Patent Description:
Various anchor types are known today within the scope of the present invention as defined by the appended claims, and examples of some of these are discussed below.

Conventional plate anchors or ship anchors, for example of "Vryhof" type. These are formed so that vessels with high towing power pull the anchors so that they dig down into the seabed. These anchor types are widely used, but also have some disadvantages. In some cases, the weak soils are of such a nature that the anchors cannot be pulled down to a sufficiently large depth to achieve the necessary holding force.

Anchor piles normally designed as steel pipe piles. These are installed using pile hammers. These anchors normally have a small diameter and may give too low holding resistance. Furthermore, they have a constant cross-section which entails a relatively large material consumption in the upper soil layer with little holding resistance.

Suction anker. These are installed by mechanical pumps attached to the pile and sucked into the ground. These anchors have a constant cross-section which results in relatively large material consumption in the upper soil layer with little holding resistance. Furthermore, they require a lid on top to establish suction. They also require a special mechanical system to enable installation into the weak soils by means of suction.

SEPLA anchors. These are formed as a plate anchor and pressed into the uncompacted masses by means of a suction anchor. This normally results in a complicated operation.

<CIT> discloses a pile which has high resistance to pulling when used as an anchor for horizontal or near-horizontal guidance. The pile has an elongated hollow body with a cross-sectional profile in the form of a closed figure which is asymmetrical about at least one axis, and is preferably triangular, especially an equilateral triangle whose equal angles are in the range <NUM>-<NUM> degrees. The pile body is preferably constructed of plate material, where at least the lower end is open, for easy driving into the carrier material (for example the seabed). A beam-like reinforcing member preferably extends over the interior of the pile body, for the full vertical length of the pile body, to strengthen the pile against bending when it its used for anchoring. A connecting element, such as a hook, is located on the pile, preferably on an edge of the reinforcing beam. In the preferred shapes of the pile, the vertical reinforcing beam forms the apex of an equilateral triangle between its equal side and at <NUM> degrees equal angles, and the connecting element is at the apex at about the middle length of the pile. Powerful marine anchoring systems are also disclosed which use the piles.

<CIT> discloses an anchor assembly for immersion in a formation below a body of water, comprising an anchor section with an elongate hollow shaft and radially extending tapered plates attached to the lower end thereof, a vibration drive unit and a releasable coupling for connecting said drive unit to said shaft. The vibrational forces fluidize the seabed whereby the anchor tends to sink by its own weight. After immersion, the coupling is deactivated to allow recovery of the drive.

An object of the present invention is therefore to provide a weak soil anchor device which solves the disadvantages and problems of the known anchor types as discussed above.

Another object is that the anchor device should be manufacturable and transportable in a cost-effective manner.

A further object is that the anchor device should be installable in an exact, predetermined position by means of standard frame equipment for piles.

A further object is that the weak soil anchor device should achieve high anchor capacity in deeper weak soils.

A yet further object is that the anchor device should be adapted and dimensioned so that the anchor has a maximum holding capacity in at least three directions, whereby the anchor can be used as a common anchor for a number of constructions.

The objects of the present invention are achieved by a weak soil anchor device for anchoring one or more constructions, characterized in that it, seen in a vertical operating position, comprises:.

Preferred embodiments of the weak soil anchor device are elaborated in claims <NUM> to <NUM>.

The object of the present invention is further achieved by a method for arranging an anchoring in weak soils for anchoring one or more structures, where a weak soil anchor device according to any one of the preceding claims <NUM> to <NUM> is used, characterized in that it comprises:.

A preferred embodiment of the method is further elaborated in claim <NUM>.

In the following, three embodiments of the weak soil anchor device for anchoring one or more (a number) structures according to the invention will be explained with reference to the accompanying figures, in which:.

Referring first to <FIG> and <FIG>, there is shown a weak soil anchor device <NUM> for anchoring a number of structures. The weak soil anchor device <NUM> is shown in a vertical operating position. The weak soil anchor device <NUM> consists of an elongate continuous open box construction <NUM> with a triangular cross-section comprising a first wall plate <NUM>, second wall plate <NUM> and a third wall plate <NUM>. An outer continuous open box structure <NUM> with a smaller vertical extent than the inner box structure <NUM> and with a triangular cross-section consisting of a first outer wall plate <NUM>, second outer wall plate <NUM> and third outer wall plate <NUM> is connected to the inner elongate continuous open box structure <NUM> in a lower area of this. The vertical center area <NUM> of the first, second and third outer wall surfaces is connected to, respectively, an outer edge area between the first and second wall surfaces <NUM>, <NUM>, second and third wall surfaces <NUM>, <NUM> and the third and first wall surfaces <NUM>, <NUM>. Referring to <FIG> an anchor bracket <NUM> is arranged respectively in each connecting area between the first and second outer wall surfaces <NUM>, <NUM>, second and third outer wall surfaces <NUM>, <NUM> and third and first outer wall surfaces <NUM>, <NUM>. Further with reference to <FIG> the anchor bracket <NUM> is arranged respectively in each connecting area between the inner box structure <NUM> and the outer box structure <NUM>. Anchor brackets <NUM> can also be arranged both in the corners of the outer box structure <NUM> and in the vertical center areas of the outer wall surfaces <NUM>, <NUM>, <NUM>.

Referring to <FIG> a third embodiment of the weak soil anchor device <NUM> is shown. The weak soil anchor device <NUM> here comprises a further outer continuous open box structure <NUM> with a triangular cross-section arranged externally of the outer continuous open box structure <NUM>.

The further outer open box structure <NUM> comprises a first further wall surface <NUM>, a second further outer wall surface <NUM> and a third further outer wall surface <NUM>. A vertical center area <NUM> of respectively the first, second and third further outer wall surfaces <NUM>, <NUM>, <NUM> is connected to respectively a lower connecting area between the first and second outer wall surfaces <NUM>, <NUM>, second and third outer wall surface <NUM>, <NUM>, third and first outer wall surface <NUM>, <NUM>. An anchor bracket <NUM> is shown here arranged in respectively each of the vertical center areas <NUM> of respectively the first, second and third further outer wall surface <NUM>, <NUM>, <NUM>.

The weak soil anchor device <NUM> according to the embodiment in <FIG> is further provided with bracing wall surfaces <NUM> extending from the vertical center area <NUM> of the first, second and third outer wall surfaces <NUM>, <NUM>, <NUM> to respectively the first, second and third further outer wall surfaces <NUM>, <NUM>, <NUM>. The bracing wall surface <NUM> in this embodiment forms an angle within the range of respectively <NUM>° and <NUM>° with the first, second and third further outer wall surfaces <NUM>, <NUM>, <NUM>. The further outer box construction <NUM> in this embodiment has a smaller vertical extent than the outer box construction <NUM>. It should be mentioned in this connection that the further outer box construction <NUM> does not necessarily needs to extend as deep as the outer box construction <NUM>. The elongate inner continuous open box structure <NUM>, the outer continuous open box structure <NUM> and the further outer continuous open box structure <NUM> each have a cross section in the form of an equilateral triangle. The box constructions <NUM>, <NUM>, <NUM> can also have a triangular-shaped cross-section which is not an equilateral triangle.

The anchor brackets <NUM> for anchor lines are fastened in the lower part of the weak soil anchor device <NUM>, where the total, resulting holding resistance from the adjacent ground masses acts based on the distribution of the ground resistance over the height of the anchor device. In this way, the weak soil anchor device <NUM> will be able to utilize the horizontal ground resistance.

Depending on the required holding force and the local ground conditions, the anchor device <NUM> can be formed by varying its geometry such as for example:.

The weak soil anchor device <NUM> is as shown in <FIG> formed from straight plates which offer a simple and cost-effective manufacturing method. The anchor device can be manufactured and transported in a lying position.

The weak soil anchor device <NUM> with the triangular box structure cross-section mean that the forces from the anchor line are distributed over the total height of the anchor device <NUM> to the surrounding weak soils by the inherent properties of the open box structure as a continuous beam.

The anchor construction <NUM> is suitable for sharing of anchors, for example that a number of floats connect to the same anchor in a wind farm. In such a case the anchor device <NUM> must take loads from different directions. The anchor device <NUM> is formed to take loads in three directions and further regarding the best holding capacity being achieved deeper in the ground, whereby the majority of the structure's material (steel, concrete) is placed in this area. The principles are that there is greater holding capacity deeper in the ground and that it is therefore effective to use more material deep down, while the upper part of the anchor device <NUM> is more to get the anchor device <NUM> pressed into the ground. The triangular-shaped box constructions <NUM>, <NUM>, <NUM> facilitate large dimensions at the bottom and at the same time minimal dimensions in the upper part that contribute little to the holding force.

As previously mentioned, the weak soil anchor device <NUM> is formed with a view to being pressed down into the seabed by means of conventional frame equipment for piling. The frame equipment can, for example, be conventional pile hammers (drop weights or hydraulic hammers) or vibrohammers. Reinforcement plates <NUM> are arranged inside in an upper area of the corners of the inner continuous box construction <NUM> to facilitate the use of piling equipment. The piling equipment can advantageously be mounted on the anchor device <NUM> on board a suitable installation vessel and lowered as a unit down to the seabed. Further driving of the anchor device <NUM> down into the weak soils takes place as for framing of free-standing piles.

After use, it will be possible to pull up the anchor device <NUM> for reuse or use of a vibrohammer combined with an upward tensile force.

The weak soil anchor device <NUM> is formed so that installation thereof does not have any limitations regarding soil profile. Different soil profiles will therefore not limit the use of the weak soil anchor device <NUM>. The soil profiles often show an increasing firmness with depth. The present weak soil anchor device <NUM> is, as previously described, formed so that it uses as little construction material as possible in the upper soil layer, but uses more construction material in deeper and firmer soil layers. There is no need to use specially made auxiliary equipment beyond standard pile hammers for installation. The anchor device <NUM> can be installed in an exact, predetermined position.

Claim 1:
A weak soil anchor device (<NUM>) for anchoring one or more structures,
wherein said device seen in a vertical operating position comprises:
an elongate inner continuous open box construction (<NUM>) with a triangular cross-section comprising a first wall surface (<NUM>), second wall surface (<NUM>) and third wall surface (<NUM>),
an outer continuous open box structure (<NUM>) with a smaller vertical extent than the inner box structure (<NUM>) and with a triangular cross-section consisting of a first outer wall surface (<NUM>), second outer wall surface (<NUM>) and third outer wall surface (<NUM>), where the vertical center area (<NUM>) of the first, second and third outer wall surfaces is connected to the inner elongate continuous open box structure (<NUM>) in a lower region of respectively an outer edge area between the first and second wall surface (<NUM>, <NUM>), second and third wall surface (<NUM>, <NUM>) and the third and first wall surface (<NUM>, <NUM>), and
anchor brackets (<NUM>) are arranged in a lower outer area of the weak soil anchor device (<NUM>),
whereby the weak soil anchor device comprising the inner and outer box structure (<NUM>, <NUM>) is lowered in use into the weak soils to a desired depth.