KR101352096B1 - Tripod suction pile substructure - Google Patents

Abstract

The present invention is equipped with a marine facility, tripod having a triangular support shape; A suction pile disposed below the tripod and disposed at a triangular support position with respect to the center of the tripod; And it is installed on the suction pile, discloses a tripod suction pile substructure comprising a floating body for floating the suction pile. The tripod suction pile substructure as described above is provided with a floating body on the upper portion of the suction pile to provide its own floating function, so that the suction pile can be transported at sea without a large barge.

Description

TRIPOD SUCTION PILE SUBSTRUCTURE}

The present invention relates to a substructure for fixing offshore facilities such as offshore wind power generators, etc., and in particular to a tripod suction pile substructure capable of self-floating.

Recently, due to the problems of environmental regulation and fossil fuel supply and demand due to global warming, the wind power generation as a renewable energy production system is in the spotlight.

In general, wind power generators have been installed mainly on land, but the installation of the sea gradually increases. For the wind power generation, the quality of the wind is generally better than that of the land, and there is an advantage that it can respond to the blade noise problem more easily. In particular, it is necessary to secure large-scale complexes in order to secure economic feasibility, and it is difficult to equip such complexes on land, and offshore and offshore seas are emerging as large offshore wind farms. In order to install these offshore wind turbines offshore, it is necessary to have a substructure for fixing the wind turbines to the seabed.

In the conventional offshore wind turbine fixed structure 10, as shown in Figure 1, the suction pile 15 is coupled to the lower portion of the tower 13 on which the wind power generator 11 is mounted, the suction pile ( 15) is immersed and penetrated the seabed (1). In addition, a single suction pile structure is used in an area of 20 m or less, and a jacket or Tripod suction pile structure is used in an area of 20 m or more.

Since the conventional substructure 10 does not have its own floating function, it is loaded on a barge (not shown) and transported to an installation position, and then lifted from the barge by a marine crane (not shown), and then sinks to an installation position to produce a steel pipe pile. It is fixed to the seabed ground (1) by using. Recently, as the offshore wind turbine becomes larger, the lower structure 10 also becomes large in size and heavy in weight, so in order to install at sea in this way, a large-capacity barge or crane is required.

In addition, the jacket or tripod is usually fixed to the seabed ground using a steel pipe pile, the steel pipe pile is first installed by installing the type on the seabed ground, then the jacket or tripod is inserted therein and then reinforced by filling the connection by grouting. This installation method has a disadvantage that the process is complicated and takes a long time because it requires a period of time to type the steel pipe pile on the seabed ground and curing period after the connection grouting. Since the expensive equipment is used at sea, it is advantageous to reduce the construction cost by simplifying the process as quickly as possible.

The present invention is to provide a tripod suction pile substructure that can be used as a floating body in the maritime transport process by giving a floating function to the tripod suction pile.

In addition, the present invention is to provide a tripod suction pile substructure to efficiently support the horizontal force and the moment transmitted by the offshore wind turbine.

In addition, the present invention is to provide a tripod suction pile substructure to reduce the construction cost by making the installation process quick and simple.

The present invention is equipped with a marine facility, tripod having a triangular support shape; A suction pile disposed below the tripod and disposed at a triangular support position with respect to the center of the tripod; And it is installed on the suction pile, discloses a tripod suction pile substructure comprising a floating body for floating the suction pile.

In addition, the float discloses a tripod suction pile substructure, characterized in that coupled to the upper portion of each suction pile.

In addition, the floating body discloses a tripod suction pile substructure, characterized in that the load filling space is provided therein so that the load can be applied to the load.

In addition, the float discloses a tripod suction pile substructure, characterized in that the upper edge portion is formed as a slope or curved surface.

In addition, the floating body discloses a tripod suction pile substructure, characterized in that the grid wire mesh is installed in the upper opening.

The present invention also discloses a tripod suction pile substructure further comprising an airbag installed on at least one of the suction pile and the float.

In addition, the airbag discloses a tripod suction pile substructure, characterized in that the detachable installation.

The tripod suction pile substructure according to the present invention has the following effects.

(1) The present invention provides the floating function and airbag on the upper portion of the tripod suction pile to give its own floating function, so that the suction pile can be transported at sea if only a tugboat is required without a large barge.

(2) In the present invention, the suction pile is inserted into the seabed and filled with loads such as concrete or sandstone in the load filling space of the floating body, and the load is applied to the load, or the concrete bag is injected into the air bag to load the load. When applied, it has an efficient support structure to resist the horizontal forces and moments transmitted by the offshore wind turbine as its own weight.

(3) The present invention has a very high rent of large equipment at sea, but if it has its own floating function, it can be quickly installed on the sea bed without using a large barge or a large crane.

1 is a view showing a substructure for fixing a conventional offshore wind power generator.
Figure 2 is a perspective view showing the tripod suction pile substructure according to a preferred embodiment of the present invention.
3 is a plan view of Fig.
4 is a cross-sectional view taken along line AA in Fig.
FIG. 5 is a plan view showing the floating body among the components of the tripod suction pile substructure of the present invention. FIG.
FIG. 6 is a cross-sectional view taken along line BB of FIG. 5.
7 is a view sequentially showing the construction of the tripod suction pile substructure of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Prior to the description of the present invention, the tripod suction pile substructure described below has been exemplified by applying the offshore wind power generator to the substructure that is fixed to the undersea ground, but it can be applied to both offshore wind power generators and offshore facilities in advance. Reveal.

Figure 2 is a perspective view showing the tripod suction pile substructure according to a preferred embodiment of the present invention, Figure 3 is a plan view of Figure 2, Figure 4 is a cross-sectional view along line AA of Figure 3, Figure 5 is a floating body 6 is a cross-sectional view taken along line BB of FIG. 5.

As shown in Figures 2 to 6, the tripod suction pile substructure 100 according to the preferred embodiment of the present invention is a tripod 110, suction pile 120, floating body 130 and airbag 140 ).

Tripod 110 is manufactured in the form of a triangular support having three supports in order to stably support the offshore facilities, for example offshore wind power generation unit 11 (see FIG. 1). The tripod 110 includes a tower 111, a support member 113, and a connection member 115.

The tower 111 is manufactured in a cylindrical shape, and the wind power generator 11 is mounted at the upper end. Here, the wind power generator 11 includes an upper tower connected to the tower 111 by a flange (not shown), etc., a nacelle coupled to the rotor and the upper tower to rotatably support the rotor. In addition, the wind power generator 11 may further include a power generator, a power storage device, or a power transmission device. Since the wind power generator 11 can be understood by known techniques, detailed description thereof will be omitted.

The support member 113 is composed of three, each disposed in the triangular support position at a rotation angle of 120 degrees around the tower 111. In addition, the support member 113 is fixed to the upper end of the suction pile 120 to be described later, the lower end of the support member 113 to support the tower 111. In this embodiment, the configuration for manufacturing the support member 113 in the form of a cylinder is illustrated, but is not limited thereto, and may also be manufactured in the form of a polygonal pillar such as a square pillar.

The connection member 115 is manufactured in the form of a rod, and a plurality of connection members 115 are provided to connect the tower 111, the support member 113, and the support member 113.

Suction pile 120 is a foundation pile of the lower structure 100, is installed in the lower portion of the tripod 110 to support the tower 111, submerged in the seabed ground (1, Fig. 7) Intrusive. In this embodiment, the suction pile 120 is composed of three, and the suction pile 120 is coupled to the lower ends of the three support members 113 of the tripod 110, respectively. In addition, the suction pile 120 may be formed in a cylindrical shape of a circular or polygonal with the upper surface sealed and the lower surface opened. In addition, the suction pile 120 may be made of steel or concrete, but it is preferable to make the suction pile 120 to be made of steel or a steel composite member for weight reduction during sea transport.

The floating body 130 is installed on the suction pile 120 to float the suction pile 120. In this embodiment, the floating body 130 is composed of three, and the floating body 130 is coupled to the upper portion of each of the three suction piles 120. For example, the floating body 130 may be manufactured by first manufacturing the suction pile 120 and then welding or bolting the upper portion of the suction pile 120. Here, when the floating body 130 is fastened to the suction pile 120 with a bolt, a sealing member (not shown) such as rubber packing is inserted into the connection portion of the suction pile 120 and the floating body 130 to leak water. It is desirable to prevent that. In addition, the floating body 130 is formed in a cylindrical shape and has the same cross section as the suction pile 120. For example, in the present exemplary embodiment, a configuration in which the floating body 130 is formed in a cylindrical shape to have the same circular cross section as the suction pile 120 manufactured in a cylindrical shape is not limited thereto, and the suction pile 120 is not limited thereto. In the case of manufacturing a polygon such as a quadrangle, the floating body 130 may be manufactured as a polygon. In addition, the floating body 130 is submerged in the suction pile 120 to penetrate the seabed ground (1), and then filled with a load (3, Fig. 7), such as concrete or sandstone, the upper surface to apply the load An open and load filling space 131 is provided therein. In addition, the floating body 130 forms an upper edge portion as an inclined surface 133 in order to prevent water from splashing into the floating body 130 by blue or spray during transportation at sea. In the present exemplary embodiment, the configuration in which the upper edge portion of the floating body 130 is formed as the inclined surface 133 is illustrated. However, the configuration is not limited thereto, and the upper edge portion of the floating body 130 may be formed as a curved surface (not shown). In addition, the floating body 130 has a grid wire mesh 135 is installed in the upper opening portion to reinforce the upper end of the floating body 130 and at the same time the interior load filling space 131 of the floating body 130 concrete or sandstone When the load 3 is filled with the load 3, the load 3 is prevented from being lost by the current.

An air bag 140 is installed on at least one of the suction pile 120 and the floating body 130 to allow the substructure 100 to float on the sea. For example, in the present exemplary embodiment, a configuration in which the airbag 140 is attached to the side of the floating body 130 coupled to the upper portion of the suction pile 120 is illustrated, but the present invention is not limited thereto, and the airbag 140 may be attached to the suction pile ( Attaching to the side of the 120 or attached to both the suction pile 120 and the floating body 130 is also possible. The airbag 140 may immerse the suction pile 120 and inject into the subsea ground 1 to inject concrete mortar or the like into the load. In addition, the airbag 140 may be detachably installed so that it can be recovered and used repeatedly. Here, as a detachable method, a known detachable means such as a bolt and a nut, a convex portion and a concave portion, a hook and a latch groove may be used.

7 is a view sequentially showing the construction of the tripod suction pile substructure of the present invention.

First, as shown in Figure 7 (a), the offshore wind power generator fixed tripod suction pile substructure 100 manufactured in a dry dock (not shown) is launched to the sea. At this time, by using the floating body 130 and the air bag 140 installed on the upper portion of the suction pile 120, the suction pile 120 is floated on the sea. By providing the self-floating function to the suction pile 120 through this, it is possible to transport the suction pile 120 at sea if there is no tug (not shown) without a large barge (not shown).

Next, as shown in FIG. 7 (b), the suction pile 120 is floated on the sea and transported to a desired position by a tugboat, and then water is injected into the floating body 130 and the airbag 140 to suction the pile ( Immerse 120).

Next, as shown in Figure 7 (c), when the lower portion of the suction pile 120 is bottomed on the sea floor using negative (-) water pressure, that is generated while extracting water from the inside of the suction pile 120 By injecting the suction pile 120 into the ground (1). When the ground penetration of the suction pile 120 is completed, a load 3 such as concrete or sandstone is filled in the load filling space 131 of the floating body 130 to apply a phase load or concrete to the airbag 140. Mortar and the like are injected to add a load. The airbag 140 may be recovered and used repeatedly if necessary. Here, in the tripod-type offshore wind power substructure 100, the compressive force and the pull force act at the point where the substructure 100 and the subsea ground 1 meet by the wind load of the upper wind turbine 11 turbine. . Since the suction pile 120 has excellent compression support but weak drawing support, loads such as concrete or sandstone (3) inside the floating body 130 and the airbag 140 installed on the upper portion of the suction pile 120 (3) ) Can be applied to the floor load to reduce the pull force itself acting on the suction pile (120). Through this, it has an efficient support structure to resist the horizontal force and the moment transmitted by the offshore wind turbine as the gravity of the load (3) applied to the suction pile (120).

Finally, the upper tower of the wind power generator 11 (see FIG. 1) is connected to the tower 111 of the tripod 110 by using a flange (not shown).

According to the tripod suction pile substructure 100 of the present invention, by installing the floating body 130 and the airbag 140 on the upper portion of the tripod suction pile 120 to give its own floating function, without the need for a large barge If there is a tugboat, the suction pile 120 can be transported at sea. In addition, when the tripod suction pile 120 reaches the installation position and immersed in the sea floor, the crane is used to correct the posture. Since the suction pile 120 is submerged in water, the weight is small and a relatively small crane is used. Can be. In addition, after the suction pile 120 is inserted into the seabed ground 1, a load 3, such as concrete or sandstone, is filled in the load filling space 131 of the floating body 130, or a load is placed thereon. By injecting concrete mortar into the airbag 140 to apply a floor load, it is possible not only to increase the resistance against the pull-out force transmitted by the offshore wind turbine, but also to provide a kind of semi-gravity type characteristics. As a result, it is possible to support horizontal loads caused by wind or waves, and thus have an efficient support structure. In addition, the rent of large equipment is very high in the sea, but if there is a self-floating function can be quickly installed on the seabed ground (1) without using a large barge or a large crane, it is possible to reduce the cost of installing the sea installation.

While the present invention has been described in connection with certain exemplary embodiments, it will be understood by those skilled in the art that various changes may be made without departing from the scope of the present invention. In addition, the description in parentheses in the description of the claims is intended to prevent obscuration of the description, and the scope of the claims of the claims should be construed to include all the items in parentheses.

100: tripod suction pile substructure
110: tripod
111: Tower
113: support member
115: connecting member
120: suction pile
130: floating body
131: load filling space
133: top slope
135: grid wire mesh
140: airbag

Claims (7)

A marine facility is mounted, the tripod having a triangular support shape;
A suction pile disposed below the tripod and disposed at a triangular support position with respect to the center of the tripod; And
Is installed in the upper portion on the suction pile, including a floating body to float the suction pile,
The floating body has a grid wire mesh is installed in the upper opening portion, the upper edge portion is formed as an inclined surface or curved surface, the load filling space is provided therein so as to fill the load to apply the phase load, the suction pile is launched After the load is filled in the filling space Tripod suction pile substructure. delete delete delete delete According to claim 1, wherein the tripod suction pile substructure,
The tripod suction pile substructure further comprises an airbag installed on at least one of the suction pile and the float. 7. The tripod suction pile substructure of claim 6, wherein the airbag is detachably installed.

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