The present invention relates to a system for lining a section of a wellbore with an expandable tubular element, whereby an elongate string extends into the wellbore. An example of such string is a drill string used to drill wellbore. During conventional wellbore drilling sections of the wellbore are drilled and provided with a casing or a liner in subsequent steps. In each step, the drill string is lowered through the casings already installed in the wellbore, and a new section is drilled below the installed casings. By virtue of this procedure, casing which is to be installed in the newly drilled section has to pass through earlier installed casing, therefore the new casing must be of smaller outer diameter than the inner diameter of the earlier installed casing. As a result the available diameter of the wellbore becomes smaller with depth. For deep wells, this consequence can lead to impractically small diameters. In the description below, references to “casing” and “liner” are made without an implied difference between such types of tubulars. Similarly, references to “lining” can be understood to mean: providing a liner or a casing in the wellbore.
It has been proposed to overcome the problem of stepwise smaller inner diameters of wellbore casing by installing a tubular element in a wellbore and thereafter radially expanding the tubular element to a larger diameter by means of an expander which is pulled, pushed or pumped through the tubular element. However, such method requires that the drill string is to be removed from the wellbore each time a new expandable tubular element is installed in the wellbore.
It is an object of the invention to provide an improved system for lining a section of a wellbore with an expandable tubular element, which overcomes the problems of the prior art.
In accordance with the invention there is provided a system for lining a section of a wellbore with an expandable tubular element, comprising an elongate string extending into the wellbore, said string being provided with the tubular element in the unexpanded form thereof whereby the tubular element surrounds a lower portion of the string, the string further being provided with an expander arranged at a lower end part of the tubular element and anchoring means for anchoring an upper end part of the tubular element in the wellbore.
In use the expandable tubular element (e.g. a liner or a casing section) is initially supported on the drill string, and at the desired depth expanded against the borehole wall for its permanent installation in the wellbore by first anchoring the upper end part against the inside of the existing casing, wellbore wall or other tubular element, and then pulling the expander upwards through the tubular element. Thereafter the drill string can be retrieved to surface completely. By this method the drill string with the expandable tubular element thereon can be operated to drill the wellbore like is normally done when drilling wells in the ground without having less strength. In the unexpanded state of the expandable tubular element the entire drill string can be pulled to surface to exchange worn parts, should this become necessary. The method can be repeated to drill another new hole section below the previously expanded tubular element. The expanded element may be additionally sealed inside the borehole by pumping a hardening fluid into any remaining annular space between the expanded element and the borehole wall.
The invention will be described hereinafter in more detail and by way of example with reference to the accompanying drawings in which:
For the purpose of simplicity, in
In the Figures, like reference numerals relate to like components.
In
Referring further to
The expansion cone 22 is at its inner surface provided with a ring 34 arranged in an annular recess 36 of the cone 22 in a manner that the ring is axially slideable in the annular recess 36. As is evident from
Referring is further made to
The two members 44, 46 are locked to each other by a locking ring 58 which is arranged in an annular recess 60 of the lower member 46, and which extends into an annular recess 62 of the upper member 44 so as to transmit axial loads between the two members 44,46. The locking ring 58 is spring loaded so as to retract fully into the annular recess 60 when released. A split seating ring 64 is arranged in the lower member 46 at the level of the annular recess 60 so as to close-off the recess 60, the seat ring 64 being axially slideable relative to lower member 46. The portion of the recess 60 between the seat ring 64 and the locking ring 58 is filled wit an incompressible fluid. A stop ring 65 is fixedly connected to the inner surface of the lower member 46, a suitable distance below the annular recess 60.
Referring further to
During normal operation the new open hole section 6 is drilled below casing 4, whereby the drill string 1 is lowered through the casing 4. The bi-centred drill bit 16 drills the new borehole section 6 to a diameter which is about equal to the diameter of the upper borehole section 2. During drilling a stream of drilling fluid is pumped through the interior passage 50 of the drill string 1. After section 6 has been drilled, the drill string 1 is positioned such that an upper end portion of the liner 12 is located inside the casing 4. Subsequently the closing plug 40 is pumped together with the stream of drilling fluid into the drill string 1 until the plug 40 becomes seated on the seating ring 64. Thereby the closing plug 40 blocks the fluid passage 50, and continued pumping of fluid into the drill string 1 causes the seat ring 64 to slide downwards against the stop ring 65. Through this movement the openings 52 become unsealed and the uncompressible medium is pushed out by the locking ring 58 which fully retracts into the annular recess 60. Thus, the upper member 44 becomes unlocked from the lower member 46.
Drilling fluid which enters the fluid chamber 82 via openings 52 and fluid passages 49 causes the fluid chamber 82 to act as a hydraulic piston/cylinder assembly whereby the upper member 44 is pushed upwardly relatively the lower member 46. The mandrel 66 is thereby subjected to an upward force at its lower tapering surface 72 from the upper member 44, and to a downward reaction force at its upper tapering surface 71 from spring device 80. As a result the mandrel segments 68 are pushed radially outward so that the mandrel 66 moves to its radially expanded mode (
Next, the closing plug 40 is released from the seating ring 64 by applying increased pumping pressure so that stop ring 65 breaks and the seating ring 64 is allowed to slide further downwards into an axial position where it can expand to a larger diameter. The closing plug 40 is pumped further down the drill string 1 until it seats on landing profile 38 of ring 34. Continued pumping of drilling fluid through the drill string 1 causes the ring 34 to slide downwards in annular recess 36, and thereby causes the holding blocks 24 to radially retract. In this manner the expansion cone 22 becomes released from the liner 12.
In a next step the drill string 1 with the expansion cone 22 is pulled upwards through the liner 12 whereby the liner 12 is restrained against axial movement by virtue of its anchored upper end part. By pulling the expansion cone 22 through the liner 12, the liner 12 is expanded to an outer diameter almost equal to the diameter of the wellbore 2.
The wall thickness of the upper end of liner 12 can be different, especially smaller, from the wall thickness of the remainder of the liner 12 to reduce the force required to expand the liner.
Instead of a bi-centred drill bit, an underreamer or an expandable bit can be used.
The expandable tubular liner can have a predetermined length which is longer than the initially planned newly drilled hole section such that there is an overlap with the existing casing. The expandable liner can be installed at any other intermediate depth should this become necessary.
The expandable liner may contain preformed holes which are closed in the unexpanded stage and which open up during expansion to allow pumping of a hardening fluid into the annular space between the expanded liner and the borehole wall.
Instead of applying the spring device 80 to provide a downward reaction force to the second annular actuator 78 in response to upward movement of the upper member 44 against the mandrel 66, a hydraulic piston/cylinder assembly can be applied to provide a downward reaction force to the second annular actuator 78. Such piston/cylinder assembly is suitably powered by hydraulic fluid pressure from fluid present in the interior 50 of the drill string 1.
Number | Date | Country | Kind |
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01204032.5 | Oct 2001 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP02/11900 | 10/23/2002 | WO | 7/6/2004 |