NO782692L - DRIVING AND RECYCLING TOOL FOR BRIDGE STRENGTH SUSPENSION DEVICE - Google Patents

Description

The use of well pipe hanger structures for placement in a wellhead cylinder and permanent cementing of a wellbore casing is previously known (U.S. Patent 3,460,615).

The present invention is directed at various improvements of such a construction which can be introduced into a wellhead cylinder, with subsequent placement of a sealing gasket and testing. Emergency recycling of the sealing device can be carried out if the seal appears unsatisfactory. A bowl protector (bowl protector) can be introduced and recovered in combination with the bridging pipe hanger or independently of this. Instructions are given on improved work tools for the introduction, placement, testing and recycling of various components in connection with the construction.

The invention relates to a trailer construction of the aforementioned type, with which a trailer seal can be placed in a removable sealing system during longitudinal movement and released by longitudinal impact. The hanger body comprises a flow channel with a longitudinally movable seal sleeve carrying a gasket to close the channel, a longitudinally movable actuating or control unit for moving the sleeve and seal into sealing position in the channel, a locking recess for receiving a lock ring moved by the control unit to releasably hold the seal in this position, and cooperatively, conical

surfaces between the control unit and the locking ring and between this and the locking recess to provide a wedging action that fixes the seal,

and a releasable locking connection, as well as a mechanical advantage in its location. Between the control unit and the sleeve, additional releasable locking devices can be arranged which keep the seal in an expanded position, e.g. releasable interlocking detents that can be released using a recovery tool. Additionally, there may be releaseable energy storage devices to maintain a clamping force on the positioned seal.

The invention also relates to a hydraulic positioning tool for moving the control unit and positioning the seal. This comprises a piston cylinder mechanism connected to a drive string and arranged to engage with the control unit, so that fluid pressure applied to the drive string can affect the mechanism to position the seal.

One of the purposes of the invention is to provide instructions for a weight placement tool for longitudinal movement of the control unit and placement of the seal.

Another purpose is the provision of a recycling.

tool for emergency recovery of the sealing device if this is unsatisfactory. This tool has a contact surface for releasing the locking devices that keep the seal clamped and includes protrusions for engagement in the control unit and withdrawal of this, the sleeve and the locking ring.

A further object is to provide a recovery tool for introducing and placing a bowl protector in combination with a well pipe hanger.

It is also an object of the invention to provide instructions for a corresponding tool for placing and recovering the bowl protector independently of the hanger, where the protector has an engagement slot for the tool, one end of which is bevelled and the tool has a spring-loaded pin for installation in the slot and a locking sleeve for the pin which is resiliently pressed against this and engages in a locking notch after the protector is placed and the tool is turned towards the inclined surface in the slot for

to bring the pin into the locking position. This tool can also be used to recover the protector by locking the locking sleeve in an out-of-engagement position, whereby the pin can engage in the aforementioned slot and retract the protector.

Another object is to provide a drive and/or recovery tool with spring-actuated chambers for engaging and positioning or recovering a bowl protector or a hanger seal device by longitudinal movement without the need for rotational orientation or influence. The spring-actuated chambers can be triggered down in the well hole by the influence of a hydraulic mechanism for positioning, of equipment without the need for rotation of the tool.

The invention will be explained in more detail below with help

of examples with reference to the drawings, where:

Fig. 1 shows a longitudinal section through the hanger construction which is placed in a wellhead cylinder before cementing the casing, fig. 2 a corresponding section with the drive tool in the flushing position for cleaning the seal and the seat area, fig. 3 and 4 longitudinal sections showing respectively a hydraulic and a weight-mechanical tool for positioning the hanger seal, fig. 5 is a side view, partially in section, of the hanger construction in a well top cylinder after placement of the seal, fig. 6 and.7 section along the lines 6-6 and 7-7 in fig. 5 on a larger scale, fig. 8 a side view partially in section of a recovery tool for the hanger sealing device, fig. 9 a corresponding view of a drive tool for a bowl protector during insertion independent of the well pipe hanger, fig. 10 a section along the line 10-10 in fig. 9 with a tool arranged for retracting the protector independently of the hanger, fig. 11 a longitudinal section through another embodiment of the tool in fig. 9, fig. 12 a section along the line 12-12 in fig. 11, fig. 13A the same as fig. 11 with the tool triggered after placing a bowl protector, fig. 13B is a side view of the tool of FIG. 11 in position for recovery of a trailer seal, fig. 14 a longitudinal section through another embodiment of the hanger in fig. 1 before the introduction, and fig. 15 the same by location.

In fig. 1 shows the well pipe hanger structure 10 according to the invention attached to a drive tool 12 for placement in a well top cylinder or supporting a well casing 16 for conventional cementing of this in the well.

The construction 10 comprises a well pipe hanger 17 with a main part with a shoulder 20 for placement on a shoulder 22 in the cylinder 14 for supporting the construction in this. Part. 18 has internal threads 24 for joining with the mantle 16, internal threads 26, preferably left-handed, for carrying the construction 10 on the tool 12, and flushing openings 28 whose purpose and function will be explained in more detail below. There is an internal cement return channel in or around the portion 18 for. return of cement that flows up along the outer side of the casing 16 and through openings 30 and 32 (fig.1 and 5) into an annular space (annulus) 29 in the well top casing

above the structure 10. A spring ring 21 is arranged on the main part 18 for engagement in a groove 23 in the cylinder 14 to releasably fix

the construction 10 in this. In addition, there is one locking recess 34 in part 18, the purpose and function of which will be explained in more detail below.

The construction 10 also comprises a sealing device with a sleeve 36 and a seal 38 which closes the channel between the part 18 and the cylinder 14, a locking ring 40 placed between the part 18 and the sleeve 36 and an impact part 42 which, during longitudinal movement downwards, displaces the sleeve 36 and the ring 40 in this direction and moves the seal 38 into the sealing arrangement between the part 18 and the cylinder 14. To begin with, the sealing arrangement consisting of the sleeve 36, the ring 40 and the impact part 42 is retained in an upper position, e.g. by means of a breaking pin 44, to keep the seal out of the channel with the openings 30 and 32 when performing conventional cementing work. The construction 10 also includes a bowl protector 4 6 which can be operated in connection with the hanger 17 or independently of it.

The construction 10 is initially introduced by means of the tool 12, which mainly consists of a pipe section with an inner diameter corresponding to the casing 16. The tool 12 is screwed into the main part 18, preferably with left-hand threads 48 which interact with threads 26 and is provided with two O-rings 50 which initially close the openings 28. The construction 10 is lowered into the well until . the shoulder 20 rests against the landing shoulder 22 in the cylinder 14'. 'Spring-. the ring 21 snaps into the groove 23 (fig. 1) and fixes the part 18 releasably in the cylinder 14. Conventional cementing is started and completed to bind the casing 16 in the wellbore by pumping cement

down through the bore in the tool 12 and the casing and up along the outside of these through the channel 29 with the openings 30 and 32.

As mentioned, the kari protector 46 is introduced in combination with the hanger 17. An intermediate piece 52 can be threaded on the upper end of the sleeve 36 to slidably rest against and control the lower end of the protector 46. This can comprise a splitting ring 54 which cooperates with a groove 56 in the cylinder 15. The groove 56 preferably contains a pin 58. - A breaking pin 60 is arranged between the tool 12 and the protector 46 for turning this and the ring 54 until the slot in the ring aligns with the pin 58 and allows it to snap into place in the groove 56 to prevent rotation of the protector 46.

After the completion of the cementation, the seal 38 and its seat area are cleaned before it is placed. The tool 12 is turned to the right (fig. 2) to unscrew the left connection between the threads 48 and 2 6 and withdraw the lower O-ring 5.0 to close up the flushing openings 28. Water is now circulated downwards through the bore in the tool 12 and the openings 28 and up through the channel 29 between the tool and the cylinder 14 to clean the seat area and the seal 38. The rotation of the tool 12 will break the pin 60 between this and the protector 46. After the completion of the flushing, further rotation of the tool 12 will disengage this from the main part 18 and it is extracted

of the well.

In fig. 3 and 4 two types of tools are seen for placing and testing the seal 38. Fig. 3 shows a hydraulic tool 62 connected to one drive shaft 64 with a shoulder 66 for abutment against a possible blowout blocking device 68 to prevent upward movement of the tool 62 and the string 64 under the influence of the seal 38. The tool 62 comprises a mechanism with a piston 72 and a cylinder 70 with an opening 74 in connection with the bore in the tool and the string 64. The piston 72 is arranged to be placed in contact with on the effect part 42 and move this longitudinally downwards. The sleeve 36 (Fig. 2) has an upward facing shoulder 80 to initially carry the ring 40 in a position above the recess 34. It can be seen that the attachment portion 42 is positioned over the top of the ring 40 so that the pin 44 is broken by downward movement of the part, which then drives the ring 40 and the sleeve 36 with the seal 38 in the same direction. The part 42 has a conical surface 82 which is adapted to cooperate with a conical surface 84 on the ring 40 when this snaps into position in the recess 34. The top of this has a conical surface 86 for cooperation with a conical surface 88 on the top of the ring 40.

In fig. 3, a ball 94 is seen which is arranged to drop into the bore in the tool 62 and lodge in a seat 96, and when hydraulic pressure is applied through the bore and opening 74, the piston 72 moves downward and pushes the impact member 42 in the same direction, the pin 44 is broken, the ring 40 is inserted into the recess 34 and the sleeve 36 and the seal 38 are pressed downwards. Further longitudinal pressure against the part 42 wedges the surface 88 of the ring 40 and the surface 86 of the recess 34 into contact and thus causes a stronger compression of the seal 38 when its lower side contacts a shoulder 90 of the main part 18 and expands between this and the cylinder 14. desired compression of the seal 38 can be achieved by combining a self-locking taper between the outwardly and downwardly directed surfaces 82 and 84 on respectively the part 42 and the ring 40, e.g. a cone angle of 7°, against the conicity between the inwardly and downwardly directed interacting surfaces 86 and 88 which may be 45°. In addition to a releasable locking mechanism for the seal 38, the two interacting pairs of cone surfaces also provide a mechanical advantage in the ratio of 3 or 4 to 1, which proportionally reduces the required positioning pressure from the piston 72. With this, the seal as shown in fig. 3 in directional position.

However, a further locking system is provided for the self-locking taper between the surfaces 82 and -84 as vibrations can loosen this connection and release the seal 38. There can be locking devices as shown in fig. 5-7, in which upward-facing detent teeth 100 are designed on the impact part 42 to cooperate with detent segments 102 with downward-facing teeth 104. The segments 102 are carried by the sleeve 36 in a recess 106 and are resiliently pressed against the part 42 by means of suitable spring means, e.g. rubber pads 108. As the part 42 is moved downwards, the interacting teeth 100,104 will ratchet against each other under the influence of the pads 108 to allow the impact part 42 to move downwards in relation to the sleeve 36 and lock the seal 38 in a compressed state and prevent it from loosening. If, however, it is desired to remove the sealing device as explained below, the teeth 100, 104 must be separated from each other and for this there are arranged segment release elements 110 on the part 42 placed against the segments 102 with ends 112 projecting inwards from this for engagement against suitable devices. ■ Thus, when the end 112 is pushed outwards, the segments 102 will move against the pads 108 to bring the teeth 110,104 out of engagement and allow the part 42 to be moved upwards relative to the sleeve 36.

After the seal 38 is placed, it is tested to ensure

ensure that it seals effectively. The tool 62 comprises a test seal 92 (Fig. 3) for sealing against the main part 18. Pressure can be applied downwards against the seal 38 through the channel 29, openings 98 in the piston 72 and the openings 32. If. the seal 92 is leaky, a break in the casing 16 is avoided, as excess pressure in this can push the ball 94 out of the seat 96 and be released through the bore 31.

If the test shows that the seal 38 does not hold properly or it is desirable for other reasons to remove the direction device, it is provided. a recovery tool 114 (Fig. 8). This comprises a plurality of wedge grooves 116 and protrusions 118 for cooperation with corresponding protrusions 120 and grooves 122 on the impact part 42 (Fig. 5). When the tool 114 is introduced into the part 4 2, the protrusions 118 must touch the protrusions 120 and a minor turning will then cause the rifled constructions to cooperate. It should also be noted that the protrusions 118 will come into contact with the inner ends 112 of the elements 110 to move the tooth segments 102 away from the impact part 42 and trigger the engagement between the teeth 100,104 to allow it to be moved upwards and extracted from the locking ring and the sleeve 36. The tool 114 further includes a plurality of spring-loaded pins 124 which move downwardly on the projections 120 for engagement with a shoulder 126. An upward pull on the tool 114 moves the impact member 42 longitudinally in the same direction and releases the snap ring 40. Further upward movement of the member 42 causes the top 128 of this to rest against the bottom of the intermediate piece 52, so that the sleeve 36 and the ring 40 are lifted at the same time. The upward movement will cause the sleeve 36 to come into contact with the bottom of the protector 36, so that it is recovered from the well together with the sealing device.

After the sealing device's removal and inspection can

it is used again and placed with the help of the tool 62 (fig. 4) by supporting the device on this with a breaking pin 132, so that the sleeve 36, the part 42 and the ring 40 can be reinserted around the part 18. The tool 62 can be modified as shown on fig. 4, so that it becomes a weight placement tool by inserting a spacer 134 in the cylinder 70 or by simply moving the tool downwards until the cylinder closes over the piston .72. Mechanical longitudinal movement of the sealing device down around the main part 18 will then position or reposition the seal 38 as explained in connection with fig. 3..

As mentioned above (fig. 1), the bowl protector 46 can be introduced in combination with the hanger 17 or introduced and recovered separately from this. The one in fig. 9 shown protector 46 comprises a tool that rests in openings 140 with a chamfered surface 142 which decreases in depth at one end (fig. 1). This tool 144 is arranged for connection to a drive string (not shown) and has spring-loaded pins 146 for engagement in the openings 140. The tool 144 also comprises a pin locking sleeve 148 which is acted upon by a spring 150 against the pins 146. Each pin 146 has a locking groove 152 at the inner end and when pressed inwards, the grooves will engage with the lower end 154 of the sleeve 148. To independently place the protector 46, the tool 144 is mounted at the well surface with the tabs 146 in the openings 140, so that the protector is carried by the tool. This and the protector are lowered into the cylinder 14 until the split ring 54 snaps into the groove 56. Then the tool 144 is turned to the right and the pins 146 will be pressed inwards by the inclined surface 14 2 and bring the grooves 152 flush with the lower end 154 of the sleeve 148 and thus lock the pins in position inwards and the tool can then be pulled out of the cylinder 14.

To recover the protector 46, the locking sleeve 148 must be neutralized to allow the pins 146 to move inwards as the tool 144 is guided down into the well and then snapped outwards into the openings 140. As shown in fig. 10, a screw 156 is inserted into the tool 144 which rests against the lower end 154 of the sleeve 148 and holds it in an upper position away from the grooves 152 in the pins 146. The tool 144 is guided downwards until a shoulder 160 of this rests against a shoulder 162 on the protector 46, whereby the pins 146 come into alignment with and enter the openings 140. A straight upward pull of the tool 144 will then lead the protector back from the cylinder 14.

It is understood that further modifications of the present invention can be used. In fig. 11,12 and 13 another tool is seen. 170 for placement and recovery of a bowl protector

and for the recovery of a hanger sealing device. The tool 170 is spring-actuated and hydraulically releasable and comprises a main part 172 which can be attached to a drive string (not shown), a hydraulic piston 174 and locking chamber 176. Between the piston 174 and the cams 176 there are arranged springs 178 which resiliently press the cams outwards. As shown in fig. 11, the tool 170 can be used to recover components with an annular engagement groove 182, e.g. a bowl protector 180. In this case, the tool 170 can be guided down into the wellbore and the combs 1.76

will pass over any obstructions or shoulders therein by moving inward against the springs 178. Once the cams 176 have entered the slot 182, the tool can be retracted together with the protector 180. It will be noted that it does not. rotational orientation or turning of the tool 170 is required for engagement in the groove 182 and that the tool has the advantage of recovery exclusively by longitudinal movement.

As shown in fig. 13B, a tool 170a similar to tool 170 but with a smaller outer diameter can be used to engage and recover the hanger seal, where the cams 176a will engage under the aforementioned shoulder 126 to move the impact member 42 upward and remove the seal as previously explained, but only during longitudinal movement as the tool 170a functions without the need for turning as for the tool according to fig. 8.

The tool'170 can, in addition to recovering equipment from the well exclusively by longitudinal movement, also place it in this way. The piston 174 has a first section 184 with an enlarged diameter, which normally abuts one end of the springs 178, and a second section 186 with a smaller diameter. In the piston 174 there is a slot 188 for engagement with a spring-loaded pin 190 which normally keeps the piston section 184 flush with the end of the springs 178. Hydraulic medium can be pumped into a bore 192 in the tool 170 to force the piston 174 down (Fig .13A) against a stop ring 194 and bringing another slot 196 into engagement with pin 190 to hold the plunger in a lower position. The downward movement of the piston 174 brings the section 184 out of contact with the springs 178 and the section 186 into contact with them. This reduces the pressure from the springs 178 against the cams 176, which, as shown in fig. 12 is movably attached to the main part 172 by means of pins 192, 194 and springs 196, 198 which compliantly press the cams 176 against the part 172. When the piston 174 is in the upper position (fig. 11), the springs 178 are in a more compressed state and overcomes spring ne 196,198 and forces cams 176 outwards into engaged position. When stamped. 174 is moved to the lower position (fig. 13A) with the springs in contact with the section 186, the springs 196,198 will, on the other hand, overcome the springs 178 and move the cams 176 inwards into the released position. It is again noted that the tool 170 can place and release equipment only by longitudinal movement without the need for rotational orientation or pivoting.

A particular embodiment of the hanger sealing device according to fig. 1-8 are shown in fig. 14 and 15, where identical parts are indicated with the same reference number and index a. The sealing construction 200 in fig. 14 and 15 comprise energy storage devices, e.g. one or more plate springs 202 to maintain a compressive force on the impact part 42a (which corresponds, to the operating part 42) and thus on the seal 38a and prevent possible leakage and relaxation when it is placed. That is that the springs 202 are compressed when the sealing construction is placed and maintain continuous pressure against the part 42a. As shown, the springs 202 are positioned above and against the portion 42a and a holding element 204 is mounted above the springs. The tool 62 carries the construction 200 by means of a breaker pin 132a for movement down the wellbore and into the cylinder 14. When the tool 62 is acted upon, e.g. by means of the piston 72, the piston 204 is moved downwards towards the springs 202 which then displaces the part 42a in the same direction as in the first embodiment to lead. the locking ring 40a and the sleeve 36a downwards and place the seal 38a.

Any suitable locking system can be used, e.g. as shown in fig. 1-8, although a simplified device would include a number of cartridge hooks 206 which are connected to the element 204 and engage a downwardly facing hook recess 208 in the sleeve 36a to retain the compressed springs 202 (Fig. 15) against the upper end of the part 42a and thus, fix the seal 36a and the conical locking surfaces between the part 42a and the ring 40a.

The construction 200 can be recovered using the tool 170 according to fig. 11-13 only by breaking a pin 205 which connects the hooks 206 with the element 204.

Claims (2)

1. Drive and recovery tool for placement and recovery of a well-pipe suspension device with a seal between the fire pipe and the wellhead, characterized by a main part (17 2), a piston (174) slidably arranged therein, barrier chamber' (176) and between these and the piston (174) arranged springs (178) which push the locking cams (176) outwards, which locking cams are released when the piston is moved for release. 2. Untool according to claim 1, characterized in that the piston (174) has a first section (184) with a larger diameter and a second section (186) with a smaller diameter, so that the springs (178) press the locking cams outwards with greater force when they are affected by the first section (184) of the piston (174), and push the locking cams outwards with less force when they are affected by the second section (186) of the piston (174), which less force is counteracted by inwardly acting springs (196, 198), thus that-the latter f yes; rer dominates - over the first-mentioned springs and presses the combs inwards and frees the fire pipe, so that this can be pulled out of the wellhead.