DE102014015801A1 - suction anchors - Google Patents

Abstract

The invention relates to a suction anchor for the offshore area as a foundation for floating equipment, such as buoys or wind turbines. The suction anchor consists of a cylindrical hollow body (1) which is open on the bottom side facing the seabed (3) and closed at the top (4) with a lid (5), wherein the lid (5) one or more openings (6 ) having. On the cylindrical hollow body (1) a supply unit (2) is decoupled, wherein the supply unit (2) from a frame (14) and a frame (14) attached to the suction pump (10) via one or more Abreißkupplungen (11) one or more self-closing valves (7) in the lid (5) of the cylindrical hollow body is connected, wherein the automatically closable valves (7) at the openings (6) in the lid (5) are arranged.

Description

The invention relates to a suction anchor for the offshore area as a foundation for floating equipment, such as buoys or wind turbines.

For the establishment of offshore installations, in particular wind turbines, a variety of known foundation types are used.

The monopile construction consists of a cylindrical hollow pole. The monopile is used in many European offshore wind farms near the coast and is suitable for foundations in water depths up to about 20 meters. Monopile designs are not suitable for using more powerful OWEA (6 MW) in deeper water. Their use is economical up to water depths of about 15 meters. Monopiles can be installed easily and quickly. However, heavy piling equipment is needed for the construction.

The jacket is a truss structure made of steel, which is similar to the construction of conventional electricity pylons. At its four feet, the jacket is anchored with piles in the seabed. The jacket construction has already proven itself in the oil industry in deeper water depths. Thanks to the truss structure, 40 to 50% steel can be saved compared to the monopile. A disadvantage of this foundation is the low collision safety.

The tripod is a tripod construction made of steel pipes that support the main pile under water. The tripod is anchored with small piles by ramming in the seabed.

The tripile consists of three steel pillars that are anchored under water. Over water, a tripod construction is placed on these steel pillars. Gravity foundations consist of a large block of concrete supporting the steel construction of the OWEA. Gravity foundations are primarily used in bridge construction and for European offshore wind farms in water depths below 10 meters.

The floating foundation is a construction where the floating offshore equipment is attached to a foundation on the seabed with a rope.

The bucket foundation is similarly flushed out of the negative pressure by an inverted bucket and suctions into the sandy ground.

In the DE 10 2009 044 278 A1 A floating foundation with improved bracing is described, which is anchored with anchors arranged vertically below junctions of a floating structure. From each anchor, guy ropes extend vertically upwards to corresponding junctions and other guy ropes obliquely upward to beyond junction points. The anchors are designed as gravity anchor. They consist of an optionally Stahlumgriffenen or steel reinforced concrete body. In a preferred embodiment, the concrete body is made of sea gravel with seawater as mixing water on site.

The GB 2378679 discloses a floating structure for a wind turbine. The floating structure comprises several floating bodies that have been submerged during operation. They are connected to each other via a support frame on which the tower of the wind turbine is centrally arranged. For anchoring suction anchors are provided with which the floating structure is connected by tension cables. These extend substantially vertically from the floats to the suction anchors. The suction anchor are not explained here in detail.

The DE 100 56 857 A1 describes a float, which is attached via anchoring cables to pile pile anchors or to pile pile anchors with ballast bodies.

The plant of DE 10 2010 026 117 A1 relates to an offshore installation, in particular a wind turbine and a method for anchoring such an offshore installation on the seabed, the uppermost layer of which is a layer of sand. The offshore installation is anchored to the seabed with at least three anchoring elements.

The anchoring elements are designed in the form of a hollow body, which encloses an interior and is open towards a lower side, wherein at least one outlet opening is provided in the upper side of the hollow body opposite the underside. Due to the dead weight of the offshore installation, the offshore installation or at least one of the anchoring elements is pressed into the sand layer. By provided at the top of the anchoring elements outlet openings in the interior of the hollow body water can leave the hollow body and thus the anchoring element upwards. Advantageously, the offshore plant has a suction device for sucking the water from the interior of the anchoring elements. For this purpose, for example, suction lines can be connected to the outlet openings on the upper side of the hollow body. In this way, the water can be sucked from the hollow body of the anchoring element or even from each of the individual chambers, provided that the anchoring element has ribs. This creates a negative pressure in the interior of the anchoring element the sinking of the anchoring elements in the sand layer of the seabed is further accelerated. The pumped out of the interior of the hollow body water can be performed, for example, arranged in a base pipes up and pumped into the sea

The DE 28 49 430 A1 discloses a suction anchor with a top plate and a downwardly projecting jacket. By at least one spike or peg, which is retractable into the water bottom of the pull-out resistance of the armature is increased. For use, the suction anchor is lowered to the bottom of the water and a pump is activated, which then creates a vacuum zone within the jacket. This negative pressure, together with the hydrostatic pressure acting on the top plate, results in a differential pressure above the top plate, which then presses the jacket into the bottom of the water until the top plate comes to rest on the bottom of the water. After completion of the burial process, the pegs of the anchor are driven by means of their associated drive devices in the bottom of the water to increase the pull-out resistance of the armature. On the top plate by means of a hydraulically actuated, cooperating with locking tabs locking bolts provided with a paddle drum and releasably aligned by means of dowel pins. In the central region of the top plate, a fastening eye for an anchor chain or an anchor line is arranged, while at the drum auxiliary eyelets are provided for their salvage after the digging of the anchor. The anchor chain or rope may conveniently be wound up prior to burying the anchor within the drum, thereby increasing the overall mass of the anchor and assisting its burial.

In addition to high costs, the foundations used hitherto cause a high level of noise pollution with considerable noise emissions during pile driving to construct the foundations with considerable effects on the life of marine mammals and other marine organisms.

Furthermore, ocean currents and the constant waves cause rinses on the foundations. As a result of this excavation, the foundations of offshore installations lose their hold in the seabed and thus their stability.

The object of the invention is to develop a foundation for offshore installations, which requires no pile driving and can be pulled out of the ground again.

According to the invention the problem is solved by the development of a suction anchor as a foundation for offshore installations. The suction anchor consists of a cylindrical hollow body ( 1 ) and one on the cylindrical hollow body ( 1 ) decoupled supply unit ( 2 ). On the cylindrical hollow body ( 1 ) is located in the direction of the seabed bottom ( 3 ) open while the top ( 4 ) with a lid ( 5 ) is closed. On the bottom ( 3 ) of the cylindrical hollow body ( 1 ) is outside the cylindrical hollow body ( 1 ) a scavenging air ring ( 12 ) arranged. In the lid ( 5 ) are one or more openings ( 6 ), to which one or more self-closing valves ( 7 ), in particular ball valves are attached. Furthermore, on the lid ( 5 ) one or more compressed air connections ( 8th ) and an anchor eyelet ( 9 ), whereby the compressed air connections ( 8th ) with the scavenging air ring ( 12 ) via air ducts ( 15 ) are connected. The supply unit ( 2 ) consists of a frame ( 15 ) with a suction pump ( 10 ), which have pull-off couplings ( 11 ) with the closable valves ( 7 ) is torn off.

The cylindrical hollow body ( 1 ) can in a further embodiment of the invention from one or more chambers ( 13 ) consist.

The invention will now be explained in more detail by way of example, wherein the 1 a schematic representation of the suction anchor, the 2 a sectional view through the suction anchor and the 3 the schematic representation of the chambers ( 13 ) in the cylindrical hollow body ( 1 ) of the suction anchor and wherein

LIST OF REFERENCE NUMBERS

1

cylindrical hollow body

2

supply unit

3

Bottom of the cylindrical hollow body ( 1 )

4

Top of the cylindrical hollow body ( 1 )

5

cover

6

Openings in the lid ( 5 )

7

valves

8th

Compressed air connections

9

anchor lug

10

suction pump

11

safe breaks

12

Spülluftkranz

13

Chambers in the cylindrical hollow body ( 1 )

14

Frame of the supply unit ( 2 )

15

air lines

• mean.

The suction anchor consists of a cylindrical hollow body ( 1 ) and one on this cylindrical hollow body ( 1 ) decoupled supply unit ( 2 ). The cylindrical hollow body ( 1 ) can in single chamber ( 13 ) be divided. The cylindrical hollow body ( 1 ) is on the underside of the seabed ( 3 ) open, while at the top ( 4 ) with a lid ( 5 ) is closed. At the open bottom ( 3 ) is outside the cylindrical hollow body ( 1 ) a scavenging air ring ( 12 ) welded. The lid ( 5 ) has one or more openings ( 6 ) on which one or more closable ball valves ( 7 ) are arranged. On the lid ( 5 ) are still one or more compressed air connections ( 8th ) and an anchor eye ( 9 ), whereby the compressed air connections ( 8th ) with the scavenging air ring ( 12 ) via air ducts ( 15 ) are connected. The supply unit ( 2 ) consists of a frame ( 14 ), which can be decoupled with the cylindrical hollow body ( 1 ), and a suction pump ( 10 ) via one or more breakaway couplings ( 11 ) in the form of pinch valves with the closable valves ( 7 ) is torn off.

To anchor the Saugankers in the seabed of the cylindrical hollow body ( 1 ) with the supply unit connected thereto ( 2 ) placed on the seabed. Through the suction pump ( 10 ) we water and if given also silt and sand from the cylindrical hollow body ( 1 ) and it is formed in the cylindrical hollow body ( 1 ) a vacuum. Due to the weight of the suction anchor and the hydrostatic pressure, it sinks into the seabed and forms a foundation for offshore installations. Due to the scavenging air ring ( 12 ), the seabed can be loosened and the sinking of the cylindrical hollow body ( 1 ).

By controlling the occupancy of the individual chambers ( 13 ) with different vacuum through the suction pump ( 10 ) oblique positions of the cylindrical hollow body ( 1 ).

After anchoring the cylindrical hollow body ( 1 ) in the seabed, the supply unit ( 2 ) from the cylindrical hollow body ( 1 ) decoupled and lifted from him. The suction pump ( 10 ) by pinch valves as Abreißkupplungen ( 11 ) from the ball valves ( 7 ) and the ball valves ( 7 ) close automatically.

For lifting the cylindrical hollow body ( 1 ) as a foundation for an offshore installation is a lifting device by means of a chain with the anchor eye ( 9 ) and lifted from the seabed to the surface. Through the compressed air connections ( 8th ) is compressed air via the air lines ( 15 ) in the scavenging air ring ( 12 ) and in this way the cylindrical hollow body ( 1 ) in the seabed.

In addition, the scavenging air wreath ( 12 ) also the task of the cylindrical hollow body ( 1 ) with a bubble curtain when working on Sauganker to surround and thus to achieve a soundproofing effect.

The suction anchor as a foundation for offshore installations not only serves as an anchorage for the seabed, but can also be used for all underwater foundations, such as in rivers or lakes.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102009044278 A1 [0009]
• GB 2378679 [0010]
• DE 10056857 A1 [0011]
• DE 102010026117 A1 [0012]
• DE 2849430 Al [0014]

Claims (4)

Suction anchor, consisting of a cylindrical hollow body ( 1 ), which on the underside facing the seabed ( 3 ) open and at the top ( 4 ) with a lid ( 5 ) is closed, the lid ( 5 ) one or more openings ( 6 ), Characterized in that (at the cylindrical hollow body 1 ) decoupled a supply unit ( 2 ), wherein the supply unit ( 2 ) from a rack ( 14 ) and one on the frame ( 14 ) attached suction pump ( 10 ) via one or more breakaway couplings ( 11 ) with one or more self-closing valves ( 7 ) in the lid ( 5 ) of the cylindrical hollow body is, consists, wherein the automatically closable valves ( 7 ) at the openings ( 6 ) in the lid ( 5 ) are arranged. Suction anchor according to claim 1, characterized in that on the underside ( 3 ) outside the cylindrical hollow body ( 1 ) a scavenging air ring ( 12 ) is arranged, which consists of a, outside the cylindrical hollow body ( 1 ) attached, provided with nozzles line. Suction anchor according to claim 1 to 2, characterized in that the cylindrical hollow body ( 1 ) into one or more chambers ( 13 ) is shared. Suction anchor according to claim 1 to 3, characterized in that on the lid ( 5 ) an anchor eyelet ( 9 ) and one or more compressed air connections ( 8th ), wherein the compressed air connections ( 8th ) with the scavenging air ring ( 12 ) via air ducts ( 15 ) are connected.

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