AU2003203507B2 - Method and apparatus for electrical communication between equipment in a lateral branch and a main well bore - Google Patents

Description

2 METHOD AND APPARATUS FOR ELECTRICAL COMMUNICATION BETWEEN EQUIPMENT IN A LATERAL BRANCH AND A MAIN WELL BORE This invention relates generally to the construction of wells for the production of petroleum products and more specifically to the construction and completion of multilateral branches from a main well bore to enable the production of petroleum products from several subsurface zones. Even more specifically the present invention concerns methods and apparatus for connecting a lateral branch liner to a main well bore to achieve predictable and stable mechanical connectivity at the lateral junctions of branch well bores to the main well bore to counter the problems of formation instability at the branch junction which may cause partial or total obstruction of the lateral or main bore at the level of the lateral junction.

In the field of multilateral well construction and production operations one of the most valuable attributes of a junction is the connectivity of lateral branches with the main bore. Partial or total loss of connectivity of the main bore with a lateral branch may cause fluid production loss. Major connectivity problems may also result in partial or total obstruction of the main or lateral bore at the level of the lateral junction.

The consequences of such problems are a substantial penalty to the operator of a well in the form of lost opportunity, increased operating cost, or lost production.

The root cause of not being able to achieve or maintain connectivity at a lateral junction can be divided into two general areas: mechanical integrity problems and production of solids from the formations surrounding the junction. Mechanical integrity problems are usually a combination of design factors limiting the strength of, and mechanical forces applied by the surrounding formations onto, the connecting equipment. Production of solids from surrounding formations occurs when the H.\flanaan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 3 junction technique does not achieve a consistent connectivity by means of mechanical liner tie-back solutions. This can be the case when a liner is connected to the parent well bore by means of cement or any similar joining technique which does not withstand tensile or shear forces that may be induced by formation pressures or subsidence or any other formation movement at the level of the lateral junction.

One form of prior art is the use of a mechanical connection embedded with a casing section which has one or a plurality of pre-fabricated windows. Although such solution provides a possible connection of the lateral liner to the parent well bore, it requires a special vessel to be installed in line with the casing string at a specific depth and, more importantly, with a correct orientation with respect to earth gravity in order to place the pre-fabricated window in the direction of the projected lateral branch. This method requires very thorough well planning and delicate control of parent casing running procedures. Another drawback of this method is that connective template and retaining features are run with the parent casing and must therefore remain protected from any mechanical abuse while drilling in the parent section or drilling the lateral branch. Such method and apparatus generally requires other additional equipment to complete the well with lateral re-entry capability. Such device may be or similar to equipment for through-tubing re-entry by means of a secondary template. As a result a junction fully completed with such method will generally offer limited diameter to access the lower section of a parent well.

Another commercially available form of lateral connectivity does not require pre-orientation of the parent casing since it is implemented by milling lateral windows in installed well casing. The lateral liner is retained into the parent well bore and cemented into place. A window is then milled into the lateral liner in H,\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 4 order to re-establish communication between the lower section of the main bore and the lateral and upper section of the main bore. However, most mechanical integrity of the lateral connection involves cement or similar filling material placed in the space surrounding the junction. As explained above, the cement lacks sufficient structural integrity, especially when shale in the formation shifts from time to time as the formation changes consistency due to production of fluid therefrom or due to production fluid from a lower or different formation, so that the cement becomes fractured and impairs the connectivity of the branch junction.

Another form of lateral connectivity is accomplished by conveying a liner into the lateral branch after milling a window in the parent casing and after lateral drilling. The liner is cemented into place while the liner is held in the parent well with a liner hanger.

After the cement has set, cement excess and the liner top is "washed-over" with adequate milling and fishing tools.

A deflection tool left in the parent well is then retrieved and this should normally leave a full bore in parent well. Completion equipment is then set in the junction, assuming an indexing packer is left below the junction. The major drawbacks of such method are similar to those described above, since the mechanical integrity of the junction involves cement or similar filling material which has been placed while setting the lateral liner.

Another form of lateral connectivity takes the form of a prefabricated outlet which fits mechanically within a special vessel that is connected in line with the parent casing. The special vessel supports a selective positioning profile and an orienting profile. The outlet is conveyed with the parent casing in retracted position and deployed in the main bore by action of an expansion tool which extends the outlet around a hinge placed on top of the outlet. The outlet and vessel are interlocked and H.\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 5 sealed after the outlet is fully extended. A liner can be set, and retained in the lateral outlet bore by means of a liner-hanger-packer device. Such method requires a very complex deployment process and more importantly requires the special vessel to be placed and oriented in a precisely predetermined position while running the parent casing, and requires the outlet to be extended before cementing. Also the fact that a lateral outlet is preinstalled in the junction restricts the size of lateral drilling with conventional methods.

SUMMARY OF THE INVENTION According to one aspect of the present invention, there is provided an apparatus for use in a well having a main bore and a lateral branch, the lateral branch including an electrical device, the apparatus comprising: an inductive coupler mechanism to electrically communicate electrical signaling in the main bore with the electrical device.

According to a further aspect of the present invention, there is provided an apparatus to communicate electrical signaling from a main bore of a well to equipment in a lateral branch, comprising: a connector mechanism connecting equipment in the main bore to equipment in the lateral branch; and a first inductive coupler portion attached to the connector mechanism to communicate electrical signaling with the lateral branch equipment.

According to a further aspect of the present invention, there is provided a completion string for use in a well having a main bore and a lateral branch, comprising: equipment in the main bore and in the lateral branch; a first inductive coupler assembly proximal the equipment in the main bore; H:\fIanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 -6a second inductive coupler assembly proximal the equipment in the lateral branch; and an electrical cable connecting the first and second inductive coupler assemblies.

According to a further aspect of the present invention, there is provided a method of communicating between main bore equipment and lateral branch equipment in a well, comprising: providing a first inductive coupler assembly electrically connected to the main bore equipment and in communication with the lateral branch equipment; and transmitting electrical signaling over an electrical cable connected to the first inductive coupler assembly.

A more particular description of the invention, briefly summarized above, may be had by reference to the preferred embodiment thereof which is illustrated in the appended drawings.

It is to be noted however, that the appended drawings illustrate only a typical embodiment of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.

In the Drawings: Fig. 1 is a sectional view illustrating part of a casing lined and cemented main well bore in an earth formation, showing the initial part of a branch bore drilled therefrom through a milled casing window and further showing the placement of a lateral connection assembly within the main well bore in preparation for lateral branch activities; Fig. 2 is a sectional view taken along line 2-2 of Fig. 1; Fig. 3 is a sectional view taken along line 3-3 of Fig. 1; Fig. 4 is a sectional view taken along line 4-4 of Fig. 1; H,\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 7 Fig. 5 is a sectional view taken along line of Fig. 1; Fig. 6 is a sectional view taken along line 6-6 of Fig. 1; Fig. 7 is an isometric illustration in partial section showing a lateral branch template constructed according to an embodiment of the present invention and having the upper portion thereof cut away to show positioning of a diverter member within the upper portion of the template; Fig. 8 is an isometric illustration similar to that of Fig. 7 and showing a liner connector member and isolation packers in assembly with the lateral branch template; Fig. 9 is an isometric illustration showing the liner connector member of Fig. 8; Fig. 10 is an isometric illustration showing the diverter member that is located within the lateral branch template as shown in Figs. 7 and 8; Fig. 11 is a fragmentary sectional view showing part of a main well casing cemented within a main well bore and further showing part of a lateral branch template located within the main well casing and oriented by an indexing coupling with a branch liner diverted through a casing window into a lateral branch bore with the lower end thereof received in sealed relation within a cemented lateral branch casing; Fig. 12 is a fragmentary sectional view similar to that of Fig. 11 showing monitoring and/or control apparatus latched within the lateral branch tube of the lateral branch connector for sensing and/or controlling production of the lateral branch well section; Fig. 13A is a longitudinal sectional view of the upper section of a lateral branch template constructed in accordance with an embodiment of the present invention and having a lateral branch connector in assembly therewith; Fig. 13B is a longitudinal sectional view of the H.\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-OO.doc 02/04/2003 8 lower section of the lateral branch template and connector assembly of Fig 13A; Fig. 14A is an isometric illustration showing the upper section of the lateral branch template of Figs. 13A and 13B; Fig. 14B is an isometric illustration showing the lower section of the lateral branch template of Figs. 13A and 13B; Fig. 15A is an isometric illustration showing the inner side of the upper section of a lateral branch connector constructed in accordance with an embodiment of the present invention and being a part of the template/connector assembly of Figs. 13A and 13B; Fig. 15B is an isometric illustration showing the inner side of the lower section of the lateral branch connector of Fig. 15A as also shown in Figs. 13A and 13B; Fig. 15C is an isometric illustration showing the outer side of the lower section of the lateral branch connector of Figs. 15A and 15B and particularly showing the flexing intermediate section thereof; Fig. 16 is a fragmentary elevational view of the well casing of a main well bore showing a casing window that is milled to additionally define a positioning and orienting geometry for engagement by the orienting key of the lateral branch template or other apparatus; and Fig. 17 is a fragmentary sectional view of a section of main well casing showing a casing window and a positioning and orienting slot located within the casing, and showing in broken line a positioning and orienting slot out of rotational phase with the casing window.

Referring now to the drawings and first to Figs.

1-8, Fig. 1 illustrates the placement of a lateral branch junction connection assembly shown generally at 10 within the main well casing 12 of a main well bore 22 that is drilled within an earth formation 16. The lateral branch junction connection assembly 10 is defined by two basic components, a lateral branch template and a lateral branch H,\flanagan\keep\SPECIICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 9 connector which, when in assembly, cooperatively define a lateral branch junction connection assembly having sufficient structural integrity to withstand the forces of formation shifting. The assembled lateral branch junction also has the capability of isolating the production flow passages of both the main and branch bores from ingress of formation solids. After the main well bore and one or more lateral branches have been constructed, a lateral branch template 18 is set at a desired location within the main well casing 12 which will have been cemented by cement 20 within main well bore 22. A window 24 will have been formed within the main well casing 12 for each lateral branch, either having been milled prior to running and cementing of the main well casing 12 within the main well bore 22 or having been milled downhole after the main well casing 12 has been run and cemented. A lateral branch bore 26 is drilled by a branch drilling tool that is diverted from the main well bore 22 through the window 24 and outwardly into the earth formation 16 surrounding the main well bore. The lateral branch bore 26 is drilled along an inclination that is established by a whipstock or other suitable drill orientation control. The lateral branch bore 26 is also drilled along a predetermined azimuth that is established by the relation of the drill bit orientation control with an indexing device that is connected in the casing string or set within the casing string.

As shown in Figs. 1-6 a lateral branch connector 28 is attached to a lateral branch liner 30 which connects the lateral branch bore 26 to the main well bore 22. It is important to note that the lateral branch connector 28 establishes fluid connectivity with both the main well bore 22 and the lateral branch bore 26. Figs. 2-6 are transverse sectional views taken along respective section lines 2-2 through 6-6 of Fig. 1 and showing the structural interrelation of the various components of the lateral branch template 18 and the lateral branch connector 28.

H,\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-0O.doc 02/04/2003 10 As shown in Fig. 1 and also in Fig. 11, a generally defined ramp 32 cut at a shallow angle in the lateral branch template 18 serves to guide the lateral branch connector 28 toward the casing window 24 while it slides downwardly along the lateral branch template 18. Optional seals 34, which may be carried within optional seal grooves 36 on the lateral branch connector 28, as shown in Figs. 1, 4, 5 and 6 establish sealing between the lateral branch template 18 and the lateral branch connector 28 to ensure hydraulic isolation of the main and lateral branch bores from the environment externally thereof. A main production bore 38 is defined when the lateral branch connector 28 is fully engaged with the guiding and interlocking features of the lateral branch template 18 which will be described in detail below. Interengaging retaining components (not represented in Fig. 1) located in the lateral branch template 18 and the lateral branch connector 28 prevent the lateral branch connector 28 from disengaging from its interlocking and sealed position with respect to the lateral branch template 18. This feature will be described in detail below in connection with Figs.

4 through 6, 14A and 14B, and 15A and Figs. 2 and 3 illustrate the lateral branch template 18 and the lateral branch connector 28 by means of transverse sectional views along the section lines depicted in Fig. 1. The transverse sectional views of Figs. 2-6 show how the main production bore 38 in the sectional view of Fig. 2, separates into two isolated production bores in the transverse sectional view of Fig.

6. The main well casing 12 is cemented within the main well bore 22 by cement 20 which is pumped into the annulus between the well casing and the well bore in the usual fashion and is allowed to harden so that the main well casing 12 is substantially integral or mechanically interlocked with respect to the surrounding formation. A lateral window 24 is shown in Figs. 3 and 4 which leads from the main well bore 22 to the lateral branch bore 26.

H,\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 11 The lateral branch connector 28 is guided and interlocked into the lateral branch template 18 by means of tongue and groove type interlocking features 44 shown particularly in Figs. 4, 5 and 6 and shown in greater detail in Figs. 14B, 15B and 15C. Optional seals 34 for hydraulic isolation of the main and lateral branch bores from the environment externally thereof may be included between the lateral branch template 18 and the lateral branch connector 28 if desired. The mechanical interrelation of the lateral branch template 18 and the lateral branch connector 28 is, however, sufficient to isolate the production bores of both the lateral branch bore and main well bore from intrusion by solids from the formation.

Figs. 7-10 collectively illustrate the lateral branch junction connection assembly 10 by means of isometric illustrations having parts thereof broken away and shown in section. The lateral branch template 18 supports positioning keys 46 and an orienting key 48 which mate respectively with positioning and orienting profiles of positioning and orientation means such as the indexing coupling 50 set into the main well casing 12 as shown in Fig. 11. If the lateral branch construction procedure is being accomplished in a well which is not provided with an indexing coupling or other indexing means within its main well casing, indexing means can be oriented and set at any desired location within the existing well casing, thus permitting the lateral branch template 18 to be accurately positioned with respect to a casing window that is milled in the casing and with respect to a lateral branch bore that is drilled from the casing window. An adjustment adapter mechanism shown at 52 in Figs. 7 and 8 allows adjustment for depth and orientation between the lower section of the lateral branch template 18 and positioning keys 46 and orienting key 48, and the upper section of the lateral branch template 18 supporting lateral branch connector 28. For directing various tools and equipment into a lateral branch bore from the main well bore a H,\flanagan\keep\SPECIICATIONS\P48979 Divisional of 23465-00.dec 02/04/2003 12 diverter member 54 including selective orienting keys 56 fits into the main production bore of the lateral branch template 18 and defines a tapered diverter surface 58 that is oriented to divert or deflect a tool being run through the main production bore 38 laterally through the casing window 24 and into the lateral branch bore 26. The lower diverter body structure 57 is rotationally adjustable relative to the tapered diverter surface 58 to thus permit selective orientation of the tool being diverted along a selective azimuth. The selective orienting keys 56 of the diverter 54 will be seated within specific key slots of the lateral branch template 18 while the upper portion 59 of the diverter 54 will be rotationally adjusted relative thereto for selectively orienting the tapered diverter surface 58. Isolating packers 60 and 62 are interconnected with the lateral branch template 18 and are positioned respectively above and below the casing window 24 and serve to isolate the template annular space respectively above and below the casing window.

According to the preferred method for connecting a lateral branch liner to a main well casing the main or parent well casing is located within the main well bore and supports one or more indexing devices such as an indexing coupling 50 or any indexing sub that can be permanently installed in the parent casing below the junction. Alternatively, locating and indexing means may be set at any desired location within a main well casing, such as by one or more packers, for example. Also, positioning and orientation of the lateral branch template may be established by MWD systems, gamma ray logging systems, movable packers and the like. Indexing features include positive locating systems to position accurately the template in depth and orientation with respect to the lateral window. The main well casing has one or a plurality of lateral windows referenced to the indexing device or devices to thus permit one or more lateral branch bores to be constructed from the main well bore and H,\flanagan\keep\SPECIFICATIONS\P4a979 Divisional of 23465-OO.doc 02/04/2003 13 oriented according to the desired azimuth and inclination for intersecting one or more subsurface zones of interest.

The lateral branch window(s) is typically milled in the casing after main well casing has been set and cemented. In this case, the main well casing does not need to be oriented before cementing. Alternatively to the above, the lateral window can be pre-fabricated into a special vessel or coupling that is installed in line in the main well casing string. In this case, the main well casing requires orientation before cementing in order to conform the orientation of the lateral branch with the well construction plan.

Whether the casing window is pre-fabricated within the casing or formed within the casing after the casing has been installed and cemented, as shown in Figs.

16 and 17, the casing may be provided with one or more positioning and orienting slots which may be formed to define the geometry of the casing window or may be located within the casing in the immediate vicinity of the casing window and may be in rotational phase or out of rotational phase with the casing window as desired. As shown in Fig.

16, the main well casing 12 defines a casing window 24 essentially as shown in Figs. 1-4. In this case the lower end of the casing window has been formed, such as by milling, to define side surfaces 25 and 27 which define a positioning and orienting slot 29. The bottom curved edge 31 of the slot 29 provides for positioning while the generally parallel side surfaces 25 and 27 provide for orientation of the lateral branch template 18 or any other tool that is positioned and oriented within the casing.

Fig. 17 shows a main well casing 12 having a casing window 24. Below the casing window the casing has been formed, such as by milling, to define a positioning and orienting slot 33 having generally parallel side edges 35 and 37 and upper and lower ends 39 and 41. The positioning and orienting slot 33, like the positioning and orienting slot 29, is adapted to receive the orienting key 48 of the H \flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 14 lateral branch template 18 or any other tool that is intended to be positioned and oriented within the casing.

As shown in Fig. 17, the positioning and orienting slot 33, shown in full line, is in rotational phase with the casing window 24. Alternatively, as shown in broken line at 33', the positioning and orienting slot may be located out of rotational phase with the casing window 24.

The lateral branch template 18 is properly located and secured into the main well bore 22 by fitting into an indexing device to position accurately the template in depth and orientation with respect to the window 24 in the main well casing 12. The lateral branch template 18 has adjustment components that are integrated into the lateral branch template 18 and which allow for adjusting the position and orientation of the lateral branch template with respect to the lateral casing window.

The main production bore 38 allows fluid and production equipment to pass through the lateral branch template 18 with minimal restriction so access in branches located below the junction is still allowed for completion or intervention work after the lateral branch template 18 has been set. The lateral opening 42 in the lateral branch template 18 provides space for passing a lateral branch liner 30 and for locating the lateral branch connector 28 which fits in it with tight tolerances taking advantage of controlled prefabricated geometries.

The lateral branch template 18 incorporates a landing profile and a latching mechanism which allows supporting and retaining the lateral branch connector 28 so it is positively connected to the main production bore 38. The lateral branch template 18 also incorporates guiding and interlocking features which cause diverting and guiding movement of the lateral branch connector 28 through the lateral opening and positioning the lateral branch connector 28 to provide support against forces that may be induced by shifting of the surrounding formation or by the fluid pressure of produced fluid in the junction.

H.\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 15 The lateral branch template 18 also provides a selective landing profile and associated orienting profile in which can fit a diverter 54 used to direct equipment from uphole through the casing window 24 and toward the lateral branch bore 26. The upper and lower ends of the lateral branch template 18 are treated so production tubing can be connected without diameter restriction by means of conventional production tubing connections. The lateral branch template 18 provides a polished bore receptacle for eventual tie back at its upper portion and is provided with a threaded connection at its lower portion. As an option, the annular space between lateral branch template 18 and main well casing 12 is isolated both above and below the lateral casing window 24 by means of isolating packers 60 and 62 to provide the well ultimately and selectively with isolation of either the lower section of the main production bore 38 or the lateral branch bore 26.

As an option, the upper and/or lower ends of the lateral branch template 18 may be equipped with electrical connectors and/or hydraulic ports so electrical and/or hydraulic fluid connections can be achieved downhole in order to carry power and/or signal lines through the template and along the main production bore 38.

Electrical connection can take the form of a mechanical contact connection, inductive connections, or electromagnetic connections. The end connection may be directed to equipment temporary or permanently installed on the template. As shown in Figs. 11 and 12, the lateral branch connector 28 is shown provided with power connector means, shown generally at 64, which comprise an electrical and/or hydraulic connector. A tubing encapsulated cable 66 extends substantially the length of the lateral branch connector 28 and, in the case of an electrical connector, is provided with parent bore and branch bore inductive couplings 68 and 70. The parent bore inductive coupling 68 is located within a polished bore receptacle 72 having H.\flanagan\keep\SPECIFICATIONSP48979 Divisional of 23465-00.doc 02/04/2003 16 an upper polished bore section 74 which is typically engaged by seal means 71 located at the lower end of a section of production tubing 75 as shown in Fig. 12. It should be borne in mind that the seal means 71 may be located in well components other than the production tubing 75 if desired. For example, the seal means 71 may be supported by a connector device being a component of running equipment for installation and removal of the lateral branch connector 28 or for running and retrieving the lateral branch template 18 or other lateral branch equipment. The parent bore inductive coupling 68 will typically derive its electrical energy from a power supply and control conductor 76 that extends along the exterior of the production tubing 75 to the surface where it is connected with an electrical power supply and connected with appropriate control conductors. When the upper junction production connection 73 is properly seated within bore receptacle 72 its inductive coupling 77 will be in induction registry with the parent bore inductive coupling 68, thereby completing the power supply connection to the lateral branch connector 28. The power supply and control conductor 76 may also incorporate hydraulic supply and control conductors for the purpose of electrically or hydraulically controlling and operating downhole equipment of the main or branch bores of the well.

As further shown in Figs. 11 and 12, lateral branch connector 28 defines an internal latching profile which receives the external latching elements 82 of a lateral production monitoring and/or flow control module 84. This module can take any suitable form, such as an electrically operated flow control valve, an electrically adjustable flow controlling choke device, a pressure or flow monitoring device, a monitoring device for monitoring various branch well fluid parameters, or a combination of the above. Lateral branch connector 28 is connected by a threaded connection 86 to a lateral connector tube 88 H,\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-OO.doc 02/0412003 17 having an end portion 90 that is received within a lateral branch connector receptacle 92 of the lateral branch liner and sealed therein by sealing means 94. The lateral production monitoring and/or flow control module 84 is provided at its upper end with a module setting and retrieving feature 96 with permits running and retrieving of the module by means of conventional running tools. The module 84 is provided with an inductive coupling 98 which is in inductive registry with the branch bore inductive coupling 70 when the module 84 is properly seated and latched by the latching elements 82.

As shown in the isometric assembly illustrations of Figs. 13A and 13B the lateral branch connector 28 is shown in interlocking assembly with the lateral branch template 18. From these assembly illustrations it will be seen that the lateral bore axis 100 of the lateral branch connector 28 is disposed in angular relation with the main bore axis 102 of the lateral branch template 18.

The upper section of the lateral branch template 18 is shown in Fig. 14A wherein the lateral opening 42 is defined by generally parallel side surfaces 104 and 106 which restrict lateral movement of the lateral branch connector 28 relative to the lateral branch template 18 and are joined at the upper end by a curved end surface 108. As the lateral branch connector 28 is moved forwardly the angulated ramp surfaces of the lateral branch template 18 guide the lower end portion of the lateral branch connector 28 through the lateral opening 42. The lower section of the lateral branch template 18, also referred to as the interlocking section, is shown in Fig. 14B and also defines the inclined ramp that is generally indicated at 32 in Figs. 1 and 11. The interlocking section defines other interlocking features that cooperate to mechanically interlock the lateral branch template 18 and the lateral branch connector 28 in properly positioned assembly to form a lateral branch connection that has sufficient structural integrity to H.\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 18 withstand the external mechanical force that might be caused by shifting of the surrounding earth formation.

The efficient connection of the interlocking section binds the lateral branch connector 28 into sufficiently tight assembly with the lateral branch template 18 to substantially prevent solids from entering the production stream from the lateral branch and permits branch connector movement that establishes efficient sealing with the lateral branch liner 30 of the lateral branch bore. In the interlocking section the lateral branch template 18 defines opposed orientation grooves 110, one of the orientation grooves being shown in the isometric illustration of Fig. 14B, which define at least one angulated guide surface for guiding the lower end of the interlocking section of the lateral branch connector 28 into interlocking relation with the lateral branch template 18. Immediately below the orientation grooves 110 the interlocking section of the lateral branch template 18 defines rear tongue and groove interlocks 112.

Below the rear tongue and groove interlocks 112 the interlocking section defines side exit guiding ramp surfaces 114 which are disposed in angular relation with the parent or main well bore axis 102 shown in Fig. 13B.

These side exit guiding ramp surfaces 114 cause lateral movement of the lower end of the lateral branch connector 28 as the connector is moved downwardly relative to the lateral branch template 18. Front tongue and groove interlocks 115 are provided below the side exit guiding ramp surfaces 114 and serve cooperatively with the rear tongue and groove interlocks 112 to lock the lateral branch connector 28 in releasable assembly with the lateral branch template 18. The inclined guiding ramp surfaces 114 also cause the lateral branch connector 28 to be drawn into sufficiently tight engagement with the lateral branch connector 18 to define a connectivity assembly that establishes a production flow path and substantially excludes ingress of solids from the H,\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 19 formation into the production flow path. The tightly engaged relation of the lateral branch connector 28 with the lateral branch template 18 also defines a junction connectivity structure of sufficient structural integrity to withstand the forces of formation shifting and maintain connectivity of the lateral branch junction with the main well bore. If it is considered desirable to provide additional structure between the lateral connectivity junction and the formation, such as to enhance the structural integrity of the lateral connectivity junction and/or to enhance the fluid sealing and solids excluding capability of the lateral connectivity junction, a liquid composition such as cement or polymer may be used to neutralize the surrounding environment about the connectivity junction by filling the space between the lateral connectivity junction and the formation.

At the lower end of the interlocking section the lateral branch template 18 defines a positive lower connector stop 116 which is engaged by a connector stop member to prevent further downward movement of the lateral branch connector 28. In this regard it should be borne in mind that proper lateral connectivity of the lateral branch connector 28 with the lateral branch liner 30 may be made without downward movement of the lateral branch connector being stopped by the connector stop 116.

Referring now to Figs. 15A, 15B and 15C, the lateral branch connector 28 is shown in detail, with the upper section thereof being shown in Fig. 15A. The isometric illustrations of Figs. 15A and 15B are oriented for viewing the inner side of the lateral branch connector 28. In contrast, the isometric illustration of Fig. is arranged to show the outer side of the lateral branch connector 28 and particularly the flexing section 134 which permits elastic or plastic deformation of the lateral branch connector 28 to permit its bending to direct it from coaxial relation with the lateral branch template 18 to the angulated, laterally diverted relation H.\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 20 shown in Figs. 13A and 13B as the lateral branch connector 28 is moved forwardly into seated and interlocked relation within the lateral branch template 18. The lateral branch connector 28 defines an upper tubular section 118 having a side opening 120 that is defined by a cut-away section having opposed side edges 122 and 124. As shown in Fig.

the side edges 122 and 124 merge with rear locking features 126 and 128 that are oriented for interlocking relation with the rear tongue and groove interlocks 112 of the lateral branch template 18. The side opening 120 and the interlocking section of the lateral branch connector 28 is further defined by front locking features 130 and 132 which are adapted for interlocking relation with the front tongue and groove interlocks 115. As the lateral branch connector 28 is moved downwardly within the lateral branch template 18 the front (130, 132) and rear (126, 128) locking features thereof will be moved into interlocking relation with the front 115 and rear 112 tongue and groove interlocks. Since the tongue and groove interlocks are inclined with respect to the longitudinal axis of the lateral branch template 18 to thus form guide ramps, the lateral branch connector 28 will be forced to follow the inclined path of the guide ramp interlocking geometry as the lateral branch connector is moved forwardly within the lateral branch template 18. As this activity occurs, the lateral branch connector 28 will be elastically and/or plastically deformed in that its forward end will be diverted from a co-axial relation with the lateral branch template 18 and main well casing and thus will be caused to follow the inclined path and move through the lateral opening of the template 18, through the casing window 24 and into the lateral branch bore 26.

As shown in Fig. 15C the lateral branch connector 28 defines a flexing section 134 which is shown in Fig. and is developed by cutting away an exterior section of the lateral branch connector 28 located opposite the side opening 120. Thus, as bending force is applied to the H,\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 21 lateral branch connector 28 by the ramping action of the front and rear tongue and groove interlocks, the lateral branch connector 28 will be deformed or flexed predominantly in the flexing section 134 to permit its front end to move through the casing window 24 and into the lateral branch bore 26.

When it is desired to ensure that the lateral branch connector 28 is in a substantially relaxed condition after its installation has been completed, the connector is pre-bent or pre-formed to the typically curved configuration that it will have. In this case, it may be physically straightened as necessary during its transit through the main well bore to permit its movement through the main well casing. Then, when the lateral branch connector 28 is diverted through the casing window 24 and into the lateral branch bore 26 by the lateral branch template 18, it will return to its relaxed pre-bent or pre-curved condition. This feature may be especially important to minimize the potential for stress corrosion of the metal when the formation fluid being produced has elevated hydrogen sulfide content, such as when the production fluid is sour crude oil or sour natural gas.

As explained above, it is not necessary for the lateral branch connector 28 to move downwardly to its full extent in order for lateral branch connectivity to be established. In the event, however, that the lateral branch connector 28 is moved downwardly to its full extent, a stop projection 136 will become shouldered against an arcuate stop shoulder that is defined by the lower connector stop 116 to prevent further forward movement of the lateral branch connector. If fluid connectivity has not been established at this point the lateral branch connector 28 must be withdrawn and its installation procedure repeated.

As an option, the lower section of the lateral branch template 18 located below the lateral connection and/or the upper section of the lateral branch template Ht\flanagan\keep\SPECITICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 22 located above the lateral connection may include permanent measuring and production control equipment or may include mechanical features to support temporary measuring and/or production control equipment.

As an additional option, the lateral branch junction connection assembly comprising the lateral branch template and lateral branch connector may facilitate location therein of an active diverting device which, after the lateral branch junction has been completed, functions to divert any equipment intended for location within the lateral branch bore from the main well bore into the lateral branch bore. Installation and retrieval of the active diverting device is achieved by conventional running and retrieval equipment. It should be noted that a diverter device will not be installed in the lateral branch junction at the time the lateral branch junction is being installed. During installation of the lateral branch junction it is desirable that both the main well bore and the lateral branch bore be unobstructed so that fluid pressure returns may be employed to confirm proper assembly of the junction in the downhole environment.

Only after proper installation of the junction connection assembly has been confirmed will a diverter be temporarily installed within the junction for diverting various tools and equipment, such as control valves, formation fluid parameter sensors, and logging tools, from the main well bore into a selected lateral branch bore.

The lateral branch connector is designed to establish an interlocking and substantially sealed connection with the lateral branch template to withstand loads that are induced thereto while running the liner or other equipment into the lateral branch, to withstand forces that may be caused by formation shifting, and to provide for exclusion of solids from the flow path that is defined by the junction. The interlocking assembly also provides for securing the lateral branch connector in fixed position and orientation with respect to the H:\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 23 template. The lateral branch connector also supports a production tubular (the liner) connected to the lateral outlet. The lateral branch connector further defines a lateral opening which permits fluid and production tools to pass through the junction and into the main production bore below the junction. At its upper portion the lateral branch connector has geometric features matching the template to allow retaining the lateral branch connector at a pre-determined position within the main well bore.

The lateral branch connector is also provided with an orienting, guiding and interlocking mechanism which allows for conveying the lateral branch connector into the lateral branch template, securing the lateral branch connector in the main template bore and to prepare the lateral branch connector for supporting forces that may be induced by shifting of the surrounding formation or by the pressure of produced fluid in the branch junction.

The lateral liner connects to the lateral branch connector at its upper end and connects to the upper portion of a lateral liner that has been installed prior to installing the connecting apparatus. Alternatively, the lateral liner may be set into the open well bore of the lateral branch along its entire length or along a portion of the lateral branch. The lateral liner also has any properties of liners that are installed in wells to isolate production or injection zones from other formations. The lateral liner may be or may not be cemented in the lateral bore depending upon the desires of the user. The mechanically interlocked relation with the lateral branch template and lateral branch connector obviates the need for cementing because, unlike conventional cemented junctions, the lateral liner, without cement, is structurally capable of withstanding mechanical or pressure induced forces that cause failure of conventional cemented lateral branch junctions.

As an alternative, the lateral liner may carry inside or outside its wall reservoir monitoring equipment H,\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-OO.doc 02/04/2003 24 which measures, processes, and transmits important data that identifies the evolution of reservoir characteristics while producing hydrocarbon products. This information may be transmitted to surface via suitable transmission means such as electric conductor cables, or electromagnetic or induction telemetry through or along the liner itself, provided adequate relays and connections are provided up to the lateral connection with the parent well.

In view of the foregoing it is evident that the present invention is one well adapted to attain all of the objects and features set forth above, together with other objects and features which are inherent in the apparatus disclosed herein.

As will be readily apparent to those skilled in the art, the present invention may be produced in other specific forms without departing from its spirit or essential characteristics. The present embodiment is, therefore, to be considered as merely illustrative and not restrictive, the scope of the invention being indicated by the claims rather than the foregoing description, and all changes which come within the meaning and range of equivalence of the claims are therefore intended to be embraced therein.

It is to be understood that, if any prior art publication is referred to herein, such reference does not constitute an admission that the publication forms a part of the common general knowledge in the art, in Australia or any other country.

For the purposes of this specification it will be clearly understood that the word "comprising" means "including but not limited to", and that the word "comprises" has a corresponding meaning.

H.\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-OO.doc 02/04/2003

Claims (15)

1. 2. An apparatus to communicate electrical signaling from a main bore of a well to equipment in a lateral branch, comprising: a connector mechanism connecting equipment in the main bore to equipment in the lateral branch; and a first inductive coupler portion attached to the connector mechanism to communicate electrical signaling with the lateral branch equipment.
2. 3. The apparatus of claim 2, further comprising an electrical cable connected to the inductive coupler portion.
3. 4. The apparatus of claim 3, further comprising a second inductive coupler portion connected to the electrical cable and attached to the connector mechanism, the second inductive coupler portion adapted to communicate signaling with the main bore equipment. The apparatus of claim 4, further comprising a third inductive coupler portion that is part of the main bore equipment to inductively couple to the second inductive coupler portion.
4. 6. The apparatus of claim 5, further comprising a fourth inductive coupler portion that is part H.\Elanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 26 of the lateral branch equipment to inductively couple to the first inductive coupler portion.
5. 7. A completion string for use in a well having a main bore and a lateral branch, comprising: equipment in the main bore and in the lateral branch; a first inductive coupler assembly proximal the equipment in the main bore; a second inductive coupler assembly proximal the equipment in the lateral branch; and an electrical cable connecting the first and second inductive coupler assemblies.
6. 8. The completion string of claim 7, wherein the equipment in the main bore includes a tubing, the completion string further comprising a connector member between the tubing and the lateral branch equipment.
7. 9. The completion string of claim 8, wherein the lateral branch equipment includes an electrical device. The completion string of claim 9, wherein the electrical device includes a monitoring module.
8. 11. The completion string of claim 9, wherein the electrical device includes a control module.
9. 12. The completion string of claim 8, further comprising a casing having a window open to the lateral branch, wherein the connector member extends through the casing window. H,\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003 27
10. 13. The completion string of claim 8, wherein the first inductive coupler assembly includes one portion attached to the tubing and another portion attached to the connector member.
11. 14. The completion string of claim 13, wherein the second inductive coupler assembly includes one portion attached to the connector member and another portion attached to the lateral branch equipment. A method of communicating between main bore equipment and lateral branch equipment in a well, comprising: providing a first inductive coupler assembly electrically connected to the main bore equipment and in communication with the lateral branch equipment; and transmitting electrical signaling over an electrical cable connected to the first inductive coupler assembly.
12. 16. The method of claim 15, further comprising: providing a second inductive coupler assembly electrically connected to the lateral branch equipment; and electrically connecting the second inductive coupler assembly to the first inductive coupler assembly.
13. 17. An apparatus as claimed in any one of claims 1 to 6, and substantially as herein described with reference to the accompanying drawings.
14. 18. A completion string as claimed in any one of claims 7 to 14, and substantially as herein described with reference to the accompanying drawings. H:\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-OO.doc 02/04/2003 28
15. 19. A method as claimed in claim 15 or claim 16, and substantially as herein described with reference to the accompanying drawings. Dated this 2nd day of April 2003 SCHLUMBERGER TECHNOLOGY B.V. By their Patent Attorneys GRIFFITH HACK Fellows Institute of Patent and Trade Mark Attorneys of Australia H\flanagan\keep\SPECIFICATIONS\P48979 Divisional of 23465-00.doc 02/04/2003