NO313597B1 - The invention device - Google Patents

Description

The background of the invention

Field of the invention

The invention relates to oil well intervention. More specifically, the invention relates to a device for providing selectable access to special side branches for intervention, whereby the angle and orientation of the intervention string is determined.

The position of the technique

as a person skilled in the art will no doubt be aware of, a previously known method for intervention in a side branch consists in simply measuring the length of pipe that is immersed in the hole. Although this method has been used for many years, it has always been problematic due to the very large stretches involved. E.g. a deviation of two inches (1 inch = 25.4 mm) would not appear to be significant when laying 100 feet (1 foot = 305 mm) of pipe. However, this is not the case when dealing with twenty thousand feet of pipe. In keeping with the example, two inches would be 400 feet. A deviation of this magnitude can significantly prevent operation of the well. It will therefore be in the industry's interest to be able to reduce the deviation to a minimum in order to maintain accuracy even at great depths.

It is clear that spring-loaded piles are nothing new in the art and have been used for various purposes including the placement of tools, but the combination of features that make the invention valuable has not, however, been thought of before.

Summary of the Invention

According to the invention, the above-mentioned and other disadvantages and shortcomings of the state of the art are overcome or reduced by a guide wedge device as stated in the following claims.

The invention is a device comprising three distinct sections including: 1) an orientation device which acts to align a guide wedge at an angle with a bore in a gasket; 2) an adjustment pipe part which can be adjusted prior to driving the unit which ensures the desired angular position of the guide wedge in relation to the gasket's alignment pipe part; and 3), if a six-inch bore is desired, a centering pipe member which acts to center the guide pipe in the wellbore. Where a six-inch bore is not required, the centering pipe section is not required, and only a spacer long enough to hold the top of the guide pipe in the packing end pipe will be required.

With regard to the orientation device, the device according to the invention also comprises a collapsible wedge and a number of selectable profiled poles. As one skilled in the art will appreciate by studying the accompanying drawings, the wedge is placed in a helical slot to rotate the device of the invention to the desired and predetermined orientation, while the pawls engage in a profile complementary thereto to prevent further downhole movement of the device. Because of the selectable profile, the device according to the invention can essentially be coded to search out the correct gasket by skipping over all non-conforming gaskets. It is important to note that when first deploying gaskets, one must assess the probability of the pawls catching the wrong gasket due to a larger profile than the pawls. Gasket profiles should be set accordingly to avoid the problem. The wedge of the device, upon reaching the intended packing, will engage a helical slot in the packing and begin to rotate the arrangement to the desired orientation. The screw slot ends in an alignment profile in the gasket. Consequently, as the device according to the invention provides a known orientation between the orientation tube part and the guide wedge, the intervention string will certainly penetrate the side branch as intended. When the pawls engage the selectable profile, downhole movement is stopped and the pawls are locked in place by means of a movable internal mandrel. Where access to the bore of six inches is required, a centering device is used which comprises a set of arms which are normally held within the tool body by means of a barbed section designed to facilitate such holding. The arms are not released until a breaking pin is overcome. A garter spring is provided to assist in pulling the arms back to a position where they are retained by the barb section after being released from the borehole. The arms can be driven out on an angular surface when desired to center the device according to the invention in the bore.

According to another embodiment where intended tool runs do not use tools with an outer diameter greater than 4.75 inches (120.65 mm), the centering tube portion as mentioned above is not necessary. Instead, the top of the guide wedge is retained in the end tube of a gasket over the selected gasket (commercially available from Baker Oil Tools of Houston, Texas) to effect centering, so that the centering tube portion is redundant for this embodiment.

Recycling methods for both designs are also shown.

The above-mentioned and other features and advantages of the present invention will be understood and recognized by experts in the field from the following detailed description and drawings.

Brief description of the drawings:

Reference is now made to the drawings where similar elements are designated by the same numbers in the various figures: Figs. 1A-1I are elongated views of an embodiment of the invention where a six-inch bore is required and centering arms are shown; Fig. 2A-2G is an elongated view of the embodiment according to fig. 1 in activated position; Fig. 3A-3K is an elongated view of a second embodiment of the invention, where a smaller access diameter is required and no centering arms are needed.

Detailed description of the preferred embodiment:

As general reference is made to Fig. 1A-11, as well as in particular to Fig. 1H is a spring wedge 12 positioned in the orientation tube part 14 of the device at an angle complementary to the angle of a helical slot 16 in the inner wall of the pre-assembled gasket. It should be noted that the gasket was fitted to form an anchor for a guide wedge which was initially used to drill the side branch that the rigger now wishes to return to. This provides an excellent anchor as a starting point for returning to the side branch. When the wedge 12 creeps into the slot 16, the device according to the invention is turned to a known orientation by tracking in the slot during downward movement. When the wedge has moved to the lowest point in the slot 16, the position of the deflector in relation to the guide wedge aligning tube part is known. Close to the downhole end of the screw slot 16, there is a selectable profile 22 which is different in each of the seals down the hole. Locking hooks or pawls 20 carry a profile that is complementary only to one of the selectable profiles 22 in one of the downhole packs. If the pawls 20 do not fit the profile 22 in a particular packing, the device according to the invention will skip over this packing and move to a packing further down the hole. It should be pointed out that care is now taken to equip the downhole gaskets with the selectable profiles 22 so that a pawl will not mistakenly engage with a profile 22 in the wrong gasket simply because it is smaller than the opening in the profile. When the pawls 20 do not creep into the profile 22, the downward movement of the device according to the invention is stopped, and the orientation of the device according to the invention is known due to the engagement of the wedge 12 in the screw slot 16. It should be noted that both the wedge 12 and the pawls 20 are spring-loaded and will extend outward to engage their respective intended targets only if sufficient space is available for them to do so (ie the profile is the complementary profile).

To ensure that the pawls 20 remain in secure engagement with the profile 22, plumb bobs are squared from the surface, which act to cut off the pin 24 as shown in the cut-off position in fig. 2G. After the pin 24 is cut, the mandrel 26 moves down the hole to support the pawl 20 into engagement with the selectable profile 22. To prevent the mandrel 26 from moving up the hole and consequently removing the support for the selectable pawl 20, it arranged a locking sleeve (eng.: collet) 28 at the down hole end of the mandrel 26, the mandrel having a number of slots 30 and fingers 32 with raised parts 34. When the mandrel 26 has moved downwards in the hole as described, the fingers 32 will spring outwards, as that the raised elements 34 are left exposed to an opposing surface 36. This prevents inadvertent movement of the mandrel 26 into the hole, as downhole forces are generally not sufficient to deflect the fingers 32 to the extent necessary to release the locking sleeve 28 from the surface 36. However, possible to intentionally release the locking sleeve 28 from the surface 36 by obtaining sufficient traction from the surface to fold the fingers 32 and thereby remove support for selectable pawls 20.

In fig. 1B and 1C another important aspect of the device according to the invention is shown. As many different orientations are possible for side branches on a main borehole in the field, it is necessary to use an adjustment pipe part which will enable orientation of the diverter 40 in relation to the orientation pipe part in order to place the angle face of the diverter 40 towards the side branch in question. In this regard, a rifle tube part (eng.: spline sub) 42 is preferred. The rifle tube part 42 comprises rifles 44 which are complementary with rifles 46 on the centering tube part 48. The rifle tube part 42 and the centering tube part 48 are rotated in relation to each other until the desired angle has been achieved. They are then pushed into engagement with each other and held in the desired position by means of the rifle holder 50 which comprises socket threads 52 complementary to pin threads 54 on the centering tube part 48. The rifle holder 50 prevents disconnection of the rifles.

Seen from below and upwards in the hole from the rifle tube part 42, the centering tube part 48 comprises a number of centering arms 56 which are held for introducing the tool in a position close to the main part of the centering tube part 48. The arms 56 are held in such a position by means of a barb section 66. The arms are articulated with the centering tube part 48 via a pin 60 at various points on the outer diameter of the device. At the downhole end of the arms 56 there are contact parts 62 which slide up an inclined plane 64 and thereby force the arms 56 outwards to contact the casing in the main bore. The part 62 further comprises the barb section 66 which hooks onto a locking projection 68 to help keep the arms in the stowed folded position after the garter spring (eng.: carter spring) 58 has forced the arms back against the part 62.

Activation of the arms 56 is achieved by firing down a plumb line to cut off a second breaker pin according to this embodiment and allowing or forcing the diverter to move down the hole to push the arms against the angled surface thereby forcing them outwards and into contact with the casing in the main bore. With reference to fig. 1B and 1C, the wedge 70 provides both resistance to twisting and the possibility of linear displacement of the outer part of the centering tube part 48. The break pin 72 is arranged to prevent such movement before the desirable time indicated by further lowering of the string to place sufficient weight on the break pin. The wedge 70 is held in place by means of a wedge holder 74 for transferring torque to the tool components down the hole.

As a person skilled in the field will understand, the tool is moved down the hole until the wedge 12 is first caught by the screw slot 16. The tool is turned as it moves further down the hole. Provided that the pawls fit the profile of the profile 22, they will engage with this and thereby prevent further movement of the tool downwards in the hole. Lowering the tool string will cut off a first break pin so that a mandrel can slide in behind the pawls and thereby support them in a locked position. Further lowering of the string will then cut off a second break pin 72 whereby the centering pipe member 48 can slide down into the hole over the mandrel 76 and push the centering arms outward on the faces 64 to center the diverter 40 in the bore for diverting a subsequent tool intended to be inserted into the side branch. The tool is shown in the activated position in the elongated fig. 2.

According to a second embodiment of the invention, as illustrated in fig. 3A-3K, a tool is shown that does not require a centering tube member with extendable arms. However, it should be understood that this tool is intended for use only with other tools having an outside dimension no greater than 4.75 inches and preferably for tools with an outside dimension of 3 inches or less. This design also depends on the gaskets down in the hole being narrow enough that the top of the guide wedge remains at the rear end of the gasket. Where these parameters are satisfied, the need for the centering tube part is eliminated, which leads to a lower price for the device. The guide wedge is kept in a centralized position by its top part being retained in the bore in the gasket in the bore closest to the top. It appears from fig. 3K that the parts which are identical to the previous embodiment and that they have the same numerical references. Further up in the hole, elements of the gasket through which the device according to the invention has passed are shown in fig. 3G-3J. These are conventional elements that need no further mention. In fig. 3G, a spacer tube according to the invention is shown with a broken line to indicate that length has been omitted in the drawings. The purpose of the spacer tube 112 is to give the entire tool, including the guide wedge deflector 114, sufficient length so that the top of the guide wedge remains at the rear end 118 of the closest overlying packing in the hole in relation to the packing that is engaged. This causes the arrester to be centered as stated above. It should be noted that the profile 123 does not fit the pawl 20, and consequently the selectable orientation portion of the invention which was passed by the gasket first shown in fig. 3A-3D. First, when the pawls 20 according to the invention reach the bottom of the package shown in fig. 3K, the pawls will spring out to engage with the profile 22.1 In all other respects, the second embodiment according to the invention works like the first.

Retraction of these tools is achieved by driving conventional fishing tools which grip into locking profiles on the guide wedges of the tools according to the invention. With respect to the 6 inch inlet design, a fishing tool (available from Baker Oil Tools) will pass through the packing bore above the guide wedge to lock onto a profile 65 cut on the outer diameter of the guide wedge. This is shown in fig. 1B. As weight is taken up in the hole, the locking sleeve 28 will contract and thereby allow the mandrel 26 to move upwards in the hole, so that the support of the pawls 20 is removed and the pawls are retracted. On further retraction, the centering arms are pulled back to their resting position by means of the die band spring 58. The protrusion 68 then engages with the barbed section 66 which holds the arms in a retracted position.

ling.

Retraction of the second embodiment of the invention is very similar to the first, but an external fish hall tool (obtainable from Baker Oil Tools, Houston, Texas) is used which engages an internal profile cut into the top of the guide wedge. The profile is indicated at 121 in fig. 3E.

Claims (13)

1. Guide wedge device for intervention in a side branch of an oil well comprising: a) an anchoring gasket with a helical slot (16) and a selectable profile (22) arranged inside the gasket; b) an orientation tube part (42) having at least one spring-loaded wedge (12) engageable with the helical slot of the gasket and at least one profiled spring-loaded pawl (20) engageable with the selectable profile of the gasket; c) a guide wedge (40) which is attached to the orientation tube part (42) and has a guide surface which can be rotated in relation to the orientation tube part (42). 2. Device according to claim 1, characterized in that the profiled pal is machined to fit the selectable profile on only one gasket and skip over any unwanted gaskets in a borehole. 3. Device according to claim 2, characterized in that the at least one pawl is placed in the orientation tube part so that when the wedge reaches a downhole end of the screw groove, the at least one pawl is in a position for engagement with the corresponding selectable profile in the inner diameter of the gasket. 4. Device according to claim 1, characterized in that the at least one pole is a number of poles which all have an identical profile, all of which can be brought into engagement with the selectable profile. 5. Device according to claim 1, characterized in that the guide wedge comprises an extension which is adapted to be received in a rear end section of a gasket in order to center the guide wedge in the well. 6. Device according to claim 1, characterized in that the guide wedge further comprises a centering tube part (48) which is axially displaceable in relation to the orientation tube part (42) and includes a main part section and a set of arms (56) which are articulated at one end with the main part section and free at its other end, and that the main part section comprises an inclined part (64) which acts to spread out the free ends of the arms by axial displacement of the centering tube part (48) towards the orientation tube part (42). 7. Device according to claim 6, characterized in that the main part section comprises a break pin (72) which prevents displacement of the centering tube part (48) until a predetermined load is placed on the pin. 8. Device according to claim 6, characterized in that the arms further comprise angled end portions which, when expanded, roughly correspond to the dimensions of the drill hole in which the guide wedge is installed. 9. Device according to claim 6, characterized in that the main part section comprises a barbed section to keep the arms in a folded position during periods when they are not in use. 10. Device according to claim 9, characterized in that the arms are forced into a folded position by means of a garter spring (58). 11. Device according to claim 1, characterized in that the guide wedge comprises a knurled regulation section for rotational orientation of the guide wedge in relation to the orientation tube part. 12. Procedure for returning to a side borehole in an oil or gas well, using the tool according to claim 1, and comprising: a) lowering the tool into the borehole whereby the wedge (12) will be captured in the helical slot (16) in each gasket through which the tool passes; b) preventing downward movement of the tool by allowing at least one pawl (20) to engage the selectable profile (22); c) introducing an intervention tool into contact with the guide surface and into the side borehole. 13. Method according to claim 12, characterized in that the guide surface is oriented correctly in relation to the side borehole, before the tool is introduced into the borehole.