KR101932432B1 - Jacket leg-can, jacket structure therewith at soft soil seabed during offshore construction and construction method therefor - Google Patents

Abstract

The present invention relates to a jacket structure having a jacket leg can which can stably form a fixed end on a soft ground, can securely be constructed using a consolidation effect, and can protect the jacket leg, and a method of constructing the jacket structure. Wherein the jacket structure comprises: a hollow tube for receiving a lower end of the jacket leg into an upper portion of the jacket structure; The hollow tube is divided into an upper space (S1) and a lower space (S2) by a plate member formed on the inner surface of the hollow tube. The lower end of the jacket leg is fixedly coupled to the upper surface of the inner intermediate partition Inner side walls; And a restraining concrete filled in the upper space S1 of the inner middle partition wall and embedded in the jacket leg fixed on the upper surface of the inner middle partition wall.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a jacket leg can, a jacket structure having the jacket leg can, and a jacket structure having the jacket leg can,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a jacket leg can, a jacket structure having the same, and a construction method thereof. More specifically, the present invention relates to a jacket leg can which can stably form a fixed end on a soft ground, can be safely constructed using a consolidation effect, and can protect a jacket leg, a jacket structure having the jacket can, and a construction method thereof.

Generally, a wind turbine generator that generates electricity using wind is constructed so that a propeller (or a blade) is installed on a rotary shaft of a generator to generate power by using a rotational force generated by the rotation of the propeller by the wind.

Such a wind turbine generator is a device for converting wind energy into electric energy, and is usually composed of a propeller, a transmission, and a generator, and rotates a propeller of a wind turbine generator, and generates electric power by the rotation force of a propeller generated at this time.

Such a wind power generation system is easy to operate and manage because it is simple in construction 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, there is a demand for a safe installation method for a blade and a tower structure to be installed in a high position and a foundation structure to be installed in water.

On the other hand, offshore wind power generation structures are classified into turbines and foundations, and three types of construction of the foundation are as follows:

First, the concrete caisson type can be used at relatively shallow water depth of 6 ~ 10m because it is easy to make and install, and it can maintain its position by friction force between its own weight and the seabed ground.

Secondly, Mono-pile type is the most used type of offshore wind farm complex at present and can be installed at a depth of 25 ~ 30m.

Third, the jacket type is a type that is showing much interest in the present state of the offshore wind farm and can be installed at a water depth of 20 ~ 80m. This jacket type introduces a method of fixing the jacket structure to the sea floor with a pile.

1A, a platform 10 is provided at an upper end of a jacket type base (jacket structure), and a jacket leg 17 (see FIG. 1A), which is inclined to the lower end of the jacket structure, ).

In order to fix the jacket structure to the seabed ground, a pin pile (16), which is inserted inside the jacket leg (hollow tube type) and installed to the ground layer such as the rock under the underwater ground, is also constructed.

After the jacket structure is manufactured on land, the pin pile 16 is penetrated through the jacket leg 170 while being leveled by sinking into the sea by a marine crane or the like, .

However, as shown in FIG. 1A, when the installation position of the jacket structure is different from the initially designed position according to the undersurface top condition of the jacket structure, it is very difficult to level the jacket structure, that is, leveling operation. Especially, in soft ground, it is difficult to form a fixed end for installation, such as settlement and activity (sliding) of a jacket structure on the sea floor.

Conventionally, in a conventional offshore wind power generation structure, a mud mat is first applied to an underside of a jacket structure where a jacket structure is to be installed, and an appropriate supporting force is secured while performing leveling to level the jacket structure on the mud mat.

Such a mud mat is formed in the form of a water plate having a constant thickness and formed integrally with the jacket leg.

Fig. 1B shows the construction of such a conventional jacket leg 17 and a mud mat 18.

In other words, a mat mat 18 in the form of a waterproof plate is integrally formed around the lower end of the jacket leg 17 constituting the jacket structure,

The mud mat 18 can be leveled in the form of a support plate around the lower end of the jacket leg 17 in the vicinity of the bottom of the seabed so that the support force can be sufficiently secured It can be seen that it has the function of That is, the conventional mud mat 18 plays a role of preventing the jacket structure from slipping or sliding (sliding) during the installation of the jacket structure in the soft ground, thereby forming the fixed end.

Fig. 1C shows an example of the construction of the scour protection hole 5 around the conventional jacket leg 17. Fig. That is, when the jacket legs 17 are mounted on the seabed ground using the pin piles 16, the jacket legs 17 are located in the water, There is a necessity of maintenance by damage or the like.

Therefore, it can be seen that the bottom of the jacket leg 17 is constructed by using slag or the like to construct the scour protection hole 5 in an inclined manner. In fact, the scour protection hole 5 is inefficient in terms of construction, air and economy .

Also, in the rocky area, the jacket legs 17 are leveled by using the pin piles 16 by using the PAD concrete 30 similar to the mud mat 5.

FIG. 1D is a flowchart showing the construction of the jacket leg 17 using the pin piles 16 by using the conventional PAD concrete 30 in the rocky area.

That is, it can be understood that the PAD concrete 30 is installed on the seabed of the rocky area, the jacket leg 17 is mounted, and the jacket leg protection hole 40 is installed.

At this time, the PAD concrete 30 applied to the seabed ground is a preliminary work for leveling the seabed ground, and also fixes the movement of the jacket structure when the bottom of the jacket leg 17 is mounted and the pin pile 16 is hammered And serves as a fixed stage for securing verticality.

At this time, a support plate is attached to the bottom of the jacket leg of the jacket structure so as to be mounted on the upper part of the PAD concrete. Usually, since the height of the jack concrete legs does not coincide with the height of the pad concrete at four places, only one jacket leg is mounted on the pad concrete, In which a jacket structure is fixed and pin fins are inserted and fixed in a state in which a vertical degree is secured.

However, when the seabed ground is soft, such as the West Sea of Korea or the South Sea, due to the characteristics of the PAD concrete, the PAD concrete self-settlement and sliding (sliding) occurs, thereby playing a role of fixing the movement of the jacket structure It is difficult to fix the bottom of the jacket leg in the soft ground, so it takes a long time to use the mud mat or the installation work in the sea,

In addition, there is a problem that frequent damages such as cracks and dropouts occur in the pad crate and the protective concrete at the lower end of the jacket leg due to the vibration transmitted from the upper part of the offshore wind power generation structure.

Korean Patent No. 10-1645362 filed on Feb. 27, 2014, entitled " Supporting Structure for Offshore Wind Jacket Using PC House and Suction File " Korean Patent Publication No. 2014-107049 (Publication date: September 4, 2014), entitled "Method of Construction of Offshore Wind Power Structure" Korean Patent No. 10-0968341 filed on Jun. 10, 2008, entitled "Method of installing a jacket structure for an industrial facility using an AlShadi bare bit"

Accordingly, it is possible to form a fixed end on a jacket leg of a jacket structure without applying PAD concrete at the time of construction of the jacket structure in the soft ground, thereby making it possible to stably construct the jacket structure and drastically reduce the construction cost and construction period And a jacket structure having the same, and a method of constructing the same.

In addition, when used, it is possible to improve the vibration resistance due to the load transmitted from the jacket structure due to the restraining effect of the lower end of the jacket leg, and to use the jacket leg can also as a scour protection ball, And to provide a jacket structure and a construction method thereof.

According to an aspect of the present invention, there is provided a method of constructing a jacket structure having a jacket leg can, the method comprising: (a) a hollow tube for accommodating a lower end portion of the jacket leg inwardly; And a plate member formed on an inner surface of the hollow tube, the hollow tube being divided into an upper space (S1) and a lower space (S2), wherein a pin hole is formed at a central portion, ; Forming a jacket leg can including the jacket leg can in a land form so as to surround a lower end portion of the jacket structure of the jacket structure, (b) After the jacket leg can is lifted up from the jacket structure formed integrally with the lower end of the jacket leg, the jacket leg can of the jacket leg is inserted into the seam bottom G, Setting a fixed end by a consolidation effect while the ground is being filled, exposing an upper part of the jacket leg can to water; And (c) placing restrained concrete in an upper space (S2) of the inserted jacket leg can by filling the upper space (S2) of the jacket leg can with the jacket leg can And the lower ends of the jacket legs are fixedly coupled to the upper surface of the inner middle partition wall in advance, and the constraining concrete in the step (c) And a steel composite structure formed by a hollow tube formed of a steel material, so as to resist a vibration load transmitted to the jacket leg.

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Since the jacket structure having the jacket leg can according to the present invention and the construction method thereof can secure a proper supporting force for settlement and activity (sliding) even in a seabed ground where an appropriate supporting force such as soft ground can not be secured, It is possible to construct the jacket structure stably, but since it is not necessary to construct a separate conventional PAD concrete and scour protection ball, it is possible to prevent defects due to cracking after construction, and it is possible to perform safe and quick construction, It can be greatly reduced.

In addition, it is possible to secure the vibration resistance due to the load transmitted from the jacket structure during use, and to provide a jacket structure having a jacket leg can which is highly effective in durability and maintenance, and a construction method thereof.

FIG. 1A is a construction cross-sectional view and leveling diagram of a conventional jacket structure,
1B is a view showing the construction of a conventional jacket leg, a jacket structure using a mud mat,
1C is a view showing the construction of a conventional jacket leg, a pin file, and a jacket structure using a scour protection ball,
1D is a view showing a construction sequence of a jacket structure using PAD concrete in a conventional rocky area,
FIGS. 2A and 2B are perspective views of a jacket leg can according to the present invention and a perspective view of a jacket structure having a jacket leg can,
FIGS. 3A, 3B and 3C are flowcharts of a method of constructing a jacket structure having a jacket leg can according to 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. Also, the term "part" or the like, as described in the specification, means a unit for processing at least one function or operation, and may be implemented by hardware or software or a combination of hardware and software.

[A jacket structure 200 having a jacket leg can 100 and a jacket leg can 100]

FIGS. 2A and 2B are perspective views of a jacket leg can 100 of the present invention and a perspective view of a configuration of a jacket structure 200 having a jacket leg can 100.

First, the jacket leg can 100 according to the first aspect of the present invention may be a housing member for covering and reinforcing the lower end of the jacket leg 210 constituting the jacket structure 200.

In FIG. 2A, although it is formed in the form of a round steel pipe, it can be formed in various cross-sectional shapes.

As shown in FIG. 2A, the jacket leg can 100 includes a hollow tube 110, an inner intermediate partition wall 120, and a constraining concrete 130.

It can be seen that the hollow tube 110 is formed to have a constant height as a hollow tube member and accommodates the lower end portion of the jacket leg 210 of the jacket structure 200 inside the upper portion. A steel hollow tube having a larger diameter than the diameter of the jacket leg 210 may be used.

The inner middle partition wall 120 is a plate member horizontally formed on the inner side of the center of the hollow tube 110 and has a pin hole 121 formed at a central portion thereof so that the lower end portion of the jacket leg 210 is inwardly And is fixedly coupled to the upper surface of the intermediate partition 120.

In this case, the jacket leg 210 is integrally coupled to the lower end of the jacket leg can 100. For this purpose, a connecting plate (not shown) such as a gusset plate is formed on the bottom surface of the jacket leg 210, So that it is simply fixed in advance by bolt coupling to the upper surface of the base plate 120.

At this time, in order to allow the pin pile 300 inserted into the jacket leg 210 to pass through the pin hole 121 of the inner intermediate partition wall 120 and extend downwardly of the jacket leg can 100, .

The restrained concrete 130 is filled in the upper space S1 of the inner intermediate partition wall 120 in a state where the jacket leg 210 is integrally coupled to the lower end of the can leg leg can 100 so that the jacket leg 210 is buried The lower end of the jacket leg 210 is formed of a steel composite structure formed of a hollow tube 110 formed of concrete and steel and serves to resist a vibration load transmitted to the jacket leg 210 .

It can be seen that the jacket leg can 100 can prevent the jacket leg 210 from being damaged by securing the vibration resistance, thereby enabling safe use of the jacket structure.

Accordingly, the jacket leg can 100 can be stably inserted into the seabed ground G such as a soft ground by self weight of the jacket structure 200 and suction if necessary.

As shown in FIG. 2B, the jacket structure 200 having the jacket leg can 100 formed at the lower end of the jacket leg 210,

Since the jacket leg can 100 is inserted into the seabed G by covering the lower end of the jacket leg 210, the jacket leg can 100 is attached to the bottom of the seabed so that the jacket leg can It can be seen that it acts as a fixed end of the leg 210.

That is, when the seabed ground G is the soft ground, the space S2 under the inner intermediate partition wall 120 of the jacket leg can 100 is inserted (intruded) into the soft ground so that the lower space S2 It is possible to secure the bearing capacity of the soft ground by the consolidation effect and to be an effective fixed stage to resist the settlement and the activity, and it can be formed as a simple support plate in the form of a horizontal plate without covering the soft ground Which is a major difference compared to the conventional mud mat 180.

Also, the jacket leg can 100 itself acts as a scouring protection hole at the lower end of the jacket leg 210 to protect and reinforce the jacket leg 210, thereby making it possible to construct a jacket structure 200 that is safe and maintenance- do.

Since the upper space S1 on the inner intermediate partition wall 120 is filled with the restrained concrete 130 as described above, it is possible to resist the vibration transmitted from the jacket leg 210 during use, and thus a safe jacket structure can be used .

Further, since the jacket leg can 100 is not fixed in water but is fixedly installed at the lower end of the jacket leg 210 in the spot or the like in advance, the jacket leg can 100 also serves as a support fixing stage for leveling, . ≪ / RTI >

[Method of constructing the jacket structure 200 having the jacket leg can 100]

FIGS. 3A, 3B and 3C show a flowchart of a construction method of a jacket structure 200 having a jacket leg can 100 according to the present invention.

First, as shown in FIG. 3A, the jacket structure 200 is manufactured in advance to include a jacket leg 210 formed to extend obliquely to the lower end of the platform, and is manufactured on the land, is mounted on a maritime work line, and is transported by sea.

At this time, the jacket leg can 100, which has been described above, is installed at the lower end of the jacket leg 210. In the assembling and installation, the upper end of the inner intermediate partition wall 120 of the jacket leg 210 on the land or sea operation line is fastened with bolts and nuts by using a connecting plate or the like not shown at the lower end of the jacket leg can 100 It is desirable to install it for a quick operation.

Thus, the jacket structure 200 in which the jacket legs 210 are assembled is moved to a position where the jacket structure 200 is mounted on the maritime operation line.

Next, as shown in FIG. 3B, after the jacket structure 200 is lifted by using the double-walled apparatus provided on the maritime work line moved to the position to be installed, the jacket leg 210 can contact the seabed ground G .

The jacket leg can 100 of the jacket leg 210 is inserted into the seabed ground G. This uses the self weight of the jacket structure 200 itself and the suction if necessary, (Referred to as "charging") while the ground subsurface soil equivalent is pushed into the subsea (S2).

In this case, the soil (S2) is subjected to the action of pressure so that the soil can be effectively pushed in more effectively by the pressure due to the vacuum state. And it is possible to improve the settlement of the fixed end and the resistance to the action.

The jacket structure 200 is inserted into the bottom seam G of the jacket leg can 100 so that when the seam bottom sand is pushed into the lower space S2 of the jacket leg can 100 and acts as a fixed end, The upper part is exposed to the upper part of the sea so that a stable jacket structure 200 can be constructed.

3C, the pin pile 300 is inserted into the jacket leg 210 of the jacket structure 200 so that the pin pile 300 passes through the pin pile hole 121 of the jacket leg can 100 So that the jacket structure 200 can be finally fixed to the bottom of the seabed by the pin pile 300 so as to extend downwardly of the jacket leg can 100. At this time, the vertical level of the jacket structure 200 is adjusted together to perform the leveling operation.

The pin pile 300 is finally extended to the rock bottom of the bottom of the seabed so that the jacket leg can 100 is finally supported by the pin pile 300 extending in the rock layer. .

When the fin pin construction is completed, the constrained concrete 130 is placed in the upper space S2 of the jacket leg can.

The combined jacket leg can 100 having the restrained concrete 130 placed in the upper space S2 improves the load resistance of the concrete by the restraining effect of the hollow tube.

Accordingly, when the jacket structure 200 is used, the vibration resistance of the jacket leg 210 is improved to prevent damage to the jacket leg such as cracks and dropouts, and it can be utilized as a scour prevention device around the jacket legs. It becomes more effective in maintenance.

It is understood that the jacket structure 200 can be constructed as a foundation of an offshore wind power generation structure, but it is natural that the jacket structure 200 can also be used as a foundation structure to be installed on the seabed ground.

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: Jacket leg can
110: hollow tube
120: inner intermediate partition
121: Pin file hole
130: constrained concrete 200: jacket structure
210: Jacket legs
300: Pin File
S1: Upper space of the jacket leg can
S2: Lower space of the jacket leg can
G: Submarine ground

Claims (11)

(a) a hollow tube 110 for receiving the lower end of the jacket leg 210 to the upper inside thereof; And a plate member formed on an inner surface of the hollow tube 110 to divide the hollow tube into an upper space S1 and a lower space S2 and having a pin hole 121 formed at a central portion thereof, And an inner middle partition wall (120) fixedly coupled to the upper surface of the jacket leg can 100. The jacket leg can 100 is fabricated on the land so as to surround the lower end of the jacket structure of the jacket structure,
the jacket leg can 100 of the jacket leg 210 is inserted into the seabed ground G after the jacket leg can 100 is lifted up from the jacket structure 200 formed integrally with the lower end of the jacket leg 100. [ So that the bottom of the jacket leg can 100 is filled with the bottom of the seabed so that a fixed end of the jacket leg can 100 is formed by the consolidation effect. And
(c) placing and placing restrained concrete 130 in the upper space S2 of the inserted jacket leg can,
In the step (a), the lower end of the jacket leg 210 is assembled on the upper surface of the inner intermediate partition wall 120 of the jacket leg can 100 by using bolts and nuts, The lower end of the jacket leg 210 is fixedly coupled to the upper surface of the inner middle partition wall 120 and the restrained concrete 130 of the step (c) And a jacket leg can is formed in a steel composite structure by the jacket legs so as to resist a vibration load transmitted to the jacket legs. The method according to claim 1,
Between step (b) and step (c)
The pin pile 300 inserted into the jacket leg 210 passes through the pin pile hole 121 of the inner middle partition wall 120 and extends downwardly of the jacket leg can 100, The method comprising the steps of: providing a jacket leg can comprising a jacket leg can. The method according to claim 1,
Wherein the jacket structure having the jacket leg can is formed as a foundation of an offshore wind power generation structure divided into a turbine and a foundation. (a) a hollow tube 110 for receiving the lower end of the jacket leg 210 to the upper inside thereof; And a plate member formed on an inner surface of the hollow tube 110 to divide the hollow tube into an upper space S1 and a lower space S2 and having a pin hole 121 formed at a central portion thereof, And an inner middle partition wall (120) fixedly coupled to the upper surface of the jacket leg can 100. The jacket leg can 100 is fabricated on the land so as to surround the lower end of the jacket structure of the jacket structure,
the jacket leg can 100 of the jacket leg 210 is inserted into the seabed ground G after the jacket leg can 100 is lifted up from the jacket structure 200 formed integrally with the lower end of the jacket leg 100. [ So that the bottom of the jacket leg can 100 is filled with the bottom of the seabed so that a fixed end of the jacket leg can 100 is formed by the consolidation effect. And
(c) placing and placing restrained concrete 130 in the upper space S2 of the inserted jacket leg can,
In the step (a), the lower end of the jacket leg 210 is assembled on the upper surface of the inner intermediate partition wall 120 of the jacket leg can 100 by using bolts and nuts, And a lower end of the jacket leg can is previously fixedly coupled to an upper surface of the inner middle partition wall 120. The jacket structure having the jacket leg can has a jacket leg 210, A hollow tube 110 for receiving a lower end portion of the hollow tube 110; The hollow tube 110 is divided into an upper space S1 and a lower space S2 by a plate member formed on the inner surface of the hollow tube 110. The lower end of the jacket leg 210 is formed with a pin- An inner intermediate partition wall 120 fixedly coupled to the upper surface; And a restraining concrete (130) filled in the upper space (S1) of the hollow tube (110) and formed so that a jacket leg (210) fixed to the upper surface of the inner middle partition wall (120) is embedded and constrained, The concrete 130 has a jacket leg 210 that forms a steel composite structure by a hollow tube 110 formed of concrete and steel and serves to resist a vibration load transmitted to the jacket leg 210, A jacket structure with a can. delete delete delete delete delete delete delete

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