NO319277B1 - Offshore production piping system, as well as a method for its laying out - Google Patents

Description

the present invention relates to a production pipe system at sea where the production pipes run between at least one valve tree on the seabed and a vessel floating on the surface, which vessel is limited in movement in all directions in the horizontal plane within a defined area, the production pipes are divided into two sections; a section that lies on the seabed and originates in a valve tree and a section that is "floating" in the water and ends up in the vessel.

The invention also relates to a method for laying a production pipe between a valve tree on the seabed and a surface vessel which, after the pipe laying, is restricted in all directions in the horizontal plane, which production pipe is divided into two sections; a bottom section and a floating section.

The present production pipe system has been developed for floating production units and forms a connection between a valve tree on the seabed and a floating vessel. The use of floating production units is constantly increasing in scope due to their cost-effectiveness, especially in deeper waters. The floating production units increasingly have capacity for both drilling and production. This means that as soon as a well is drilled and completed for production, production can take place through a first riser while drilling well no. 2, etc. Thus, an early start of production is achieved, and the capacity increases as new wells are drilled.

For floating production solutions, special riser designs are used so that the floating vessel can move to all well locations for normal operations and to move to the side during a possible emergency. The riser systems that are usually used are flexible risers made of steel-reinforced thermoplastic pipes. These risers have a limited lifespan and the cost is very high. Especially for oil fields with high temperature and high pressure, it is difficult to use flexible risers. The use of dynamic metal risers has therefore been taken up for consideration for the next generations of offshore oil fields.

For solutions using flexible risers to the valve trees below, a yielding waveform or a steep S design would usually be used. The steep S has a riser foundation with a horizontal connection to the static connecting line and a vertical connection to the riser. The compliant wave design can be installed in one length using flanges. The riser foundation for this solution is a block weight anchored to a 90' bend. The disadvantages of the steep S design are extra installation time to make two pipeline retracts, extra equipment on the riser foundation and finally this that the vertical riser has a fixed support. This latter means that high bending moments must be taken close to the vertical connection point.

The use of rigid metal risers not laid in corrugated form instead of flexible risers raises several new problems. Such problems are: (1) Installation of risers. The installation can be carried out with a vessel using drums or a carousel, where the riser can be welded in place or it can be towed out in a continuous length. For these solutions, the 90<*> bend creates problems that lead to a need for an underwater coupling. (2) Achieve the necessary flexibility for the vessel's movement.

It becomes much more important to have a good riser design because the bending radius is much more critical for metal risers than flexible risers. Risers with yielding waveform are best suited for metal risers, as the 90° bend is a "hinge point" and the bending moments are absorbed by a large proportion of the horizontal connecting wire during rig movement.

When it comes to the installation of risers, there are several important factors that must be taken into account with regard to the choice of installation method. Firstly, independence between the vessels during installation is important. Furthermore, it is important to easily replace or retrieve individual components, such as the valve tree, the riser or the connection line, while adjacent wells are still producing. Furthermore, the layout of the seabed is important and you must have an installation method that allows the valve trees and the risers/connecting lines to be placed close to each other.

Here you also have to take into account the pull-in method you will use for the connection on the seabed.

As can be seen from this description, it is important that the system provides the opportunity to replace individual modules or pipe runs without disturbing the others. For retrieving the valve tree, it is essential that the riser creates tension backwards in the connecting cable and helps when extracting it from the valve tree.

In accordance with the present invention, a production pipe system of the type mentioned at the outset is provided, which is characterized by the fact that the bottom section and the floating section are connected in one place and at some distance from the seabed, that either the bottom section or the floating section near the connection point describes a knee, and that the floating section is resiliently anchored to the seabed 1 near the connection point As the pipes are thus held under tension.

The point of attack for the pipe anchorage on the pipe can advantageously be some distance from the said pipe section, for example 1 to 20 m.

To prevent the connecting cable from getting stuck in the seabed mud, it is suggested to have a protective sliding sleeve made of a plastic material wrapped around the pipe when the connecting cable is laid out. The sliding casing ensures improved thermal insulation, provides mechanical protection and maintains low friction between the connecting cable and the seabed. Furthermore, it will be able to absorb any torsional moments over the entire length of the blinding line. The pipes can advantageously be non-flexible and consist of titanium, steel or stainless steel (Duplex).

In accordance with the present invention, a method of the type mentioned at the outset has also been provided, which is characterized by the fact that the bottom section is laid out on the seabed mainly in a straight line and is attached to the valve tree at one end, that the floating section is laid out in chain-line form and floats with the help of floating bodies down in the water and is attached at one end to the vessel and at its other end the yielding is attached to a bottom anchorage, and with the pipe end somewhat at a distance from the bottom, and that the pipe ends are pulled towards each other and connected at said distance from the bottom, as the yielding of the bottom anchoring and the rigid the pipe's elasticity is utilized to enable this without introducing point loads in the pipes, as well as keeping them 1 stretch. Appropriately, the pipe ends are pulled towards each other using a pulling tool that is put in place with an ROV.

The pull-in tool can be connected to the end of the floating section, after which a line is placed and attached using the ROV to the end of the bottom section before the pull-in tool is put into operation and pulls the pipes towards each other and makes the connection. As a practical measure, the floating section can advantageously be laid out before the bottom section.

The method can be used for the replacement of only the bottom section in a production piping system, where the pipes are disconnected and the end of the bottom section is dropped in a controlled manner towards the seabed, after which the end of the bottom section is dropped in a controlled manner towards the seabed, after which the other end of the bottom section is detached from the valve tree and removed and a replacement bottom section is installed according to the previously stated procedure .

A method is also provided for replacing only the floating section in a production pipe system, where the pipe ends are disconnected and the end of the bottom section is dropped in a controlled manner towards the seabed, after which the other end of the floating section is detached from the vessel and removed and a replacement floating section is installed according to the previously stated method.

Other and further purposes, features and advantages will be apparent from the following description of currently preferred embodiments of the invention, which is given for description purposes, without thereby being limiting, and given in connection with the attached drawings where: Fig. 1 shows the production pipe system according to the invention during deployment between a valve tree on the seabed and a floating vessel, Fig. IA shows the actual connection point between the bottom tube section and the float tube section according to fig. 1 in more detail,

fig. 2 shows the production piping system fully connected,

fig. 2A shows in more detail the knee part of the hovering section

at the connection point.

Fig. 1 shows a floating drilling and production vessel 8 which floats on the water surface 12 above a production valve tree 5 which is lowered into the seabed 11. Between the valve tree 5 and the vessel 8 runs a production pipe system consisting of a bottom pipe section 1, often called a connecting line, and a floating pipe section 2, often called the riser, which pipe sections are interconnected 4 1 an area that lies just above the seabed 11.

The bottom section 1 can advantageously be laid out mainly in a straight line from the valve tree 5, in contrast to the previously commonly used S-shape. The floating pipe section 2 floats 1 the water and describes an approximate sinusoid, or overturned S-shape between the seabed 11 and the floating vessel 8. The lower end of the floating section 2 is connected to the bottom section 1 by means of a retracting tool 6 and an ROV. The ROV is controlled from a surface vessel 10 which is connected to the ROV via a cable 15.

As can be seen from fig. IA, the pipe ends are pulled together using the retracting tool 6, which is described in more detail in Norwegian patent application NO-920518. A further discussion of this tool will not be described here, apart from its ability to pull in a pipe cable towards the tool 6 and connect two adjacent pipe ends. The tool 6 is transported and maneuvered into place using a remote-controlled underwater vehicle (ROV) which is of a commonly known type, and is not described in more detail here.

As is further evident from Fig. IA, the floating section 2 describes at its lower end a knee 3 which can suitably form approximately 90*. The end of the floating section 2 is anchored to the bottom 11 with the help of a lump weight 7 and an anchoring line 13 which has an attachment point 9 to the floating section 2. This type of anchoring gives the end portion 4 of the floating section 2 freedom of movement in a mainly horizontal direction. Furthermore, at a certain location, it will help to orient the 2 end flanges of the floating section to be flush with or point towards the touching part that is drawn in. This means that the starting point 1 points in the direction of the valve tree 5. This is to be understood as meaning that the knee 3 together with the anchoring 7,9,13 are both orienting and give the pipe end 4 freedom of movement.

Figure 2 shows, like fig. 1 a production pipe system between a valve tree 5 on the seabed and a production vessel 8 on the sea surface. The figure schematically shows two different states;

one for a floating section 2 that transports gas and a second condition where the floating section 2 is filled with water or oil. In such a situation, the floating section can advantageously be equipped with floating bodies 2' to contribute to increased buoyancy in the floating section 2, at least over parts of the floating tube section.

The connection point 4 is shown in more detail in fig. 2A. That is it is the floating section 2 end that is shown, and its orientation. The figure shows a different embodiment of the anchoring than that shown in fig. IA. As before, the anchoring consists of a lump weight 7' and an anchoring line 13' and an attack point 9'. However, the point of attack 9' has been moved to a distance up along the vertical part of the floating section 2 and the distance from the pipe knee 3 to the point of attack 9' can vary from 1 to 20 metres, for example. This helps to further increase the flexibility 1 of the pipe section 2 end 4. It should also be mentioned that this design of the floating section and the anchoring helps to keep the bottom section 1 under tension. This stretch is also maintained if the production platform 8 moves on the sea surface 12 in any direction within a defined, delimited area.

As mentioned, the proposed procedure sequence is based on the use of a retracting system with a retracting tool 6 that is put in place with an ROV. The retracting tool 6 and ROV are used both for retracting the bottom section 1 towards the valve tree 5 and the contraction of the opposite end of the bottom section 1 and the lower end of the floating section 2. The connecting lines 1 can be equipped with protective caps to prevent the ingress of seawater. The lids can have ROV-operated filling ports that enable filling with seawater before retraction. Rotational orientation of the valve tree is required within an accuracy of approximately ±1<*.> Different solutions are possible, such as a position indicator in relation to the connecting line's 1 downdraft valve. Retraction is carried out using the ROV operated retraction system against the valve tree. It is important that the riser has sufficient flexibility to allow the retraction at the valve tree end to be approximately 1 m. The retraction can be carried out using the ROV-operated retraction system between the horizontal bottom section and the floating section. The bottom section is lifted up while the floating section end is forced horizontally until the connection parts are brought together and connection with a clamp connection is made. Execution of water and internal pressure testing is carried out. Production can begin.

The system is dependent on several functional requirements for the riser system. In the event of loosening of the valve stem, the floating section must take up the necessary setback of approximately 450 mm. This backlash at the valve tree should not cause pressure in the bottom pipeline 1. The riser pipe stone should create positive tension in the static lines also during loosening. In case of replacement of a floating section, the connection between the bottom section and the floating section must be able to be detached. This is possible without loosening between the bottom section 1 and the valve tree. In the event that the bottom section is to be replaced, the two couplings must be released without picking up or damaging the floating section.

Claims (10)

1. Production pipe system at sea where the production pipes run between at least one valve tree (5) on the seabed (11) and a vessel (8) floating on the surface (12) 1 the area above the valve tree or trees (5), which vessel (8) is limited in mobility in all directions in the horizontal plane Within a defined area, the production pipes are divided into two sections; a section (1) which lies on the seabed and originates in a valve tree (5) and a section (2) which is "floating" in the water and ends up in the vessel (8), characterized in that the bottom section (1) and the floating section ( 2) are non-flexible and connected in only one place (4) and at some distance from the seabed, that either the bottom section (1) or the floating section (2) near the connection point (4) describes a knee (3), and that the floating section (2) ) is compliantly anchored to the seabed (11) in the vicinity of the connection point (4) and in the extension of the bottom section (1), as the pipes are thus kept under continuous tensile load. 2. Production pipe system according to claim 1, characterized in that the point of attack (9) for the pipe anchorage on the pipe is at some distance, such as 1-20 m, from said pipe knee (3) (fig. 2A). 3. Production pipe system according to claim 1 or 2, characterized by the fact that the bottom section (-1) is laid in a casing with the intention of enabling some axial movement of the bottom section (1) as well as absorbing any torsional moments over the entire length of the bottom section. 4. Production pipe system according to claim 1, 2 or 3, characterized in that the pipes consist of titanium, steel or stainless steel (Duplex). 5. Procedure for laying a production pipe between a valve tree (5) on the seabed and a surface-floating vessel (8) which, after the pipe laying, is restricted in all directions in the horizontal plane, which production pipe is divided into two sections; a bottom section (1) and a floating section (2), characterized in that the bottom section (1) is laid out on the seabed mainly in a straight line and is attached to the valve tree (5) at one end, that the floating section (2) is laid out in chain-line form and floating by means of floating bodies down in the water and are attached at one end to the vessel (8) and at the other end the yielding is attached to a bottom anchorage (7), and with the pipe end somewhat at a distance from the bottom, and that the pipe ends are pulled towards each other and connected 1 the said distance from the bottom, as the compliance of the bottom anchoring and the elasticity of the rigid pipes are utilized to enable this without introducing point loads in the pipes, as well as keeping them in tension. 6. Procedure According to claim 5, characterized in that the pipe ends are pulled towards each other using a retracting tool which is placed with an ROV (6). 7. Method according to claim 6, characterized in that the retracting tool is connected to the end of the floating section after which a line is placed and fixed with the help of ROV (6) to the end of the bottom section before the retracting tool is put into operation and pulls the pipe ends towards each other and makes the connection. 8. Procedure According to claim 5, characterized in that the floating section (2) is laid out before the bottom section (1). 9. Procedure for replacing the bottom section of a production piping system According to claims 1-4, characterized in that the pipe ends are disconnected from each other and the end of the bottom section is dropped in a controlled manner towards the seabed, after which the other end of the bottom section is detached from the valve tree and removed and a replacement bottom section is installed according to the method according to one of claims 5- 7. 10. Procedure for replacing the floating section of a production pipe system according to claims 1-4, characterized in that the pipe ends are disconnected and the end of the bottom section is dropped in a controlled manner towards the seabed, after which the other end of the floating section is detached from the vessel and removed and a replacement floating section is installed according to the method according to one of claims 5- 7.