NO338827B1 - High pressure riser assembly - Google Patents

Description

High pressure riser assembly

The present invention relates to a high-pressure riser assembly where an upper part of the assembly can be detached from a riser string extending down to a seabed position to avoid mutual movement between the upper part and a surface installation during heave movements.

Background

Various heaving elimination systems are known to avoid mutual movement between an upper part of a riser system and a heaving installation during work on equipment on the upper part. Such equipment can be, for example, a surface flow valve tree. Without such hive elimination systems, such work is fraught with risk and the operating window is significantly reduced by weather conditions.

Such systems often involve a sliding joint or a telescoping joint. Two sleeves, one telescopically inserted into the other, are arranged to reciprocate relative to each other during work on the upper part of the riser system. The two casings are also arranged to be locked together in a high pressure mode, in which situation well pressure goes up to the upper casing.

A somewhat similar solution is described in Norwegian patent publication NO330829.1 this solution extends a high-pressure riser string from the seabed and is connected to a floating installation through a tension ring which is connected to the tensioning system of the installation. At a distance below the tension ring, below the water surface, a locking device is provided together with an upper blowout protection (upper BOP). From the floating installation, a high-pressure sleeve is lowered inside a sleeve for the larger diameter riser string. The high-pressure sleeve can be locked to the locking device to complete a high-pressure path from the seabed up to the installation. During work on the upper part of the high-pressure sleeve, it can reciprocate inside the riser string, above the position of the locking device.

Patent publication US6173781 B1 describes a telescopic riser joint where two high-pressure pipes are firmly connected relative to each other in a non-telescoping mode, and which are displaceable relative to each other in a telescoping mode. Their mutual fastening takes place at the upper area of the outer sleeve, and at a distance from the lower area of the inner sleeve.

Norwegian patent application NO20041094 describes a high-pressure riser system comprising a telescopic connection.

The invention

In accordance with a first aspect of the present invention, there is provided a high pressure riser assembly comprising a string of risers extending upwards from the seabed towards a floating structure. The floating structure has a heave compensating tension system which is connected to an upper part of the riser string via a tension ring. The high pressure riser assembly further comprises a high pressure sleeve, the lower end of which is adapted to be releasably attached to the upper end of the riser string by means of a locking device. When in a disconnected mode, the high pressure sleeve pulls together with the floating structure and when in a connected mode, the high pressure sleeve is fixed relative to the riser string. The extent of the high pressure sleeve remains constant. In accordance with the first aspect of the present invention, the locking device is arranged above the water level. Furthermore, the locking device is exposed.

In particular, the locking device is exposed to the surrounding air in a space between the floating structure and the water table in such a way that the operator can make a visual inspection of the locking device without removing any components covering the locking device.

The upper part of the riser string may comprise a high-pressure riser joint to which a tension ring adapter is attached. The tension ring is attached to the tension ring adapter. The high-pressure riser joint will typically be called an overhaul riser joint.

In one embodiment, the locking device and tension ring adapter are one unit. It can, for example, be made by forging. In another embodiment, one can imagine that this unit also includes an interface or connector to the riser string / an overhaul riser. Such a connector can also be part of the one unit, together with the tension ring adapter and the locking device. The tension ring adapter can, for example, be connected to the riser string by means of threads or by welding.

In a further embodiment, when the high-pressure sleeve is connected to the riser string, the high-pressure sleeve may be exposed to the surroundings above the position of the locking device. That is, there is no sleeve arranged around the high-pressure sleeve.

In an advantageous embodiment, a receiving bore for a main body of the locking device comprises an inclined entry surface against which a split for an engaging part (feeding part), such as the lower end of the high-pressure sleeve, is arranged to slide when entering the receiving bore. The splitting ring is pulled back radially by sliding against said entry surface. The split ring is designed to engage with a locking profile in the main body of the locking device.

Furthermore, a plurality of hydraulic actuators are preferably arranged around the circumference of the main body of the locking device and are arranged to push the split in a radial direction out of said locking profile.

When in the disconnected mode, the high-pressure casing can hang freely in the air below a drill deck.

Example of embodiment

As the various aspects of the invention have been described in general terms above, some detailed examples of embodiment will be given below with reference to the figures, where

Fig. 1 is a schematic diagram of a high pressure riser assembly in accordance

with an aspect of the invention;

Fig. 2 is a schematic diagram of a high pressure riser assembly in accordance

with another aspect of the invention;

Fig. 3 is a schematic view of a similar high-pressure riser assembly

the assembly shown in Fig. 2;

Fig. 4 is a cross-sectional view of the locking device; Fig. 5 is an enlarged cross-sectional view of a part of Fig. 4; Fig. 6 is a schematic view of the locking device in Fig. 4 together with a

tension ring and a tension ring adapter, mounted on an overhaul riser; and

Fig. 7 is a schematic view of the same components as shown in Fig. 6, but

with a different configuration.

Fig. 1 shows a high pressure riser assembly 100 in accordance with one aspect of the present invention. A floating surface installation has a drill deck 101 down through which extends a high-pressure (HP) casing 103. In connection with a subsea well, a high-pressure riser string 105 extends upwards from a valve tree 107 and an emergency disconnection package (EDP - emergency disconnection package). 109. A locking device 111 is arranged at an upper part of the riser string 105. The locking device 111 is designed to connect to a lower part of the HP sleeve 103 in such a way that a high-pressure path can exist from the seabed well, through the bore of the HP riser string 105 and further through the bore to the HP sleeve 103, up to the floating installation (represented by the drill deck 101). A surface flow valve tree (SFT) 113 is arranged at an upper part of the HP sleeve 103. The SFT 113 and the HP sleeve 103 hang down from a tension frame 115 in the derrick.

In the configuration shown in Fig. 1, the locking device 111 is arranged below sea level 117.

The HP sleeve 103 hangs down from the floating installation inside a spacer pipe 119 (spacer joint) and an outer cylinder (barrel) 121. The spacer pipe 119 is connected to the floating installation, hanging down from the drilling deck 101. The spacer piece 119 presents an outer diameter smaller than the inner diameter of the outer cylinder 121, and is adapted to reciprocate inside the outer cylinder 121.

The outer cylinder 121 is connected to and provides tension in the HP riser string 105. Via a tension ring 123 arranged on an upper part of the outer cylinder 121, the outer cylinder 121 is connected to a set of tension cables 125 which are part of the tension system of the floating installation.

The locking device 111 will be described in detail later.

When the HP sleeve 103 is disconnected from the locking device 111, no well pressure will exist in the upper part of the HP riser string 105. The riser string 105 may be provided with a riser valve (not shown), for example, which may be arranged a place between the EDP 109 and the upper part of the riser string 105.

The HP sleeve 103 will consequently have a disconnected mode where it pulls together with the drill deck 101 and consequently does not move in relation to the drill deck 101, and a connected mode where it does not move in relation to the riser 105, but moves in relation to the drill deck 101.

Fig. 2 shows another embodiment of an HP riser assembly 200. Several of the components of the HP riser assembly 200 in Fig. 2 are the same as those shown in Fig. 1. Corresponding components are given the same number, although in 200 -series instead of in the 100 series.

A particular difference from the embodiment shown in Fig. 1 is that the locking device 211 is arranged above the sea level 217. In addition, neither the outer cylinder 221 nor a spacer tube (not shown in Fig. 2) covers the HP sleeve 203. In disconnected mode, the lower part of the HP sleeve 203 freely in the air under the drill deck 201.

Furthermore, the locking device 211 is also not covered by any outer tube. As the locking device 211 is exposed, it is thus possible to inspect the locking device 211 visually, both during connected mode and disconnected mode. If necessary, it will even be possible to inspect the locking device from close range, for example by lowering personnel down to it with a harness.

The tension ring 223 is connected to the outer cylinder 223 and the locking device 211 is in a position above the tension ring 223.

Fig. 3 shows yet another HP riser assembly 300. As with the riser assembly 200 shown in Fig. 2, the HP sleeve 303 is exposed. Furthermore, the locking device 311 is arranged above sea level 317 and is also exposed.

A significant difference from the HP riser assembly 200 shown in Fig. 2 is that the HP riser assembly 300 shown in Fig. 3 is without the outer cylinder (221 in

Fig. 2). Instead, the tension ring 323 is connected to the upper part of the HP riser string 305 via a tension ring adapter. This component will be described later with reference to Fig. 6 and Fig. 7. A simplified HP riser assembly is thus provided.

With reference to Fig. 4 and Fig. 5, a locking device 11 will now be described. The locking device 11 could fit into the three embodiments of HP riser assemblies 100, 200, 300 described above. In this embodiment, the locking device 11 is attached to the upper part of the HP riser string 5, to which it is connected by means of an interface not shown at the lower end of the locking device. One skilled in the art will appreciate that the locking device could also be attached to the lower end of the HP sleeve 3, 103, 203, 303, and be adapted to connect to the upper part of the riser string.

Fig. 4 shows a main body 51 of the locking device in a cross-sectional view. The main body 51 has a bore 53 aligned with the bore of the riser string below it and to which it is attached. In an inner receiving bore 55, the lower part of an HP sleeve 3 is landed. In a lower part of the receiving bore 55 there is a sealing section 57 which is provided with high pressure seals.

The lower part of the HP sleeve 3 is provided with a split ring groove 59 in which a split ring 61 is held, cf. Fig. 5. The split ring 61 is arranged to expand radially outwards and into an opposing locking profile 63 in the receiving bore 55 of the main body 51 .That is, when the lower part of the HP sleeve 3 is not engaged with the locking device 11, the split ring 61 extends radially from the outer diameter of the lower part of the HP sleeve 3, and consequently past the diameter of the receiving bore 55.

When the split 61 enters the receiving bore 55, it slides on an inclined entry surface 65 over the receiving bore 55 with a substantially parallel sliding surface 66. This pushes the split 61 radially inwards, further into the splitting groove 59. As it is moved further down inside the receiving bore 55, the split will finally slip into the locking profile 63 of the main body 51. The HP sleeve 3 will then be locked to the locking device 11 and consequently to the HP riser string 105, 205, 305 below it.

In order to disconnect the HP sleeve 3 from the locking device 11, a plurality of hydraulic actuators 57 are arranged in the main body 51 around its circumference. The actuators 67 are designed to push the split ring 61 radially in and out of engagement with the locking profile 63. The actuators 67 can typically be hydraulic pistons that act directly on the split ring 61.

Particularly in the embodiments described above with reference to Fig. 2 and Fig. 3, one can also imagine a manual additional device which would make it possible to press the splitting ring 61 radially inwards and consequently out of the locking position. There could, for example, be a plurality of threaded through holes provided with threaded bolts which, when screwed in, could act directly on the split.

Fig. 6 shows a locking device 11, a tension ring 25 and a tension ring adapter 81 attached to an HP riser 5. This configuration fits with the high pressure riser assembly 300 described above with reference to Fig. 3. In this embodiment, the tension ring 25 is attached directly to a overhaul riser 5 with the help of a tension ring adapter 81. The outer cylinder shown in Fig. 1 and Fig. 2 is thus avoided.

Furthermore, in a particular embodiment of the configuration shown in Fig. 6, the locking device 11 and the tension ring adapter 81 have been produced as one unit, for example by forging.

In contrast to this, in the embodiment shown in Fig. 7, the locking device 11 is attached to the HP riser string 5 at a vertical distance from the tension ring adapter 81.

In the embodiments shown in Fig. 6 and Fig. 7, the tension ring 23 exhibits an internal bore 23a which receives the tension ring adapter 81. The two components exhibit opposing landing surfaces which transmit the vertical forces between the set of tension wires 25 and the HP riser string 5.

It will be understood by those skilled in the art that the locking device described herein, instead of being provided to the upper part of the riser string, may be provided to the lower end of the HP sleeve and be arranged to connect to the upper end of the riser string.

Claims (7)

1. High pressure riser assembly (200, 300) comprising a riser string (205, 305) extending upwards from the seabed towards a floating structure (201, 301), wherein the floating structure has a heave compensating tension system (225, 325) which is connected to an upper part of the riser string (205, 305) via a tension ring (223, 323), where the high-pressure riser assembly (200, 300) further comprises a high-pressure sleeve (203, 303) whose lower end is adapted to be releasably attached to the the upper end of the riser string (205, 305) by means of a locking device (211, 311), whereby when in a disconnected mode, the high pressure sleeve (203, 303) pulls together with the floating structure (201, 301) and when in a connected mode the high-pressure sleeve (203, 303) is fixed in relation to the riser string (205, 305), whereby the extent of the high-pressure sleeve (203, 303) remains constant, characterized in that - the locking device (211, 311) is arranged above the water level (217, 317); and that - the locking device (211, 311) is exposed. 2. High-pressure riser assembly (300) in accordance with patent claim 1, characterized in that the upper part of the riser string (305) comprises a high-pressure riser joint to which a tension ring adapter (81) is attached, and that the tension ring (323) is attached to the tension ring adapter (81 ). 3. High-pressure riser assembly in accordance with patent claim 2, characterized in that the locking device (311) and the tension ring adapter (81) are in one unit. 4. High-pressure riser assembly in accordance with one of the preceding patent claims, characterized in that when the high-pressure sleeve (203, 303) is connected to the riser string (205, 305), the high-pressure sleeve is exposed to the surroundings above the position of the locking device (211, 311). 5. High-pressure riser assembly (200, 300) in accordance with one of the preceding patent claims, characterized in that a receiving bore (55) of a main body of the locking device comprises an inclined entry surface (65) against which a split ring (61) is arranged to slide by entry in the receiving bore (55), whereby the splitting ring (61) is radially retracted by sliding against said entry surface (65), and whereby the splitting ring (61) is arranged to engage with a locking profile (63) in the main body (51) to the locking device. 6. High-pressure riser assembly (200, 300) in accordance with patent claim 5, characterized in that a plurality of hydraulic actuators (67) are arranged around the circumference of the main body (51) of the locking device and are arranged to push the split ring (61) in a radial direction out of said locking profile (63). 7. High-pressure riser assembly (200, 300) in accordance with one of the preceding patent claims, characterized in that when in the disconnected mode the high-pressure sleeve (203, 303) hangs freely in the air under a drill deck (201, 301).