NO336087B1 - Test device for subsea well equipment - Google Patents

Description

Test device for subsea well equipment

The present invention relates to a device for testing and for inspecting various seabed components, such as a seabed valve tree or an internal valve tree cap. In particular, the device is designed for inspection of such well equipment from below.

Background

In the field of subsea hydrocarbon wells, valve trees are arranged on top of a subsea wellhead to control pressure and fluid flows. The valve trees, as well as other subsea well equipment such as blowout preventers (BOP), are lowered from a surface installation down to the wellhead.

Publication US4007782 describes a device for parking and moving a blowout preventer overboard on a floating drilling rig, between a parked position and an applied position.

Before installation on the well, the valve tree is tested and inspected on land and/or on the floating installation. To test the seals of the tree, it is connected to a test head which is arranged on a test device, often called a test skid. The test head is a piece of pipe that corresponds to the wellhead nozzle of the seabed well. When properly connected to the test head, the operator can apply pressure to perform a seal test.

In addition to the sealing test, the valve tree is also inspected visually. To inspect the lower interior side of the tree, the tree must be raised to a level that allows personnel to walk under it. To mount the tree in such a position, it is arranged on an inspection skid that provides space under the tree, where personnel can move.

Furthermore, the operator has other test skids available for testing other equipment, such as an internal valve cover (ITC). To perform testing, the operator locks the ITC to the internal bore of an ITC test head on an ITC test skid. The ITC test head exhibits internal locking profiles that correspond to the internal profiles of the valve tree head stub, to which the ITC is adapted to be locked when in use at the well location.

Having one test skid for each subsea component to be tested in addition to different skids for inspection results in an inappropriate amount of equipment. Such equipment increases the space required on site for testing and inspection. This is particularly important when this location is on a surface installation at sea, where both space and weight must be taken into account.

Accordingly, the purpose of the present invention is to provide test and inspection equipment that simplifies the test and inspection process, as well as reduces the required amount of equipment.

The invention

In accordance with the invention, there is provided a device comprising a support body and a test head, which test head is adapted to receive subsea well equipment, including a valve tree. The device also includes guide posts which are designed to guide such equipment on the device. In accordance with the invention, the device further comprises support platforms which are arranged to occupy at least two different vertical positions on the guide posts and to support the equipment.

The support platforms can advantageously comprise a support surface and partially surround an open space, whereby the support platforms are arranged to receive the guide posts in said space when they are moved laterally on the guide posts. With such a construction of the support platforms, they can be mounted on the guide posts from the side. There is no need to introduce the guide posts into a central limited space for the support plate forms.

The support platforms preferably comprise a retaining pin slot which is adapted to receive a retaining pin which, when arranged in the retaining pin slot, surrounds said open space together with the support platform. Such a retaining pin will consequently keep the support platform from moving laterally out of engagement with the guide post to which it is attached.

Further, the guide posts advantageously comprise apertures in at least two different vertical positions, adapted to receive a securing pin adapted to maintain the vertical position of the support platform when inserted into the aperture. This solution ensures that the support platforms are maintained in their vertical position when mounted on the guide posts.

In a preferred embodiment, the device comprises guide post extensions which are arranged to be arranged on top of the guide posts, in which position they together with the guide posts form a guide post assembly which projects vertically further up than the guide posts themselves.

The guide post extensions may present one or more apertures adapted to receive a locking pin adapted to maintain the vertical position of a support platform when inserted into the aperture. Consequently, the guidepost extensions can be used to support the subsea well equipment at a higher level.

The support body may comprise a guide post extension receiving assembly. In this way, the guide post extensions will always be available and you do not need to handle them separately.

In yet another embodiment, the test head is adapted to be moved on the support body, out of and into a test position. In this way, when it is moved out of the test position centrally under the subsea well equipment, personnel will have room that can be used during inspection of the equipment from below.

Example of embodiment

While the present invention has been described in general terms above, a more detailed and non-limiting example of embodiment will be given below with reference to the accompanying drawings, in which

Fig. 1 is a perspective view of a test and inspection skid in accordance therewith

the present invention;

Fig. 2 is a cross-sectional view of the test and inspection skid in Fig. 1; Fig. 3 is a cross-sectional view of the skid in Fig. 1, with a test head in another position; Fig. 4 is an enlarged perspective view of part of the skid in accordance with the invention; Fig. 5 is another enlarged perspective view of the skid; Fig. 6 to Fig. 8 are perspective views of a support platform, and show the process by connection to a guide post to the skid; Fig. 9 is a cross-sectional view of the support platform shown in Fig. 6 to Fig. 8; Fig. 10 is a cross-sectional view of the support platform shown in Fig. 6 to Fig. 9; Fig. 11 is a cross-sectional view of part of the test head of the skid; Fig. 12 is a cross-sectional view of the test head; Fig. 13 is a cross-sectional view of the skid in accordance with the invention, with an in reversible valve cover installed in the test head; Fig. 14 is an enlarged cross-sectional view of the upper end of a guide post and the lower end of a guide post extension provided thereon; Fig. 15 is an enlarged perspective view of the upper end of a guide post; Fig. 16 is an enlarged perspective view of a holding assembly adapted to

holding two guide posts and a chain hoist, arranged on the support body of the device; and

Fig. 17 is a detailed perspective view of part of the holding assembly.

Fig. 1 shows a test and inspection device in accordance with one embodiment of the present invention, herein called a test and inspection skid 1. The skid 1 comprises a lower support body 3. A test head 5 protrudes from the support body 3, which in Fig. 1 is arranged in a central test position. At each of the four corners of the support body 3 there is a guide post 9. The guide posts 9 are, among other features, designed to guide subsea equipment, such as a valve tree (XT) on the test head 5 for testing the valve tree.

Reference is now made to Fig. 2, which illustrates a valve stem assembly 100 arranged on the test and inspection skid 1 shown in Fig. 1. The XT assembly 100 is guided down on the guide posts 9. Furthermore, the XT assembly 100 is supported in an elevated inspection position with support platforms 11. On each guide post 9, the support platforms 11 are locked to the guide post 9 at a predetermined level. Accordingly, as seen in Fig. 2, the XT assembly 100 is supported at a level where it is not in contact with the test head 5. This elevated position is convenient for manual inspection of the XT assembly 100, and particularly of its interior lower part of the valve tree 101.

When connecting the XT 101 to the test head, the support platforms 11 are arranged in a lower position on the guide posts 9. This feature will be described in further detail with reference to Fig. 6 to Fig. 10.

Fig. 3 is an illustration corresponding to Fig. 2. In Fig. 3, however, the test head 5 is shown in a position where it has been pulled out of the test position shown in Fig. 2. When it is pulled aside from the test position, space is provided directly under The XT 101 for personnel to inspect the inner and lower parts of the XT 101. In particular, the seals or sealing surfaces of the XT 101 are inspected from this room.

In this particular embodiment, a chain tensioner or chain pulley 13 is fixed between two connecting devices 15 which constitute a first pair of connecting devices, to move the test head 5 out of the test position shown in Fig. 2. Accordingly, the test head 5 can be moved out of the test position by means of manual force.

In order to provide sufficient space for the chain hoist 13, an extension arm 19 is arranged in the support body 3 for the test and inspection skid 1. When the chain hoist 13 is arranged to pull the test head 5 out of the test position, the extension arm 19 is extended a distance from the support body 3 and locked in this position. This position is shown in Fig. 3, while Fig. 2 shows the non-extended position. One of the connecting devices 15 of the first pair of connecting devices is arranged at the far end of the extension arm 19. Thus, space is provided for the chain hoist 13, even though the test head 5 has been pulled out of the test position and to a position at an edge of the support body 3.

To pull the test head 5 back to the central test position, the chain hoist 13 is attached to a second pair of connecting devices 17 which are arranged on the opposite side of the test head 5. Fig. 4 illustrates the extension arm 19 and the chain hoist 13 arranged between the first pair of connecting devices 15 in further detail. In order to facilitate the movement of the extension arm 19 out of and into the support body 3 by manual force, sliding plates 21 are arranged on the extension arm 19 which are arranged to provide only a low friction resulting from contact with the support body 3. Also shown is a extension arm locking pin 23 which is adapted to lock the extension arm 19 in the extended or retracted position. The locking pin 23 (only locking pin handle visible in Fig. 4) projects into a flange projecting from the support body 3 and locking hole 25 in the extension arm 19. Fig. 5 shows the first pair of connecting devices 15 when the test head 5 is in the central test position, before the extension arm 19 has been arranged in the extended position. In Fig. 5, a pair of sliding plates 27 are also shown on which the test head 5 slides when it is moved. The sliding plates 27 present a shoulder 27a which extends in the direction of the opposite sliding gap 27. A fixing plate 28 is attached to the downward facing side of the test head 5. The fixing plate 28 extends down into the space between the sliding plates 27 and into the grooves provided by said shoulders 27a , that is, under the shoulders 27a. In this way, the test head 5 is prevented from tilting or from leaving its contact with the sliding plates 27.

Reference is again made to Fig. 1. Here you can see the second pair of connecting devices 17. One connecting device 17 is attached to an edge part of the support body 3, while the other is attached to the test head 5. When the test head 5 is pulled back into the test position, the chain hoist 13 is attached between these connecting devices 17.

It should be obvious to a person skilled in the art that the test head 5 can also be moved in and out of the test position by other means. For example, a hydraulic piston device can be arranged instead of using a manual chain hoist. Furthermore, instead of sliding plates 27, the test head could have been arranged on a rotating support plate whereby the test head was arranged eccentrically on the support plate in relation to the plate's axis of rotation.

As shown in Fig. 1 to Fig. 3 above, support platforms 11 are arranged on the guide posts 9. The support platforms 11 are designed to support seabed equipment at a predetermined elevated position on the skid 1. With reference to Fig. 6 to Fig. 10, their function will now be described in more detail.

Fig. 6 shows a detailed perspective view of a guide post 9 on which a support platform 11 is to be mounted. The support platform 11 presents a support surface 51 on which the seabed equipment, such as the XT assembly 100, is arranged to rest. Centrally arranged in the support surface 51 is an open space 53 which is only partially surrounded by the support surface 51. This makes it possible to move the support platform 11 on the guide post 9 with a lateral movement, so that the guide post 9 is arranged in said open space 53. Fig. 7 shows the support platform 11 in such a position.

In order to maintain the support platform 11 in the position mounted on the guide post 9, a retaining pin 55 is inserted into two opposing retaining pin grooves 57 in the support plate form 11. When the retaining pin 55 is arranged in these receiving grooves 57, the supporting platform 11 cannot be pulled out laterally by engagement with the guide posts 9. I

In Fig. 8, the retaining pin 55 is fully inserted into the retaining pin grooves 57.

Furthermore, in order to prevent the support platform 11 from moving downward on the guide post 9 in the vertical direction, a safety pin 59 is provided below it. The securing pin 59 extends through receiving pin openings 61 in the walls of the guide post 9. The receiving pin openings 61 are perhaps shown more clearly in Fig. 1. Consequently, the receiving pin openings 61 in the guide posts 9 define at which levels the support platforms 11 can be attached, and consequently the possible elevations to the subsea equipment to be installed on the skid 1, such as the XT assembly 100 (Fig. 2 and Fig. 3).

Fig. 9 and Fig. 10 show the support platform 11 and parts of a guide post 9 in cross-sectional view.

Referring to Fig. 6 to Fig. 10, the support platform 11 also includes means for locking the supported seabed equipment 100 to the support platform 11. One such locking device is the clamp 63. The clamps 63 present a layered main part with a nut at one end. At the opposite end, the clamps 63 have a hook which is arranged to be engaged with the seabed equipment 100. This happens when the clamp 63 is at a more elevated position in relation to the position shown in Fig. 6 to Fig. 9. When the hook is in engagement with the seabed equipment 100, the connection can be tightened by rotating the nut.

Other means of attaching the seabed equipment to the support platforms 9 are rotatable clamps 65. The rotatable clamps 65 can be rotated about their hinged connection with the support platform 11 and grasp and hold a part of the seabed equipment arranged on the support platform 11. Fig. 11 shows an enlarged cross-sectional view of a part of the test head 5. Attached to a lower part of the test head 5 is a test chamber 5a with pressure connection devices for supplying test pressure. The connecting devices are in fluid communication with a pressure-conducting line 5b which is connected to a pressure-conducting channel 5c in the wall of the test head 5. With this arrangement, the operator is able to provide test pressure inside the test head when subsea equipment, such as the valve tree 101, is attached to it. Fig. 12 shows a cross-sectional view of a preferred test head 5. In this preferred embodiment, the test head 5 exhibits different profiles which are adapted to engage with different types of seabed equipment. Such equipment may comprise a valve tree 101, an internal valve tree cover or a cup tester. The test head 5 shown in Fig. 12 comprises an XT profile 5x which is arranged to engage with connected profiles of a valve tree. The XT profile 5x is also suitable for connection to a valve tree setting tool. Furthermore, the test head 5 has internal profiles 5y which are arranged to connect to an internal valve cover (ITC). In Fig. 13, the test and inspection skid 1 is shown with an ITC 200 installed in the test head 5. In addition, the test head 5 can have an inner profile arranged for connection to a cup tester (not shown).

Consequently, with such a test head 5, as illustrated in Fig. 12, it is possible to test different types of subsea equipment with only one test skid 1.

In some cases, it may be necessary to extend the vertical extent of the guide posts 9 to support subsea equipment, such as a valve tree setting tool

(TRT) at an elevated position. This can advantageously be done by arranging guide post extensions 109 on top of the guide posts 9. The combination will thus form a guide post assembly that projects further up than the movable guide posts 9. Similarly to the guide posts 9, the guide post extensions 109 also include one or more openings 61 arranged to receive a securing pin 59 when support platforms 11 are arranged on the guide post extensions 109. Fig. 14 shows an enlarged cross-sectional view of the upper part of the guide post 9 and the lower part of a guide post extension 109 which is arranged on the guide post 9. As shown, the guide post 9 has an upper narrow part which is arranged to be introduced into a lower sleeve part of the guide post extension 109. Inside the guide post extension 109, a shoulder is arranged which abuts the narrow part. In Fig. 15, the upper part of a guide post 9 is shown, with its narrow part. The narrow portion presents a groove into which a radially inwardly projecting protrusion of the guide post extension 109 will enter when lowered onto the guide post 9, to align the angle of the guide post extension 109.

When the guide post extensions 109 are not in use, they can advantageously be stored on the support body 3 of the device 1. Fig. 16 shows a perspective view of a guide post extension holding assembly 181 which is arranged on the support body 3. The holding assembly 181 is designed to secure two guide post extensions 109. In addition it is arranged to hold the chain hoist 13, with which the test head can be moved as explained above. Fig. 17 shows one end part of the guide post extension holding assembly 181, without the guide post extensions 109, but with the chain hoist 13 attached. By storing the chain hoist 13 and the guide post extensions 109 on the support body 3, they are always available and there is no need to transport or store them separately.

In addition, one can advantageously store means for lifting the device, such as lifting straps, on the support body 3.

Instead of having the guide post extensions arranged to be fixed on top of the guide posts, one can also imagine a solution with telescopic guide post extensions. With such a solution, the extensions can be arranged within an inner diameter of the guide posts, and be pulled up to protrude above the guide posts when in use. Their outer diameter would then of course have to be smaller than the outer diameter of the guide posts. For example, they could be secured to the desired vertical position with a pin projecting through aligned holes in the guide posts and guide post extensions, respectively.

Claims (8)

1. Device (1) comprising a support body (3) and a test head (5), which test head (5) is adapted to receive subsea well equipment (100), including a valve tree (101), which device further comprises guide posts (9) arranged to guide the equipment (100) on the device (1), characterized in that the device further comprises support platforms (11) which are arranged to occupy at least two different vertical positions on the guide posts (9) and to support the equipment (100). 2. Device in accordance with patent claim 1, characterized in that the support platforms (11) comprise a support surface (51) and that they partially surround an open space (53), the support platforms (11) being arranged to receive the guide posts (9) in said space (53) when moving laterally on the guide posts (9). 3. Device in accordance with patent claim 2, characterized in that the support platforms (11) comprise a retaining pin slot (57) arranged to receive a retaining pin (55) which, when arranged in the retaining pin slot (57), surrounds said open space (53) together with the support platform (11). 4. Device according to one of the preceding patent claims, characterized in that the guide posts (9) comprise openings (61) in at least two different vertical positions, arranged to receive a securing pin (59) which is arranged to maintain the vertical position of the support platform (11) when introduced into the opening (61). 5. Device in accordance with one of the preceding patent claims, characterized in that it further comprises guide post extensions (109) which are arranged to be arranged on top of the guide posts (9), in which position they, together with the guide posts (9), form a guide post assembly that protrudes vertically higher than the guide posts (9). 6. Device according to patent claim 5, characterized in that the guide post extensions (109) present one or more holes (161) which are adapted to receive a securing pin (59) which is adapted to maintain the vertical position of the support platform (11) when inserted into the opening (161). 7. Device in accordance with patent claim 5 or 6, characterized in that the support body (3) comprises a guide post extension holding assembly (181). 8. Device in accordance with one of the preceding patent claims, characterized in that the test head (5) is arranged to be moved on the support body (3), out of and into a test position.