AU745010B2 - Method and apparatus for establishing branch wells at a node of a parent well - Google Patents

Description

AUSTRALIA

Patents Act 1990 COMPLETE SPECIFICATION STANDARD PATENT Applicant(s): ANADRILL INTERNATIONAL, S.A.

Invention Title: METHOD AND APPARATUS FOR ESTABLISHING BRANCH WELLS AT A NODE OF A PARENT WELL .9 9 9* The following statement is a full description of this invention, including the best method of performing it known to me/us: ANA034 19.211 APPLICATION FOR PATENT TITLE: METHOD AND APPARATUS FOR ESTABLISHING BRANCH WELLS AT A NODE OF A PARENT WELL INVENTOR(S): HERVE' OHMER CROSS-REFERENCE TO RELATED APPLICATIONS This application claims priority from Provisional Application No. 60/013,227, filed March 11, 1996, and Provisional Application No. 60/025.033, filed August 27, 1996, the contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION Field of the Invention This invention relates generally to the field of wells, particularly to the field of establishing branch wells from a parent hydrocarbon well. More particularly the invention relates to establishing multiple branch wells from a common depth point, called a node, deep in the well.

Description of the Related Art Multiple wells have been drilled from a common location, particularly while drilling from an offshore platform where multiple wells must be drilled to cover the great expenses of offshore drilling. As illustrated in Figures 1A and IB. such wells are drilled through a common conductor pipe, and each well includes surface casing liners, intermediate casing and parent casing as is well known in the field of offshore drilling of hydrocarbon wells.

Branch wells are also known in the art of well drilling as illustrated in Figure 2. Branch wells 1/ are created from the parent well, but necessarily the parent well extends below the branching point of the primary well. As a result, the branching well is typically of a smaller diameter than that of the primary well which extends below the branching point. Furthermore, difficult sealing problems have faced the an for establishing communication between the branch well and the primary well.

For example, U.S. Patent 5,388,648 describes methods relating to well juncture sealing with various sets of embodiments to accomplish such sealing. The disclosure of the '648 patent proposes solutions to several serious sealing problems which are encountered when establishing branches in a well. Such sealing problems relate to the requirement of ensuring the connectivity of the branch casing liner with the parent casing and to maintaining hydraulic isolation of the juncture under differential pressure.

A fundamental problem exists in establishing branch wells at a depth in a primary well in that apparatus for establishing such branch wells must be run on parent casing which must fit within intermediate casing of the well. Accordingly, any such apparatus for establishing branch wells must have an outer diameter which is essentially no greater than that of the parent casing.

S Furtherriore, it is desirable that when branch wells are established, they have as large a diameter as possible. Still further, it is desirable that such branch wells be lined with casing which may be established and sealed with the branching equipment with conventional casing hangers.

i: An important object of this invention is to provide an apparatus and method by which multiple branches connect to a primary well at a single depth in the well where the branch wells are controlled and sealed with respect to the primary well with conventional liner-to-casing connections.

Another important object of this invention is to provide a multiple outlet branching sub ha-ing an outer diameter such that it may be run in a well to a deployment location via primary casing.

Another object of this invention is to provide a multiple outlet branching sub in which multiple outlets are fabricated in a retracted state and are expanded while downhole at a branching deployment location to produce maximum branch well diameters rounded to provide conventional liner-to-casing connections.

Another object of this invention is to provide apparatus for downhole expansion of retracted outlet members in order to direct each outlet into an arcuate path outwardly from the axis of the _~ir~Jrar~~~ slr-~j -3 primary well and to expand the outlets into an essentially round shape such that after a branch well is drilled through an outlet, conventional liner-to-casing connections can be made to such outlet members.

SUMMARY OF THE INVENTION According to the present invention there is provided a method of forming a branch well from a parent well, the method comprising the steps Of: running a branching sub with a parent casing through a parent well to a branching location, said branching sub including a branching chamber and multiple branching outlets; and expanding and forming at least one of said branching outlets until it extends in a path beyond the diameter of said branching chamber.

According to the present invention there is further 20 provided a method of expanding and forming downhole at least one outlet member of a branching sub comprising a 0000.:plurality of outlet members, the method comprising the steps of: *:.00:positioning a forming tool in said branching sub, said forming tool having at least one forming head; o o acstating said at least one forming head to expand and form said at least one outlet member.

According to the present invention there is still further provided a branching sub for deployment in a borehole, comprising: an open first end of cylindrical shape adapted for connection with a string of well casing; a plurality of branching outlet members in fluid communication with said first end, at least one of said H:\Shona1\Keep\Speci\P3845S BRANCH WELLS OF A PARENT WELL 14/01/02 -4 plurality of outlet members being expandable and in a retracted state, said plurality of outlet members collectively defining an effective outer diameter less than the diameter of said first end; and wherein said at least one outlet member is adapted for expansion and forming to an expanded state wherein said at least one outlet member extends in a path beyond the diameter of said first end.

BRIEF DESCRIPTION OF THE DRAWINGS The objects, advantages and features of the invention will become more apparent by reference *.aa a H:\Shona1\Keep\Speci\P38455 BRANCH WELLS OF A PARENT WELL 14/01/02 to the drawings which are appended hereto and wherein an illustrative embodiment of the invention is shown, of which: Figures I A and I B illustrate a prior art triple liner packed in a conductor casing termination in which the outlet members are round during installation and are packed to fit within the conductor casing; Figure 2 illustrates a prior art parent or vertical well and lateral branch wells which extend therefrom; Figures 3A, 3B, and 3C illustrate a three outlet branching sub according to the present invention where Figure 3A is a radial cross-section through the branching outlets of the sub, with one outlet completely in a retracted position, with another outlet in a position between its retracted position and its fully expanded position, and the third outlet being in a fully expanded position, and V where Figure 3 B is a radial cross-section through the branching outlets of the sub with each of the outlets fully expanded after deployment in a parent well. and Figure 3C is an axial cross-section of the branching sub showking two of the branching outlets fully expanded to a round shape in which casing has been run into a branch well and sealed with respect to the branching outlets by means of conventional liner hanging packers.

Figure 4 is a perspective view of a three symmetrical outlet branching sub of the present invention wvith the outlet branches expanded.

Figures 5A, 5B. 5C. and 5D illustrate configurations of the present invention with asymmetrical branching outlets with at least one outlet having larger internal dimensions than the *.:other two, wkith Figure 5A being a radial cross-section through the branching outlets along line SA in a retracted position. with Figure 5B being an axial cross-section through the lines SB-SB of Figure 5A. with Figure 5C being a radial cross-section along lines SC-SC of Figure SD with the branching outlets in an expanded position, and with Figure 5D being an axial cross-section along lines SD-SD of Figure 5C with the branching outlets in an expanded position; Figures 6A-6E illustrate radial cross-sections of several examples of branching outlet configurations of the branching sub according to the invention, with all outlet branches fully expanded from their retracted state during deployment in a parent well. with Figure 6A illustrating two equal diameter outlet branches. Figure 6B illustrating three equal diameter outlet branches.

Figure 6C, like Figure 5C, illustrating three outlet branches with one branch characterized by a larger diameter than the other two, with Figure 6D illustrating four equal diameter outlet branches. and with Figure 6E illustrating five outlet branches with the center branch being of smaller diameter than the other four; Figures 7A-7E illustrate stages of expanding the outlet members of an expandable branching sub according to the invention, with Figure 7A illustrating an axial cross-section of the sub showing multiple branching outlets with one such outlet in a retracted position and the other such outlet being expanded starting with its connection to the branching head and continuing expansion downwardly toward the lower opening of the branching outlets, with Figure 7B illustrating a radial cross-section at axial position B of Figure 7A and assuming that each of three symmetrical branching outlets are being expanded simultaneously, and with Figures 7C through 7E showing various stages of expansion as a function of axial distance along the branching outlets: Figures 8A and 8B illustrate respectively in axial cross-section and a radial cross-section along lines 813-813, latching and orientation profiles of a branching chamber of the branching sub, and Figure 8A further illustrates an extension leg and supporting shoe for deployment in a parent well and for providing stability to the branching sub while expanding the branching outlets from their retracted position; F Figure 9 schematically illustrates uphole and downhole apparatus for expanding the branching outlets of the branching sub; Figure 10 illustrates steps of the process of expanding and forming the branching outlets with :a pressure forming pad of the apparatus of Figure 9; Figures 1 IlA- IIH illustrate steps of an installation sequence for a nodal branching sub and for creating branch wells from a parent well according to the invention: Figure 12 illustrates a branching sub deployed in a parent well and further illustrates branch well liners hung from branching outlets and still further illustrates production apparatus deployed in the branching sub for controlling production from branch wells into the parent well: Figures IS3A and 1 3B geometrically illustrate the increase in branch well size achievable for this invention as compared wkith prior art conventional axial branch wells from liners packed at the end of parent casing:- -6- Figures 14A-14D are illustrative sketches of nodal branching according to the invention where Figure 14A illustrates establishing a node in a parent well and establishing branch wells at a common depth point in the parent well, all of which communicate with a parent well at the node of the parent well; with Figure 14B illustrating an expanded branching sub which has had its branching outlets expanded beyond the diameter of the parent casing and formed to be substantially round; with Figure 14C illustrating using a primary node and secondary nodes to produce hydrocarbons from a single strata; and with Figure 14D illustrating using an expanded branching sub from a primary node to reach multiple subterranean targets; Figure 15A illustrates a two outlet version of a branching sub according to the invention, with Figures 15B, 15B', 15C,. and 15D illustrating cross-sectional profiles of such two outlet version of a branching sub with an alternative post-forming tool at various depth locations in the outlet members; Figure 16 illustrates a two arm alternative version of a post-forming tool; and Figures 1 7A- 17D illustrate the operation of such alternative post-forming tool.

DESCRIPTION OF THE PREFERRED

EMBODIMENTS

As described above, Figures 1A and 1B illustrate the problems with prior art apparatus and methods for establishing branch wells from a parent well. Figures IA and 1B show radial and axial cross-sections of multiple outlet liners 12 hung and sealed from a large diameter conductor pipe The outlets are round in order to facilitate use of conventional lining hanger packers 14 to seal the outlet liners 12 for communication with the conductor pipe 10. The arrangement of Figures 1A and 1B requires that multiple round outlets of diameter Do fit within the diameter Dsl of the conductor pipe 10. In many cases. especially where the conductor pipe must be deployed at a depth in the well.

rather than at the surface of the well. it is not feasible to provide a borehole of sufficient outer diameter to allow branch well outlets of sufficient diameter to be installed.

The technique of providing branch wells according to the prior art arrangement depicted in Figure 2 creates branch wells 22. 24 from a primary well 20. Special sealing arrangements 26. unlike conventional casing hangers. must be provided to seal a lined branch well 22. 24 to the primary well Description of Brnching Sub According to the Invention Figures 3A, 3B, and 3C illustrate a branching sub 30 according to the invention. The branching sub includes a branching chamber 32, (which may be connected to and carried by parent well casing (See parent casing 604 of Figure and multiple outlet members, for example three outlet members 34, 36, 38 illustrated in Figures 3A, 3B, and 3C. Figure 3A is a radial cross-section view through the branching chamber 32 which illustrates one outlet member 34 in a retracted state, a second outlet member 36 in the state of being expanded outwardly, and a third outlet member 38 which has been fully expanded outwardly. (Figure 3A is presented for illustrative purposes, because according to the invention it is preferred to'expand and circularize each of the outlets simultaneously.) In the retracted state, each outlet is deformed as shown particularly for outlet member 34. A round tube is deformed such that its cross-sectional interior area remains essentially the same as that of a circular or round tube, but its exterior shape is such that it fits cooperatively with the deformed shape of the other outlet members, all within an imaginary cylinder having a diameter essentially the same as that of the branching chamber 32. In that way the branching chamber 32 and its retracted outlet members have an effective outer diameter which allows it to be run in a parent well to a deployment location while attached to a parent casing. Outlet member 34 in its retracted state is illustrated in an oblong shape, but other retracted shapes may also prove to have advantageous characteristics. For example, a concave central area of deformation in the outer side of a retracted outlet member may be advantageous to provide a stiffer outlet member. Such deformation is progressively greater and deeper starting from the top to the bottom of the outlet member.

Figure 3A shows outlet member 36 in a state of being expanded in an arcuate path outwardly from the branching chamber 32 while simultaneously being rounded by a downhole forming-expanding tool that is described below. The arrows labeled F represent forces being applied from the interior of the outlet member 36 in order to expand that outlet member both ourwai.-y in an arcuate path away from branching chamber 32 and to circularize it from its retracted state (as is the condition of outlet member 34) to its expanded or fully deployed state like outlet member 38.

Figure 3B is a radial cross-section as viewed by lines 3B-3B of Figure 3C through the branching -8- I

C

sub 30 at the level of outlet members 36, 38. Figure 3C illustrates conventional casing liners 42, 44 which have been installed through branching chamber 32 and into respective outlet members 36, 38. Conventional liner hanging packers 46, 48 seal casing liners 42, 44 to outlet members 36, 38.

As illustrated in Figures 3B and 3C, if the diameter Ds2 of the branching chamber 32 is the same as the diameter Dsl of the conductor pipe of prior art Figure 1 B, then the outlet diameter Dc of Figure 3C is 1.35 times as great as the outer diameter Do of Figure lB. The liner cross-sectional area Sc of the sub of Figure 3C is 1.82 times as great as the liner cross-sectional area So of Figure 1A. When fully expanded, the effective diameter of the expanded outlet members 34, 36, 38 exceeds that of the branching chamber 32.

Figure 4 is a perspective view of the branching sub 30 of Figures 3A, 3B, 3C where the branching sub is shownafter expansion. Threads 31 are provided at the top end of branching chamber 32. Threads 31 enable branching sub 30 to be connected to a parent casing for deployment at a subterranean location. Outlet members 34. 36. 38 are shown expanded as they would look downhole at the end ofa parent well.

-Figures 5A-5D illustrate an alternative three outlet branching sub 301 according to the invention. Figures 5A and 5B illustrate in radial and axial cross-section views the sub 301 in its retracted position. Outlet members 341. 361 and 381 are illustrated with outlet member 361 being about equal to the combined radial cross-sectional area of outlet members 341 and 381 combined.

Each of the outlet members are deformed inwardly from a round tubular shape to the shapes as illustrated in Figure 5A whereby the combined deformed areas of outlet members 341, 361 and 381 .i substantially fill the circular area of branching chamber 321. Other deformation shapes may be advantageous as mentioned above. Each deformed shape of outlet members 341, 361 and 381 of Figure 5A is characterized by (for example, of the outlet member 341 a circular outer section 342 and one or more connecting, non-circular sections 343. 345. Such non-circular sections 343. 345 are cooperatively shaped with section 362 of outlet member 361 and 382 of outlet member 381 so as to maximize the internal radial cross-sectional areas of outlet members ,41. 361 and 381.

Figures SC and 5D illustrate the branching sub 301 of Figures 5A and 5B after its outlet members have been fully expanded after deployment in a parent well. Outlet members 361 and 381 are illustrated as having been simultaneously expanded in a gently curving path outwardly from the -9axis of branching chamber 321 and expanded radially to form circular tubular shapes from the deformed retracted state of Figures 5A and Figures 6A-6E show in schematic form the size of expanded outlet members as compared to that of the branching chamber. Figure 6A shows two.outlet members 241, 242 which have been expanded from a deformed retracted state. The diameters of outlet members 241 and 242 are substantially greater in an expanded state as compared to their circular diameters if they could not be expanded. Figure 6B repeats the case of Figure 3B. Figure 6C repeats the uneven triple outlet configuration as shown in Figures 5A-5D. Figure 6D illustrates four expandable outlet members from a branching chamber 422. Each of the outlet members 441,442, 443, 445 are of the same diameter. Figure 6E illustrates five outlet members, where outlet member 545 is smaller than the :other four outlet members 541, 542, 543. 544. Outlet member 545 may or may not be deformed in the retracted state of the branching sub.

Description of Method for Expanding a Deformed Retracted Outlet Member -Figures 7A-7E illustrate downhole forming heads 122, 124, 126 operating at various depths o in outlet members 38, 34, 36. As shown on the right hand side of Figure 7A, a generalized forming head 122 is shown as it enters a deformed retracted outlet member, for example outlet member 38, at location B. Each of the forming heads 122, 124, 126 has not yet reached an outlet member, but the heads have already begun to expand the outlet wall of branching chamber 32 outwardly as illustrated in Figure 7B. The forming heads 122, 124, 126 continue to expand the outlet members outwardly as shown at location C. Figure 7C shows the forming heads 122, 124, 126 expanding the outlet members outwardly while simultaneously circularizing them. Forming pads 123, 125, 127 are forced outwardly by a piston in each of the forming heads 122. 124. 126. The forming heads simultaneously bear against central wall region 150 which acts as a reaction body so as to simultaneously expand and form the outlet members 38. 34. 36 while balancing reactive forces while expanding. Figures 7D and 7E illustrate the forming btep locations D and E of Figure 7A.

Figures 8A and 8B illustrate an axially extending slot 160 in the branching chamber 32 of branching sub 30. Such slot 160 cooperates with an orienting and latching sub of a downhole forming tool for radial positioning of such orienting and latching sub for forming and expanding the multiple outlet members downhole. A notch 162 in branching chamber 32 is used to latch the downhole forming tool at a predetermined axial position.

An extension leg 170 projects downwardly from the central wall region 150 of branching sub 30. A foot 172 is carried at the end of extension leg 170. In operation, foot 172 is lowered to the bottom of the borehole at the deployment location. It provides support to branching sub during forming tool expanding and other operations.

Description of Forming Tool a) Description of Embodiment of Figures 9. Figures 9 and 10 illustrate the forming tool used to expand multiple outlet members, for :example outlet members 34, 36, 38 of Figures 3A, 3B, and 3C and Figures 7B, 7C, 7D and 7E. The forming tool includes uphole apparatus 100 and downhole apparatus 200. The uphole apparatus 100 "includes a conventional computer 102 programmed to control telemetry and power supply unit 104 S* and to receive commands from and display information to a human operator. An uphole winch unit 106 h.s-an electrical wireline 110 spooled thereon for lowering downhole apparatus 200 through a parent well casing and into the branching chamber 32 of a branching sub 30 which is connected to and carried at the end of the parent casing.

The downhole apparatus 200 includes a conventional cable head 202 which provides a strength/electrical connection to wireline 110. A telemetry, power supplies and controls module 204 includes conventional telemetry, power supply and control circuits which function to communicate with uphole computer 102 via wireline 110 and to provide power and control signals to downhole modules. Hydraulic power unit 206 includes a conventional electrically powered hydraulic pump for producing downhole pressurized hydraulic fluid. An orienting and latching sub 208 includes a latching device 210 (schematically illustrated) for fitting within notch 162 of branching chamber 32 of Figure 8A and an orienting device 212 (schematically illustrated) for cooperating with slot 160 of branching chamber 32. When the downhole apparatus 200 is lowered into branching sub orienting device 212 enters the slot 160 and the downhole apparatus 200 is further lowered until the latching device 210 enters and latches within notch 162.

Fixed traveling head 213 provides hydraulic fluid communication between hydraulic power unit 206 and the traveling forming heads 122, 124. 126, for example. Telescopic links 180 provide pressurized hydraulic fluid to traveling forming heads 122. 124, 126 as the heads 122, 124. 126 move downwardly within the multiple outlet members. for example outlet members 34, 36, 38 of Figures 7B-7E. Monitoring heads 182. 184, 186 are provided to determine the radial distance moved while radially forming an outlet member.

Figure 10 illustrates traveling forming heads 126, 124, 122 in different stages of forming an outlet member of branching sub 30. Forming head 126 is shown in outlet member 36, which is illustrated by a heavy line before radial forming in the retracted outlet member 36. The outlet member is shown in light lines 36'. 36'. Where the outlet member is depicted as 36' in an intermediate stage of forming and as 36" in its final formed stage.

The forming head 124 is shown as it is radially forming retracted outlet member 3 4 (in light line) to an interme-diate stage 34'. A final stage is illustrated as circularized outlet member 34". The forming head 124. like the other two forming heads 126. 122, includes a piston 151 on which forming pad 125 is mounted. Piston 151 is forced outwardly by hydraulic fluid applied to opening hydriulic line 152 and is forced inwardly by hydraulic fluid applied to closing hydraulic line 154.

A caliper sensor 184 is provided to determnine the amount of radial travel of piston 151 and formning pad 125, for example. Suitable seals are provided between the piston 151 and the forming head 124.

The forming head 122 and forming pad 123 are illustrated in Figure 10 to indicate that under certain circumstances the shape of the outlet member 38 may be "over expanded" to create a slightly oblong shaped outlet, such that when radial formning force from forming pad 123 and forming head 122 is removed, the outlet will spring back into a circular shape due to residual elasticity of the steel outlet member.- At the level of the branching chamber 32. forming heads 122, 124. 126, balance each other against the reaction forces while forcing the wvalls of the chamber outw, ardly. Accordingly, the forming heads 122. 124. 126 are operated simultaneously, for example at level B of Figure 7A. while forcing the lower enid of the wall of the branching chamber 32 outwardly. When a forming head 122 enters an outlet member 38 for example. the pad reaction forces are evenly supported by the central wall reg-ion 150 of the branching chamber 32. The telescopic links 180 may be rotated a small amount so that the forming pads 127. 125. 123 can apply pressure to the right or left from the normal -12- C S

C.

V

*VV.

C. CC C C axis and thereby improve the roundness or circularity of the outlet members. After a forming sequence is performed, for example at location D in Figure 7A, the pressure is released from piston 1. and the telescopic links 180 lower the forming heads 122, for example, down by one step. Then the pressure is raised again for forming the outlet members and so forth.

The composition of the materials of which the branching sub 30 is constructed is preferably of an alloy steel with austenitic structure, such as manganese steel, or nickel alloys such as "Monel" and "Inconel" series. Such materials provide substantial plastic deformation with cold forming thereby providing strengthening.

b) Description of Alternative Embodiment of Figures 15A- I5D. 16 and 17A- I7D An alternative post-forming tool is illustrated in Figures 15A, 1513, 1513', 15C, 15D, 16, and 17A-1I7D. The post-forming tool 1500 is supported by common downhole components of Figure 9 includi ng a cable head 2-02. telemetry, power supplies and controls module 204, hydraulic power unit 206 and an orienting and latching sub 208. Figure 16 illustrates that post-forming tool 1500 includes a travel actuator 1510. A piston 1512 of travel actuator 1510 moves from an upper retracted position as shown in Figure 17A to a lower extended position as shown in Figures 17C and 17D.

Figure 1 7B shows the piston 15 12 in an intermediate position. Piston 1512 moves to intermediate positions depending on the desired travel positions of forming heads in the outlet members.

Figures 16 and 1 7D illustrate a two forming head embodiment of the post-formning tool 1500 where two outlet members see outlet members 1560 and 1562 of Figures 15A-15D) are illustrated. Three or more outlet members may be provided with a corresponding number of forming heads and actuators provided. Links 1514 connect the piston 1512 to actuator cylinders 1516.

Accordingly, actuator cylinders 1516 are forced downwardly into outlet members 1560, 1562 as piston 1512 moves downwardly.

Actuator cylinders 1516 each include a hydraulically driven piston 1518 which receives pressurized hydraulic fluid from hydraulic power unit 206 (Figure 9) via travel actuator 15 10 and iinks 1514. The piston 1518 is in an upper position as illustrated in Figures 1 7A and 1 7C and in a lower position as illustrated in Figures 1 7B and I 7D.

The actuator cylinders 1 516 are pivotally linked via links 1524 to forming pads 1520. The pistons 1518 are linked via rods 1526 to expanding rollers 1522. As shown in Figures 17A and -13the forming pads 1520 enter an opening of two retracted outlet members as illustrated in Figure 15SB. The expanding rollers 1522 and forming pads 1520 are in a retracted position within retracted outlet members 1560, 1562.

The piston 1512 is stroked downwardly a small amount to move actuator cylinders 1516 downwardly a small amount. Next, pistons 1518 are stroked downwardly causing expanding rollers 1522 to move along the inclined interior face of forming pads 1520 causing the pads to push outwardly against the interior walls of retracted outlet members 1560, 1562 until the outlet members achieve a circular shape at that level. Simultaneously, the outlet members are forced outwardly from the axis of the multiple outlet sub 1550. Next, the pistons 1518 are stroked upwardly, thereby returning the expanding rollers 1522 to the positions as shown in Figure 15C. The piston 15 12 is .stroked another small distance downwardly thereby moving the forming pads 1520 further down into the outlet members 1560, 1562. Again. the pistons 1518 are stroked downwardly to further expand the outlet members 1560, 1562 outwardly and to circularize the outlets. The process is continued until the positions of Figures 15D and 17D are reached which illustrate the position of the forming pads'1 520 and actuator cylinders 1516 at the distal end of the multiple outlet members 1560, .1562.

Description of Method for Povidn Banch Wells Figures 1 lA-I lH and Figure 12 describe the process for establishing branch wells from a branching sub 30 in a well. The branching sub 30 is illustrated as having three outlet members 34, 36, 38 (per the example of Figures 3A, 3B, 3C and Figures 7A-7E) but any number of outlets may :also be used as illustrated in Figures 6A-6E. Only the outlets 38, 36 are illustrated from the axial cross-sectional views presented, but of course a third outlet 34 exists for a three outlet example, but it is not visible in the views of Figures 1 lA-i IH or Figure 12.

Figure I IlA shows that the branching sub _30 is first connected to the lower end of a parent casing 604 which is conveyed through intermediate casing 602 (if present). Intermediate casing 602 lines the wellbore and is typically run through surface casing 600. Surface casing 600 and intermediate casing 602 are typically provided to line the %vellbore. The parent casing 604 may be hung from intermediate casing 602 or from the wellhead at the surface of the earth or on a production platform.

-14- The outlet members 36, 38 (34 not shown) are in the retracted position. Slot 160 and notch 162 are provided in branching chamber 32 of branching sub 30 (see Figure 12) to cooperate with orienting device 212 and latching device 210 of orienting and latching sub 208 of downhole apparatus 200 (See Figure When the parent casing 604 is set downhole, the branching sub may be oriented by rotating the parent casing 604 or by rotating only the branching sub 30 where a swivel joint is installed (not illustrated) at the connection of the branching sub 30 with the parent well casing 604. The orienting process may be monitored and controlled by gyroscopic or inclinometer survey methods.

Figure 11B illustrates the forming step described above with forming heads 122, 126 shown forming outlet members 38, 36 with hydraulic fluid being provided by telescopic links 180 from hydraulic power unit 206 and fixed traveling head 213. The outlet members 36, 38 are rounded to maximize the diameter of the branch wells and to cooperate by fitting with liner hangers or packers in the steps described below. The forming step of Figure 11 B also strengthens the outlet members 36, 38 by their being cold formed. As described above, the preferred material of the outlet members .36,j38-of the branching sub is alloyed steel with an austenitic structure, such as manganese steel, .which provides substantial plastic deformation combined with high strengthening. Cold forming (plastic deformation) of a nickel alloy steel, such as "Inconel", thus increases the yield strength of the base material at the bottom end of the branching chamber 32 and in the outlet members 36, 38.

The outlet members are formed into a final substantially circular radial cross-section by plastic deformation.

As described above, it is preferred under most conditions to convey and control the downhole forming apparatus 200 by means of wireline 110. but under certain conditions, under-balanced wellbore conditions. (or in a highly deviated or horizontal well) a coiled tubing equipped with a wireline may replace the wireline alone. As illustrated in Figure 11B and described above, the downhole forming apparatus 200 is oriented, set and locked into the branching sub 30. Latching device 210 snaps into notch 162 as shown in Figure 11B (see also Figure 12). Hydraulic pressure generated by hydraulic power unit 206 is applied to pistons in forming heads 122. 126 that are supported by telescopic links 180. After a forming sequence has been performed, the pressure is released from the pistons, and the telescopic links 180 lower the forming pads down by one step.

Then the pressure is raised again and so on until the forming step is completed with the outlet members circularized. After the outlet members are expanded, the downhole forming apparatus 200 is removed from the parent casing 604.

Figures 11C and 11D illustrate the cementing steps for connecting the parent casing 604 and the branching sub 30 into the well. Plugs or packers 800 are installed into the outlet members 36, 38. The preferred way to set the packers 800 is with a multiple head stinger 802 conveyed either by cementing string 804 or a coiled tubing (not illustrated). A multiple head stinger includes multiple heads each equipped with a cementing flow shoe. The stinger 802 is latched and oriented in the branching chamber 32 of branching sub 30 in a manner similar to that described above with respect to Figure I 1B. As illustrated in Figure 11D, cement 900 is injected via the cementing string 804 into the packers 800, and after inflating the packers 800 flows through conventional check valves (not shown) into the annulus outside parent casing 604, including the bottom branching section 1000.

Next, the cementing string 804 is pulled out of the hole after disconnecting and leaving packers 800 in place as shown in Figure 11E.

As shown in Figure 1 IF, individual branch wells 801) are selectively drilled using any suitable drilling technique. After a branch well has been drilled, a liner 805 is installed, connected, and sealed in the outlet member, 36 for example, with a conventional casing hanger 806 at the outlet of the branching sub 30 (See Figures 11G and 11H). The liner may be cemented (as illustrated in Figure 11 G) or it may be retrievable depending on the production or injection parameters, and a second branch well 808 may be drilled as illustrated in Figure 11H.

Figure 12 illustrates completion of branch wells from a branching sub at a node of a parent well having parent casing 604 run through intermediate casing 602 and surface casing 600 from wellhead 610. As mentioned above, parent casing 604 may be hung from intermediate casing 602 rather than from wellhead 610 as illustrated. The preferred method of completing the well is to connect the branch wells 801. 808 to a downhole manifold 612 set in the branching chamber 32 above the junction of the branch wells 801, 808. The downhole manifold 612 is oriented and latched in branching chamber 32 in a manner similar to that of the downhole forming tool as illustrated in Figures 8A, SB and 1 lB. The downhole manifold 612 allows for control of the production of each respective branch well and provides for selective re-entry of the branch wells 8oi,808 with testing -16- L2i" i or mainLftenlance CqIpment whichnmay be Conveyed bhougti prcduct in cubing 820 ontesrc.

In case of remedial work in dhe cmreac casing 604, Chc doWnjholc manifold 612 can isclate the parent weUl from the braench wcl.Us so01, 808 6Y Pluggingrdi tfle c CCtk Qthe dow-ahole-m'irdfOld 6 12.

This is done by cconveyl ag a p ackt: tchrough productionr cubingt 82 0. and scrting it- in the cutle-t ofE downhole rmanifold 612 befor= disccnnectr- and removing (hc productLion Mubing 3210. Valves cona-ollable& om the surfacz and Cesciag ec.uipmrn can also bez plactrd in Ehe: dC'rLoleeour[ Fhe monoeranifold 612 c-.i also be car:-iectzd tc maultzi-'e cOnpletion tribUin sUch thaIt each branch wej;I so 1, 808 car be imdcc ndccntly conzected to the surface wcl ]Iaad.

in heuse ofa branc~ig sub for 'Ormch weU.. fozmaziorn as described above, Cb- a C.iJl: bzc--rch well configuzic, afflows che use c od.'annadca~y smaller par casian as ccr.-n-ared co that reoL'uired L-1 the prior art as-caateent of EH-7rts [A aund lB. rhe rtla-iccs .ius between thie branching sub diamiccer Ds., ma-ximaur ecanded outlet diianetaer Dc, and the Lmaximum. dia=meter of a ccnverttional axial br-anch Dc for aotwo outlet case is show,;, in Figire l1 and 'cr athree- outet case in Figzure 17B. The sa-me kfid of' ana.Y.sis auc~ics for other Mu1tl=le Outlet ~~nrt.I COMI-arisc to an ccUl-yivan axial1 branchi~ that could be made oF £inesa: sockcd at the en--d of me Carent casing, the branching WCl! methods and araats ofctEc cresea: inventi'on allow a -at;n L'n branch cross-s-cr"'o-,al area nanri-- &om 20 to 80 pernc..

Figuzt 14A-14 D i~usnareL various uses of t4wo n1ode branch well coadguaaicas according to ct inventioa. Figure-s 14A and 14B LUlusntre a braachig sub at a node according to the invenrica. Figurc 14C Mluszazs how branch wells caay be tisc to &ain a siagle strata or rtservoir 1100, whilet Figuzc 14D Mlusnarcs thec use o-F a siingle aode 'cv whicn rnt±1d-le bt-anch wells au-e d:-ectd to dii-er-ta agetones 1120, 1140, 1160. A~yL~cw-mve-_::dsaL1cwl or any Lzrrvencioa., Ojucc~, or. c abamcdorntat separate-. jforri, =7aote wels Var-ious mod-cajrris~ and alterations ;a Qhe described mthod; anid aZO~,.CauW ll~ be ao'careac to cthose skilled in dic arcc of the foregoing descriouca w'cb.do not deaM CM the SoCilir *oz. the inveritcn. For "Is reason. such chan~ges are desL-=d Lo included witlhin the scope of thec acptnded claims5 which;, LrIc!'" 4 Z th_ onIVlY -mitaors to re preset Lvcndcn. Thet descnriot- earu_--Le which s ernlovedfor sttL~ crch &t emnbodirmenc shculd bincetrred as illuscratiebu o Throughout the specification and claims, the words "comprise", "comprises" and "comprising" are used in a non-exclusive sense.

17.-

Claims (25)

1. 2. The method of claim 1, wherein said expanding and forming step is performed upon a plurality of said 15 branching outlets.
2. 3. The method of claim 2, further comprising the steps of: oplugging each of said multiple branching outlets; S. 20 forming a branch borehole through a selected one of said multiple branching outlets; oooo• S•installing a linear in said branch borehole; and :oo: sealing an end of said linear to said selected one of said multiple branching outlets.
3. 4. The method of claim 3, wherein said sealing of said end of said liner to said selected one of said multiple branching outlets is by means of a liner hanger packer. The method of claim 3, further comprising the steps of: forming a branch borehole through a plurality of said multiple branching outlets; installing a liner in each of said plurality of said multiple branching outlets; and sealing an end of each of said liners to a H:\Shona\Keep\Speci\P38455 BRANCH WELLS OF A PARENT WELL 14/01/02 *j ~j s: ii i_ 1,;I I 19 respective end of one of said plurality of said multiple branching outlets.
4. 6. The method of claim 5, further comprising the steps of: installing a downhoie manifold in said branching chamber; completing each branch well; and controlling the production of each branch well to said parent well with said manifold.
5. 7. The method of claim 1, further comprising the step of orienting said branching sub by means of a swivel joint between said branching sub and said parent casing until said multiple branching outlets are disposed in a predetermined orientation.
6. 8. The method of claim 1, further comprising: circularizing said at least one of said branching outlets by means of mechanical pressure.
7. 9. The method of claim 8, further comprising drilling a branch borehole through at least one of said branching outlets. 25 10. The method of claim 1, wherein expanding and forming said at least one of said branching outlets comprises expanding and forming said at least one of said branching outlets until it achieves a substantially round shape.
8. 11. The method of claim 10, wherein said expanding and forming is accomplished by means of a forming tool.
9. 12. The method of claim 11, wherein said forming tool is hydraulically powered. H:\Shonal\Keep\Speci\P38455 BRANCH WELLS OF A PARENT WELL 14/01/02 tj 20
10. 13. The method of claim 10, further comprising the steps of: drilling a branch borehole through at least one of said branching outlets; and installing a liner in said branch borehole.
11. 14. The method of claim 13, further comprising the steps of: installing a manifold in said branching chamber such that an inlet opening in said manifold is aligned with said branch borehole; and running production tubing from an outlet opening in said manifold through said parent well to the surface of the earth.
12. 15. The method of claim 1, further comprising: deforming to a non-circular cross sectional shape at least one outlet member of a branching sub having a plurality of outlet members before the expanding and S 20 forming step; wherein said expanding and forming comprises i expanding and reforming said at least one deformed outlet member to a substantially circular cross sectional shape.
13. 16. The method of claim 15, further comprising the steps of: installing a packer in each of said plurality of outlet members; and injecting cement through said packers and around the exterior of said casing string.
14. 17. The method of claim 16, wherein said packers are installed by means of a multiple head stinger.
15. 18. The method of claim 17, wherein said multiple head stinger is conveyed by means of coiled tubing. H:\Shona\Keep\Speci\P38455 BRANCH WELLS OP A PARENT WELL 14/01/02 x lnr- L-LI -CL' 21
16. 19. A method of expanding and forming downhole at least one outlet member of a branching sub comprising a plurality of outlet members, the method comprising the steps of: positioning a forming tool in said branching sub, said forming tool having at least one forming head; positioning said at least one forming head in said at least one outlet member; and actuating said at least one forming head to expand and form said at least one outlet member. The method of claim 19, wherein said at least one forming head is hydraulically actuated. 15 21. The method of claim 19, further comprising the steps of: moving said at least one forming head to another position progressively further into said at least one coutlet member; and actuating said at least forming head to further expand and form said at least one outlet member.
17. 22. The method of claim 19, further comprising the steps of: 25 providing a plurality of forming heads on said forming tool adapted for positioning in separate ones of said plurality of outlet members; positioning at least one of said plurality of forming heads in a separate one of said plurality of outlet members; and balancing the reaction forces applied by said plurality of forming heads during actuation against a central wall region of said branching sub.
18. 23. A branching sub for deployment in a borehole, comprising: an open first end of cylindrical shape adapted H;\Shonal\Keep\Speci\P38455 BRANCH WELLS OF A PARENT WELL 14/01/02 22 for connection with a string of well casing; a plurality of branching outlet members in fluid communication with said first end, at least one of said plurality of outlet members being expandable and in a retracted state, said plurality of outlet members collectively defining an effective outer diameter less than the diameter of said first end; and wherein said at least one outlet member is adapted for expansion and forming to an expanded state wherein said at least one outlet member extends in a path beyond the diameter of said first end.
19. 24. The branching sub of claim 23, wherein said adaptation for expansion and forming comprises a reaction 15 body between at least two of said plurality of outlet members. The branching sub of claim 24, wherein said reaction body is central to said plurality of outlet 20 members.
20. 26. The branching sub of claim 23, wherein said at *least one outlet member when in a retracted state has a non-circular sectional shape, wherein said at least one 25 outlet member is adapted for expansion and forming to a circular cross sectional shape.
21. 27. The branching sub of claim 26, wherein said adaptation for expansion and forming comprises a reaction body between at least two of said plurality of outlet members.
22. 28. The branching sub of claim 27, wherein said reaction body is central to said plurality of outlet members.
23. 29. The branching sub of claim 23, wherein at least H;\Shonal\Keep\Speci\P38455 BRANCH WELLS OF A PARENT WELL 14/01/02 x~r~l~;nc X a r r -t i 23 two of said plurality of outlet members are predeformed so as to. have substantially identical cross-sectional shapes. The branching sub of claim 23, further comprising a stiffening structure provided at least at a junction between two of said branching outlet members.
24. 31. The branching sub of claim 30, further comprising a stiffening structure provided at the junction between each of said branching outlet members.
25. 32. A method of forming a branch well from a parent well substantially as herein described with reference to and as illustrated in figures 3A to 17D. A method of expanding and forming downhole at least one outlet member of a branching sub comprising a plurality of outlet members substantially as herein described with reference to and as illustrated in figures 20 3A to 17D. *34. A branching sub for deployment in a borehole substantially as herein described with reference to and as illustrated in figures 3A to 17D. Dated this 14 thday of January 2002 ANADRILL INTERNATIONAL S.A. By their Patent Attorneys GRIFFITH HACK Fellows Institute of Patent and Trade Mark Attorneys of Australia H-\Shona1\Keep\SpeCi\P38455 BRANCH WELLS OF A PARENT WELL 14/01/02