BR102017002467A2 - CUSHION RETAINING SYSTEM FOR C-RINGS COMPLETELY SUSTAINED - Google Patents

Description

Report of the Invention Patent for "FULLY SUSTAINED C-RING serrated wedge retention system".

TECHNICAL FIELD

[001] The present invention relates generally to sealing lining supports and more particularly to a fully supported C-ring serrated wedge retention system for use in a sealing lining support.

BACKGROUND

When drilling a well, a hole is typically drilled into the earth's surface to a selected depth and a casing column is suspended and then cemented into place within the hole. A drill bit is then passed through the initial coated hole and is used to drill a smaller diameter hole to an even greater depth. A smaller diameter casing is then suspended and cemented into place within the new hole. This is conventionally repeated until several concentric columns are suspended and cemented into the well to a depth that extends the well through one or more hydrocarbon production formations.

Instead of suspending a concentric liner from the bottom of the hole to the surface, a sealing liner is often suspended adjacent to the lower end of the previously suspended liner, and from a previously cemented suspended liner so as to extend the seal liner from the pre-fixed liner or seal liner to the bottom of the new hole. A seal coating is defined as a coating that does not move to the surface. A seal liner support is used to suspend the seal liner within the lower end of the prefixed liner or liner.

A displacement and clamping tool disposed at the lower end of a work column can be releasably attached to the seal liner support, which is fixed to the top of the seal liner. The working column lowers the sealing liner support and sealing liner into the open hole until the sealing liner bracket is adjacent to the lower end of the pre-attached liner or sealing liner, with the lower end of the sealing liner typically slightly above the bottom of the open hole. When the sealing liner reaches the desired location with respect to the bottom of the open hole and the pre-fixed liner or sealing liner, a clamping mechanism is conventionally actuated to grind an anchor element (e.g., serrated wedges) into the sealing liner bracket. a compressed position into an expanded position and in engagement with the pre-fixed liner or seal liner. Thereafter, when a pre-set weight is applied to the anchor body, the anchor member is fixed to support the seal liner.

The sealing liner support anchor may include a radially expandable and contractable C-ring with serrated wedge teeth formed around its outer and inner edge and a tapered tapered surface to support the liner within the pre-fixed coating or seal coating. Typically, the serrated C-ring wedge (or anchor body) is held in a compressed position within a recess of the seal liner body while the seal liner is lowered through the hole. The serrated C-ring wedge is then moved out of the recess in the body of the sealing liner support and in its expanded position.

Unfortunately, the serrated C-ring wedge sometimes becomes dislodged from the recess in the sealing liner support body while the sealing liner support is being lowered through the hole, thereby unintentionally expanding the anchor element. before the seal liner bracket is ready to be fixed. This premature expansion of the anchor element may cause undesirable delays as the seal liner mounting assembly must be removed from the well and the anchor element readjusted.

BRIEF DESCRIPTION OF DRAWINGS

For a more complete understanding of the present invention and its aspects and advantages, reference is now made to the following description, taken in conjunction with the accompanying drawings, in which: Figure 1 is a cut-away view of a mounting assembly. sealing liner having a fully sustained C-ring serrated wedge retained in a locked position according to an embodiment of the present invention;

Fig. 2 is a sectional view of a serrated wedge retention system used in the sealing liner assembly of Fig. 1 according to an embodiment of the present invention;

Fig. 3 is a radial cross-sectional view of the serrated wedge retention system of the sealing liner support assembly of Fig. 1, according to one embodiment of the present invention;

Fig. 4 is a radial cross-sectional view of a support sleeve held within a body of the sealing liner support assembly of Fig. 1 according to an embodiment of the present invention;

Figure 5 is a perspective view of an anti-rotation feature where the finger of the support sleeve extends through a T-slot in the serrated wedge of the C-ring of the sealing liner support assembly of Figure 1, according to one embodiment of the present invention;

Fig. 6 is a perspective view of certain components of the sealing liner support assembly of Fig. 1 in an offset position according to an embodiment of the present invention;

Fig. 7 is a perspective view of a certain component of the sealing liner support assembly of Fig. 1 in an unlocked position according to an embodiment of the present invention;

Figure 8 is a sectional view of the serrated wedge retention system of the figure being unlocked according to an embodiment of the present invention;

Fig. 9 is a sectional view of the serrated wedge retention system of Fig. 1 with the serrated C-ring wedge being compressed according to one embodiment of the present invention; and Figure 10 is a sectional view of the serrated wedge retention system of Figure 1 with the serrated C-ring wedge being extracted in accordance with one embodiment of the present invention. DETAILED DESCRIPTION

Illustrative embodiments of the present invention are described in detail herein. For the sake of clarity, not all aspects of an actual implementation are described in this report. Of course, it will be appreciated that in developing any such real modality, numerous implementation-specific decisions must be made to achieve developer-specific goals, such as compliance with system-related and business-related constraints, which will vary from implementation to implementation. . Furthermore, it will be appreciated that such a development effort could be complex and time consuming, but nevertheless would be a routine undertaking for those skilled in the art having the benefit of the present invention. Moreover, by no means should the following examples be read to limit or define the scope of the invention.

Certain embodiments in accordance with the present invention may be directed to a sealing liner support with a fully supported C-ring serrated wedge retention system and associated method for retaining and extracting the C-ring serrated wedge for securing the seal liner support.

Seal casing holders typically retain a serrated C-ring wedge in a compressed position under an edge of the seal casing support body as the seal casing is being lowered to the bottom of the well. Once the sealing liner support reaches a desired location within a pre-fixed liner or sealing liner, existing systems often use tie rods to remove the serrated C-ring wedge from the lip to secure the sealing liner bracket. Unfortunately, such tie rods are susceptible to deformation failure modes when impact forces act on the C-ring knurled wedge. In addition, the C-ring knurled wedge can sometimes become dislodged from the lip in the support bracket. sealing liner while the sealing liner support is being lowered through the hole, thereby prematurely and unintentionally releasing the serrated wedge or anchor element.

The embodiments described address the shortcomings of prior seal coating support designs by providing an improved C-ring serrated wedge retention system, which allows for a "fully sustained C-ring serrated wedge". The C-ring serrated wedge retention system may use an axially movable support sleeve with a support ring to secure the C-ring serrated wedge against a sealing lining support body retaining lip. In some embodiments, the sealing liner support body and C-ring serrated wedge may be constructed with specifically keyed profiles that allow tight fitting and distribution of impact forces from the C-ring serrated wedge to the rest of the C-ring serrated support. sealant coating. The described restraint system also prevents the serrated C-ring wedge from prematurely dislodging the sealing liner support body while the sealing liner support is being lowered through a hole.

The C-ring serrated wedge retention system may also include anti-rotation features that prevent the C-ring serrated wedge from rotating with respect to the sealing liner support body. Such anti-rotation features may include support sleeve bosses designed to engage corresponding slots formed in the C-ring serrated wedge to eliminate or minimize rotation of the C-ring serrated wedge.

In the sealing lining support system and method, the support sleeve may be axially displaced to extract the serrated C-ring wedge from the sealing coating body, allowing the serrated C-ring wedge to expand. and secure the seal liner bracket. Such actuation of the support sleeve in the axial direction can simultaneously unlock the serrated C-ring wedge from its position within the retaining lip and disengage anti-rotation features. In some embodiments, extracting the serrated C-ring wedge from the retaining lip may involve moving the support ring relative to the serrated C-ring wedge to allow the serrated C-ring wedge to compress and move beyond the locking profile. on the retaining lip. In certain embodiments, disengaging the anti-rotation features may involve axially moving the support sleeve such that the anti-rotation shoulders on the support sleeve are withdrawn from the corresponding slot walls and into expanded portions of the slots.

The described C-ring serrated wedge retention system and method for extracting the C-ring serrated wedge may facilitate a more secure sealing liner support that prevents release of the serrated wedge or anchor element. The retention system and anti-rotation features keep the serrated C-ring wedge in a desired axial, radial and angular position prior to extraction. The system allows for the effective transfer of large axial / radial forces and torques that could act on the C-ring serrated wedge while the sealing liner support is being lowered into the deep end while facilitating the extraction of the C-ring serrated wedge by by applying a relatively small acting force.

Turning now to the drawings, Figure 1 is a sectional view of a sealing liner support 10 having a fully supported serrated C-ring wedge according to one embodiment of the present invention. The sealing liner support 10 includes a sealing liner support body 12 and an improved C-ring serrated wedge retention system 14 for retaining a C-ring serrated wedge 16 in a locked / compressed position within the holder. It is desirable to keep the serrated C-ring wedge 16 in this locked / depressed position while the sealing liner holder 10 is being lowered a hole to prevent premature attachment of the sealing liner holder 10. The wedge C-ring serrated 16 is a radially expandable and contractable C-ring having serrated wedge teeth 18 formed around its outer edge and its inner edge, and a tapered tapered surface 20 to support the sealing liner support 10 within a pre-fixed liner or seal liner (not shown). As described in detail below, sealing liner bracket 10 may also include anti-rotation features to prevent rotation of the C-ring serrated wedge 16 about a longitudinal axis 22 of sealing liner bracket 10 while the serrated ring-ring wedge C 16 is arranged in the locked position.

In the embodiment illustrated, the C-ring serrated wedge retention system 14 may include a retaining lip 24 formed on the sealing liner support body 12, a support sleeve 26, and a support ring 28. O retaining lip 24 is a lip formed around the sealing liner support body 12, and the lip 24 extends in a direction parallel to the longitudinal axis of the seal liner support 22. The retaining lip 24 defines a cavity between the lip 24 and the rest of the seal liner support body 12 for receiving and maintaining the serrated C-ring wedge 16 when the serrated C-ring wedge 16 is in a compressed state. The support sleeve 26 may include one or more glove parts which are disposed within the seal liner support body 12 and axially movable with respect to the support liner and seal liner 12. The support ring 28 is a ring disposed around of the support sleeve 26.

A more detailed view of the C-14 serrated wedge retention system is illustrated in Figure 2. The illustrated C-14 serrated wedge retention system may be a two-part serrated wedge retention system. . The first part of the C-ring serrated wedge retention system 14 is the interface between the C-ring serrated wedge 16 and the retaining lip 24. Specifically, the C-ring serrated wedge 16 may include a profile. 50 facing an inner wall 54 of the retaining lip 24. The inner wall 54 of the retaining lip 24 may include a complementary profile 56 for receiving the C-ring serrated wedge profile 50 and thereby retaining the serrated ring wedge at C 16 and the retaining lip 24.

The second part of the C-ring serrated wedge retention system 14 is the support ring 28 disposed against an inner surface 58 of the C-ring serrated wedge 16. The support ring 28 may orient the serrated wedge of C-ring 16 radially outwards and in a secure engagement (by means of locking profiles 50 and 56) with the inner wall 54 of the retaining lip 24.

In the illustrated embodiment, the retaining profile 50 of the C-ring serrated wedge 16 may include two shoulders 60, and the complementary profile 56 in the retaining lip 24 may be sized to receive corresponding shoulders 60 when the retaining system C-ring serrated wedge ring 14 is locked. As illustrated, the two shoulders 60 may have different widths from one another. These "widths" may be measured in a direction parallel to the longitudinal axis 22 of the sealing liner support 10. For example, a first (front) shoulder 60A disposed closer to the extended edge of the retaining lip 24 may have a width of less than one. second (rear) shoulder 60B located farthest from the extended edge of the retaining lip 24. This arrangement may prevent the rear shoulder 60B from being caught in the portion of the retaining shoulder profile 56 sized to interface with the smaller front shoulder 60A when the serrated C-ring wedge 16 is withdrawn from the retaining lip 24. In other embodiments, the two shoulders 60 may have different heights for similar effect.

Although two shoulders 60 are illustrated in Figure 2, in other embodiments the mutual locking profiles 50 and 56 may include any suitable number of shoulders 60. In still other embodiments, the profiles 50 and 56 may include any desirable type and number. of keyed features that create a precision fit between the outer edge 52 of the C-ring serrated wedge 16 and the inner wall 54 of the retaining lip 24.

The shoulders 60 may encompass the circumference of the C 16 ring serrated wedge to provide a relatively large area of interference between the C 16 ring serrated wedge and retaining lip 24. In some embodiments, such as shown in figure 6, for example, front shoulder 60A may span nearly 360 degrees around the serrated C-ring wedge 16 (except in the C-ring range). The rear shoulder 60B, as shown in Figure 6, may be separated by T-slots 112 periodically disposed around the circumference of the serrated C-ring wedge 16.

Turning to Figure 2, the serrated C-ring wedge 16 is generally supported from below by the support ring 28, which guides the serrated C-ring wedge 16 in engagement with the retaining lip profile 56 24. The support ring 28 may be axially held in place by the support sleeve 26 with respect to the longitudinal geometric axis 22 of the sealing liner support 10. This arrangement allows the serrated wedge of the outwardly oriented C-ring 16 to be locked. mechanically in place against retaining lip 24 with full circumferential contact on the shoulders 60.

The C-ring serrated wedge retention system 14 may prevent the C-ring serrated wedge 16 from being pulled out of the retaining lip 24, for example, if debris is trapped at the outer edge (e.g. for example, serrated wedge teeth 18) of the C-ring serrated wedge 16 while sealing liner support 10 is being lowered through a hole. If an impact force acts on the serrated wedge of the C-16 ring (eg in direction 62), the force would be transmitted to the retaining lip 24 by means of keyed locking profiles 50 and 56. Axial force 62 can then be converted to a radial load on the support ring 28 and a stress load on the sealing liner support body 12. This force transfer within the serrated C-ring wedge retention system 14 may prevent premature release of the wedge. serrated C-ring 16 of retaining lip 24. It should be noted that the serrated wedge retention system described 14 does not use tie rods as conventional sealing liner supports. Therefore, the serrated wedge retention system 14 eliminates deformation as a failure mode allowing axial impact force 62 to be converted to radial force that is transmitted in the sealing liner support body 12 by means of the support ring 28.

Figure 3 is a radial cross-sectional view of the serrated wedge retention system 14, taken through the axial location of the support ring 28. In the illustrated embodiment, the serrated wedge retention system 14 is in the locked position. compressed to hold the serrated wedge of the C-ring 16 within the retaining lip 24. As shown, the support ring 28 is disposed against the serrated wedge of the C-ring 16 and guides the serrated wedge of the C-ring 16 against the flange. retainer 24. The support sleeve 26 may include a number of support sleeve fingers 26A-E disposed about a circumference of the seal liner support body 12.

[0035] Figure 4 is another radial cross-sectional view of the sealing liner support 10 taken at an axial position away from the serrated wedge retention system 14. In this position of the sealing liner support 10, the fingers of the glove 26A-E may extend through dovetail slots 90 formed in the seal liner support body 12. The dovetail slots 90 may prevent the support sleeve 26 from deforming and help resist twisting of the mounting sleeve. support 26 preventing rotational movement of the support sleeve with respect to the seal liner support body 12.

Turning to Figure 3, the support ring 28 may be disposed around and coupled to the support sleeve parts 26, as shown. By arranging the support ring 28 around the support sleeve portions 26, the system allows for a relatively easy installation method for the seal liner support 10. That is, the fingers of the sleeve 26A-E may be individually disposed through cavities. (e.g., dovetail slots 90) in the sealing liner support body 12, and the support ring 28 may be fitted around the support sleeve 26. The support ring 28 may hold the support sleeve parts 26 joints (for example as a single unit) and provide a circumferential interface between the support sleeve 26 and the serrated C-ring wedge 16.

As mentioned above, the described C-ring serrated wedge retention system 14 may include anti-rotation features that substantially prevent the C-ring serrated wedge 16 from rotating with respect to the longitudinal axis of the sealing liner support while the support of sealing coating is moving into a hole. Such anti-rotation features may be particularly suitable for use in "compact" seal coating supports. However, other conventional size seal coating supports may benefit from anti-rotation features as well.

Fig. 5 illustrates an embodiment of anti-rotation features 110 that may be used to prevent rotation of the serrated C-ring wedge 16 relative to the sealing liner support body 12. Anti-rotation features 110 may include a slot T-112 formed on the serrated wedge of the C-ring 16 and a corresponding anti-rotation portion 114 of the support sleeve 26. The anti-rotation part 114 of the support sleeve 26 may be positioned within the T-slot 112 of the serrated C-ring wedge 16 to minimize rotation of the C-ring serrated wedge 16 with respect to the support sleeve 26 (and, consequently, in the seal liner support body 12 due to the fingers of the support sleeve 26 in the dovetail slots 90) prior to extraction C-ring serrated wedge 16 of retaining lip 24.

To this end, the serrated C-ring wedge 16 and the anti-rotation portion 114 of the support sleeve 26 may include anti-rotation shoulders 116 as shown. The serrated wedge of the C-ring 16 may include opposite anti-rotation shoulders 116 on opposite sides (or walls) of the T-slot 112, while anti-rotation sleeve portion 114 may include anti-rotation shoulders 116 on opposite edges thereof to interface with anti-rotation shoulders. 116 of the T-slot 112.

Any torsional load (for example, in a rotational direction 118) imparted to the serrated C-ring wedge 16 may be transmitted via the anti-rotation shoulders 116 on the support sleeve 26 and the dovetail slots 90 of the sealing liner support 12 thereby preventing further rotation of the C-ring serrated wedge 16. In this manner, anti-rotation features 110 substantially prevent rotation of the C-ring serrated wedge 16 with respect to support sleeve 26. Anti-rotation features 110 can only allow minimal rotation of the serrated wedge of the C-ring 16 (i.e. just enough for the anti-rotation shoulder 116 of the T-slot 112 to engage the shoulder 116 of the anti-rotation sleeve portion 114).

Figures 6 and 7 illustrate a more detailed view of the support sleeve 26, the support ring 28, and the serrated C-ring wedge 16 of the serrated C-ring wedge retention system 14 having anti-rotation features. 110 described above. Anti-rotation features 110 may include five T-slots 112 which are strategically machined at one end 130 (facing the opposite side of the serrated wedge teeth 18) of the C-ring serrated wedge 16. T-slots 112 may be mounted on together with the five fingers of the corresponding support sleeve 26A-E forming the support sleeve 26. In other embodiments, different numbers (e.g. 1, 2, 3, 4, 6, 7, 8, 9, or more) T-slots 112 and corresponding support sleeve fingers may be used within the system to prevent rotation of the C-ring serrated wedge 16 while the serrated wedge retention system 14 is locked.

In Figure 6, components of the serrated wedge retention system are shown in the "locked / compressed" position (i.e. to retain the serrated C-ring wedge 16 within the retaining lip). In general, sealing liner support 10 may be lowered into a hole in this locked / compressed position, so that no external force acting on the serrated wedge of the C 16 ring leads to premature extraction of the serrated wedge of the C 16 ring.

While sealing liner bracket 10 is being moved downhole in the locked position, any torsional loads (eg rotational impact forces) acting on the serrated wedge of the C 16 ring can be easily transmitted through the support sleeve 26 for large seal liner support body 12. Specifically, a rotational impact force applied to the serrated wedge of the C-ring 16 may be transferred from the serrated wedge of the C-ring 16 to the anti-rotation portion 114 of the sleeve. 26 by means of the flat anti-rotation shoulders 116. The support sleeve 26 may be disposed within and connected to the seal liner support body 12 (not shown) through the support sleeve fingers 26A-E extending into the tail slits. dovetail (90 of FIG. 3) of the seal liner support body 12. The dovetail slots 90 work together to reinforce the support sleeve fingers 26A-E and provide give a reaction force commensurate with the rotational impact transferred from the serrated C-ring wedge 16.

The support sleeve 26 may also transmit rotational impact forces from the serrated C-ring wedge 16 to the sealing liner support body 12 via one or more prongs 132. As illustrated, each support sleeve portion 26 may include a spike 132 extending longitudinally from the anti-rotation portion 114 of the support sleeve 26. As shown in figures 8-10, the sealing liner support body 12 may include elongated slots 134 formed therethrough for receiving and securing the members. Seals 132. The sealing lining support 10 may be constructed such that the lugs 132 are held at least partially within the elongated slots 134 of the sealing lining support body 12 even after the support sleeve is actuated to fully extract the wedge. C-ring serrated 16. In this manner, the support sleeve 26 can be continuously piloted within the seal liner support body 12 when o is actuated axially between the "locked / compressed" position and a serrated wedge extraction position.

A detailed description of the method for unlocking the C-ring serrated wedge retention system described 14 for extracting the C-ring serrated wedge 16 will now be provided. In the locked / compressed position described above with reference to figures 1, 2 and 6, the serrated wedge of the C-ring 16 can be mechanically locked to prevent any radial movement (by means of the serrated wedge retention system 14) as well as any movement. angular (through anti-rotation features 110). It is generally desirable to unlock both locking mechanisms 14 and 110 before releasing the C-ring serrated wedge 16.

[0046] In some embodiments, a hydraulically actuated piston in a sealing liner support displacement tool may axially pull up hole in the support sleeve 26, thereby moving the support sleeve in an axial direction. Actuating the support sleeve 26 in the axial direction may unlock the serrated C-ring wedge retention system 14 and anti-rotation features 110 at approximately the same time. A relatively small amount of force may be applied to actuate the support sleeve 26 to unlock the system. The serrated wedge retention system 14, however, may be capable of imparting a much greater amount of C-ring serrated wedge force 16 to the sealing liner support body 12 when the serrated C-ring wedge 16 is retained. in the locked position.

Figures 8-10 illustrate the support sleeve 26 being used to extract the serrated wedge of the C-ring 16 from the retaining lip 24 of the sealing liner holder 10. As illustrated, the serrated wedge of the C-16 ring may be including a recess 152 for receiving the support ring 28 when the support sleeve 26 is axially moved 150 relative to the serrated wedge of the C-ring 16. The actuation of the support sleeve 26 may remove the support ring 28 in the recess 152 of the C-ring serrated wedge 16. This effectively unlocks the C-ring serrated wedge retention system 14, as the support ring 28 is no longer pushing against and guiding the C-ring serrated wedge 16 in engagement. with the profile on the retaining lip 24. The serrated wedge retention system 14 is shown in the "unlocked" position in figure 8.

Figure 7 illustrates another view of the serrated wedge retaining members shown in the "unlocked" position. As mentioned above, the serrated wedge retention system 14 is moved to this unlocked position by actuating the support sleeve 26 in the axial direction 150 away from the retaining lip 24 (not shown). This actuation of the support sleeve 26 may also unlock the anti-rotation features 110 present within the system. Specifically, the actuation of the support sleeve 26 may remove each anti-rotation part 114 (having anti-rotation shoulders) of the support sleeve 26 in an expanded part 153 of the corresponding T-slot 112. In this manner, actuate the support sleeve 26 in the direction 150 to unlocking the serrated wedge retention system 14 may also unlock the anti-rotation features 110.

Turning now to Figure 8, as the C-ring serrated wedge retention system 14 and anti-rotation features 110 are unlocked, the additional actuation of the support sleeve 26 in direction 150 may compress the serrated wedge of the C-ring 16 for a smaller diameter. The serrated wedge of the C-ring 16 is configured to radially inwardly compress when the support ring 28 is disposed in recess 152. When the support sleeve 26 is further actuated, an angled face (rear angle) 154 in an extraction shoulder of the support sleeve 26 is engaged with a corresponding slanted surface of the serrated C-ring wedge 16. The slanted face 154 may assist in the removal of the serrated C-ring wedge 16 by guiding the compression of the serrated C-ring wedge 16 to a smaller diameter in response to the axial movement of the support sleeve 26.

The serrated wedge retention system 14 is shown in the compressed position in Figure 9. As illustrated, the compression of the serrated C-ring 16 to this smaller diameter disengages the serrated C-ring 16 of the profile. 56 of retaining lip 24. It should be noted that compression of the C-ring serrated wedge 16 may only be possible using the support sleeve 26 since the serrated wedge retention system 14 has been unlocked such that the The serrated wedge of the C-ring 16 is no longer forced against the retaining lip 24 by the support ring 28.

After compressing the serrated C-ring wedge 16, the offset tool can continue the travel of the support sleeve 26 in the axial direction 150 until the serrated C-ring serrated outward wedge 16 has been completely withdrawn from the shoulder. retainer 24 of the sealing liner support body 12. The serrated C-ring wedge 16 is shown in the fully extracted position in Figure 10. Once the serrated C-ring wedge 16 has been fully withdrawn, the serrated ring wedge at C 16 may expand radially outward. This outward expansion allows the serrated wedge teeth 18 to engage with a tapered tapered surface 156 of the sealing liner support body 12 on one side, and with an inside diameter of the liner (or sealing liner) on the other side, thereby securing the seal liner support 10.

The serrated wedge retention system described 14 may provide a mechanical lock for radial deflections as well as anti-rotation features 110 for angular deflections. The system can ensure that any axial impact exerted on the serrated wedge of the C-ring 16 is absorbed by the mutual locking profile at the retaining lip 24 and converted into a radial collapse force that is finally transmitted to the sealing liner support body 12. by means of the support sleeve 26. Torsion loads acting on the serrated wedge of the C-ring 16 can also be transmitted to the sealing liner support body 12 by the anti-rotation aspects 110 (i.e. T-slots 112 and anti-rotation shoulders on the support sleeve 26). Both mechanical locking systems can be deactivated, and the serrated C-ring wedge 16 extracted from the retaining lip 24 by a single axial movement of the support sleeve 26 actuated by, for example, a single hydraulic piston in one direction. seal coating support offset tool. While the present invention and its advantages have been described in detail, it should be understood that various changes, substitutions and changes may be made herein without departing from the spirit and scope of the invention as defined by the following claims.

Claims (20)

1. C-ring serrated wedge retention system, characterized in that it comprises: a serrated C-ring wedge comprising a radially expandable and compressible C-ring; a retaining lip defining a cavity sized to hold the serrated C-ring wedge in a compressed position against an inner wall of the retaining lip; an axially movable support sleeve; and a support ring disposed radially around the support sleeve and disposed in contact with an inner serrated C-ring wedge to guide the serrated C-ring wedge against the inner wall of the retaining lip. C-ring serrated wedge retention system according to claim 1, characterized in that the C-ring serrated wedge comprises a recess along an inner diameter of the C-ring serrated wedge sized to receive the support ring. C-ring serrated wedge retention system according to Claim 1, characterized in that the C-ring serrated wedge comprises a keyed profile, wherein the inner wall of the retaining lip comprises a complementary profile. . C-ring serrated wedge retention system according to Claim 3, characterized in that the keyed profile comprises a first shoulder and a second shoulder extending radially out of the C-ring serrated wedge. that the first and second shoulders have different widths or heights. C-ring serrated wedge retention system according to claim 4, characterized in that the second shoulder is closer to an axial end of the C-ring serrated wedge than the first shoulder, and at that the second cam has a wider width than the first cam. C-ring serrated wedge retention system according to Claim 1, characterized in that the support sleeve comprises an inclined face disposed next to a corresponding inclined face on the C-ring serrated wedge. Knurled C-ring wedge retention system according to claim 1, characterized in that the knurled C-ring wedge comprises a T-slot disposed at one end and the support sleeve comprises a portion of anti-rotation sleeve arranged within the T-slot of the serrated C-ring wedge. Seal coating support system, characterized in that it comprises: a serrated C-ring wedge comprising a radially expandable and compressible C-ring, wherein the serrated C-ring wedge comprises a T-slot formed in a far end; a sealing liner support body comprising a retaining lip defining a cavity sized to retain the serrated C-ring wedge; and an axially movable support sleeve disposed within the sealing liner support body, wherein the support sleeve comprises an anti-rotation sleeve portion, wherein the anti-rotation sleeve portion is disposed within the serrated wedge T-slot of the ring. C to minimize rotation of the serrated C-ring wedge relative to the seal liner support body. Sealing lining support system according to claim 8, characterized in that the serrated C-ring wedge comprises anti-rotation shoulders at opposite walls of the T-slot, and wherein the anti-rotation sleeve portion comprises anti-rotation shoulders. extending to the anti-rotation slits of the T-slot. Sealing lining support system according to claim 9, characterized in that the T-slot comprises an expanded portion at one end of the T-slot adjacent to the walls of the T-slot having the anti-rotation shoulders. Seal cover support system according to Claim 8, characterized in that the support sleeve extends axially through a dovetail slit formed in the seal cover support body. Seal coating support system according to claim 8, characterized in that the support sleeve comprises an axially extending spike portion from the anti-rotation sleeve portion in a spike slot formed in the support body. of seal coating. Sealing liner support system according to claim 8, characterized in that it further comprises a support ring disposed around the support sleeve and disposed in contact with an internal serrated C-ring wedge for orient the serrated C-ring wedge against the inner wall of the retaining lip. A method, characterized in that it comprises: locking a serrated C-ring wedge in an axial position within a retaining lip of a sealing liner support body by means of a support sleeve; minimizing rotation of the serrated C-ring wedge relative to the sealing liner support body by an anti-rotation portion of the support sleeve interfacing with the serrated C-ring wedge; and actuating the support sleeve axially to remove the non-rotating support sleeve portion of a C-ring serrated wedge interface portion and extract the C-ring serrated wedge from the retaining lip. A method according to claim 14, characterized in that minimizing rotation of the C-ring serrated wedge comprises engaging the anti-rotation shoulders on the anti-rotation portion of the anti-rotation shoulder support ring comprising both sides of a T-slot. formed on the serrated C-ring wedge. Method according to claim 14, characterized in that actuation of the support sleeve withdraws the anti-rotation shoulder of the support sleeve away from the anti-rotation shoulder of the T-slot and on an expanded portion of the T-slot. A method according to claim 14, further comprising maintaining a spike portion extending from the anti-rotation portion of the support sleeve within a spike slot formed in the seal coating support body when the spike is provided. support sleeve is actuated to extract serrated C-ring wedge. Method according to claim 14, characterized in that locking the serrated C-ring wedge in the axial position comprises pressing a keyed profile of the serrated C-ring wedge against a corresponding profile at the retaining lip by means of a locking profile. a support ring disposed around the support sleeve. The method of claim 18 further comprising withdrawing the support ring in a recessed C-ring serrated wedge in response to axial movement of the support sleeve, and compressing the serrated ring wedge in C for a smaller diameter to extract the serrated C-ring wedge. Method according to claim 14, characterized in that it further comprises expanding the serrated C-ring wedge in engagement with a tapered tapered surface of the sealing liner support body in extracting the serrated ring wedge in C of the retaining lip.