NO134979B - - Google Patents

Description

The present invention relates to a foundation anchor for floating marine construction.

Exploration of the seabed and drilling of holes for gas

and crude oil is usually undertaken from a fixed platform or a floating vessel. If a platform is used, it stands on legs that protrude through the water and are anchored to the sea-

the bottom by means of piles or by suitable means. If drilling is carried out from a floating vessel, this is held in position by an anchoring device that protrudes down to the seabed, or by means of a built-in dynamic mechanism such as thrusters or the like that serves to hold the vessel in place within a certain defined area during the drilling operation.

A type of drilling platform that is believed to be particularly suitable in deep water consists of a floating vessel or a platform in the water surface that is held in a relatively fixed position by means of a rigid mooring column that projects down to the seabed.

The lower end of the mooring structure is usually anchored

at a single point so that the surface platform can make a limited swing movement depending on the forces of wind and waves. This is e.g. shown in French Patent No. I.519.89I.

In order to achieve a sufficient anchoring force with such an arrangement, the anchoring device must necessarily be efficient and have a sufficiently large weight and bearing surface to withstand horizontal forces that are exerted both against the floating vessel and against the mooring pillar. For practical reasons, the anchor is usually designed

be made of concrete or other material that has sufficient weight to provide the necessary downward thrust so that the vessel is stabilized as shown in the aforementioned French patent.

Such anchors are difficult to handle at the surface of the water

because of their weight. This does not only apply to the production of

the anchor but also transport of the unit and control of the lowering of the anchor to the seabed.

In the aforementioned French patent, this is solved by the anchor

is connected to the floating drilling platform and is floated together with this out onto the drilling field where the anchor is controllably lowered to the bottom by means of lines attached to the anchor and which are released from winches on the platform. Because the anchor and platform are connected, the platform must be brought into the correct position before the anchor can be lowered, which is a laborious and time-consuming job, especially in bad weather, which is associated with large costs. Due to a relatively complex connection device between the anchor and a base plate on the platform, these cannot be separated from each other later, and the entire anchor with the platform's base rod is thereby lost when the platform is moved.

Because of the uncertainty regarding the possibility

in order to extract oil products from a particular borehole, it is desirable that as much as possible of the drilling and production equipment can be reused, that the above-mentioned vessel or platform and the mooring column can be reused by only detaching one or both parts from the seabed and then move them to the desired location. They can then be placed in the desired position in the same way as before. However, it is often difficult and impractical to try to save the actual anchor or anchoring element as mentioned in connection with the aforementioned French patent.

The purpose of the present invention is therefore

to provide a deep-water anchor for stabilizing a floating drilling vessel or platform in the water surface, which can be easily and quickly brought into place and lowered independently of the platform and which can be picked up and used again.

According to the invention, this is achieved by means of the features indicated in the characteristics of the subsequent claims.

The invention will be described in more detail below

with reference to an embodiment shown in the drawing where

fig. 1 is an elevation in partial horizontal section of a foundation anchor according to the invention,

fig. 2 is a cross-section along the line II-II in fig. 1,

fig. 3-6 show the different steps in the installation of the composite foundation anchor in connection with the location

of a platform in the sea,

fig. 7 shows a locking mechanism for securing the buoyancy section of the foundation anchor to its foundation element for transport of the latter to the place of installation, as well as for joining the two parts together on the seabed.

With a view to the above purposes it is provided

a multi-component foundation anchor that can partially be used several times, for a drilling platform or similar. The foundation anchor comprises at least two parts which are connected in such a way that they can be separated at the surface of the water, so that each part can be sunk to the seabed in turn.

The foundation anchor consists of a foundation element 11

of concrete or similar material that forms a first anchoring base. This element is further provided with protruding coupling devices 27 for connection with a lower end of a floating platform or other vessel, through a rigid mooring structure or column 17 which is rotatably connected to the foundation anchor 12

and which project from this up to the vessel.

The ballast or buoyancy section 12, which can preferably be designed as a series of closed, tubular parts, is designed with a view to retaining the foundation element 11 or alternatively to support this as it is lowered through the water. The buoyancy section 12 consists of a series of separate bulkheads connected to a manifold device by which the weight and buoyancy of the section can be regulated. A device is also provided for storing liquid such as crude oil or drilling mud. If drilling mud is to be stored, this can also serve as ballast to keep the buoyancy section 12 in position on the seabed.

In fig. 6 shows a foundation anchor 10 of a type which is intended to be partially buried in the seabed. A platform 15 extends vertically from a point just above the seabed to a distance above the sea surface. At the upper end of the platform there is a deck 16 on which drilling equipment, production equipment, ballast equipment, instruments and the like can be mounted. The platform comprises a number of elongated legs or columns 17 with buoyancy anchors 18 at the upper end. In its normal operating position, the platform 15 extends mainly vertically through the water.

The lower end of one or more legs 17 which make up the platform column is connected to a coupling device 27 on the foundation anchor 10. The platform 15 can thus make a limited swing movement depending on forces from wind and waves,

and yet remain relatively stable to enable continuous drilling, production or other operations from deck 16.

The foundation anchor 10 composed of a number of components mainly consists of a foundation element 11 which is surrounded by a buoyancy section 12. The outer shape of the foundation element 11 is of importance only to the extent that a flat, pillow-like shape will facilitate the retention function by providing sufficient weight and sufficient bearing surface to prevent the foundation anchor from sinking too deeply into a soft substratum on the seabed.

The foundation element.il consists of a relatively strong reinforced plate 13 made of concrete. As shown, this element has a plate-like shape with opposite upper and lower surfaces 21 and 22. A primary reason for choosing a predominantly flat shape for this element is, as noted above, that it is desirable to provide a lower surface with a relatively large bearing surface which rests against a soft surface without sinking too deeply into it.

In order to provide a reliable hold between the concrete slab 13 and the seabed, the lower surface 22 is designed with a projecting circumferential lip 23 that defines a shallow cavity 24. The lip 23 is designed with a downward-facing sharp edge that makes it easy for the edge to penetrate in the seabed.

In a number of places around the perimeter of the concrete slab 13, an inclined surface 60 and a recess 61 are designed for shear pins 62 which are used to lock the buoyancy section 12 to the foundation element 11. The shear pins 62 are again placed in hydraulic cylinders 63 which can be activated by a pump 69 which pushes hydraulic fluid from a reservoir, through the line 65 to the cylinders 63. The pressure fluid in each cylinder acts on a piston 64 which compresses the spring 66 and pulls the pin 62 back. By relieving the pressure in the line 65, the pins 62 can freely move in as a result of them resting with the weight of the buoyancy section 12 against the inclined edge 60, so that the two sections can be automatically connected again. (The hydraulic system is used to detach the foundation element 11 from the buoyancy section 12 when both float in the water surface.

The concrete slab 13, i.e. the foundation element 11, is further provided with transverse passages 19 which go from the upper surface to the lower surface, whereby mud and water can flow between the inner cavity and the surrounding water as the slab 13 is lowered towards a base.

The foundation element 11 is further provided with a coupling device for connecting an element of a leg 17 to thereby limit the horizontal movement of the platform 15 to some extent. The coupling device comprises at least one and preferably several protruding coupling bolts 27 on the upper surface of the foundation element 11. The bolts 27 have a constant diameter with their lower end firmly embedded in the concrete slab 13 which forms the foundation element 11 to thereby fix the bolts in a vertical position.

The buoyancy section 12 mainly consists of one or more tanks which are connected to a pump system which serves to vary the buoyancy of the buoyancy section 12 to thereby enable the section to either float on the surface of the water or to be lowered. The buoyancy section 12 comprises a number of hollow elements 28, 29, 31 and 32, preferably with a cylindrical cross-section, which are placed along its outer edge. The aforementioned hollow elements are formed from thick-walled tubes, and are butt-welded to each other so that a continuous ring element is formed. The shape of this largely depends on the shape of the foundation element Eb 11 so that this and the buoyancy section can be connected together for transport or while in their position on the seabed.

Although the shape of the foundation element 13 and buoyancy section 12 is shown rectangular in the drawings, the actual shape may depend on a number of factors.

Each cylindrical member of the buoyancy section is provided with one or more internal panels such as 33" placed on

across the element, so that tanks such as 34 and 36 are formed on each side of said panel. In order to reduce the displacement of fluid ballast during the movement of the section 12, the tanks 34 and 36 can be provided with transverse, perforated plates 37 and 38 so that the movement of water or drilling mud is dampened. As shown in fig. 2 lies the buoyancy-six ion. 12 against a profiled edge 26 of the foundation plate 13. Although the buoyancy section 12 is shown hanging over the edge of the foundation plate 13, it should be noted that this does not necessarily have to be so as the buoyancy section 12 can also serve by only being placed directly on top of the foundation plate.

The buoyancy section 12 further comprises transverse stiffeners 59 and 58 which run between opposing cylindrical elements. The transverse struts intersect a central main strut 39, and are provided with separate, intermediate guide rods 41,42 which in between form an opening 43. These openings are so placed in the buoyancy six ion 12 that they correspond to and are connected together with the coupling bolts 27 which protrudes from the foundation plate 13-The buoyancy section 12 further comprises a pump device connected to the respective tanks 34 and 36 therein.

Said pump device can either be placed on the platform 15 or be remotely controlled from the water surface. The pump device can e.g. comprise a manifold arrangement formed by an upward line 44 which is connected to the pump 46 which is either located in the tank section 36 or on the platform deck 16. The flow of the material, which can either be ballast water or drilling mud, is controlled through a series of valves represented by the valves 47 and 48. Said valves can either be placed on the platform deck 16 or placed on the bottom.

In the latter case, the valves can be controlled remotely from the platform deck 16 or from a vessel on the surface of the water.

When the buoyancy section 12 serves as a transport vessel for the entire anchor construction 10, the buoyancy section 12 and foundation pMen 13 are firmly connected to each other at the water surface. The foundation plate 13 can preferably be submerged in the water to reduce the buoyancy required by the buoyancy section 12. In this condition, the unit can be towed in the surface of the water until the place where it is to be lowered is reached.

The foundation element 11, which is made up of the foundation plate 13 and the section 12, is connected so that they can be easily separated,

so that the foundation plate 13 can be lowered to the seabed. Such a connection can be arranged in a number of different ways. In order to keep the foundation plate 13 and the buoyancy section 12 in the correct mutual relationship, the latter is provided with one or more, preferably two flexible lines 51 and 52, e.g. in the form of a cable or chain. These latter lines are connected at their lower end to the foundation plate 13 before this is lowered to the seabed. The lines are held at the surface of the water and the tension in these is regulated as the foundation plate 13 is lowered and the buoyancy section 12 remains afloat. The lines pass through the guide opening 43 in the buoyancy section 12, and the latter's buoyancy is regulated so that it sinks

in the water and is guided to its correct position with the help of lines 51 and 52 to abut against the foundation plate 13.

The connection system may comprise one or more line drums on the buoyancy section 12 provided with a winch on which the line, possibly cable or chain, is wound up. However, the lines can also be controlled externally, e.g. by means of a floating crane or the like on the water surface, which controls the buoyancy section 12 as it is lowered to the seabed.

As shown in fig. 3-6, the installation of a foundation anchor 10 of the described type takes place in a series of steps. The foundation anchor 10 is towed with the foundation element 11 and the buoyancy section 12 connected together, to the desired location in the sea. Flexible guide lines 51 and 52 are then attached to the foundation plate 13, preferably at the upper ends of the respective coupling bolts 27. Said guide lines run through the respective guide openings 43 in the buoyancy section 12, after which the foundation plate sinks to the seabed. The lowering operation takes place by detaching the foundation plate 13 from the buoyancy section 12 and a regulated lowering of the foundation plate takes place either with the aid of the crane barge 54 or by speed regulation of the respective support lines as they are released from drums by means of a winch on the buoyancy section 12.

With the foundation plate 13 at least partially buried

in the seabed as shown in fig. 4, water is filled in the buoyancy tanks 34 and 36 so that the buoyancy characteristic of the buoyancy section 12 changes. The upper ends of the lines 51 and 52 are connected to buoys 57 in the water surface in order to later be connected to the platform 15. The buoyancy section 12 is then lowered in a controlled manner towards the seabed along the guide lines 51 and 52 whereby the respective guide openings 43 come to enclose the projecting coupling bolts 27 .

The buoyancy section 12 can be provided with one or more piles 56 which protrude from the underside thereof. Thus, when the latter is in its rest position, the weight of the unit will cause the respective piles 56 to penetrate into the substrate so that the foundation anchor's 10 resistance to horizontal forces is increased.

When the foundation anchor 10 is in place, the lines are guided

51 and 52 through the respective legs 17 to the platform 15. By regulating the buoyancy characteristic of the platform structure, the lower end of this can be brought down towards the seabed where the end points of the respective legs come into engagement with the protruding coupling bolts 27 on the foundation plate 13.

When it is desired to move the equipment from one drilling site to another, the reverse procedure is followed to thereby save the buoyancy section 12 and/or the foundation plate 13.

The platform 15 is then given sufficient buoyancy so that it detaches from the foundation plate 13. The buoyancy of the buoyancy section 12 is then gradually changed so that the entire unit rises to the surface in a controlled manner along the guide lines 51

and 52. Then, by using the buoyancy section 12 as a support structure on the surface of the water, either alone or together with a crane barge 54, the foundation plate 13 can be raised to the surface. If the foundation plate 13 has been dug so far into the seabed that it cannot be loosened, it can be left on the seabed and a new foundation plate can be used which is adapted in a similar way to the buoyancy section 12 for the next installation.

With the buoyancy section 12 in the submerged position and connected to the foundation plate 13, the ballast material will usually be water. However, in order to more effectively utilize the storage capacity of the respective ballast tanks 34 and -36, these can be filled in whole or in part with a fluid that is used during drilling operations, such as drilling mud or the like. The drilling mud is thus pumped in liquid phase into the respective storage tanks 34 and 36 and kept there until the mud is to be used for the drilling operation. The sludge is suctioned or pumped from the tanks and the resulting void can be filled with water or other material to give the buoyancy section 12 the desired weight.

To facilitate the transfer of drilling fluid, each storage tank 34 and 36 may be provided with a device to hold the mud in a solution or liquid suspension so that it can be easily handled by the pump and manifold system. Thus, a pump can be built into each storage tank, the suction side of which is immersed in the stored fluid, and which is provided with one or more outflow devices which are directed down into the fluid, so that it is subjected to vigorous stirring and thus remains in liquid form . The same result can also be achieved in that each of the storage tanks can alternatively be provided with a pipe mechanism such as, for example. a motor-driven

pipe organ placed in the tank, and remotely controlled from the surface,

so that the drill mud can be given sufficient agitation before it is extracted from the tank.

Claims (2)

1. Foundation anchor for a floating marine structure, characterized in that the foundation anchor comprises two parts, one of which is a foundation element (11) and the other is a buoyancy section (12) whose buoyancy and position can be regulated using a pump system (46;, and where the foundation element (11) has a coupling device (27) designed to cooperate with a submerged end of a floating marine structure for anchoring the structure, and that the buoyancy section (12) is connected to the foundation element (11) by means of guide lines (51,52) which are extendable for first adjustable lowering of the foundation element (11) to the seabed from the buoyancy section (12) when this floats, and which are then intended to be connected, in their extended state, with buoys (57) at the surface to form guides for lowering the buoyancy section in a negative buoyancy condition, to reconnect with the previously lowered foundation element (11). 2. Foundation anchor according to claim 1, characterized in that the buoyancy section comprises a number of separate buoyancy tanks (28,29,31,32) each of which is separately connected to the pump system (46) for regulating individual buoyancy of these.