NO334831B1 - Offshore structure and procedure for installing the structure - Google Patents

Abstract

A construction for offshore operation, which is comprised of a foundation element (1) having a base and a top. The foundation element (1) is movably supported by one or more elongated legs (4). Both the upper and lower portions of each of the legs (4) are detachably coupled to an upright system (2, 3), whereby each leg is adapted to be able to move vertically in both directions for lifting and lowering the foundation member (1). Wire deck systems (2, 3) are adapted to be biased during the lifting and lowering operation of the foundation element (1).

Description

Field of the invention

The present invention generally relates to an improved structure for offshore operation, which will be able to be adapted to be lowered and raised in relation to the seabed in a mainly stable manner.

In particular, the present invention applies to a technology for being able to lower and raise a structure, such as an offshore platform, where one will be protected against jacking legs and jacks being damaged due to the effects of heaving and sudden jolts, which will be triggered by wind at high seas and from waves.

More particularly, the present invention relates to a structure for offshore operation according to the preamble of claim 1 and a method according to the preamble of claim 6.

Technical background for the invention

Installation of structures, such as offshore platforms in offshore areas, especially for the extraction and production of oil and gas, has been known to be cumbersome, due to the constant challenges that come with the weather at sea: More concretely, being able to maintain a mainly stability of the structure and associated equipment when installing and uninstalling in high seas, be something that still needs to be solved.

A number of technologies have already been adopted for the installation of such offshore structures. Lifting of platform sections by crane vessels, followed by in situ assembly will be known. However, a sustained operation using this technology will not always be possible, as it could involve huge costs.

Attaching buoyancy blocks to the structures to float in place and install the structures by ballasting, with or without the additional use of jacking legs, would be another known technique.

The techniques that have been mentioned above have not been found to be satisfactory due to the fact that they would involve complicated machinery for installation, which would consequently entail a high cost.

Consequently, moving the structures to another installation site, after completing an operation at one site, could also have a high cost.

GB2330854A shows a technique for transporting and installing an offshore structure using a barge. It also shows the attachment of the structure to the barge using wire jack systems (English: "strand jacks"), where the wire jack systems will also serve to lower the structure to the seabed. However, in this technique, the involvement of a barge, which will constitute a main element for the transport and installation of the structure, will lead to large costs. Apart from this, it does not describe how the lifting and lowering operation of the structure should be able to be done in a stable manner, so that the structure should not be damaged due to heave from the waves.

US 2010/0135728A1 shows a technique for using jacking legs, wire jacking systems, with mats placed under the hull-shaped structure to be installed, and ballast tanks. By activating the wire jack system, the hull structure can be raised, with the mat, legs and lowering box being lowered to the seabed. The lift can be further strengthened by de-ballasting the hull and ballasting the mat. During lowering of the hull to sea level, to tow it to another location, the wire jacking system will be able to be deactivated and the mat and legs will be jacked up. This operation will be further reinforced by de-ballasting the mat and ballasting the hull.

GB 1 551 859 describes a jacking platform designed to be floated to an installation site, where the jacking legs are lowered by means of linear jacks, each having a cable extending from the upper part of the leg, through a channel and to the lower part of the leg.

The technique referred to in the preceding paragraph attempts to some extent to solve the problem of the high costs. However, it fails when it comes to learning how to ensure the old challenge of being able to maintain mainly stability when installing and uninstalling such structures when there are high seas. Furthermore, it particularly fails to show how the legs, the wire jack system and the hull should be able to withstand the effects of the waves during the lowering and lifting operations.

US 3986368 shows how to ensure stability once the structure has been installed on a jacking leg. However, it is not shown here how to ensure substantial stabilization during installation and removal of the structure when there are high seas. Furthermore, the arrangement that will be used in the load balancing system seems to be rather complicated. Rack and pinion checks will be very expensive, and they will not be able to be removed after installation to be used on another structure.

US20060062637 shows the minimization of deformation of legs, and of damage to the hull structure and jacking machinery by being able to register the extent of bending of legs, differential bending of spans and inclination of hull. Strictly speaking, however, it does not show how significant stabilization can be ensured during installation and removal of the structure when the sea is high.

Consequently, there has been a desire to achieve a structure for offshore operation, which has a simple structure, is economical and at the same time will be able to be technically efficient in order to be able to maintain significant stability when installing and uninstalling the structure when there are high seas, and will could have the possibility of being easily moved from one place to another without having to have the help of other vessels, such as vessels or barges with large cranes.

The present invention meets the above long-felt need and other associated needs.

Purpose of the invention

The primary purpose of the invention is to provide a structure for offshore operation, which has a simple structure, and which is economically and technically efficient to be able to maintain substantial stability during installation and removal of the structure when there are high seas.

It is another object of the present invention to provide a structure for offshore operation, which will be able to be operated all year round.

It is a further object of the present invention to provide a structure for offshore operation, which is adapted to ensure that the jacking legs and wire jacking systems which have been mounted thereon will not be damaged by the sudden action of a wave, during lifting- and the lowering operation.

It is another object of the present invention to be able to provide a structure for offshore operation, which will be adapted to be towed or be self-propelled to the installation site, without there being any need for any heavy crane vessel or the like.

It is a further object of the present invention to be able to provide a structure for offshore operation, which is adapted to be brought down to sea level after a towing operation to another installation site has been completed.

It is yet another purpose of the present invention to provide an offshore platform which should be able to act as an extraction and/or production facility, and which has a simple structure, and which will be economically and technically efficient to be able to maintain substantial stability by installation and uninstallation of the structure when the sea is high.

It is another object of the present invention to provide a method for installing and uninstalling a structure on an offshore site, and which should be able to maintain substantial stability when installing and uninstalling the structure in high seas.

Throughout the description, including the requirements, the words "foundation", "hull", "tower", "frame", "jacking legs", "ballast tanks",

"wire jack systems", "jack housing", "hydraulic cylinder", "platform",

"structure", "offshore operation", "hydrocarbon" are interpreted in the broadest sense of the respective terms and include all corresponding items in the art known by other terms, as will be clear to those skilled in the art. Restrictions / limitations, if there are any, and which have been shown in the description, are only an example and for understanding the present invention.

Summary of the invention

According to a first aspect of the present invention, there is provided a structure for offshore operation comprising a foundation having a plinth and a top, said foundation being movably supported by one or more elongate legs, each of the legs being connected to jacking systems which is arranged to move the legs vertically in both directions in relation to the foundation, as the legs with their base are arranged to cooperate with the seabed to lift the foundation in relation to the sea surface. The invention is characterized by the fact that each leg is connected to at least two separate jack systems, each jack system comprising at least one wire jack and at least one wire cable, that the upper part of each said leg is removably connected to an upper jack system where the at least one wire cable to the upper the jacking system extends from an upper portion of the leg to the foundation, and the lower portion of each leg is removably connected to a lower jacking system wherein the at least one wire cable of the lower jacking system extends from a lower portion of the leg to the foundation, and that the wire cables of both the upper and lower jacking systems are designed to be held in tension during the movement of the legs relative to the foundation.

According to a preferred embodiment of the first aspect of the present invention, the jack system can be adapted to be tensioned in advance during the lifting and lowering operation for the foundation.

Most preferably, the foundation is a platform that will act as a facility for hydrocarbon extraction and/or production.

According to a second aspect of the present invention, a method for installing a floating offshore structure is provided. According to the method, one or more jacking legs are attached to said structure, which will then have mounted pre-tensioned wire jack systems, which wire jack systems comprise at least one wire jack and at least one wire cable, where at least one of the wire jack systems extends between the upper part of the leg and the structure, and at least one of the wire jacking systems extends between the lower part of said jacking legs and the structure. The method then involves towing, or self-propelled propulsion, of said structure which has said jacking legs and said wire jacking systems attached thereto with fasteners, to the desired installation location, after an adjustment of the ballast tank content in the structure has been made in order to achieve the desired draft. When you reach the desired place, the sea anchors will be removed as best suits you, and you will be able to start the ballasting operation. Simultaneously with this, or immediately afterwards, the wire jacking system at both the upper and lower parts of the jacking legs will be activated to cause the legs to be slowly lowered to the seabed, while all the wire jacking systems are kept in tension, whereby the structure will gradually be raised to a appropriate height above sea level to provide an adequate air gap, and to make it ready for operation.

Preferably, the wire jack system will be deactivated and disconnected after the lifting operation has been completed, in order to be applied to another structure.

More preferably, the ballast tanks in the structure will be filled up after completing the operation with said structure, and the jacking legs will be pulled out in an upward direction relative to the seabed by means of said wire jacking system, which will now go in an opposite direction. This will facilitate the lowering of said structure on the sea and being able to move it to a second installation site, by applying the steps that have been described here previously.

In a preferred embodiment, a skirt for dampening wave impact around the circumference of the lower part of the structure could be mounted. Said skirt, which will be able to include several chambers without a bottom, which are adapted to be able to transport water by suction as the structure is lifted out of the water. This will prevent the hammering forces. The skirt will be able to be regulated so that it contains as much water or air as desired for the operation to be carried out, either by lifting the structure out of the water or by lowering it into the water.

Brief description of the drawings

After having described the most important features of the invention above, a more detailed and non-limiting description will be given of what will serve as an example in what now follows, with reference to the drawings, where: Figure 1 is an elevation from the side of a preferred embodiment of the structure according to the present invention, in a state of transport and before installation. Figures 2 to 6 illustrate the various stages that will be engaged in carrying out the installation operations for the structure illustrated in Figure 1.

Detailed description of the invention

What follows now is a preferred embodiment of the invention, which will serve as an example for the sake of understanding the present invention and which is non-limiting to the scope of the protection. It is hereby also established that the structure according to the present invention will be able to act as a foundation for offshore operations, such as the extraction and production of hydrocarbons, but which is not limited to this function. It is equally effective in achieving its goals, in all corresponding operations, as will be clear to those skilled in the art. Furthermore, hereinafter the structure will be referred to as a foundation/platform only for the sake of brevity and for a clear understanding, and not as any kind of limitation.

The accompanying figure 1 illustrates a side elevation of the platform 1 according to the present invention. At the installation site, it will play the role of a foundation structure for oil and gas extraction and/or production. It is comprised of three or more jacking legs 4 (in this example four jacking legs), a platform crane 12 which extends upwards from its flat top part V. The legs 4 extend upwards from the flat top part 1' to the platform 1 and downwards past the bottom surface of platform 1.

Within the above context, it is hereby clear that the top surface / upper part and bottom surface / lower part of the platform 1 and the legs 4 are as defined here previously and from now on, with reference to the seabed 5. The top surface is the one facing away from the seabed 5 This should be clear from figures 1 to 6.

Preferably, the platform is designed as a hull unit with its own propulsion or it is adapted to be towed by one or more auxiliary vessels.

The special features of the platform will be further understood from the accompanying figure 2. It clearly shows the jacking legs 4, on top of which will be mounted wire jack systems (strand jacks) 2, 3. Of course, the number and shape of the wire jack systems 2, 3 and the legs 4 will not be limited to the embodiment shown. the thread jack systems are represented by reference number 3 and the threads are represented by reference number 2.

Figure 2 clearly shows that each of the legs 4 is equipped with wire jacking systems 3, both attached to the upper part and the lower part. The wire jack systems 3 will cause movement of the legs 4 vertically with respect to the platform 1. How this can be achieved will be explained later. In order to maintain stability during transport or during the lifting / lowering operation, both sets of upper and lower wire jack systems will be pre-tensioned. In other words, the cables 2 for the wire jack systems will always be kept under tension.

Advantageously, there will be ballast tanks 6 at the plinth portion of the platform 1, and which extend downwards from where there is a skirt arrangement 7 which has perforations therein. The outer lower part of each leg is provided with cushions 9 which will rest on the seabed 5, below the seawater 8, and will also be able to have skirts which can penetrate into the seabed.

The platform could be removably fixed with a drilling frame (not shown).

The materials that are used for the construction of the platform, and the special features that accompany these, will be conventional and known to professionals in the field, and such materials will have no consequences for the present invention. As such, they will not be discussed further here.

How the features interact, and the advantages that will thereby be achieved, will now be explained with reference to the installation procedure, which has been described in figures 2 to 6. In all these figures, the same reference numbers will refer to the same features.

At the first stage, three or more jacking legs 4 will be attached to the platform 1. Pre-tensioned wire jacking systems 3 will be mounted on both the top and bottom surface areas of the platform 1, where the wires 2 of the jacks are suitably attached to the top or bottom, for each jacking leg respectively.

All the threads 2 in the jacks will always be kept in tension, to provide stability for the structure during transport or when raising / lowering. These will be secured in the initial stage with the platform, using suitable sea anchoring means, as will be known in and of itself. At the first stage, the legs 4 will be supported by the platform 1, in contrast to the stages that have been shown in figures 3 to 6, where the legs 4 will gradually take over the support of the platform 1.

In the next stage, since the platform 1 is designed as a hull unit, it will be towed by one or more vessels, or in a self-propelled arrangement, to the installation site. For this purpose, the ballast tanks 6 will be adjusted to bring the platform at sea level to achieve the desired draft. The ballast tanks will be filled with water or air to adjust the buoyancy, but this will have no consequences for the present invention.

When arriving at the desired installation location, the fasteners will be removed, the platform will be de-ballasted and the wire jack systems 3 will be activated to tension the wires 2 and move the legs 4 vertically downwards in relation to the hull / platform 1 and towards the seabed. This stage is shown in Figure 2.

As mentioned earlier, in order to provide stability for the whole process, the threads for the individual jacks will always be kept in tension. To bring the legs 4 down, the threads of the jacks 3, which are mounted near the top surface of the platform 1, will be pulled. As the legs 4 descend, this will generate a further tension in the threads of the jacks mounted nearby of the bottom surface of the platform 2. These threads will then be loosened somewhat to allow the legs 4 to come down, but the lower jacks 3 will always hold the lower threads 2 in a certain tension. The steps will be repeated again and again, in order to be able to lower the legs.

As the legs 4 are gradually brought down in relation to the platform 1 towards the seabed 5, the platform will gradually be lifted up.

In Figure 3, the cushions 9 of the legs 4 will have touched the seabed 5 by a gradual lowering of the legs with continuous activation of the wire jack systems 2, 3, as well as by increased ballast water / suction.

In Figure 4, the legs 4 will have further penetrated the seabed 5, and will lift the platform 1 further. Figure 5 indicates the next stage when the legs 4 have further penetrated the seabed 5, and will lift the platform 1 further and above the water level.

In Figure 6, the platform has been raised to a height above sea level, where there is a suitable air gap. This will be followed by a final pre-loading by ballasting or diagonal jacking and finally a jacking to the position where it will be ready to be put into operation.

It will be sufficiently clear from all figures 2 to 6 that the wire jacking systems 2, 3 will be activated at both the upper and lower parts of the jacking legs 4, during lifting / lowering or transport, whereby the wires will always be in tension. Thus, during the lifting operation, both the upper wire jack systems and the lower wire jack systems will be kept in tension. This will effectively smooth out the overloads on the legs 4 and on the platform 1, when the platform 1 is exposed to heaving movements from sea waves and wind. This aspect also works effectively at the same time as platform 1 is lowered.

To be precise, if the platform were to be exposed to waves, which is likely to happen during high seas, the wire jack systems could be damaged by excessive forces, should they be subjected to a sudden impact. Damage to parts of the structure may also occur. With a stretch in the threads at all times, the threads will not get any slack due to heaving, and you will be able to avoid sudden jerks in the platform 1 and the legs 4.

It should be understood that, in all the stages of installation of the platform 1, which have been shown in Figures 2 to 6, lifting of the platform will be caused by the legs 4 activated by the wire jack systems 2, 3, as well as by the de-ballast action for the platform. These two actions will either take place simultaneously, or the wire jack systems will be activated immediately after initiation of the de-ballast action.

Another advantageous feature, which is best shown in figure 2, is a skirt element 7 which extends downwards from the bottom of the ballast tanks 6. The skirt element 7 is perforated. It will prevent the waves from entering under platform 1 and will hammer against the underside. It will act like a pillow. Thus, a sufficient air gap will be formed before the wave enters under the platform 1. Thus, the perforated skirt element 7, which extends downwards under the ballast tanks 6, will quickly increase the air gap, which will allow trapped air or water, depending on what may be, must be able to be released slowly while raising or lowering the platform.

As soon as the platform has been installed, in order to have a safe air gap above sea level and a sufficient pressure against the seabed from the legs, as shown in figure 6, the wire jack systems 2, 3 will be deactivated and disconnected in order to be put into use on another platform .

As the platform 1 is brought down, so that it reaches down to sea level, the wire jack systems 2, 3 will now operate in a manner opposite to that which has been described with reference to Figures 2 to 6.

As soon as the operation of the platform 1 has been finished after a period of time, the ballast tanks 6 on the platform 1 will be filled up, and the wire jacking systems 2, 3 will be made ready to be able to go in the opposite direction so that the jacking legs 4 are again pulled vertically upwards in relation to the platform. This action will facilitate being able to lower platform 1 into the sea to a suitable level to be able to have a desirable draft, so that it will be able to be towed or be self-propelled to another installation site. Alternatively, it will be able to support a production facility at the installation site.

The function of the wire jack systems 2, 3 will now be explained in more detail. As mentioned earlier, the wire jacks 2, 3 are activated for locking and for moving the legs 4 vertically downwards in relation to the hull / platform 1 towards the seabed. Wire jacking systems will be generally well known in the art, and will not be explained in more detail here. However, a detailed description of wire jacking systems can be found in a Dorman Long Technology brochure. Wire jack systems have also previously been used to lift heavy offshore constructions, as for example shown in GB 2462565.

In the non-limiting embodiment to be illustrated here, and which will serve as an example, the jack body 3 will be attached to the platform 1, and the ends of the cables passing through the jacks will be attached to the top or bottom ends of the legs 4.

Now, in order to understand the operation of the wire jacks, the top jacks must be considered first. It should be mentioned that all jacks on the top row of jacks will not operate at the same time, because otherwise the basic idea of always keeping the threads taut would be lost. As soon as the unit contracts, it will pull the thread downwards, and at the same time leg 4 will follow, since the end of thread 2 will be attached to it.

Now we will look at the bottom jacks. When the locked leg 4 is pulled downwards, the threads of the bottom jacks are held in further tension. Thus, a few of the clamps that are in the row of bottom jacks will be loosened, whereupon the threads for these will then move to a certain extent to loosen the tension. These will again be clamped and a further set will be loosened in a similar way. As a result, a certain amount of tension will always be maintained in the threads, which will thus provide additional stability for the platform and legs against heaving movements.

When lowering the platform, the wire jack systems will work in the opposite way to what has been explained above. The lowering can also be reinforced by ballasting the platform, as has been explained previously.

The arrangement of wire jack systems 2, 3, according to the present invention, will thus facilitate the vertical lowering of (and in the same way a raising of) the legs 4 in relation to the platform 1 and finally the lowering of the legs 4 down to the seabed 5 , so that the platform 1 is lifted up to a suitable height above the water level, from where it will be made ready for operation.

The present invention also embraces a method for being able to produce hydrocarbons by drilling a well using the platform, according to the present invention.

It will be understood from the exhaustive explanation above, and also from the attached requirements, that the platform has a simple structure, that it is economically and technically efficient to be able to maintain a significant stability when installing and uninstalling the structure when there is a high sea. It will be able to be kept in operation throughout the year. Furthermore, the present invention will ensure that the jacking legs, and the wire jacking systems that have been mounted on them, will not be damaged by any sudden impact from a wave during the lifting and lowering operation.

In addition, it will be able to be adapted to be towed or be self-propelled to the installation site, without the need for any heavy crane vessels and the like. Furthermore, it will be able to be brought down to sea level after the operation of towing to a second installation site has been completed.

The present invention has been described with reference to a preferred embodiment and a few drawings for the sake of understanding only, and it should be clear to those skilled in the art that the present invention will be capable of including all legitimate modifications within the scope of what has been described herein previously and which are defined in the attached requirements.

Claims (9)

1. Structure for offshore operation, comprising a foundation (1) having a plinth and a top, said foundation (1) being movably supported by one or more elongate legs (4), each of the legs (4) being connected to jacking systems which are arranged to move the legs (4) vertically in both directions in relation to the foundation (1), the legs (4) with their base being arranged to cooperate with the seabed to lift the foundation in relation to the sea surface, characterized in that each leg is connected with at least two separate jack systems (2, 3), each jack system (2, 3) comprising at least one wire jack and at least one wire cable, that the upper part of each said leg (4) is removably connected to an upper jack system (2, 3 ) where the at least one wire cable of the upper jacking system extends from an upper part of the leg (4) to the foundation (1), and the lower part of each leg (4) is removably connected to a lower jacking system (2, 3) where the at least one wire cable to the lower jack system (2, 3) extends e.g ra a lower part of the leg (4) to the foundation (1), and that the wire cables of both the upper and the lower jack systems (2, 3) are arranged to be kept in tension during the movement of the legs (4) in relation to the foundation ( 1). 2. Structure according to claim 1, characterized in that said plinth of said foundation (1) is equipped with one or more ballast tanks (6) for ballasting and de-ballasting said foundation (1) during the lowering and lifting operations, respectively. 3. Structure according to claim 2, characterized in that said foundation (1) is equipped with a perforated skirt element (7) which extends downwards under said ballast tanks (6) for rapid increase of an air gap between the foundation and the sea surface. 4. Structure according to any one of claims 1 to 3, characterized in that said foundation (1) is a platform adapted to serve as a facility for hydrocarbon extraction and/or production. 5. Structure according to claim 4, characterized in that said platform (1) is designed as a hull unit which is adapted to be floated to an installation site in deep water. 6. Procedure for the installation of a floating offshore structure, characterized by the following steps: a) attaching one or more jacking legs (4) to said structure, which legs have removable pre-tensioned wire jacking systems (2, 3), which wire jacking systems comprise at least one wire jack and at least one wire cable, where at least one of the wire jacking systems extends between the upper part of the leg and the structure (1), and at least one of the wire jacking systems extends between the lower part of said jacking leg (4) and the structure (1), b) to tow or by own operation bring said structure, which has said jacking legs and said wire jacking systems (2, 3) attached to it, to the desired installation location after having adjusted the contents of ballast tanks in the structure in order to thus be able to obtain a desired draft, c) initiate de-ballasting of the structure , d) activate the wire jacking systems (2, 3) at both the upper part and the lower part of the jacking legs (4) either simultaneously with, before or after ini tiering of said ballasting to cause said leg (4) to be gradually lowered to the seabed, whereby said structure (1) will be raised to a suitable height above sea level to provide a suitable air gap, to make it ready for operation, all the wire jack systems during the entire immersion of the legs and subsequent raising of the structure (1) are kept in tension. 7. Method according to claim 6, characterized by deactivation and disconnection of said wire jacking systems (2, 3) in order to apply these to another structure after the installation has been completed. 8. Method according to claim 7, characterized in that after the structure has completed its service at the installation site, the ballast tanks (6) in said structure (2) are filled up, then the jacking legs (4) are pulled up from the seabed using said wire jacking systems (2, 3 ) which now goes in the opposite direction, thereby lowering said structure to the sea surface and using steps (a) and (b) to move said structure (1) to a second installation location. 9. Method according to any one of claims 6 to 8, characterized by using said structure (1), after completing an installation, to support a production facility and/or facilitate hydrocarbon recovery.