NO20110047A1 - Seabed valve tree assembly with top routing - Google Patents

Abstract

The subsea valve tree assembly comprising a valve tree, a valve tree frame, a control module and actuators with couplings that can be connected on the seabed to which a control module is connected through one or more wires. The wires are routed mainly along an upper side of the valve frame.

Description

Seabed valve tree assembly with top routing

The present invention relates to a seabed valve tree assembly and in particular lines which provide communication between a control module and various valve tree actuators.

Background

It is common to operate subsea valve actuators from a distance, for example from a floating installation. Such valve trees can include different valve actuators for opening and closing fluid communication. Due to the possible failure of communication with the actuators or the desire to operate a valve without communicating a signal through the field communication network, it is known to provide actuators with ROV interfaces, thus enabling the operator to operate the relevant actuators with an ROV (remotely controlled underwater vessel). Valve trees can include locking devices for locking and unlocking seabed elements to the valve tree itself or locking the valve tree to the wellhead. In particular, the operator can monitor parameters such as temperature and pressure in the well and in the valve tree using monitoring meters.

It is known to operate the actuators from a distance using electricity or hydraulic fluid which is provided from the seabed control module arranged to the valve tree assembly.

The control module is connected to the operator through communication lines and contains electrical and/or hydraulic means to operate the actuators. The control module is connected to the various actuators through wires.

The actuators are typically arranged in a group on one side of the valve frame. Furthermore, it is known to protect the actuators with an actuator cover. The actuator cover exhibits a plurality of openings that enable an ROV to engage and operate the actuators through the openings. In addition, the actuator cover has markings for the openings, which inform the ROV operator which opening leads to which actuator.

Due to the size of the seabed control module, it is arranged on an opposite or adjacent side of the valve tree frame in relation to the group of actuators and the actuator cover. Consequently, the wires running from the control module to the actuators must be routed between various components of the valve train assembly. This routing is done during assembly of the valve tree assembly, before it is lowered into the well. It is advantageous not to have the cables routed laterally outside the valve tree frame, as they will then be exposed to damage, for example in the event of a collision with an ROV or other subsea tools.

If a line needs to be replaced, the valve tree is usually pulled to the surface. This is a time-consuming process that is desirable to avoid. It is consequently an object of the present invention to provide a seabed valve tree assembly which is designed to facilitate the replacement of a line at a seabed location by means of an ROV.

The invention

In accordance with the present invention, a seabed valve tree assembly has been provided comprising a valve tree, a valve tree frame and actuators with connectors connectable on the seabed to which a control module is connected through one or more lines. In accordance with the invention, the wires are routed mainly along an upper surface of the valve frame.

In an advantageous embodiment of the invention, the mainly horizontal part of the routing path of the wires is arranged to be exposed to the surroundings in an upward direction. This move gives the operator access to the wires using an ROV from above.

The wires are preferably arranged at least partially under a movable protective structure which forms part of the upper surface of the valve frame. The operator is thus able to reach the wires by moving the protective structure out of its closed or protective position. The cables can still be protected against possible collisions, such as against colliding subsea equipment, when the movable protective structure is closed over the cable or cables.

The movable protective structure is preferably attached to the valve wooden frame by means of hinges. In this way, the operator can easily turn the protective structure between an open and closed position without having to take into account where it should be stored when it is not in the closed and protective position.

In a particularly advantageous embodiment, the valve tree assembly comprises a cable routing device, such as a guide channel, arranged in the upper part of the valve tree frame. The guide device can advantageously be arranged in combination with a protective structure arranged above it, such as a movable structure as described above. One can also imagine a guide structure without the protective structure. The guide structure can, for example, be in the form of a relatively deep and narrow channel, whereby its upper parts will constitute sufficient protection for the wires and thus make a movable protective structure unnecessary.

In another advantageous embodiment of the present invention, a connection between the actuators and the control module comprises individual wires that are connected between the actuators and a distribution device, which distribution device connects them to a lower number of wires that are connected to the control module. With such an embodiment, only a single wire needs to be replaced if a fault occurs, for example at the location of an actuator. Furthermore, a replacement of one of the lower number of wires is simplified, as the operator only needs to reconnect one wire between the control module and the distribution device. This feature will be further described in the example embodiment below.

The feature of having the wires routed mainly along an upper surface of the valve frame will preferably mean that most of the routing portion of the wires which is in the lateral direction (ie horizontal component) is done along it

the upper surface of the valve tree frame or valve tree assembly, and that the wire or wires in this routing section are not covered by any component of the assembly, except perhaps by any protective structure.

Accordingly, the operator will preferably be able to lay a wire from above, into his intended routing path, in said routing section, without having to remove a component of the valve tree assembly (other than the protective structure, if any, such as a hatch) or having to thread a wire through openings or under components to the valve reassembly. The operator will be able to perform routing using an ROV in the seabed position.

Example of embodiment

As the general features of the invention have been described above, a more detailed, non-limiting example of embodiment will be described in the following with reference to the drawings, in which

Fig. 1 is a perspective view of a valve tree assembly in accordance with the invention, comprising a valve tree tube spigot (Xmas tree spool) and a valve tree frame; Fig. 2 is a perspective view of the valve tree assembly of Fig. 1, seen from another angle; Fig. 3 is a perspective view of the valve tree assembly in Fig. 1, seen from a third angle; Fig. 4 is a perspective view of the valve tree assembly in Fig. 1, seen from a fourth angle; Fig. 5 is a top view of the valve tree assembly of Fig. 1;

Fig. 6 is an enlarged partial perspective view of the drawing in Fig. 3; and

Fig. 7 is a perspective view of a wiring device.

Fig. 1 shows a seabed valve tree assembly 1 with a valve tree frame 3 and valve tree 5 arranged in this. The valve tree 5 has a valve tree pipe stub 7 which projects upwards from the valve tree frame 3. The valve tree frame 3 has a mainly rectangular shape, with a corner post 9 typically arranged at each of the four corners.

For the purpose of describing the shown example of embodiment, the valve tree assembly 1 is defined to have a front side 3a, a back side 3b, and two flank sides 3c. In addition, it has a top side 3d.

A control module 11 is arranged at the back 3b of the valve tree 5. The control module 11 is connected to a surface location, such as a floating installation (not shown). The control module 11 shown in this embodiment has four wet-mate connections 11a which are arranged to be connected to the lines 101 by means of an ROV (remotely operated underwater vessel). The lines 101 contain electrical and/or hydraulic conductors for communication with a plurality of valve tree actuators 13 arranged on the opposite side of the valve tree 5, namely on the front side 3a of the valve tree assembly 1.

The valve actuators 13 can thus be remotely controlled by the operator through the control module 11 and connected lines 101. The actuators 13, shown in the pictures, are valve actuators for controlling different fluid passages, but the lines 101 can also be connected to valve tree pressure and valve tree temperature sensors, or butterfly valve systems, distributor boxes or other equipment with which power and/or signal communication is required.

As somewhat indicated in Fig. 1, two wires 101 are routed from the rear side 3b towards the front side 3a along an upper part of the valve tree assembly 1.1 the upper part to the top side 3d of the valve tree frame 3, a protective structure in the form of a protective hatch 15 is arranged. The protective hatch 15 is arranged over the path of the wires 101 towards the actuators 13. As illustrated in Fig. 2, the protective hatches 15 are connected to the valve frame 3 by hinges, so that an ROV is able to move it between an open and closed position. When in the closed position, the protective hatch 15 is flush with an adjacent top plate, so that it forms a substantially flat top surface of the valve frame 3.

In the embodiment shown in the figures, two wires 101 are routed to a distribution device 105 (described below), from which further wires 103 are led to the actuators 13. However, it should be noted that the embodiments with wires routed directly from the control module 11 to the actuators 13 also fall within the scope of the present invention.

Reference is now also made to Fig. 2 and Fig. 3. The majority of actuators 13 are arranged at the front side 3a of the valve tree assembly 1. An upper ROV cover 17a and a lower ROV cover 17b are arranged in front of the actuators 13. The upper ROV cover 17a is attached to the valve frame 3 by means of hinges 19. The upper ROV cover 17a can thus be moved between an open and closed position by means of an ROV. In addition, the ROV covers 17a, 17b present openings 21 through which an ROV can access an actuator 13. Accordingly, in the event of a failure of the communication line between an operator and a valve actuator 13, the operator can use an ROV to operate the actuator 13 , through said openings 21.

In the event of a malfunctioning actuator 13, it can be replaced with a replacement actuator using an ROV when the ROV cover 17a is in the open position. Consequently, the operator does not need to pull the entire valve stem assembly 1 to the surface to replace the actuator 13.

To prevent the ROV cover 17a from moving unintentionally, for example as a result of water flow, the valve tree assembly advantageously includes a safety locking device (not shown) which maintains the cover in its closed position. Such a locking device can, for example, be a simple hook on the valve frame 3 which the operator can turn in and out of a loop in the ROV cover 17a to lock and unlock, using the ROV. It may also, for example, be a holding clamp device which will retain the ROV cover in the closed or a predetermined open position until a predetermined force is applied to the cover. Another embodiment comprises providing a motor to the cover, which enables the operator to open or close the cover from a distance and to maintain it in the desired position with the help of the motor.

The actuators 13 are provided with wet-mateable connections 13a which are connected to the wires 103. The wires 103 form part of the communication line between the operator and the actuators 13. It is known in the art to connect wires directly between an actuator 13 and the control module 11.1 in this embodiment, however, a majority of first wires 103 are connected between the actuators 13 and a distribution device 105, while a couple of other wires 101 are connected between the distribution device 105 and the control module 11. This will now be explained in more detail.

The distributor device 105 is arranged near the actuators 13, at the front side 3a of the valve tree assembly 1. This is illustrated in Fig. 3, which shows the valve tree assembly 1, with the protective hatch 15 and the adjacent top plate removed for illustration purposes. The distributor device 105 has a plurality of first wet-connectable connectors 105a which are connected to the first wires 103 which are connected to the actuators 13. In addition, as shown in the top view of Fig. 5, it has second wet-connectable connectors 105b connected to the second wires 101, which are connected to the control module 11. The distribution device 105 thus connects a number of first lines 103 to a lower number of second lines 101. Only one second line 101 will advantageously be sufficient to establish communication between the control module 11 and the connected actuators 13. However, in the event of a malfunction at the second line 101, a redundant line 101 is arranged in parallel with the other, so that a replacement is avoided in the event of one of the two failing.

It will now be obvious to a person skilled in the art that the described valve tree assembly 1 is particularly well suited for replacing a line 101, 103 and/or an actuator 13 by means of an ROV. Instead, as in accordance with the prior art, of having to replace a wire leading from one actuator to a remotely located control module by means of an ROV, one can now replace either a short first wire 103 arranged at the front side 3a of the assembly 1, or the second wire 101 arranged at the top side 3d of the assembly 1. This makes it unnecessary to route a wire in a manner consistent with the prior art, along the outside of the valve frame 3, or to pull the entire assembly to the surface to replace the wire.

In addition, with the ability to open the ROV cover 17a with the ROV, the operator is also able to replace a malfunctioning actuator 13 at the seabed location. In this embodiment, the lower ROV cover 17b is bolted to the valve tree assembly 1, and has small valves bolted to it. However, one can also imagine an embodiment where the valves were arranged behind the lower cover 17b and the cover was movable.

Fig. 6 shows a part of the diagram in Fig. 3 in more detail.

In the top part of the valve tree assembly 1, a wiring device 201 (not shown in Fig. 6) is advantageously arranged. This principle is shown separately in Fig. 7, which shows part of the distribution device 105, the control module 11, and two other lines 101 which are arranged in a guide channel 201. The second line or lines 101 will therefore be easy to route by means of a ROV, between the distribution device 105 and the control module 11.1 addition, the wires will be well protected by the movable protection hatch 15, shown in

Fig. 1 and Fig. 2.

Instead of guide channel 201, as shown in Fig. 7, other types of cable guide devices 201 can also be imagined. For example, a series of U-shaped arches can be arranged in the upper part of the valve tree frame 3.

As an alternative embodiment of the communication assembly between the control module 11 and the actuators 13, a second line 101' is led from the control module 11 and to a logical distribution device 105'. In this embodiment, the second line 101' does not include the majority of communication lines originating from the actuators 13 and which are combined in the distribution device 105, as described above. Instead, it has only one, two, three or a few lines of communication with the logic distribution device 105'. The operator thus communicates with a logic unit inside the logic distribution device 105', and the distribution device is arranged to transmit or receive the desired electrical signal to or from an actuator 13. Accordingly, by providing a logic device, such as a microcontroller, inside the distribution device 105', the second wire(s) 101' can be reduced to a single wire or a wire with fewer lines than the second wire 101 in accordance with the embodiment described above. An advantage of this is that the wet connection includes fewer contacts.

Claims (6)

1. Seabed valve tree assembly comprising a valve tree, a valve tree frame and actuators with connections connectable on the seabed to which a control module is connected through one or more wires, characterized in that the wires are routed mainly along an upper side of the valve tree frame. 2. Seabed valve tree in accordance with patent claim 1, characterized in that the main horizontal part of the routing path of the cables is designed to be exposed to the surroundings in the upward direction. 3. Seabed valve tree in accordance with patent claim 1 or 2, characterized in that the wires are arranged at least partially under a movable protective structure which forms part of the upper surface of the valve tree frame. 4. Seabed valve tree in accordance with patent claim 3, characterized in that said protective structure is attached to the valve tree frame by means of hinges. 5. Seabed valve tree in accordance with one of the preceding patent claims, characterized in that the assembly comprises a wiring device, such as a guide channel, arranged in the upper part of the valve tree frame. 6. Seabed valve tree assembly in accordance with one of the preceding patent claims, characterized in that the connection between the actuators and the control module comprises separate lines connected between the actuators and a distribution device, which distribution device connects them to a lower number of lines connected to the control module.