In many well applications, packers are used to seal off sections of a wellbore. The packers are delivered downhole via a well string and then set against the surrounding wellbore surface to provide annular barriers between the adjacent uphole and downhole sections of wellbore. In various applications, each packer comprises an elastomeric element which may be expanded radially into sealing engagement with the surrounding borehole surface. Additionally, some applications utilize an expandable metal packer or packers mounted along a base pipe of the well string. Such expandable metal packers use a deformable metal membrane which is deformed permanently by the pressure of inflating fluid. However, the coupling between the packer and the base pipe may be susceptible to undesirable sliding or rotation of the packer with respect to the base pipe.
In general, a system and methodology are provided for utilizing a packer in a borehole or within other tubular structures. The packer may be constructed for mounting about a generally tubular base pipe. The packer generally comprises a metal sleeve combined with extremities located at each axial end of the metal sleeve. The metal sleeve maintains a seal once expanded to a surrounding wellbore wall, e.g. a casing wall. For example, the metal sleeve may be combined with an elastomer along its exterior, the elastomer sealing against the surrounding wellbore wall when the metal sleeve is radially expanded. Additionally, an anchoring system is disposed within one or both of the extremities and oriented for engagement with the tubular base pipe so as to act against rotation and sliding of the packer with respect to the tubular base pipe.
However, many modifications are possible without materially departing from the teachings of this disclosure. Accordingly, such modifications are intended to be included within the scope of this disclosure as defined in the claims.
Certain embodiments of the disclosure will hereafter be described with reference to the accompanying drawings, wherein like reference numerals denote like elements. It should be understood, however, that the accompanying figures illustrate the various implementations described herein and are not meant to limit the scope of various technologies described herein, and:
In the following description, numerous details are set forth to provide an understanding of some embodiments of the present disclosure. However, it will be understood by those of ordinary skill in the art that the system and/or methodology may be practiced without these details and that numerous variations or modifications from the described embodiments may be possible.
The disclosure herein generally involves a system and methodology for utilizing a packer in a borehole or within other tubular structures. For example, one or more of the packers may be deployed downhole into a wellbore via a well string. The packer or packers may then be actuated to a set position to form a seal with the surrounding wellbore surface, e.g. an interior casing surface or an open hole surface, and to isolate sections of the annulus along the well string.
By way of example, the packer may be an expandable metal packer constructed with a metal sealing element. The metal sealing element may be mounted around a base pipe which may be part of a well string, e.g. a drilling string, or other tubing string. When the packer is positioned at a desired location within the borehole or other tubular structure, the metal sealing element may be expanded under fluid pressure for sealing engagement with a surrounding wall surface. For example, the metal sealing element may be a permanently deformable metal bladder, e.g. a metal membrane, which is deformed downhole via the fluid pressure, e.g. hydroforming.
According to an embodiment, a system and methodology are provided for utilizing a packer in a borehole or within other tubular structures. The packer may be constructed for mounting about a generally tubular base pipe. In general, the packer comprises a metal sleeve combined with extremities located at each axial end of the metal sleeve. The metal sleeve maintains a seal once expanded to a surrounding wellbore wall, e.g. a casing wall. For example, the metal sleeve may be combined with an elastomer along its exterior. The elastomer may be a single piece or a plurality of pieces positioned to seal against the surrounding wellbore wall when the metal sleeve is radially expanded. Additionally, an anchoring system is disposed within one or both of the extremities and oriented for engagement with the tubular base pipe so as to act against rotation and sliding of the packer with respect to the tubular base pipe.
As described in greater detail below, the packer may be fixed in both axial and rotational directions on a variety of tubular base pipes. The anchoring system enables the packer to hold against high torque that may occur between the packer and the base pipe. Consequently, the packer may be used in various types of well applications which can incur torque loads. An example of a suitable application is a casing while drilling application. In such an application, the packer or packers may be mounted as part of a drill string to perform a stage cementing operation.
Referring generally to
The expandable metal sleeve 40 is disposed between extremities 44. For example, the extremities 44 may be coupled with the expandable metal sleeve 40 and positioned with one extremity 44 on each axial end of the expandable metal sleeve 40. Each extremity 44 may comprise a metal collar 46 positioned around the base pipe 36. During mounting of packer 34 along tubing string 38, the metal collars 46 may be plastically deformed, e.g. crimped, to secure the packer 34 to the base pipe 36.
The packer 34 further comprises an anchoring system 48 positioned between at least one of the extremities 44 and the base pipe 36 to prevent both axial sliding and rotation of the expandable metal packer 34 relative to the base pipe 36. In the example illustrated, the anchoring system 48 operates between each of the extremities 44 and the base pipe 36. As described in greater detail below, the anchoring system 48 may utilize various features to create interference between the packer 34 and the base pipe 36 so as to prevent relative rotation even under high torque loads.
Depending on the application, the expandable metal sleeve 40 may comprise a metal membrane, e.g. a bladder, or other metal structure which may be plastically deformed into a permanent expanded structure engaging the surrounding wall surface 42. In some embodiments, the metal sleeve 40 is expanded via fluid pressure, e.g. via a hydroforming process. For example, high pressure fluid may be delivered along an interior of tubing string 38 and directed into an interior of the expandable metal sleeve 40 via a passage or passages extending through a wall of base pipe 36.
Referring generally to
The axial mechanism 50 comprises at least one axial movement prevention ring 54, e.g. a plurality of rings 54. The rings 54 may be located in corresponding grooves 56 formed in collar 46 of the corresponding extremity 44. It should be noted the axial mechanism 50 and rotational mechanism 52 may be employed in each of the extremities 44.
As illustrated in
With additional reference to
When a torque, as represented by arrow 68, is applied to the base pipe 36, the corresponding curved side 66 of each pad 60 wedges against the corresponding curved side of recess 62 to create a load as represented by arrows 70 (load side depends on the direction of the applied torque). The pads 60 effectively create interference via the wedge effect to prevent rotational motion of the packer 34 with respect to the base pipe 36.
When packer 34 is mounted to base pipe 36 at a desired location, the collars 46 may initially be in an expanded configuration, as illustrated in
According to another embodiment, additional recesses 74 also may be formed in base pipe 36 as illustrated in
Referring generally to
By way of example, each wedge member 76 may have a cross-sectional shape with a hump or curved portion 78 received in a corresponding recess 80 formed in the interior surface of the corresponding collar 46. Additionally, the interior of each wedge member 76 may comprise gripping features 82 oriented to grip into base pipe 36 once the collar 46 is suitably plastically deformed in a radially inward direction. Similar to other embodiments described herein, the wedge members 76 create an interference between the base pipe 36 and the packer 34. However, the orientation of wedge members 76 serve to create interference in both axial and rotational directions.
Referring generally to
The annular ring 84 may extend circumferentially along the corresponding recess 88, e.g. groove, formed along a portion of the interior of the corresponding collar 46. The annular ring 84 also comprises ends 92. The ring ends 92 are located adjacent interference portions 94 of collar 46 at the ends of recess 88 to prevent movement of annular ring 84 along the recess/groove 88 (see
Furthermore, once the collar 46 is suitably plastically deformed in the radially inward direction, the ring ends 92 of split annular ring 84 prevent relative rotation of the packer 34 with respect to the base pipe 36 via interfering engagement with interference members 94 (as the base pipe 36 is gripped via gripping features 90). In this manner, the annular ring 84 serves as both the axial mechanism 50 and rotational mechanism 52.
Referring generally to
Additionally, the interior of waved annular ring 96 may comprise gripping features 106 oriented to grip into base pipe 36 once the collar 46 is suitably plastically deformed in a radially inward direction. The waved annular ring 96 may extend circumferentially along the corresponding recess 100 formed in the interior of the corresponding collar 46. For example, the waved annular ring 96 may extend circumferentially along a portion of the interior of the corresponding collar 46 between ring ends 108, as illustrated in
When the collar 46 of the corresponding extremity 44 is crimped radially inward into engagement with base pipe 36, the gripping features 106 engage base pipe 36 and cooperate with the hump or curved portion 98 to prevent sliding axial movement of the packer 34 with respect to the base pipe 36. Once the collar 46 is suitably plastically deformed in the radially inward direction, the gripping features 106 and the larger humps of axially wide sections 102 prevent relative rotation of the packer 34 with respect to the base pipe 36. In other words, the larger humps of axially wide sections 102 create an interfering engagement with the corresponding collar 46 to prevent rotation of the collar 46 (thus preventing rotation of the packer 34) with respect to the base pipe 36. In this manner, the waved annular ring 96 effectively serves as the axial mechanism 50 and the rotational mechanism 52.
Referring generally to
The dome-shaped members 110 each have a gripping side with rotational gripping features 114 oriented toward base pipe 36 for engagement with base pipe 36 when the corresponding collar 46 is plastically deformed in an inward direction. Each dome-shaped member 110 also has a curved side 116, e.g. domed side, disposed in the corresponding recess 112 and oriented against the corresponding collar 46/extremity 44. Placement of dome-shaped members 110 in corresponding recesses 112 effectively creates interference between the base pipe 36 and the collar 46/packer 34 in both an axial direction and a rotational direction. As illustrated, a retention member 118, e.g. a spring or a split ring, may be used to initially maintain the dome-shaped members 110 in their corresponding recesses 112 prior to the plastic deformation.
When the collar 46 of the corresponding extremity 44 is crimped radially inward into engagement with base pipe 36, the gripping features 114 of each dome-shaped member 110 engage base pipe 36 and cooperate with the domed side 116 to prevent sliding axial movement of the packer 34 with respect to the base pipe 36. Furthermore, once the collar 46 is suitably plastically deformed in the radially inward direction, the gripping features 114 and the domed side 116 also prevent relative rotation of the packer 34 with respect to the base pipe 36. In other words, the dome-shaped members 110 create an interfering engagement with the corresponding collar 46 to prevent rotation of the collar 46 and overall packer 34 with respect to the base pipe 36. In this manner, the dome-shaped members 110 serve as both the axial mechanism 50 and the rotational mechanism 52.
Depending on the characteristics of a given application and environment, well system 30 may have many types of configurations. For example, the well system 30 may utilize tubing string 38 in the form of a casing while drilling string or other suitable tubing string used in high torque load applications. Additionally, the expandable metal packer 34 may be employed as an isolation device in a variety of operations and environments which may be subjected to high differential pressures. For example, the expandable metal packer 34 may be used in well applications and in other applications in which isolation between sections of a tubular structure is desired. The expandable metal packer 34 may be constructed with various types and sizes of expandable metal sleeves 40 depending on the parameters of a given operation. In a variety of well applications, the expandable metal sleeve 40 may be formed from a plastically deformable metal membrane, bladder, or other metal structure which may be radially expanded via fluid pressure.
Similarly, the anchoring system 48 may have various configurations and may be located between one of the extremities 44 and the base pipe 36 or between both extremities 44 and the base pipe 36. Additionally, the expandable metal sleeve 40 may be secured to extremities 44 via a variety of techniques, including threaded engagement, welding, combined seals and fasteners, crimping, and/or other suitable coupling techniques. The anchoring system 48 also may utilize features of various sizes and configurations to create interference between the packer 34 and the base pipe 36 so as to prevent relative rotation of the packer 34 with respect to the base pipe 36.
Although a few embodiments of the disclosure have been described in detail above, those of ordinary skill in the art will readily appreciate that many modifications are possible without materially departing from the teachings of this disclosure. Accordingly, such modifications are intended to be included within the scope of this disclosure as defined in the claims.
Number | Date | Country | Kind |
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19305084.6 | Jan 2019 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/051609 | 1/23/2020 | WO | 00 |