KR20140130863A - Large diameter steel-pipe pile of reclamation type for offshore wind generation, and constructing method thereof - Google Patents

Abstract

Provided are a buried-type large diameter steel-pipe pile for offshore wind generation and a construction method for burying the same. The construction method for burying the buried-type large diameter steel pipe pile for offshore wind generation is provided to bury the large steel pipe pile in an excavated position of foundation ground (natural ground) after the large steel pipe pile is horizontally transported on the sea to the excavated positon, while controlling the buoyancy and self-load of the large steel pipe pile by a pump, and thus is capable of using only a barge having a simple crane installed thereon to bury the large steel pipe pile without using a large-sized jack-up barge or large equipment. The construction method is capable of easily making the large steel pipe pile stand on the excavated position, while preventing water from rapidly flowing into an inlet formed on the lower end of the large steel pipe pile; separating and collecting the buried large steel pipe pile by a plug which is integrated with a pump, after the large steel pipe is buried, wherein the plug is provided to seal the upper end of the large steel pipe pile and coupled to the pump; and easily transporting the large steel pipe pile, since the large steel pipe is transported after both ends are sealed by the plug and the inlet cap.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a large diameter steel pipe pile for marine wind power generation,

The present invention relates to a steel pipe pile for offshore wind power generation, and more particularly, to a steel pipe pile for offshore wind power generation in which a steel pipe pile of a mono-pile type for offshore wind power generation is transported to an excavation position of a foundation ground, The present invention relates to an embankment large-diameter steel pipe pile for offshore wind power generation and a method for embedding the same.

Generally, a wind turbine generator that generates electricity using wind is constructed so that a blade (or a propeller) is installed on a rotary shaft of a generator to generate power by using rotational force generated by the rotation of the blade by the wind. Such a wind turbine is a device for converting wind energy into electric energy, usually composed of a blade, a transmission, and a generator, and rotates a blade of a wind turbine, and generates electric power by rotating the blade.

Here, the blade is a device for converting wind energy into mechanical energy by being rotated by the wind, and the transmission device transmits the rotational force generated by the blade to the transmission gear through the central rotation axis and increases to the rotation speed required by the generator, The generator is a device that converts the mechanical energy generated by the blade into electric energy.

Such a wind power generation system is easy to operate and manage because it is simple in its structure and installation, and can be unmanned and automated. In the past, wind power structures were mainly located on land, but due to problems such as wind resource capacity, aesthetics, and location constraints, it is in recent trends to build a large scale wind farm on the sea. However, in order to construct a wind turbine structure safely at sea, a safe installation method for a blade and a tower structure to be installed in a high position is required.

In other words, such a wind turbine system is a system configured to convert kinetic energy by wind into electrical energy, and can be divided into onshore and offshore depending on the environmental conditions to be installed. In addition, there are various methods of installing such a pile or a pile, such as a hovering type, a hydraulic pressure type, and a suction type. In order to install a large diameter file or pile, it is necessary to install the pile in a vertical direction.

In this wind turbine installation, it is the role of the tower to position the nacelle capable of generating wind power at a given height to achieve the desired and desired power. There are horizontal and vertical types of wind turbines. Recently, development and installation of horizontal type wind turbines have been actively carried out in domestic and overseas. There are many types of wind turbine towers such as mono file type, jacket type, and branch line type. In the case of large wind turbines in recent years, mono file type towers, in particular, steel hollow mono file towers, have been widely used. At this time, a joint for transmitting a load to the foundation of the ground is formed on the steel hollow tower. These joints can be divided into anchor bolts and anchor rings.

1 is a view schematically illustrating a wind power generator supporting structure.

The offshore wind power generation structure is largely divided into a turbine and a support structure, and the turbine basically applies the same technology as that of the offshore wind turbine 10. These offshore wind power structures have a life span of about 20 years, and wind turbines of 3 ~ 5MW or more, which are larger than those on land, are applied. Each component of this offshore wind power structure can be designed and coated to prevent corrosion damage due to salinity.

Here, the support structure is typically a concrete caisson type, a mono-pile type, a jacket type, a tripod type, and a floating type ) Can be divided into five types can be explained.

Concretely, the concrete caisson type is gravity type, which is used in the early offshore wind power generation complex because it is easy to manufacture and install, and was applied to Vindeby, Middelgrunden offshore wind farm, and the like. These types of concrete caissons can be used at relatively shallow water depths of 6 to 10 m and maintain their position with their own friction and seabed friction. At this time, the base diameter of concrete caisson type is 12 ~ 15m.

Also, as shown in FIG. 1, the monophile type 20 is the most commonly used offshore wind turbine foundation system, and can be installed at a depth of 25 to 30 m. Horns Rev, North Hoyle offshore wind farms, etc., and large diameter piles on the seabed are fixed by driving or drilling. It is economical. At this time, the base diameter of the monofile type is often 3 to 3.5 m.

The jacket type is currently being shown with great interest in the countries with offshore wind farms, and can be installed at a depth of 20 ~ 80m. These jacket types are supported by a jacketed structure and secured to the sea floor by a pile. Such a jacket type is a structure of a large water depth ocean, has high performance and high reliability, and is advantageous in that it is economically advantageous when used in a large-scale complex composition like the monophasic type 20 described above.

As shown in FIG. 1, the tripod type 30 is constructed by extending the above-described monofile type 20 downward and can be installed at a depth of 20 to 80 m. This tripod type 30 is characterized in that it does not need to clean the floor but uses a small diameter file, but an anchor file is required, which increases the manufacturing cost.

Also, as shown in FIG. 1, the floating type (40) is a mandatory task of future deep-sea wind power generation, and many wind turbine companies are studying to be installed at a depth of 40 to 900 meters.

On the other hand, as a prior art, Korean Patent No. 10-1240615 discloses an invention entitled "Offshore installation method of offshore wind power supporting structure for suction file integral ", which is penetrated into the sea floor by using its own weight and suction pressure After penetration, the self-weight and suction pressure are used to penetrate the bottom of the sea. The structure is installed by using the suction.

On the other hand, in the case of the mono file, a mono file is installed on the sea floor, a supporting structure is formed on the mono file, and an upper structure such as a tower, a nacelle and a blade is installed on the supporting structure. At this time, the mono-file can be installed, for example, by dragging and buiding on a barge using buoyancy or excavation.

FIG. 2A is a photograph showing a large-diameter steel pipe file according to a conventional technique, and FIG. 2B is a view illustrating a plug coupled to a large-diameter steel pipe file.

2A, a large-diameter steel pipe file 70 according to a conventional technique is dragged horizontally by buoyancy using a barge 50 for transportation at sea, and is excavated or crushed using a crane 60 A large-diameter steel pipe file 70 can be installed in the hovering position. At this time, both ends of the large diameter steel pipe pile 70 are closed after being sealed using the plug 80 as shown in FIG. 2B.

3A and 3B are diagrams for explaining how a large diameter steel pipe file according to a conventional technique is embedded.

3A and 3B, a large-diameter steel pipe file 70 is conventionally fixed on the barge, a jackup pants 90 is fixed in the sea, Was placed on a fixed hinge and the steel pipe pile (70) was slowly installed using the crane (60).

Therefore, large equipment such as a jack-up barge having a large size must be installed at the time of installing the large-diameter steel pipe file according to the conventional technique, and thus the construction cost and the construction period are long.

Korean Patent No. 10-1240615 filed on Oct. 5, 2012, entitled "Marine installation method of offshore wind supporting structure for suction file" Korean Patent Publication No. 2012-0071190 (published on July 2, 2012), entitled "Towing and Towing Instrument Assembly and Towing Method for Transporting Offshore Facilities" Korean Patent Publication No. 2010-0086800 (Published on Aug. 2, 2010), entitled "Method of Transporting Civil Structures in Underwater Environment" Korean Patent No. 10-1106219 filed on May 13, 2011, entitled "Pile-Mounted Underwater Large-Scale Casing Hybrid Structure Using Sheet File and Method of Construction thereof" Korean Patent No. 10-1013789 filed on November 17, 2008, entitled " Method and apparatus for installing a marine wind turbine generator " Japanese Laid-Open Patent No. 2011-137365 (Published on July 14, 2011), entitled "Method of Construction of Foundation Structure in Wind Power Generation Facilities" Japanese Unexamined Patent Application Publication No. 2007-120470 (Publication Date: May 17, 2007), entitled "Fundamental Structure of Offshore Wind Power Generation Device and Method of Establishing Fundamental Structure of Offshore Wind Power Generation Device & Japanese Unexamined Patent Publication No. 2006-322400 (Published on November 30, 2006), entitled "Gravity Basis of Offshore Wind Power Generation System" Japanese Unexamined Patent Publication No. 2006-046013 (Publication Date: Feb. 16, 2006), entitled "Monophasic Fundamental Structure of Wind Power Generation Facilities"

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and an object of the present invention is to provide a large-diameter steel pipe pipe for a marine wind power generation of a mono-pile type, A large-diameter steel pipe file for offshore wind power generation that can be purchased while controlling the buoyancy and weight of the large-diameter steel pipe file by using a pump when the steel pipe is purchased.

It is another object of the present invention to provide a buried large diameter steel pipe file for offshore wind power generation capable of easily erecting a large diameter steel pipe file at an excavation position while preventing rapid inflow of water by an inlet formed at a lower end of a large diameter steel pipe file, So as to provide a method of constructing the same.

Another object of the present invention is to provide a method and apparatus for an offshore wind turbine that can be separated and recovered after purchase of a large-diameter steel pipe file by using a pump-integrated plug in which a pump is fastened on a plug for sealing an upper end portion of a large- And to provide a buried large-diameter steel pipe pile and a method of constructing the same.

As a means for achieving the above technical object, the embedding type large diameter steel pipe file for offshore wind power generation according to the present invention is a large diameter steel steel pipe file for offshore wind power generation of a mono-pile type, (EN) A large - diameter steel pipe pile body which is buried in a foundation foundation excavated in a pile pile. An inlet formed at a lower end of the large-diameter steel pipe main body so that water is not rapidly introduced into the large-diameter steel pipe main body during the filling operation; An inlet cap which is fastened to temporarily close the inlet when the main body of the large diameter steel pipe is transported to the excavation position of the foundation foundation; A plug tightened to close an upper end of the large diameter pipe structure; And a pump coupled to the plug to discharge water or air flowing into the large-diameter pipe of the steel pipe main body, wherein the large-diameter steel pipe main body has a buoyancy and a self-weight controlled by the pump, And is upright.

The inlet is formed to extend a predetermined length into the large-diameter steel pipe main body so that water does not flow rapidly during the filling operation of the large-diameter steel pipe main body.

The embankment type large-diameter steel pipe file for offshore wind power generation according to the present invention may further include a remote pump control unit installed on the barge to remotely control the pump connected to the pump through a power cable.

Here, the plug and the pump are integrally formed, and an outlet for discharging water or air is formed to penetrate through the plug and the pump.

Here, the integrally formed plug and pump may be separated from the large-diameter steel pipe main body after the large-diameter steel pipe main body is erected at the excavation position.

Here, the plug has a conical diaphragm formed in eight directions from the center so as to withstand the high pressure of the large-diameter steel pipe main body.

Here, the inlet cap is fastened to the inlet port when the main body of the large-diameter steel pipe tube is transported, and the suction of the positive pressure is provided by the pump so that the inlet cap is not released.

According to another aspect of the present invention, there is provided a method for embedding and loading a buried large-diameter steel pipe file for offshore wind power generation according to the present invention, The method comprising the steps of: a) excavating a foundation foundation for installation of an offshore wind power support structure; b) fabricating a large-diameter steel pipe file main body having a water inlet formed at a lower end thereof; c) closing the interior of the large-diameter steel pipe main body by fastening the pump-integrated plug and the inlet stopper, each of which has a pump on the plug, to both ends of the large-diameter steel pipe main body; d) transporting the embankment-type large-diameter steel pipe pile having both ends sealed in the horizontal direction from the sea to the excavation position using the barge; e) removing the inlet cap from the main body of the large-diameter steel pipe, and adjusting the buoyancy and weight of the main body of the large-diameter steel pipe using the pump, while standing up; And f) separating and collecting the pump-integrated plug fastened to the main body of the large-diameter steel pipe.

Here, the pump-integrated plug of step c) is characterized in that water or an outlet for discharging air is formed so as to pass through the pump-integrated plug.

Here, the pump of the step c) is connected to a remote pump control unit installed on the barge through a power cable to be remotely controlled.

Here, the inlet cap of the step c) may be provided with suction of the positive pressure by the pump so that the inlet cap is not released when the main body of the large diameter pipe is transported.

In the step (e), the buoyancy and the weight of the large-diameter steel pipe main body are adjusted by using the pump so that water does not flow rapidly through the water inlet.

In step f), the pump-integrated plug may be detached or mechanically detached by applying a positive pressure to the pump so that the pump can be separated from the large-diameter pipe.

Here, the barge in the step (d) is a barge for carrying a crane, and the main body of the large diameter steel pipe is buried in the excavation position.

According to the present invention, when the large-diameter steel pipe file for offshore wind power generation is transported to the excavation position of the foundation ground (the ground panel) and is buried, buoyancy and self weight of the large- It is possible to install large diameter steel pipe file with barge with simple crane without using equipments, which can reduce construction cost and air.

According to the present invention, the large-diameter steel pipe file can be easily erected at the excavation position while preventing the rapid inflow of water by the inlet formed at the lower end of the large diameter steel pipe pile.

According to the present invention, by using a pump-integrated plug in which a pump is fastened on a plug for sealing an upper end portion of a large diameter pipe, the large diameter pipe can be separated and recovered after the pipe is taken.

According to the present invention, it is easy to carry a large-diameter steel pipe file by closing both ends of a large-diameter steel pipe file using a plug and an inlet stopper and then transporting the same.

Figure 1 is a schematic illustration of a wind power support structure.
FIG. 2A is a photograph showing a large-diameter steel pipe file according to a conventional technique, and FIG. 2B is a view illustrating a plug coupled to a large-diameter steel pipe file.
FIGS. 3A and 3B are views for explaining how a large-diameter steel pipe file according to a conventional technique is embedded.
4 is a cross-sectional view of a buried large-diameter steel pipe pile for offshore wind power generation according to an embodiment of the present invention.
5 is a top plan view and a bottom plan view of a buried large-diameter steel pipe pile for offshore wind power generation according to an embodiment of the present invention.
FIG. 6 is a view showing a concrete pump-integrated plug in a buried large diameter steel pipe file for offshore wind power generation according to an embodiment of the present invention.
7 is a view illustrating a plug in which a diaphragm is formed in the pump-integrated plug shown in Fig.
8 is a view for explaining the use of a pump when carrying and embedding an embossed large-diameter steel pipe pile for offshore wind power generation according to an embodiment of the present invention.
FIG. 9 is a flowchart illustrating a method for embedding a buried large-diameter steel pipe file for offshore wind power generation according to an embodiment of the present invention.
10A to 10E are views for explaining a method for embedding a buried large-diameter steel pipe file for offshore wind power generation according to an embodiment of the present invention, respectively.
11 is a view showing an upper structure formed on a buried large-diameter steel pipe pile for offshore wind power generation according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Structure of Recessed Large Diameter Steel Pipe File for Offshore Wind Power Generation]

FIG. 4 is a cross-sectional view of an embedment-type large-diameter steel pipe pile for offshore wind power generation according to an embodiment of the present invention, FIG. 5 is a plan view of an upper end portion and a lower end portion of a buried large-diameter steel pipe pile for offshore wind power generation according to an embodiment of the present invention, 6 is a view specifically showing a pump-integrated plug in an embankment-type large-diameter steel pipe file for offshore wind power generation according to an embodiment of the present invention, and FIG. 7 is a view illustrating a plug in which a diaphragm is formed in the pump- .

4 to 7, the embedding type large diameter steel pipe file 100 for offshore wind power generation according to the embodiment of the present invention is a mono-pile type embedding type large diameter steel pipe file for offshore wind power generation Pipe 130, a pump 140, an inlet cap 150, and an outlet 160, and is also provided with a large-diameter steel pipe file body 110, A remote pump controller 170 may be further included.

The embedding type large diameter steel pipe pile 100 may be a large diameter steel pipe main body 110 having an inlet port 120 formed at a lower end thereof, The pump 140 and the inlet cap 150 are fastened to each other.

The large-diameter steel pipe file body 110 is buried in the excavated foundation foundation. At this time, the large-diameter steel pipe file body 110 is, for example, a large-diameter steel pipe file having a radius of several meters, and its length may be several tens of meters, and its own weight may be several hundreds of tons. 5 (a)), the upper end of the large-diameter pipe structure 110 is formed in the shape of a hollow pipe so that the pump-integrated plug having the pump 140 coupled thereto can be fastened on the plug 130 As shown in FIG. 5B, the lower end of the large-diameter steel pipe main body 110 is formed with an inlet 120 through which water can flow. In the embodiment of the present invention, the embankment large-diameter steel pipe pile 100 is constructed such that the large-diameter steel pipe pile main body 110 is buried in the excavated position after excavating the ground pile as the foundation ground. That is, the large-diameter steel pipe main body 110 is not formed in a foundation ground, but can be constructed in such a manner that the foundation foundation is excavated and embedded.

The inlet 120 is formed at the lower end of the large-diameter steel pipe main body 110 so that water is not rapidly introduced into the large diameter pipe main body 110 when the main body 110 is buried. The inlet 120 is formed to extend from the lower center portion of the large diameter pipe body 110 by a predetermined length d so as to prevent the water from flowing rapidly during the filling operation of the large diameter pipe body 110. [ . At this time, the length (d) and radius of the inlet 120 extending into the large-diameter steel pipe main body 110 can be changed according to the buoyancy and self weight of the large-diameter steel pipe main body 110. In addition, the inlet of the inlet 120 is preferably formed in a conical shape so that the inlet cap 150 can be easily inserted.

The inlet cap 150 is tightened to temporarily close the inlet 120 when the large diameter pipe body 110 is transported to the excavation position of the foundation foundation. That is, the inlet stopper 150 is fastened to the inlet 120 at the time of conveying the large-diameter steel pipe main body 110 and suctions of the pressure by the pump 140 so that the inlet stopper 150 is not removed. ) May be provided. In other words, when air is discharged to the outside by using the pump 40 while the large-diameter pipe structure 110 is closed, the internal pressure of the large-diameter pipe structure 110 becomes smaller than the external pressure, The inlet cap 150 which closes the inlet 120 is not removed.

The plug 130 is tightened to close the upper end of the large diameter pipe body 110. 7A, a diaphragm 131 is formed from the center so that the large-diameter steel pipe main body 110 can withstand high pressure. At this time, The diaphragm 131 may be a conical diaphragm installed in eight directions as shown in Fig. 7 (b). That is, the conical diaphragm prevents the plug 130, which is fastened to the upper end of the large-diameter pipe structure 110, from being pulled out of the large-diameter pipe structure body 110 at the time of transportation or embedding.

The pump 140 may be, for example, an underwater pump for discharging water or air inside the large-diameter steel pipe main body 110 to the outside, and water or air To be discharged to the outside.

6, the plug 130 and the pump 140 may be integrally formed, and an outlet 160 for discharging water or air may be formed between the plug 130 and the pump 140, respectively. Also, the plug 130 and the pump 140 integrally formed can be separated from the large-diameter steel pipe main body 110 and recovered after the large-diameter steel pipe main body 110 is erected at the excavation position.

6, the remote pump controller 170 is connected to the pump 140 through a power cable 180 and is installed in the barge line 300 to remotely control the pump 140. As shown in FIG. At this time, it is apparent to those skilled in the art that the pump 140 can be remotely controlled by the remote pump controller 170, and thus a detailed description thereof will be omitted.

Accordingly, the large-diameter steel pipe main body 110 can be upright at the excavation position of the foundation ground while the buoyancy and self-weight are controlled by the pump 140. [

 Specifically, the embedment-type large-diameter steel pipe file for offshore wind power generation according to the embodiment of the present invention is a mono-file type embedded large-diameter steel pipe file 100 in which a water inlet is formed, The pipe body 110 is horizontally transported to the excavation position of the foundation sheet as a foundation ground by using a barge and then the pump installed on the upper portion of the large diameter pipe structure body 110 140 adjusts the buoyancy and the weight of the large diameter pipe of the pipe body vertically at the excavation position of the large diameter pipe body 110. At this time, the large diameter pipe body 110 is vertically uprighted and the water inlet 120 So that the large-diameter steel pipe main body 110 can be upright at the excavation position.

8 is a view for explaining the use of a pump when carrying and embedding an embossed large-diameter steel pipe pile for offshore wind power generation according to an embodiment of the present invention.

8 (a), in the embedding-type large-diameter steel pipe file for offshore wind power generation according to the embodiment of the present invention, the pump 140 is provided with a conical plug 130 can be inserted to apply a negative suction that is not large enough to be transported. That is, the inlet port 120 at the lower end of the large diameter pipe body 110 is sealed using the inlet port 150, and the upper end of the large diameter pipe body 110 is sealed using the plug 130 The pump 140 can be used to lower the pressure in the large diameter pipe body 110 to prevent the conical plug 130 and the inlet stopper 150 from being dislodged.

8 (b), the pump 140 draws air or water from the large-diameter steel pipe main body 110 to lower the pressure in the large diameter pipe main body 110, So that the vertical installation of the large diameter steel pipe main body 110 can be induced.

As a result, according to the embodiment of the present invention, when the large-diameter steel pipe file for offshore wind power generation is transported to the excavation position of the foundation ground (the ground panel), the buoyancy and self weight of the large- It is possible to purchase and install a large diameter steel pipe file with a barge equipped with a simple crane without using a large jack-up barge or large equipment, thus reducing construction cost and air. In addition, the large-diameter steel pipe file can be easily erected at the excavation position while preventing the rapid inflow of water by the inlet formed at the lower end of the large-diameter steel pipe file. In addition, by using a pump-integrated plug in which a pump is fastened on a plug for sealing the upper end portion of a large-diameter pipe, the large-diameter pipe can be separated and recovered. Also, it is easy to carry large-diameter steel pipe files by sealing both ends of the large diameter steel pipe file with a plug and an inlet stopper and then transporting the same.

[Construction method of embankment type large diameter steel pipe file for offshore wind power generation]

FIG. 9 is a flowchart illustrating a method of embedding a buried large-diameter steel pipe file for offshore wind power generation according to an embodiment of the present invention. FIGS. 10a to 10e are views showing an embedding type large diameter steel pipe file for offshore wind power generation according to an embodiment of the present invention, And drawings for explaining the embedding construction method in detail.

Referring to FIGS. 4 and 9, the embedding type large diameter steel pipe file construction method for offshore wind power generation according to the embodiment of the present invention can be applied to a monofilament type offshore wind power generation embankment type large diameter steel pipe file for foundation ground excavation As a method of embedding in a site, first, a ground sheet as a foundation ground for installing a supporting structure for offshore wind power generation is excavated (S110). Specifically, as shown in FIG. 10A, a foundation foundation 200 for installing a support structure for an offshore wind power generator is excavated as shown by a reference A in FIG. Here, the buried large-diameter steel pipe pile for offshore wind power generation according to the embodiment of the present invention is buried after excavating the foundation ground. Here, the buried pile construction refers to a place where the large diameter steel pipe main body 110 is inserted And the large-diameter steel pipe main body 110 is sandwiched between the excavated positions. At this time, in case of the ground base sheet 200, which is the foundation ground, in the case of the sandy soil and the sandy soil, a casing can be installed and excavated to prevent the pore wall collapse.

Next, a large-diameter pipe body 110 having a water inlet 120 formed at its lower end is manufactured (S120), and a pump-integrated plug 130 and an inlet stopper 140 are fastened to both ends of the large- (S130). Specifically, as shown in FIG. 10B, a large diameter pipe body 110 having a water inlet 120 formed at its lower end is manufactured, and a pump-integrated plug 100 having a pump 140 coupled to the plug 130 and a pump- The inlet cap 150 is fastened to both ends of the large diameter pipe body 110 to seal the inside of the large diameter pipe body 110. [ Here, the pump-integrated plug 130 is formed such that a discharge port 160 for discharging water or air passes through the pump-integrated plug 130. The pump 140 may be remotely controlled by being connected to a remote pump controller 170 installed on the barge 300 through a power cable 180. Suction of a positive pressure may be provided to the inlet cap 150 by the pump 140 so that the inlet cap 150 is not released when the main body 110 of the large diameter pipe is transported.

Next, using the barge line 300, the large-diameter steel pipe pile 100 having the inside sealed up from the sea to the excavation position is transported in the horizontal direction (S140). Specifically, as shown in FIG. 10C, the embankment-type large-diameter steel pipe pile 100 having both ends closed is carried in the horizontal direction from the sea to the excavation position by using the barge line 300. At this time, the barge is a barge for carrying a crane, and the large-diameter steel pipe main body 110 can be buried in the excavation position. Accordingly, the large-sized pipe pipe can be installed and constructed with the barge 300 having the simple crane installed therein without using a jack-up barge or large equipment, which can reduce construction cost and air.

Next, the inlet cap 140 is removed from the large-diameter pipe body 110 and the buoyant force and the weight of the large-diameter pipe body 110 are adjusted by using a pump 132 (S150). 10D, after the inlet cap 150 is removed from the large-diameter capstan pipe body 110, the buoyant force and the weight of the large-diameter capstan pipe main body 110 are measured using the pump 140 Adjust while upright. That is, the buoyant force and the weight of the large diameter pipe body 110 can be adjusted by using the pump 140 so that water does not flow rapidly through the water inlet 120.

Next, the pump-integrated plug 130 fastened to the large-diameter steel pipe main body 110 is separated and collected (S160). Specifically, as shown in FIG. 10E, the pump-integrated plug secured to the large-diameter pipe structure 110 can be separated and recovered. At this time, the pump-integrated plug can be detached or mechanically detached by applying a positive pressure to the pump 140 so that the pump-integrated plug can be separated from the large-diameter pipe body 110 and recovered.

11 is a view showing an upper structure formed on a buried large-diameter steel pipe pile for offshore wind power generation according to an embodiment of the present invention.

As described above, after the embedded large-diameter steel pipe pile for offshore wind power generation according to the embodiment of the present invention is embedded at the excavation position of the foundation foundation, subsequently, as shown in Fig. 11, And an offshore wind power generator is installed by forming an offshore wind power generator superstructure 400 such as a tower, a nacelle, and a blade on the support structure.

In the embodiment of the present invention, the embedment-type large-diameter steel pipe file is embedded in the foundation structure for offshore wind power generation. However, the embedding-type large-diameter steel pipe file may be used in the embedding construction of the foundation structure for other sea structures.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Embossed large diameter steel pipe file
110: large-diameter steel pipe file body
120: Inlet
130: Plug
131: Diaphragm (Diaframe)
140: Pump
150: inlet cap
160: Outlet
170: remote pump controller
180: Power cable
200: foundation ground (or ground)
300: Barge
400: Offshore wind turbine superstructure

Claims (14)

In a large-diameter steel-pipe pile for offshore wind power generation of a mono-pile type,
A large-diameter steel pipe pile main body 110 which is buried in the excavated base pile;
An inlet 120 formed at the lower end of the large diameter pipe body 110 so that water does not flow rapidly during the filling of the large diameter pipe body 110;
An inlet cap (150) fastened to temporarily close the inlet (120) when the large diameter pipe body (110) is transported to the excavation position of the foundation foundation;
A plug 130 fastened to seal the upper end of the large diameter pipe body 110; And
A pump 140 coupled to the plug 130 to discharge water or air flowing into the large diameter pipe body 110,
, ≪ / RTI &
Wherein the large-diameter steel pipe main body (110) is upright at an excavation position of the foundation ground while the buoyancy and self weight are controlled by the pump (140). The method according to claim 1,
Wherein the inlet port (120) is formed to extend a predetermined length into the large-diameter pipe body (110) so that the water does not flow rapidly during the filling operation of the large-diameter pipe body (110) Recessed large diameter steel pipe file. The method according to claim 1,
And a remote pump controller 170 connected to the pump 140 through a power supply cable 180 and installed on the barge 300 to remotely control the pump 140. The embedding type large diameter steel pipe for offshore wind power generation file. The method according to claim 1,
Wherein the plug (130) and the pump (140) are integrally formed and an outlet (160) for discharging water or air is formed to penetrate the plug (130) and the pump (140) Recessed large diameter steel pipe file for power generation. 5. The method of claim 4,
Wherein the integrally formed plug (130) and the pump (140) are separated from the large-diameter steel pipe main body (110) and recovered after the large-diameter steel pipe main body (110) Recessed large diameter steel pipe file for power generation. The method according to claim 1,
Wherein the plug (130) is formed with a conical diaphragm (131) formed in eight directions from the center so that the large diameter pipe body (110) can withstand high pressure. file. The method according to claim 1,
The inlet cap 150 is connected to the inlet port 120 when the main body 110 of the large diameter pipe is transported and suctions of the positive pressure are provided by the pump 140 so that the inlet cap is not released Large diameter steel pipe file for embankment for offshore wind power generation. A method for embedding an embankment-type large-diameter steel pipe file for offshore wind power generation of a mono-file type at an excavation position of a foundation foundation,
a) excavating a foundation foundation for installation of a support structure for offshore wind power generation;
b) fabricating a large diameter pipe body 110 having a water inlet 120 formed at a lower end thereof;
c) a pump-integrated plug having a pump 140 coupled to the plug 130 and an inlet cap 150 are fastened to both ends of the large-diameter pipe file body 110 to form the inside of the large-diameter pipe file body 110 Sealing;
d) horizontally transporting the embankment-type large-diameter steel pipe pile 100 having both ends closed at sea to the excavation position by using the barge line 300;
e) removing the inlet plug 150 from the large diameter pipe file body 110 and using the pump 140 to adjust the buoyancy and weight of the large diameter pipe file body 110 while standing up; And
f) separating and collecting the pump-integrated plug fastened to the large-diameter steel pipe main body 110
A method of installing and embedding an embankment-type large-diameter steel pipe for offshore wind power generation. 9. The method of claim 8,
Wherein the pump-integrated plug of step c) is formed such that a discharge port 160 for discharging water or air passes through the pump-integrated plug. 9. The method of claim 8,
Wherein the pump 140 in the step c) is connected to the remote pump controller 170 installed on the barge 300 through the power cable 180 and is remotely controlled by the remote pump controller 170. The purchase of the buried large diameter steel pipe file for offshore wind power generation Construction method. 9. The method of claim 8,
The inlet port 150 of the step c) is characterized in that suction of the positive pressure is provided by the pump 140 so that the inlet port 150 is not released when the large diameter ported pipe body 110 is transported. A method of installing and embedding a large diameter steel pipe for embankment for offshore wind power generation. 9. The method of claim 8,
Wherein the buoyancy and self weight of the large diameter pipe structure body (110) are adjusted by using the pump (140) so that water is not rapidly introduced into the water inlet port (120) A method of installing and embedding large diameter steel pipe for embedding. 9. The method of claim 8,
Wherein the pump-integrated plug is detachably or mechanically detached from the large-diameter pipe body 110 by inserting a positive pressure into the pump 140 so that the pump-integrated plug can be separated from the large- Construction method of buried large diameter steel pipe for power generation. 9. The method of claim 8,
Wherein the barge in the step d) is a barge for a car equipped with a crane, wherein the large diameter pipe body 110 is embedded in the excavation position.

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