Title: PETE 689 Underbalanced Drilling UBD
1PETE 689 Underbalanced Drilling (UBD)
Lesson 4 Air, Gas and Mist Drilling.
- Read UDM - Chapter 2.1 - 2.4
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2Air, Gas, and Mist Drilling
- Gases used in UBD.
- Dry air drilling.
- Nitrogen drilling.
- Natural gas drilling.
- Mist drilling.
- Optimized hole cleaning.
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3Gases for UB Drilling
- Air.
- Cryogenic Nitrogen.
- Membrane Nitrogen.
- Engine Exhaust.
- Natural gas.
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4Gases for UB Drilling
Compressed Air
- 79 N2 , 21 O2.
- Corrosion.
- Fire.
- US3,000 Day.
- Mod and Demob.
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5Cryogenic Nitrogen
- 40 year old technology.
- Made as a by product of liquid oxygen
manufacture. - Air replacement.
- No corrosion.
- No downhole fires.
- 99.9 pure N2
- 7K-40K US/day.
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6Delivery
Cryogenic Nitrogen
- Bottled gas.
- Truck.
- Storage tank on
- a ship.
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7Cryogen Nitrogen-Pumping Equipment
Stainless Steel
Carbon Steel
Vaporizer
Liquid Nitrogen (-320OF)
Pump
Gaseous Nitrogen to well 80OF, 0-10,000 psi
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8Procedure
- Determine Gas Volume Required.
- Convert from Liquid Volume.
- 1 gallon liquid nitrogen produces 93.12 ft3 of N2
at SCP. - 1 m3 of N2 liquid produces 698 m3 of gas at SCP.
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9Nitrogen Conversion Factors
- 1 gal of liquid nitrogen is93.12 ft3 at STC.
- 1 gal of liquid nitrogen is0.1333 ft3.
- 1 liter of liquid nitrogen is698 litres of gas
at STC.
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10Cryogenic Nitrogen Cost
- World-wide
- 1-3 US /gal.
- 0.10 US /scf.
- Canada
- 0.02 US /scf.
- South America
- 1.00 US /m3.
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11UB Drilling Gas Alternatives
- Nitrogen Membranes
- 95 N2 , 3-5 O2.
- Corrosion considerations.
- Combustion considerations.
- Approximately 15,000 US /day.
- Mob/demob costs.
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12Membrane Nitrogen
- On site manufacture.
- Dependent on concentration.
- Directly proportional to pressure and rate.
- Inversely proportional to gas partial pressure.
- Driven by dissolution and diffusion.
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13Individual Hollow Polmeric Gas Separation Fiber
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14Individual Hollow Polmeric Gas Separation Fiber
Nitrogen Oxygen Water Vapor
Nitrogen
Oxygen and Water Vapor are Fast Gases which
quickly permeate the membrane, allowing Nitrogen
to flow through the fiber bores as the product
stream.
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15N2 Generating Unit A Bundle Of Fibers
OXYGEN- ENRICHED AIR
FEED AIR
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16Equipment Required
- Compressor.
- Filters-fibers will plug if the air is not
filtered. - NPU or NGU.
- Controller.
- Booster(s).
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17Membrane Nitrogen Production Unit
Filter and Air Separation Membrane System
Optional Booster Compressor
Feed Air Compressor
Drilling Rig
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181997 Nitrogen Unit.
- N2 units with coolers.
- 8x30x8 high
- 23,000 psi
- 1200 scfm N2 at 5 02
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19Skid-Mounted Nitrogen Producing Unit (NPU)1998
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20Weatherford 2000Nitrogen Generation Unit.
- 1. N2 500-600 scfm.
- 2. 2000 psi comp.
- 3. 27 gph diesel.
- 4. 8x20x16 high.
- Nominal O2 5
1.
3.
2.
4.
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21Nitrogen Membrane System 1999
2
3
5
1
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22Procedure
- Determine volume requirement.
- Determine maximum oxygen concentration.
- Determine effective volume from units.
- Determine pressure requirement.
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23Oxygen Concentration
- Oxygen is only partially a valid concept for
fire. - Ignition temperatures and water content play a
big part. - Oxygen is important for corrosion.
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24Recent Combustion Work
- Testing
- Alberta Research Council.
- Counter claims of increased corrosion and
combustion with membrane generated N2
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25Minimum Oxygen for Combustion (with Methane)
Oxygen Required for Combustion
0 500 1000 1500
2000 2500 3000
Pressure (psia)
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26Nitrogen Source SelectionCryogenic vs. Membrane
- Location.
- Job duration.
- Volume requirement.
- Pressure requirement.
- Purity requirement.
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27Operating Cost
- Canada
- USA
- Crossover between cryogenic costs and membrane
costs is generally about three days of operation.
- Transportation and mobilization are big items.
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28Cryogenic Nitrogen Operating Cost
- Canada
- 10,000 US /day minimum.
- 40,000 US /day maximum.
- (500-1800 scfm for 20 hrs/day).
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29Flow Path
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30Exhaust Gas Generating Unit 1980
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31Exhaust Gas System
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32Natural Gas for UB Drilling
- Available.
- No downhole fires.
- No corrosion.
- Low cost, long term contracts.
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33Pressure
- Determine requirement as for air, but allow for
lesser specific gravity. - Delivery pressure set at source.
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34Fuel Gas Group Gas Pipeline
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35Natural Gas Pipeline Hook Up(Lyons, 1984)
Main Pipeline.
Auxiliary line to rig.
500 Psig
Flow to rig.
Choke/Controller
Pipeline Flow
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36Natural Gas Concerns
- May be pressure limited.
- Heavier hydrocarbons repress foam so be sure that
they are stripped out.
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37- Amoco Crossfield
- Gas Recovery Project
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38Amoco Crossfield 9-12 Well
88.9 mm Drill Pipe
Drilling Fluid Water 1000 kg/m3 Viscosity 1cP
KOP 2250 m
2350 m
177.8 mm Casing _at_ 2403 m
155.6 mm Openhole
120.6mm PDM
Elkton Gas BHP 7.0 MPa BHT 80oC
778 m
Target TMD 3181 m
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39CrossfieldGas Recovery Project
- Why it was done
- Increasing public concerns over flaring.
- Increasing EUB requirements for public
consultation and notification.
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40CrossfieldGas Recovery Project
- Perfect fit with Amocos goal of
- reducing greenhouse gas
- emissions.
- Try out new idea and technology.
- Great plumbing setup.
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41Gas Recovery Project
RBOPTM
Gas Flare System
Drilling Rig
Choke Manifold
Flare Knockout Vessel
Horizontal Separator
Feed Gas Compressors
Produced Gas Compressors
Gas Processing Unit
Feed Gas Line
Gas Gathering Line
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42Compression Scrubber/Filter Units
Recovery Gas Compressors
Feed Gas Compressors
Scrubber/Filter Unit
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43Flow Control Manifold
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44Gas Scrubber Filter Unit
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45Gas Recovery Summary
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46Gas Recovery Summary
Gas Conserved
Gas Flared
16
- Conserved 92.
- Inc. Cost 170k US .
- No need to optimize GLRs.
- 75 MMCFD well.
14
12
10
8
6
4
2
0
10-Jul
12-Jul
14-Jul
16-Jul
18-Jul
20-Jul
22-Jul
24-Jul
26-Jul
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47Crossfield Gas Recovery Project
- Results
- Estimated costs were 250k US , actual cost was
170k US . - Conserved 92 of flow from the well.
- Eliminated need to optimize the gas/liquid
ratios. - 75 MMCFD storage well.
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48Hole Cleaning
- Optimizing hydraulics with gasses is primarily
concerned with hole cleaning - getting the
cuttings that are generated by the bit out of the
hole. - With gas, rheological properties have very little
to do with hole cleaning. - Hole cleaning with gasses is almost entirely
dependent on the annular velocity.
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49Drag and Gravitational Forces
- Flowing air exerts a drag force on cuttings.
- Gravitational force on the cuttings
- Therefore there is a threshold velocity in which
the cuttings will be lifted from the wellbore. - Threshold velocity increases with size of
cuttings.
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50Hole Cleaning
- Compressibility of air (or gas) complicates
matters. - Frictional pressure increases downhole pressure -
decreases velocity downhole. - Suspended cuttings increase the density of the
air, increasing downhole pressure.
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51Hole Cleaning
- Temperature has an effect on
- volumetric flow rate.
- We must pump at a velocity
- high enough to remove the
- cuttings, but not too high
- where we waste energy.
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52Hole Cleaning Criteria
- Terminal Velocity Criteria.
- Minimum Energy Criteria.
- Minimum BHP Criteria.
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53Terminal Velocity Criteria
- Gray determined that the minimum velocity of the
gas must be at least as high as the terminal
velocity of the cutting in order to lift the
cutting from the wellbore. - Vc Vf - Vt
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54Terminal Velocity
?c ?f 3Cd ?f
Vt
4gdc
g gravitational acceleration, 32.17
ft/sec2 dc characteristic particle diameter,
ft. Cd drag coefficient. ?c density of
cuttings, lbm / ft3 ?f density of fluid, lbm/
ft3
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55Terminal Velocity
dcT?c P
Vt 3.369
For flat cuttings
dcT?c P
Vt 4.164
For sub-round cuttings, T and P are at bottom
hole conditions in 0R and psia.
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56Terminal Velocity
- Terminal velocity in air drilling is determined
mainly by - cutting diameter, shape, and density.
- bottom hole temperature and pressure.
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57Factors Effecting Vt
- Shape (roundness).
- Increased Size.
- Increased Temperature.
- Increased Density.
- Increased Pressure.
- Increases.
- Increases.
- Increases.
- Increases.
- Decreases.
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58Terminal Velocity
- As pressure increases Vt decreases.
- As pressure increases Air velocity decreases.
- If the mass flow rate of gas remains constant the
local air velocity decreases with increasing
pressure. - The air flow rate required to lift the cuttings
increases with increasing BHP.
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59Friction Pressure
?m
Eq. 2.5
fm Friction factor of the mixture
of air and cuttings. ?m Mixture density,
lbm/cu.ft. Vm Mixture velocity, ft/s. g
Acceleration due to gravity. Dh
Hole diameter, ft. Dp Pipe diameter, ft.
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60Friction Pressure
fm a c
Weymouth quation.
0.14 ( Dh Dp) 0.333
a
Gou argued that Nikuradse is more correct.
1 a
2? Dh - Dp
1.14 0.86ln
? absolute roughness of the pipe.
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61Friction Pressure
- Mixture density of air and cuttings in the
annulus is determined by the mass of the cuttings
and the density of the air. - Air density is a function of the pressure.
- Mass of the cuttings in the wellbore is a
function of - ROP
- Hole cleaning efficiency.
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62Friction Pressure
- Pressure drops down the drillstring and through
the bit play a part in BHP due to temperature
effects. - Temperature is also effected by
- Formation temperature.
- Influx of formation fluid (expansion of gas into
the wellbore). - Mechanical friction.
- Pressure.
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63Required injection rates?
- Relating downhole air velocities to surface
injection rates is quite complex. - We need cuttings shape and size to determine
terminal velocity. - Methods required knowledge of the cutting shape
and size.
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64Minimum Energy Criteria
- Probably the most widely used criteria was
developed by Angel in 1957. - Angel assumed that, for efficient cuttings
transport downhole, the kinetic energy of the air
striking each cutting should be the same as that
of air giving efficient cuttings transport at
standard pressure and temperature.
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65Minimum Energy Criteria
1 2
1 2
?min V 2min
? stp V 2stp
Pmin Density of air (or gas) at the minimum
required downhole injection rate,
lbm/cuft. Vmin Air (or gas) velocity downhole,
ft/min. Pstp Density of air (or gas) at
standard temp and pressure, lbm/cuft. Vstp
Air (or gas) velocity at standard Temp and
pressure, ft/min.
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66Minimum Energy Criteria
Pstp Pmin
Vmin Vstp
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67Minimum Energy Criteria
- Experience from shallow blast holes, drilled in
limestone quarrying operations, indicated that
cuttings were transported efficiently if the air
velocity equaled or exceeded 3,000 feet per
minute. - This is equivalent to Grays terminal velocity
for flat cuttings with a diameter of 0.46 in. and
for sub-rounded particles of 0.26 in.
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68Minimum Energy Criteria
Angel computed the downhole air pressure with eq.
2.5
m ? m V 2m 2g (Dh Dp)
dP dL
?m
Wc Wa
?m ?a
1
Wc Mass of cuttings generated in a given
time the mass flow rate of cuttings,
lbm/min. Wa Mass of air flowing past any
point in the well in given time the mass flow
rate of air, lbm/min.
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69Minimum Energy Criteria
2aG
abTs2 T abT2 G a Ts
G - a
Pb P2s-
Ps Surface air pressure, lbf/sq.ft,
absolute. Ts Surface temperature, 0F. G
Annular temperature gradient, 0F/100. T
Downhole temperature TsGh h Hole depth.
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70Minimum Energy Criteria
SQ 28.8 . ROP . Dh2 53.3Q
a
S Gas specific gravity (air1) Q
Gas flow rate, scf/m ROP Penetration rate,
ft/hr
1.625 x 10-6Q2 (Dh Dp) 1.333 (Dh2
Dp2)2
b
Dh Hole diameter, ft. D2 Drillpipe
diameter, ft.
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71Minimum Energy Criteria
This was combined with the cuttings transport
criterion defined in Eq 2.10 to deduce the
minimum air flow rate as a function of hole
depth, annular geometry, and penetration rate.
? stp ? min
Vmin Vstp
Eq. 2.10
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72Minimum Energy Criteria
To simplify, the average downhole temperature can
be used to calculate BHP.
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73Minimum Energy Criteria
This was solved numerically for the gas injection
rate required to give an annular velocity
equivalent in cuttings lifting power to air with
a velocity of 3000 ft/min. A series of charts was
generated for different combinations of hole
size, drillpipe diameter and penetration rates
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74Minimum Energy Criteria
- Qmin can be approximated by
- Qmin Qo NH
- Qo Injection rate (scfm) at zero
depth that corresponds to an annular
velocity of 3000 ft/min - N Factor dependent on the
penetration rate (Appendix C) - H Hole depth, (thousands of feet).
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75Appendix C
Data for calculating approximate circulation
rates required to produce a minimum annular air
velocity which is equivalent in lifting power to
standard air velocity of 3.000 ft/min. (Angel,
1957).
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76250
200
150
Bottomhole Pressure (psia)
100
50
0
0 2000 4000 6000
8000 10000 12000
Depth (feet)
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7780
70
60
50
Bottomhole Pressure (psia)
40
30
20
10
0
0 2000 4000 6000
8000 10000 12000
Depth
(feet)
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787-7/8 hole 3-1/2 drillpipe 6 drill
collars 3800 hole depth
Annular Bottomhole Pressuresin An Air Drilled
Hole-comparison Of Predictions And Measurements
Made While Circulating Off-bottom
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7945
40
35
Bottomhole Pressure (psia)
30
25
20
- 600 700 800 900
1000 1100 1200 1300 -
Flow Rate (scfm)
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8034
32
30
28
Bottomhole Pressure (psia)
26
24
22
20
- 600 700 800 900
1000 1100 1200 1300 -
Flow Rate (scfm)
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813.5
3
2.5
2
Required Rate of Air (scfm)
1.5
1
0.5
0
0 2000 4000 6000 8000 10000
12000 14000 16000 18000
Depth ( feet)
Comparison of air rates recommended by several
different cuttings transport analyses (after Guo
et al, 199412).
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82Minimum BHP Criteria
Angel analysis does not predict a minimum BHP,
but gives a pressure that decreases monotonically
with decreasing air flow rate.
Annulus Pressure Drop
Annulus Pressure Drop
Annulus Air Velocity
The influence of air flow rate on annular
pressure drop (after Supon and Adewumi, 19915).
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