KR101694963B1 - Flexible structure for reducing Ocean wave - Google Patents

Abstract

[0001] The present invention relates to a flexible structure for reducing waves, comprising a support structure provided on a sea floor and an offshore wind turbine including a wind turbine installed on one side of the support structure, The flexible structure absorbs or disperses the impact generated by the waves to prevent the impact from being transmitted to the supporting structure and the floor of the seabed so that the entire structure of the offshore wind power system Stability can be achieved. In addition, by further including a net installed in a form of wrapping the entire outer circumference so as to provide a cage space on one side of the flexible structure, it is possible to efficiently utilize the unavailable space at the location where the offshore wind farm is installed, It is possible to utilize the natural resources around it efficiently.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a flexible structure for reducing wave,

The present invention relates to a flexible structure for reducing waves, and more particularly, to a flexible structure for reducing waves by providing a flexible structure on one side of a supporting structure provided on the sea floor, In addition to damping the force acting on the support structure, the flexible structure installed so that the shock generated by the wave, especially the waves generated in the sea, can not be transmitted to the ground absorbs the shock generated by the wave. The present invention also relates to a flexible structure for reducing a wave that allows cage formation in a cage space inside a mesh network provided with a mesh on one side of a flexible structure.

As the use of various resources is rapidly increasing in accordance with industrialization, development of resources such as crude oil and natural gas is becoming a very important problem. Recently, marine structures for exploration and drilling have been developed in the ocean, and exploration and mining works are being carried out for the production of various resources. Among these offshore structures, wind power generation is a new and renewable energy and has high efficiency and market competitiveness.

 Although the initial wind power is mainly developed on the land, wind turbines are becoming bigger, and due to various restrictions due to the place and noise, they are moving from land to sea and the offshore wind power is becoming the center. Such offshore wind power is one of the most promising renewable energy. It can generate high output for a long period of time with strong and constant wind power than onshore wind power, and can compensate for the disadvantages of existing onshore wind power such as noise, spatial limit, and landscape degradation.

In general, an offshore wind turbine is roughly divided into a wind turbine and a support structure. The wind turbine is a rotating mechanism that converts the kinetic energy of the wind into mechanical energy. The support structure supports the above- It is a structure that is installed on the ground and is divided into Concrete caisson type, Mono-pile type, Jacket type, Tripod type and Floating type. can do.

In such a conventional offshore wind power system, after the support structure is installed on the bottom of the sea floor as described above, a wind turbine is installed on the support structure. In this case, among the various factors that may occur in the sea, The impact caused by the wind waves on the surface of the sea and the wake caused by the waves to the other sea area greatly fluctuates the sea level and the fluctuation of the sea level wave pressure is transmitted to the bottom of the sea floor, The water pressure fluctuation is caused and the instability of the ground can be caused, and the stability of the entire offshore wind turbine installation has become a serious problem.

In addition, the conventional offshore wind power system is manufactured in a very large size with a limited space limit compared with the offshore wind power system, but it is used only for the offshore wind power system, which causes a lot of space and resources to be wasted.

Korean Patent Laid-Open Publication No. 2012-0002184 (published on Jan. 05, 2012), entitled "Offshore Wind Power Generation Device" Korean Patent Laid-Open Publication No. 2013-0039826 (Publication date: March 23, 2013), entitled "Support structure of an offshore wind power generator and method of installing the same" Korean Registered Patent No. 10-1164227 (Registered on Mar. 07, 03.), entitled "Offshore wind structure using steel pipe pile foundation and prefabricated structure"

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

A problem to be solved by the present invention is to provide a flexible structure on one side of a supporting structure provided on the sea floor so that the flexible structure absorbs or disperses impacts generated by waves, So that the generated impact can not be transmitted to the support structure and the floor of the seabed.

It is also an object of the present invention to provide a flexible structure on one side of a supporting structure, which is located at a predetermined distance from the ground so that the impact generated by the waves is located in the most severe position to absorb or disperse the impact.

In addition, a separate flexible structure is installed at a position spaced apart from the existing support structure so that the shock generated by the wave absorbing or dispersing the flexible structure can not be transmitted to the supporting structure and the floor of the seabed It has its purpose.

Further, it is an object of the present invention to provide a flexible structure in the form of a circular or polygonal plate to absorb or disperse the impact generated by the waves more easily.

In addition, the flexible structure may be formed to include a flexible portion and a rigid fixing portion, and the fixing portion may be provided so as to be spaced apart from the supporting structure so that the impact generated by the wave absorbed by the flexible portion is not transmitted to the fixing portion So that it can not be transmitted to the support structure.

Another object of the present invention is to prevent the flexible structure from being moved due to the movement of seawater through a connecting member provided on one side of the flexible structure and the other side disposed on the sea floor.

It is also an object of the present invention to provide a structure in which a plurality of connecting members are additionally provided so that the shock absorbed by the flexible structure can be absorbed or dispersed.

It is also an object of the present invention to provide a cage-style cage which can raise fish or aquatic organisms in the cage space by providing a mesh network that covers the entire outer circumference of the flexible structure so that a cage space is provided at one side of the flexible structure.

In order to accomplish the above object, the present invention provides a flexible structure for reducing waves, comprising: a support structure installed on a sea floor; an offshore wind turbine including a wind turbine installed on one side of the support structure; And can be achieved by a flexible flexible structure capable of absorbing or dispersing impact caused by waves.

According to an aspect of the present invention, there is provided a flexible structure for reducing waves, comprising: a support structure installed on a surface of a sea floor; and a flexible flexible member capable of absorbing or dispersing impact due to waves, Structure can be achieved.

And an offshore wind power system comprising a wind turbine installed on one side of the support structure.

It is preferable that the flexible structure is installed so as to surround the outer periphery of the supporting structure and that the impact generated by absorbing or dispersing the impact caused by the waves generated in the vicinity of the supporting structure is prevented from being transmitted to the supporting structure and the ground surface Do.

Preferably, the flexible structure is spaced apart from the bottom of the seabed so that the impact caused by waves generated in the sea is located in the greatest interval.

The flexible structure may include a soft flexible portion formed outwardly to absorb or disperse the impact generated by the waves, and a rigid fixed portion formed inwardly to prevent the impact from being further transmitted.

The flexible structure is installed such that the fixing portion surrounds the outer periphery of the supporting structure and the fixing portion is spaced apart from the outer periphery of the supporting structure such that the impact absorbed by the flexible portion is not transmitted to the supporting structure .

The flexible structure for reducing the wave may be configured such that one side of the flexible structure is detachably installed on one side of the flexible structure so that the flexible structure is prevented from moving due to the movement of the seawater, It is preferable to further include them.

A flexible flexible structure capable of absorbing or dispersing an impact caused by waves, and a flexible structure which is detachably installed on one side of the flexible structure so as to prevent the flexible structure from being moved due to movement of seawater, And a connecting member provided on the ground.

The connecting member may be detachably installed between the flexible structure and the bottom so that the impact absorbed by the flexible structure can be dispersed and absorbed.

It is preferable that the flexible structure for reducing the waves further includes a mesh network provided to surround the entire outer circumference so as to provide a cage space on one side so that a cage culture capable of raising fish or aquatic organisms in the cage space is possible .

As described above, the flexible structure for reducing waves according to the present invention has a flexible structure on one side of a supporting structure installed on the bottom of the sea floor, so that the flexible structure absorbs vibration caused by waves generated by waves, The impact is prevented from being transmitted to the support structure and the ground surface of the seabed so that the stability of the entire offshore wind power system installed on the sea floor can be maximized.

In addition, the flexible structure is positioned at the most severe impact generated by the wave, so that the impact generated by the wave can be remarkably reduced.

In addition, since a separate flexible structure can be installed at a position spaced apart from the support structure by a predetermined distance, even if a floating structure is installed in advance without considering the installation of the flexible structure, a separate flexible structure is installed around the flexible structure, It is possible to prevent the impact from being transmitted to the support structure and the ground surface of the seabed.

Further, the flexible structure is formed in the shape of a circular or polygonal plate material, so that the impact generated by the waves can be more absorbed or dispersed, thereby further reducing the impact.

Further, the flexible structure may be formed to include a flexible portion and a rigid fixing portion so that the flexible flexible portion absorbs or disperses the impact generated by the wave, but prevents the impact from being transmitted to the rigid fixing portion, And furthermore, it is possible to provide a stable effect of the entire offshore wind power system by preventing the stationary portion from being transmitted to the support structure even if a small impact is provided from the support structure.

In addition, by providing a connecting member between the flexible structure and the bottom of the sea floor, the flexible structure can be prevented from being floated due to the movement of the seawater, or being out of the specified range, thereby maximizing the efficiency of reducing the impact caused by the waves .

In addition, since a plurality of connecting members are additionally provided, the impact absorbed by the flexible structure can be dispersed and absorbed by the connecting member, the impact caused by the wave can be reduced more efficiently.

In addition, since a mesh network that surrounds the entire outer circumference of the flexible structure can be installed so that a cage can be formed on one side of the flexible structure, fish or aquatic life can be raised, thereby effectively utilizing the unavailable space at the location where the off- As well as being able to utilize the natural resources around, it is effective.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall perspective view of a flexible structure for reducing the wave of the present invention. FIG.
2 is a cross-sectional view of Fig.
Figure 3 is another embodiment of a flexible structure.
4 is a state of use in a state where a plurality of connecting members are installed.
5 is a state of use in which a mesh is provided in the flexible structure.
6 is an exemplary view showing a conventional offshore wind turbine installed on a sea floor.
Fig. 7 is a state of use in a state in which the flexible structure of the present invention is installed.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Unless defined otherwise, all terms herein are the same as the general meaning of the term as understood by one of ordinary skill in the art to which this invention belongs, and if the terms used herein conflict with the general meaning of the term Are as defined herein.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. .

Hereinafter, the structure of the flexible structure 100 for reducing the wave according to the present invention will be described in detail with reference to FIGS. 1 and 2. FIG. 1 is an overall perspective view of a flexible structure 100 for reducing waves, and Fig. 2 is a sectional view of Fig.

1 and 2, a flexible structure 100 for reducing waves according to the present invention includes a flexible structure 130 installed on an offshore wind power system 110 and an offshore wind power system 110 .

The offshore wind power system 110 may include a support structure 113 and a wind turbine 111.

The support structure 113 may be fixedly installed on the ground of the sea bed. More specifically, after a foundation construction in which the support structure 113 can be fixedly installed on the water surface of the sea below the surface of the sea where the water depth is low, one side of the support structure 113 is fixed to the foundation work, At this time, the support structure 113 may be vertically installed from the sea surface so that the other side is positioned at the sea beyond the sea surface. This is to cope with the problem that the support structure 113, which is the center of the offshore wind turbine 110, can be generated by various factors generated in the sea (a threat of stability due to vibration). In particular, the following flexible structure 130 is installed on one side of the support structure 113 in order to prevent the impact caused by the wave, and a detailed description will be given later.

Meanwhile, the supporting structure 113 according to the present invention should be construed to include all the structures that are fixed to the sea floor and support the sea structure. Preferably, the structure supporting the offshore wind power system 110 is suitable.

The wind turbine 111 may be fixedly installed on the other side of the support structure 113 located on the sea. At this time, separate power generators including the wind turbine 111 may be fixedly installed on the other side of the support structure 113. This is to ensure that the wind turbine 111 is installed at a certain distance from the sea surface so that the flow of wind is best. This allows the wind turbine 111 to more efficiently convert the kinetic energy of wind into mechanical energy.

The flexible structure 130 may be installed on one side of the support structure 113. This is to absorb or disperse the impact caused by the waves, especially the elements that may occur at sea, and a detailed description will be given later.

Here, the flexible structure 130 is preferably made of a material of ductility (a property that a metal material is not broken by a tensile force not less than an elastic limit but stretched and plastic deformation) A material having the same ductility material may be the material of the flexible structure 130 according to the present invention.

The flexible structure 130 may be installed to surround the entire outer circumference of the support structure 113. This is because the flexible structure 130 absorbs or disperses all of the impact caused by the waves generated in the vicinity of the support structure 113 so that the impact can not be transmitted to the ground surface of the seabed, So as not to be applied.

Here, the flexible structure 130 can absorb or disperse the shock because, when an impact caused by the wave, particularly among the elements that can be generated in the sea, occurs, the generated impact causes the seawater to vibrate. Since the flexible structure 130 installed to surround the entire support structure 113 is made of a flexible material, when the vibration is transmitted, the flexible structure 130 may be deformed accordingly, so that the vibration is not touched, In this case, the absorbed vibration is dispersed again, and the vibration is transmitted to the surroundings. As a result of this process, the transmitted vibration is significantly reduced, and the vibration can be dispersed to such an extent that vibration can not be felt.

The flexible structure 130 may be installed at a certain distance from the bottom of the supporting structure 113. More specifically, the flexible structure 130 may be spaced apart from the bottom of the supporting structure 113 by about 1 - 5 m. This is to maximize the efficiency by locating the flexible structure 130 in a region in which the impact generated by the above-described waves is most severely generated, thereby significantly reducing vibration due to impact. In order to utilize a space that can be formed between the bottom of the flexible structure 130 and the bottom of the sea floor due to the separation of the flexible structure 130, a detailed description will be given later.

The flexible structure 130 may be formed in a circular or polygonal plate shape. This can be any form as long as the user can arbitrarily change the shape of the flexible structure 130 to absorb or disperse the impact sufficiently to absorb or disperse the impact generated by the waves.

The flexible structure 130 may be formed of a flexible material as described above. However, as shown in FIG. 3, a flexible flexible portion 131 is formed on the outer side of the flexible structure 130, And a hard portion 133 of a hard material may be formed on the inner side. This is because vibrations caused by the impact generated at this time can be transmitted to the flexible flexible part 131 formed on the outer side and can be absorbed or dispersed when a wave impact is generated as described above, The vibration is not transmitted to the support structure 133 so that the vibration can not be transmitted to the bottom of the sea floor and the vibration can not be transmitted to the support structure 113 so that the safety of the entire offshore wind power system 110 is not threatened . It is also possible to prevent the vibration from being transmitted to the support structure 113 due to the rigid fixing part 133 and to prevent the vibrations from being transmitted due to the minute vibration even when the fixing part 133 is provided at a predetermined distance from the supporting structure 113 It may be prevented in advance by separating the fixing portion 133 and the supporting structure 113 from each other.

4, the flexible structure 100 for reducing waves according to the present invention is constructed such that one side is detachably installed on one side of the flexible structure 130 and the other side is fixed to the ground of the seabed The connection member 150 may be formed of a metal plate. This is to prevent the flexible structure 130 installed in the support structure 113 from being moved due to the movement of seawater.

Here, the connecting member 150 may be a wire formed by twisting a plurality of strands of steel wire together so as not to be broken even if the flexible structure 130 moves due to the movement of seawater.

Meanwhile, the connection member 150 is installed between the flexible structure 130 and the bottom of the sea floor. It is also possible to provide a plurality of connection members 150 at this time. This is because the flexible structure 130 absorbs the vibration transmitted by the impact generated by the waves. In order to distribute the vibration by dividing the vibration through the coupling member 150 when the absorbed vibration is dispersed, to be.

As shown in FIG. 5, the flexible structure 100 for reducing waves according to the present invention is an alternative embodiment, and the network structure 170 may be further included at one side of the flexible structure 130.

The mesh 170 is installed to surround the entire outer circumference of the flexible structure 130 and a separate cage space 171 may be provided inside the installed mesh 170. At this time, the cage space 171 may form a cage that can raise fish or aquatic creatures. This is to efficiently utilize natural resources and space that are not utilized in the place where the offshore wind power system 110 is installed.

Meanwhile, the flexible structure 100 for reducing the wave according to the present invention can be installed on one side of the support structure 113 as described above to reduce the wave, and also, as shown in FIG. 8, The flexible structure 130 may be separately installed at a position spaced apart by a predetermined distance from the flexible structures 130 and 113. At this time, the flexible structure 130 can be detachably fixed by the connecting member 150 as described above, and the mesh structure 170 that surrounds the outer periphery of the flexible structure 130 is installed to form the cage- You may. This is because not only the offshore wind turbine 110 installed in advance for installing the flexible structure 130 but also the surrounding of all the installed marine structures without considering the installation of the flexible structure 130 It is possible to reduce the number of waves by installing a flexible structure 100 for reducing the number of waves and to utilize space and natural resources that can not be utilized through the cage style.

 Therefore, as described above, the flexible structure 130 is installed on one side of the support structure 113, so that the flexible structure 130 absorbs or disperses the impact generated by the wave, Can be reduced, and the space and resources that can not be utilized can be utilized efficiently.

Hereinafter, the operation principle of the flexible structure 100 for reducing the wave of the present invention will be described in detail with reference to the drawings. FIG. 6 is an exemplary view showing a conventional offshore wind power system 110 installed on a sea floor, and FIG. 7 is a state of use in a state where a flexible structure 130 is installed on an offshore wind power system 110.

First, the conventional offshore wind power system 1 can be described below. As shown in FIG. 6, the support structure 2 is installed vertically from the sea surface so that one side of the support structure 2 is located above the sea surface and is located in the sea. Accordingly, the conventional support structure 2 can be fixedly installed on the floor of the sea floor, and separate power generation devices including a wind turbine can be installed on the fixed support structure 2.

However, the conventional support structure 2 is simply fixed to the bottom of the sea floor, but it is not provided with a separate apparatus and configuration, so that it suffers serious damage to the impact caused by the waves, particularly, generated from the sea. That is, as described above, when an impact is generated by the wave, the seawater is vibrated by the impact generated. The fluctuation of the wave pressure on the sea surface is transmitted to the bottom of the seabed so that the bottom of the seabed becomes unstable . This poses a serious problem in the stability of the support structure 2 fixed to the sea floor and can cause serious problems in a separate power generation device including the wind turbine installed in the support structure 2. [

Next, the offshore wind power system 110 in which the flexible structure 100 for reducing the wave of the present invention is installed can be described below. 7, the support structure 113 may be fixedly mounted on the ground of the sea floor. More specifically, the support structure 113 may be fixed to the sea floor below the sea surface of the sea, The supporting structure 113 is installed vertically to the sea surface so that the other side is positioned on the sea beyond the sea surface . Accordingly, the conventional support structure 113 can be fixedly installed on the floor of the sea floor, and separate power generation devices including the wind turbine 111 can be installed on the fixed support structure 113.

Next, a flexible flexible structure 130 is installed on one side of the support structure 113. Thus, according to the above description, in the prior art in which the flexible structure 130 is not provided, the vibration caused by the impact caused by the waves is transmitted to the floor surface where the support structure 2 is installed, However, in the present invention in which the flexible structure 130 is installed, the vibration due to the impact generated by the waves is transmitted to the flexible flexible structure 130 provided in the support structure 113 so that the flexible structure 130 absorbs the vibration Or disperse to reduce the wave. Therefore, the most effective effect is obtained in the stability of the support structure 113.

On the other hand, the flexible structure 130 is installed approximately 1 to 5 meters from the sea floor. Accordingly, since the flexible structure 130 can be installed at the position where the impact generated by the waves is most severe, the impact generated by the waves can be effectively and effectively reduced. Further, a space remaining in the lower portion of the flexible structure 130 can be efficiently utilized, and a detailed description will be given later.

Next, the flexible structure 130 installed on the support structure 113 and the connection member 150 detachable between the bottom surface of the sea bed are installed. Accordingly, since the support structure 113 is fixed to prevent the support structure 113 from moving due to the movement of the seawater, the flexible structure 130 is prevented from deviating from the designated range, thereby reducing the impact generated by the waves Efficiency can be maximized. At this time, since the flexible structure 130 is detachably installed, even if the flexible structure 130 is damaged due to a strong external force, the flexible structure 130 can be easily replaced and repaired.

Accordingly, in the offshore wind power system 110 in which the flexible structure 100 for reducing the waves according to the present invention is installed, the flexible structure 130 absorbs or disperses the impact generated by the waves, So that the stability of the entire offshore wind power system 110 can be improved.

In addition, the impact caused by the waves can be located at the most severe position, so that the impact caused by the waves can be more remarkably reduced.

In addition, since the flexible structure 130 is installed between the flexible structure 130 and the bottom of the sea floor to prevent the flexible structure 130 from being floated due to the movement of the seawater, or to be out of the specified range, The efficiency can be maximized.

In addition, since a plurality of connecting members 150 are additionally provided, the impact absorbed by the flexible structure 130 can be dispersed and absorbed by the connecting member 150, so that the impact generated by the wave can be reduced more efficiently There is also an effect.

The flexible structure 130 may be formed to include a flexible flexible portion 131 and a rigid fixed portion 133 so that the flexible flexible portion 131 absorbs or disperses the impact generated by the wave, It is possible to prevent the shock from being transmitted to the support 133 and prevent the impact from being transmitted to the support structure 113 as well as to secure the support 133 to the support structure 113, So that the stability of the entire offshore wind power system 110 can be improved.

Next, another embodiment of the offshore wind power system 110 in which the flexible structure 100 for reducing the wave of the present invention is installed can be described below.

First, as shown in FIG. 5, a mesh 170 is installed to cover the entire outer circumference of the flexible structure 130. Accordingly, a cage space 171 is provided inside the mesh 170. In this cage space 171, fishes or aquatic organisms can be stored in the cage space 171. Therefore, It is possible to efficiently utilize the unused space of the offshore wind turbine 110 and to utilize the natural resources efficiently.

Accordingly, since the offshore wind power system 110 having the flexible structure 100 for reducing the waves according to the present invention can form a cage on one side of the flexible structure 130, it is possible to utilize the position where the offshore wind power system 110 is installed In addition to being able to efficiently utilize the space that has not been available, it also has the effect of efficiently utilizing the natural resources around.

100: Flexible structure for reducing blue
110: offshore wind power unit 111: wind turbine
113: Support structure 130: Flexible structure
150: connecting member 170: mesh

Claims (10)

An offshore wind turbine comprising a support structure installed on the sea floor and a wind turbine installed on the support structure; A flexible structure disposed at a predetermined distance from the support structure and installed to surround the outer periphery of the support structure to prevent the impact caused by the waves generated around the support structure from being transmitted to the support structure; And a connecting member formed between the flexible structure and the sea floor to support the flexible structure,
The flexible structure
It is formed as a disk with a hollow that is horizontal to the sea floor. It prevents the impact of waves from being transmitted to the supporting structure and the bottom of the sea floor. It is formed to be spaced from the bottom of the sea by a certain distance, A flexible flexible portion for allowing the flexible portion to be positioned; And a rigid fixing part formed to extend from the inside of the flexible part by a predetermined length to block and disperse the vibration of the flexible part,
The connecting member includes:
Wherein the flexible structure is formed of a plurality of wires connected to the flexible portion at a plurality of points. delete delete delete delete delete delete delete delete delete

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