KR102014812B1 - Buoyant body for marine Structure - Google Patents

Abstract

The present invention relates to a buoyant body for an offshore structure, capable of maintaining constant buoyancy when being damaged. According to the present invention, the buoyant body for an offshore structure comprises: a buoyant pipe (10) independently formed in a plurality of watertight spaces (21) by a watertight partition (11) to provide buoyancy; a seawater bypass groove (20); a plurality of seawater passing holes (30); and a plurality of fixing rings (40) installed on one or both outer surfaces of the buoyant pipe (10).

Description

Buoyant body for marine structure

The present invention relates to a buoyancy body for offshore structures, and more particularly, the buoyancy body itself is formed of a watertight bulkhead and a tubular body having a fixing ring and a connecting ring formed therein, so that it can be installed without a separate connecting socket as well as when damaged. It relates to a buoyancy body for offshore structures that can maintain a constant buoyancy.

Floating structures floating on the sea are used for a variety of purposes.

Among them, the Buzan Bridge for berthing ships refers to the Buzan Bridge, a mooring facility built on the shore to dock ships, and the Taoism bridge that connects the land and the Buzan Bridge. It is widely used as part of a port facility by facilitating berthing of vessels regardless of the change of.

In addition, there is a cage farm that is installed at sea for the production of various marine products as a floating structure.

This floating offshore structure is installed on the sea to float in water using a buoyancy body made of a hollow tube having a hollow space therein.

In the case of the Buzan Bridge, for example, a hollow cylindrical buoyancy body made to float in water is laid on the water and the bottom reinforcement plate is made of reinforced concrete, steel plate, wood, and resin on it, so that the passengers can get on and off the cargo. have.

Since the Buzan Bridge is a buoyant body integrally formed and its upper part is completely enclosed by a top plate such as concrete, it has not only a heavy weight but also cannot be disassembled after assembly, making it difficult to install the Buzan Bridge by moving it through the land. there is a problem.

Therefore, it is common to provide a plurality of buoyancy pipes, and to install the buoyancy pipes to be connected to each other by a separate connection bracket, and to produce a Buzan bridge by combining a bottom reinforcing plate on the upper side of the connection bracket and the buoyancy pipe.

Examples of offshore structures such as buzan bridges made using connecting brackets include Patent Registration Nos. 14,448 (brackets for buoyancy bodies and Buzan bridges using them), and 1536278 (buoyant support holders for installing additional buoyancy bodies) Used marine floating structures), No. 1806193 (Marine floating structures with reduced rolling and improved stability) are disclosed.

However, the above-mentioned offshore structure has a problem in that the buoyancy body is integrally formed so that the offshore structure itself may sink due to leakage when partial breakage occurs in the buoyancy body.

In order to solve this problem, as in Patent Registration No. 1471014 (buoyancy pipe connecting socket for floating structures), a plurality of buoyancy pipes are connected and installed using a connection socket so that a certain buoyancy pipe can be maintained even if a part of the buoyancy pipe is damaged. The technique to do that was disclosed.

However, in the case of the above technology, it is possible to maintain a constant buoyancy, but it is necessary to provide a connection socket, which has a problem in that the structure is complicated, the production time is long, and the efficiency is not good.

In addition, the buoyancy body is easily shaken by sea water movement and waves as it is simply floating in sea water, and especially when the waves hit, the pressure acts directly, and thus the possibility of breakage (both end portions, bottom surface by shaking) Hole in the case of contact), as well as a problem that is severely shaken.

Korean Patent Publication No. 10-1471014 (As of December 3, 2014, buoyancy pipe connecting socket for floating structures) Korean Patent Publication No. 10-2012-0120679 (August 2, 2012, Floating Floating Structure with Buoyancy Preflection and Its Construction Method) Korean Patent Publication No. 10-1448948 (2014. 10. 1., Bracket for buoyant body connection and Buzan Bridge using the same) Korean Patent Publication No. 10-1806193 (December 1, 2017, marine floating structure with reduced rolling and improved resilience)

The present invention was devised to solve the above problems, and an object of the present invention is to produce a plurality of watertight spaces with a simple structure without using a separate connection socket by making a pipe body having a plurality of watertight bulkheads formed inside the buoyancy pipe. A buoyancy body having a shape can be formed, and by forming seawater wave grooves and seawater through-holes on both circumferential surfaces and both ends, a part of the waves introduced to both ends of the buoyancy pipe is broken and passed through the other part again to be secondary It is to provide a buoyancy body for offshore structures that reduces the force of the wave.

In addition, the present invention, when the non-slip plate is installed on the buoyancy tube upper surface of the buoyancy tube during the production of the non-slip plate by extrusion molding the non-slip plate is formed integrally with the buoyancy tube to provide a buoyancy body with a non-slip plate installed It is to provide a buoyancy body for offshore structures that can be easily manufactured.

Solution to Problem The present invention for achieving the above object is provided with a plurality of watertight bulkheads 11 at regular intervals along the longitudinal direction therein, the outer peripheral surface is fused to the inner surface is formed integrally, the watertight bulkhead 11 A plurality of watertight spaces 12 are independently formed by the buoyancy pipe 10 to provide buoyancy; It is formed as a groove of a predetermined depth from the end to the outermost watertight bulkhead 11 at both ends in the longitudinal direction of the buoyancy pipe 10, and through both ends of the buoyancy pipe 10 in a state in which the lower portion is locked in seawater. A seawater wave groove 20 which guides the wave introduced into the wave after hitting the outermost watertight bulkhead 11; The buoyancy pipe 10 is formed so as to communicate with the seawater wave groove 20 by passing through the buoyancy pipe on both sides in the longitudinal direction of the end portion of the buoyancy pipe 10, and a portion of seawater and waves introduced into the seawater wave groove pass through the buoyancy pipe 10. A plurality of seawater passing holes (30) for guiding to exit in the circumferential direction; A plurality of the outer surface or one side of the buoyancy pipe 10 is installed on a plurality of outer surface, passing through or coupling the connecting means 60, buoyancy pipe and buoyancy pipes arranged in parallel in the width direction connected to each other to fix or buoyancy pipe When the bottom reinforcing plate 51 is installed on the upper side of the buoyancy tube 10 and the bottom reinforcing plate 51 is connected to each other to fix the fixing ring 40;

'형상으로 형성된 것이 바람직하다.At this time, the buoyancy pipe 10 has a cross-section so that the lower portion has an arc '

It is preferred that it is formed in a 'shape.

Here, the buoyancy pipe 10, the watertight bulkhead 11 is introduced into the watertight bulkhead 11 at a predetermined interval in the extrusion process of the pipe forming the outer shape by fusion of the entire outer peripheral surface of the watertight bulkhead on the inner surface of the buoyancy pipe each watertight bulkhead. After forming a plurality of watertight spaces 12 are formed between the cut to the set length, but is produced by cutting to form the seawater wave groove 20 on both sides.

On the other hand, the upper surface of the buoyancy tube 10 is installed with a non-slip plate 50 made of a resin material, the non-slip plate 50 is integral with the buoyancy tube through extrusion molding on the upper surface of the buoyancy tube 10. It is preferable to form to be.

According to the buoyancy body for offshore structures having the above-described configuration, it is possible to provide a plurality of watertight spaces in the buoyancy pipe without the use of connecting sockets, making it easy to manufacture as well as simple structure, thereby significantly reducing the production cost There is.

In addition, as seawater wave grooves and seawater through-holes are formed on both sides and both sides of the buoyancy pipe, even if waves collide, they are effectively broken off, and some are escaped through seawater through-holes, and some are again broken through seawater wave grooves. The impact of the wave is reduced or canceled as it hits the wave, and the seawater moves smoothly while submerged in the sea, so that the flow can be kept more stably with the flow minimized, as well as the buoyancy pipe. It is effective to prevent breakage.

In addition, when the non-slip plate is installed on the upper surface of the buoyancy tube, the non-slip plate is formed integrally by extruding the non-slip plate in the manufactured buoyancy tube can be easily produced in a short time, and there is an effect that can reduce the production cost. .

1 is a perspective view of a buoyancy body for offshore structures according to the present invention,
2a is a cross-sectional view taken along line AA of FIG.
2b is a cross-sectional view of the watertight bulkhead fused in the 'T' type according to the present invention
3 is a cross-sectional view according to BB of FIG. 1,
Figure 4 is a connection state in the width direction of the buoyancy body for offshore structures according to the present invention,
5 is a longitudinal connection state of the buoyancy body for offshore structures according to the present invention,
Figure 6 is a state formed integrally by extrusion molding the anti-skid plate on the buoyancy pipe upper surface according to the present invention,
Figure 7 is a state diagram showing an embodiment of the Buzan bridge is installed buoyancy body according to the present invention.

Hereinafter, a buoyancy body for an offshore structure according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1 to 7, the buoyancy body for the marine structure according to the present invention is a buoyancy body to provide a buoyancy to float on the water to install the offshore structures, such as Bujan bridge or farm.

The buoyancy body is a buoyancy pipe 10 having a plurality of watertight spaces 12 formed therein, seawater wave grooves 20 formed on both sides in the longitudinal direction of the buoyancy pipe 10, seawater wave grooves 20 and Consists of the seawater passing through the hole 30 and the fixing ring 40 formed on the outer surface of the buoyancy pipe (10).

The buoyancy pipe 10 has a plurality of watertight bulkheads 11 are formed at regular intervals along the longitudinal direction to form a plurality of watertight spaces 12 therein.

The watertight partition wall 11 is preferably formed by introducing into the inside of the tube body forming the buoyancy pipe (10).

That is, in the extrusion process of the pipe forming the outer shape, the watertight bulkheads 11 are introduced into the inside at regular intervals so that the entire outer circumferential surface of the watertight bulkheads is fused to the inner surface of the pipe to form a plurality of watertight spaces between the watertight bulkheads ( 12) is to form a tubular body to be formed, so that the molded tubular body is cut to a predetermined length to produce a buoyancy tube (10).

Since a plurality of watertight spaces 12 are formed by the watertight bulkhead 11, even if a portion of the buoyancy pipe is flooded due to breakage, the buoyancy is maintained by the remaining watertight space, thereby preventing sinking. .

Here, the watertight partition wall 11 may have a cross-sectional shape of '┃' shape as shown in Figure 2a or 'T' shape as shown in Figure 2b.

When the watertight bulkhead 11 is formed in a 'T' shape, it is for reinforcing the upper portion of the buoyancy pipe 10, and when a considerable pressure is applied from the upper side of the buoyancy pipe, such as when a large load is loaded depending on the purpose. This is to prevent breakage of the buoyancy pipe.

As such, the watertight partition wall 11 may be provided in a form suitable for the purpose of the offshore structure to which the buoyancy body is applied.

The buoyancy pipe 10 may be manufactured in a transportable length (about 1m ~ length (m) according to the user's request), the watertight bulkhead 11 is the user's required interval (about 0.5 ~ according to the user's request) At intervals m), the buoyancy tube 10 may be provided to be fused.

The seawater wave groove 20 is formed at both ends of the longitudinal direction of the buoyancy pipe 10, and has a predetermined depth from the end to the outermost watertight bulkhead 11 for the introduction of seawater in a state of being installed at sea. It is formed as a groove, and is provided so that the lower portion is submerged in sea water.

The seawater wave groove 20 is a state in which the seawater is introduced into the lower portion of the seawater is prevented by the shaking of the buoyancy pipe 10 by the introduced seawater to minimize the flow of the buoyancy body to maintain a more stable floating state It will help you.

In addition, the seawater wave groove 20 is formed to a predetermined depth, when the wave is introduced into the seawater wave groove, the incoming seawater hits the outermost watertight bulkhead 11 and then is again broken out.

The seawater passing hole 30 is formed to communicate with the seawater wave groove 20 by penetrating the surface of the buoyancy pipe on both circumferential surfaces of the buoyancy pipe 10 in the longitudinal direction.

The seawater passage hole 30 is formed so that the lower portion of the buoyancy pipe 10, that is, the part submerged in the seawater, communicates through the seawater passage hole, so that the seawater introduced into the seawater wave groove minimizes the shaking of the buoyancy pipe 10. Rolling or shaking of offshore structures has the effect of minimizing or preventing seawater ripples.

In addition, when the wave hits both ends of the buoyancy pipe 10 formed with seawater wave grooves and seawater passing holes, the wave hits the circumferential surface of the buoyancy pipe formed with a plurality of seawater passage holes 30 formed with a plurality of waves introduced into the seawater wave grooves While being split, some are broken into small pieces as they pass through the seawater passing hole and exit in the circumferential direction of the buoyancy pipe, and some are again waved in the direction facing the seawater wave groove (the direction of the wave's inflow) and hit the secondary wave. By reducing or canceling the force (wave strength) of the wave to minimize the shaking of the offshore structure, there is an effect that can reduce the breakage of the buoyancy pipe that can be caused by the impact of the wave.

The fixing ring 40 is fixed to connect the buoyancy pipe and buoyancy pipes arranged in parallel in the width direction to each other, or to connect and fix the buoyancy pipe and the bottom reinforcing plate 51 installed on the upper side of the buoyancy pipe to each other. It is provided to give.

The fixing ring 40 may be formed in plural on both sides of the buoyancy pipe 10 or installed in plural only on one outer surface, and in the form of a ring in which the holes are formed in the up and down direction to pass or bind the connecting means. It is preferred to be provided.

When the fixing ring 40 is formed on both sides of the buoyancy pipe, the fixing ring may be formed on the same horizontal line on both sides of the buoyancy pipe, respectively, as shown in FIGS. 3 and 4 on both sides of the buoyancy pipe. Formed to cross each other at different heights are arranged parallel to each other when combined with the buoyancy pipes provided adjacent to each other can be such that the fixing ring installed in each buoyancy pipe is engaged with each other.

The connecting means may use a rope or bolt and nut.

At this time, the buoyancy pipe 10 needs to be interconnected in the longitudinal direction in addition to the interconnection in the width direction when manufacturing a relatively large offshore structure.

To this end, connecting rings 45 are formed on both outer surfaces of the buoyancy pipe 10 in the longitudinal direction. The connecting ring 45 has a ring shape formed with a hole in the left and right direction inside, it can be coupled to each other by connecting the adjacent buoyancy pipes using a connecting means such as a rope or a stainless bolt and a nut as described above.

The connecting ring 45 is formed so that two or more than one so as not to be easily separated in the connected state by the connecting means while maintaining a reduced connection state.

'형상으로 형성된 것이 바람직하다.And the buoyancy pipe 10 in the present invention is not limited to its shape, but the cross-section 'to have an arc shape in order to effectively install the bottom reinforcing plate 51 installed on the upper side while being less affected by sea water'

It is preferred that it is formed in a 'shape.

That is, in the past, while using a buoyancy tube made of a cylindrical body, each buoyancy tube is connected to a separate connecting bracket formed with a flat upper plate, and a buoyant body is formed by combining a bottom reinforcing plate such as a foot plate on the upper portion of the connecting bracket. In the present invention, in order to directly install a non-slip plate, such as a floor reinforcement plate or scaffold on the buoyancy pipe itself to form a buoyancy body flat on the top.

'형상으로 압출성형할 수 있기 때문에 가능한 것이다.The reason for this is because, in the present invention, the buoyancy pipe does not need to use a separate connecting bracket because the buoyancy pipe is formed by introducing the watertight partition 11 into the watertight space 11 to form the watertight space 12 during the extrusion process of the pipe. And also the cross section during

It is possible because it can be extruded into shape.

The bottom reinforcing plate 51 may be formed of any one material of reinforced concrete, steel plate, wood, resin material, such a floor reinforcing plate is made separately and then supported on the upper surface of the buoyancy pipe (10) Can be installed by assembling and assembling.

Of course, the top of the bottom reinforcing plate 51 may be used to further install a finishing plate according to the type of offshore structure.

On the other hand, in the present invention can be installed on the upper surface of the buoyancy tube 10, the non-slip plate 50 made of a resin material, in this case, the non-slip plate is directly extruded to the upper surface of the buoyancy tube and attached to the buoyancy tube It can be formed integrally.

The non-slip plate 50 to be extruded may be integrally formed along the longitudinal direction of the buoyancy tube 10 by extruding an area equal to or larger than the upper area of the buoyancy tube 10.

The anti-skid plate 50 can be installed when used alone without the combination of a separate floating structure, such as a cage farm, the bottom reinforcement plate 51 is the Buzan Bridge or offshore mooring facilities and offshore cargo loading facilities or barges When used in a structure such as, etc. are installed for the purpose of reinforcing the floor surface.

In the case of the bottom reinforcing plate 51 may be provided in a direction perpendicular to the buoyancy pipe for reinforcement.

In the present invention, the buoyancy pipe 10 is a watertight bulkhead 11 is inserted into the inside of the pipe during the extrusion molding process to produce a buoyancy pipe by cutting by a set length, the buoyancy pipe, cutting the buoyancy pipe by a set length In this case, it will be desirable to cut the middle portion of the watertight space 12 so that the seawater wave grooves 20 are formed on both sides thereof.

As such, there is an advantage in that the seawater wave groove can be easily formed through the process of cutting the pipe in which the watertight space is formed, which is possible because the extrusion forming the pipe forming the buoyancy pipe in the present invention.

Here, the space of the seawater wave groove 20 formed on both sides of the buoyancy pipe may be made smaller through additional processes such as further cutting both ends of the buoyancy pipe after cutting the pipe.

According to the present invention configured as described above, even if a plurality of watertight spaces are formed inside the buoyancy pipe, even if a portion is submerged by breakage, the sinking can be prevented as the buoyancy is maintained due to the remaining watertight space, and seawater passes through the seawater. Through the seawater into the seawater wave groove through the opening or the seawater into the seawater wave groove exits through the seawater passage hole, it is possible to maintain a stable floating state while minimizing the fluctuation of the buoyancy pipe. When the bumps are broken into small pieces and pass through the seawater passage hole, the breakage of the buoyancy pipes caused by the waves is prevented, but the phenomenon of rising of the waves hitting the buoyancy pipes does not occur.

10: buoyancy pipe 11: watertight bulkhead
12: watertight space 20: seawater wave groove
30: seawater passage hole 40: fixed ring
45: link 50: slipper plate
51: floor reinforcing plate 60: connecting means

Claims (6)

A plurality of watertight bulkheads 11 are provided at predetermined intervals along the longitudinal direction therein, and the outer circumferential surface is fused to the inner surface to be integrally formed, and the plurality of watertight spaces 12 are independently formed by the watertight bulkheads 11. A buoyancy pipe 10 for providing buoyancy;
It is formed as a groove of a predetermined depth from the end to the outermost watertight bulkhead 11 at both ends in the longitudinal direction of the buoyancy pipe 10, and through both ends of the buoyancy pipe 10 in a state in which the lower portion is locked in seawater. A seawater wave groove 20 which guides the wave introduced into the wave after hitting the outermost watertight bulkhead 11;
The buoyancy pipe 10 is formed so as to communicate with the seawater wave groove 20 by passing through the buoyancy pipe on both sides in the longitudinal direction of the end portion of the buoyancy pipe 10, and a portion of seawater and waves introduced into the seawater wave groove pass through the buoyancy pipe 10. A plurality of seawater passing holes (30) for guiding to exit in the circumferential direction;
A plurality of the outer surface or one side of the buoyancy pipe 10 is installed on a plurality of outer surface, passing through or coupling the connecting means 60, buoyancy pipe and buoyancy pipes arranged in parallel in the width direction connected to each other to fix or buoyancy pipe A fixing ring 40 for fixing the buoyancy pipe 10 and the bottom reinforcing plate 51 to each other when the bottom reinforcing plate 51 is installed at an upper side thereof;
Buoyancy body for offshore structures, characterized in that consisting of.
The method of claim 1,
For the offshore structure, characterized in that the connecting ring 45 is formed on the outer surface of both ends of the buoyancy pipe 10 in the longitudinal direction to connect the buoyancy pipe and the buoyancy pipe to each other in the longitudinal direction using the connecting means 60. Buoyancy body.
The method of claim 1,
The buoyancy pipe 10 has a cross section so that the lower portion has an arc shape.

Buoyancy body for offshore structures, characterized in that formed in the shape.
The method of claim 1,
The buoyancy pipe 10 is introduced into the watertight bulkhead 11 at a predetermined interval in the extrusion molding process of the pipe forming the outer shape by fusion of the entire outer peripheral surface of the watertight bulkhead on the inner surface of the buoyancy pipe between each watertight bulkhead. Buoyancy body for offshore structures, characterized in that the plurality of watertight space (12) is formed to cut the pipe formed to a set length, the seawater wave grooves 20 are formed on both sides.
The method of claim 1,
An upper surface of the buoyancy tube 10 is provided with a non-slip plate 50 made of a resin material, the non-slip plate 50 is integral with the buoyancy tube through extrusion molding on the upper surface of the buoyancy tube 10. Buoyancy body for offshore structure, characterized in that forming.
The method of claim 1,
The watertight bulkhead 11 is a buoyancy body for offshore structures, characterized in that the cross-sectional shape '형' type or 'T' shape for the upper reinforcement of the buoyancy pipe (10).

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