NO20110161A1 - Find for a floating structure - Google Patents

Abstract

A finding for a floating platform having at least one platform column is described. The fin is formed of at least one single plate, but preferably of a number of single plates, and with at least one bracket. The fins are intended for welding to the platform column, and the plates in the fins are welded together edge to edge, so that a continuous fin is formed. Also described is a floating structure with such a fin, and a method for reducing speed-induced movements on a floating platform.

Description

The present invention relates to fins for a floating structure, in particular for a floating platform.

The main reason floating platforms are equipped with fins is to prevent velocity induced motions (VIM motion - Velocity Induced Motions) in extreme eddy currents. Such currents occur, for example, in the Gulf of Mexico. When a floating platform is equipped with fins, these will provide a defined separation point for the laminar flow around the column, thereby preventing extreme lateral movements, which will help prevent incidents related to fatigue in mooring and riser devices.

Platforms are sometimes moved from one location to another location, where the need to reduce speed-induced movements will be greater than at the first location. There is therefore a need for fins that can be mounted on existing structures. There is also a need for a fin which has a simple design and which can be easily attached to a platform column, particularly platform columns which do not have a uniform outer diameter.

It is therefore a purpose of the present invention to provide one or more fins which can be arranged on existing platforms which are already in use.

Another object of the invention is to provide a fin for a platform having columns with a varying outer diameter.

Furthermore, it is a purpose of the invention to provide fins which have a simple structure, can be easily attached to existing platform columns, and are cheap to manufacture.

These purposes are achieved with a fin as stated in claim 1, with a floating structure as stated in claim 10, and with a method for reducing speed-induced movements on a floating platform as stated in claim 18. Further embodiments of the fin are stated in the independent requirements 2-9. Further embodiments of the floating structure are stated in the independent claims 11-17, and further embodiments of the method for reducing speed-induced movements on a floating platform are stated in the independent claims 19-22.

A fin is provided which is formed using at least one single plate, but can advantageously consist of several plates, which plates are designed to be welded to the platform column and edge to edge with adjacent plates in the fin so that a continuous fin is thereby formed. Such plates are easy to cut and to adapt to a column that has a varying diameter.

In order to absorb forces and moments that act on the fin, the fin is equipped with at least one support bracket. The at least one support bracket is preferably attached to the fin plate in such a way that the at least one support bracket will be essentially horizontal when the fin is mounted on a platform column, and the platform column is in a vertical position.

The at least one support bracket can be attached to the fin and to the platform column in various ways, but is preferably welded to the fin and adapted for welding to the platform column. The at least one support bracket can also be connected to the fin and the column by means of bolts or similar fasteners.

The size and number of support brackets will depend on several factors, such as the size of the fin and the strength of the water currents where the platform will be used.

Furthermore, the at least one support bracket is preferably formed from a single metal plate. If the fin is provided with two or more support brackets, these are preferably arranged on the same side of the fin.

The plate or plates forming the fin can also be provided with at least one stiffener which will give the fin plate or fin plates extra strength. The at least one brace is preferably formed from a single plate which is attached to the fin plate or fin plates by means of suitable fasteners, such as bolts, or preferably by means of welding. The at least one brace is preferably connected to the fin so that the at least one brace will be essentially parallel to the surface of the platform pillar when the fin is connected to the platform pillar, i.e. the at least one brace runs mainly in the longitudinal direction of the fin. The size and number of braces will depend on several factors, such as the size of the fin and the strength of the water currents where the platform is to be used.

The at least one support bracket and the at least one brace are preferably arranged on the same side of the fin. The plates in the at least one fin and/or the support brackets and/or the stiffeners are preferably made of weldable metal, such as steel.

An embodiment of the invention includes a number of individual plates that are welded together edge to edge, and are designed for welding to a platform column. It further includes support brackets formed from a single plate and welded to the fin and adapted for welding to a platform column, as well as braces welded to the fin, thereby providing a fin which is sufficiently strong, is light and cheap to manufacture, can easily can be adapted to a platform column with a varying outer diameter and can easily be adapted to a connection to an existing platform.

A floating structure is also proposed which includes at least one column that penetrates the water surface, at least one column being provided with at least one fin. The at least one fin is formed from at least one single plate, but can advantageously be composed of a number of single plates. The plates are welded to the platform column and edge to edge with adjacent plates in at least one fin, so that a continuous fin is thereby provided.

The at least one fin preferably extends down from the waterline for the columns, forming a helix shape.

The at least one fin is further equipped with at least one support bracket. The at least one support bracket is attached to the at least one fin so that the at least one support bracket will be substantially horizontal when the at least one fin is mounted on a platform column, and the platform column is in a vertical position.

The at least one support bracket is advantageously welded to the at least one fin and to the platform column at the same vertical level as the horizontal ring frames and decks inside the columns. The at least one support bracket can also be connected to the column and/or fin by means of other fasteners, such as bolts.

In a preferred embodiment of the floating structure, all support brackets for the at least one fin are located on one and the same side of the at least one fin.

In a further embodiment of the plate or plates which form the at least one fin, at least one stiffener is arranged. Preferably, the at least one support bracket and the at least one brace attach the at least one fin to one and the same side of the at least one fin.

Other designs of the support brackets and stiffeners in the floating structure are described above in connection with the fin.

A method is also proposed for reducing speed-induced movements on a floating platform, which includes at least one column. The method includes welding at least one fin, formed by means of at least one single plate, but preferably by means of a number of plates, which fin is welded directly to the hull of the at least one column. Preferably, the at least one fin is given a helical shape, and extends downwards from the waterline to the at least one column.

The method further includes welding at least one support bracket, including a single plate, directly to the fins and to the hull of the at least one column. The method also preferably includes a placement of the at least one support bracket for the at least one fin on one and the same side of the fin, and preferably also a placement of the support brackets in the same plane, and at the same vertical level as the horizontal ring frames and tires inside the at least one the pillar.

It should be mentioned that a single plate in connection with the present invention means that the plate is not a double plate.

A non-limiting embodiment of the invention will now be described in more detail with reference to the figures, where

Fig. 1 shows fins in accordance with the invention, mounted on a platform column,

Fig. 2 shows the same column as in fig. 1, but seen from a different angle,

Fig. 3 shows an embodiment of a fin, and

Fig. 4 shows the same fin as in fig. 3, but seen from a different angle.

Fig. 1 and 2 show one and the same embodiment of the invention, but seen from different sides, and show fins arranged on a platform column 18. Fig. 3 and 4 show the fins in more detail.

The embodiment of the floating structure shown in the drawing includes one or more columns 10 which penetrate the surface of the water. The column 10 may have a circular cross-section over its entire length (ie vertical), but the embodiment shown in the drawing is divided into three sections, an upper section 12 having a cylindrical shape with a circular cross-section, a middle section 14 with a varying outer diameter, and a lower section 16 having a circular cylindrical shape. The middle section 14 has an upper part 20 with a conical shape, a middle part 22 with a circular cylindrical shape, and a lower part 24 with a conical shape. The floating structure is designed so that the upper part 20 of the middle section 14 passes through the water line (reference numeral 40 indicates a belt or part of the column which moves up and down through the water surface).

The column 10 is provided with at least one, and preferably three, fins 18 as shown in the two figures. Naturally, any other number of fins 18 associated with the column can be used. The fins 18 are made from one or more single plates which are welded to the column 10. As already mentioned, here a single plate means that the plate is not a double plate.

The fins 18 are preferably produced from two or more such single plates 19, see fig. 3, which plates are arranged edge to edge as indicated by the lines 23. The plates are welded together so that they form continuous fins 18.

As shown in fig. 1-2, the fins 18 are given a helical shape, i.e. they extend in a helical shape down the column. Preferably, the fins begin at the column 10 waterline 40, and extend downward to approximately the lower edge of the middle portion 22 of the middle section 14. The fins 18 may also be carried further down if necessary. The height of the fins (i.e. the radial height from the column and towards the outer edge of the fin) can be in the order of approx. 10% of the column's largest diameter. In some embodiments of the invention, this may be about 2 meters.

As shown in the drawing, the fins 18 are carried or supported by a number of support brackets 30. The support brackets 30 are formed from single plates without the use of double plates or internal bracing. The support brackets 30 are welded to the plates 19 in the fins 18, and to the column 10. The support brackets 30 are preferably placed in the same plane and at the same vertical level as the horizontal ring frames and decks (not shown) inside the column 10. This will provide support for the support brackets 30 , and contribute to the absorption of forces and moments acting on the fin 18.

The fins 18 are also shown with a number of stiffeners 21 which preferably extend in the longitudinal direction of the fin 18. The braces 21 are preferably single plates which are welded to the fin's plates 19. As shown in fig. 3 and 4, the stiffeners 21 are preferably arranged on the same side of the fin 18 as the support brackets 30.

The fins 18 described above include single plates 19 which are assigned to support brackets 30 and stiffeners 21, these also made from single plates. Because the plates 19 are preferably welded together edge to edge, and the support brackets are preferably welded to the plates 19 and to the column 10, while the braces 21 are welded to the plates 19, a fin 18 is provided which is easy to manufacture and mount on a platform column in both existing platforms and for platforms under construction, and the fin can be easily adapted to columns that have varying outer diameters. The latter detail is particularly important when it comes to fins that are to be mounted on a pillar in an existing platform.

Claims (20)

1. Fin for a floating platform comprising at least one platform column, characterized in that the fin is formed from a plurality of plates, and that the fin is arranged with at least one support bracket, the fin being designed for welding to the platform column, and is welded edge-to-edge to any plate or plates of the fin so that a continuous fin is formed. 2. Find according to claim 1, characterized in that the at least one support bracket is attached to a fin plate so that the at least one support bracket will be essentially horizontal when the fin is mounted on a platform column, and the platform column is in a vertical position. 3. Find according to one of the claims 1-2, characterized in that at least one support bracket is welded to the fin, and is adapted for welding to the platform column. 4. Finding according to one of claims 1-3, characterized in that the support brackets are arranged on the same side of the fin. 5. Finding according to one of claims 1-4, characterized in that the at least one support bracket is shaped using a single metal plate. 6. Find according to requirements 1-5, characterized in that the plate or plates forming the fin are provided with at least one stiffener. 7. Finding according to one of claims 1-6, characterized in that the at least one support bracket and the at least one brace are arranged on the same side of the fin. 8. Find according to claims 1-7, characterized in that the plates and/or the at least one support bracket and/or the at least one brace are of a weldable metal. 9. Floating structure including at least one column that penetrates the water surface, the at least one column being provided with at least one fin, characterized in that the at least one fin is formed from a number of plates, and is equipped with at least one support bracket, the plates in the at least one fin being welded together edge to edge, so that a continuous fin is thereby formed, which fin is welded to the platform column . 10. Floating structure according to claim 9, characterized in that the at least one support bracket is attached to the at least one fin so that the at least one support bracket will be essentially horizontal when the at least one fin is mounted on a platform column, and the platform column is in a vertical position. 11. Floating structure according to one of claims 9-10, characterized in that the at least one support bracket is welded to the at least one fin, and to the platform column at the same vertical level as the horizontal ring frames and/or decks inside the column. 12. Floating structure according to one of claims 9-11, characterized in that all support brackets for the at least one fin are located on the same side of the at least one fin. 13. Floating structure according to one of claims 9-12, characterized in that the plates that make up the at least one fin are provided with at least one stiffener. 14. Floating structure according to one of claims 9-13, characterized in that the at least one support bracket and the at least one brace are attached to the at least one fin on the same side of the fin. 15. Floating structure according to one of claims 9-14, characterized in that the at least one fin extends down from the column's waterline in a helical shape. 16. Method for reducing speed-induced movements on a floating platform that includes at least one platform column, characterized by welding at least one fin, formed from a number of plates, and with at least one support bracket, directly to the hull of the at least one column. 17. Method according to claim 16, characterized by welding of at least one support bracket directly to the fin. 18. Method according to one of claims 16-17, characterized by placement of the at least one support bracket for the at least one fin on the same side of the fin. 19. Method according to one of claims 16-18, characterized by placement of the support brackets in the same plane and at the same vertical level as the horizontal ring frames and/or decks inside the smallest one column. 20. Method according to one of claims 16-19, characterized by providing the at least one fin with a helical shape extending down from the waterline to the at least one column.