EP0489816A1 - Well casing flotation device and method - Google Patents

Well casing flotation device and method

Info

Publication number
EP0489816A1
EP0489816A1 EP90913295A EP90913295A EP0489816A1 EP 0489816 A1 EP0489816 A1 EP 0489816A1 EP 90913295 A EP90913295 A EP 90913295A EP 90913295 A EP90913295 A EP 90913295A EP 0489816 A1 EP0489816 A1 EP 0489816A1
Authority
EP
European Patent Office
Prior art keywords
fluid
duct
cavity
flotation
plug
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP90913295A
Other languages
German (de)
French (fr)
Inventor
Mark David Mueller
Frank Leroy Unocal Indonesia Inc. Jones
Julio Manuel Quintana
Kenneth Edward Ruddy
Michael Gene Mims
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Union Oil Company of California
Original Assignee
Union Oil Company of California
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US07/401,086 external-priority patent/US4986361A/en
Priority claimed from US07/560,389 external-priority patent/US5113411A/en
Application filed by Union Oil Company of California filed Critical Union Oil Company of California
Publication of EP0489816A1 publication Critical patent/EP0489816A1/en
Withdrawn legal-status Critical Current

Links

Classifications

    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B33/00Sealing or packing boreholes or wells
    • E21B33/10Sealing or packing boreholes or wells in the borehole
    • E21B33/13Methods or devices for cementing, for plugging holes, crevices or the like
    • E21B33/14Methods or devices for cementing, for plugging holes, crevices or the like for cementing casings into boreholes
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B33/00Sealing or packing boreholes or wells
    • E21B33/10Sealing or packing boreholes or wells in the borehole
    • E21B33/13Methods or devices for cementing, for plugging holes, crevices or the like
    • E21B33/14Methods or devices for cementing, for plugging holes, crevices or the like for cementing casings into boreholes
    • E21B33/16Methods or devices for cementing, for plugging holes, crevices or the like for cementing casings into boreholes using plugs for isolating cement charge; Plugs therefor
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B31/00Fishing for or freeing objects in boreholes or wells
    • E21B31/035Fishing for or freeing objects in boreholes or wells controlling differential pipe sticking
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B43/00Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
    • E21B43/02Subsoil filtering
    • E21B43/10Setting of casings, screens, liners or the like in wells
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B7/00Special methods or apparatus for drilling
    • E21B7/04Directional drilling

Definitions

  • This invention relates to well drilling and well completion devices and processes. More specifically, the invention relates to an apparatus and method of setting liner or casing strings in an extended reach well, during oil, gas or other well completions.
  • a string In some extended reach wells, such as wells drilled from platform or "islands," a string must be set in a slant drilled (i.e., inclined angle) portion of a deviated hole.
  • the inclined portion is located below an initial (top) portio of a lesser inclined angle.
  • the angle (from vertical) of these inclined holes frequently approaches 90 degrees (i.e., the horizontal) and sometimes exceeds 90 degrees. The result is a well bottom laterally offset from the top by a significant distance.
  • a deviated hole portion is defined as one having an axis in a direction at a significant incline angle to the vertical or gravity direction.
  • a casing or liner pipe string may become differentially stuck before reaching the desired setting depth during running into a deviated or high drag hole, especially if the incline angle exceeds a critical angle where the weight of the casing or liner in the wellbore produces more drag force than the component of weight tending to slide the casing or liner down the hole. If sufficient additional force (up or down) cannot be applied, the result will be stuck pipe string and possible effective loss of the well. Even if a stuck string is avoided, the forces needed to overcome high drag may cause serious damage to the pipe.
  • the plugable portion After providing a means to plug the ends of a pipe string portion, the plugable portion is filled with a low density, miscible fluid to provide a buoyant force.
  • the low density fluid must be miscible with the well bore fluids and the formation. Miscibility is required to avoid a burp or "kick" to or from the formation outside the pipe string when plugged portion fluid is discharged to the formation/well bore. Circulation of drilling mud is also not possible during running or feeding the plugged string into the wellbore. After feeding the plugged string into the well bore, the plugs are drilled out and the low density miscible fluid is forced into the well bore/pipe annulus. Further casing operations, if any,
  • cementing are accomplished without the assistance of a low density miscible fluid providing a buoyant force.
  • the known string flotation method requires added risk and well completion steps, especially if cementing is required.
  • the low density fluids compatible with the formation and bore fluid must be circulated out ahead of a cement slurry. This requires drilling out the plug(s) prior to cementing of the casing or liner string. Subsequent to the cementing, a second drilling out (of hardened residual cement) is frequently also required.
  • a simplified flotation device and method are needed to allow the placement and completion of long pipe strings in extended reach well bores.
  • the method and device should also be safe, reliable, and cost effective.
  • the invention provides a flotation plug device and process for running a casing or liner into a high drag inclined hole without the need to remove the plug device prior to cementing.
  • a float shoe/float collar and a shear-pinned plug insert trap air (or other low density fluids, not necessarily miscible with the formation or well bore fluids) within a portion of the casing string being run in a deviated hole.
  • a sealed port in the insert is opened to allow the air to be vented to the surface.
  • a cementing bottom wiper plug induced by applied pressure, forces the plug and insert to slide piston-like within the string to land and latch into a landing collar during normal cementing procedures.
  • the latched plug/insert/landing collar forms a single drillable assemblage. The assemblage is removed during normal post-cementing drilling out, avoiding multiple drilling steps.
  • the process of using this first embodiment attaches a float shoe and/or float collar (having a flapper or check valve) and a landing collar at one end of an air filled flotation portion of the casing.
  • the float shoe or collar prevents fluid inflow as the casing is lowered into the initial low angle portions of the fluid filled well bore.
  • An insert attached to an upper portion of the casing forms the other end of the "floating" portion.
  • the insert includes a releasable plug (attached by a first set of shear pins) to block a passageway in the body of the insert and contain the air.
  • the plug insert is attached within and pinned to the string with a second set of shear pins. This seals the air to form a flotation cavity, creating an increased buoyant force on the pipe string when the string is submerged in the fluid filled well bore.
  • the buoyant forces reduce effective weight, assisting the running of the string to the setting depth by reducing drag forces generated by the effective weight.
  • increased internal string pressure shears the first set of shear pins, opening the passageway. This allows air to vent up the string while mud flows down.
  • a cement slurry is then pumped down-hole separated from the mud by a bottom wiper plug.
  • the bottom wiper plug mates with the open ported insert and shears the second set of shear pins. Shearing releases the mated wiper plug and insert combination to move down-hole. The combination then latches to the landing collar, forming a single driliable assemblage.
  • a top wiper (segregating cement slurry from fluid above the cement slurry) may also be used. A differential pressure across the top wiper forces the cement slurry out and up the bore/string annulus. The assemblage (and top wiper, if used) is drilled out during normal post-cementing procedures.
  • the ported and slidable air trapping insert allows simplified running of long strings in inclined holes by controlled reduction of effective string weight, not by adding weight or reducing the coefficient of friction. Flotation is achieved without the need to 1) use a miscible low density fluid or 2) separately remove plugs prior to cementing the string.
  • Another embodiment also forms a flotation cavity in a portion of a tubular string between two ends (e.g., between a shoe and an insert/plug) to be set into a borehole, but adds a conduit between the flotation cavity ends.
  • This embodiment is preferred when sufficient buoyant forces can be obtained when the added space and weight of the conduit within the flotation cavity is considered.
  • the conduit and tubular string now form an annular shaped flotation cavity where the lower density fluid is contained outside the conduit to provide the increased buoyant forces.
  • the conduit (surrounded by the flotation cavity) allows drilling mud and other fluids to circulate during running or other following operations, specifically including cementing.
  • Figure 1 shows a schematic cross sectional view of one flotation device used to provide buoyant liner or casing forces during running operations
  • FIG. 2 shows a schematic side view of an alternative embodiment of the flotation device during installation
  • Figures 3a through 3f show simplified representations of the alternative device during well completion activities
  • Figure 4 shows a side and partial cross sectional view of an air trapping device portion of the engaged assemblage
  • Figure 5 shows a side cross-sectional view of another alternative embodiment
  • Figure 6 is a graphical representation of the results of a test of the flotation device.
  • Figure 7 shows a schematic side view, similar to Figure 2, of an alternative air annulus embodiment during installation.
  • FIG. 1 shows a schematic cross-sectional view of one embodiment for running a casing string (or liner or other duct) into a fluid filled bore hole (or cavity) 2.
  • a portion of the casing or liner string 4 is placed in the top vertical or low angle section of drilled bore hole 2 (lower slanted or high angle portion not shown for clarity).
  • the bottom end 3 of liner or casing string 4 has a float shoe 5 attached.
  • the float shoe 5 includes an outwardly or downwardly opening flapper or check valve 6.
  • the valve 6 prevents inflow of a first or bore fluid 7 during the running or lowering of the string (see downward direction "A" shown on Figure 1) into the well bore 2.
  • the flapper (or ball) of valve 6 may be spring or otherwise biased closed to prevent inflow, but allow pressurized fluid outflow (in the downward direction "A"). Outflow occurs if the pressure force within the string 4 can overcome flap seating forces and bore fluid 7 pressure forces.
  • Figure 1 shows the bladder 10 in a fully inflated position. Inflation is achieved by applying air or other second fluid pressure through open venting ports 15 in stem 14 (source of inflation air is not shown for clarity). Inflation also pressurizes the flotation cavity 12 to prevent collapse of the string under down hole conditions. After inflation, pulling or twisting of stem 14 closes the air venting ports 15 and the source of inflation can be removed.
  • the bore fluid 7 is normally a single density drilling mud, but may also be a mixture or several layers of different density fluids.
  • the various densities within the well bore allow a single flotation cavity 12 to have different buoyant forces at different portions of the well bore proximate to different density bore fluids. This can be highly desirable in extremely high drag well bores or variable incline angle bore portions.
  • the distance between the float shoe 5 at one end of the flotation cavity 12 to the bridge plug 8 at the other end is variable to allow control of buoyant forces generated. Repositioning the bridge plug 8 changes the buoyant ' forces on the "floating" pipe string portion enclosing cavity 12.
  • the float shoe 5 is installed at the surface before entry of the casing string end into the bore hole 2.
  • the length of the flotation cavity or portion of the string is selected to control the force tending to run the casing into the hole.
  • the bridge plug 8 seals and is attached to the duct by pressurizing the bladder after installing the length of "floating" pipe string portion into the bore hole 2. Alternatively, repositioning the bridge plug when in the hole may also be possible to further adapt and change buoyant forces, if required.
  • Buoyant forces in a non-vertical borehole portion can provide bending forces (e.g., buoyant forces exceed the weight of a buoyed portion of pipe string ahead of a non-buoyed portion in an inclined borehole curving towards a horizontal orientation), and repositioning the bridge plug can adjust these bending forces to adapt to the specific incline/curvature/bending needed.
  • the diameter and cross sectional thickness (and associated weight) of the pipe string enclosing cavity 12 can be set equal to the weight of the displaced bore fluid 7. This creates a neutral buoyancy so that this "floating" section exerts no upward or downward forces on the walls of the bore hole 2, regardless of orientation or slant. Even if-,neutral buoyancy is not desired, the controlled effective (buoyed) weight of the selected casing/liner pipe string which must be supported (hung) and any resulting drag during installation operations can be significantly reduced. This reduced maximum effective weight may allow a smaller capacity derrick or rig to be used, or added safety when using a larger one.
  • the remainder of the string above the bridge plug 8 is fluid filled with a third .or heavier fluid 13, such as drilling mud.
  • a third .or heavier fluid 13 such as drilling mud.
  • the larger effective weight of the remaining non-flotation portion forces the flotation cavity pipe string portion to the other (i.e., higher incline angle) portions of the well bore 2 (see Figure 3). These other well portions may be nearly horizontal.
  • the non-flotation portion may extend to the surface, i.e, fill the remainder of the string with the heavier fluid 13.
  • string installation may require a second or multiple floating portions within the string, separated by other bridge plugs 8, especially for deviated hole portions having different angles.
  • a retrieving device is run on the end of drill pipe and latched on the retrieving stem (or fishing neck) 14.
  • the ports 15 are opened by the action of the drill pipe latching or twisting onto the retrieving dog on stem 14.
  • the ports 15 may also be remotely actuated in an alternative embodiment. These opened venting ports 15 allow the higher density fluid 13 to exchange places with the lower density fluid (air) in cavity 12.
  • the bridge plug 8 is also then deflated by twisting and/or pulling on the retrieving stem 14.
  • An alternative embodiment can separately actuate cavity pressurisation/venting and bladder inflation/ deflation. Cavity pressurization may not be required if the string can withstand the differential pressure. Fluids (water in this embodiment) used to inflate bladder and pressurize cavity can also be segregated in this alternative embodiment.
  • the latch-in collar 16 is attached to the casing or liner string 4 near the float collar/float shoe end (see Figure 1) of the cavity 12a.
  • the latch-in collar 16 includes a threaded or latching aperture 17 (shown dotted in Figure 2 for clarity) which engages a threaded or latching protrusion 18 of an air release plug holder 19 of an air trapping device (or member) 20.
  • the piston-like air trapping device 20 also includes an air release plug 22 (shown dotted for clarity).
  • a first set of (or passage) shear pins 23 attaches the release plug 22 to an internal port (or passageway) 24 (shown dotted for clarity) within the plug holder 19.
  • a second set of (or plug holder) shear pins 21 attaches the plug holder 19 to the liner/casing 4.
  • the size and shape of the plug 22 and internal port 24 allow the sheared away plug 22 to slide down (direction "A" is towards the well bottom, not necessarily vertically down) toward the protrusion 18.
  • the internal port 24 is in fluid communication with both the cavity 12a below (through slotted ports 25) and the non-flotation fluid 13 above the translated plug 22.
  • the lateral slotted ports 25 allow fluid passage to and from the lower portion of the internal port 24 and the cavity 12a (fluid flow shown as a solid and dotted arched arrow).
  • the height of plug 22 is selected to be less than height of the slotted ports 25, allowing fluid flow in this lower portion.
  • a basket 26 near the bottom of the air trapping device 20 acts as a retainer of the plug 22 within the internal port 24 when the passage shear pins 23 break and plug 22 moves downward under fluid pressure from above.
  • a cement slurry is introduced into the string above the air trapping device 20.
  • a bottom wiper plug 27 separates the cement slurry above wiper plug 27 from the drilling mud 13 above the air trapping device 20.
  • a third set of (or wiper) shear pins 30 attaches an inner wiper plug 29 to a wiper plug port 28 (shown dotted) of the wiper plug 27. The inner plug 29 prevents fluid communication above and below the wiper plug 27 until the inner plug 29 moves (i.e., is sheared away) from the plug port 28.
  • Each set of shear pins is selected to rupture at increasingly incremental pressures above normal operating hydrostatic pressure within the string.
  • This alternative embodiment uses a (differential) pressure increment of 34 atmospheres (500 psi) to prevent accidental actuation (shearing).
  • the first set of shear pins 23 rupture at approximately 34 atmospheres (500 psi) over hydrostatic (allowing air to vent and mud to circulate)
  • the second set of shear pins 21 (allowing the piston-like trapping device to translate) are set at approximately 68 atmospheres (1000 psi) over hydrostatic
  • the third set of shear pins 30 (allowing cement slurry flow) are set at approximately 102 atmospheres (1500 psi) over hydrostatic.
  • FIGS 3a through 3f show simplified representations of the alternative apparatus shown in Figure 2 during well completion activities in the deviated well bore 2.
  • the inclined angle "i" angle between the center line of the slanted well portion and the vertical shown in Figure 3a
  • a positive means to prevent fluid inflow to the bottom of the air filled cavity is needed, i.e., float shoe 5.
  • Lower incline angle holes may avoid using a float shoe, depending upon density differences and the lack of fluid miscibility to limit inflow to the flotation portion.
  • Large incline angles "i” can also indicate the need for a flotation method of running the casing into the hole.
  • FIG 3a shows the initial apparatus positions after installing the string 4 in the deviated well bore 2.
  • the cavity 12a includes landing collar 16 between the float shoe 5 and air trapping device 20.
  • the air release plug 22 (shown darkened for clarity) is shear pin attached to air trapping device 20 (see Figure 2).
  • Cavity 12a contains trapped air or other low density fluid, creating buoyancy during the (just completed) insertion of the string portion into the bore hole 2 containing drilling mud 7.
  • drilling mud 7 is also the non-flotation fluid (see item 13 in Figure 1) present above the air trapping device 20 in a non-flotation (or high density fluid filled) cavity portion 31.
  • the apparatus geometry and mud density can be adjusted to control buoyancy and the effective weight of the casing 4 proximate to the cavity 12a.
  • Figure 3b shows the apparatus of Figure 3a after rupturing the first set of shear pins 23 (see Figure 2) and movement of the air release plug 22.
  • An increased pressure above the air trapping device 20 sheared the first set of pins.
  • the positions of the elements are unchanged except for the release plug 22.
  • the sheared-away release plug 22 may be biased and/or pressure actuated to slide towards the cavity 12a to open ports 25 (see Figure 2). Opening ports 25 allow fluid communication between the air cavity 12a and non-flotation (i.e., filled with a higher density fluid) cavity portion 31.
  • the air from cavity 12a migrates upward in the casing ox liner 4 so that it may be then vented at the surface. In wells that have an incline angle of greater than 90 degrees, it may be necessary to positively vent air from cavity 12a.
  • the drilling mud 7 and displaced air form a mud-air interface 32 in the previously weighted cavity 31.
  • the previously buoyant cavity 12a is now full of drilling mud 7.
  • Another alternative embodiment can provide a plurality of internal ports 24 and release plugs 22. This embodiment would assure migration/displacement of fluids in various orientations, e.g., at least one internal port primarily for venting air towards the surface, another for flowing drilling mud into cavity 12a.
  • FIG 3d shows the devices after installing and pumping a bottom wiper 27 (i.e., a plug wiping the interior surface of the string as it moves) to mate with the air trapping device 20.
  • a bottom wiper 27 i.e., a plug wiping the interior surface of the string as it moves
  • Above the bottom wiper 27 is a cement slurry 33.
  • Drilling mud 7 within the casing 4 above air trapping device 20 has been displaced through passage 24 (See Figure 2) in the air trapping device 20, landing collar 16, and flapper valve 6 of the float shoe 5 (see Figure 1).
  • a top wiper 34 contains the cement slurry 33 between the two sliding and sealing wipers.
  • Wiper plug 29 contains the cement 33 between the landed assemblage at the landing collar 16 and the top wiper 34.
  • the drilling mud 7 previously contained in cavity 12a has been displaced and flowed though the landing collar 16 and flapper valve 6 of float shoe 5 into the annular space between well bore 2 and casing/liner 4. Displaced drilling mud continues to flow through the float shoe 5 until the top wiper 34 joins the assemblage. Applying another pressure increment tends to shear the third shear pin set 30 (see Figure 2) holding the wiper plug 29.
  • Figure 3f shows the top wiper plug 34 joined to the assemblage and cement slurry 33 nearly fully displaced out of the string ' 4 to the annulus between the casing/liner 4 and well bore 2. Shearing and displacing the wiper plug allows the cement to flow through the bottom wiper plug 27 and the slotted ports 25 (see Figure 2) to the annulus between the casing 4 and well bore 2 through flapper valve 6. The pressurized cement flow also causes the top wiper 34 to slide and contact the bottom wiper plug 27. The cement-mud interface 35 (previously separated by bottom wiper 27) is now in the annulus between the well bore 2 and casing 4. A portion of the cement slurry 33 remains between the assemblage and float shoe 5. This residual cement is drilled out (after setting) in normal post cementing operations (not shown).
  • FIG. 4 shows a side and partial cross sectional view of the engaged bottom wiper 27 and pinned air trapping device 20 assemblage within a joint in the casing string 4.
  • the casing string 4 (shown quarter sectioned) in hole 2 is composed of many sections of pipe segments 36 joined by a drift (or piping) collar 37 at each end.
  • the piping collar 37 is internally threaded to join the external threaded ends of pipe segments 36.
  • the illustrated pipe string joint is typical of the string of joined pipe segments.
  • An alternative pipe string can used without interconnecting pipe segments, avoiding the need for a piping or drift collar 37.
  • the piping shown is attached to the air release plug holder 19 portion of the air trapping device 20 (shown in cross section) by the second set of shear pins 21.
  • the air trapping device 20 also includes a pair of holder O-ring seals 38 forming a fluid tight sliding connection to the interior of the string 4.
  • the internal port 24 is attached to the air release plug holder 19 portion of the air trap
  • FIG. 2 (see Figure 2) includes an initial threaded portion 39, a cylindrical wiper plug mating portion 40 and a release plug cylindrical portion 41.
  • the plug 22 was retained by the first set of shear pins 23 (shown sheared in Figure 4). A pressure differential was applied sufficient to break the plug shear pins 23 and translate the plug 22 to rest against the perforated basket 42 (similar to basket 26 shown in Figure 2).
  • The-.plug 22 also includes a plug O-ring seal 43 which, when plug 22 is pinned in the initial position, formed a fluid tight sliding seal to the plug cylindrical portion 41 of the internal port 24 (see Figure 2).
  • the perforated basket 42 catches and prevents further translation or loss of the plug 22.
  • the perforations of basket 42 and ports 25a allow fluids to pass around the displaced plug 22.
  • the air trapping device 20 also includes a latch protrusion 18 which attaches to the landing collar 16 (see Figure 3) after the second set of shear pins 21 are broken and the assemblage has been displaced to landing collar 16.
  • the protrusion 18 and latch or threaded portion 39 prevent rotation of the assemblage (wiper plugs, air trapping device and landing collar) when the assemblage is being drilled out.
  • the bottom wiper plug 27 (shown in side view for clarity within sectioned casing string 4) includes a series of elastomeric cup shaped wipers 44, an external threaded or latch portion 45 (threadably mating with the internal threaded or latch portion 39 of the air trapping device 20), a pair of elastomeric wiper O-rings 46 (shown darkened for clarity and bearing against the interfacing passageway portion 40), and (hidden from view) an inner plug 29 held in place within wiper port 28 by a third set of shear pins 30 (see Figure 2).
  • An alternative embodiment can extend the bottom wiper dimensions to positively displace the plug 22 when bottom wiper contacts and mates with air trapping device 20 (see Figure 2).
  • Other types and locations of elastomeric seals, and other mating shapes and dimensions may also be provided for other alternative embodiments.
  • Solid materials of construction of the air trapping device 20 are primarily 6061 aluminum, but various other materials of construction-,can be used, as long as they are drillable or otherwise removable.
  • the bottom wiper 27 acts as a sliding and wiping seal or separator along the interior of the casing.
  • the bottom wiper 27 separates cement on the upstream side from fluid on the downstream side during certain fluid movements, i.e., slurry cement pumping down-well (direction "A").
  • the orientation (right hand engaging) of the external and internal threads shown in Figure 4 are selected to tighten or engage the air trapping device during drilling and prevent unlimited rotation.
  • a further advantage of this embodiment is the use of existing components, simple fabrication and design.
  • the top and bottom wiper plugs can be produced by modifying a commercially available liner wiper plug.
  • the use of 6061 aluminum results in light weight and easily machinable components of the device.
  • FIG 5 shows a side cross-sectional view of another alternative embodiment of an air trapping device or an air plug 20a.
  • a second set of shear pins 21 attaches the air plug 20a to the casing pipe string 4.
  • the air plug 20a is similar in construction to a conventional bottom cementing plug.
  • the air plug 20a includes an aluminum insert 48 covered by rubber wipers 44.
  • a rupture diaphragm 49 separates the flotation cavity 12b, retaining air (or other low density fluid such as nitrogen or light hydrocarbon fluids) from the higher density fluid filled cavity 31a.
  • the rupture diaphragm 49 replaces the releasable plug 22 and shear pins 23 of this alternative embodiment (see Figure 2).
  • the rupture diaphragm 49 has the advantage of simplicity, but may not be capable of withstanding the down hole pressures and forces or be removable without difficulty. Still other alternative embodiments could replace other slidable plugs and inserts with rupture or burst diaphragms. Once the casing or liner string is run to the total or desired depth, increased pressure is applied to burst the diaphragm 49. Similar to the previous discussion, the ruptured diaphragm allows the trapped air from cavity 12b to migrate to the top of the well and be replaced by drilling mud. The air is again vented at the surface (not shown for clarity). Circulation of the drilling muds can now be accomplished in this embodiment, if required. Near normal cementing operations can now be accomplished.
  • Figure 6 is a graphical representation of the results of a test of the flotation method in a deviated underground well bore. The devices and methods used were similar to those shown and described in Figure 1.
  • Figure 6 shows the actual and expected indicator (or slack-off) weight supported during installation of the casing pipe string 4 (see Figure 1). The string was installed by sections from a derrick at the surface.
  • the remaining string portion above the air filled cavity was filled with drilling mud.
  • the actual and flotation expected curve shape (dotted and associated dashed line portion “D"), are similar to, but displaced from, the expected non-flotation curve shape (solid line “B”). This displacement allows the string to be placed to a greater depth (depth increment "E") before the supported weight becomes insufficient to move the string into the bore hole.
  • the dotted and dashed curve shape (and ability to install casing or liner) can be altered by changing the number and length of the floated sections as well as by using a flotation fluid other than air or changing the density of the mud in the borehole or the mud above the flotation device.
  • the prior art non-flotation method (shown as a solid curve) was expected to produce a larger maximum force (or indicator weight as shown at point "F") to overcome the later developed frictional drag when compared to the flotation method maximum indicator weight (point "G") .
  • the mud filled sections generate more drag (shown by the indicator weight declining with depth) than can be overcome by weight (i.e., exceeds critical incline angle). If the particular well included an even higher incline angle section, the decline in indicator weight would be even more severe.
  • results of this test example show that flotation of the casing displaced and maintained a controlled margin of supported weight during the entire installation procedure, avoiding a stuck casing.
  • results also show that a reduced maximum indicator weight was achieved while allowing a deeper installation and avoiding multiple drilling out procedures.
  • Figure 7 shows a schematic side view, similar to
  • FIG 2 of another alternative embodiment (i.e., an air annulus embodiment) of the apparatus when near the location where the casing is to be set (i.e., one end of a casing string 4 ⁇ is near the bottom of the wellbore 2).
  • the extended reach wellbore 2 contains one or more drilling muds 7 having densities greater than air (or other fluid in cavity 12b) and a casing string 4.
  • a portion of the casing string 4 and ported packers/ retainers 55 and 56 forms the exterior surfaces of a modified "flotation" cavity 12b, similar to the cavity 12a shown in. Figure 2a.
  • the casing string 4 also contains drilling mud 1 , similar to Figure 2a.
  • the pipe string 4 has a float shoe 5 and float collar 16 attached proximate to one end of the pipe string similar to Figure 2, but the ends of the modified cavity 12b within the pipe string 4 is defined by a pair of inflatable packers/retainers 55 and 56, similar to the bridge plug 8 shown in Figure 1.
  • the air annulus embodiment also contains a conduit 60 forming the interior surface of (i.e., is surrounded by) cavity 12b.
  • the conduit 60 provides a passageway for fluids from one end of the modified cavity 12b to another (i.e., conduit 60 is attached to ports in the upper inflatable packer 55 and lower cement retainer 56).
  • the conduit 60 is attached in this embodiment to a surface connecting conduit 61 (typically a string of smaller diameter drill pipe sections) within the remainder of the casing string 4.
  • the fluid shown within conduits 60 and 61 is drilling mud 7, allowing drilling mud 7 to be circulated during running or other operations, but a cement slurry or other fluid may also be conducted.
  • Mud circulation i.e., pumping drilling mud at the surface through the casing string 4, surface connecting string 61, and conduit 60 to the borehole 2 through float collar 16 and float shoe 5 to the annular space between the casing string 4 and borehole- 2, then screened or filtered to remove particles (e.g. cuttings or other formation solids) prior to returning to the surface pump) allows lubrication and other fluid properties to assist in the running operations, while the casing string is buoyed within the drilling muds in the borehole 2.
  • a wire-line plug is then set in a fitting (e.g., an XN nipple) in conduit 60 and tested.
  • Packer 55 is then inflated and tested.
  • Plug 63 is then pulled and conduit 60 is filled with mud 7.
  • the remaining portions of the casing 4 are run in hole while circulating mud 7.
  • the surface connecting conduit 61 is run in hole, latching and sealing at overshot connector 62 to conduit 60.
  • the casing 4 is reciprocated (i.e., translated in an oscillating manner along the borehole axis) and drilling mud 7 is circulated until clean (free of filterable solids).
  • a cement slurry is then pumped down the surface connecting conduit 61 and conduit 60 while the casing is reciprocated.
  • Inflatable packer 55 can be deflated before or after cement setting, along with the venting of air in cavity 12b and pulling out surface connecting conduit 61, conduit 60, inflatable packers/retainers 55 & 56.
  • a similar procedure is used to run, rotate and cement a liner (not shown, but similar to casing 4 shown in Figure 7).
  • the liner is a tubular string to be contained in a lower portion of the borehole 2 and attached or hung from a larger diameter up-hole casing section. At least a first portion of a liner is run into the borehole 2.
  • the lower cement retainer 56, plug 63 and upper inflatable packer 55 are similarly set and tested in the liner. Plug 63 is removed and the assembly is filled with drilling mud 7 except for cavity 12b.
  • the surface connecting conduit 61 is similarly latched and sealed to connector 62, followed by running the liner and surface connecting conduit 61 in hole.
  • the liner is then rotated (in an oscillating or continuous manner) and drilling mud is circulated clean.
  • a cement slurry is pumped down the conduits out to the borehole/liner annulus while the liner continues to be rotated, again improving distribution and bond strength.
  • the liner is released (hung on casing), the packer is deflated, and surface connecting conduit (drill pipe), packer(s) and conduit are pulled out.
  • a modified air trapping device similar to the device 20 shown in Figure 2 may be used in place of the upper inflatable packer 55.
  • the modified device includes another port for connecting to conduit 60.
  • conduit 60 may be directly connected to a modified float shoe or float collar, similar to the shoe 5 and collar 16 shown in Figure 2.
  • a 17.8 cm (7 inch) nominal diameter, 129 newtons (29 pound) nominal weight liner string approximately 1676.4 meters (5,500 feet) long is to be run to 4572 meters
  • the well path after an initial near vertical section of approximately 304.8 meters (1000 feet) is planned to include a build section where an incline angle build rate of approximately 3.5 degrees per 30.48 meters (100 feet) is maintained until an incline angle of 80.88 degrees is reached at approximately 1009.2 meters (3311 feet) measured depth.
  • the incline angle of approximately 80.88 degrees is to be held until a measured depth of4572 meters (15,000 feet) is reached.
  • a 9 5/8 inch (24.45 cm) nominal diameter casing is planned to extend to 3048 meters (10,000 feet), with an expected friction factor during running of the liner within the casing of 0.35.
  • the expected friction factor in the nominal 21.59 cm (8 1/2 inch) diameter hole extending from 3048 meters (10,000 feet) to 4572 meters (15,000 feet) is 0.50.
  • the planned mud has a density of approximately 1121 kilograms per cubic meter (70 pounds per cubic foot).
  • 1.814 kilogram (4 pound) tubing i.e., conduit 60 shown in Figure 7 within the liner, a buoyed weight of approximately 24.40 newtons/meter (18.00 pounds/foot) compared to a flotation cavity 12a (see Figure 2) within a liner buoyed weight (without tubing) of 33.69 newtons/meter (24.85 pounds/foot) .
  • shear pins placement of cylindrical or otherwise ported solid inserts (e.g., foam) or higher density fluid into the flotation cavity 12 in addition to lower density (flotation) fluids (to improve the control of buoyant forces); combining the float shoe, float collar, and/or the landing collar in a single component; combining centralizing (outward radial) protrusions on the string (to create a string stand off annulus within the well bore) with multiple trapping devices at pipe joints; replacing the float shoe valve with a float type trap or other back-flow preventer; and having translating components, conduits, and piping strings primarily composed of flexible material (to more easily navigate deviated sections and alter buoyant forces).
  • cylindrical or otherwise ported solid inserts e.g., foam
  • lower density (flotation) fluids to improve the control of buoyant forces
  • combining the float shoe, float collar, and/or the landing collar in a single component combining centralizing (outward radial) protrusions on the string (to create
  • a still further alternative embodiment is to make portions of the devices such as plugs from materials which are dissolvable, thermally degradable or fluid reactive/decomposing (avoiding pressure increments or drilling out procedures). Although no longer required, lubricants can also be used in conjunction with these flotation methods and devices to further control or reduce the running coefficient of friction.
  • opening a circulation and cementing path can be accomplished by a simple increase ⁇ in pressure and translation of insert/plug devices without entirely removing the devices. This embodiment also allows circulation during buoyant operations and reciprocating/rotation during cementing. Devices are finally removed by normal post-cementing drilling out techniques, avoiding the need for a separate removal step.
  • the use of air and lightweight materials minimizes storage and other related requirements.
  • the present invention also reduces the maximum capability of the drill rig needed to accomplish the setting of the casing/liner string and extended reach well could theoretically have an infinite length (i.e., total measured depth) if flotation cavity sections are at neutral buoyancy. More typically, the invention provides major advantages for higher than critical incline angle (e.g., nearly horizontal) well portions (to be lined or cased) of at least 914 meters (3,000 feet) in length , more preferably at least 1524 meters (5,000 feet), and still more preferably at least 1828 meters (6,000 feet) in length.
  • the buoyancy forces also allow a high build rate, limited only by the flexibility of the liner or casing tubular members.
  • the buoyant forces can theoretically provide a bending force without scraping (and possibly damaging or excessively opening) the build portion of the wellbore. More typically, the invention provides major advantages for build rates of at least approximately 2.0 degrees per 30.48 meters (100 feet), more preferably a build rate of at least approximately 3.5 degrees per 30.48 meters (100 feet). Further advantages of the device include: increased safety (avoiding large casing running loads at the drilling platform), reliability (reducing the likelihood of stuck casing), maintenance (single use, drillable compo ents), efficiency (full flow production/ injection capability), and reduced cost (no separate removal step or need to recover items from great depth).
  • Flotation devices for and methods of accomplishing drilling and completion of extended reach wells are also disclosed in paper entitled "Extended Reach Drilling From Platform Irene," by M.D. Mueller, J.M. Quintana, and M.J. Bunyak, presented to the 22 Annual Offshore Technology Conference in Houston, Texas, May 7 - 10, 1990, the teaching of which are incorporated herein by reference.
  • a hydraulic release oil tool which may be used advantageously with the present invention is disclosed in U.S. Patent Application Serial No. 07/418,510, filed on October 9, 1990, the teachings which are incorporated in their entirety by reference.
  • the release tool may be used to removably attach a drill string to a liner having a flotation cavity and being run into an extended reach wellbore.
  • the release tool allows bidirectional rotation and high torque, combined with ease of release and removal.

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Abstract

Un sabot à clapet inverse à orifices (5) et un collier d'ancrage (16) sont fixés à une première extrêmité d'une partie d'une colonne de cuvelage (4) et un élément rapporté coulissant pour piéger l'air (20) est fixé à l'autre extrêmité. L'élément rapporté piégeant l'air (20) comprend un passage pour le flux de liquide (24) bloqué par un dispositif (22) fixé par des broches de cisaillement à l'élément rapporté (20) ou bien l'élément rapporté piégeant l'air est un élément rapporté expansible (55) dont une conduite (60) offre un passage au liquide vers la première extrêmité. L'élément rapporté piégeant l'air et le sabot à clapet inverse forment une cavité d'air (12a ou 12b) à l'intérieur de la partie de colonnes (4). La cavité d'air crée des forces de flottations au cours des opérations de descente dans la colonne, de cimentation, ou au cours d'autres opérations de cuvelage dans un puits de forage (2) réduisant la probalité d'avoir un écoulement de retroussement et la probalitité correspondante d'avoir un cuvelage calé différemment (4). Cette cavité d'air permet aussi le mouvement alternatif et la rotation au cours de la cimentation et elle évite les étapes de démontage distinctes.An orifice reverse valve shoe (5) and an anchor collar (16) are attached to a first end of a portion of a casing column (4) and a sliding insert for trapping air (20 ) is attached to the other end. The air trapping insert (20) includes a passage for the liquid flow (24) blocked by a device (22) fixed by shear pins to the insert (20) or the trapping insert air is an expandable insert (55), a line (60) of which provides a passage for the liquid towards the first end. The air-trapping insert and the reverse valve shoe form an air cavity (12a or 12b) inside the column portion (4). The air cavity creates flotation forces during column descent, cementing, or other casing operations in a wellbore (2) reducing the probability of having a backflow and the corresponding probability of having a casing differently calibrated (4). This air cavity also allows reciprocating movement and rotation during cementing and it avoids separate disassembly steps.

Description

WELL CASING FLOTATION DEVICE AND METHOD
Related Applications and Publications
This application is a continuation-in-part (CIP) of co-pending U.S. Applications: (1) Serial No. 07/401,085, filed on August 31, 1989; (2) Serial No. 07/486,312 filed on February 28, 1990; and (3) Serial No. 07/560,389, file July 31, 1990, which is a CIP of applications (1) and (2). The teachings of these three prior filed applications are incorporated in their entirety herein by reference. Technical Field
This invention relates to well drilling and well completion devices and processes. More specifically, the invention relates to an apparatus and method of setting liner or casing strings in an extended reach well, during oil, gas or other well completions.
Background Art
Many well completions involve setting a liner or casing string in a portion of the well bore. In some extended reach wells, such as wells drilled from platform or "islands," a string must be set in a slant drilled (i.e., inclined angle) portion of a deviated hole. The inclined portion is located below an initial (top) portio of a lesser inclined angle. The angle (from vertical) of these inclined holes frequently approaches 90 degrees (i.e., the horizontal) and sometimes exceeds 90 degrees. The result is a well bottom laterally offset from the top by a significant distance. Current state-of-the-art allows extensive drilling of well bores at almost any angle, but current well completion methods have experienced problems, especially related to the setting o casing or liner strings in long, highly deviated well bores. The liner or casing string is set in a pre-drilled hole. The drill string and bit used to cut the hole is rotated, thereby reducing drag forces which retard the pipe string from sliding into the hole. The diameter and weight of the casing/liner string being set is larger and heavier than the drill string. Because of this, the torsional forces needed to rotate the casing or liner can be greater than the torsional strength of the pipe itself, or greater than the available rotary torque. Casing or liner strings are therefore normally run (i.e., slid) into the hole without drag reducing rotation.
Running in deviated holes can result in significantly increased (high) drag forces. A deviated hole portion is defined as one having an axis in a direction at a significant incline angle to the vertical or gravity direction. A casing or liner pipe string may become differentially stuck before reaching the desired setting depth during running into a deviated or high drag hole, especially if the incline angle exceeds a critical angle where the weight of the casing or liner in the wellbore produces more drag force than the component of weight tending to slide the casing or liner down the hole. If sufficient additional force (up or down) cannot be applied, the result will be stuck pipe string and possible effective loss of the well. Even if a stuck string is avoided, the forces needed to overcome high drag may cause serious damage to the pipe. These problems are especially severe for wells with long, nearly horizontal (i.e., an incline angle of nearly 90 degrees) intervals. Long, nearly horizontal well intervals may be needed for fluid production from tight and/or thin bed reservoirs or from fields having limited surface access. For example, an offshore drilling site may be unlicensable or excessively costly. The ability to drill from an on-shore site to an offshore resource horizontally displaced from the drilling site by several kilometers may mean the difference between an unavailable and a producing resource. Even for fields where reservoir access (or permeability) is not a problem, long nearly horizontal well portions may be economically desirable because of higher production rates. Higher production rates may be possible in horizontal well portions from zones where production of unwanted fluids (such as water/gas in oil fields) from adjacent beds, normally occurs in vertical wells, i.e., coning.
Common casing or liner running (i.e., installation) methods to overcome increased drag in a deviated well portion either 1) add downward force or 2) reduce the coefficient of friction, e.g., by lubrication. A modification of the added force approach provides bumpers to deliver downward shocks and blows in addition to added downward static forces. However, only a limited downward force can be exerted on the pipe string. Excessive downward force can convert a pipe string (normally supported from the top of the well) into a highly compressed member. Compression tends to buckle the string, adding still further drag forces (if laterally supported by the well bore) or causing structural failure (if laterally unsupported). In addition, large amounts of added downward force may be impractical.
Similar limits affect common lubricating or coefficient of friction reducing methods since the coefficient of friction cannot be reduced to zero. These lubricating methods do allow longer pipe strings to be run into a deviated hole. However, as longer lubricated pipe strings are run into the deviated well, unacceptable drag forces will still be generated. The geometry and drilled surface conditions of some holes may also create increased resistance (high drag) conditions in shorter inclined holes, even if lubricating methods are used. A flotation method of placing a pipe string into a deviated, liquid filled hole is also known. This method is illustrated in U. S. Patent No. 4,384,616. After providing a means to plug the ends of a pipe string portion, the plugable portion is filled with a low density, miscible fluid to provide a buoyant force. The low density fluid must be miscible with the well bore fluids and the formation. Miscibility is required to avoid a burp or "kick" to or from the formation outside the pipe string when plugged portion fluid is discharged to the formation/well bore. Circulation of drilling mud is also not possible during running or feeding the plugged string into the wellbore. After feeding the plugged string into the well bore, the plugs are drilled out and the low density miscible fluid is forced into the well bore/pipe annulus. Further casing operations, if any,
(i.e., cementing) are accomplished without the assistance of a low density miscible fluid providing a buoyant force. The known string flotation method requires added risk and well completion steps, especially if cementing is required. The low density fluids compatible with the formation and bore fluid must be circulated out ahead of a cement slurry. This requires drilling out the plug(s) prior to cementing of the casing or liner string. Subsequent to the cementing, a second drilling out (of hardened residual cement) is frequently also required.
The multi-step drilling result in costly well completions and increase the risk of damage to the pipe string and formation. None of the current approaches known to the inventors allow the flotation of a string into a high drag slanted well without a multi-step completion process. The cost of the miscible fluid and multi-step completion process has apparently resulted in little or no commercially practical application of the current flotation method.
A simplified flotation device and method are needed to allow the placement and completion of long pipe strings in extended reach well bores. The method and device should also be safe, reliable, and cost effective.
Disclosure of Invention
The invention provides a flotation plug device and process for running a casing or liner into a high drag inclined hole without the need to remove the plug device prior to cementing. , In a first embodiment, a float shoe/float collar and a shear-pinned plug insert trap air (or other low density fluids, not necessarily miscible with the formation or well bore fluids) within a portion of the casing string being run in a deviated hole. After running the string to the desired setting depth in a liquid filled hole, a sealed port in the insert is opened to allow the air to be vented to the surface. A cementing bottom wiper plug, induced by applied pressure, forces the plug and insert to slide piston-like within the string to land and latch into a landing collar during normal cementing procedures. The latched plug/insert/landing collar forms a single drillable assemblage. The assemblage is removed during normal post-cementing drilling out, avoiding multiple drilling steps.
The process of using this first embodiment attaches a float shoe and/or float collar (having a flapper or check valve) and a landing collar at one end of an air filled flotation portion of the casing. The float shoe or collar prevents fluid inflow as the casing is lowered into the initial low angle portions of the fluid filled well bore. An insert attached to an upper portion of the casing forms the other end of the "floating" portion. The insert includes a releasable plug (attached by a first set of shear pins) to block a passageway in the body of the insert and contain the air. When a sufficient "floating" length of string is run, the plug insert is attached within and pinned to the string with a second set of shear pins. This seals the air to form a flotation cavity, creating an increased buoyant force on the pipe string when the string is submerged in the fluid filled well bore.
The buoyant forces reduce effective weight, assisting the running of the string to the setting depth by reducing drag forces generated by the effective weight. After setting the string, increased internal string pressure shears the first set of shear pins, opening the passageway. This allows air to vent up the string while mud flows down. After circulation of the mud, a cement slurry is then pumped down-hole separated from the mud by a bottom wiper plug. The bottom wiper plug mates with the open ported insert and shears the second set of shear pins. Shearing releases the mated wiper plug and insert combination to move down-hole. The combination then latches to the landing collar, forming a single driliable assemblage. A top wiper (segregating cement slurry from fluid above the cement slurry) may also be used. A differential pressure across the top wiper forces the cement slurry out and up the bore/string annulus. The assemblage (and top wiper, if used) is drilled out during normal post-cementing procedures.
The ported and slidable air trapping insert allows simplified running of long strings in inclined holes by controlled reduction of effective string weight, not by adding weight or reducing the coefficient of friction. Flotation is achieved without the need to 1) use a miscible low density fluid or 2) separately remove plugs prior to cementing the string.
Another embodiment also forms a flotation cavity in a portion of a tubular string between two ends (e.g., between a shoe and an insert/plug) to be set into a borehole, but adds a conduit between the flotation cavity ends. This embodiment is preferred when sufficient buoyant forces can be obtained when the added space and weight of the conduit within the flotation cavity is considered. The conduit and tubular string now form an annular shaped flotation cavity where the lower density fluid is contained outside the conduit to provide the increased buoyant forces. The conduit (surrounded by the flotation cavity) allows drilling mud and other fluids to circulate during running or other following operations, specifically including cementing. These methods and devices have the added benefits of possibly allowing a lower lifting capacity rig to be used (since the maximum effective hanging weight is reduced by buoyant forces) and increasing possible tubular string (casing or liner) setting depths, because of reduced drag forces.
Brief Description of Drawings
Figure 1 shows a schematic cross sectional view of one flotation device used to provide buoyant liner or casing forces during running operations;
Figure 2 shows a schematic side view of an alternative embodiment of the flotation device during installation; Figures 3a through 3f show simplified representations of the alternative device during well completion activities;
Figure 4 shows a side and partial cross sectional view of an air trapping device portion of the engaged assemblage;
Figure 5 shows a side cross-sectional view of another alternative embodiment;
Figure 6 is a graphical representation of the results of a test of the flotation device; and
Figure 7 shows a schematic side view, similar to Figure 2, of an alternative air annulus embodiment during installation.
In these Figures, it is to be understood that like symbols and reference numerals refer to like elements, methods or features.
Best Mode for Carrying Out the Invention Figure 1 shows a schematic cross-sectional view of one embodiment for running a casing string (or liner or other duct) into a fluid filled bore hole (or cavity) 2. A portion of the casing or liner string 4 is placed in the top vertical or low angle section of drilled bore hole 2 (lower slanted or high angle portion not shown for clarity). The bottom end 3 of liner or casing string 4 has a float shoe 5 attached. The float shoe 5 includes an outwardly or downwardly opening flapper or check valve 6. The valve 6 prevents inflow of a first or bore fluid 7 during the running or lowering of the string (see downward direction "A" shown on Figure 1) into the well bore 2. The flapper (or ball) of valve 6 may be spring or otherwise biased closed to prevent inflow, but allow pressurized fluid outflow (in the downward direction "A"). Outflow occurs if the pressure force within the string 4 can overcome flap seating forces and bore fluid 7 pressure forces.
A releasable and inflatable bridge plug (or packer) 8 is located at the other (second or top) end of a portion of the string to contain air, i.e., to be "floated" in the liquid filled borehole 2. The bridge plug 8 comprises a cylindrically shaped solid form 9 and an elastomeric bladder (or diaphragm) 10. Pressurizing the bladder 10 through port 11 traps air or other flotation fluid within a flotation cavity 12 below the bridge plug 8 and prevents the entry of third (or non-flotation) fluid 13 from above the bridge plug 8 into cavity 12.
Figure 1 shows the bladder 10 in a fully inflated position. Inflation is achieved by applying air or other second fluid pressure through open venting ports 15 in stem 14 (source of inflation air is not shown for clarity). Inflation also pressurizes the flotation cavity 12 to prevent collapse of the string under down hole conditions. After inflation, pulling or twisting of stem 14 closes the air venting ports 15 and the source of inflation can be removed.
The bore fluid 7 is normally a single density drilling mud, but may also be a mixture or several layers of different density fluids. The various densities within the well bore allow a single flotation cavity 12 to have different buoyant forces at different portions of the well bore proximate to different density bore fluids. This can be highly desirable in extremely high drag well bores or variable incline angle bore portions.
The distance between the float shoe 5 at one end of the flotation cavity 12 to the bridge plug 8 at the other end is variable to allow control of buoyant forces generated. Repositioning the bridge plug 8 changes the buoyant 'forces on the "floating" pipe string portion enclosing cavity 12. The float shoe 5 is installed at the surface before entry of the casing string end into the bore hole 2. The length of the flotation cavity or portion of the string is selected to control the force tending to run the casing into the hole. The bridge plug 8 seals and is attached to the duct by pressurizing the bladder after installing the length of "floating" pipe string portion into the bore hole 2. Alternatively, repositioning the bridge plug when in the hole may also be possible to further adapt and change buoyant forces, if required. This can be useful when bending a tubular member through an arced borehole portion (e.g., running a casing through a build section of an extended reach well). Buoyant forces in a non-vertical borehole portion can provide bending forces (e.g., buoyant forces exceed the weight of a buoyed portion of pipe string ahead of a non-buoyed portion in an inclined borehole curving towards a horizontal orientation), and repositioning the bridge plug can adjust these bending forces to adapt to the specific incline/curvature/bending needed.
The diameter and cross sectional thickness (and associated weight) of the pipe string enclosing cavity 12 can be set equal to the weight of the displaced bore fluid 7. This creates a neutral buoyancy so that this "floating" section exerts no upward or downward forces on the walls of the bore hole 2, regardless of orientation or slant. Even if-,neutral buoyancy is not desired, the controlled effective (buoyed) weight of the selected casing/liner pipe string which must be supported (hung) and any resulting drag during installation operations can be significantly reduced. This reduced maximum effective weight may allow a smaller capacity derrick or rig to be used, or added safety when using a larger one.
The remainder of the string above the bridge plug 8 is fluid filled with a third .or heavier fluid 13, such as drilling mud. The larger effective weight of the remaining non-flotation portion forces the flotation cavity pipe string portion to the other (i.e., higher incline angle) portions of the well bore 2 (see Figure 3). These other well portions may be nearly horizontal. The non-flotation portion may extend to the surface, i.e, fill the remainder of the string with the heavier fluid 13. In some applications or embodiments, string installation may require a second or multiple floating portions within the string, separated by other bridge plugs 8, especially for deviated hole portions having different angles.
After the casing is run to setting depth, a retrieving device is run on the end of drill pipe and latched on the retrieving stem (or fishing neck) 14. The ports 15 are opened by the action of the drill pipe latching or twisting onto the retrieving dog on stem 14. The ports 15 may also be remotely actuated in an alternative embodiment. These opened venting ports 15 allow the higher density fluid 13 to exchange places with the lower density fluid (air) in cavity 12. The bridge plug 8 is also then deflated by twisting and/or pulling on the retrieving stem 14.
An alternative embodiment can separately actuate cavity pressurisation/venting and bladder inflation/ deflation. Cavity pressurization may not be required if the string can withstand the differential pressure. Fluids (water in this embodiment) used to inflate bladder and pressurize cavity can also be segregated in this alternative embodiment.
collar 16 is attached to the casing or liner string 4 near the float collar/float shoe end (see Figure 1) of the cavity 12a. The latch-in collar 16 includes a threaded or latching aperture 17 (shown dotted in Figure 2 for clarity) which engages a threaded or latching protrusion 18 of an air release plug holder 19 of an air trapping device (or member) 20.
The piston-like air trapping device 20 also includes an air release plug 22 (shown dotted for clarity). A first set of (or passage) shear pins 23 attaches the release plug 22 to an internal port (or passageway) 24 (shown dotted for clarity) within the plug holder 19. A second set of (or plug holder) shear pins 21 attaches the plug holder 19 to the liner/casing 4. The size and shape of the plug 22 and internal port 24 allow the sheared away plug 22 to slide down (direction "A" is towards the well bottom, not necessarily vertically down) toward the protrusion 18. After moving/sliding the plug 22 down, the internal port 24 is in fluid communication with both the cavity 12a below (through slotted ports 25) and the non-flotation fluid 13 above the translated plug 22. The lateral slotted ports 25 allow fluid passage to and from the lower portion of the internal port 24 and the cavity 12a (fluid flow shown as a solid and dotted arched arrow). The height of plug 22 is selected to be less than height of the slotted ports 25, allowing fluid flow in this lower portion. A basket 26 near the bottom of the air trapping device 20 acts as a retainer of the plug 22 within the internal port 24 when the passage shear pins 23 break and plug 22 moves downward under fluid pressure from above. After venting the trapped air from the cavity 12a through port 24, filling the cavity 12a with drilling mud, and circulating drilling mud to the formation/string annulus (see Figure 3), a cement slurry is introduced into the string above the air trapping device 20. A bottom wiper plug 27 separates the cement slurry above wiper plug 27 from the drilling mud 13 above the air trapping device 20. A third set of (or wiper) shear pins 30 attaches an inner wiper plug 29 to a wiper plug port 28 (shown dotted) of the wiper plug 27. The inner plug 29 prevents fluid communication above and below the wiper plug 27 until the inner plug 29 moves (i.e., is sheared away) from the plug port 28. An initial (before wiper shear pins are sheared) fluid pressure from a source at the surface creates a differential pressure across the wiper plug 27. Pressure differential will tend to move the wiper plug 27 (in direction "A") towards the air trapping device 20. When the wiper plug 27 element reaches the air trapping device 20 element, the elements are shaped to join together. They are also shaped to be capable of sliding as a unit when joined. When the pressure differential across the wiper plug 27 is increased, a force that will rupture the plug holder shear pins 21 is then produced. The joined wiper plug 27 and air trapping device 20 will then slide toward the landing collar 16 as a unit. Upon reaching the landing collar 16, a further increase in pressure differential will rupture the wiper shear pins 30. Cement slurry above the wiper plug 27 can then circulate through landing collar 16, float collar if installed (not shown), and float shoe 5 (see Figure 1) into the annular space between well bore 2 and casing 4.
Each set of shear pins is selected to rupture at increasingly incremental pressures above normal operating hydrostatic pressure within the string. This alternative embodiment uses a (differential) pressure increment of 34 atmospheres (500 psi) to prevent accidental actuation (shearing). Thus the first set of shear pins 23 rupture at approximately 34 atmospheres (500 psi) over hydrostatic (allowing air to vent and mud to circulate), the second set of shear pins 21 (allowing the piston-like trapping device to translate) are set at approximately 68 atmospheres (1000 psi) over hydrostatic, and the third set of shear pins 30 (allowing cement slurry flow) are set at approximately 102 atmospheres (1500 psi) over hydrostatic.
Figures 3a through 3f show simplified representations of the alternative apparatus shown in Figure 2 during well completion activities in the deviated well bore 2. When the inclined angle "i" (angle between the center line of the slanted well portion and the vertical shown in Figure 3a) approaches larger (nearly horizontal) values, a positive means to prevent fluid inflow to the bottom of the air filled cavity is needed, i.e., float shoe 5. Lower incline angle holes may avoid using a float shoe, depending upon density differences and the lack of fluid miscibility to limit inflow to the flotation portion. Large incline angles "i" can also indicate the need for a flotation method of running the casing into the hole.
Operations in large inclined angle "i" well bores are at most risk of a stuck casing string. At an incline angle at or exceeding a critical angle and friction factor, the drag generated by the pipe section is equal or greater than the weight component tending to slide the pipe section into the hole. For friction factors ranging from 0.2 to 0.5, this critical angle ranges from 78.7 degrees to 63.4 degrees, respectively. Flotation methods are therefore indicated when the inclined angle "i" is greater than these critical values for a substantial distance.
Figure 3a shows the initial apparatus positions after installing the string 4 in the deviated well bore 2. The cavity 12a includes landing collar 16 between the float shoe 5 and air trapping device 20. The air release plug 22 (shown darkened for clarity) is shear pin attached to air trapping device 20 (see Figure 2). Cavity 12a contains trapped air or other low density fluid, creating buoyancy during the (just completed) insertion of the string portion into the bore hole 2 containing drilling mud 7. In this embodiment, drilling mud 7 is also the non-flotation fluid (see item 13 in Figure 1) present above the air trapping device 20 in a non-flotation (or high density fluid filled) cavity portion 31. The apparatus geometry and mud density can be adjusted to control buoyancy and the effective weight of the casing 4 proximate to the cavity 12a.
Figure 3b shows the apparatus of Figure 3a after rupturing the first set of shear pins 23 (see Figure 2) and movement of the air release plug 22. An increased pressure above the air trapping device 20 sheared the first set of pins. The positions of the elements are unchanged except for the release plug 22. The sheared-away release plug 22 may be biased and/or pressure actuated to slide towards the cavity 12a to open ports 25 (see Figure 2). Opening ports 25 allow fluid communication between the air cavity 12a and non-flotation (i.e., filled with a higher density fluid) cavity portion 31. Because of the fluid density differences, shape of the passage 24, downward sloping orientation of the bore hole 2, and fluid communication through the internal port 24 to the surface, the air from cavity 12a migrates upward in the casing ox liner 4 so that it may be then vented at the surface. In wells that have an incline angle of greater than 90 degrees, it may be necessary to positively vent air from cavity 12a. As shown in Figure 3b, the drilling mud 7 and displaced air form a mud-air interface 32 in the previously weighted cavity 31. The previously buoyant cavity 12a is now full of drilling mud 7. Another alternative embodiment can provide a plurality of internal ports 24 and release plugs 22. This embodiment would assure migration/displacement of fluids in various orientations, e.g., at least one internal port primarily for venting air towards the surface, another for flowing drilling mud into cavity 12a.
Figure 3c shows the devices of Figure 3b after the air (above the mud-air interface shown on Figure 3b) is vented at the surface (not shown for clarity) and replaced with drilling mud 7. Position of the devices is unchanged, except that drilling mud 7 fills all of the string interior and the annulus between the liner/casing string 4 and well bore 2. Circulation of drilling muds is now possible, if required for hole cleaning or other reasons, without "burps" or "kicks."
Figure 3d shows the devices after installing and pumping a bottom wiper 27 (i.e., a plug wiping the interior surface of the string as it moves) to mate with the air trapping device 20. Above the bottom wiper 27 is a cement slurry 33. Drilling mud 7 within the casing 4 above air trapping device 20 has been displaced through passage 24 (See Figure 2) in the air trapping device 20, landing collar 16, and flapper valve 6 of the float shoe 5 (see Figure 1). To limit and segregate the top of a fixed amount of cement slurry 33, a top wiper 34 contains the cement slurry 33 between the two sliding and sealing wipers. When forced by a differential pressure, the portion of the bottom wiper 27 proximate to inner plug 29 (shown shaded for clarity) mates within the internal port 24 of the air trapping device 20 (see Figure 2). This seating or mating of the bottom wiper 27 to the air trapping device 20 and a further increment of differential (above hydrostatic) pressure across the mated devices applies a shearing force to the second set of shear pins 21 (see Figure 2). Figure 3e shows the devices after breaking the second set of shear pins 21 (see Figure 2) attaching the air trapping device 20 to the casing 4. The released air trapping device 20 and bottom wiper 27 are shown having been translated to land and latch or threadably engage the landing collar 16, which prevents rotation of the landed assemblage. Wiper plug 29 contains the cement 33 between the landed assemblage at the landing collar 16 and the top wiper 34. The drilling mud 7 previously contained in cavity 12a (see Figure 3d) has been displaced and flowed though the landing collar 16 and flapper valve 6 of float shoe 5 into the annular space between well bore 2 and casing/liner 4. Displaced drilling mud continues to flow through the float shoe 5 until the top wiper 34 joins the assemblage. Applying another pressure increment tends to shear the third shear pin set 30 (see Figure 2) holding the wiper plug 29.
Figure 3f shows the top wiper plug 34 joined to the assemblage and cement slurry 33 nearly fully displaced out of the string'4 to the annulus between the casing/liner 4 and well bore 2. Shearing and displacing the wiper plug allows the cement to flow through the bottom wiper plug 27 and the slotted ports 25 (see Figure 2) to the annulus between the casing 4 and well bore 2 through flapper valve 6. The pressurized cement flow also causes the top wiper 34 to slide and contact the bottom wiper plug 27. The cement-mud interface 35 (previously separated by bottom wiper 27) is now in the annulus between the well bore 2 and casing 4. A portion of the cement slurry 33 remains between the assemblage and float shoe 5. This residual cement is drilled out (after setting) in normal post cementing operations (not shown).
Figure 4 shows a side and partial cross sectional view of the engaged bottom wiper 27 and pinned air trapping device 20 assemblage within a joint in the casing string 4. The casing string 4 (shown quarter sectioned) in hole 2 is composed of many sections of pipe segments 36 joined by a drift (or piping) collar 37 at each end. The piping collar 37 is internally threaded to join the external threaded ends of pipe segments 36. The illustrated pipe string joint is typical of the string of joined pipe segments. An alternative pipe string can used without interconnecting pipe segments, avoiding the need for a piping or drift collar 37. The piping shown is attached to the air release plug holder 19 portion of the air trapping device 20 (shown in cross section) by the second set of shear pins 21. The air trapping device 20 also includes a pair of holder O-ring seals 38 forming a fluid tight sliding connection to the interior of the string 4. The internal port 24
(see Figure 2) includes an initial threaded portion 39, a cylindrical wiper plug mating portion 40 and a release plug cylindrical portion 41.
The plug 22 was retained by the first set of shear pins 23 (shown sheared in Figure 4). A pressure differential was applied sufficient to break the plug shear pins 23 and translate the plug 22 to rest against the perforated basket 42 (similar to basket 26 shown in Figure 2). The-.plug 22 also includes a plug O-ring seal 43 which, when plug 22 is pinned in the initial position, formed a fluid tight sliding seal to the plug cylindrical portion 41 of the internal port 24 (see Figure 2). The perforated basket 42 catches and prevents further translation or loss of the plug 22. The perforations of basket 42 and ports 25a allow fluids to pass around the displaced plug 22.
The air trapping device 20 also includes a latch protrusion 18 which attaches to the landing collar 16 (see Figure 3) after the second set of shear pins 21 are broken and the assemblage has been displaced to landing collar 16. The protrusion 18 and latch or threaded portion 39 prevent rotation of the assemblage (wiper plugs, air trapping device and landing collar) when the assemblage is being drilled out.
The bottom wiper plug 27 (shown in side view for clarity within sectioned casing string 4) includes a series of elastomeric cup shaped wipers 44, an external threaded or latch portion 45 (threadably mating with the internal threaded or latch portion 39 of the air trapping device 20), a pair of elastomeric wiper O-rings 46 (shown darkened for clarity and bearing against the interfacing passageway portion 40), and (hidden from view) an inner plug 29 held in place within wiper port 28 by a third set of shear pins 30 (see Figure 2).
An alternative embodiment can extend the bottom wiper dimensions to positively displace the plug 22 when bottom wiper contacts and mates with air trapping device 20 (see Figure 2). Other types and locations of elastomeric seals, and other mating shapes and dimensions may also be provided for other alternative embodiments. Solid materials of construction of the air trapping device 20 are primarily 6061 aluminum, but various other materials of construction-,can be used, as long as they are drillable or otherwise removable.
The bottom wiper 27 acts as a sliding and wiping seal or separator along the interior of the casing. The bottom wiper 27 separates cement on the upstream side from fluid on the downstream side during certain fluid movements, i.e., slurry cement pumping down-well (direction "A"). The orientation (right hand engaging) of the external and internal threads shown in Figure 4 are selected to tighten or engage the air trapping device during drilling and prevent unlimited rotation.
Several advantages of the present invention to the prior flotation methods can be discerned. The first advantage is that the present invention avoids the need to use miscible flotation fluids. Air (or any other low density fluid, whether miscible or not) is safely contained and vented to the surface from within the string. A second advantage of the present invention is it avoids the need to remove wiper/plug/insert devices in order to circulate mud or cement slurry. Shear pinned plugged ports open to allow flow for normal circulating, cementing, and drilling out or other operations.
A third advantage is the translating/latching ability. The various components translate and latch together to form a single drillable unit latched to the landing collar. The unit or assemblage does not rotate or spin with the rotating drill, avoiding drilling difficulties. The drillable unit's location at a single known depth eliminates multiple drilling or retrieval operations at various depths. These advantages are compounded if using multiple floating segments. The protrusion 18 (see Figure 4) can be designed to include a nesting ability with other air trapping devices 20 which would form the ends of multiple floating segments. The protrusion 18 would latch into the internal portion 39 of a second (nested) downstream located air trapping device. The nested air trapping devices again secure multiple segments within an assemblage at a single landing collar for post cementing drilling out procedures. A further advantage of this embodiment is the use of existing components, simple fabrication and design. The top and bottom wiper plugs can be produced by modifying a commercially available liner wiper plug. The use of 6061 aluminum results in light weight and easily machinable components of the device.
Figure 5 shows a side cross-sectional view of another alternative embodiment of an air trapping device or an air plug 20a. A second set of shear pins 21 attaches the air plug 20a to the casing pipe string 4. The air plug 20a is similar in construction to a conventional bottom cementing plug. The air plug 20a includes an aluminum insert 48 covered by rubber wipers 44. A rupture diaphragm 49 separates the flotation cavity 12b, retaining air (or other low density fluid such as nitrogen or light hydrocarbon fluids) from the higher density fluid filled cavity 31a. The rupture diaphragm 49 replaces the releasable plug 22 and shear pins 23 of this alternative embodiment (see Figure 2). The rupture diaphragm 49 has the advantage of simplicity, but may not be capable of withstanding the down hole pressures and forces or be removable without difficulty. Still other alternative embodiments could replace other slidable plugs and inserts with rupture or burst diaphragms. Once the casing or liner string is run to the total or desired depth, increased pressure is applied to burst the diaphragm 49. Similar to the previous discussion, the ruptured diaphragm allows the trapped air from cavity 12b to migrate to the top of the well and be replaced by drilling mud. The air is again vented at the surface (not shown for clarity). Circulation of the drilling muds can now be accomplished in this embodiment, if required. Near normal cementing operations can now be accomplished. The cement slurry flows past the ruptured diaphragm until the top cement wiper 34 (see Figure 2) engages the air plug 20a. Increasing the cement slurry pressure on the engaged air plug/wiper fractures the second set of shear pins 21. If the wipers 44 are slidably attached to the insert 48, another set of shear pins 50 can be used as a redundant means to allow fluid exchange in addition to the rupture diaphragm 49 (allowing fluid exchange even if rupture diaphragm does not rupture).
Results using one embodiment of the present invention are illustrated by the following example:
EXAMPLE 1
Figure 6 is a graphical representation of the results of a test of the flotation method in a deviated underground well bore. The devices and methods used were similar to those shown and described in Figure 1. Figure 6 shows the actual and expected indicator (or slack-off) weight supported during installation of the casing pipe string 4 (see Figure 1). The string was installed by sections from a derrick at the surface.
The bore fluid for this example was a drilling mud having a density related value of approximately 1137 kilograms/cubic meter (71 pounds/cubic foot). The casing used was a 9 5/8 inch (24.45 cm) nominal diameter pipe string. The resulting buoyed weight of mud filled casing was approximately 54.78 newtons/meter (40.4 pounds/foot), whereas the buoyed weight of the air filled cavity portion was 15.73 newtons/meter (11.6 pounds/foot).
After verifying air filled casing would not collapse under the increased pressure differential (when compared to the differential pressure resulting from a mud filled casing), approximately 1219 meters -(4000 feet) of casing (having a float shoe attached at the bottom end and centralizer bands on the bottom for approximately 853 meters or 2800 feet) was initially run into the hole to form the flotation cavity. An inflatable packer was set at the other end of the 1219 meter (4000 foot) section and the remaining casing run into the hole. The dog on an inflatable packer was latched and air venting ports opened (see Figure 1) for 15 minutes to allow the air within the casing to migrate to the surface for removal. The packer was then deflated (i.e., dog was twisted). Mud circulation was followed by generally normal cementing and post cementing (drilling) operations.
The expected results without flotation (solid curve), the expected results with flotation (dashed curve) and the actual indicator weight results using the flotation method and devices (dotted curve) are shown in the graph of Figure 6. The initial actual (dotted line) and associated expected (dashed line portion "A") indicator weight increasing with depth shows a significant reduction in supported (indicator) weighjt, when compared to the non-flotation method (solid line portion "B" ), was achieved by the buoyant effect on the floated portion of the string within the fluid filled well bore.
The remaining string portion above the air filled cavity (point "C" on flotation expected curve) was filled with drilling mud. The actual and flotation expected curve shape (dotted and associated dashed line portion "D"), are similar to, but displaced from, the expected non-flotation curve shape (solid line "B"). This displacement allows the string to be placed to a greater depth (depth increment "E") before the supported weight becomes insufficient to move the string into the bore hole. The dotted and dashed curve shape (and ability to install casing or liner) can be altered by changing the number and length of the floated sections as well as by using a flotation fluid other than air or changing the density of the mud in the borehole or the mud above the flotation device.
During the installation in the initial low angle portion of the well bore, the prior art non-flotation method (shown as a solid curve) was expected to produce a larger maximum force (or indicator weight as shown at point "F") to overcome the later developed frictional drag when compared to the flotation method maximum indicator weight (point "G") . However, as the casing end approaches the lower portion (solid line portion "H" ) beginning at approximately 2286 meters (7500 feet), the mud filled sections generate more drag (shown by the indicator weight declining with depth) than can be overcome by weight (i.e., exceeds critical incline angle). If the particular well included an even higher incline angle section, the decline in indicator weight would be even more severe.
The results of this test example show that flotation of the casing displaced and maintained a controlled margin of supported weight during the entire installation procedure, avoiding a stuck casing. The results also show that a reduced maximum indicator weight was achieved while allowing a deeper installation and avoiding multiple drilling out procedures.
Figure 7 shows a schematic side view, similar to
Figure 2, of another alternative embodiment (i.e., an air annulus embodiment) of the apparatus when near the location where the casing is to be set (i.e., one end of a casing string 4^ is near the bottom of the wellbore 2). The extended reach wellbore 2 contains one or more drilling muds 7 having densities greater than air (or other fluid in cavity 12b) and a casing string 4. A portion of the casing string 4 and ported packers/ retainers 55 and 56 forms the exterior surfaces of a modified "flotation" cavity 12b, similar to the cavity 12a shown in. Figure 2a. Above the modified cavity 12b, the casing string 4 also contains drilling mud 1 , similar to Figure 2a. The pipe string 4 has a float shoe 5 and float collar 16 attached proximate to one end of the pipe string similar to Figure 2, but the ends of the modified cavity 12b within the pipe string 4 is defined by a pair of inflatable packers/retainers 55 and 56, similar to the bridge plug 8 shown in Figure 1. The air annulus embodiment also contains a conduit 60 forming the interior surface of (i.e., is surrounded by) cavity 12b. The conduit 60 provides a passageway for fluids from one end of the modified cavity 12b to another (i.e., conduit 60 is attached to ports in the upper inflatable packer 55 and lower cement retainer 56). The conduit 60 is attached in this embodiment to a surface connecting conduit 61 (typically a string of smaller diameter drill pipe sections) within the remainder of the casing string 4. The fluid shown within conduits 60 and 61 is drilling mud 7, allowing drilling mud 7 to be circulated during running or other operations, but a cement slurry or other fluid may also be conducted. Mud circulation (i.e., pumping drilling mud at the surface through the casing string 4, surface connecting string 61, and conduit 60 to the borehole 2 through float collar 16 and float shoe 5 to the annular space between the casing string 4 and borehole- 2, then screened or filtered to remove particles (e.g. cuttings or other formation solids) prior to returning to the surface pump) allows lubrication and other fluid properties to assist in the running operations, while the casing string is buoyed within the drilling muds in the borehole 2.
After the set location of the casing string 4 is achieved or approached as shown in Figure 7, the surface connecting conduit 61 can be run within the casing string 4 to connect with the conduit 60 at an overshot connector 62. Alternatively, the surface connecting conduit 61 can be pre-assembled and run into the borehole 2 concurrently with the casing string 4. A removable plug 63 shown in the conduit 60 is optional, provided if needed to prevent drilling mud from flowing in the conduit during portions of the operations when flow is unwanted, such as pressure testing. Removable plug 63 from conduit 60 can be removed by differential pressure.
This air annulus embodiment specifically allows flotation and reciprocation of the casing during cementing operations. A cement slurry can be fed through the surface connecting conduit 61 and conduit 60, out through the float collar 16 and float shoe 5 to the annulus between the casing 4 and borehole 2 while reciprocating the casing to obtain improved slurry distribution in the annulus and (after setting) bond strength. Improved distribution helps prevent channeling and other problems. The cementing process first runs a first portion of the casing 4 (with conduit 60 and packers/retainers 55 & 56) into the borehole 2. The cement retainer 56 is set and tested (e.g., a test of its integrity against fluid pressure). Plug 63 (i.e. a wire-line plug) is then set in a fitting (e.g., an XN nipple) in conduit 60 and tested. Packer 55 is then inflated and tested. Plug 63 is then pulled and conduit 60 is filled with mud 7. The remaining portions of the casing 4 are run in hole while circulating mud 7. The surface connecting conduit 61 is run in hole, latching and sealing at overshot connector 62 to conduit 60. The casing 4 is reciprocated (i.e., translated in an oscillating manner along the borehole axis) and drilling mud 7 is circulated until clean (free of filterable solids). A cement slurry is then pumped down the surface connecting conduit 61 and conduit 60 while the casing is reciprocated. The casing is then located (i.e., landed) and the cement allowed to set. Inflatable packer 55 can be deflated before or after cement setting, along with the venting of air in cavity 12b and pulling out surface connecting conduit 61, conduit 60, inflatable packers/retainers 55 & 56.
A similar procedure is used to run, rotate and cement a liner (not shown, but similar to casing 4 shown in Figure 7). Typically, the liner is a tubular string to be contained in a lower portion of the borehole 2 and attached or hung from a larger diameter up-hole casing section. At least a first portion of a liner is run into the borehole 2. The lower cement retainer 56, plug 63 and upper inflatable packer 55 are similarly set and tested in the liner. Plug 63 is removed and the assembly is filled with drilling mud 7 except for cavity 12b. The surface connecting conduit 61 is similarly latched and sealed to connector 62, followed by running the liner and surface connecting conduit 61 in hole. The liner is then rotated (in an oscillating or continuous manner) and drilling mud is circulated clean. A cement slurry is pumped down the conduits out to the borehole/liner annulus while the liner continues to be rotated, again improving distribution and bond strength. When ready to allow the cement to set, the liner is released (hung on casing), the packer is deflated, and surface connecting conduit (drill pipe), packer(s) and conduit are pulled out. Alternatively, a modified air trapping device similar to the device 20 shown in Figure 2 may be used in place of the upper inflatable packer 55. The modified device includes another port for connecting to conduit 60. Still further, conduit 60 may be directly connected to a modified float shoe or float collar, similar to the shoe 5 and collar 16 shown in Figure 2.
Results using an air annulus embodiment of the present invention are illustrated by the following example:
EXAMPLE 2
A 17.8 cm (7 inch) nominal diameter, 129 newtons (29 pound) nominal weight liner string approximately 1676.4 meters (5,500 feet) long is to be run to 4572 meters
(15,000 feet) total measured depth. The well path after an initial near vertical section of approximately 304.8 meters (1000 feet) is planned to include a build section where an incline angle build rate of approximately 3.5 degrees per 30.48 meters (100 feet) is maintained until an incline angle of 80.88 degrees is reached at approximately 1009.2 meters (3311 feet) measured depth. The incline angle of approximately 80.88 degrees is to be held until a measured depth of4572 meters (15,000 feet) is reached. A 9 5/8 inch (24.45 cm) nominal diameter casing is planned to extend to 3048 meters (10,000 feet), with an expected friction factor during running of the liner within the casing of 0.35. The expected friction factor in the nominal 21.59 cm (8 1/2 inch) diameter hole extending from 3048 meters (10,000 feet) to 4572 meters (15,000 feet) is 0.50. The planned mud has a density of approximately 1121 kilograms per cubic meter (70 pounds per cubic foot). By using a nominal diameter 6.0325 cm (2 3/8 inch), 1.814 kilogram (4 pound) tubing (i.e., conduit 60 shown in Figure 7) within the liner, a buoyed weight of approximately 24.40 newtons/meter (18.00 pounds/foot) compared to a flotation cavity 12a (see Figure 2) within a liner buoyed weight (without tubing) of 33.69 newtons/meter (24.85 pounds/foot) .
ON
shear pins); placement of cylindrical or otherwise ported solid inserts (e.g., foam) or higher density fluid into the flotation cavity 12 in addition to lower density (flotation) fluids (to improve the control of buoyant forces); combining the float shoe, float collar, and/or the landing collar in a single component; combining centralizing (outward radial) protrusions on the string (to create a string stand off annulus within the well bore) with multiple trapping devices at pipe joints; replacing the float shoe valve with a float type trap or other back-flow preventer; and having translating components, conduits, and piping strings primarily composed of flexible material (to more easily navigate deviated sections and alter buoyant forces). A still further alternative embodiment is to make portions of the devices such as plugs from materials which are dissolvable, thermally degradable or fluid reactive/decomposing (avoiding pressure increments or drilling out procedures). Although no longer required, lubricants can also be used in conjunction with these flotation methods and devices to further control or reduce the running coefficient of friction.
These flotation devices and methods satisfy the need for a simple method to run a casing or liner string in a long horizontal well bore. Portions of the string are
"floated" in the well bore fluids by providing one or more plugged buoyant cavities. In one embodiment, opening a circulation and cementing path can be accomplished by a simple increase^in pressure and translation of insert/plug devices without entirely removing the devices. This embodiment also allows circulation during buoyant operations and reciprocating/rotation during cementing. Devices are finally removed by normal post-cementing drilling out techniques, avoiding the need for a separate removal step.
The use of air and lightweight materials minimizes storage and other related requirements. The present invention also reduces the maximum capability of the drill rig needed to accomplish the setting of the casing/liner string and extended reach well could theoretically have an infinite length (i.e., total measured depth) if flotation cavity sections are at neutral buoyancy. More typically, the invention provides major advantages for higher than critical incline angle (e.g., nearly horizontal) well portions (to be lined or cased) of at least 914 meters (3,000 feet) in length , more preferably at least 1524 meters (5,000 feet), and still more preferably at least 1828 meters (6,000 feet) in length. The buoyancy forces also allow a high build rate, limited only by the flexibility of the liner or casing tubular members. The buoyant forces can theoretically provide a bending force without scraping (and possibly damaging or excessively opening) the build portion of the wellbore. More typically, the invention provides major advantages for build rates of at least approximately 2.0 degrees per 30.48 meters (100 feet), more preferably a build rate of at least approximately 3.5 degrees per 30.48 meters (100 feet). Further advantages of the device include: increased safety (avoiding large casing running loads at the drilling platform), reliability (reducing the likelihood of stuck casing), maintenance (single use, drillable compo ents), efficiency (full flow production/ injection capability), and reduced cost (no separate removal step or need to recover items from great depth). Flotation devices for and methods of accomplishing drilling and completion of extended reach wells are also disclosed in paper entitled "Extended Reach Drilling From Platform Irene," by M.D. Mueller, J.M. Quintana, and M.J. Bunyak, presented to the 22 Annual Offshore Technology Conference in Houston, Texas, May 7 - 10, 1990, the teaching of which are incorporated herein by reference. Still further, a hydraulic release oil tool which may be used advantageously with the present invention is disclosed in U.S. Patent Application Serial No. 07/418,510, filed on October 9, 1990, the teachings which are incorporated in their entirety by reference. The release tool may be used to removably attach a drill string to a liner having a flotation cavity and being run into an extended reach wellbore. The release tool allows bidirectional rotation and high torque, combined with ease of release and removal. Although preferred embodiments of the invention has been shown and described (each embodiment is preferred for different well conditions and applications), and some alternative embodiments also shown and/or described, changes and modifications may be made thereto without departing from the invention. Accordingly, it is intended to embrace within the invention all such changes, modifications and alternative embodiments as fall within the spirit and scope of the appended claims.

Claims

WHAT IS CLAIMED IS:
1. An apparatus useful in installing a string of joined pipe sections from a surface into a well bore containing a first liquid, said apparatus comprising: a pipe string portion, one end of said string portion forming one end of an air filled flotation cavity within the string; a slidable member sealing and forming the other end of the flotation cavity, the slidable member having a passageway for conducting air out of the flotation cavity and liquid into the flotation cavity; a plug sealing the passageway; one or more first shear pins attaching the plug to the sliding member; and one or more second shear pins attaching the sliding member to the pipe string.
2. The apparatus of Claim 1 wherein the one flotation cavity end also comprises a float shoe attached to the pipe string.
3. The apparatus of Claim 2 wherein the slidable member also forms a first end of a non-flotation cavity adjacent to the flotation cavity within the string, and which also comprises: a slidable wiper forming a second end of the non-flotation cavity; and means-»for filling the non-flotation cavity with a second liquid.
4. The apparatus of Claim 3 which also comprises means for pressurizing the second liquid sufficient to shear the first shear pins and unseal the passageway.
5. The apparatus of Claim 4 which also comprises: fluid pressure means for sliding the slidable wiper; fluid pressure means for attaching the slidable wiper to the slidable member; fluid pressure means for shearing the second shear pins; and fluid pressure means for sliding the attached wiper and member towards the float shoe.
6. The apparatus of Claim 5 wherein the wiper also comprises a wiper port in fluid communication with the non-flotation cavity, and which also comprises; a wiper plug sealing the wiper port; one or more third shear pins attaching the wiper plug to the wiper port, and means for shearing the third shear pins.
7. An apparatus useful in installing a duct segment into a cavity containing a first fluid, said apparatus comprising: a duct, a part of which forms a flotation portion capable of excluding some of said first fluid and containing a second fluid when said duct segment is installed in said cavity, said flotation portion having a first end generally distal from a second end; means for sealing said second end; means'*for unsealing said second end; means for removing said second fluid from said duct through said unsealed second end; wherein said apparatus is shaped and dimensioned to prevent contact of said removed second fluid from said excluded first fluid when said duct segment is installed in said cavity; and means for circulating a third fluid from said duct to said cavity and back to said duct when said second end is unsealed.
8. The apparatus of Claim 7 wherein said second fluid is not miscible with said first fluid and which also comprises means for limiting inflow of said first fluid attached to said duct and forming said first end.
9. An apparatus useful in installing a duct segment into a cavity containing a first fluid, said apparatus comprising: a duct, a part of which forms a flotation portion capable of excluding some of said first fluid and containing a second fluid when said duct segment is installed in said cavity, said flotation portion having a first end generally distal from a second end; means for limiting inflow of said first fluid attached to said duct and forming said first end; means for sealing said second end comprising:, a slidable member having a fluid passageway shaped and dimensioned to allow removal of said second fluid from said flotation cavity, said slidable member located within said duct and forming said second end of said flotation portion; a plug capable of sealing said passageway; and means for releasably attaching said slidable member within said duct; means for unsealing said second end; means for removing said second fluid from said duct through said unsealed second end; and wherein said apparatus is shaped and dimensioned to prevent contact of said removed second fluid from said excluded first fluid when said duct segment is installed in said cavity.
10. The apparatus of Claim 9 wherein said slidable member also forms a first end of a non-flotation portion within said duct, and which also comprises: a slidable wiper within said duct forming a second end of said non-flotation cavity; and means for filling said non-flotation cavity with a third fluid.
11. The apparatus of Claim 10 wherein said plug is first shear pin attached to said slidable member in a manner which unseals said passageway when said pin is sheared, and wherein said means for releasably attaching said slidable member comprises a second shear pin, said second shear pin attachment shaped and dimensioned to allow sliding of said slidable member after shearing.
12. The apparatus of Claim 11 which also comprises: means for shearing said first shear pin and unsealing said passageway; means for sliding said slidable wiper; means for attaching said slidable wiper to said slidable member to form a first joined element; means for shearing said second shear pin; and means:,for sliding said attached wiper and member towards said inflow prevention means.
13. The apparatus of Claim 12 wherein said slidable wiper also comprises a wiper port in fluid communication with said non-flotation cavity, and which also comprises; means for releasably sealing said wiper port; and means for releasing said releasable sealing means.
14. The apparatus of Claim 13 wherein at least one of said first or second fluids is composed of a plurality of fluid layers having different densities.
15. The apparatus of Claim 14 which also comprises: means for inserting said duct segment into said cavity; and wherein the density of said second fluid is generally less than the density of said third fluid.
16. The apparatus of Claim 15 wherein said wiper also forms the first end of a slurry cavity capable of containing a fourth fluid, and wherein said means for releasably sealing, said means for releasing, said shearing means, said attaching means, and said sliding means comprise: a slidable wiper plug sealing said wiper port; and means for pressurizing said fourth fluid within said slurry portion sufficient to slide said wiper plug towards said slidable member to form a second joined element.
17. The apparatus of Claim 16 wherein said pressurizing means is also sufficient to slide said slidable wiper plug and unseal said wiper port.
18. The apparatus of Claim 17 which also comprises a means for preventing rotation of said first and second joined elements within said duct.
19. The apparatus of Claim 18 wherein said first fluid is generally in a liquid state and said second fluid is in a generally gaseous state.
20. The apparatus of Claim 19 wherein said second fluid is air.
21. The apparatus of Claim 20 wherein said duct inflow limiting means comprises: a float shoe having a flap covered port, wherein the differential pressure acting on said flap prevents significant fluid inflow to the flotation portion and allows fluid outflow from the flotation portion; and a latch-in collar attached to the interior of said duct proximate to said float shoe.
22. The apparatus of Claim 7 wherein said sealing means comprises a bridge plug-like device.
23. The apparatus of Claim 7 wherein said sealing means comprises an inflatable packer-type device.
24. The apparatus of Claim 7 wherein said sealing means comprises«a burst diaphragm-type device.
25. An apparatus useful in installing a duct segment into a cavity containing a first fluid, said apparatus comprising: a duct, a part of which forms a flotation portion capable of excluding some of said first fluid and containing a second fluid when said duct segment is installed in said cavity, said flotation portion having a first end generally distal from a second end; means for sealing said second end comprising a piston-like air trapping device having duct contactable elastomeric sliding seals, a fluid passageway, and a slidable plug blocking said passageway; means for unsealing said second end; means for removing said second fluid from said duct through said unsealed second end; and wherein said apparatus is shaped and dimensioned to prevent contact of said removed second fluid from said excluded first fluid when said duct segment is installed in said cavity.
26. The apparatus of Claim 25 wherein said air trapping device is attached to said duct by the means of a second set of shear pins.
27. The apparatus of Claim 26 wherein said slidable plug is attached to said trapping device by means of a first set of shear pins.
28. An apparatus for installing a duct within the boundary of an underground hole partially containing a first fluid comprising: a duct shaped and dimensioned to be run into said hole; a flow restrictor attached to one end of said duct so as to restrict flow of said first fluid into the interior of said duct portion; a plug slidably attached within said duct so as to form a flotation cavity between said plug and said restrictor capable of containing a second fluid, said plug having a fluid communication port within said plug extending from said flotation cavity to an adjacent internal portion of said duct; means for partially filling said adjacent cavity with a third fluid; means for releasably blocking said port; means for unblocking said port so as to allow a partial exchange of said fluids from said flotation cavity to said adjacent cavity; means for removing said second fluid wherein said withdrawn second fluid does not contact said hole boundary; means for sliding said plug towards said flow preventer until said plug contacts said flow restrictor; means for attaching said plug to said flow restrictor; means for removing said attached plug and flow restrictor from said duct; and means for circulating a third fluid from said duct to said hole and back to said duct when said port is unblocked.
29. The apparatus of Claim 28 which also comprises a plurality of centralizers attached to said duct and extending beyond the cross sectional dimensions of said duct.
30. The apparatus of Claim 28 wherein said plug is composed of a fluid disco posable material.
31. The apparatus of Claim 28 which also comprises a closed cell foam insert within said flotation cavity.
32. The apparatus of Claim 28 which comprises a plurality of said plugs and wherein said means for attaching is also capable of attaching said plurality of plugs when in contact with said flow restrictor.
33. A process useful in installing a duct segment within a first fluid containing hole using a second fluid, a fluid inflow restriction device, a means for circulating fluid from the duct to the hole and back to the duct, and a fluid trapping duct insert, said process comprising: attaching said fluid inflow restriction device to said duct segment to form one end of a flotation duct portion capable of containing a second fluid and generally capable of excluding said first fluid: attaching said fluid trapping insert to the other end of said flotation portion within said duct segment; installing said duct segment into said hole; removing said second fluid from said duct segment without said second fluid contacting said excluded first fluid; and circulating a fluid from said duct segment to said hole and back to said duct segment.
34. The process of Claim 33 wherein said fluid trapping insert'is slidable within said duct segment having a sealed passage from said flotation portion to an adjacent portion of said duct segment, and which process step of circulating a fluid comprises: opening said sealed passage after installing said duct segment, wherein said opening transfers said second fluid from said flotation portion to said adjacent portion; filling said flotation portion with said second fluid before attaching said fluid trapping insert; flowing a hardenable cement slurry through said duct segment after opening said passage; and removing said opened passage trapping insert after said cement slurry hardens.
35. The process of Claim 34 which also comprises sliding said opened passage trapping insert towards said inflow prevention device prior to removing said trapping insert.
36. The process of Claim 35 wherein said removing comprises drilling out of said insert, said inflow prevention device, and a portion of said hardenable cement remaining within said duct.
37. An apparatus useful in installing a duct into a cavity containing a first fluid, said apparatus comprising: a duct, a part of which forms a flotation portion capable of excluding some of said first fluid and containing a second fluid when said duct is installed in said cavity, said flotation portion having a first end generally distal from a second end; means^for sealing said second end; means for unsealing said second end; means for removing said second fluid from said duct through said unsealed second end; and means for circulating at least a portion of a third fluid from said duct to said cavity and back to said duct after removal of said second fluid.
38. The apparatus of claim 37 wherein said first and third fluids have essentially the same composition and wherein said circulating means is also a means for mixing said first and third fluids.
39. The process of Claim 36 which also comprises repositioning said slidable insert prior to said sliding towards said inflow prevention device, said repositioning changing buoyant forces on said cavity.
40. A process useful in installing a duct segment within a first fluid containing cavity within a material, the process using a second fluid having a density less than said first fluid, a first fluid inflow restriction device, means for circulating fluid from the duct segment to the cavity and back to the duct segment, a fluid trapping duct insert having a fluid port, and a fluid conduit capable of providing a fluid passageway between said port and said restriction device, said process comprising: attaching said inflow restriction device to said duct segment; attaching said fluid trapping insert to the other end of said flotation portion within said duct segment, whereby said duct segment, restriction device, and insert form a flotation portion capable of containing said second fluid and excluding some or all of said first fluid; attaching one portion of of said fluid conduit to said fluid port and a second portion of said fluid conduit to said restriction device; translating said conduit and flotation portion containing duct segment into a position generally within said cavity; and circulating a fluid from said duct segment through said conduit to said cavity and back to said duct segment.
41. The process of Claim 40 which also comprises the step of flowing a cement slurry through said conduit to said a portion of said cavity outside of said duct segment after said circulating step.
42. The process of Claim 41 which also comprises the step of moving said duct segment in a transverse oscillating manner relative to said cavity during said flowing step.
43. The process of Claim 42 which also comprises the steps of stopping said oscillating motion and removing said second fluid from said duct segment without said second fluid contacting said excluded first fluid after said circulating step.
44. The process of Claim 43 wherein said cavity is a subsurface borehole, said duct segment is a casing string, said first fluid is one or more drilling muds, said first fluid is air, and said conduit is a pipe string having a diameter smaller than said casing string.
45. An apparatus useful in installing a duct into a cavity within a material, said cavity containing a first fluid, said apparatus comprising: a duct, part of which forms an exterior portion of a flotation hollow capable of excluding at least some of said first fluid when containing a second fluid having a density less than said first fluid and when said duct is at least partially located within said cavity, said flotation hollow having a first end generally distal from a second end; a conduit, part of which forms an interior portion of said flotation hollow, said conduit providing a fluid passageway between said first end and said second end; means for restricting a flow of first fluid from at or near said first end to said flotation hollow and capable of flowing fluid through said conduit; and means for sealing said second end except for said conduit.
46. The apparatus of Claim 45 which also comprises means for moving said duct in a oscillating manner when a fluid is flowing through said conduit.
47. The apparatus of Claim 46 which also comprises means for pumping a cement slurry through said conduit.
48. The apparatus of Claim 47 which also comprises means for unsealing said second end and removing said second fluid from said duct through said unsealed second end.
49. An apparatus useful in installing a duct into a cavity within a formation material, said cavity containing a first fluid, said apparatus comprising: a duct, part of which forms an exterior portion of a flotation hollow capable containing a second fluid having a density less than said first fluid and when said duct is at least partially located within said cavity, said flotation hollow having a first end generally distal from a second end; means for first end restricting said first fluid from entering said flotation hollow; means for second end restricting said a fluid within said duct and outside of said flotation hollow from entering said flotation hollow; wherein said second fluid is not miscible with said formation material.
50. The apparatus of Claim 49 wherein said second fluid is a gas and said first fluid is a liquid and wherein a portion of said cavity is essentially cylindrical in shape having an axis which forms an incline angle to the vertical direction at least 63.4 degrees and said cavity portion extends for a distance of at least 914 meters.
51. The apparatus of Claim 50 wherein said incline angle is at least an average of approximately 63.4 degrees and said cavity portion extends for a distance of at least 1524 meters.
52. The apparatus of Claim 51 wherein said incline angle is at least an average of approximately 78.7 degrees over a distance- of at least 1829 meters.
53. The apparatus of Claim 52 wherein said second end restricting means also comprises a sealable port capable when unsealed of flowing said second fluid out of said flotation hollow is a direction having a component opposite to the direction of gravity.
54. The apparatus of Claim 53 wherein said incline angle and said density differences between said first and second fluids create a buoyant force of at least 24.4 newton per meter of duct.
55. The apparatus of Claim 54 wherein said duct has a nominal diameter of at least approximately 17 cm.
56. A process useful in installing a duct segment within a first fluid containing hole using a second fluid, a fluid inflow restriction device, a means for circulating fluid from the duct to the hole and back to the duct, and a fluid trapping duct insert, said process comprising: attaching said fluid inflow restriction device to said duct segment to form one end of a flotation duct portion capable of containing a second fluid and generally capable of excluding said first fluid: attaching said fluid trapping insert to the other end of said flotation portion within said duct segment; installing said duct segment into said hole; flowing a cement slurry through said duct segment into said hole; and removing said fluid inflow restriction device and said fluid trapping insert after said flowing step.
57. The process of Claim 56 wherein said removing step comprises drilling out said fluid inflow restriction and said fluid trapping insert.
58. The process of Claim 57 wherein said drilling also removes a portion of said cement slurry after setting.
EP90913295A 1989-08-31 1990-08-22 Well casing flotation device and method Withdrawn EP0489816A1 (en)

Applications Claiming Priority (6)

Application Number Priority Date Filing Date Title
US07/401,086 US4986361A (en) 1989-08-31 1989-08-31 Well casing flotation device and method
US48631290A 1990-02-28 1990-02-28
US486312 1990-02-28
US07/560,389 US5113411A (en) 1989-07-31 1990-07-31 Modulator and demodulator for data transmission systems
US560389 1990-07-31
US401086 2003-03-27

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EP0489816A1 true EP0489816A1 (en) 1992-06-17

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AU (1) AU6345890A (en)
BG (1) BG95990A (en)
BR (1) BR9007627A (en)
CA (1) CA2065338A1 (en)
FI (1) FI920904A0 (en)
HU (1) HUT60362A (en)
WO (1) WO1991003620A1 (en)

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JPH05500695A (en) 1993-02-12
AU6345890A (en) 1991-04-08
WO1991003620A1 (en) 1991-03-21
HU9200682D0 (en) 1992-05-28
FI920904A0 (en) 1992-02-28
BR9007627A (en) 1992-08-18
CA2065338A1 (en) 1991-03-01
BG95990A (en) 1993-12-24
HUT60362A (en) 1992-08-28

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