. Choices of between 3 and 4 are common, although height restrictions may force the choice of a lower slenderness ratio.
sec
Stage separationWhen two or more equilibrium separation stages are used in series, the process is termed stage separation.
Although three to four stages of separation theoretically increase the liquid
Prediction of the performance of the various separators in a multistage separation system can be carried out with compositional computer models
51
Although three to four stages of separation theoretically increase the liquidrecovery over a two-stage separation, the incremental liquid recovery rarelypays out the costcost ofof thethe additionaladditional separatorsseparators. It has been generallyrecognized that two stages of separation plus the stock tank are practicallyoptimum. The increase in liquid recovery for three-stage separation over two-stage separation usually varies from 22 toto 1212%%,, depending on wellstreamcomposition and P&T although 2020 toto 2525%% increases in liquid recoveries havebeen reported.
Stage separation
Np
3rd stage10-75 psig Stock
2nd stage100-500 psig
1st stage gas
2nd stage gasVent gas1st stage
500-1500 psig
Well stream fluid 3rd stage gas
4 stage separation
52
Np
3 stage separation
10-75 psig Stock tank
1st stage100-500 psig
2nd stage10-75 psig Stock
tank
Well stream fluid
1st stage gas 2nd stage gas Vent gas
Np
Stage separation
1st stageStock tankWell stream fluid
1st stage gas Vent gas
Np
1st stage10-100 psig Stock
tankWell stream fluid
1st stage gas Vent gas
Np
2 stage separation
53
2nd stage40-100 psig
1st stage400-1000 psig
Stock tank
Well stream fluid
1st stage gas 2nd stage gas Vent gas
Np
AlternativeArrangement for 3 stage separation
Stage separation
stN
s
p ppR
1
1
=
Pressures at low-stage separations can be determined based on equal pressure ratios between the stages (Campbell, 1976):
whereRp = pressure ratioNst = number of stages -1
54
Nst = number of stages -1p1 = first-stage or high-pressure separator pressure, psiaps = stock-tank pressure, psia
Pressures at the intermediate stages can then be designed with the following formula:
p
ii R
pp 1=
where pi = pressure at stage i, psia.
Stage separation
( )057.0686.012
+=AApp
The equal pressure ratios bear no relationship with the magnitude of separation (i.e., the LGR) Whinery and Campbell (1958) studied three-stage separation for several different types of well streams
For streams with specific gravity >1 (air=1)
55
0233.012+= App
For streams with specific gravity
Low temperature separationLow-temperature separation units are based upon principle that lowering the operating temperature of a separator increases the liquid recovery. In addition, it dehydrates the gas.
p=pinitial-pfinal
Based on 25% liquid
Approximate temperature correction for hydrocarbon liquid content of a water free well stream
56Temperature drop accompanying a given Pressure drop (Eng. Data Book, GPSA)
T (oF)
pinitial
Based on 25% liquid condensed on expansion and % liquid recovered in stock tank
Gas cleaningGas cleaning is important for pipeline transportationsystem in order to:
1. Reduce the operational problems2. Maximize operating efficiency3. Gas storage4. Sale specifications
57
4. Sale specifications5. Prevent catalyst and solution contamination First phase of cleaning at the wellhead by such means of strainer, sand traps and filters.Second phase of cleaning is carried out in the gas liquid separators.Further cleaning is required before the gas arrives at a processing plant, and before the processing is begun.
Gas cleaningA clean up gas transmission averages about 2 lbm/MMSCF particulate matter in the gasGas cleaning involves the removal of two types of materials
1.Gross solids and liquids, called pipeline trash or sludge.
58
1.Gross solids and liquids, called pipeline trash or sludge. This consists of liquids such as heavier end hydrocarbons, water, chemicals such as amines, glycols, methanol, corrosion inhibitors, drilling muds, pipeline scales such as corrosion products.
2.solid particles and liquid (aerosols). These are suspended solids or liquids and are much more difficult to remove because of their ultra-small particle size.
Gas cleaning
( ) nnn
gpn
p
Cad
v
+
=
21
1
1
34
General equations for particles suspended in a gasThe terminal velocity of a particle falling through a fluid under the influence of a force that exerts an acceleration on the particle is:
v= velocity in ft/sa= acceleration in ft/s2dp=, particle diameter in ftg = gas density in lbm/ft3 = particle density in lbm/ft3
59
n
gn
gdC 13 p= particle density in lbm/ft3
g = gas viscosity, lbm/ft.sThe drag coefficient Cd and exponent n are as follows (Lapple, 1984):
Flow regime NRe Law Cd n RemarkLaminar
Gas cleaningFor small particles less than 3For small particles less than 3 micronsmicrons the Stokes law is no longer valid. In this case the particles are so small that they slip between the gas molecules at a rate greater than that predicted by Stokes law. For particles smaller than 3 microns, a random motion,
60
For particles smaller than 3 microns, a random motion, known as Brownian movement, also begins to occur. Its effect superimposed upon the particle settling velocity, and for particles under 0.1 microns, Brownian motion becomes the dominant phenomenon. Gas cleaning is never really persuade to such levels.
Typical process applications and operating range of equipment
61Sulzer Chemtech
Gas cleaning methods1. Gravity settling2. Centrifugal action3. Impingement4. Filtration5. Scrubbing6. Electrostatic precipitation
1.1. Wire mesh padsWire mesh pads can remove droplets down to 4 microns in size.2. A Gas flow velocity of 5-10 ft/s provides maximum operation efficiency.
62
1. The vanevane--typetype designed for horizontal flow through the vanes.
2. The pressure drop is very small 3. It can handle solids4. It can remove droplets about 40 microns
1.1. Fiber mist eliminatorFiber mist eliminator offers high efficiency up to 99.98%2. Can handle mists smaller than 3 microns
2. A Gas flow velocity of 5-10 ft/s provides maximum operation efficiency. 3. Designed for vertical flow
Gas cleaning methodsFiltersFilters have been traditionally used to remove solids particles by using a filtration medium that allows only gas to pass through. Bag filters using woven fabric or compressed felt fabric, glass fibers have been used.
ScrubbersScrubbers may use liquids to aid the removal of a particles from gas. Scrubbers include dry, oil bath, and cartridge type. Dry and oil bath scrubbers can be effective down to almost 4 microns particles size.
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scrubbers can be effective down to almost 4 microns particles size. Cartridge type are very effective and can remove solid particulate matter down to a size of 0.3 micron but require more maintenance and thus expensive.
Electric precipitatorsElectric precipitators (ESP) induce an electrical charge that attracts the particulate matter. A strong electrostatic field is provided that ionizes the gas to some extent. The particle suspended in this partially ionized gas become charged and migrate under the action of the applied electric field.
Strainers Strainers are device which helps in restricting flow of unwanted particles
like pipeline debris or seal/jointing compound, weld metal, scaling and other solids in flowing liquids or gases, which may damage the down stream equipment or reduce the efficiency.
A pump or compressor shall have suction strainers so that clean fluid enters into the system.
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A strainer should be fitted at upstream of every steam trap, flow meter and control valve to avoid malfunctioning.
Strainers can be classified according to their body configuration or shape: e.g.
1. Y-type2. Basket type or Tee type 3. Bucket type4. Conical
Y-type Strainers Inlet
Filter
Outlet
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1. Horizontal steam or gas lines should be installed in such a mannerso that the pocket is in the horizontal plane.
2. On liquid system the pocket should point vertically downwards3. Installation of Y-type strainer is not possible in case of vertical line
upward flow4. In vertical line downward flow it is possible and very effective.
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Basket type or Tee type strainer
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1. For very high flow2. Can be installed in horizontal pipe line or vertical line in downward flow only3. The pressure drop across the strainer is less then Y-type strainer
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Temporary Strainers mounted between two flanges as protection of pipelines and plants.
Bucket and Conical Type Strainers
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1. Thin or low viscosity fluids or gases2. Provide higher straining areas than
any other type of strainers 3. Can be installed in horizontal lines
only 4. Rate of increase of pressure drop is
normally very slow as compares to conical strainers
1. These are conical in shape and can be installed in either direction, over the cone or under the cone.
2. Can be installed in any pipelines and are preferred in case gases where flow is very high
Conical Type StrainersBucket Type Strainers
Typical strainer pressure drop chart
1000
10000
100000
F
l
o
w
R
a
t
e
(
G
P
M
)
30"16"
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10
100
1000
0.1 1 10Pressure Loss (psi)
F
l
o
w
R
a
t
e
(
G
P
M
)
4"
Sand TrapsThe migration of formation sand caused by the flow of reservoir fluids.
Sand drops out from reservoir well-streams into surface facilities.
The production of sand can:
1. Take up valuable separation volume, reducing residence time2. Restrict productivity
69KW International
2. Restrict productivity3. Stabilise unwanted emulsions formed by the oil and water4. Erode completion components,5. Presents a major safety risk 6. Impede wellbore access7. interfere with the operation of downhole equipment8. Present significant disposal difficulties.
Three-phase oil and water separatorsThree-phase separator and free-water knockout are terms used to describe pressure vessels that are designed to separate and remove the free water from a mixture of crude oil and water. Because flow normally enters these vessels directly from either (1) a producing well or (2) a high pressure separator, the vessel must be designed to separate the gas that flashes from the liquid as well as separate the oil and water.
Three-phase separator: when there is a large amount of gas to be separated
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Three-phase separator: when there is a large amount of gas to be separatedFree-water knockout: when the amount of gas is small relative to the amount of oil and water.
3-30 min
water
oil
Three phase separatorsInlet diverter illustrating principles of water washing
oil
Schematic of a horizontal three-phase separator
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water
1. Gas-oil Interface at 50-75% of separator diameter.
2. Separators with bucket and weir are more suitable for high WOR wells or small density differences.
3. Separators with interface level control is good for high oil rate and large density differences.
4. Separators with bucket and weir are more suitable for heavy oil.with bucket and weir
with interface level control and weir
Three phase separators (cont.)
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Horizontal and vertical free-water knockout
Three phase separators (cont.)Horizontal three phase separator with flow splitter
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Horizontal three phase separator with a liquid boot
Three phase separators (cont.)
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a vertical three-phase separator with interface level control
Cutaway view of a vertical three-phase separator without water washing and with vane mist extractor
Three phase separators (cont.)Horizontal vessels are most economical for normal oil-water separation, particularly where there may be problems with emulsions, foam, or high gas-liquid ratios.
Vertical vessels work most effectively in low gas-oil ratio (GOR) applications and where solids production is anticipated
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Cutaway view of a vertical three-phase separator without water washing andwith wire-mesh mist extractor Liquid level control schemes
Three-phase separators (cont.)Coalescing plates
Turbulent Flow Coalescers
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It is possible to use various plate or pipe coalescer designs to aid in the coalescing of oil droplets in the water and water droplet in the oil. The installation of coalescing plates in the liquid section will cause the size of the water droplets entrained in the oil phase to increase, making gravity settling of these drops to the oil-water interface easier. This may lead smaller vessel but there is a potential for plugging with sand, paraffin, or corrosion products
Horizontal three-phase separator fitted with free-flow turbulent coalescers (SP Packs)
Potential operating problems
Three-phase separators may experience the same operating problems astwo-phase separators. In addition, three-phase separators may developproblems with emulsions which can be particularly troublesome in the operation of three-phases separators. Over a period of time an accumulation oil emulsified materials and/or other impurities may form at
Emulsions
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accumulation oil emulsified materials and/or other impurities may form at the interface of the water and oil phases. In addition to adverse effects on the liquid level control, this accumulation will also decrease the effective oil or water retention time in the separator, with a resultant decrease in water-oil separation efficiency. Addition of chemicals and/or heat often minimizes this difficulty.Frequently, it is possible to appreciably lower the settling time necessaryfor water-oil separation by either the application of heat in the liquid section of the separator or the addition of de-emulsifying chemicals.
Three-phase water oil separator design theory
Example water droplet size distribution. Size distribution varies widely for different process
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for different process conditions and water properties
Three-phase Horizontal water oil separator design
Gas capacity
Horizontal separator
Horizontal separator
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Three-phase Horizontal water oil separator design (cont.)Horizontal separator
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Settling water droplets from oil phase
This is the maximum thickness the oil pad can be and still allow the water droplets to settle out in time tro
( ) ( )
SGtor
dm =
=
320500
sec.
Three-phase Horizontal water oil separator design (cont.)
For a given oil retention time and a given water retention time, the maximum oil pad thickness establishes a maximum diameter in accordance with the following procedure:
( ) ( ) ( )
SGth oro
= 320max
1. Compute (ho)max. Using 500 micron droplet if no other information is available
2. Calculate the fraction of the vessel cross-sectional area occupied by water
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2. Calculate the fraction of the vessel cross-sectional area occupied by water phase given by:
Three-phase Horizontal water oil separator design (cont.)
3. Determine 4. Calculate dmax using
Any combination of d and Leff, that
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Any combination of d and Leff, that satisfies the following equations:
will meet the necessary criteria.
Three-phase Horizontal water oil separator design (cont.)Settling water droplets from oil phase
( ) ( )w
ord SGtm
=
=
2.51200
w
w
w w
w
ww
w
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ww
Seam-to-Seam LengthFor vessels sized on a gas capacity basis, some portion of the vessel length is required to distribute the flow evenly near the inlet diverter. Another portion of the vessel length is required for the mist extractor. The length of the vessel between the inlet diverter and the mist extractor with evenly distributed flow is the Leff. The seem to seam length may be estimated as the larger of the following: Lss = Leff +d/12 or Lss = (4/3)Leff for gas capacityFor vessels sized based on a liquid capacity basis Lss = (4/3)Leff
Slenderness ratioExperience indicated that the ratio of the Lss divided by outside diameter should be between 3-5
Three-phase Horizontal water oil separator design (cont.)Horizontal separators sizing other than half full
Gas capacity
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Liquid capacity
If is known, can be determined from chart.
Gas and liquid capacity constraint design constant vs. liquid height of a cylinder for a horizontal separator other than 50% full of liquid ( field units).
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Three-phase Horizontal water oil separator design (cont.)Settling Equation Constraint
From the maximum oil pad thickness, liquid flow rates, and retention times, a maximum vessel diameter may be calculated. The fractional cross-sectional area of the vessel required for water retention may be determined as follows:
wherel : fractional area of liquids,w : fractional area of water.
The fractional height of the vessel required for the water can be determinedby solving the following equation by trial and error:
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by solving the following equation by trial and error:
where w, represents the fractional height of water. A maximum vessel diameter may be determined from the fractional heights of the total liquids and water as follows:
where dmax is the maximum vessel internal diameter in inches. Any vessel diameter less than this maximum may be used to separate specified water droplet size in the specified oil retention time.
Three-phase vertical water oil separator designBy setting the gas velocity equal to the terminal droplet, the following may be derived:
Settling water droplets from oil phase
Gas capacity
The requirement for settling water droplets from the oil requires that thefollowing equation must be satisfied:
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following equation must be satisfied:
for dm=500 micron SGQd oo
=
0267.02
Three-phase vertical water oil separator design (cont.)
Settling oil droplets from water phase
SGQd oo
=
167.02
For 200 micron droplets
Retention time constraint
From two-phase separator design:
88In vertical separators whose sizing is liquid dominated, it is common to choose slenderness ratios no greater than 4 To keep the height of the liquid collection section to a reasonable level. Choices between 1.5 to 3 are common, although height restrictions may force the choice of a lower slenderness ratio.