Downhole tubular patch, tubular expander and method

Information

  • Patent Grant
  • 6763893
  • Patent Number
    6,763,893
  • Date Filed
    Friday, July 18, 2003
    21 years ago
  • Date Issued
    Tuesday, July 20, 2004
    20 years ago
Abstract
A system for forming a patch in a well at a location along a tubular string which has lost sealing integrity includes a central patch body 60, an upper expander body 52 carrying an upper seal 50 or 56, and a lower expander body 98 carrying a lower seal 102, 104. The running tool includes an inner mandrel 14 axially moveable relative to the central patch body, and one or more pistons 20, 30, 20A axially moveable relative to the inner mandrel in response to fluid pressure within the running tool. Top expander 48 is axially moveable downward relative to the upper expander body in response to movement of the one or more pistons, and a bottom expander 120 is axially moveable upward relative to a lower expander body. After the upper expander body and a lower expander body have been moved radially outward into sealing engagement with a downhole tubular string, the running tool is retrieved to the surface.
Description




FIELD OF THE INVENTION




The present invention relates to downhole tools and techniques used to radially expand a downhole tubular into sealing engagement with a surrounding tubular. More particularly, this invention relates to a technique for forming a downhole tubular patch inside a perforated or separated tubular utilizing a conventional interior tubular and a tool which forms an upper seal and a lower seal above and below the region of the perforation or separation. The invention also involves a tubular expander for expanding a downhole tubular, and a patch installation and tubular expander method.




BACKGROUND OF THE INVENTION




Oil well operators have long sought improved techniques for forming a downhole patch across a tubular which has lost sealing integrity, whether that be due to a previous perforation of the tubular, high wear of the tubular at a specific downhole location, or a complete separation of the tubular. Also, there are times when a screened section of a tubular needs to be sealed off. A tubular patch with a reduced throughbore may then be positioned above and below the zone of the larger diameter tubular which lost its sealing integrity, and the reduced diameter tubular then hung off from and sealed at the top and bottom to the outer tubular. In some applications, the patch may be exposed to high thermal temperatures which conventionally reduce the effectiveness of the seal between the tubular patch and the outside tubular. In heavy oil recovery operations, for instance, steam may be injected for several weeks or months through the tubular, downward past the patch, and then into a formation.




U.S. Pat. No. 5,348,095 to Shell Oil Company discloses a method of expanding a casing diameter downhole utilizing a hydraulic expansion tool. U.S. Pat. No. 6,021,850 discloses a downhole tool for expanding one tubular against a larger tubular or the borehole. Publication U.S. 2001/0,020,532A1 discloses a tool for hanging a liner by pipe expansion. U.S. Pat. No. 6,050,341 discloses a running tool which creates a flow restriction and a retaining member moveable to a retracted position to release by the application of fluid pressure.




Due to problems with the procedure and tools used to expand a smaller diameter tubular into reliable sealing engagement with a larger diameter tubular, many tools have avoided expansion of the tubular and used radially expandable seals to seal the annulus between the small diameter and the large diameter tubular, as disclosed U.S. Pat. No. 5,333,692. Other patents have suggested using irregularly shaped tubular members for the expansion, as disclosed in U.S. Pat. Nos. 3,179,168, 3,245,471, 3,358,760, 5,366,012, 5,494,106, and 5,667,011. U.S. Pat. No. 5,785,120 discloses a tubular patch system with a body and selectively expandable members for use with a corrugated liner patch. U.S. Pat. No. 6,250,385 discloses an overlapping expandable liner. A sealable perforating nipple is disclosed in U.S. Pat. No. 5,390,742, and a high expansion diameter packer is disclosed in U.S. Pat. No. 6,041,858.




Various tools and methods have been proposed for expanding an outer tubular while downhole, utilizing the hydraulic expansion tool. While some of these tools have met with limited success, a significant disadvantage to these tools is that, if a tool is unable to continue its expansion operation (whether due to the characteristics of a hard formation about the tubular, failure of one or more tool components, or otherwise) it is difficult and expensive to retrieve the tool to the surface to either correct the tool or to utilize a more powerful tool to continue the downhole tubular expansion operation. Accordingly, various techniques have been developed to expand a downhole tubular from the top down, rather than from the bottom up, so that the tool can be easily retrieved from the expanded diameter bore, and the repaired or revised tool then inserted into the lower end of the expanded tubular.




The disadvantages of the prior art are overcome by the present invention, and an improved system for forming a patch in a well and a location along the downhole tubular string which has lost sealing integrity is hereafter disclosed. The system includes a tubular patch with a central patch body, an upper expander body, and a lower expander body, and a running tool with a top expander and a bottom expander to move the tubular patch into sealing engagement with the downhole tubular string. The present invention also discloses a tubular expansion running tool and method which may be reliably used to expand a downhole tubular while facilitating retrieval of the tool and subsequently reinsertion of the tool through the restricted diameter downhole tubular.




SUMMARY OF THE INVENTION




A system for forming a patch in a well includes a tubular patch for positioning within the downhole tubular string at a location that has lost sealing integrity. The tubular patch is supported on a running tool suspended in the well from a work string. The tubular patch includes a central patch body having a generally cylindrical central interior surface, an upper expander body having a generally cylindrical upper interior surface and an upper exterior seal, and a lower expander body having a generally cylindrical lower interior surface and a lower exterior seal. The tubular patch may also include an expansion joint positioned between the upper expander body and the lower expander body to compensate for expansion and contraction of the tubular patch caused by thermal variations between the tubular patch and the tubular string exterior of the patch. The running tool includes an inner mandrel that is axially movable relative to the central patch body, and one or more pistons each axially movable relative to the inner mandrel in response to fluid pressure within the running tool. A top expander is axially moveable downward relative to the upper expander body in response to axial movement of or one or more pistons, and a bottom expander axially moves upward relative to the lower expander body in response to axial movement of the one or more pistons. The one or more pistons preferably includes a first plurality of pistons for moving the top expander relative to the upper expander body, and a second plurality of pistons for moving the bottom expander relative to the lower expander body. Each of the upper expander body and lower expander body may include a set of slips for gripping engagement with the inner surface of the tubular string.




It a feature of the present invention that the lower expander includes a first plurality of axially-spaced expander segments and a second plurality of axially-spaced expander segments. Each of the second plurality of expander segments is spaced between adjacent first expander segments and is axially movable relative to the first expander segments. When the first and second plurality of expander segments are vertically aligned, the expander segments together expand the lower expander body as they are moved upward through the lower expander body. When the first expander segments are axially spaced from the second expander segments, the expander segments of the running tool may be passed through the central patch body for purposes of installing the running tool on the tubular patch and for retrieving the running tool to the surface after setting of the tubular patch.




It is a feature of the present invention that an outer sleeve interconnects a first plurality of cylinders to the top expander, and that a shear member may be provided for interconnecting the outer sleeve and the running string.




A related feature of the invention is that another shear member may be provided for disconnecting the first plurality of pistons and the top expander after a selected axial movement of the top expander relative to the upper expander body.




It is a feature of the invention that exterior seals may each be formed from a variety of materials, including a graphite material.




It is another feature of the invention that an expansion joint may be provided between the upper expander body and the lower expander body for thermal expansion and/or contraction of the central patch body.




Still another feature of the invention is that the running tool may be provided with a plug seat, so that a plug landed on the seat achieves an increase in fluid pressure within the running tool and to the actuating pistons.




Another significant feature of the present invention is that a running tool and method are provided for expanding a downhole tubular while within the well. Hydraulic pressure may be applied to the tool to act on the lower expander to either expand an outer tubular, or to expand the lower expander body of the thermal patch. The expander members may be positioned between axially aligned positions for expanding the downhole tubular and axially separated positions for allowing the expander members to collapse allows the running tool to be easily retrieved to the surface.




Yet another feature of the invention is that a plurality of dogs or stops may be provided on the running tool for preventing axial movement of the upper expander body in response to downward movement of the upper expander, and axial movement of the lower expander body in response to upward movement of the lower expander. The dogs may move radially inward to a disengaged position for purposes of installing the running tool on the tubular patch and for retrieving the running tool after installation of the tubular patch. Each of a plurality of dogs may be biased radially outward to an engaged position within the controlled gap of the expansion joint.




It is a significant advantage that the system for forming a patch in a well according to the present invention utilizes conventional components with a high reliability. Also, existing personnel with a minimum of training may reliably use the system according to the present invention, since the invention relies upon utilizing well-known surface operations to form the downhole patch.




These and further objects, features and advantages of the present invention will become apparent from the following detailed description, wherein reference is made to the figures in the accompanying drawings.











BRIEF DESCRIPTION OF THE DRAWINGS





FIGS. 1A through 1J

illustrate sequentially (lower) components of the patch system according to the present invention. Those skilled in the art will appreciate that line breaks along the vertical length of the tool may eliminate well known structural components for inter connecting members, and accordingly the actual length of structural components is not represented. The system as shown in

FIG. 1

positions show the running tool on a work string, with the running tool supporting a tubular patch in its run-in configuration.





FIGS. 2A-2E

illustrates components of the running tool partially within the central patch body during its installation on the tubular patch at the surface.





FIG. 3A

illustrates components of the running tool with the ball landed to increase fluid pressure to expand the upper expansion body and to shear the upper shear collar.





FIG. 4A

shows the lower end of the running tool configured for withdrawing the running tool from the tubular patch to the surface.











DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS





FIGS. 1A-1J

disclose a preferred system for forming a patch in a well at a location along a downhole tubular string that has lost sealing integrity. The running tool is thus suspended in a well from the work string WS, and positioned within the casing C. The system of the present invention positions a tubular patch within the downhole casing C at a location that has lost sealing integrity, with the tubular patch being supported on the running tool


10


and thus suspended in the well from the work string WS.





FIGS. 1D-1H

depict the tubular patch of the present invention along with various components of the running tool. When installing the patch within a well, the patch is assembled from its lowermost component, the lower expander body


98


, to its uppermost component, the upper expander body


52


, and lowered into the well and suspended at the surface. The lower expander body


98


is attached by thread connection


96


at its upper end to the expansion joint mandrel


86


, as shown in

FIGS. 1G and 1H

. The expansion joint mandrel extends into a honed seal bore of the expansion joint body


70


and maintains sealing engagement therewith by a dynamic metal-to-metal ball seal


81


on expansion joint mandrel


86


. A sealed expansion joint thus allows thermal expansion and contraction of the thermal patch secured at the upper and lower ends to the casing. A controlled gap


71


of a selected axial length, located between the shoulder


61


and the top end


83


of the expansion joint mandrel


86


, is maintained by shear pins


94


(

FIG. 1B

) extending from the retainer


92


, which is threadedly attached to the bottom


84


of the of the expansion joint body


70


.

FIGS. 1E and 1F

depict a portion of the central patch body


60


of the tubular patch. The central patch body


60


extends upward from the expansion joint body


70


to the upper expander body


52


, as shown in FIG.


1


D. The central patch body


60


, in many applications, may have a length of from several hundred feet to a thousand feet or more. Both the lower expander body


98


and the upper expander body


52


preferably have a generally cylindrical interior surface and support one or more vertically spaced respective external seals


102


,


104


and


54


,


56


formed from a suitable seal material, including graphite. Graphite base packing forms a reliable seal with the casing C when the expander bodies are subsequently expanded into sealing engagement with the casing. Both the lower expander body


98


and upper expander body


52


also preferably include a plurality of respectively circumferential-spaced slips


106


,


58


. The foregoing assembled tubular patch is thus suspended at the surface of the well, prepared for installation of the running tool.




The running tool


10


is assembled in two halves to facilitate installation and support of the tubular patch thereon. The lower half of the running tool is illustrated in

FIGS. 2B-2E

and

FIGS. 1C-1J

, while the upper half of the running tool is illustrated in

FIGS. 1A-1C

and FIG.


2


A. In

FIGS. 2C and 2D

, the I.D. of the central patch body


60


is shown by line


61


.




Referring to

FIGS. 1G and 1H

, the lower body


108


of the running tool


10


is attached to the lower end of the running tool mandrel


14


. An inner collet ring


112


is slidably supported about the lower body


108


. A plurality of collet fingers


116


extends downward from the collet ring


112


. An outer collet ring


114


is slidably supported about the inner collet ring


112


, and a plurality of collet fingers


118


extend downward from collet ring


112


. The outer collet ring is connected to the inner collet ring by limit screw


115


that is slidable within slot


113


in the outer collet ring. When in the position shown in

FIG. 1H

, the expanded position, each of the collet fingers includes a lower end


120


with a radially expanding outer curved surface


121


. Shear collar


124


is threaded at


122


to body


108


and engages the lower collar support surface


111


to fix the downward position of the lower ends


120


when expanding the lower expander body


98


. The inner surface


110


on each of the lower ends


120


thus engages the upper surface of shear collar


124


to prevent the collet fingers


116


and


118


from flexing inward radially during the expanding operations. The expanders are circumferentially interlaced, as shown in

FIG. 1J

, during the expansion of the lower expansion body. The outer collet ring


114


has an upper extension


100


that serves to release the collets, and will be discussed in detail below.




The running tool mandrel


14


extends upward and is threadedly connected with the connector


65


having a stop surface


66


for engagement with sleeve


64


. Sleeve


64


includes an upper portion having an enlarged diameter


73


, and a lower portion


88


having a reduced diameter


87


, as shown in

FIGS. 1F-1G

. A collar


90


is positioned at the lower end of the sleeve


88


, with both sleeve


64


and collar


90


being in sliding engagement with mandrel


14


. A cage


68


is supported in sliding engagement about the sleeve


64


and contains a plurality of windows


69


(see

FIG. 2C

) with retaining lugs


67


spaced radially about cage


68


. A plurality of dogs


74


each extend through a respective window


69


. The dogs


74


are furnished with upper lugs


78


and lower lugs


67


that limit radial movement of each dog within the windows. The dogs


74


prevent closing of the control gap


71


in the expansion joint


70


to prevent downward movement of the upper expander body in response to the top expander and upward movement of the lower expander body in response to the lower expander. A biasing member, such as spring


76


, exerts a radially outward bias force on the dog


74


. When the cage


68


and dogs


74


assembly are position about the enlarged diameter


73


of sleeve


64


, the dogs are locked in an outward radial position. When the cage


68


and dogs


74


assembly are position about the reduced diameter


87


of sleeve


64


, the dogs are released and can be moved radially inward within the respective window when an inward compressive force is applied to the dogs.




The lower half of the running tool, as thus assembled as discussed above, is run inside the tubular patch that is suspended within and from the surface of the well. Additional lengths of mandrel


14


and connectors


65


are threadedly made-up to the connector shown in

FIG. 1F

to correspond with the length of central patch body


60


of the tubular patch. As the lower half of the running tool is lowered into the tubular patch, the lower ends


120


of inner collet fingers


116


and outer collet fingers


118


are moved upward relative to the lower body


108


so as to position the lower ends


120


adjacent the reduced diameter


109


of lower body


108


. Additionally, the inner collet ring


112


is moved upward relative to the outer collet ring


114


, until limit pin


115


contacts the upper end of slot


113


, as shown in FIG.


2


D. This permits the upper and lower collet fingers to flex radially inward to the reduced diameter


109


of lower body


108


and allows the lower ends


120


to pass through the reduced internal diameter of the central patch body


60


. Similarly, referring to

FIG. 2C

, the cage


68


is positioned adjacent the reduced diameter


87


of sleeve


64


, allowing dogs


74


to be pressed inwardly, until the cage


68


has been lowered to a position adjacent the reduced internal diameter


49


of the upper expander body


52


(see

FIGS. 1D-1F

) by engagement of stop surface


66


on collar


65


with the top of sleeve


64


. The cage


68


and dogs


74


may maintain this position adjacent the reduced diameter


87


of sleeve


64


until sufficient lengths of mandrel


14


have been added to position the cage and dogs adjacent the controlled gap


71


of the expansion joint of the tubular patch, at which time the enlarged diameter


73


of the sleeve


64


will move adjacent the cage


68


and dogs


74


, thereby locking the dogs into the controlled gap


71


.




After adding a sufficient length of mandrel


14


to the lower half of the running tool to correspond to the central patch body


60


, a seat collar


63


(see

FIG. 3A

) is connected to the top of the mandrel


14


, and supports a sleeve


64


that has a seat thereon and is connected to the seat collar


62


by pins


66


. During expansion of the patch, a ball


68


or other type of plug lands on the sleeve seat


64


to close and seal the throughbore permitting increase in pressure within the running tool and develop the required forces to expand the tubular patch. Alternatively, the ball could land on a permanent seat, or the seat collar


62


could be furnished with a solid plug to use in place of a ball and seat.




A final length of mandrel


14


is added to the lower half of the running tool above the seat collar


62


. An upper collet ring


50


is positioned in sliding engagement about the mandrel


14


. A plurality of collet fingers


46


extend upward from the upper collet ring


50


and terminate in expander members


47


with curved surfaces


48


at their upper ends, as shown in FIG.


1


D. The upper collet ring, collet fingers and expander members are lowered to engage the tapered surface


53


at the top of the upper expander body


52


. An upper shear collar


42


is threadedly engaged with adjusting mandrel


40


and is placed about the mandrel


14


and lowered into engagement with the top


49


of expander members


47


of the expander collet


46


. A connector


34


is attached to the top of the mandrel


14


. The collet support hub


44


of the upper shear collar


42


supports the top expander members


47


, thus preventing inward radial movement of the top expander members during setting of the tubular patch. Referring to

FIG. 2E

, the lower threads of sleeve


27


are threaded over the upper thread of adjusting collar


39


until the sleeve


27


and adjusting collar


39


are completely telescoped within one another. Similarly, the lower threads of adjusting collar


39


are threaded over the upper threads of the adjusting mandrel


40


until the bottom end


41


of adjusting collar


39


abuts the top of the shear collar


42


.




After checking to ensure that the lower half of the running tool has been lowered sufficiently within the surface suspended tubular patch to position the lower ends


120


of the lower expanders below the bottom of lower expander body


98


, the lower half of the running tool is raised, moving the inner surface


110


and the bottom surface


111


of the shear collar into engagement with the lower expanders


120


. The expanders


120


are thereafter raised until the outer curved surface


121


of the expanders


120


engage the tapered bottom


123


at the bottom of the lower expander body


98


, as shown in FIG.


1


H.




With sufficient tensile strain maintained on the lower half of the running tool, the upper half of the running tool may now be attached to the lower half of the running tool and adjustments made for running the tubular patch to the desired setting depth within the well. The upper half of the running tool may be assembled as a unit from the top, as shown in

FIGS. 1A-1C

and FIG.


2


A.




The upper end of the upper half of the running tool includes a conventional top connector


12


that is structurally connected by thread


16


to the running tool inner mandrel


14


. A throughport


18


in the mandrel


14


and below the top connector


12


allows fluid pressure within the interior of the running tool to act on the outer connector


20


, which as shown includes conventional seals for sealing between the mandrel


14


and the outer sleeve


28


. A shear sleeve


22


may interconnect the outer connector


20


to the connector


12


, so that downward forces in the work string WS may be transmitted to the outer sleeve


28


by shoulder


26


acting through the shear sleeve


22


. A predetermined amount of fluid pressure within the running tool acting on the outer connector


20


will thus shear the pin


24


and allow for downward movement of the outer sleeve


28


relative to the connector body


12


.





FIG. 1B

shows another outer connector


20


A and an inner connector


30


. Fluid pressure to the inner connector


30


passes through the throughport


18


A, and connector


30


is axially secured to the inner mandrel


14


. Fluid pressure thus exerts an upward force on the inner connector


30


and thus the mandrel


14


, and also exerts a further downward force on the outer sleeve


28


A due to the outer connector


20


A. Those skilled in the art will appreciate that a series of outer connectors, inner connectors, sleeves and mandrels may be provided, so that forces effectively “stack” to create the desired expansion forces, as explained subsequently. It is a particular feature of the present invention that a series of inner and outer connectors, outer sleeves and mandrels exert a force on each the upper expander body and lower expander body in excess of 100,000 pounds of axial force, and preferably in excess of about 150,000 pounds of axial force, to expand the expander bodies and effect release of the running tool from the tubular patch.





FIG. 1B

shows a conventional connector


20


A for structurally interconnecting lengths of outer sleeve


28


, while connector


30


similarly connects lengths of mandrel. The lower end of sleeve


28


A is connected to connector


32


to complete the upper half of the running tool


10


, as shown in FIG.


2


A.




The upper half of the running tool


10


as above described may be connected to the lower half of the running tool (including the suspended tubular patch) by engagement of threads shown at the bottom of mandrel


14


, as shown in

FIG. 2A

, with threads in the top of connector


34


, as shown in FIG.


2


B. With the running tool in tension while supporting the tubular patch on the expanders


120


, the telescoped sleeve


27


and adjusting collar


39


are positioned to engage the thread


38


on the bottom of the adjusting collar


39


with the thread on the top of adjusting mandrel


40


. The adjusting collar


39


and sleeve


27


are un-telescoped and the thread


36


on the bottom of the sleeve


27


is engaged with the external thread at the top of the adjusting collar


39


, and the thread on the top of the sleeve


27


is engaged with the thread at the bottom of the connector


32


, as shown in FIG.


1


C. The upper shear collar


42


is adjusted downward on the lower threaded end


44


of the adjusting mandrel


40


until the expander members


47


with curved surfaces


48


abut the top internal tapered surface


53


of the upper expander body


52


. With the tubular patch now properly supported on the running tool, a work string WS is connected to the top connector


12


and the tubular patch and running tool are conveyed to the setting depth within the well.




The tubular patch is set by seating a ball


68


or other plug on the sleeve seat


63


of the seat collar


62


and increasing fluid pressure to activate the plurality of pistons


20


,


30


of the running tool to develop the required tensile and compressive forces to expand the tubular patch. Compressive forces are delivered to the upper expander members


47


to expand the upper expander body


52


of the tubular patch by shear sleeve


22


, outer connectors


20


and


20


A, sleeves


28


, connector


32


, sleeve


27


, adjusting collar


39


, adjusting mandrel


40


and upper shear collar


42


to axially move expander members


47


downward into the enlarged bore


59


of the upper expander body


52


, thus expanding the exterior surface of the upper expander body


52


and bringing packing


54


,


56


and slips


58


into respective sealing and gripping engagement with the casing C.




Simultaneously, tensile forces are delivered to the lower expander members


120


to expand the lower expander body


98


of the tubular patch by top connection


12


, mandrels


14


, inner connectors


30


, connector


34


, seat collar


62


, connector


65


, lower body


108


and lower shear collar


124


to axially move expander members


120


into the enlarged bore


117


of the lower expander body


98


, thus expanding the exterior surface of the lower expander body


98


, and bringing packing


102


,


104


and slips


106


into respective sealing and gripping engagement with the casing C. Tensile and compressive forces developed by the running tool in expanding the tubular patch are prevented from closing the axial controlled gap


71


of the expansion joint by locking the dogs


74


within the controlled gap


71


as previously discussed.




As the running tool continues to “stroke” under fluid pressure and the upper expander body


52


and lower expander body


98


are expanded against the casing, sufficient forces are developed by the running tool to effect shearing of the lower shear collar


124


, and optionally also the upper shear collar


42


, to release the running tool


10


from the expanded tubular patch. The upper expander members


47


, collet fingers


46


and collet ring


50


are forced downward inside the upper expander body until shoulder


51


of collet ring


50


abuts internal shoulder


55


of upper expander body


52


, stopping further downward axial movement of the expander members


47


. Increased fluid pressure continues to move compressive members of the running tool downward, shearing the controlled thin walled section of the upper shear collar


42


, allowing the threaded hub of the shear collar to move toward the collet ring


50


, thereby permitting the expander members


47


and the upper collet fingers


46


to flex inward, as permitted by the axial gaps between the collet fingers


46


. As the work string WS is raised to pull the running tool from engagement with the tubular patch, the upper shoulder of seat collar


62


abuts the collet ring


50


, as shown in

FIG. 3A

, lifting the upper collet and expander from engagement with the upper expander body


52


.




Simultaneously, the lower expander members


120


, outer collet fingers


118


, inner collet fingers


116


, inner collet ring


112


and outer collet ring


114


and its upper extension


100


are forced upward inside the lower expander body


98


until the top shoulder


101


of upper extension


100


abuts the bottom shoulder


82


(

FIG. 1F

) of the cage


68


that is retained in its locked position by virtue of the dogs


74


positioned in the axial controlled gap


71


of the expansion joint


70


. Increased pressure continues to move tensile members of the running tool upward, shearing the controlled thin walled section of the lower shear collar


124


, allowing the threaded hub of the shear collar to move into abutment with the inner collet ring


112


, thereby shifting upward the inner collet ring


112


, the inner collet fingers


116


and the attached expander members


120


A, until limit pin


115


abuts the upper end of slot


113


in the outer collet ring


114


. This upward shifting of the inner expander members


120


A and the inner collet figures


116


move the inner expander members


120


A axially from outer expander members


120


on the outer collet fingers


118


. Both expander members


120


and


120


A can now flex inwardly toward the reduced diameter


119


of lower body


108


, as shown in FIG.


4


A. The lower sheared portion of shear collar


124


is caught by lower retainer


126


, as shown in FIG.


4


A. As the running tool


10


is raised upward by the workstring WS relative to the tubular patch, the top shoulder


107


of lower body


108


engages the bottom of collar


90


attached to sleeve


64


. Continued raising of the workstring moves the enlarged diameter


73


of sleeve


64


from locking engagement with the dogs


74


and positions the reduced diameter portion


87


of sleeve


64


adjacent the dogs


74


. The cage


68


and dogs


74


are thus released from the controlled gap


71


within the tubular patch as the running tool is released from the tubular patch and pulled from the well.




Those skilled in the art will appreciate that the patch of the present invention provides a highly reliable system for sealing within a casing, and is particularly designed for a system that minimizes the annular gap between the sealing element and the casing under elevated temperature and pressure conditions that are frequently encountered in downhole thermal hydrocarbon recovery applications. In some applications, an expansion joint along the length of the patch body may not be required, and thus the dog and cage assembly discussed above used to limit or prevent axial movement of the upper and lower expander bodies may be eliminated. While two upper seals and two lower seals are shown, at least one upper seal on the upper expander body and at least one lower seal on the lower expander body will be desired for most applications.




Those skilled in the art will appreciate that the running tool of the present invention may also be used in various applications for expanding the diameter of a downhole tubular. In one application, only a mid-portion of a downhole tubular may be expanded, e.g., to assist in closing off a water zone from hydrocarbon zones above and below the water zone. In that case, the downhole tubular may be expanded with a tool similar to that disclosed above. An expanded recess may be provided in which the expanded members


120


may be positioned, and the downhole tubular expanded with hydraulic forces to pull the inner tool mandrel upward, as disclosed herein. For this application, the outer housing of the tool may be secured by slips to a top portion of the outer tubular which will not be expanded. In other applications, substantially the entire length of the outer tubular may be expanded by performing a series of expansion operations, each initiated by grippingly engaging the body of the tool with an upper portion of the outer tubular, using hydraulic forces as disclosed herein to pull an inner mandrel of the tool upward and expand the outer tubular to a position below the engaging slips, and then raising the engaging slips to a higher level in the well while leaving the lower expanders below the upper end of the expanded tubular. Those skilled in the art will appreciate the significant advantages of the tubular expander and method of the present invention in that, if for some reason the tool is not able to expand the outer tubular during the expansion operation, fluid pressure may be increased to allow the expansion members


120


and


120


A to axially separate, thereby allowing the tool to be easily retrieved to the surface through the unexpanded portion of the outer tubular.




As disclosed herein, a preferred embodiment of the invention for forming a tubular patch includes a first plurality of pistons for raising the lower expander members


120


, and another plurality of pistons for lowering the upper expander members


47


. This configuration significantly improves the reliability of the tool, and allows the operator to effectively select the desired axial force for the expansion operation by stacking pistons, as discussed above. In a less preferred embodiment, one or more hydraulic pistons may be provided, and either hydraulic flow channels or mechanical linkage mechanisms used to convert the force from the one or more pistons to opposing upward and downward forces which will raise the lower expanders and lower the upper expanders, respectively.




It will be understood by those skilled in the art that the embodiments shown and described are exemplary and various other modifications may be made in the practice of the invention. Accordingly, the scope of the invention should be understood to include such modifications, which are within the spirit of the invention.



Claims
  • 1. A tool for suspending in a well on a work string to radially expand a downhole tubular, comprising:a housing securable downhole within the well on a lower end of the work string; a mandrel axially moveable relative to the housing; one or more pistons each axially moveable relative to the mandrel in response to fluid pressure within the mandrel; a lower expander axially moveable upward relative to the downhole tubular in response to axial movement of the one or more pistons for radially expanding the downhole tubular; and the lower expander including a first plurality of expander segments and a second plurality of expander segments, each of the second plurality of expander segments being spaced between adjacent first expander segments and axially moveable relative to the first plurality of expander segments, such that when the first and second plurality of expander segments are vertically aligned, the first and second expander segments together expand the downhole tubular, and when the first plurality of expander segments are axially spaced from the second plurality of expander segments, the tool may be retrieved to the surface through a portion of the outer tubular which was not expanded.
  • 2. The tool as defined in claim 1, further comprising:an outer sleeve interconnecting the one or more pistons and the lower expander; and a shear member for interconnecting the outer sleeve and the work string.
  • 3. The tool as defined in claim 1, where the one or more pistons include a first plurality of pistons for moving the lower expander relative to the downhole tubular.
  • 4. The tool as defined in claim 1, further comprising:a plug seat positioned within the running tool, such that a plug landed on the plug seat causes an increase in fluid pressure in the running tool and to the one or more pistons.
  • 5. A method of expanding a downhole tubular, comprising:securing a tool housing within a well; supporting a mandrel axially moveable within the tool housing; providing one or more pistons axially moveable relative to the mandrel in response to fluid pressure within the mandrel; axially moving a lower expander relative to a downhole tubular in response to axial movement of the one or more pistons for radially expanding the outer tubular; and providing the lower expander with a first plurality of expander segments and a second plurality of expander segments, each of the second plurality of expander segments being spaced between adjacent first expander segments and axially moveable relative to the first plurality of expander segments, such that when the first and second plurality of expander segments are vertically aligned, the first and second expander segments together expand the outer tubular, and when the first expander segments are axially spaced from the second expander segments, the tool may be retrieved to the surface through the portion of the outer tubular which has not been expanded.
  • 6. The method as defined in claim 5, further comprising:interconnecting the one or more pistons and the lower expander with an outer sleeve; and interconnecting the outer sleeve and the work string with a shear member; and increasing fluid pressure to shear the shear member.
  • 7. The method as defined in claim 5, further comprising:positioning a plug seat within the tool, such that a plug landed on the plug seat causes an increase in fluid pressure in the tool and to the one or more pistons.
  • 8. The method as defined in claim 5, further comprising:expanding only a selected portion of the downhole tubular, the expanded portion being positioned below a portion of the downhole tubular which is not expanded.
  • 9. The method as defined in claim 5, wherein the downhole tubular is expanded along substantially its entire length.
Parent Case Info

This application is a divisional of U.S. application Ser. No. 09/998,810 filed Nov. 30, 2001, now U.S. Pat. No. 6,622,789.

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6098717 Bailey et al. Aug 2000 A
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Foreign Referenced Citations (1)
Number Date Country
WO 0026502 Oct 1999 WO