NO335432B1 - Subsea well frame with side protection panel - Google Patents

Description

Subsea well frame with side protection panel

The present invention relates to well frames for seabed wells. In particular, the invention relates to a configuration of well frame hatches for the protection of valve trees and other internal equipment.

Background

It is common to arrange subsea wells in protective subsea well frames with a majority of well locations. For example, the well frame may comprise four well spaces, whereby two spaces are arranged on either side of a manifold placed in between. In order to gain access to well equipment, such as the valve trees, hatches are arranged over the well spaces which can be turned or lifted away.

Such a well frame is shown in the accompanying Fig. 1, which illustrates a well frame with four well spaces and rotatable hatches which are supported on a robust framework. The top of the well frame is flush with the top cover of a manifold arranged between two pairs of well spaces. For the discussion here and below, we say that the manifold has a longitudinal axis that is parallel to the lines between the two well sites in each pair of well sites (which are on different sides of the manifold).

The vertical sides of the well frame are open for access to the valve trees by an ROV, through openings under the upper frame rod. With the well frame shown, an ROV can access the valve tree from two sides, namely from the side opposite the side facing the manifold and the side facing in directions parallel to the longitudinal axis of the manifold.

The hatches turn about a pivot axis that is perpendicular to the longitudinal axis of the manifold. Accordingly, when a hatch is in an open position, the ROV will preferably have access to a valve tree from the side opposite the manifold to avoid collision with the hatch.

When the manifold is lowered into the well frame, all hatches will preferably be in an open position to avoid collision with the manifold. It should be noted that the upper framework must be sized to accommodate the manifold when it is lowered or raised.

Patent publication N0177647 describes another protective structure for subsea equipment. The structure has a robust framework, on top of which a plurality of rotatable hatches are arranged.

Publication NO944507 describes a protective cover for underwater installations, where the cover is made of composite material. The covers are rotatably fixed at the top of a framework.

GB2462266 describes a seabed protection structure that is intended for a single well site. The structure can be tilted away from its protective position and thus expose the well site.

Publication CA2508559 describes a protection structure adapted to the protection of a wellhead for an onshore well. The structure presents two parts which together form a closed superstructure over the wellhead. The two parts can be individually tilted apart so that the wellhead is exposed. One part features an inspection hatch that can be opened and closed to view the structure when in the closed position.

Publication WO02075103 likewise describes a protective structure with only one cover intended to protect subsea equipment.

Another embodiment of a protection device for seabed installations is described in international patent application WO 03044316. This device has a top cover with a grid and four slanted and grid-equipped side covers which project up to the top of the device from a lower position. The side covers are hinged at the lower position so that they can pivot out of the device to an open position.

The purpose of the present invention is to provide a subsea well frame that can accommodate a manifold and with a plurality of well frames, which well frame combines effective protection of the subsea equipment inside while providing effective operational access, such as for an ROV.

The invention

The present invention provides a seabed well frame comprising a plurality of well spaces arranged adjacent to a manifold receiving space, whereby the well frame comprises a plurality of well frame hatches for the protection of well equipment, including a valve tree. The hatches comprise at least a top protection cover and a side protection panel. Furthermore, the side protection panel comprises a secondary door which is hingedly attached to the hatch. The secondary door leaves an access opening adjacent to an adjacent hatch position when in an open position.

This feature provides ROV access to subsea equipment in the well frame even if the hatch is in a closed position, for example to a valve tree instrument panel.

Such a secondary door may leave an access opening adjacent to an adjacent hatch when the secondary door and said adjacent hatch are both in open positions. One hatch is preferably arranged for each well space. As will be apparent from the example description below, this secondary door enables an ROV to gain access to the space between two adjacent valve trees even when the hatch comprising said secondary door is closed.

The side protection panel may also include a primary door hinged to the hatch.

The well frame preferably does not have any remaining framework structures that protrude towards the top of the well frame when the hatches are in an open position.

In accordance with a further embodiment, the well frame comprises a wire deflector arranged in the gap between adjacent arranged hatches. The deflector will prevent wires, such as trawl wires, from entering the gap. Such entry could cause trawl equipment to become stuck in the well frame, which could cause large forces from the cable when the trawl crew tries to untie it.

In the embodiment comprising a wire deflector, the wire deflector is preferably attached to a first of said adjacent hatches and the second hatch comprises a deflector guide element. The guide element is arranged to lift away said deflector when the second hatch is moved from an open position to a closed position. Thus, the deflector is moved out of the path of movement of the second hatch when this is closed. The deflector is thus brought into a position in which it partially overlaps both of the aforementioned adjacent hatches. As will be apparent from the drawings referred to in the example description below, the deflector is advantageously arranged in connection with the edges of said hatches which lie flush.

The well frame preferably has a plurality of valve trees arranged in said well locations, whereby at least one of said valve trees has a valve tree connection interface facing an adjacent valve tree, whereby said valve tree connection constitutes a fluid connection to the manifold connection pipe. That is, in this embodiment, the valve tree connection interface is arranged between two adjacent valve trees. Said manifold connection interface can consequently be operated by an ROV which is arranged at least partially in the space between said one valve tree and said adjacent valve tree. The ROV can preferably have access to said room both when only one of the adjacent hatches is in an open position and when both of the adjacent hatches are in an open position, in the first case partly through said secondary door.

With such a solution, even with a well frame with more than four well spaces, for example six or eight, all valve tree connections to the manifold can be operated with an ROV. It is therefore not necessary to have a separate tool for such an operation.

The top protective cover and a side protective panel preferably have a substantially horizontal and vertical extent, respectively.

The shown configuration of the hatches results in a number of advantages. For example, one hatch will provide top and side protection of subsea equipment, while simultaneously providing both top and side access when in an open position. Furthermore, one avoids having remaining framework in the area of the seabed equipment when the hatches are opened. This provides more space and freedom of movement for other operational equipment, such as an ROV. This advantage also applies to the installation of a manifold to be placed between the well spaces, which will be clear to a person skilled in the art from the discussion of the example description.

The omission of a framework that surrounds the seabed equipment when the hatches are in the open position makes it possible to use a smaller well frame than in the known technique. This is because the frameworks used in the known solutions must be sufficiently large to provide access for an ROV between the framework elements.

Furthermore, by providing the hatches with side protection panels, trawl doors or trawl vanes will not be caught in any framework bar. Instead, when they hit the well frame they will just slide upwards along the side protection panel, until they move free from the well frame. With known framework well frames, a trawl door can become hooked, resulting in extremely large forces being applied to turn the trawl door around the framework rod before it disengages. The subsea well frame in accordance with the present invention will therefore not be exposed to such extreme forces.

Due to the necessity of being trawlable, the well frame should be provided with inclined surfaces leading to the top of the well frame structure. Due to the omission of the overhanging framework, these surfaces may start further in (or lower, respectively) on the well frame than would be possible with a framework well frame. This feature also helps to make the well frame smaller than with the known solutions.

The hatches of the well frame are preferably arranged to rotate between a closed and an open position, about a pivot axis arranged at a lower end of the hatch when it is in the closed position.

A manifold receiving space is advantageously arranged to receive a manifold with a longitudinal direction, whereby said hatches are arranged to rotate between a closed and an open position about a pivot axis which extends mainly parallel to said longitudinal direction. Turning the hatches in this direction will remove them from the manifold receiving space when installing or removing the manifold.

The axis of rotation is preferably arranged under an ROV operating room, whereby said operating room is able to accommodate an ROV which is arranged to operate an ROV interface to said valve tree. Consequently, when a hatch is pivoted to the open position, an ROV can be placed over the side protection panel and pivot axis or hinges when in an operational position. In such a position, it can, for example, operate an instrument panel on a valve tree arranged in a well space.

Execution example

As the essential features of the present invention have been described above, a more detailed embodiment example is given in the following with reference to the accompanying drawings, in which

Fig. 1 is a perspective view of a seabed well frame in accordance with the known

technique;

Fig. 2 is a perspective view of a seabed well frame in accordance therewith

the present invention, with all hatches in a closed position;

Fig. 3 is a perspective view of the well frame in Fig. 2, with all hatches in one open

position and four valve trees installed;

Fig. 4 is a top view of the well frame in Fig. 3, with only three valve trees; Fig. 5 is an enlarged perspective view of part of the well frame and an ROV in it an operating position; Fig. 6 is an enlarged perspective view of part of the well frame and an ROV in it an additional operating position; Fig. 7 is an enlarged top view of part of the well frame, with an ROV in it an operating position; Fig. 8 is an enlarged perspective view of a gap between two adjacent ones well frame hatches; Fig. 9 is the same drawing as in Fig. 8, with one of the hatches in a partially rotated position; Fig. 10 is an enlarged perspective view of a connection device for

providing fluid communication between a valve tree and the manifold.

Fig. 1 shows a seabed well frame in accordance with known technology, with four well locations, of which two locations are arranged on each side of a manifold with a longitudinal axis and longitudinal sides. The well frame has a robust framework with protective hatches arranged on top. The protective hatches lie flush with the top protective cover of the manifold, thus forming a substantially flat upper surface. Fig. 2 and Fig. 3 show a subsea well frame 1 in accordance with the invention. The well frame 1 is anchored to the seabed (not shown) with four suction anchors 3. It has four well spaces, each of which has an installed valve tree 5 (Fig. 3). Between the two pairs of well spaces with valve trees 5, a manifold 7 with a longitudinal axis and longitudinal sides is arranged. The two longitudinal sides each face a pair of valve trees 5. At each end of the manifold 7, a protective cover 11 for an underwater line is arranged.

For each well space, the well frame 1 comprises one hatch 9. The shown well frame 1 consequently has four hatches 9. The hatches 9 can rotate about a pivot axis, between a closed and an open position. The axis of rotation is defined by hinges 13 to which the hatches 9 are attached.

The hatches 9 can be opened by pulling connected cables or by operating a hydraulic cylinder (not shown).

The closed position is shown in Fig. 2, whereby the open position is shown in Fig. 3. When the hatches 9 are in the open position, they have rotated in a direction away from the centrally arranged manifold 7, so that they reveal the valve trees 5 in the well sites. It should be noted that in the open position there is no remaining framework above the well spaces or in the area of the manifold 7 (apart from any framework for the manifold itself). The manifold 7 can therefore be lowered or raised into or out of position between the valve trees 5, even when the protective cover for the underwater line is attached to it, without risk of collision with the well frame 1.

The hatches 9 have a top protection cover 9a, a first side protection panel 9b and a second side protection panel 9c. The top protective cover 9a is substantially horizontal in the closed position, whereby the first and second side protective panels 9b, 9c are substantially vertical. However, one can also imagine that they have a different angle, provided that the top protection cover 9a has an extent with a horizontal component and the side protection panels 9b, 9c have extents with vertical components. In the embodiment shown, the hatches also have inclined transition surfaces 9d which extend between the top protection cover 9a and the two side protection panels 9b, 9c, respectively.

It should be noted that with a well frame in accordance with the invention with more than four well spaces, for example six or eight, hatches can be arranged over the intermediate well spaces without any other side protection panel

Fig. 4 shows a top view of the well frame 1 in Fig. 1 and Fig. 2, with all hatches 9 in the open position, but with only three valve trees 5. The hatches 9 are turned approximately 90 degrees out from the valve trees 5, leaving an ROV - operating room above the hatch 9, or the first side protection panel 9b, and the axis of rotation (hinges 13). This space is capable of accommodating an ROV 15 which is arranged to operate an ROV interface (not shown) to the valve tree 5. In the figures, the ROV 15 is only schematically shown.

The dashed circle with reference number 6 indicates a free space for additional equipment, such as a blowout preventer (BOP), when the hatches 9 are in the open position.

Fig. 4 also shows the manifold connection pipe 17 for fluid connection between the valve trees 5 and the manifold 7. As can be seen from Fig. 4, all the valve trees 5 in this embodiment are connected to the manifold 7 with the valve tree connection interface 19 which is connected to the manifold connection pipes 17. Furthermore, all the valve tree connection interfaces 19 are arranged on the same side of the valve tree 5 relative to the manifold 7. This position is a position rotated relative to the valve tree 5 approximately 90 degrees clockwise from the manifold 7. This means that from the perspective of the ROV 15 approaching se any valve tree 5 from the side opposite the manifold 76, each valve tree 5 will have the same configuration of the valve tree connection interface 19. A valve tree connection interface 19 could also be arranged on the opposite side of the valve tree. However, they should preferably be arranged on the same side of the valve tree 5 in relation to the access direction of the ROV 15. It should be noted, however, that for the valve trees 5 arranged in the position of that at the lower, right corner in Fig. 4, the ROV one 15 preferably use access to the valve tree connection interface 19 from the right side, i.e. access in a direction parallel to the longitudinal axis of the manifold 7. This is illustrated in Fig. 7. The same applies to a valve tree 5 arranged in the opposite upper left well space to the well frame 1 in Fig. 4.

Reference is now made to Fig. 5, where the ROV 15 is shown in a position for operating the valve tree connection interface 19 (not shown in Fig. 5 due to the ROV in front of it). The ROV 15 has moved partially into the space between the left and right (barely visible) shown valve tree 5. In contrast to Fig. 4, the well frame 1 in Fig. 5 is shown with the hatch 9 covering the valve tree 5 on the right side in the closed the position. The hatch 9 on the left side is in the open position. In order to provide a sufficiently large access space for the ROV 15, the first side protection panel 9b of the right hatch 9 in Fig. 5 is provided with a secondary door 21b. When the secondary door 21b is in the open position, part of the first side protection panel 9b of the hatch 9 on the right side will be pivoted away, leaving an opening for the ROV 15.

Note that if the hatches 9 covering both the right and left valve tree 5, or well spaces, respectively, are in the open position (as in Fig. 3 and Fig. 4), the ROV 15 will also be able to position itself in the operating position shown in Fig. 5. However, it is usually required that the adjacent well spaces or valve trees 5 are protected during operation over a valve tree 5. Consequently, all hatches 5 will usually only be open at the same time during installation of the manifold 7. Reference is made to Fig. 6, where all the hatches 9 are in the closed position. In this figure, the ROV 15 is shown in an operational position in which it can operate an ROV interface to the valve tree 5, such as an instrument panel (not shown). To gain access, a primary door 21a of the first side protection panel 9b is opened. Consequently, the valve tree 5 can be operated with the ROV without the need to open the hatches 9.

As briefly mentioned above, when operating the valve tree connection interface 19 to the valve tree 5 in the lower, right position in Fig. 4, the ROV 15 will have access in a direction parallel to the longitudinal axis of the manifold 7, as shown in Fig. 7. In Fig 7 is the lower right hatch 9 in the open position, providing ROV access space on the right side of the valve tree 5 in the drawing shown.

Reference is now made to Fig. 8 and Fig. 9, where a wire deflector 23 is shown arranged in the gap between two adjacent hatches 9. Such a gap can be, for example, 0.5 cm. The deflector 23 is preferably arranged in such a way that it partially overlaps two adjacent hatches 9, in the position of the edge which extends between the top protection cover 9a and the inclined transition surfaces 9d. The deflectors 23 are preferably arranged between each adjacent hatch and serve to prevent cables, such as trawl cables (not shown), from penetrating into the gaps between adjacent hatches 9. In a particularly advantageous embodiment, the deflector 23 is attached to a first hatch 9, whereby a deflector guide element 25 is attached to the opposite adjacent hatch 9. This is shown in Fig. 9. When the hatch 9 on the right side in Fig. 9 is turned into the open position, the deflector 23 will move with the hatch 9 itself. However, when the hatch 9 on the left side in Fig. 9 is rotated from the closed position, the deflector 23 will be lifted by an edge part 27 of the left hatch 9, until it slides off the edge part 27. When the left hatch 9 is rotated back into the closed position, the deflector guide member 25 will engage the deflector 23 and lift it sufficiently to allow it to slide on the surface of the edge portion 27. In this way, the wire deflector 23 is arranged to overlap both hatches 9 and at the same time enable both the adjacent the hatches 9 to move in and out of the closed position.

In Fig. 10, a connection device is shown for providing fluid connection between a valve tree 5 and the manifold 7. The connection device comprises an ROV-operable hydraulic piston 29 which is used by the ROV 15 to pull the opposite sides of the connection device together into a secure fluid connection. The connection device connects to the valve tree connection interface 19 (Fig. 4). The device can be operated with an ROV 15 in the position indicated in Fig. 5.

In one embodiment, the hatches 9 can be easily detached and attached to the rest of the well frame 1. When lowering or raising the well frame 1, its weight is consequently reduced accordingly. In addition, the additional mass that results from the hatches when they are moved in water is reduced, so that the requirements for the installation equipment dimensions are reduced.

Claims (2)

1. Subsea well frame (1) comprising a plurality of well spaces arranged adjacent to a manifold receiving space, which well frame comprises a plurality of well frame hatches (9) for the protection of well components, including a valve tree, characterized in that said hatches (9) comprise at least a top protection cover (9a) and a side protection panel (9b); said side protection panel (9b) comprises a hinged secondary door (21b). attached to the hatch (9), which secondary door (21b) leaves an access opening adjacent to an adjacent hatch position when said secondary door (21b) is in an open position. 2. Subsea well frame in accordance with patent claim 1, characterized in that said side protection panel (9b) comprises a primary door (21a) hinged to the hatch (9).