Pinning tool for pinning a tubular structure

Abstract

A pinning tool is for pinning a tubular structure by pressing a pin through a sidewall of the tubular structure. The pinning tool comprises: a tool body configured for receiving the tubular structure; an actuator mounted on the tool body, the actuator being provided with a piston rod, wherein the actuator is configured for displacing the piston rod in a translational movement; a pin adaptor releasably coupled to the piston rod of the actuator and being configured for receiving and releasably holding the pin to be pressed through and remain in the sidewall of the tubular structure, and a reaction member for fixing a relative position between the tool body and the tubular structure during pinning, wherein the translational movement of the piston rod causes displacement of the pin adaptor, thereby pressing, in operational use, the pin through the sidewall of the tubular structure.

Claims

1. A pinning tool for pinning a tubular structure by pressing a pin through a sidewall of the tubular structure, the pinning tool comprising: a tool body configured for receiving the tubular structure; an actuator mounted on the tool body, the actuator being provided with a piston rod, wherein the actuator is configured for displacing the piston rod in a translational movement; a pin adaptor releasably coupled to the piston rod of the actuator and being configured for receiving and releasably holding the pin to be pressed through and remain in the sidewall of the tubular structure, and a reaction member for fixing a relative position between the tool body and the tubular structure during pinning, wherein the translational movement of the piston rod causes displacement of the pin adaptor, thereby pressing, in operational use, the pin through the sidewall of the tubular structure.

2. The pinning tool according to claim 1, wherein the actuator, the pin adaptor and the tool body are arranged such that, in operational use when the pin is provided on and held by the pin adaptor, the pin penetrates through the sidewall, wherein a longitudinal axis of the pin is substantially parallel to a direction of the translational movement.

3. The pinning tool according to claim 1, wherein the pin is provided on and held by the pin adaptor.

4. The pinning tool according to claim 3, wherein the pin is provided with a projection extending helically about the longitudinal axis.

5. The pinning tool according to claim 3, wherein a first end portion of the pin is replaceable.

6. The pinning tool according to claim 1, wherein a position of the pin adaptor relative to the tubular structure is adjustable in a transverse direction orthogonal to the longitudinal axis.

7. The pinning tool according to claim 1, wherein the reaction member is hinged to the tool body, and, in a closed position, enveloping the tubular structure.

8. A combined pinning and cutting tool for pinning and cutting a tubular structure, the combined pinning and cutting tool comprising: a pinning tool comprising: a tool body configured for receiving the tubular structure; an actuator mounted on the tool body, the actuator being provided with a piston rod, wherein the actuator is configured for displacing the piston rod in a translational movement; a pin adaptor releasably coupled to the piston rod of the actuator and being configured for receiving and releasably holding a pin to be pressed through and remain in a sidewall of the tubular structure, and a reaction member for fixing a relative position between the tool body and the tubular structure during pinning, wherein the translational movement of the piston rod causes displacement of the pin adaptor, thereby pressing, in operational use, the pin through the sidewall of the tubular structure; a non-rotatable cutting element connected to the piston rod; and a second reaction member for applying a reaction force on the tubular structure during cutting.

9. The combined pinning and cutting tool according to claim 8, wherein the second reaction member is hinged to the tool body and comprises a second cutting element directed towards, in an operational position, the non-rotatable cutting element for facilitating the cutting.

10. A method for pinning a tubular structure via a pinning tool, the pinning tool comprising: a tool body configured for receiving the tubular structure; an actuator mounted on the tool body, the actuator being provided with a piston rod, wherein the actuator is configured for displacing the piston rod in a translational movement; a pin adaptor releasably coupled to the piston rod of the actuator and being configured for receiving and releasably holding a pin to be pressed through and remain in a sidewall of the tubular structure, and a reaction member for fixing a relative position between the tool body and the tubular structure during pinning, wherein the translational movement of the piston rod causes displacement of the pin adaptor, thereby pressing, in operational use, the pin through the sidewall of the tubular structure; the method comprising: providing the pinning tool with a pin releasably held by the pin adaptor; positioning the pinning tool adjacent the tubular structure; fixing the position of the pinning tool relative to the tubular structure; activating the pinning tool for pressing the pin through the sidewall of the tubular structure by carrying out the translational movement of the piston rod of the actuator, and releasing the pin from the pin adaptor.

11. The method according to claim 10, wherein, in the step of positioning the pinning tool, the positioning comprises adjusting a position of the pin adaptor relative to the tubular structure in a transverse direction orthogonal to the longitudinal axis.

12. The pinning tool according to claim 4, wherein a first end portion of the pin is replaceable.

Description

BRIEF DESCRIPTION OF THE FIGURES

(1) In the following is described an example of a preferred embodiment illustrated in the accompanying drawings, wherein:

(2) FIG. 1 shows a perspective view of a pinning tool according to one embodiment of the invention;

(3) FIG. 2 shows a plane view of the pinning tool with a reaction member in an open position;

(4) FIG. 2A shows a portion of a pin according to one embodiment of the invention;

(5) FIG. 3 shows a perspective view of the pinning tool in an engaged position;

(6) FIG. 4A-E shows, in a smaller scale than FIG. 2, in a simplified manner the various steps of a pinning operation using the pinning tool;

(7) FIG. 5A shows, in the same scale as FIG. 1, a combined pinning and cutting tool according to one embodiment of the invention, and

(8) FIG. 5B shows, in a smaller scale than FIG. 5A, a plane view of the combined pinning and cutting tool.

DETAILED DESCRIPTION OF THE FIGURES

(9) In the figures and detailed description only one example of a pinning tool is given. It must be stressed that the invention is not limited to this example. FIG. 1 shows a perspective view of an embodiment of a pinning tool 1 in accordance with the invention. The pinning tool 1 may be installed on the drill floor as a mount onto a roughneck (not shown) or as a stand-alone system (not shown), which may be run back and forth (for instance using a rail system) over a Rotary Kelly Bushing (RKB) for each pinning operation. Alternatively, it may be manipulated by means of a crane or manipulator (not shown).

(10) FIG. 1 shows the pinning tool 1 comprising a tool body 2. A rotatable reaction member 3 is mounted on the tool body 2. The reaction member 3 may be selectively opened or closed. The reaction member 3 comprises a first enveloping element 33 and a second enveloping element 34 forming an enclosure 30 (see FIG. 2) for receiving a tubular structure 8 (see FIG. 4B). The second enveloping element 34 is connectable to the first enveloping element 33.

(11) The reaction member 3 is connected to the tool body 2 by a hinging mechanism 32. In a closed position, the reaction member 3 may be locked in place by a locking bolt 31 insertable through the tool body 2 and the reaction member 3.

(12) In the closed position, the reaction member 3 fixes a relative position between the tool body 1 and the tubular structure 8. An inner diameter D (see FIG. 2) of the enveloping elements 33, 34 may be adjusted by inserts to match an outer diameter of the relevant tubular structure 8 and provide firm anchoring between the pinning tool 1 and the tubular structure 8.

(13) The second enveloping element 34 is provided with a hole 35 for letting a pin 4 pass through. The first enveloping element 33 may also be provided with a similar hole (not shown).

(14) FIG. 1 further shows the pinning tool 1 comprising an actuator 5. In this specific embodiment, the pinning tool 1 is provided with three actuators 5. The actuator 5 comprises a housing 51 and a piston rod 52 (see FIG. 3). The actuator 5 is operated by hydraulic pressure to displace the piston rod 52. The actuator 5 is configured to deliver a considerable amount of axial force, for example 1000 tons.

(15) Each piston rod 52 is coupled to a common bracket 6 (see FIG. 3). As the actuators 5 extend the piston rods 52 towards the reaction member 3, the bracket 6 is guided along a track 60 on the tool body 2 for support.

(16) FIG. 2 shows a pin adaptor 7 coupled to the common bracket 6. The pin adaptor 7 is connectable to the common bracket 6 by means of for example bolts. A transverse position of the pin adaptor 7 relative to the bracket 6 is adjustable. A transverse direction corresponds to the Y-direction illustrated by the X-Y coordinate system 200. Adjusting the transverse position of the pin adaptor 7 may be required to ensure that the pin 4 is pressed through (=penetrates) the tubular structure 8 at a desired location, such as through a center of the tubular structure 8. The pin adaptor 7 is configured to receive and support the pin 4. A longitudinal axis 40 of the pin 4 is shown to be arranged parallel to piston rods 52, and thus parallel to the direction of the translational movement of the piston rods 52.

(17) A first end portion 41 of the pin 4 is configured with a pointed tip 410 to penetrate a sidewall 80 of the tubular structure 8 more easily. The first end portion 41 may have different embodiments, only one is shown in the figures. In one embodiment, the first end portion 41 is removable. This enables replacing the first end portion 41 of the pin 4, for example with a first end portion 41 made from a higher-grade material.

(18) A second end portion 42 of the pin 4 is connectable to the pin adaptor 7. In one embodiment, the pin 4 may be fixed to the pin adaptor 7. In another embodiment, the pin 4 may be rotatably connected to the pin adaptor 7. A rotatable connection allows the pin 4 to rotate as it is pressed through the tubular structure 8. FIG. 2a shows a portion of an embodiment of the pin 4 comprising a projection 411 extending helically about the longitudinal axis 40. The helical projection 411 projects from an outer surface 412 of the first end portion 41 of the pin 4. The projection 411 may cause the pin 4 to rotate as it is pressed through the tubular structure 8. The rotation may reduce a required axial force to drive the pin 4 through the tubular structure 8.

(19) In FIG. 2 the piston rods 52 are shown to be partially extended and the reaction member 3 is in the open position. In FIG. 3 the piston rods 52 are shown to be fully extended and the reaction member 3 is in the closed position. With the piston rods 52 fully extended, the pin 4 cross through the enclosure 30.

(20) FIGS. 4 and 5 shows a pinning operation in simplified steps. FIG. 4A shows the pinning tool 1 in a starting position, wherein the reaction member 3 is in the open position and the second enveloping element 34 is disconnected from the first enveloping element 33. The piston rods 52 are in a retracted position and the pin 4 is mounted on the pin adaptor 7.

(21) FIG. 4B shows the pinning tool 1 positioned adjacent a tubular structure 8, such as a casing. In FIG. 4C the reaction member 3 is rotated to the closed position and the second enveloping element 34 is connected to the first enveloping element 33 to fix the relative position of the tubular structure 8 relative to the tool body 2. The pinning tool 1 is now ready to pin the tubular structure 8.

(22) FIG. 4D shows the pin 4 pressed through the sidewall 80 of the tubular structure 8. FIG. 4E shows the pin 4 fully pressed through the tubular structure 8. After pinning, the pin 4 is disconnected from the pin adaptor 7, leaving the pin 4 in the tubular structure 8 while the piston rods 52 are retracted.

(23) FIG. 5A shows a combined pinning and cutting tool 100. The combined tool 100 comprises the pinning tool 1 as previously described and a cutting tool 101. As may be seen from the previous figures, the pinning tool 1 is depicted comprising the cutting tool 101. However, it is important to note that the pinning tool 1 does not require the cutting tool 101 to function, it is merely for illustration purposes. The cutting tool 101 comprises two cutting blades 102, 103. A first cutting blade 102 mounted on the common bracket 6 and a second cutting blade 103 mounted on a second independently rotatable reaction member 104. The second rotatable reaction member 104 is hinged to the tool body 2 and may be selectively opened or closed, independently of the reaction member 3 used for pinning. The second rotatable reaction member 104 may be locked in a closed position by the locking bolt 31.

(24) The tubular structure 8 is cut by the translational movement of the piston rods 52, displacing the first cutting blade 102 towards the second cutting blade 103. The second cutting blade 103 reduces the required time to perform the cut. Cutting may be performed after the tubular structure 8 has been pinned. The cutting blades 102, 103 may be arranged such that they cut through the tubular structure 8 at a different elevation than where the pin 4 is located. Alternatively, the cutting blades 102, 103 may be arranged at the same elevation as the pin 4. However, between pinning and cutting, the tubular structure 8 is lifted or lowered relative to the tool body 2 such that the cut is performed at a different elevation from where the pin 4 is located.

(25) In a situation where several tubular structures are positioned within each other (not shown), pinning the tubular structures prior to cutting may prevent an inner tubular structure from dropping or sliding relative to an outer tubular structure after cutting.

(26) FIG. 5B shows an example of a tubular structure 8 that has been pinned and is ready to be cut. As can be seen from FIG. 5B, the tubular structure 8 is positioned closer to the actuators 5 as compared to when the tubular structure 8 is held by the reaction member 3 used for pinning. This is due to the limitation in stroke of the piston rods 52. To enable the cutting blades 102, 103 to fully cut through the tubular structure 8 within the stroke of the piston rods 52, the tubular structure must be positioned closer to the first cutting blade 102.

(27) From FIG. 5B it can also be seen that the cutting blades 102, 103 are positioned at a lower elevation than the pin 4 to prevent the pin 4 from restricting the cutting operation. It can also be seen that the reaction member 3 used for pinning is opened in FIG. 5B, as compared to closed in FIG. 5A. In FIG. 5A the second enveloping element 34 is also removed. Whether the reaction member 3 is opened or closed has no effect on the cutting operation. One or the other may be desirable for practical reasons.

(28) It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design many alternative embodiments without departing from the scope of the appended claims. In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. Use of the verb “comprise” and its conjugations does not exclude the presence of elements or steps other than those stated in a claim. The article “a” or “an” preceding an element does not exclude the presence of a plurality of such elements.

(29) The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.