NO20101082A1 - Anti-blowout fuse - piston stroke operated load string sheaves / seal stroke piston - Google Patents

Description

BOP Pipe Impactor Operated Load String Shear/Seal Impactor

The present invention relates to a pipe suspension landing string housing for use in a blowout preventer (BOP) in a well, a well with such a

pipe suspension landing string housing, and a method for emergency shutdown of a well.

During the lifetime of a well, there is a need to install, remove and/or carry out work on a pipe suspension in a well. To do this, a pipe suspension string is used. When this is locked to the pipe suspension, the landing string sits in the blowout protection (BOP). One of the main functions of a BOP is to be able to isolate the well and enable the riser to be disconnected via a lower riser seal in the blowout preventer. This must be able to happen quickly in emergencies, for example when a drilling or service vessel from which the riser is exposed is operated from its station in bad weather.

Subsea completion and maintenance riser equipment has certain functional requirements. One such requirement is the ability to be able to cut various media (coil pipes, braided cables, smooth cables) and to be able to isolate a well, in accordance with the equipment user's requirements. A pipe suspension landing string that sits in the blowout protection represents an additional complication with regard to the requirements to be able to cut a number of media. There is therefore a need for the introduction of an option for a landing string with cutting possibilities, and also the possibility of cutting with a possible high load on various media. Such cutting options must often also include possibilities for liquid and gas sealing of the barrier element after cutting.

Solutions to this problem are subject to limitations in outer diameter (BOP-ID (inner diameter)) and length (to accommodate BOP spacing for other jobs), and are challenging in terms of the combined effects of internal and external pressures and temperatures.

There are some solutions where ball valves are used to provide a liquid and gas seal after a cap, as the ball valve itself also enables a cap. Details regarding some of these known solutions can be found, for example, in US 6 708 946 (Expro), "caged" floating ball valves used in connection with landing strings, in WO 200640592 (Enovate), "En-Power "-ball valve, floating ball valve used in connection with landing strings, and in patent EP 20204619 (Schlumberger) SenTree ball valve, "confined" floating ball valve used in connection with landing strings.

US 6,474,412 describes a pipe suspension landing string with a BOP operated release mechanism. In the system described there, the blowout fuse's rams (eng: rams) are used to activate/deactivate a connection in the tube suspension landing string, to divide this into two separate elements, thereby enabling an easy and quick release.

However, these previously known solutions represent limited solutions to the problem. For landing string applications, it is based on the use of ball valves to achieve sealing. Given the space requirements and geometry of a ball valve, when it is used for capping, the sealing areas and thereby also the sealing integrity will be highly susceptible to compromise. As such, a gas-tight seal after capping has proven difficult to achieve with existing technology.

Furthermore, the ball valve technology typically requires a linear movement of a piston, which must then be transformed into a rotary movement of the ball element. This constitutes very large forces in the ball valve activation mechanism and is a limiting factor with regard to the valve's casing properties. There is also limited available space in a blowout preventer (BOP), and this also represents limitations regarding the possible load that can be transferred between the linear piston and the rotational movement of the ball element, which represents a disadvantage.

One purpose of the present invention is to be able to avoid some of the disadvantages associated with the known methods.

This purpose is achieved with a pipe suspension landing string housing, with a well, and with a method as stated in the patent claims. The independent patent claims and the description indicate further features.

A pipe suspension landing string housing is thus proposed which includes an outer structure with a through passage which, during use, will be aligned with the wellbore, as the outer housing is also intended to be placed in a blowout preventer (BOP) in a well.

In accordance with the invention, the housing further includes a movement device which is arranged movably in the outer structure, with a first end which cooperates with, or forms working equipment in the through passage of the landing string housing, and with a second end which is designed to cooperate with an activator on the outside of the tube suspension landing string housing. The work equipment can be a cutting device for cutting elongated elements such as coiled pipes, cables, etc., which pass through the through passage, or a sealing device which seals the through passage across this, as an emergency disconnect device (eng: emergency disconnect device) often includes both the possibility of capping and sealing in addition to being able to divide the landing string housing into two parts, or a combination of these possibilities, for example a capping and sealing function in one and the same work equipment.

According to one aspect, the movement device may include a movement element which is radially movable in the housing, and forms the other end, being a

fluid piston arrangement is associated with the moving element on one side, in cooperation with at least one work equipment on the other side of

the fluid piston arrangement. This makes it possible to have a movement device which

activates several elements, and that the movement element can provide an axial movement in different directions to activate the work equipment. Another possibility for achieving this is that the movement device can include a movement element that can be moved radially in the housing, and forms the other end, with at least a second movement element being connected to the first movement element in the housing, and is connected to a work equipment for movement of this from an inactive position, and to an active position.

According to one aspect, the movement device can include a movement element arranged radially movable in the housing, with a first end forming a casing device, a sealing device, an emergency breaking device or a combination of these, and the other end is designed to cooperate with an activator.

Two movement devices are advantageously used with a movement element with a casing and sealing function arranged on opposite sides of the housing. At least one device or movement element is designed with a sheathing edge on a first end, while a second end is designed to cooperate with an activator. These ends can be arranged on opposite ends of the device or element. The device is so arranged in relation to the outer structure that the first end is directed inwards, while the other end is directed outwards away from the outer structure. An inward direction is to be understood here as meaning that the device is directed into the continuous passage in the house. The second end can be arranged on an opposite end relative to the first where the cutting edge is, so that an essentially linear connection between the two sides is thereby achieved. The device is arranged to be movable in the outer structure in such a way that it can be moved from a retracted position, where there is a continuous passage in the house, and to an extended position where the continuous passage will be closed with the device element and any objects in the opening are been cut. With more than one device, the devices or elements together can close the through passage. As mentioned above, the device can be affected non-linearly, for example cam-operated, arm-operated or rotation-operated. The relatively large load that can be transferred from the BOP pipe bearing rams (eng: BOP pipe ram) is used to activate the casing and/or sealing device.

This movement is achieved as a result of the cooperation between an external activator and the device's other end. The device is arranged in the outer structure in such a way that the movement from the retracted position to the extended position is activated by means of an activator which is placed outside the housing's outer structure.

A system according to the present invention will have the advantage that a relatively high activation load can be transferred on the traditionally limited landing string, so that coiled pipes with larger diameters can thereby be cut. The system according to the invention also removes the need for a specific umbilical and control system for an activation mechanism for the landing string. A favorable synchronization of the control system logic between the blowout fuse and the landing string is enabled. These elements will reduce system costs, reduce the risk of damage, and will also increase the system's speed of use, with associated reduced costs.

According to one aspect, the outer structure and the device's other end can be designed so that, in use, a pipe impact piston in the blowout protection will be able to interact with the other end. The outer structure will then have an outer shape that is adapted for placement at a certain level in the blowout protection, and the device will be so arranged in relation to the outer structure that the other end of the device will cooperate with a pipe impact piston in the blowout protection, for activation of the device from a withdrawn position, and to a driven position. The movement of the pipe impact piston and the movement of the device will be linear movements, so that it will be possible to achieve large forces for the movement of the device, for cutting or cutting objects that may be in the passage through the house.

According to another aspect, a locking system can be arranged between the device and the outer structure, so that the device cannot thereby be operated unintentionally. Such a locking system can be a shear bolt which is arranged between the device or the movement element and the outer structure. Another possibility is to have a cutting disc that covers the device's first end or the work equipment towards the through passage, or possibly to have a locking ring that is arranged between the outer structure and the device. With such a locking system for locking the device in a retracted position, it is prevented that the device can be activated, for example during pressure testing of the blowout fuse.

The casing and sealing device can also form a sealing surface that closes the continuous passage in the housing when the device is in a run-out state. According to one aspect, the casing edge of the device can be arranged on a different side of the device or the movement element than a sealing surface.

According to another aspect, the housing may include at least electrical sealing seats arranged in the outer structure. The sealing seat will cooperate with the device, the work equipment, or the movement element in an extended position, thereby sealing the continuous passage in the house. The sealing seat can be an element or several connected elements, which are arranged in the through passage of the housing, or it can be at least partially formed by the element forming the outer structure.

According to yet another aspect, the outer structure may include slits for positioning the movable device, and at least one sealing element arranged between the device and the outer structure in the slits. This will seal the continuous passage in the house against the surroundings around the house, in normal use usually an annular space between the house and the blowout protection.

According to another aspect, two devices can be arranged in the outer structure, which devices can move in the same direction, in intersecting or opposite directions, across an axis in the through passage, since in an extended state they will cooperate to close the continuous opening in the housing. In normal use of the house, a first device can be arranged in such a way that it will be placed above the second device, and the devices can in an extended state have overlapping surfaces. One device will then be arranged closer to one end of the house than the other device. Thus, it can be said that the devices are arranged mutually offset in the house. In such an embodiment, with two devices, with one arranged above the other in the housing, one of the devices can be designed with a casing edge in a lower part, or in the lower part of the side of the device that faces the other device, which will then be arranged under the first device. The second device can then have a casing edge on an upper part or on the top part of the side of the device that faces the first device. When the two devices are moved towards each other, from a retracted to an extended state, one or the two cutting edges will move towards the other device, forming an effective cutting tool. During this movement, the cutting edges of the devices will be the first parts of the devices that meet each other for cutting an object, and the devices will continue the movement until they overlap each other, and have provided a seal.

The devices will be moved to an extended position, where they overlap each other, in which extended position they close the continuous opening in the housing. In such an embodiment, the sealing surfaces can be arranged on sides of the device adjacent to the side that includes the sheath edge. The sealing surfaces can be arranged on sides of the devices facing away from the other device, as sealing seats are arranged in the housing's through bore or the housing, and cooperate with a sealing surface on the device. In such an embodiment, two sealing seats will be arranged, arranged on opposite sides of the two devices.

According to the invention, it is also proposed a system for a well, including a blowout protection which is placed at the entrance to the well, and a pipe suspension string housing in accordance with one of the embodiments described above, and where the other end of the device is arranged opposite a pipe impact piston which is arranged in the blowout fuse. When the pipe impact piston in the blowout protection is activated, this will activate the device from a retracted position and to an extended position, where the through opening in the housing will be closed. In such an embodiment, the force acting on the devices for cutting objects in the house will be a linear force from the pipe punches and via the devices. This makes it possible to use fairly large forces in this system.

The invention also relates to a method for an emergency disconnection of a well, including a pipe suspension string housing which is arranged in a blowout preventer (BOP). In accordance with the invention, the method includes activation of a pipe impact piston in the blowout protection, for cutting objects that may extend through the pipe suspension landing string housing, and with closing the through opening in the pipe suspension landing string housing, a device arranged in the pipe suspension landing string housing being moved from a retracted position and to a exhausted position. The retracted position will correspond to an open condition in the house.

With the help of the invention, blowout protection pipe rams can be used to cut and seal a tool string in the landing string bore without using the blowout valve's shear rams (eng: BOP pipe rams). It will also be possible to use an activation mechanism for cutting and sealing which will be independent of the landing string control system.

As the devices move in a linear direction flush with the blowout fuse's pipe impact piston, very high cutting or cutting forces will be available, using the blowout fuse's pipe impact piston. This means, for example, that coiled pipes with a large outer diameter OD can be cut. This will also result in a quick response time for cutting and sealing with the use of the blowout protection's pipe impact piston.

One of the possible inventive features is that the sealing surfaces of the devices are separated from the casing edges, the casing edges being on the inner surfaces, while the sealing surfaces are on the outer surfaces. As, according to prior art, ball valve technology is used for capping and sealing, the present invention offers an alternative to the existing solutions.

In summary, the inventive concept includes two possible sheathing and sealing devices and seating elements that are located inside the main landing gear housing. The devices can extend through the main housing and into the blowout protection annulus for the marine riser, and are sealed both with respect to internal and external pressure by means of sealing elements arranged in the landing string main housing. Movements of the sealing devices under the influence of internal or external pressure are limited by means of a locking system, for example shear pins. These shear bolts prevent the casing devices from being activated in connection with routine pressure testing of the landing string or blowout protection. The landing string main housing, which includes the casing and sealing details, is placed with precise spacing in the blowout fuse so that the landing string casing and sealing locations are brought up to the level of the blowout fuse's pipe impact piston level. If, in connection with normal operations, it is deemed necessary to cut off the internal tool string in the landing string bore, then the aforementioned blowout protection rams can be activated to a closed position. Thereby, the shear pins which hold the landing string sheath and sealing devices in the open position are cut off, and they are activated so that they go to the closed position, i.e. an extended position, cutting the internal tool string, and providing a seal against internal seal seats in the landing string.

The invention will now be described in more detail in the form of a non-limiting embodiment example, and with reference to the drawing, where Fig. 1 shows a cross-section through part of a blowout fuse with part of a pipe suspension landing string housing placed inside the blowout fuse, and in a closed position, and

Fig. 2 shows the system in fig. 1 in an open state.

As indicated in fig. 1 and 2, a pipe suspension landing string housing 2 is placed in a blowout protection 1. Between the outer side of the housing 2 and the inside of the blowout protection 1, there is an annular space 3. The pipe suspension landing string housing 2 also has a continuous opening 9. These elements, the blowout protection 1 and the pipe suspension landing string housing 2 , which is only partially shown here, will otherwise be in accordance with other necessary features that are found in a blowout protection and in a pipe suspension landing string housing.

According to the invention, the housing 2 includes a casing and sealing device 5, in the embodiment shown two casing and sealing devices 5. The devices 5 are movable in slots 21 in the housing 2. The devices 5 are further designed with a first end 50 with a casing edge 51, and with a second end 54 which is designed to cooperate with an activator which is placed outside the housing 2. The first end 50 and the second end 54 are arranged on opposite sides of the device 5. The activator for activating the devices from a retracted position which shown in fig. 2, and to an extended position as shown in fig. 1, will in normal use be a BOP pipe stroke piston 4, as shown in the endorsement. The devices 5 also include sealing surfaces 52. These are arranged on a side of the device which faces from the side where the cover edge 51 is designed. These sealing surfaces 52 will cooperate with a landing string sealing seat 8 which is connected to the housing 2. Thereby, two parts of the through opening 9 are sealed in relation to each other. Sealing elements 7 are also arranged in grooves 22 in the slot 21, between the devices 5 and the slots 21 in the housing 2. These sealing elements 7 seal the continuous opening 9 in the housing 2 against the annular space 3. A shear bolt 6 is also indicated, which acts as a locking system between the devices 5 and the housing 2.

The two devices 5 are arranged on opposite sides of the housing 2. The respective first end 50 of the devices 5 includes the cutting edge 51, which faces the through opening 9 in the housing 2. The other end 54 faces outwards from the housing 2, and is arranged in the annular space 3 between the housing 2 and the blowout protection 1. This other end 54 can be affected by a blowout protection impact piston 4, so that the device can thereby be moved from a retracted position to an extended position. This cooperation enables a mainly linear power transfer, and therefore allows for the use of greater forces during cutting. The devices 5 are further arranged above each other in the outer structure, so that they will overlap each other in the extended position. The sheath edges 51 of the two devices will only meet each other when the devices are moved. The other end 54 can be designed to cooperate with the pipe impact piston 4, so that the device 5 can thereby be moved from a retracted position to an extended position, and from the extended position and back to the retracted position.

Fig. 2 shows a condition where a tool in a cable and/or coiled pipe can be guided through the landing string. When the devices 5 are activated, they will be moved from the retracted position, and across the central opening where the tool, the wire and/or the coil pipe are located. Thereby, these components are cut with the help of the cutting edge 51. In the embodiment shown, the cutting takes place as a result of the cooperation between two cutting edges 51, which come from two opposite directions. This helps to keep the wire, coil tube or tool in a substantially centered position during cutting, before the devices 5 have cut the element, and cooperates with the landing string seal seat 8, and closes and seals the passage.

The invention is explained above with reference to a non-limiting embodiment example. Changes and modifications are conceivable all within the inventive framework as determined by the patent claims.

Claims (15)

1. Pipe suspension string housing including an outer structure with a through passage which in use will be arranged flush with the wellbore, which outer housing is designed for placement in a blowout preventer (BOP) in a well, characterized in that the housing further includes a movement device which is arranged to move in the outer structure, with a first end which cooperates with or forms a work equipment in the through passage in the landing string housing, and with a second end designed to cooperate with an activator outside said tube suspension landing string housing. 2. Pipe suspension string housing according to claim 1, characterized in that the movement device includes a movement element which is radially movable in the housing, and forms the other end, and a fluid piston arrangement associated with the movement element on one side, and cooperates with at least one work equipment on the opposite side of the fluid piston arrangement. 3. Pipe suspension string housing according to claim 1, characterized in that the movement device includes a movement element which is radially movable in the housing, and forms the other end, and at least one second movement element which is connected to the first movement element arranged in the housing, and connected to a work equipment for moving the work equipment from an inactive position to a active position. 4. Pipe suspension string housing according to claim 2 or 3, characterized in that the work equipment is a casing device, a sealing device, an emergency breaking device or a combination of these. 5. Pipe suspension string housing according to claim 1, characterized in that the movement device includes a movement element which is arranged radially movable in the housing, the first end forming a casing device, a sealing device, an emergency breaking device or a combination of these, while the other end is designed to cooperate with an activator. 6. Pipe suspension string housing according to claim 5, characterized in that the movement element is designed with a sheathing edge at the first end, and that the device is arranged in relation to the outer structure in such a way that the first end faces inwards, while the other end is accessible from the outside of the outer structure, as the device is arranged to be movable in the outer structure, so that it can be moved from a retracted position where there is a through passage in the housing, and to an extended position where the through passage will be closed, and any objects extending through the opening will be cut off as a result of the device's movement. 7. Pipe suspension string housing according to one of the preceding claims, characterized in that the outer structure and the other end of the movement device are designed so that in use a pipe impact piston in the blowout protection will be able to cooperate with the other end. 8. Pipe suspension string housing according to one of the preceding claims, characterized in that a locking system is arranged between the movement device and the outer structure, which locking system prevents an inadvertent activation of the movement device from the retracted and to the extended position. 9. Pipe suspension string housing according to claim 6, characterized in that the device's cutting edge is designed on a different side of the device than a side that has a sealing surface. 10. Pipe suspension string housing according to one of the preceding claims, characterized in that the housing includes at least one sealing seat which is arranged in or at least partially formed by the outer structure, to cooperate with the device for sealing the through passage. 11. Pipe suspension string housing according to one of the preceding claims, characterized in that the outer structure includes slots for placing the movable device, and that at least one sealing element is arranged between the device and the outer structure in the slots. 12. Pipe suspension string housing according to one of the preceding claims, characterized in that at least two movement devices are arranged in different places around a perimeter of the housing, which movement devices act in a transverse direction or in opposite directions across the axis through the through passage, each movement device including a movement element which, in an extended state, cooperates to close the continuous passage in the house. 13. Pipe suspension string housing according to claim 12, characterized in that the devices are arranged mutually offset. 14. Well including a blowout preventer located at the entrance to the well, and a pipe suspension landing string housing in accordance with one of claims 1-13 of the blowout preventer, characterized in that the device's other end is arranged opposite a pipe impact piston which is arranged in the blowout protection. 15. Procedure for emergency disconnection of a well, including a pipe suspension landing string housing which is arranged in a blowout protection, characterized by the activation of a pipe impact piston in the blowout protection for cutting objects that had to extend through the pipe suspension landing string housing, with closing of the through opening in the pipe suspension landing string housing.