BR112020023439B1 - METHOD FOR INTRODUCING A JOINT ASSEMBLY FROM A PRIMARY WELL HOLE INTO A SIDE WELL HOLE, AND, JOINT SYSTEM - Google Patents

Abstract

A joining system for casing a lateral wellbore may include a joining assembly and a passing tool. The joint assembly may include an anchor, a transition joint, a load transfer device, and a side liner. The through tool assembly may be configured to extend into a center hole of the joint assembly. The passing tool assembly may include a seating tool for seating the anchor and a locking device to allow transfer of axial or rotational force between the side liner and a work string.

Description

FIELD OF TECHNIQUE

[001] The present description refers in general to joint assemblies and, more particularly, for example, and without limitation, to methods and apparatus for introducing a joint assembly with a side liner in a single maneuver.

FUNDAMENTALS OF DISCLOSURE

[002] In the oil and gas industry, hydrocarbons are produced from well holes that traverse hydrocarbon-producing underground formations. Many current well completions include more than one wellbore. For example, a generally vertical first wellbore may be initially drilled within or adjacent to one or more hydrocarbon-producing formations. Any number of additional well holes may then be drilled extending generally laterally away from the first well hole to respective selected locations to optimize production from the associated hydrocarbon-producing formation or formations. These well completions are commonly referred to as multilateral wells.

BRIEF DESCRIPTION OF THE DRAWINGS

[003] In one or more implementations, not all components represented in each figure may be necessary and one or more implementations may include additional components not shown in a figure. Variations in the arrangement and type of components may be made without departing from the scope of disclosure of the subject. Additional components, different components, or fewer components may be used within the scope of the subject matter disclosure.

[004] Figure 1 is a cross-sectional view of a one-well system that may employ the principles of the present disclosure, according to some embodiments.

[005] Figure 2 is an elevation view of a junction assembly, according to some embodiments.

[006] Figure 3 is a cross-sectional view of an anchor of the junction assembly of Figure 2, according to some embodiments.

[007] Figure 4 is a cross-sectional view of a load transfer device of the junction assembly of Figure 2, according to some embodiments.

[008] Figure 5 is a cross-sectional view of a passing tool, according to some embodiments.

[009] Figure 6 is a perspective view of a joining system, according to some embodiments.

[0010] Figure 7 is a cross-sectional view of an upper portion of a seating tool and an anchor of the joint system of Figure 6, in accordance with some embodiments.

[0011] Figure 8 is a cross-sectional view of a lower portion of the seating tool and the anchor of the joint system of Figure 6, according to some embodiments.

[0012] Figure 9 is a cross-sectional view of a locking device and a load transfer device of the joint system of Figure 6, according to some embodiments.

[0013] Figure 10 is a cross-sectional view of a drive eyelet in a retracted position, according to some embodiments.

[0014] Figure 11 is a cross-sectional view of the drive eyelet of Figure 10 in a driven position, according to some embodiments.

[0015] Figure 12 is a cross-sectional view of a joint system introduced into a primary wellbore, according to some embodiments.

[0016] Figure 13 is a cross-sectional view of the joint system advancing into a side wellbore, according to some embodiments.

DETAILED DESCRIPTION

[0017] This section provides several examples of implementations of the disclosed subject matter, which are not exhaustive. As those skilled in the art would appreciate, the described implementations may be modified without departing from the scope of the present disclosure. Therefore, the drawings and description should be considered illustrative and not restrictive in nature.

[0018] The present description refers in general to joint assemblies and, more particularly, for example, and without limitation, to methods and apparatus for introducing a joint assembly with a side liner in a single maneuver.

[0019] After formation of a side wellbore, the open hole of the side wellbore can be cased for future operations. A lateral liner can be introduced into the well system through the main wellbore and advanced to the lateral wellbore. Additionally, a transition joint is introduced into the bottom of the well to provide a transition joint window to allow access to portions of the primary wellbore below the lateral wellbore access window.

[0020] Advancing the lateral liner through the lateral wellbore often requires significant axial and rotational force to be applied to the lateral liner, particularly if the lateral wellbore is highly offset. However, the transition joint often has limited axial and torsional strength due to the material removed to form the transition joint window. Therefore, a transition joint going downhole with the lateral liner may not be able to withstand the forces necessary to reliably set the lateral liner to a desired depth. Therefore, the introduction and seating of both the lateral liner and the transition joint often require multiple maneuvers with passing tools to introduce the lateral liner and the transition joint separately.

[0021] One aspect of at least some embodiments disclosed herein is the understanding that, by releasably coupling a passing tool to an anchor above the transition joint and a load transfer device below the transition joint, an side liner and a transition joint can be reliably introduced and installed in a single maneuver.

[0022] Figure 1 is a cross-sectional view of a well system that may employ the principles of the present disclosure. As illustrated, the wellbore 100 may include a primary wellbore 102 and a secondary wellbore 104 that extends at an angle to the primary wellbore 102. The primary wellbore 102 may alternatively be referred to as a parent wellbore or a main wellbore, and the secondary wellbore 104 may be referred to as a side wellbore. In some embodiments, the expression "primary wellbore" may not imply that the wellbore is the first wellbore of a well and the expression "secondary wellbore" may not imply that the wellbore is the second wellbore wellbore of a well, but instead the expressions "primary wellbore" and "secondary wellbore" may refer to the relationship between a parent wellbore and the lateral (or derived) wellbore that extends from the parent wellbore. Although only one secondary wellbore 104 is depicted in Figure 1, it will be appreciated that the wellbore 100 may include multiple secondary (side) wellbores 104 that extend from the primary wellbore 102 at various locations. Likewise, it will be appreciated that the well system 100 may include multiple tertiary (derived) well holes (not shown) that extend from one or more of the secondary well holes 104 at various locations. In this way, the wellbore system 100 can be characterized and otherwise referred to as a "multilateral" wellbore system.

[0023] Primary and secondary well holes 102, 104 can be drilled and completed using conventional well drilling techniques. The primary wellbore 102 may have a liner or casing 106.

[0024] A port or casing window 110 may be machined, drilled, or otherwise defined along the casing 106 at the junction between the primary and secondary well holes 102, 104. The casing window 110 generally provides access for tools downhole casing 102. The casing 106 above the casing window 110 may be referred to as the upper wellbore casing 106 and the casing below the casing window 110 may be be referred to as the lower wellbore casing 108. Additionally, the portion of the wellbore 102 below the casing window 110 may be referred to as the lower wellbore 103.

[0025] In this way, the open hole of the side wellbore 104 can be lined with a side liner 160. The side liner 160 can facilitate access to the side wellbore 104 and maintain the integrity of the side wellbore 104. In In some embodiments, the lateral liner 160 is cemented into the lateral wellbore 104.

[0026] A junction assembly 120 may be disposed between the primary wellbore 102 and the secondary wellbore 104 to allow access to both wellbores 102, 104. In some embodiments, the junction assembly 120 may be arranged between any two wellbores, such as the secondary wellbore 104 and a tertiary (derived) wellbore (not shown). A transition joint 140 of the junction assembly 120 may provide access from the upper portion of the primary wellbore 102 to the secondary wellbore 104 and/or the lower wellbore 103. Additionally, the transition joint 140 may allow transfer of fluids, including cement, fracturing fluids, acid treatments, etc., to the secondary wellbore 104 and/or lower wellbore 103. In some embodiments, the transition joint 140 may provide access and/or allow the transferring fluids while a passing tool is in place and/or after the passing tool has been removed. In the illustrated example, an upper end portion 144 of the transition joint 140 is disposed in the primary wellbore 102, while the lower end portion 146 of the transition joint 140 is disposed in the secondary wellbore 104, providing access to the wellbore. In addition, a transition joint window 142 formed in the transition joint 140 provides access to the lower wellbore 103. An anchor 130 may connect or anchor the transition joint 140 to the casing 106 in the primary wellbore 102 .

[0027] As illustrated, a load transfer device 150 may couple the side liner 160 to the lower end portion 146 of the transition joint 140. The load transfer device 150 may be any suitable device or mechanism that allows loads, such as torque and/or axial loads are transferred from the passing tool to or from the side liner 160 or a work column. As described herein, by coupling the side liner 160 and the transition joint 140, the joint assembly 120 can be advantageously introduced and set into the well system 100 in a single maneuver, while reliably advancing the side liner 160 and the transition joint 140. The load transfer device 150 may be integrated with the side liner 160 or the transition joint 140.

[0028] Figure 2 is an elevation view of a junction assembly, in accordance with some embodiments of the present disclosure. The joint assembly 120 includes an anchor 130, a transition joint 140, a load transfer device 150 and a side liner 160 coupled and having a collective central hole 121 therethrough. Coupling the elements of the joint assembly 120 allows the introduction of the joint assembly 120, including the transition joint 140 and lateral liner 160, into a well system together in a single maneuver.

[0029] In the depicted example, the transition joint 140 provides access between the upper portion of the primary wellbore and the secondary wellbore through the central hole 121. Additionally, the transition joint 140 includes a transition joint window 142 to allow additional access path to the central borehole 121. Therefore, during operation, the transition joint window 142 may provide access between the upper portion of the primary wellbore and the lower portion of the primary wellbore.

[0030] Removing or milling material from the transition joint 140 can form the transition joint window 142. For example, removing a partial cross-section of the transition joint 140, such as an arc along the cross-sectional shape of the transition joint 140, may form the transition joint window 142. The transition joint window 142 may be a cut, slot, slot or hole formed between the upper end portion 144 and the lower end portion 146. Optionally , the transition joint 140 can be introduced into the bottom of the well without a window, wherein the transition joint window 142 can be milled or cut at a location in the bottom of the well.

[0031] In some embodiments, removing material from the transition joint 140 to form the transition joint window 142 may reduce the axial and torsional strength and/or stiffness of the transition joint 140. Therefore, in some applications, the joint transition 140 may not be able to withstand or transmit axial or rotational forces therethrough.

[0032] As shown, an anchor 130 is coupled to the transition joint 140 at the upper end portion 144. The anchor 130 may couple or connect the transition joint 140 to the casing to anchor the transition joint 140 in a primary wellbore. .

[0033] Additionally, a load transfer device 150 is coupled to the transition joint 140 at the lower end portion 146. The load transfer device 150 may couple or connect the side liner 160 to the transition joint 140.

[0034] Figure 3 is a cross-sectional view of an anchor of the junction assembly of Figure 2, in accordance with some embodiments of the present disclosure. The anchor 130 may be coupled to the transition joint on the lower portion 138 of the anchor 130. The anchor 130 may be expandable or otherwise adjustable to anchor the transition joint to the casing. As illustrated, the anchor 130 includes an expandable portion 134 that can deform and expand. Optionally, the expandable portion 134 may include sealing portions 132 to seal or insulate the transition joint.

[0035] To facilitate expansion or seating with a seating tool, the anchor 130 may include an anchor profile 136 for interfacing with a seating tool. The anchor profile 136 is one or more geometric features that can engage with a setting tool to transmit axial forces experienced by the anchor 130 during setting. During operation, the anchor profile 136 may allow the anchor 130 to remain stationary during setting. Optionally, the anchor profile 136 may not transmit any rotational force therethrough.

[0036] Figure 4 is a cross-sectional view of a load transfer device of the junction assembly of Figure 2, in accordance with some embodiments of the present disclosure. In the example shown, the upper end 152 of the load transfer device 150 is coupled to the transition joint and the lower end 154 of the load transfer device 150 is coupled to the side liner 160. Therefore, the load transfer device 150 couples the side liner 160 to the transition joint 140.

[0037] Additionally, the load transfer device 150 includes a load transfer device profile 155. The load transfer device profile 155 includes one or more geometric features that can engage a locking device. As illustrated, the profile of the load transfer device 155 includes axial force transfer surfaces 156 and rotational force transfer surfaces 158. The axial force transfer surfaces 156 may include surfaces with planes that are normal to the axial movement of the device. load transfer surfaces 150. The axial force transfer surfaces 156 may engage the locking device to transfer axial force between the locking device and the load transfer device 150. Likewise, the rotational force transfer surfaces 158 may include surfaces with planes that are normal to the rotational motion of the load transfer device 150. The rotational force transfer surfaces 158 may engage the locking device to transfer rotational force between the locking device and the load transfer device 150 .

[0038] Optionally, as shown in the depicted example, the side liner 160 is rotationally and/or axially coupled to the load transfer device 150. Therefore, the profile of the load transfer device 155 can transfer rotational and axial forces between the device liner 160. When transferring loads between the side liner 160, the load transfer device 150 and the locking device coupled thereto, the loads and forces required to advance the side liner 160 can be deflected away from the transition joint. During operation, all force between the locking device and the side liner 160 can be diverted away from the transition joint. Optionally, part of the force between the side liner 160 and the locking device is diverted away from the transition joint.

[0039] Figure 5 is a cross-sectional view of a passing tool, in accordance with some embodiments of the present disclosure. As illustrated, the passage tool 200 includes an upper connection 202 configured to be connected to a drill string or work string. The work column may transmit a rotational and/or axial force to the upper connection 202 and to the passage tool 200 generally to advance and/or rotate the passage tool 200.

[0040] In the example shown, the passing tool 200 is configured to be inserted into the central hole of the joint assembly. The passing tool 200 may couple to the joint assembly in the seating tool 210 and the locking device 230 to advance, rotate and adjust the joint assembly. Advantageously, by coupling the passing tool above and below the transition joint, the rotational and/or axial forces required to install the lateral liner can be isolated from the transition joint.

[0041] During operation, the setting tool 210 is configured to engage the anchor in the central hole therein. The seating tool 210 may releasably couple to the anchor to seat the anchor in the desired downhole location.

[0042] As illustrated, the locking device 230 is configured to engage the profile of the load transfer device with the inner surface of the load transfer device. The locking device 230 may releasably couple to the load transfer device to transfer axial and rotational force from the work column to the side liner for manipulating the side liner during advancement of the side liner.

[0043] As illustrated, one or more extension mandrels 204 may be used to allow the seating tool 210 and the locking device 230 to be aligned with the anchor and the load transfer device of the joint assembly. As shown, extension mandrels 204 may extend through the axial distance of the transition joint to permit engagement of seating tool 210 and locking device 230 above and below the transition joint.

[0044] In some embodiments, the passage tool 200 may include one or more drive lugs 220 to rotationally and/or axially align the transition joint window with the window in the primary wellbore. During operation, the drive eye 220 may extend to locate the bottom of the window. The drive eye 220 may remain retracted during advancement of the passing tool 200 to prevent damage to the casing or prevent displacement of the bottom hole.

[0045] Figure 6 is a perspective view of a joining system, in accordance with some embodiments of the present disclosure. As shown, the joint assembly 120 receives the through tool 200, wherein the through tool 200 and the joint assembly 120 are collectively referred to as the joint system 300. In the example depicted, the through tool 200 is coupled to the joint assembly 120, to allow the joint assembly 120 to be advanced into the wellbore. As previously described, the passing tool 200 is coupled to the joint assembly 120 at the anchor 130 and the load transfer device 150.

[0046] Furthermore, the joint system 300 allows for the seating of the anchor 130 and the transmission of axial and/or rotational force to the side liner 160. In particular, as the load transfer device 150 couples the side liner 160 to the passage tool 200, the axial and/or rotational forces are diverted from the transition joint 140. By allowing a coupling of the passage tool 200 to the side liner 160 by means of the load transfer device 150, the junction system 300 can provide sufficient force transfer to allow the side liner 160 to reliably reach a desired seating depth and prevent damage to the transition joint.

[0047] Figure 7 is a cross-sectional view of an upper portion of a seating tool and an anchor of the joint system of Figure 6, in accordance with some embodiments of the present disclosure. As shown, the upper portion of the seating tool 211 is disposed on the anchor 130. In some embodiments, the upper portion of the setting tool 211 expands the anchor 130 to anchor the joint assembly within the casing at a desired location.

[0048] Optionally, one or more expansion cones 215 are driven to expand against the expandable portion 134 of the anchor 130. During operation, the expansion cones 215 expand the expandable portion 134 and the sealing portions 132 against the casing to anchor the anchor. As shown, an actuator 213 such as a hydraulic piston or an electromechanical actuator compresses, squeezes or otherwise drives one or more expansion cones 215 outward toward the expandable portion 134 of the anchor 130.

[0049] In some embodiments, wedges configured to engage the casing or other anchoring devices, such as a conventional anchor, can anchor the joint assembly.

[0050] Figure 8 is a cross-sectional view of a lower portion of the seating tool and the anchor of the joint system of Figure 6, in accordance with some embodiments of the present disclosure. As shown, the lower portion of the seating tool 212 is disposed on the anchor 130. During seating of the anchor 130, the anchor 130 may experience an axial reaction force. Therefore, the lower portion of the seating tool 212 may engage with the anchor 130 to axially retain the anchor 130 during seating thereof.

[0051] As illustrated, one or more collets 218 have geometric features or a profile complementary to the anchor profile profile 136. When passing the anchor profile 136, the collets 218 can move along the mandrel 214 to engage the anchor profile. anchor 136. During operation, a drive device 216 may move the tongs 218 to an engaged position. The actuating devices 216 may similarly release the grippers 218 as desired.

[0052] Upon engagement, the clamps 218 have geometric characteristics to axially retain the seating tool 212 in relation to the anchor 130 to allow seating of the anchor 130 without axial movement thereof. In some embodiments, the clamps 218 do not rotationally restrict the seating tool 212 relative to the anchor 130, allowing rotation therebetween.

[0053] Figure 9 is a cross-sectional view of a locking device and a load transfer device of the joint system of Figure 6, in accordance with some embodiments of the present disclosure. As shown, the locking device 230 is disposed on the load transfer device 150. In the example shown, the locking device 230 axially and/or rotationally couples the load transfer device 150 below the transition joint to facilitate the transfer of axial and/or rotational loads between the seating tool and the side liner 160. Advantageously, by facilitating transfer between them, the passing tool can transmit high compression and torque loads to the side liner 160 to facilitate the advancement of the side liner 160 reliably in lateral wells, including highly deviated wellbores. In comparison, an adjustment tool and anchor coupling and/or a transition joint may not be able to transfer the desired compression and torque loads to the side liner, requiring multiple trips to install the side liner and transition joint. transition.

[0054] As shown, the locking device 230 utilizes a slot locking mechanism to axially and rotationally couple the locking device 230 to the load transfer device 150. As illustrated, the locking device 230 includes a complementary locking profile 235 that includes one or more geometric features that are complementary to or interface with the load transfer device profile 155. In some embodiments, the complementary locking profile 235 includes a complementary axial force transfer surface for engaging the transfer surfaces. of axial force of the load transfer device profile 155 to engage and transfer axial force between the locking device 230 and the load transfer device 150. Likewise, the complementary locking profile 235 includes a force transfer surface complementary rotational to engage the rotational force transfer surfaces of the load transfer device profile 155 to engage and transfer rotational forces between the locking device 230 and the load transfer device 150.

[0055] In some embodiments, the locking device 230 uses frictional engagement between the complementary locking profile 235 and the load transfer device profile 155 alternatively or in addition to the geometric relationships of the profiles to facilitate the transfer of force between them. . Optionally, the complementary locking profile 235 may be rotated, translated and/or extended to engage the load transfer device profile 155 by a drive mechanism 234. The drive mechanism 234 may be hydraulic and/or electromechanical and may engage and selectively disengaging the complementary locking profile 235 from the load transfer device profile 155.

[0056] Additionally, the locking device 230 may utilize other engagement mechanisms, such as a friction engagement clutch with an engagement surface.

[0057] Figure 10 is a cross-sectional view of a drive eyelet in a retracted position, in accordance with some embodiments of the present disclosure. In the illustrated example, the driving eye 220 can be used to locate the base of the casing window in the primary wellbore and further axially and/or rotationally align the transition joint window with the casing window. Advantageously, by locating the base portion of the casing window, the drive eye 220 can determine when the side liner is advanced to a desired depth to allow application of a seating force to install the side liner.

[0058] Embodiments of the drive eye 220 can be described in U.S. Patent No. 6,244,340. The drive eye 220 can be installed in line with the extension mandrels to be aligned with the transition joint window. As illustrated, the drive eye 220 is held in a retracted position to permit introduction of the joint system without damage to or interference with the primary wellbore casing. A release mechanism 226 may maintain the eye member 222 in a retracted position.

[0059] Figure 11 is a cross-sectional view of a drive eyelet in a driven position, in accordance with some embodiments of the present disclosure. As illustrated, the eye member 222 of the drive eye 220 is shown in an extended position. The eye member 222 may be deployed to be extended as the joining system approaches the casing window of the primary wellbore.

[0060] As shown, the eyelet member 222 is biased outwardly. As the release mechanism 226 releases the eye member 222, the eye member 222 may rotate away from the mandrel 221 to extend outward. The eye member 222 may rotate about a pivot 224.

[0061] The released eyelet member 222 may engage a bottom of the casing window to axially and rotationally align the transition joint window with the casing window. Optionally, more than one drive eye 220 can be used.

[0062] Figure 12 is a cross-sectional view of a joint system introduced into a primary wellbore, in accordance with some embodiments of the present disclosure. In the depicted example, the joining system 400 is shown being introduced and advanced into the primary wellbore 102. The passing tool 200 can advance the joining system 400.

[0063] At an upper end, the passage tool 200 is coupled to a work string 101 to axially and rotationally drive the joint system 400 into the primary wellbore 102. During operation, the passage tool 200 advances the anchor 130, the transition joint 140, the load transfer device 150 and the side liner eye 160 together in a single maneuver. As previously described, the passing tool 200 is coupled to the anchor 130 via the seating tool 210 and to the load transfer device 150 via the locking device 230. Additionally, the drive eye 220 is aligned with a portion bottom of the transition joint window 142. As the joint system 400, and in particular the transition joint 140, is disposed above a casing window, the drive eye 220 remains retracted to allow maneuvering of the transition joint window 142. junction 400 through primary wellbore 102.

[0064] Figure 13 is a cross-sectional view of the joint system advancing into a side wellbore, in accordance with some embodiments of the present disclosure. As illustrated, portions of the joint system 400 may be introduced into the side wellbore 104. In particular, as illustrated, the side liner eye 160 and portions of the transition joint 140 may deflect and advance through the side wellbore 104.

[0065] During advancement of the side liner eye 160 through the side wellbore 104, the locking device 230 and the load transfer device 150 apply rotational and/or axial force to the side liner eye 160. In some applications , highly deviated wellbore paths may require significant axial and/or radial force on the lateral liner eye 160.

[0066] Advantageously, by providing sufficient force to the side liner 160 through the load transfer device 150 and the locking device 230, the side liner 160 can be safely advanced to a desired depth. Optionally, the drive eye 220 may extend through the transition joint window 142 to locate the lower portion of the casing window 110. The drive eye 220 may capture or engage a portion of the casing window 110, e.g., the lower portion of the casing window 110, to locate and align the transition joint window 142 with the casing window 110.

[0067] Additionally, the position of the drive eye 220 can confirm the location or depth of the side liner 160. After the side liner 160 is located at a desired depth, the passing tool 200 can apply a set weight to adjust the side liner 160 in position. In some embodiments, the side liner 160 is set by rotating the passing tool 200. Optionally, the passing tool 200 may direct cement around the side liner 160 to cement the side liner 160 into position.

[0068] After the side liner 160 is adjusted to depth, the anchor 130 can be adjusted to anchor the transition joint 140 to the liner 106. The seating tool 210 can seat the anchor 130 as previously described. Advantageously, a single passing tool 200 can introduce and install both the side liner 160 and the anchor 130 in a single maneuver.

[0069] Upon setting of the anchor 130, the passage tool 200 can disengage the load transfer device 150 and the anchor 130 and be retrieved from the well system.

[0070] Various examples of aspects of the disclosure are described below as convenience clauses. These are provided as examples and are not limited to the technology in question.

[0071] Clause 1. A method for introducing a joint assembly from a primary wellbore into a lateral wellbore, the method comprising: introducing a passing tool into the joint assembly, wherein the joint assembly includes an anchor , a transition joint coupled to the anchor, a load transfer device coupled to the transition joint and a side liner coupled to the load transfer device; releasably attach the passage tool to the anchor and the load transfer device; advancing the passing tool and joint assembly through a casing of the primary wellbore; introducing the side liner through a liner window; and applying rotational or axial force to the side casing and the load transfer device via the passing tool to position the side liner into the side wellbore.

[0072] Clause 2. The method of Clause 1, further comprising diverting a load from the side liner to the seating tool by means of the load transfer device.

[0073] Clause 3. The method of Clause 1 or 2, further comprising locating the casing window by means of the passage tool.

[0074] Clause 4. The method of any previous clause, further comprising milling a transition joint window in the transition joint.

[0075] Clause 5. The method of Clause 4, wherein milling the transition joint window comprises milling the transition joint window at a downhole location.

[0076] Clause 6. The method of any preceding clause, further comprising aligning a transition joint window of the transition joint with the cladding window.

[0077] Clause 7. The method of Clause 6, wherein aligning the transition joint window further comprises axially aligning the transition joint with the casing window.

[0078] Clause 8. The method of Clause 6, wherein aligning the transition joint window further comprises rotationally aligning the transition joint with the casing window.

[0079] Clause 9. The method of any previous clause, further comprising cementing the lateral liner within the lateral wellbore.

[0080] Clause 10. The method of any previous clause, further comprising laying the anchor.

[0081] Clause 11. The method of Clause 10, wherein setting the anchor further comprises expanding the anchor.

[0082] Clause 12. The method of Clause 11, wherein expanding the anchor comprises hydraulically expanding the anchor.

[0083] Clause 13. The method of Clause 11, wherein expanding the anchor comprises mechanically expanding the anchor.

[0084] Clause 14. The method of any previous clause, further comprising: disengaging the passage tool from the joint assembly; and retrieve the primary wellbore traversing tool.

[0085] Clause 15. Joint system for lining a lateral wellbore extending from a primary wellbore, the joint system comprising: a joint assembly including an anchor, a transition joint, a transfer device load and a side liner collectively defining a central hole extending therethrough, the transition joint coupled to the anchor, the transition joint including a transition joint window extending through the transition joint into the hole central, the load transfer device coupled to the transition joint, the load transfer device including a load transfer device profile disposed within the central hole, wherein the load transfer device profile includes an engagement portion axial and a rotational engagement portion, the side liner positioned below the transition joint; and a through tool assembly configured to extend into the center hole of the joint assembly, the through tool assembly including: an upper connection to a work column; connection; and an axially spaced locking device of the seating tool, the locking device including locking profile complementary to the load transfer device profile for engaging the axial engagement portion or rotational engagement portion of the load transfer device profile, wherein axial and rotational engagement between the load transfer device and the locking device allows the transfer of axial or rotational force between the side liner and the work column.

[0086] Clause 16. The joining system of Clause 15, further comprising a mechanical actuator coupled to the expansion cone.

[0087] Clause 17. The joining system of Clause 15 or 16, further comprising a hydraulic piston coupled to the expansion cone.

[0088] Clause 18. The joining system of Clauses 15 to 17, further comprising an extension mandrel coupling the seating tool and the locking device.

[0089] Clause 19. The joint system of Clause 18, wherein the extension mandrel extends through the transition joint.

[0090] Clause 20. The joining system of Clauses 15 to 19, further comprising a drive eyelet assembly disposed between the seating tool and the locking device, the drive eyelet assembly including: a pivotally coupled eyelet to an eye body on a pivot; and a deflection member radially urging the eyelet away from the eyelet body.

[0091] Clause 21. The joining system of Clause 20, further comprising a retention mechanism that releasably couples the eyelet to the eyelet body, wherein the retention mechanism is arranged opposite the pivot.

[0092] Clause 22. The joining system of Clause 20, wherein the drive eyelet assembly includes a plurality of drive eyelet assemblies.

[0093] Clause 23. Joint system for lining a lateral wellbore extending from a primary wellbore, the joint system comprising: a joint assembly, an anchor, a transition joint, a load transfer device and a side liner collectively defining a central hole extending therethrough, the anchor including an anchor profile disposed in the central hole, the transition joint coupled to the anchor, the load transfer device coupled to the transition, the load transfer device including an internal engaging surface, the side liner coupled to the load transfer device; and a through tool assembly configured to extend into the center hole of the joint assembly, the through tool assembly including: * an upper connection configured to be coupled to a work column; a seating tool coupled to the upper connection, the seating tool including a seating tool collet and a mandrel extending in the seating tool collet, wherein the seating tool collet includes a descent profile complementary to the seating profile. anchor and is configured to receive the anchor profile; and an axially spaced seating tool locking device, the locking device including locking profile configured to engage the inner engagement surface, wherein axial and rotational engagement between the load transfer device and the locking device enables transfer of axial or rotational force between the liner and the work column.

[0094] Clause 24. The joining system of Clause 23, wherein the anchor includes a wedge assembly disposed on an outer surface of the anchor, wherein the wedge assembly is coupled to the inner engaging surface.

[0095] Clause 25. The joining system of Clause 23 or 24, wherein the locking device includes a clutch configured to engage the inner engaging surface.

[0096] Clause 26. The joining system of Clauses 23-25, further comprising an extension mandrel coupling the seating tool and the locking device.

[0097] Clause 27. The joint system of Clause 26, wherein the extension mandrel extends through the transition joint.

[0098] Clause 28. The joining system of Clauses 23-27, further comprising a drive eyelet assembly disposed between the seating tool and the locking device, the drive eyelet assembly including: a pivotally coupled eyelet to an eye body on a pivot; and a deflection member radially urging the eyelet away from the eyelet body.

[0099] Clause 29. The joining system of Clause 28, further comprising a retention mechanism that releasably couples the eyelet to the eyelet body, wherein the retention mechanism is arranged opposite the pivot.

[00100] Clause 30. The joining system of Clause 28, wherein the drive eyelet assembly includes a plurality of drive eyelet assemblies.

[00101] Clause 31. A joining system for lining a lateral wellbore extending from a primary wellbore, the joining system comprising: an anchor including an expandable portion and an anchor profile disposed in a hole anchor center; a transition joint coupled to the anchor, the transition joint including a transition joint window extending through the transition joint; a load transfer device coupled to the transition joint, the load transfer device including a load transfer device profile disposed in the central hole, wherein the load transfer device profile includes an axial engagement portion and a rotational engagement portion; and a side liner coupled to the load transfer device.

[00102] Clause 32. A passing tool assembly for casing a side wellbore extending from a primary wellbore, the passing tool assembly comprising: an upper connection configured to be coupled to a work string; a seating tool coupled to the upper connection, the seating tool including an expansion cone, a seating tool collet and a mandrel extending in the expansion cone, and the seating tool collet, wherein the seating tool collet settlement includes a settlement profile; and an axially spaced locking device of the seating tool, the locking device including locking profile, wherein the locking device allows the transfer of axial or rotational force between the locking device and the work column.

[00103] Clause 33. The passage tool assembly of Clause 32, further comprising a mechanical driver coupled to the expansion cone.

[00104] Clause 34. The passing tool assembly of Clause 32 or 33, further comprising a hydraulic piston coupled to the expansion cone.

[00105] Clause 35. The passing tool assembly of Clauses 32-34, further comprising an extension mandrel coupling the seating tool and the locking device.

[00106] Clause 36. The passing tool assembly of Clauses 32-35, further comprising a drive eye assembly disposed between the seating tool and the locking device, the drive eye assembly including: a coupled eyelet of shape hinged to an eye body on a pivot; and a deflection member radially urging the eyelet away from the eyelet body.

[00107] Clause 37. The passage tool assembly of Clause 36, further comprising a retention mechanism that releasably couples the eyelet to the eyelet body, wherein the retention mechanism is disposed opposite the pivot.

[00108] Clause 38. The passing tool assembly of Clause 36, wherein the drive eye assembly includes a plurality of drive eye assemblies.

Claims (15)

1. Method for introducing a joint assembly (120) from a primary wellbore (102) into a lateral wellbore (104), the method characterized by the fact that it comprises: introducing a passing tool (200) into the assembly junction assembly (120), wherein the junction assembly (120) includes an anchor (130), a transition joint (140) coupled to the anchor (130), a load transfer device (150) coupled to the transition joint (140) and a side liner (160) coupled to the load transfer device (150); milling a transition joint window (142) into the transition joint (140); releasably couple the passage tool (200) to the anchor (130) and the load transfer device (150); advancing the passage tool (200) and joint assembly (120) through a casing (106) of the primary wellbore (102); introduce the side liner (160) through a coating window (110) of the coating (106); and applying rotational or axial force to the side liner (160) and the load transfer device (150) via the passing tool to position the side liner (160) within the side wellbore (104). 2. Method according to claim 1, characterized by the fact that it further comprises diverting a load from the side liner (160) to the passing tool by means of the load transfer device (150). 3. Method according to claim 1, characterized by the fact that it further comprises locating the coating window (110) by means of the passage tool (200). 4. The method of claim 1, wherein milling the transition joint window (142) comprises milling the transition joint window (142) at a downhole location. 5. Method according to claim 1, characterized by the fact that it further comprises aligning the transition joint window (142) of the transition joint (140) with the casing window (110); and, optionally, wherein aligning the transition joint window (142) further comprises axially aligning the transition joint (140) with the casing window (110); and, optionally, wherein aligning the transition joint window (142) further comprises rotationally aligning the transition joint (140) with the casing window (110). 6. Method according to claim 1, characterized by the fact that it further comprises cementing the lateral liner (160) within the lateral wellbore (104). 7. Method according to claim 1, characterized by the fact that it further comprises setting the anchor (130). 8. Method according to claim 7, characterized by the fact that seating the anchor (130) further comprises expanding the anchor (130); and, optionally, wherein expanding the anchor (130) comprises hydraulically expanding the anchor (130); and, optionally, wherein expanding the anchor (130) comprises mechanically expanding the anchor (130). 9. Method according to claim 1, characterized by the fact that it further comprises: disengaging the passage tool (200) from the joint assembly (120); and recovering the passage tool (200) from the primary wellbore (102). 10. Joint system for lining a lateral wellbore (104) extending from a primary wellbore (102), the joint system characterized by the fact that it comprises: a joint assembly (120) including an anchor (130), a transition joint (140), a load transfer device (150) and a side liner (160) which collectively define a central hole extending therethrough, the transition joint (140) coupled to the anchor (130), the transition joint (140) including a transition joint window (142) extending through the transition joint (140) to the center hole, the load transfer device (150) coupled to the joint transition device (140), the load transfer device (150) including a load transfer device profile (155) disposed in the central hole, wherein the load transfer device profile (155) includes an engagement portion axial and a rotational engagement portion, the side liner (160) positioned below the transition joint (140); and a through tool assembly configured to extend into the center hole of the joint assembly (120), the through tool assembly including: an upper connection (202) with a work column; a seating tool (210) coupled to the upper connection (202); and a locking device (230) axially spaced from the seating tool (210), the locking device (230) including locking profile complementary (235) to the load transfer device profile (155) for engaging with the axial engagement or the rotational engagement portion of the load transfer device profile (155), wherein axial and rotational engagement between the load transfer device (150) and the locking device (230) allows axial force transfer or rotational between the side liner (160) and the work column. 11. Joining system according to claim 10, characterized by the fact that it further comprises an extension mandrel coupling the seating tool (210) and the locking device (230). 12. Joint system according to claim 11, characterized in that the extension mandrel extends through the transition joint (140). 13. Joining system according to claim 10, characterized by the fact that it further comprises a drive eye assembly disposed between the seating tool (212) and the locking device (230), the drive eye assembly including : an eyelet coupled to an eyelet body; and a deflection member radially pushing the eye away from the eye body. 14. The joining system of claim 13, wherein the drive eyelet assembly includes a plurality of drive eyelet assemblies. 15. Joint system for lining a lateral wellbore (104) extending from a primary wellbore (102), the joint system characterized by the fact that it comprises: a joint assembly (120) including an anchor (130), a transition joint (140), a load transfer device (150) and a side liner (160) which collectively define a central hole extending therethrough, the anchor (130) including a anchor (136) disposed within the central hole, the transition joint (140) coupled to the anchor (130), the load transfer device (150) coupled to the transition joint (140), the load transfer device (150) ) including an internal engagement surface, the side liner (160) coupled to the load transfer device (150); and a through tool assembly configured to extend into the center hole of the joint assembly (120), the through tool assembly including: an upper connection (202) with a work column; a seating tool (210) coupled to the upper connection (202), the seating tool (210) including a seating tool collet, and a mandrel (221) extending within the seating tool collet, wherein the seating tool clamp includes a seating profile complementary to the anchor profile (136) and is configured to receive the anchor profile (136); and a locking device (230) axially spaced from the seating tool (210), the locking device (230) including a locking profile (235) configured to engage the inner engagement surface, wherein axial and rotational engagement between the load transfer device (150) and locking device (230) allow the transfer of axial or rotational force between the side liner (160) and the work column.