NO335586B1 - Suction anchors made of fiber-reinforced plastic - Google Patents

Abstract

The present invention relates to a suction anchor comprising a cylindrical main element (1), closed at one end with a top element (3) and open at the opposite end of the cylindrical element, the open end of the cylindrical main element (1) forming an edge (2) to be driven into the seabed. According to the invention, at least part of the main cylindrical element (1) is formed of fiber-reinforced plastic.

Description

The present invention relates to a suction anchor and a method for producing such anchors.

Suction anchors are largely used for anchoring offshore installations, whether the installations are floating on the surface or underwater installations. Examples of known suction anchors are for example described in US 2005/0201835, US 6,360,682 and US 4,270,480.

US 6,659,182 relates to a method and device for installing casing for offshore oil wells. A retrievable suction device drives a string of casing into the seabed using hydrostatic pressure. A seal is formed around the casing and a pump is then used to lower the pressure in the suction system.

WO 01/71105 relates to a foundation for an offshore construction and a method for establishing the foundation on the seabed. The foundation is designed with a mainly bell-shaped base in steel with a central cavity and peripheral pressure-tight chambers. After the foundation has been arranged on the seabed, a negative pressure is created in the pressure-tight chambers in order to drive the foundation down into the seabed.

US 6,321,844 relates to a method for transporting petroleum products from a seabed and to a floating surface structure, where hybrid risers are used. A lower end of each hybrid riser is connected to a suction or weight anchor.

A suction anchor is held on the seabed by the frictional forces between the wall of the suction anchor. Due to common practice in the field, suction anchors are made of a metal. As a result, when large size suction anchors are required, the suction anchors will tend to have a high weight. A large metal suction anchor can be made from two cylindrical parts with different wall thicknesses that are welded together.

Based on what has been mentioned above, a need has arisen for an alternative suction anchor. This purpose is met with a suction anchor as defined in the attached requirements.

The present invention relates to a suction anchor comprising a cylindrical main element, which is closed at one end with a top element and which is open at the opposite end of the cylindrical element. The open end of the cylindrical main element forms an edge to be driven into a seabed. The cylindrical member has a longitudinal axis at the center of the cylinder which extends from the top member to the open end. According to the invention, at least part of the main element is formed of fiber-reinforced plastic (FRP). This means that one element can be made from FRP and another element from another material, part of an element can be made from FRP and the other part of the element can be made from another material, or all the elements can be made from FRP. The elements can also be made from different types of FRP, where the different types of FRP will have different properties. The other materials can consist of a composite material or a metal.

The open end of the main cylindrical member is adapted to be inserted into the seabed, thereby forming a chamber in the main cylindrical member, the top member and the seabed. The suction armature will be equipped with means to apply a suction to this chamber. There can also be a hatch in the top element to facilitate the movements of the suction anchor through the bodies of water before it is installed.

By manufacturing at least part or all of the main cylindrical element from FRP, the weight of the suction anchor is reduced. When the elements produced from FRP are shaped, there is a greater degree of reproducibility, as the elements are produced by using a mold, where the shape of the mold can be designed to the exact desired shape of the FRP element. In this way, elements made of FRP can be shaped almost or completely circular due to the shape of the mould. There is, by choosing the elements almost completely circular, a reduced risk of collapse of the suction armature, as large cylindrical elements made of FRP are, due to its manufacturing process, less prone to out-of-roundness compared to similarly large cylinders made of metal. The weight issue of a lighter anchor with at least one part made with FRP is particularly important, as a large diameter metal suction anchor must be made with an increased amount of material to reduce the risk of collapse. Another feature of an element made from FRP is that the fibers in the FPR can be wound in the desired directions relative to the element, thereby providing an element that is optimized in relation to load and weight. An element made of FRP is also easy to adapt to the desired shape and the desired wall thickness for the various sections of the element. The element produced from FRP with a varying wall thickness can also be produced with a continuous transition between different wall thicknesses, and thereby without a gradual change in wall thickness.

A reduced weight also reduces the weight to be lifted when the suction anchor is installed underwater, or when an underwater structure is installed when the suction anchor forms part of a larger underwater structure. In the latter case, the suction anchor will act as anchoring and foundation elements for the underwater structure. For underwater installations, there is less need for large anchors, as the installations are normally positioned under a wave zone. However, there is a need to reduce the total weight of the installation, and a reduction in the weight of, for example, four suction anchors placed under four legs of the installation would be beneficial.

According to one aspect of the invention, at least one section of the main cylindrical element can be designed as a corrugated section. It is possible, when the main cylindrical member is made of FRP, to have at least one section made with a shape different from the rest of the main cylindrical member.

One possibility is to have this section corrugated. The length of the corrugations can have an orientation essentially parallel to the longitudinal axis of the main cylindrical element. The section will then be formed so that a cross-section of the main cylindrical element will show the corrugations. The shape of the corrections can be rounded corrugations or more angled corrugations. The corrugations may be uniformly distributed around a circumference, or they may be grouped and they may vary around the circumference. The section with the corrugations preferably extends around the circumference of the cylindrical main element. The section with the corrugation is also preferably a section of the main cylindrical element to be inserted into the seabed. By having the section to be inserted into the seabed at least partially corrugated, an increased contact area between the wall of the suction anchor and the seabed will be achieved compared to a smooth wall with the same main diameter. An increased area will give increased frictional forces. This means that the same amount of frictional forces is achieved with a reduced diameter compared to a smooth cylindrical wall.

In accordance with an embodiment of the invention, the end part of the suction anchor can have a shape which reduces the frictional forces between this part of the suction anchor and the ground to a minimum, in order to facilitate the initial penetration of the end part into the ground. Sufficient initial penetration is required for the suction system to be effective. In one aspect of this embodiment, the end portion may be formed with a circular (non-corrugated) cross-section and a smooth cylindrical wall portion. To ensure a permanent installation of the suction anchor in the bottom of the seabed, the part adjacent to the penetrating end part of the suction anchor can be designed corrugated to provide a friction zone between the suction anchor and the bottom. As a person skilled in the art will understand, this adjacent part can also be designed differently, to ensure sufficient frictional forces between the suction anchor and the ground in the seabed.

In accordance with one aspect, an end section of the main cylindrical member, comprising the edge of the main cylindrical body, may be made of another material. A main cylindrical member made of FRP at the edge of the member, which is to be inserted into the seabed, may need to be reinforced to prevent delamination of the FRP material, in the event that the edge hits a rock or similar hard part of the seabed. One possibility is, as stated, to produce the end section of the main element from another material, such as another plastic or a metal or other kind of composite. The material that forms the end section of the cylindrical main element can exhibit properties that increase the possibility of driving the suction anchor into the seabed without the edge being destroyed unnecessarily, thereby facilitating the insertion of the edge of the suction anchor into the seabed. The end member may be provided by a material that has a high resistance to permanent deformation, hence a material that has sufficient hardness to resist destruction during insertion.

According to another aspect, the edge of the main cylindrical element can at least over a part be formed of a different material than the rest of the edge. A cross section of the edge will then comprise two different materials. For example, a metal ring may be placed in a recess cut in the edge of the cylindrical main element. This ring can be an outer ring, an inner ring or can be placed on the edge.

By having part of the edge of the end section formed from another material, one is not limited to the properties of the FRP which at least forms part of the rest of the main cylindrical element in the piece of suction anchor to be driven into the seabed. By having such a limited part of the suction anchor made of metal, for example, the weight of the suction anchor is not increased to a large extent, but it is ensured that the edge will not deform and make the insertion of the suction anchor in the seabed unnecessarily difficult.

According to another aspect, the top element and the main element may be formed as a unit of fibre-reinforced plastic. By forming the top element and the main element as a unit, one can also form the transition between the main body and the top element as a rounded transition. Such a rounded transition can be advantageous when the suction armature handles greater pressure.

In one aspect, the parts of the suction anchor made up of FRP can be produced by assembly, for example by gluing, where the rings of FRP together form the different FRP parts of the suction anchor.

According to another aspect, the main element can be formed with at least a recess in an outer surface and/or an inner surface"-. Such a recess can be used

to place a fastening element for a fastening element to fasten, for example, an anchor chain. It can be used to connect the top element to the main element, or it can be used to connect an end section to the main element or place a ring of a harder material at the edge of the main element.

According to another aspect, the main element can be produced with a varying wall thickness. This variation can occur along a longitudinal axis of the cylindrical shape. There is also the possibility of having an increased wall thickness around the perimeter. This variation of wall thickness can be used to adapt the suction anchor for the pressures at different sections of the anchor. The part of the wall that is to be inserted into the seabed will experience different pressures than the part of the wall that is exposed to the water and the inner suction chamber. The varying wall thickness can be used to reinforce the wall at given positions. Since at least the main cylindrical element is made of FRP and the method of making elements with FRP is to wrap the elements into the desired shape; the wrapping process can be adapted to provide the desired finished element required. As an alternative to the winding described here, the shape can be produced by casting or by other methods which are suitable for the production of specific shapes. The fiber in the FRP can also be wound in the direction and quantity that is necessary to handle different forces acting on the suction anchor.

According to the invention, a suction anchor can be used as an independent suction anchor for anchoring, for example, floating vessels. Larger suction anchors according to the invention will have a greater degree of security against collapsing than correspondingly large suction anchors made of metal. The inventive suction anchor will also be lighter than a corresponding metal suction anchor of the same diameter. One can also by producing an anchor partly from FRP with several elements of metal still achieve an anchor that has substantial weight if that is desired, but again achieve less risk of collapse with the increased safety of a circular form of FRP' a part of the main body.

According to the invention, the suction anchor as described above can also be used as an integral part of an underwater structure for anchoring the structure and forming a foundation for the structure. This will reduce the total weight of the underwater structure when it is to be installed.

The present invention will now be explained in greater detail with an embodiment with reference to the accompanying drawings, where;

Figure 1 shows a typical suction anchor according to the invention.

As shown in Figure 1, a suction anchor according to the invention comprises a cylindrical main element 1. This cylindrical main element 1 is closed at one end with a top element 3 and open at the opposite end. The main cylindrical member 1 has a longitudinal axis extending from the top member 3 to the open end. At the open end, the cylindrical main element 1 is produced with an edge 2. It is the edge 2 that is inserted or driven into the bottom of the seabed, in order to place a part of the main cylindrical element in the bottom of the seabed. This part of the cylindrical main element 1 will then experience frictional forces on both sides of the wall of the cylindrical main element 1. The rest of the suction anchor, arranged above the seabed, will experience suction forces when this is applied to the suction anchor. In this example, the edge 2 is shown to be shaped by a ring, incorporated in the cylindrical main element 1.1 the top element 3, a hatch 4 is formed which can be opened to facilitate transport through the bodies of water. Connection points 5 are also arranged for suction equipment or to fill a material in the space formed by the inner walls of the cylindrical main body 1, the top element 3 and the seabed. This may be the case when the suction anchor is used as a foundation under an underwater structure. In the embodiment shown, the cylindrical main element 1 is produced with a peripheral outer recess, in which a fastening element 7 is placed, for example a metal ring, which forms a lifting ear support, for attaching a fastening element, in the shown embodiment arranged as a lifting ear 6. An anchor chain (not shown) can be attached to the lifting eye 6.

Figure 2 shows an underwater structure, with a suction anchor according to the invention placed under each of the four legs of the underwater structure.

Figures 3a and 3b show a cross-section along the longitudinal axis of the main cylindrical element 1. In figure 3a, the wall is shown with an inner recess 10 and in figure 3b the wall is shown with an outer recess 9.

Figure 4 shows a partial cross-section along the longitudinal axis of an end section of the main cylindrical body 1.1 this embodiment, the part la of the main cylindrical member made of FRP is connected to a part 1b forming the edge 2 of the open end, which is made of a different material, for example metal. The conical connection surface is made uneven to increase the adhesive anchorage between the two different materials.

Figures 5a and 5b show different embodiments of the cross-section given in Figure 4. In Figure 5a, a part 1b of another material, which forms the edge 2, is designed with an L-shaped cross-section and is connected to the part 1b made of FRP without a bolted connection, for example by using glue.

Figure 6 shows an embodiment where the cylindrical main element 1 is produced in one piece with the top element 3, and produced from FRP. An outer recess 9 is also produced in the cylindrical main element 1. The transition between the cylindrical main body 1 and the top element 3 is also produced rounded.

Figure 7a shows another possibility for connecting the top element 3 to the cylindrical main element 1. The cylindrical main element is designed with an inward facing flange 12 at the end, and the top element 3 is connected to a surface of the flange 12.

Figure 7b shows an open end section of the cylindrical main element 1. On the edge 2 of the cylindrical main element 1, an outer recess 9 has been produced, in which an end ring lc of a different material has been placed, in order to increase the strength of the edge 2.

Figures 8a and 8b show a partial cross-section of a wall of the main cylindrical element 1, which in figure 8a is uniformly reduced in wall thickness and in figure 8b is designed with a section 1d with increased wall thickness.

In figure 9 are the principles of how a section of the cylindrical main element 1 can be designed with corrugations, and where the length of the corrugations are mainly parallel to a longitudinal axis of the cylindrical main element 1. As shown, the corrugations will be formed alternately around a circumference forming the main diameter of the main cylindrical member 1. The corrugations may be curved or they may be shaped with substantially flat surfaces angled relative to each other lf.

The invention has now been explained with embodiments and with reference to the attached drawings. A person skilled in the art will, however, understand that changes and modifications can be made to the explained embodiments which are within the scope of the invention as defined in the claims.

Claims (9)

1. A suction anchor comprising a cylindrical main element (1), closed at one end with a top element (3) and open at the opposite end of the cylindrical main element, where the open end of the cylindrical main element (1) forms an edge (2 ) which is to be driven down into a seabed, characterized in that the cylindrical main element (1) is made of fibre-reinforced plastic, where at least part of the cylindrical main element (1) is made of a material other than fibre-reinforced plastic. 2. Suction anchor according to claim 1, characterized in that at least one section of the cylindrical main element (1) is formed with corrugations. 3. Suction anchor according to claim 1 or 2, characterized in that the edge (2) is made of a material other than fibre-reinforced plastic. 4. Suction anchor according to claim 3, characterized in that the edge (2) is made of metal. 5. Suction anchor according to claim 1, characterized in that at least part of the cylindrical main element (1) is made of metal. 6. Suction anchor according to one of the preceding claims, characterized in that the top element (3) and the cylindrical main element (1) are formed as a unit of fibre-reinforced plastic. 7. Suction anchor according to one of the preceding claims, characterized in that the cylindrical main element (1) is formed with at least one recess (8, 9) in an outer surface and/or an inner surface. 8. Suction anchor according to one of the preceding claims, characterized in that the cylindrical main element (1) is formed with a varying wall thickness along a longitudinal axis of the cylindrical shape. 9. Underwater installation, characterized in that it comprises at least one suction anchor according to one of claims 1 to 8.