WO2012022287A2 - Rotation-prevention means for borehole pumps - Google Patents

Abstract

The invention relates to a rotation-prevention means for ascending pipes in a borehole. The rotation-prevention means brings at least two, tooth-reinforced claws into operative connection with an inner wall of a borehole by way of at least two protuberances. The at least two protuberances are arranged on a preferably hollow basic body. The ascending pipe and/or an eccentric screw pump can be centred by the rotation-prevention means. The claws are connected to one another and/or braced in each case by at least one helical compression spring.

Description

 VERDREUSICHERUNG FOR DRILLING PUMPS

The invention relates to an anti-rotation device for a riser in a borehole in conjunction with the operation of a progressing cavity pump. The

 The device operatively couples at least two toothed jaws through at least two cams to an inner wall of a wellbore. The at least two cams are arranged on a preferably hollow base body. The eccentric screw pump can be centered by the device.

US Pat. No. 4,605,063 discloses an apparatus with which a linkage in a pipeline can be secured against axial movement. The jaws, which are equipped with upwardly and downwardly directed teeth, are moved to prevent rotation in the direction of the inner walls of the pipeline. To move the claws back to the starting position, these are connected to one another by tension springs. For centering the linkage and the

 Device, the device is provided with additional centering elements. These centering elements are arranged between the claws.

 US Pat. No. 4,811,785 discloses a tool which prevents twisting of a linkage in a borehole. To this end, toothed claws are pressed radially outward against the borehole wall by cams located on the inside of the jaws. This is done by turning clockwise. To release the claws, the linkage is rotated counterclockwise with cams. To center the device elements are arranged above the claws, which are pressed by leaf springs to the outside of the borehole inner wall.

The American patent US 5,275,239 discloses another device with which the rotation of the linkage in a borehole can be avoided. In this device, a plurality of triangular claws are each pressed by a leaf spring radially outward against the borehole wall. In a clockwise rotation of the linkage, the triangular claws are moved so that they are placed in a pivot point. The outermost point of the triangular Claw wedges with the borehole wall, with the leaf spring being pressed in. To relax the leaf springs, the linkage is in the opposite

Direction moves.

 Object of the present invention is to provide an anti-rotation, with the twisting and / or unscrewing a strand screwed risers in a borehole during normal operation is avoidable.

 The object of the invention is achieved by a device by the

Characteristics of claim 1 is described. Further advantageous features for preventing the rotation of a riser in a borehole can be found in the dependent subclaims.

 Furthermore, the invention has for its object to provide a method with which the rotation of a riser can be avoided in a borehole.

 This object is achieved by a method comprising the features of claim 9.

 It is disclosed an anti-rotation device for risers in a borehole. The anti-rotation device according to the invention consists of at least two teeth provided with claws. By at least two cams are the claws with a

Inner wall of a borehole brought into operative connection. The at least two cams are arranged on a preferably hollow base body. The eccentric screw pump, which is fastened directly to the anti-twist device, can additionally be centered by the anti-twist device. The claws are interconnected and / or prestressed by at least one helical compression spring.

 The Kiauen are pressed by the spring forces of the spiral compression springs to the inner wall of the wellbore that the rotation and centered with it the riser and the eccentric screw pump. The claws are fixed against rotation by a rotational movement of the cam on the inner wall of the wellbore. By a rotational movement of the cams in the opposite direction, the kuauen of the inner wall of the borehole are unlocked again.

Each claw is provided with at least one claw stop and each cam with a cam stop. By a rotational movement of the body with the on the cam cams are brought into operative connection with the claw stops. This interaction ensures separation of the claws from the inner wall of the borehole. This happens because the cam stops engage in the claw stop acting as a driver and transmit the rotational movement of the riser pipe to the latter. By this rotational movement of the unlocking process is then initiated.

 The main body of the rotation is a pipe or a solid rod or part of the eccentric screw pump. On an upper side, the base body has at least one radially arranged bore, through which a liquid column can be derived from an annular space. The annular space is formed between the riser or the eccentric screw pump and the borehole wall. The holes are important because the perforation of the well can also be above the eccentric screw pump and thus above the rotation. In order for the medium to flow freely into the eccentric screw pump and not have to flow past the anti-rotation lock in order to flow into the lower intake region of the eccentric screw pump, at least one radial bore is introduced into the main body.

 Furthermore, the invention discloses a method for using an anti-rotation device for risers in a borehole. The device is assigned to a riser. The jaws of the device are connected by helical compression springs with each other and are held with their help in the same distance from each other, wherein the claws are pressed by a spring force of the helical compression springs to an inner wall of the wellbore. The device is centered in the borehole by the spring forces acting on the claws.

By a rotational movement of the body with the cam thereon in

Locking the claws are fixed to the inner wall of the borehole. By a rotational movement of the cam against the locking direction, the claws are unlocked again from the inner wall of the wellbore.

By a rotational movement in the unlocking direction, the cam stops are brought into operative connection with the claw stops. The clamping of the claws is released by this operative relationship of the inner wall of the wellbore. A liquid sac from an annulus is drained via at least one radially disposed bore below a threaded sleeve of the device.

In the following, embodiments of the invention and their advantages with reference to the accompanying figures will be explained in more detail. The proportions of the individual elements to each other in the figures do not always correspond to the actual size ratios, since some shapes are simplified and other shapes are shown enlarged for better illustration in relation to other elements.

 Figure 1 shows schematically the position of a device according to the invention in a borehole.

FIG. 2 shows the structure of the device.

 Figure 3 shows the structure of the device in an exploded view.

 Figure 4 shows a sectional view of the device according to the invention.

 For identical or equivalent elements of the invention, identical reference numerals are used. Furthermore, for the sake of clarity, only reference numerals in the fifteen individual figures are shown, which are required for the description of the respective figure.

 Figure 1 shows schematically the position of a rotation 20 according to the invention in a borehole 12. At the earth's surface 16 is the drive 14 through which the rod 10 is set in rotation. With the linkage 10 is the

 20 eccentric screw pump 18 driven. At the lower end 35 of the eccentric screw pump 18 is the rotation 20 by means of threaded sleeve 36th

 appropriate. Above the rotation 20, a liquid column 48 is shown, which is in the annular space 50 between the riser 11 and / or between the eccentric screw pump 18 and the inner wall 40 of the borehole

25 12 is located. This liquid column 48 is discharged through the holes 38 in the main body 28 of the rotation 20 to the underside 37 and / or sucked at the lower end 35 of the eccentric screw pump 18.

 FIG. 2 shows the structure of the anti-twist device 20. The anti-rotation device 20 consists of a base body 28, which consists of a seamless precision tube. 3 o Alternatively thick-walled pipes can be used with both

Internal thread and / or are equipped with external thread. The number of claws 22 depends on the outer diameter of the anti-rotation device 20. The larger the outer diameter, the more claws 22 are present. In general, three claws 22 are sufficient to adequately clamp the anti-rotation device 20 in the borehole 12 and center it at the same time. The jaws 22 must be dimensioned so that they slide, in an installation of the rotation 20 in the borehole 12, over the gap between the individual well pipes, without getting caught. Furthermore, each claw 22 retaining rings 23 are assigned, which are fastened to the base body 28 with screws 25. In addition, the claws 22 on both sides of a narrow collar 27. This collar 27 is designed so that the claws 22 are in operative connection with the retaining rings 23 and can not fall out. Lateral, radial bores 38 in the base body 28 allow the outflow of liquid column from the overlying annular space between the riser and the wellbore.

 Figure 3 shows the structure of the rotation 20 in an exploded view. The rotation 20 consists of a base 28 on the cam 24 are welded. The number of cams 24 corresponds to the number of claws 22. For larger outer diameters of the anti-twist device 20, instead of the welded-on cams 24, a cam ring (not shown) can also be shrunk onto the base body 28. The claws 22 are provided on both sides with a collar 27 which forms an effective pairing with the securing rings 23. Two claws 22 are each assigned in the tangential direction, on each side, two helical compression springs 30. The claws 22 of the device 20 are connected via spiral compression springs 30 with each other. This connection ensures that the claws 22 are evenly spaced and distributed around the main body 28. At the same time, the claws 22 are pressed against the inner wall of the borehole. With retaining rings 23, the claws 22, against each other and the

Threaded sleeve 36 and the bottom 37 out, secured. The retaining rings 23 are releasably fixed to the base body 28 by means of screws 25.

FIG. 4 shows a cross-sectional view of the anti-rotation device 20 according to the invention. The anti-rotation device 20 is introduced into a drilled hole 12 in FIG. 4 and secured against rotation by the claws 22 against the inner wall 40 of the drilled hole 12. For this purpose, the cams 24 are rotated in the blocking direction 42 and the claws 22 are pressed against the inner wall 40. By a rotational movement of the cam 24th in the unlocking 44, the claws 22 are unlocked again. If the jaws 22 have wedged too much in the inner wall 40 with the teeth 26, the cams 24 are rotated in the unlocking direction 44 until the cam stops 34 engage in the claw stops 32. By this action, the claws 22 are moved in the unlocking direction 44 and detach from the inner wall 40th

 Furthermore, it can be seen that helical compression springs 30 are arranged between the claws 22. The helical compression springs 30 act with their spring force 46 in each case on two adjacent claws 22. By this spring force 46, the claws 22 are pressed outwards and against the inner wall 40 of the borehole. When the anti-rotation lock 20 is unlocked, the cam stops 34 and the claw stops 32 come into operative connection. The force generated by the rotation in the unlocking direction 44 overcomes the spring force 46 of the spiral compression springs 30, as well as the frictional connection between the teeth 26 of the jaws 22 and the inner wall 40 of the borehole 12. As a result, the claws 22 relative to the inner wall 40 of the borehole 12 are movable again ,

The invention has been described with reference to a preferred embodiment.

reference numeral

10 linkage

 11 riser

 12 borehole

14 drive

 16 Earth's surface

 18 eccentric screw pump

 20 anti-twist device

 22 claw

 23 circlips

 24 cam

 25 screw

 26 teeth

 27 fret

 28 basic body

 30 helical compression spring

 32 kiauen stop

 34 cam stop

 35 Lower end of the eccentric screw pump

36 threaded sleeve

 37 bottom

 38 bore

40 inner wall

42 reverse direction

44 Unlocking direction

46 spring force

 48 liquid column

 50 annulus

Claims

Patent claims

1. Anti-twist device (20) for riser pipes (11) in a borehole (12), whereby

at least two claws (22) provided with teeth (26) can be brought into operative connection with an inner wall (40) of a borehole by at least two cams (24), the at least two cams (24) being arranged on a preferably hollow base body (28). are and wherein the riser pipe (11) can be centered by the anti-rotation device (20), characterized in that the claws (22) are each secured by at least one

Spiral compression spring (30) are connected to one another and/or prestressed.

2. Anti-rotation device (20) according to claim 1, characterized in that the

Claws (22) can be pressed onto the inner wall (40) of the borehole (12) by the spring forces (46) of the spiral compression springs (30) in such a way that the anti-rotation device (20) can be centered.

3. Anti-rotation device (20) according to one of claims 1 or 2, characterized in that the claws (22) can be fixed against rotation on the inner wall (40) of the borehole (12) by a rotational movement of the cams (24).

4. Anti-rotation device (20) according to one of claims 1 to 3, characterized in that the claws (22) can be unlocked by a rotational movement of the cams (24) from the inner wall (40) of the borehole (12).

5. Anti-twist device (20) according to one of claims 1 to 4, characterized in that each claw (22) is provided with at least one claw stop (32).

6. Anti-rotation device (20) according to one of claims 1 to 4, characterized in that each cam (24) is provided with a cam stop (34).

7. Anti-twist device (20) according to one of claims 5 or 6, characterized in that by a rotary movement of the cams (24), the cam stops (34) can be brought into effective connection with the claw stops (32) and that the claws ( 24) can be moved again on the inner wall (40) of the borehole (12).

8. Anti-twist device (20) according to one of claims 1 to 7, characterized in that the base body (28) is a pipe and / or a solid rod and / or part of an eccentric screw pump (18) and that at least one threaded sleeve (36). has a radially arranged bore (38) through which a liquid column (48) can be derived from an annular space (50).

9. Method for using an anti-twist device (20) for riser pipes (11) in a borehole (12), characterized in that:

- the device (20) is assigned to a riser pipe (11),

- Claws (22) of the device (20) are connected to one another via spiral compression springs (30),

- the claws (22) are held at a distance from one another by the spring forces (46) acting on the claws (22), which are generated by the spiral compression springs (30),

- the claws (22) are pressed against the inner wall (40) of the borehole (12) by the spring force (46) of the spiral compression springs (30), and

- The device (20) is centered in the borehole (12) by the spring forces (46) acting on the claws (22).

10. The method according to claim 9, characterized in that the claws (22) are releasably clamped to the inner wall (40) of the borehole (12) by a rotational movement of the cams (24) in the locking direction (42).

1. The method according to claim 10, characterized in that the clamping of the claws (22) is released from the inner wall (40) of the borehole (12) by a rotary movement of the cams (24) against the locking direction (42).

12. The method according to any one of claims 9 to 11, characterized in that the cam stops (34) are brought into effective connection with the claw stops (32) by a rotary movement of the cams (24) in the unlocking direction (44) and that through this effective connection the Claws (24) can be moved relative to the inner wall (40) of the borehole (12).

13. The method according to any one of claims 9 to 12, characterized in that at least one radially arranged bore (38) below one Threaded sleeve (36) a liquid column (48) is derived from an annular space (50).