Downhole pressure activated device and a method

Information

  • Patent Grant
  • 6321847
  • Patent Number
    6,321,847
  • Date Filed
    Monday, November 29, 1999
    24 years ago
  • Date Issued
    Tuesday, November 27, 2001
    22 years ago
Abstract
A downhole pressure activated device and a method of operating a tool comprises a chamber which has a fluid port for communication between the chamber and downhole fluid located outwith the device. The fluid port preferably comprises a check valve and a fluid flow restrictor connected in parallel, where preferably, the check valve permits fluid flow into the chamber and substantially prevents reverse flow. The chamber is provided with a pressure transmission means by which a pressure in the chamber greater than that in the downhole fluid is capable of being applied to a tool to be operated by the device.
Description




BACKGROUND OF THE INVENTION




This invention relates to a pressure activated device and a method for use downhole in oil wells and the like. The device and method can be used to set devices such as packers and hangers which must be mechanically engaged with tubing.




Most setting mechanisms previously used have relied on elastomeric seals to prevent leaks between the tubing and the annulus, but the elastomers degrade with time and this arrangement gives poor reliability in completion strings.




Setting devices have previously been used in which sealing between the tubing and the annulus does not rely on elastomeric seals. Such devices use an electronic module and an explosive charge held within an atmospheric chamber. The electronic module monitors pressure pulse signals applied to the drill or completion string and in response to the correct code ignites the explosive charge to generate a high pressure gas. The gas in turn is used to apply hydraulic pressure to the tool to be set.




This type of setting tool is very complicated and has a number of disadvantages. Atmospheric chambers in the tool are inherently unreliable, and typically dependent upon the elastomeric seals, and in the event of leakage into the chamber the tool becomes inoperable. The electronic module is subject to temperature limitations, especially at depth. Since the explosive charge is housed within the atmospheric chamber, no pressure differential will be generated at the setting piston until the hydrostatic pressure outside the setting tool has been overcome by the charge pressure, which limits the setting load available and puts a depth limit on the setting tool.




BRIEF SUMMARY OF THE INVENTION




According to a first aspect of the present invention, a downhole pressure activated device comprises a chamber having a fluid port for communication between the chamber and downhole fluid located outwith the device, the fluid port comprising a fluid flow control mechanism which permits fluid flow into the chamber and substantially prevents reverse flow, and the chamber being provided with a pressure transmission means by which a pressure in the chamber greater than that in the downhole fluid is capable of being applied to a tool to be operated by the device.




According to a second aspect of the present invention, there is provided a method of operating a tool downhole by applying pressure, the method comprising the steps of:




including in a string for insertion into a borehole a pressure activated device comprising a fluid chamber which communicates with downhole fluid located outwith the device in the borehole in a manner that allows substantially uninhibited flow of fluid into the chamber but substantially restricts flow of fluid out of the chamber, a pressure transmission means in fluid communication with the chamber and the pressure transmission means being connected to the tool operated by applying pressure;




inserting the string into the borehole;




increasing the pressure of fluid within the borehole so that a portion of the fluid flows from the borehole into the chamber;




reducing the pressure of the fluid in the borehole to generate a pressure differential between the fluid in the borehole and the fluid in the chamber;




whereby the pressure differential acts upon the pressure transmission means to operate the tool by applying pressure.




Preferably, the fluid flow control mechanism comprises a check valve and a fluid flow restrictor arranged in parallel, the check valve permitting fluid flow into the chamber and substantially preventing reverse flow.




Preferably, the chamber is a second chamber, and the device further comprises a first chamber, the first and second chambers being interconnected by the fluid port, and the first chamber having a fluid inlet which, in use, is open to the downhole fluid located outwith the device.




Typically, the pressure transmission means is a piston located within the second chamber that causes a mechanical force to be applied to the tool.




Preferably, the piston is provided with means permitting motion of the piston in a tool setting direction and preventing reverse motion.




Alternatively, the pressure transmission means may be a fluid outlet that transmits the pressure of the fluid to the tool.




In a preferred form of the invention, the device comprises an inner mandrel for connection in a borehole string, and an outer mandrel, the annular space between the inner and outer mandrels being divided by a seal ring to define said first and second chambers, the piston being a cylindrical member slidable between the inner and outer mandrels at one end of the device, and said inlet being provided at the opposite end of the device and including filter means.




The check valve may be within the seal ring and communicating with the first chamber via an inlet tube.




The means permitting one way motion may suitably be in the form of a C-shaped annular member interposed between the piston and the outer mandrel, the C-shaped member being provided on its opposite faces with circumferential threads or teeth engaging in matching formations in the pistons and the outer mandrel. Typically, the outwardly facing threads or teeth of the C-shaped mandrel will be relatively coarse and the inwardly facing ones relatively fine.




Typically, the piston is initially locked to the outer mandrel by means such as shear pins adapted to yield under a given applied load.




Preferably, the device is included in a completion string.











BRIEF DESCRIPTION OF THE DRAWINGS




Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:





FIG. 1

is a system block diagram of a downhole pressure activated device in accordance with the invention;




FIG.


2


(


a


) shows the upper quarter of a first form of the device combined with a hanger, in a half-sectional side view;




FIG.


2


(


b


) shows an exploded view of a check valve included in FIG.


2


(


a


);




FIG.


2


(


c


) shows the upper middle quarter of the device of FIG.


2


(


a


);




FIG.


2


(


d


) shows the lower middle quarter of the device of FIG.


2


(


a


);




FIG.


2


(


e


) shows the lower quarter of the device of FIG.


2


(


a


);





FIG. 3

is a perspective view of a C-ring used in the device of

FIG. 2

;




FIG.


4


(


a


) shows the upper half of a second form of the device combined with a hanger, in a half-sectional side view;




FIG.


4


(


b


) shows an exploded view of a check valve included in FIG.


4


(


a


); and




FIG.


4


(


c


) shows the lower half of the device of FIG.


4


(


a


).











DETAILED DESCRIPTION OF THE INVENTION




Referring to

FIG. 1

, the device of the present invention has the purpose of selectively operating a piston


14


by means of which mechanical force may be applied to any desired mechanically-set downhole tool, the tool to be set not forming part of the present invention.




The piston


14


is actuated by hydraulic pressure from a reservoir


18


filled with compressible fluid which forms a second chamber. A first chamber or top up chamber


19


is connected to the reservoir


18


via a top up chamber outlet tube


7


as shown in FIG.


2


(


a


), and a LEE (™) check valve


17


permitting flow from the top up chamber


19


to the reservoir


18


, and in parallel by a two-way restrictor


15


. The top up chamber


19


is in communication with the borehole annulus via a filter assembly


20


.




Referring now to FIGS.


2


(


a


), (


b


), (


c


), (


d


) and (


e


), the device includes an inner mandrel


1


having a through-bore and provided with the customary pin and box connections. An outer mandrel


5


concentric with the inner mandrel


1


, in conjunction with an end cap


2


and a piston


14


, defines an annular chamber which is partitioned by a concentric seal ring


8


to form the top up chamber


19


and the reservoir


18


, these being sealed from each other by O-rings


9


and


10


carried by the seal ring


8


. The seal ring


8


sits within shoulders formed on the outer


5


and inner


1


mandrels. The check valve


17


is positioned within the seal ring


8


and communicates with the top up chamber


19


via a top up chamber outlet tube


7


. The two-way restrictor


15


is also positioned within the seal ring


8


at a position not seen in FIGS.


2


(


a


), (


b


), (


c


), (


d


) or (


e


).




The top up chamber


19


communicates with the borehole annulus via a fluid inlet tube


6


and first and second stage filters


3


and


4


respectively which together form the filter assembly


20


.




The fluid inlet tube


6


, and the top up chamber outlet tube


7


are staggered radially and longitudinally, as shown in FIG.


2


(


a


), and this arrangement promotes the advantage that fluid flowing into the top up chamber


19


displaces fluid originally located therein into the outlet tube


7


, and thereafter into the oil reservoir, thus forming a debris trap.




The piston


14


is of annular form and, in this embodiment, is integral with the operating mechanism


30


of a hanger designated generally as


21


. The piston


14


is provided with inner


13


and outer


12


T-seals bearing against the inner mandrel


1


and outer mandrel


5


. The piston


14


is initially locked with respect to the outer mandrel


5


by one or more shear pins, one of which is seen at


16


. After fracture of the shear pin


16


, the piston


14


is restrained to downward motion, downwards as seen in FIG.


2


(


c


), by means of a serrated C-ring


22


which will be described in greater detail below.




In use, the reservoir


18


and the top up chamber


19


are filled with a suitable fluid. The assembly of FIGS.


2


(


a


) to (


e


) is preferably included in a completion string, but could also be included in a drill string, and is run to the desired position.




A significant feature of the invention is that in use the reservoir


18


is filled with a compressible fluid. It is preferred to use a compressible liquid such as silicon oil. Conveniently, the top up chamber


19


will be initially filled with the same fluid but it would be possible to use a different fluid.




The main function of the top up chamber


19


is to provide a clean compressible fluid which can be inserted into the reservoir


18


, upon activation of the device, as will now be described.




When the device has been run to the desired position, pressure is applied to the well fluid surrounding the device, causing well fluid to flow through the filters


3


and


4


with fluid in the top-up chamber


19


flowing via the check valve


17


into the reservoir


18


.




The applied pressure in the well fluid is then released rapidly. Fluid in the first chamber


19


can exhaust freely back through the filters


3


and


4


, but fluid in the reservoir


18


cannot return through the check valve


17


and can only return through the flow restrictor


15


at a very slow rate. There is therefore a transient positive pressure differential between the reservoir


18


and the exterior well fluid surrounding the device which acts on the cross-sectional area of the end of the piston


14


.




When a sequence of applying and releasing well fluid pressure is carried out, the piston


14


will initially shear the shear pins


16


and then be intermittently driven out of the reservoir


18


with each pressure cycle. The force that can be generated is a function of the applied pressure and the cross-sectional area chosen for the moveable piston


14


.




The piston


14


is prevented from return motion by the C-ring


22


which is shown in greater detail in FIG.


3


. The C-ring


22


is in the form of a split cylinder having circumferential teeth on its inner


32


and outer


31


surfaces. Instead of being truly circumferential, it may be convenient to provide the teeth


31


and


32


by conventional screw thread cutting. The outer teeth


31


may suitably be of about 8 threads per inch and the inner teeth


32


of a much finer pitch. Matching formations are machined on the facing surfaces of the piston


14


and the outer mandrel


5


. The C-ring


22


may be dimensioned to have a degree of inward resilience, such that it is a close fit on the piston


14


and a looser fit on the outer mandrel


5


. This arrangement works a one way motion or ratchet means.




FIGS.


4


(


a


), (


b


) and (


c


) show a modified embodiment which is generally similar to that of FIGS.


2


(


a


) to (


e


) and in which like parts are denoted by like reference numerals. In this embodiment, however, the actuating device is physically separate from the tool to be set and hydraulic pressure is communicated from the reservoir


18


via a conduit


40


to an annular piston


14




a


within a separate annular chamber.




These embodiments have a number of advantages. The elastomeric seals are subject only to a limited differential pressure for a short period of time, and are not subject to absolute pressure as no atmospheric chamber is required. In any event the seals are not crucial to the integrity of the well after completion. Therefore, once the setting sequence is completed, the seals become redundant. Further, as the embodiments operate by using a differential pressure and do not require an atmospheric chamber, there is no setting depth limitation. The control of the device is simple. The setting sequence can be repeated any desired number of times. Also, the device allows testing of the completion annulus before setting the tool, by increasing the pressure in the completion annulus to check for leaks.




If it is decided to abort the setting sequence, then slowly bleeding off the pressure in the completion annulus will avoid setting the tool. For instance, if the differential pressure required to break the shear pins


16


is 1500 p.s.i., then if the pressure in the annulus is reduced slowly in stages of 500 p.s.i., the fluid contained in the reservoir


18


will leak through the flow restriction


15


, thereby maintaining the shear pins


16


in tact.




Modifications and improvements may be made to the foregoing embodiments within the scope of the present invention.



Claims
  • 1. A downhole pressure activated device comprises a chamber having a fluid port for communication between the chamber and downhole fluid located outwith the device, the fluid port comprising a fluid flow control mechanism which permits fluid flow into the chamber and substantially prevents reverse flow, and the chamber being provided with a pressure transmission means by which a pressure in the chamber greater than that in the downhole fluid is capable of being applied to a tool to be operated by the device, wherein the chamber is a second chamber, and the device further comprises a first chamber, the first and second chambers being interconnected by the fluid port, and the first chamber having a fluid inlet which, in use, is open to the downhole fluid located outwith the device.
  • 2. A downhole pressure activated device according to claim 1, wherein the fluid flow control mechanism comprises a check valve and a fluid flow restrictor arranged in parallel, the check valve permitting fluid flow into the chamber and substantially preventing reverse flow.
  • 3. A downhole pressure activated device according to claim 1, wherein the pressure transmission means is a piston, which is in fluid communication with the second chamber, and which is capable of applying a mechanical force to the tool.
  • 4. A downhole pressure activated device according to claim 3, wherein the piston is provided with means permitting motion of the piston in a tool setting direction and substantially preventing reverse motion.
  • 5. A downhole pressure activated device according to claim 1, wherein the pressure transmission means is a fluid outlet provided for the second chamber and which is capable of transmitting pressure of fluid located in the second chamber to the tool.
  • 6. A downhole pressure activated device according to claim 1, wherein the device comprises an inner mandrel for connection in a borehole string, and an outer mandrel, the annular space between the inner and outer mandrels being divided by a seal ring to define said first and second chambers.
  • 7. A downhole pressure activated device according to claim 6, wherein the piston is a cylindrical member slidable between the inner and outer mandrels at one end of the device, and said fluid inlet being provided at the opposite end of the device and including filter means.
  • 8. A downhole pressure activated device according to claim 6, wherein the check valve is located within the seal ring and communicates with the first chamber via an inlet tube.
  • 9. A downhole pressure activated device according to claim 6, wherein the fluid flow, control mechanism comprises a check valve and a fluid flow restrictor arranged in parallel, the check valve permitting fluid flow into the chamber and substantially preventing reverse flow, wherein the fluid flow restrictor is located within the seal ring and communicates with the first chamber.
  • 10. A downhole pressure activated device according to claim 4, wherein the device comprises an inner mandrel for connection in a borehole string, and an outer mandrel, the annular space between the inner and outer mandrels being divided by a seal ring to define said first and second chambers, wherein the means permitting motion of the piston in a tool setting direction is a C-shaped annular member interposed between the piston and the outer mandrel, the C-shaped member being provided on its opposite faces with formations which engage in substantially matching formations in the piston and the outer mandrel.
  • 11. A downhole pressure activated device according to claim 3, wherein the device comprises an inner mandrel for connection in a borehole string, and an outer mandrel, the annular space between the inner and outer mandrels being divided by a seal ring to define said first and second chambers, and wherein the piston is initially locked to the outer mandrel by a destructible locking mechanism which is adapted to yield under a given applied load.
  • 12. A method of operating a tool downhole by applying pressure, the method comprising the steps of:including in a string for insertion into a borehole a pressure activated device comprising a fluid chamber which communicates with downhole fluid located outwith the device in the borehole in a manner that allows substantially uninhibited flow of fluid into the chamber but substantially restricts flow of fluid out of the chamber, a pressure transmission means in fluid communication with the chamber and the pressure transmission means being connected to the tool operated by applying pressure; inserting the string into the borehole; increasing the pressure of fluid within the borehole so that a portion of the fluid flows from the borehole into the chamber; reducing the pressure of the fluid in the borehole to generate a pressure differential between the fluid in the borehole and the fluid in the chamber; whereby the pressure differential acts upon the pressure transmission means to operate the tool by applying pressure, wherein the chamber is a second chamber, and the device further comprises a first chamber, the first and second chambers being interconnected by the fluid port, and the first chamber having a fluid inlet which, in use, is open to the downhole fluid located outwith the device.
  • 13. A method according to claim 12, wherein the fluid chamber communicates with the downhole fluid located outwith the device in the borehole via a check valve and a fluid flow restrictor arranged in parallel, the check valve permitting fluid flow into the chamber and substantially preventing reverse flow.
  • 14. A method according to claim 12, wherein the pressure transmission means is a piston, which is in fluid communication with the second chamber, and which causes a mechanical force to be applied to the tool.
  • 15. A method according to claim 14, wherein the piston is provided with means permitting motion of the piston in a tool setting direction and substantially preventing reverse motion.
  • 16. A method according to claim 12, wherein the pressure transmission means is a fluid outlet provided for the second chamber and which transmits pressure of fluid located in the second chamber to the tool.
  • 17. A method according to claim 12, wherein the pressure activated device is included in a completion string.
  • 18. A downhole pressure activated device comprises a chamber filled with a compressible liquid, the chamber having a fluid port for communication between the chamber and downhole fluid located outwith the device, the fluid port comprising a fluid flow control mechanism which permits fluid flow into the chamber during application of pressure in the downhole fluid located outwith the device, the fluid flow control mechanism further substantially preventing reverse flow, and a pressure transmission means which is in fluid communication with the compressible liquid in the chamber, such that following application of an initial pressure in the downhole fluid located outwith the device and further following reduction of the initial pressure in the downhole fluid located outwith the device, the compressible fluid within the chamber stores the initial pressure, and the stored initial pressure acts upon the pressure transmission means which is capable of applying the stored initial pressure to a tool to be operated by the device, the pressure transmission means only being capable of applying the initial pressure to the tool after the application of the initial pressure outwith the device has been reduced.
  • 19. A downhole pressure activated device according to claim 18, wherein the fluid flow control mechanism comprises a check valve and a fluid flow restrictor arranged in parallel, the check valve permitting fluid flow into the chamber and substantially preventing reverse flow.
  • 20. A downhole pressure activated device according to claim 18, wherein the chamber is a second chamber, and the device further comprises a first chamber, the first and second chambers being interconnected by the fluid port, and the first chamber having a fluid inlet which, in use, is open to the downhole fluid located outwith the device.
  • 21. A downhole pressure activated device according to claim 20, wherein the pressure transmission means is a piston, which is in fluid communication with the second chamber, and which is capable of applying a mechanical force to the tool.
  • 22. A downhole pressure activated device according to claim 21, wherein the piston is provided with means permitting motion of the piston in a tool setting direction and substantially preventing reverse motion.
  • 23. A downhole pressure activated device according to claim 20, wherein the pressure transmission means is a fluid outlet provided for the second chamber and which is capable of transmitting pressure of fluid located in the second chamber to the tool.
  • 24. A downhole pressure activated device according to claim 20, wherein the device comprises an inner mandrel for connection in a borehole string, and an outer mandrel, the annular space between the inner and outer mandrels being divided by a seal ring to define said first and second chambers.
  • 25. A downhole pressure activated device according to claim 24, wherein the pressure transmission means is a piston, which is in fluid communication with the second chamber, and which is capable of applying a mechanical force to the tool, and the piston is a cylindrical member slidable between the inner and outer mandrels at one end of the device, and said fluid inlet being provided at the opposite end of the device and including filter means.
  • 26. A downhole pressure activated device according to claim 24, wherein the fluid flow control mechanism comprises a check valve and a fluid flow restrictor arranged in parallel, the check valve permitting fluid flow into the second chamber and substantially preventing reverse flow, and the check valve is located within the seal ring and communicates with the first chamber via an inlet tube.
  • 27. A downhole pressure activated device according to claim 24, wherein the fluid flow control mechanism comprises a check valve and a fluid flow restrictor arranged in parallel, the check valve permitting fluid flow into the chamber and substantially preventing reverse flow, wherein the fluid flow restrictor is located within the seal ring and communicates with the first chamber.
  • 28. A downhole pressure activated device according to claim 22, wherein the device comprises an inner mandrel for connection in a borehole string, and an outer mandrel, the annular space between the inner and outer mandrels being divided by a seal ring to define said first and second chambers, wherein the means permitting motion of the piston in a tool setting direction is a C-shaped annular member interposed between the piston and the outer mandrel, the C-shaped member being provided on its opposite faces with formations which engage in substantially matching formations in the piston and the outer mandrel.
  • 29. A downhole pressure activated device according to claim 21, wherein the device comprises an inner mandrel for connection in a borehole string, and an outer mandrel, the annular space between the inner and outer mandrels being divided by a seal ring to define said first and second chambers, and wherein the piston is initially locked to the outer mandrel by a destructible locking mechanism which is adapted to yield under a given applied load.
  • 30. A method of operating a tool downhole by applying pressure, the method comprising the steps of:including in a string for insertion into a borehole a pressure activated device comprising a fluid chamber filled with compressible liquid which communicates with downhole fluid located outwith the device in the borehole in a manner that allows substantially uninhibited flow of fluid into the chamber but substantially restricts flow of fluid out of the chamber, a pressure transmission means in fluid communication with the chamber and the pressure transmission means being connected to the tool operated by applying pressure; inserting the string into the borehole; increasing the pressure of fluid within the borehole so that a portion of the fluid flows from the borehole into the chamber; reducing the pressure of the fluid in the borehole to generate a pressure differential between the fluid in the borehole and the fluid in the chamber; whereby the pressure differential acts upon the pressure transmission means to operate the tool by applying pressure, where the pressure transmission means is only capable of applying the pressure to the tool during the presence of the pressure differential.
Priority Claims (1)
Number Date Country Kind
9710746 May 1997 GB
PCT Information
Filing Document Filing Date Country Kind 102e Date 371c Date
PCT/GB98/01553 WO 00 11/29/1999 11/29/1999
Publishing Document Publishing Date Country Kind
WO98/54439 12/3/1998 WO A
US Referenced Citations (14)
Number Name Date Kind
3964305 Wray et al. Jun 1976
4113012 Evans et al. Sep 1978
4285400 Mullins, II Aug 1981
4421174 McStravick et al. Dec 1983
4444268 Barrington Apr 1984
4448254 Barrington May 1984
4595060 Beck Jun 1986
4664196 Manke May 1987
4665991 Manke May 1987
4766960 Williamson, Jr. Aug 1988
4791991 Morris et al. Dec 1988
5050681 Skinner Sep 1991
5209303 Barrington May 1993
5564501 Strattan et al. Oct 1996
Foreign Referenced Citations (1)
Number Date Country
2 289 488 Nov 1995 GB