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Slimhole wells are normally defined ashaving at least 90% of
their diameter lessthan 7 in. They are drilled using rotary
rigsthat are much smaller than normalrigsabout 20% of their weight,
requiringabout a quarter of the drillsite area. Overhalf of
drilling costs depend on factorsother than drilling time, such as
construct-
45
In this article, FSTS (Formation Selective TreatmentSystem),
SideKick and CoilLIFE are marks of DowellSchlumberger. SLIM1 is a
mark of Anadrill.
For help in preparation of this article, thanks to BruceAdam,
Dowell Schlumberger, Rosharon, Texas, USA.
1. For details of coiled-tubing hardware and its applica-tions
to workover and logging:
Ackert D, Beardsel M, Corrigan M and Newman K:The Coiled Tubing
Revolution, Oilfield Review1,no. 3 (October 1989): 4-16.
2. Littleton J: Coiled Tubing Springs into HorizontalDrilling,
Petroleum Engineer International2 (Febru-ary 1992): 20-22.
In recent years, workover and logging usingcoiled tubing has
become increasinglywidespread (above).1 During workoveroperations,
coiled tubing has been usedsuccessfully to drill out cement plugs
andremove scalein most cases harder to drillthan formation. Now
attention is focused oncoiled-tubing drilling as a technique
todeliver cost-effective slimhole wells for bothexploration and
production.2
Interest in drilling slimhole wells with coiled tubing is high.
So far, only a few experimental wells have been
drilled and many technological issues remain unresolved. But if
these challenges are met, coiled-tubing
drilling could become the medium that finally delivers slimhole
wells across the industry.
Mick AckersDenis DoremusSugar Land, Texas, USA
Ken NewmanMontrouge, France
nsn A coiled-tubingunit with diagramof the
injectorhead(left)andblowout preven-ters(center).
An Early Look at Coiled-Tubing Drilling
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New wells Re-entry
Disposable
exploration wells
Deviated
development
wells
Well deepening into
new producing zone
Horizontal extension
into producing zone
Multiple radial
drainholes
Straight
holes
Lateral
holes
Original
New
and avoided the expense and potential dam-aging effects to the
formation of pumpingbrines to kill the well prior to tripping.
To prepare the well, Oryx used a conven-tional service rig to
remove the existingcompletion hardware, set a whipstock
andsidetrack out of 41/2-in. casing at a true verti-cal depth of
5300 ft [1615 m]. Drilling wasthen continued using 2-in. coiled
tubing,
downhole mud motors, wireline steeringtools, a mechanical
downhole orienting tooland 3 7/8-in. bits. An average buildup rate
of15/100 ft [15/30 m] was achieved and ahorizontal section drilled
for 1458 ft [444m].4 The main bottomhole assembly (BHA)components
were:
DrillstringOryx employed a reel com-prising 10,050 ft [3060 m]
of 2-in. outsidediameter coiled tubing with 5/16-in. mono-conductor
cable installed inside the tubing.
ing the drill pad and access roads, movingthe rig, and the cost
of casing and consum-ables like mud.3 A coiled-tubing unit (CTU)is
even smaller than a slimhole rig, is easierto mobilize and requires
less equipmentand personnel. Its smaller site requirementleads to
lower civil engineering costs. Thesmaller, quieter CTUs have a
reduced envi-ronmental impact.
There are also particular benefits offeredby use of continuous
tubing. It avoids theneed for connections, speeding up trip
timesand increasing safetymany drill floor acci-dents and
blowout/stuck-pipe incidentsoccur when drilling is stopped to make
aconnection. CTUs have pressure controlequipment designed to allow
the tubing tobe safely run in and out of live wells. Thestripper
above the blowout preventers(BOPs) seals the annulus during
drilling andtripping. This offers increased safety
duringdrillingsimilar to having a conventionalrigs annular
preventer closed all the time.
This safety feature also facilitates underbal-anced drilling, in
which drilling is carriedout while the well is flowing.
A range of different uses has been pro-posed for slim holes
drilled by a CTU(right). So far, lateral production and
verticalre-entry wells have been drilled. Theseexperimental wells
were designed to provethat the technique can effectively meetdesign
specifications.
Three re-entry horizontal production wellshave been drilled in
the Austin chalk, Texas,USA, using 2-in.
directionally-controlledcoiled tubing with 37/8-in. bits. In an
effort
to prove the efficacy of coiled-tubingdrilling for exploration,
a vertical well wasdeepened in the Paris basin, France,
using11/2-in. coiled tubing with 37/8-in. bits. Thiswas also a
re-entry, but a new vertical wellis also planned.
This article reviews one of the Austinchalk wells and the Paris
basin well. Then itwill look at the technological challengesarising
from these experiences.
46 Oilfield Review
Lateral Re-Entry for Production
Last year, Oryx Energy Company re-entereda vertical well in the
Pearson field, Texas,USA, completed in Austin chalk.
Horizontaldrilling in Austin chalk using mud com-monly encounters
almost total lost circula-tion. To reduce mud losses, formation
dam-age and costs, water is often used as drillingfluid. This
decreases bottomhole hydrostatic
pressure to less than formationpressureunderbalanced drilling.
To com-bat annular pressure from formation flowduring drilling,
conventional rigs use a rotat-ing stripping head or rotating BOPs
to sealthe annulus. The wells are killed each timea trip is
made.
By using a CTU, which has its annulussealed throughout drilling
by the stripper,Oryx was able to run in and out of holewithout
killing the well. This improved safety
3. Randolph S, Bosio J and Boyington B: SlimholeDrilling: The
Story So Far... Oilfield Review3, no. 3(July 1991): 46-54.
4. Ramos AB, Fahel RA, Chaffin M and Pulis KH: Hori-zontal
Slim-Hole Drilling With Coiled Tubing: AnOperators Experience,
paper IADC/SPE 23875, pre-sented at the 1992 IADC/SPE Annual
Drilling Confer-ence, New Orleans, Louisiana, USA, February
18-21,1992.
Wesson HR: New Horizontal Drilling TechniquesUsing Coiled
Tubing, paper SPE 23951, presented atthe 1992 Permian Basin Oil and
Gas Conference,Midland, Texas, USA, March 18-20, 1992.
5. Traonmilin E, Courteille JM, Bergerot JL, Reysset JLand
Laffiche J: First Field Trial of a Coiled Tubing forExploration
Drilling, paper IADC/SPE 23876, pre-sented at the IADC/SPE Annual
Drilling Conference,New Orleans, Louisiana, USA, February
18-21,1992.
Traonmilin E and Newman K: Coiled Tubing Used forSlim Hole
Re-entry, Oil & Gas Journal90 (February17, 1992): 45-51.
6. Ackert et al, reference 1.
nsn Potential applica-tions for coiled-tub-
ing drilling.
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Vertical Exploration Well
Last year, Elf Aquitaine embarked on a seriesof trials to
determine whether coiled tubingcould be used to drill slimhole
wells, cuttingexploration drilling costs. The goal of thefirst well
was to demonstrate that a CTU candrill a vertical well sufficiently
fast, cut coresand test formations. Elf envisions initiallydrilling
these slimhole wells with a single
openhole sectionavoiding the need forcasingwith the surface
casings set usinglow-cost, water well rigs.
This first trial involved the re-entry of wellSaint Firmin 13 in
the Paris basin.5 The planwas to use the CTU to set cement
plugsacross the existing perforations at 2120 ft[646 m] and then
drill a 2105-ft [642-m]vertical section of 37/8-in. diameter.
Direc-tional measurements using a coiled-tubing-conveyed survey
were to be taken every500 ft [150 m]. Then a 50-ft interval was
tobe cored and logged. Finally, a zone was tobe flow tested by
measuring pressure
between two straddle packers.6
The trial was carried out by DowellSchlumberger using a
trailer-mounted CTUwith a reel of about 6000 ft [1830 m] of11/2-in.
tubing. To avoid the need for costlymodifications, standard surface
hardware,like injector head with stripper and BOPstack, were used.
A workover rig substruc-ture was installed over the existing
wellheadto act as a work platform.
The operation encountered difficulties atthe outsetnot with the
drilling but with theintegrity of the wells 30-year-old
casing.After cement plugs were set, the well would
not hold the 360 psi above hydrostatic pres-sure required to
withstand the anticipatedformation pressures. Because of this,
drillingdepth was limited to 2955 ft [901 m] whichallowed limestone
coring but did not extendto a high-pressure aquifer.
The drilling BHAs employed a high-speed, low-torque motor with
PDC bits. Forcoring, a high-torque motor was used. Thedrilling and
coring assemblies were made tohang vertically by incorporating
heavy drillcollars into the BHA, creating a pendulumassembly. At
the start, the deviation at thecasing shoe was 2 and, as expected,
the
BHA did not build angleat 2362 ft and2795 ft [720 m and 852 m],
the deviationangles were 23/4 and 21/4 respectively.During
drilling, the rates were comparableto those drilled by conventional
rigs at workin the area. This showed that a CTU candrill vertical
wells at commercial rates. Twocores were cut and retrieved with
goodrecoverymeeting the second objective ofthe trial.
ware. Orienting the tool face was not diffi-cult, but
maintaining it was hard because ofthe unpredictable reaction of the
coiled tub-ing to the torque generated by the drillingmotors
rotation. Drilling was also slowedby failure of BHA components,
particularlythe orienting and directional survey tools.
These difficulties affected the final costanalysis. Total cost
was estimated by Oryxat twice that of using a conventional
rignondrilling time was responsible fornearly 40% of this
(below). However, aspurpose-designed equipment becomesavailable and
drilling procedures arerefined, coiled tubing should deliver
morecost-effective, slimhole, lateral wells.
Orientation toolBecause coiled tubingcannot be rotated from
surface to alterdrilling direction, a downhole method ofchanging
tool face orientation is needed. Toachieve this, Oryx deployed a
mechanicaltool that converts tubing reciprocation
intorotationcompression rotated the tool faceto the right,
extension to the left. Onceadjusted, the tool face was locked in
placeusing a minimum 250-psi differential pres-
sure across the tool.Directional survey toolThe survey
toolinside a nonmagnetic collar relayed direc-tional information to
surface via the wireline.
Directional BHATwo assemblies wereused, depending on the build
ratesrequireda double-bend assembly consist-ing of a conventional
27/8-in. bent housingmud motor coupled to a single bent sub, ora
steerable assembly comprising a single-bend motor.
BitThermally stable diamond bits wereused to drill the curve and
build sectionsand polycrystalline diamond compact
(PDC) bits to drill the lateral section.Oryxs motive for
drilling this well was to
prove that coiled tubing could be used todrill a lateral well in
a controlled manner.This was achievedthe final wellbore tra-jectory
came within a 50-ft [15-m] verticalwindow along the horizontal
section (above).
Because this well was the first of its kind,new techniques had
to be developed, andmuch of the drilling equipment had to beadapted
from existing conventional hard-
47July 1992
Normal drilling
60.9%
Waiting/repairs
20.5%
Directional
7.1%
Fishing
11.5%nsn Cost breakdown for the first Oryx well.
nsn Final analysis of the Oryx well in Austin chalk, Texas, USA.
With a steerable bottom-hole assembly, the horizontal section was
drilled within its 50-ft vertical window.5100
5300
5500
5700
5900
61000 400200 600 800 1000 1200 1400 1600 1800
Displacement, ft
Trueverticaldepth,
ft
Coiled tubing and final
well trajectoryWireline connector
Downholeorienting sub
WhipstockDirectional survey tool
Check valve
Positivedisplacementmud motor
Fixed cutter bit
Tubing reel Power supply
Tubing injector
Bent sub
50 ft
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Because the program had to be revised toavoid high-pressure
zones, no oil-bearingformation could be tested. To prove the
test-ing technology and meet the third objective,a drawdown test
was carried out on a zonebetween 2221 ft and 2231 ft [677 m and
680 m]. The FSTS Formation Selective Treat-ment System was
deployed with its twopackers straddling this zone. The formationwas
successfully isolated and, if it had beena reservoir, would have
produced into thecoiled tubing (above).
The BOPs will be mounted below theinjector head directly on top
of the well-head, casing or christmas tree. If the holediameter is
less than 4 in. [10 cm], 4 1/16-in.,10,000 psi coiled-tubing BOPs
will be used.If the hole is larger, a standard set of 71/16-in.,
5000 psi drilling BOPs will be usedinstead. In both cases an
annular preventerwill also be incorporated into the stack
(below and next page, left).In the directional wells drilled so
far usingcoiled tubing, BHA direction has beenaltered using
reciprocation of an orientingtool. This technique has the dual
disadvan-tages of interrupting drilling and requiringmanipulation
with pressure in the tubing,which has a severe fatiguing effect.
The taskforce has therefore designed BHAs thatincorporate an
orienting tool controlled byusing mud flow rate.
Directional information can be sent tosurface either using
wireline or mud-pulsetelemetry. Wireline offers real-time
transmis-
sion of high volumes of information. How-
Packer
Formation to
be tested
Packer
FSTS setting tool
Looking to the Future
In addition to proving that coiled tubing canbe used to drill
wells, the trial pointed outhow procedures could be changed
andwhere future hardware development isrequired. For example, rate
of drilling couldbe increased by incorporation of
measure-ment-while-drilling tools to make direc-tional surveys,
improving surface handling
and weight-on-bit (WOB) control tech-niques and better
optimization of the BHA.To address these issues, Dowell Schlum-
berger has assembled a multidisciplinarytask force with Sedco
Forex and Anadrill. Itswide-ranging agenda covers equipmentneeds,
operational and safety procedures,tubing limits and personnel
requirements.
Equipment needsThe Elf job utilized aworkover rig substructure.
In the future, apurpose-built substructure will be
employed.Standing 10 ft [3 m] off the ground and overthe wellhead,
this substructure will act asthe drill floor to make or break the
BHA and
also to support the injector head.
48 Oilfield Review
nsn The FSTS Formation Selective TreatmentSystem. The
coiled-tubing conveyed FSTSstraddle packers were set across the
for-mation to allow reservoir fluids to flow,proving that drillstem
tests can be carriedout using coiled tubing. Blind ramsShear
ramsSlip rams
Pipe rams
Kill line Choke line
Ground
Wellhead, casing
or christmas tree
Annular preventer
Injector head
Stripper
Drill floor
Mud returns
BOP stack41/16in. 10,000 psi
nsn Blowout preven-ter configurationfor a well drilledwith a
hole sizeless than 4-in.
diameter.
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BHAstraight hole
BHA forbuildup and
horizontal sections
Connector
Check valve
assembly
Pressure
disconnect
Orienting tool
Coiled tubing
SLIM1 MWDin nonmagnetic
drill collar
Mud motor
Adjustable
bent housing
Mud motor
Drill collars
ever, having wireline in the tubing requiresa high level of
maintenance and cuts downpumping optionslike acidization
treat-ments. To avoid the need for a cable link,the task force has
adapted Anadrills SLIM1measurement-while-drilling systemwhichuses
mud pulse telemetryso that it fitsinside a 31/16-in. diameter
nonmagnetic drillcollar (right).
The chemistry of muds used when drillingwith a CTU is not
expected to be signifi-cantly different from muds used in
conven-tional wells. However, the technique doeshave some special
rheological require-ments. In a re-entry well, the coiled
tub-ing/casing annulus may be relativelylargeperhaps 2 in. inside 7
in.slowingthe annular velocity of the fluid and possi-bly
compromising the cuttings-carryingcapacity of the mud. Further,
because thefluid is pumped through small-diameter tub-ing, friction
must be kept to a minimum byusing low solids muds with low
viscosities
and yield points. To mix and treat drilling
nsn Blowout preven-ter configurationfor a well drilledwith a
hole sizegreater than 4-in.
diameter.
nsn Straight hole and buildup/horizontalbottomhole assemblies
(BHAs). In both,fullbore check valves prevent backflow tosurface.
The pressure disconnect suballows recovery of the coiled-tubing
stringif the BHA gets stuck. A ball is droppedand pumped through
the tubing until itseats in the disconnect sub. Internal tub-ing
pressure is then applied that shears
pins in the sub and releases the string.The straight hole BHA
includes drill col-
lars, so that the string acts as a pendulumand tends to the
vertical. Buildup andhorizontal BHAs include an adjustablebent
housing to facilitate deviateddrilling. The housing angle is fixed
at sur-face before the BHA is run, and its effecton the drilling
angle is controlled byusing the orienting tool to rotate the
toolface. Progress is monitored by the SLIM1MWD tool, which relays
the information tosurface via mud pulses.
A CTU employs a low WOB, 2000 lb[900 kg] compared to 4000 to
6000 lb[1800 to 2700 kg] for conventional slim-hole drilling. So
high-speed700 rpmlow-torque drilling motors are expected tobe most
effective. Polycrystalline diamondcompact or thermally stable bits
are used.
Injector head
Stripper
Drill floor
Ground
ChokeKill
Mud returns
Annular preventer
Blind rams
Shear rams
BOP Stack71/16in. 5000 psi
Wellhead, casing
or christmas tree
49July 1992
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fluid, a trailer-mounted pumping and treat-ment unit has been
constructed.
In a vertical hole, the setdown weightread at surface is
equivalent to the WOB.However at high angles, the tubing
com-presses inside the wellbore. If too muchweight is set down, the
tubing may lockagainst the walls of the well, failing to trans-fer
any further weight to the bit.7
Experience from the Paris basin wellshowed that while manual
control of set-down weight was possible, it was tediousand required
absolute concentration fromthe operator. To improve drilling
efficiency,the CTU has been fitted with a system thatautomatically
maintains a setdown weight.With this autodrilling system, the
operatorcan monitor progress without having tomake continual minute
weight changes.
The task force is reviewing three otherareas of equipment
development underreview. All involve handling tubulars:removing the
existing production tubing in
re-entry wells, deploying the BHA into alive well, and running
casing.Operational and safety procedures
Procedures for controlling a slimhole wellwhen drilling with a
CTU differ from thoseneeded when drilling with a
conventionalslimhole rig. At the heart of this is the differ-ence
in annuli. Conventional slimholewells have a narrow annulus and the
mudtraveling up it creates a back pressure,called the equivalent
circulating density(ECD). The ECD increases with pump rateand
raises bottomhole hydrostatic pressure.This provides the option of
dynamic
killincreasing the rate to increase thepressurebut also a
potential disadvantageof losing mud due to ECD exceeding
theformation fracture gradient.
nsn Comparison of gas kicks in 5000-ft wellsdrilled using
coiled-tubing and conven-tional methods with 31/8-in. and
61/2-in.BHAs, respectively. SideKick software wasused to compare
the effects of influxesthat gave similar annular heights. In
both
cases, the drillers method was used to cir-culate out the kick,
during which casingshoe pressures were about the same.Because of
its smaller annular volume,the well being drilled by CTU
experi-enced much smaller pit gains.
wells (left). But in modeling an influx of 7.5barrels in the
slim and conventional annuli,the SICP and CSP in the coiled-tubing
wellwere much higherdouble or more.
Therefore, early detection of gas influxesduring coiled-tubing
drilling is vital. TheCTUs stripper seals the annulus and
ensuresthat the mud return line is full, improvingthe reliability
of delta flow measurements
the difference between mud flow rate in andout of the well.
Delta flow is measurabledown to 10 gal/min [0.8 liter/sec],
permit-ting rapid detection of kicks after allowingfor the volume
increase due to cuttings. Inthe mud pits, resolution of
conventionallevel sensors is improved by having mudtanks with a
smaller base area than is normal.
All drilling operations are subject to safetyregulations
limiting operational equipmentto zonesin Europe, Zone I allows only
themost stringent explosion-proof equipment,Zone II the next most,
and so on. Ironically,the compactness of a CTU complicates
compliance with these regulations.In the Paris basin well, the
Zone II classifi-cation was specially reduced by the authori-ties
from a 100-ft to a 50-ft radius from thewellhead. If the radius had
been any larger,it would have extended the zones require-ments to
the cars on the edge of the lease(next page). Changes in local
regulationsand in equipment classification may berequired in the
future.
Tubing limitsCoiled tubing had a slowstart as a workover service
because of unre-liability and propensity for unpredicted fail-ure.
To combat this, Dowell Schlumberger
has developed a better understanding of thefactors governing
tubing fatigue; this is nowbeing applied to drilling
operations.9
Repeated use of coiled tubing has threetypes of limitation:
50 Oilfield Review
7. Ackert et al, reference 1.
8. White D and Lowe C: Advances in Well ControlTraining and
Practice, paper, presented at the ThirdAnnual IADC European Well
Control Conference,Noordwijkerhout, The Netherlands, June 2-4,
1992.
9. Newman KR: Coiled-Tubing Pressure and TensionLimits, paper
SPE 23131, presented at the OffshoreEurope Conference, Aberdeen,
Scotland, September3-6, 1991.
10. Newman KR and Newburn DA: Coiled-Tubing-LifeModeling, paper
SPE 22820, presented at the 66thSPE Annual Technical Conference and
Exhibition,Dallas, Texas, USA, October 6-9, 1991.
Newman K: Determining the Working Life of aCoiled Tubing String,
Offshore51 (December1991): 31-32, 34-36.
25
40 80
15
Pitgain,
bbl
Time, min
Coiled tubing
Conventional drilling
5
110 130
600
800
1000
Casingshoepressure,psi
0
When drilled with a CTU, the annulus islargerparticularly in
re-entry wellsECDis not a factor and dynamic kill cannot beapplied.
To evaluate other well-kill strate-gies, the task force used
SideKick softwareto model gas influxes in a full size wellbeing
drilled conventionally and a slimhole
well being drilled by a CTU.8The SideKick model was used to
assess
the significance of the volume of influx.First, it modeled
influxes that gave compara-ble heights of gas in conventional
andcoiled-tubing annuli (about 7.5 and 3 bar-rels, respectively).
The shut-in casing pres-sure (SICP) at surface and the casing
shoepressure (CSP) were broadly similar in both
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Pressure and tension limitsthe burst andcollapse pressures and
the maximum ten-sion and compression at various pres-sures. These
are analogous to the limitsexperienced by drillpipe and can be
cal-culated through tests and carefullyavoided during
operations.
Diameter and ovality limitsthe degreeto which the pipe is
collapsed, ballooned
or mechanically damaged. This also hasan analogy in drillpipe
where damagedpipe and couplings have to be detected.With coiled
tubing, the physical shape ofthe tubing can be continuously
monitoredduring the job to detect damage.
Life limitsprimarily due to bending inthe pipe at the gooseneck
and on the reelas it is spooled on and off, often with thetubing
pressured. Anticipating life limits oftubing has proved difficult,
but is vital toavoid catastrophic failure. At its crudest,the
fatigue of a reel of tubing can beequated to the number of times it
is run
into and out of the welltermed cycles.After extensive research,
Dowell Schlumber-ger has developed a way of assessing coiled-
tubing fatigue that is more sophisticated thansimply counting
cyclesthe CoilLIFEmodel.10 During jobs, all tubing movementand
pressures are monitored and recorded.The CoilLIFE software then
calculates theamount of life remaining in the string. Ittakes into
account the relative severity ofeach cycle, the nature of the
fluids that havebeen pumped and the sequence in which
the cycle occurredwhich affects the accu-mulated
damage.Personnel requirementsThe number of
personnel required for coiled-tubing drillingis likely to be
about 50% of that needed forconventional operations. Not only are
day-to-day operational requirements lower, butthe number of service
personnel can also bereduced. For example, when running cas-ing,
the mud system could be employed tomix and pump cementeliminating
theneed for a cementing engineer. All thedrilling information,
along with basic mudlogging data and general surface data, will
be centralized in a computerized informa-tion system,
eliminating the need for a full-time mud logger. CFnsn Layout of
Elfs
coiled-tubingdrilling site in theParis basin,France.
51July 1992
Portakabin Portakabin
Access road
CT unitGenera
tor
Catfracunit
backuppump
Bin Bin Bin
Substructure
Cranetruck
Mud products
storage area
Tool rack
50 ft safety perimeter
Water tank
Mud treatment/
pumping unit
Fuel tank
Choke
manifold
