NO336296B1 - Device for lifting and / or moving operations of drilling equipment - Google Patents

Description

The invention relates to a device for lifting and/or moving operations on a deck, such as a drilling deck, comprising at least one lifting arm. The device is particularly suitable for lifting and/or moving loads, such as pipes, between different stations.

The invention can be used both on land and offshore.

In the oil and gas industry, pipes are used to create a fluid connection between a platform and a borehole. The pipe that forms the fluid connection can, in addition to being other types of pipe, for example be a drill string. The drill string is used to create a drill hole as the drill string progresses further and further down into the earth's crust. A drill string is usually formed by screwing together three and three, or four and four drill pipes (three, four drill pipes = one "stand", 27 - 40 meters long) for intermediate storage in a fingerboard, before one and one stand are screwed to the existing drill string and follows the drill string further down into the earth's crust. It is known to use so-called "iron roughnecks" for screwing together and unscrewing the drill pipes, and a number of companies offer this. "Iron roughneck" usually consists of a two-part wrench assembly and a spinning device. The spinning device sets one drill pipe length in rotation in relation to another drill pipe length for either screwing together to, or unscrewing from, the two drill pipe lengths in relation to each other. The wrench unit provides the necessary torque for screwing together or unscrewing.

Due to the limited space available on a typical drilling deck, it is often necessary to be able to move equipment, such as "iron roughneck", guide devices, gripping devices, etc. before, during, or after drilling operations. It may be necessary to move the equipment between different locations, for example to and from the well center, to and from a pipe storage location, such as a fingerboard, or to a parking position.

From US 7178612 B2, a device is known for moving an iron drilling assistant (Eng. "iron roughneck") in position for inserting or removing threaded pipe lengths in a drill string. The device can be designed as a double parallelogram arm. A number of embodiments are shown in US 7178612 B2 on how the connection point between a lower and an upper support arm is arranged. In all the embodiments shown, the moment will be transferred 'across' through the connection point, from a lower support arm, via the connection point with different configurations for moment transfer, to a diagonally opposite upper support arm. Furthermore, the moment arms are in direct contact with each other according to known technology, alternatively they are in contact with each other via a single joint.

US 2011/0108264 Al relates to an articulated device for handling drilling equipment, where the device comprises a foundation, a first set of arms which are rotatably connected to the foundation through one end, a connecting element rotatably connected to a second end of the first set of arms, a second set of arms pivotally connected through one end to the connecting member and a holder assembly pivotally connected to a second end of the second set of arms. A drive system cooperates with the first and second sets of arms to move the drilling equipment between a parked position and an extended position.

It is a disadvantage of the known technique that the parallelogram arm gets a movement that is not parallel to the floor or the substrate, and that the parallelogram arm will thus have different heights during extension. This entails a requirement for extra clearance under load to avoid bumping into the ground. Furthermore, the tool does not necessarily hit the load at the same height every time, which in some situations will require a height adjustment of the tool (parallelogram arm).

Other embodiments of the known technique will result in the moment transmission taking place by the lower support arm having to be designed with an extending arm to attach the connection point between the arms, which connection point is attached to the extending arm of the upper support arm. This will set specific requirements for a minimum size of the load transfer connection, which in turn sets design-limiting requirements for the height between the arms, the distance between the attachment of the lower and upper shock arms, as well as how much torque can be transferred as a result of gearing.

A purpose according to the present invention is therefore to provide a device which ensures rectilinear movement of the lifting arm, parallel to the drill deck, while at the same time creating greater freedom in relation to the design of the lifting arm.

The invention is defined in the independent patent claim, while the non-independent patent claims describe other characteristics of the invention.

The present invention relates to a device for lifting and/or moving operations of drilling equipment on a deck comprising a suspension device with at least one lifting arm, where the at least one lifting arm comprises at least one pair of torque arms comprising at least a first torque arm and a second torque arm,

where a first end of at least the first moment arm is connected to the suspension device and a second end of at least the first moment arm is connected to a synchronization link,

where a first end of the second moment arm is connected to the synchronizing link and a second end of the second moment arm is connected to a load-bearing device, and where the first and second moment arms are further connected through each synchronization link to at least one common synchronizing device. The invention stated herein will ensure that all arm attachments are always parallel in relation to each other, which in turn will mean that the load-carrying device will remain parallel to the floor, e.g. a drill deck.

The torque transmission in the synchronization link according to the present invention has at least three separate links; the two synchronizing links which are connected to each torque arm, as well as the synchronizing device. The suspension device, to which the lifting arm is connected, can displace the lifting arm in a vertical movement up or down, in order to raise or lower a load above the floor.

In a preferred embodiment of the device, the lifting arm further comprises at least a first and a second synchronizing arm, where the first torque arm is arranged in parallel with at least the first synchronizing arm,

and where a first end of the first synchronization arm is connected to the suspension device and a second end of the first synchronization arm is connected to the synchronization link,

where the second torque arm is arranged in parallel with at least the second synchronizing arm, and where a first end of the at least second synchronizing arm is connected to the synchronizing joint and a second end of the at least second synchronizing arm is connected to the load-bearing device.

According to one aspect of the device, the synchronizing link comprises at least one guide for recording the at least one synchronizing device.

In one embodiment, the synchronization link can be arranged perpendicular to a direction of movement of the at least one lifting arm.

In one embodiment, the synchronization device may comprise at least one wheel, at least one sliding block or at least one roller bearing.

In a further aspect, the synchronizing device may comprise a shaft to which the synchronizing links may be connected.

In one embodiment, the synchronization link comprises one or more beams.

In one embodiment, the at least one lifting arm can further comprise a movement device for moving the at least one lifting arm. In a specific embodiment, the movement device may comprise a cylinder or an electric motor, or another device which causes the lifting arm to move.

In one aspect, the movement device may be connected to the suspension device at the first end and the first or second torque arm at the other end. Alternatively, the movement device can be connected to the first or the second synchronization device.

In one embodiment, the lifting arm can further comprise at least one second synchronizing link connected to the other end of the second torque arm and a third torque arm connected to the second synchronizing link at one end and where the second and third torque arms are further connected through each synchronization link to at least one common synchronization device.

Several non-limiting embodiments of the invention will now be described with reference to the accompanying figures where like parts are given like reference numbers, and where: Fig. 1 shows an embodiment of a lifting arm according to the present invention; Figures 2A-2D show the position of the synchronizing device in different positions of the lifting arm; Fig. 3A-3B show an alternative embodiment of the synchronizing link; Figure 4 shows an alternative embodiment of a lifting arm according to the invention; and Figures 5 and 6 show further embodiments of a lifting arm according to the invention. Fig. 1 shows an embodiment of a lifting arm 1 according to the present invention. The lifting arm 1 is connected to a suspension device 6 at one end. The lifting arm 1 has a first pair of torque arms comprising a first torque arm 2 and a second torque arm 3. A first end of the first torque arm 2 is connected to the suspension device 6 and a second end of the first torque arm 2 is connected to a synchronization link 9 in a first attachment point 14. A first end of the second torque arm 3 is connected to the same synchronizing joint 9 as the first torque arm 2 in a second attachment point 15, so as to be able to transfer torque from the first torque arm 2 to the second torque arm 3. A second end of the the second torque arm 3 is connected to a load-bearing device 7 in a fifth attachment point 18.

The synchronization link 9 comprises first and second synchronization links 10, 11, where a first synchronization link 10 is connected to the first torque arm 2 at one end and to a synchronization device 12 at the other end, and a second synchronization link 11 is connected to the synchronization device 12 at one end end and the other torque arm 3 at the other end. At least one guide 13, for recording the synchronization device 12, is arranged in the synchronization link 9.1 the example shown, the guide 13 is arranged vertically, and will thus allow a vertical movement, but prevent a horizontal movement of the synchronization device 12.

Furthermore, a first 4 and a second 5 synchronization arm are shown. The first synchronizing arm 4 is arranged in parallel with the first torque arm 2. A first end of the first synchronizing arm 4 is connected to the suspension device 6 and a second end of the first synchronizing arm 4 is connected to the synchronizing link 9 in a third attachment point 16. The second synchronizing arm 5 is arranged in parallel with the second moment arm 5. A first end of the second synchronizing arm 5 is connected to the synchronizing joint 9 in a fourth attachment point 17 and a second end of the second synchronizing arm 5 is connected to the load-carrying device 7 in a sixth attachment point 19.

A movement device 8, shown as a cylinder &, is connected to the suspension device 6 at one end and the second synchronizing arm 5 at the other end. In other embodiments, the movement device 8 may be connected to any of the first torque arm 2, the second torque arm 3, or the first synchronization arm 4. Alternatively, the movement device 8 may be connected to a synchronization link or between arms, such as between the first and second torque arms 2, 3 or between the first and second synchronizing arms 4, 5. If the lifting arm 1 comprises more torque arms or synchronizing arms than is shown in the figure, the movement device 8 can be connected to any of these.

In operation, the movement device 8 will control the movement of the second synchronization arm 5, which will move the second torque arm 3 in parallel. A rotational movement of the second torque arm 3, as a result of movement of the movement device 8, will force the second synchronizing link 11 to push on the synchronizing device 12, which will force the first synchronizing link 10 in an opposite rotational movement relative to the second synchronizing link 11 and hence an opposite movement of the first moment arm 2. The first and second moment arms 2, 3 will therefore mainly, in the embodiment shown in Figure 1, always form the same angle in relation to a vertical plane through the synchronization link 9 (i.e. mirror-symmetrical if the synchronization link 9). Figures 2A-D show the position of the synchronization device 12 in different positions of the lifting arm 1. Figure 2A shows the lifting arm 1 in a fully extended position. In this position, the synchronization device 12 will be at the top of the guide 13 and the first and second torque arms 2, 3 are in an extended position, each of the torque arms 2, 3 with an extension angle of approx. 60 degrees. In Figure 2B, the lifting arm 1 is in a partially extended position compared to what appears in Figure 2A. Figure 2C shows the lifting arm 1 in a partially folded position, while in Figure 2D the lifting arm 1 is in a fully folded position. Figures 3A and 3B show alternatives at the synchronization link. Figure 3B shows the inside of the synchronization link 9 and the connections between the synchronization links 10, 11, the moment arms 2, 3, the synchronization device 12 in the guide 13 etc. Figure 3B also shows details of a first connection ear 20 arranged on the first moment arm 2, which connection ear 20 connects the first torque arm 2 to the first synchronizing link 10, and a second connecting ear 21 on the second torque arm 3, which connects the second torque arm 3 to the second synchronizing link 11.

Although the shown embodiments are shown with the torque arms 2, 3 arranged below the synchronizing arms 4, 5, it should be understood that the torque arms 2, 3 can be arranged above the synchronizing arms 4, 5. An example of such an embodiment is shown in Figure 4. Furthermore, a person skilled in the art will understand that although the shown embodiments show a "V-shape" on the lifting arm 1, it is also possible to turn the lifting arm 1 the other way so that it will form an inverted "V-shape", examples of this is shown in figures 5 and 6. Figure 5 shows an embodiment where the first and second torque arms 2, 3 are arranged above the first and second synchronizing arms 4, 5, while in figure 6 the torque arms 2, 3 are arranged below the synchronizing arms 4, 5 .

The embodiments described herein are to be considered non-limiting. It is obvious that a specialist in the field can make modifications or changes to the invention without going outside the scope of the invention, as defined in the appended patent claims. Although the lifting arm described herein is described in connection with "iron roughneck", it should be understood that the device can be used to move or lift other elements as well, such as mud box, casing tongs, grease for pipe threads, centering arm etc. Furthermore, it can be several moment arms and the synchronizing arm synchronizing arms connected to the examples shown, so that a lifting arm can comprise at least three moment arms, with an associated increasing number of synchronizing joints.

Claims (10)

1. Device for lifting and/or moving operations of drilling equipment on a deck comprising a suspension device (6) with at least one lifting arm (1), where the at least one lifting arm (1) comprises at least one pair of torque arms comprising at least one first torque arm (2) and a second torque arm (3), where a first end of the first torque arm (2) is connected to the suspension device (6) and a second end of the first torque arm (2) is connected to a synchronization link (9), characterized in that the synchronization link (9) comprises at least one guide (13) ) for recording at least one common synchronizing device (12), where a first end of the second torque arm (3) is connected to the synchronizing link (9) and a second end of the second torque arm (3) is connected to a load-bearing device (7) , and where the first (2) and second (3) moment arms are further connected through each synchronization link (10, 11) to the at least one common synchronization device (12). 2. Device according to claim 1, characterized in that the lifting arm (1) further comprises at least a first (4) and a second (5) synchronizing arm, where the first torque arm (2) is arranged in parallel with at least the first synchronizing arm (4), and where a first end of the first synchronization arm (4) is connected to the suspension device (6) and a second end of the first synchronization arm (4) is connected to the synchronization link (9), where the second torque arm (3) is arranged in parallel with at least the second synchronizing arm (5), and where a first end of the at least second synchronizing arm (5) is connected to the synchronizing link (9) and a second end of the at least second synchronizing arm (5 ) is connected to the load-bearing device (7). 3. Device according to claim 1, characterized in that the guide (13) is arranged perpendicular to a direction of movement of the at least one lifting arm (1). 4. Device according to any one of claims 1-3, characterized in that the synchronization device (12) comprises at least one wheel, at least one sliding block or at least one roller bearing. 5. Device according to any one of claims 1-4, characterized in that the synchronization device (12) comprises a shaft to which the synchronization links (10, 11) are connected. 6. Device according to any one of claims 1-3, characterized in that the synchronization links (10, 11) comprise one or more beams. 7. Device according to any one of claims 1-5, characterized in that the at least one lifting arm (1) further comprises a movement device (8) for moving the at least one lifting arm (1). 8. Device according to claim 7, characterized in that the movement device (8) is connected to the suspension device (6) at the first end and the first (2) or the second torque arm (3) at the other end. 9. Device according to claim 7, characterized in that the movement device (8) is connected to the suspension device (6) at the first end and the first (2) or the second (3) synchronizing arm at the other end. 10. Device according to any one of claims 1-9, characterized in that the lifting arm (1) further comprises at least one second synchronizing link connected to the other end of the second torque arm (3) and a third torque arm connected to the second synchronizing link in its first end, and where the second (3) and third torque arm are further connected through each synchronization link to at least one common synchronization device.