WO2015163618A1

WO2015163618A1 - Buoyant pipe connecting socket for offshore floating structure

Info

Publication number: WO2015163618A1
Application number: PCT/KR2015/003659
Authority: WO
Inventors: 안원균
Original assignee: 안원균
Priority date: 2014-04-24
Filing date: 2015-04-13
Publication date: 2015-10-29
Also published as: JP6279147B2; KR101471014B1; JP2017513774A

Abstract

The present invention relates to a buoyant pipe connecting socket for an offshore floating structure and, more specifically, to a buoyant pipe connecting socket for an offshore floating structure that interconnects a plurality of buoyant pipes coupled to a bracket that is an offshore floating structure, and enables a buoyant force to be uniformly maintained even if the offshore floating structure is flooded due to damage to the buoyant pipes. The buoyant pipe connecting socket for an offshore floating structure, according to the present invention, which longitudinally interconnects a plurality of buoyant pipes that are coupled through a bracket having a plurality of footholds coupled to the upper portion thereof and provide a buoyant force in order to float the bracket on the sea water, comprises: a hollow body having the same diameter as the buoyant pipes; and watertight partition walls formed in the center of the interior of the body to partition the interior of the body into a plurality of buoyant spaces.

Description

Buoyancy Pipe Connection Socket for Offshore Floating Structures

The present invention relates to a buoyancy pipe connecting socket for floating structures, and more particularly, it connects a plurality of buoyancy pipes coupled to a bracket that is a floating structure to function as a water barrier bulkhead, even when flooded due to damage of the buoyancy pipe It relates to a buoyancy pipe connecting socket for offshore floating structures that can maintain a constant buoyancy by the partition function so that it is not sunk or liberated.

In general, Bujan Bridge, aquaculture farms, marine leisure facilities, marine fishing, marine work vessels, sofas, bridges (Taokyo), etc. are injured using a separate float, such a float is fixed by a separate fixing means. Fixing means for fixing the floats is made of a variety of structures in the characteristics of the floats.

In particular, styrofoam and buoyancy pipes are used to maintain buoyancy by trapping creatures using nets in large spaces of the sea cage farms to keep them buoyant. Styrofoam is a major cause of serious pollution of the marine environment. According to environmental regulations, the establishment of wooden cage farms using styrofoam is prohibited in Korea.

Due to the above problems, recently, polyethylene (PE), preferably medium-density polyethylene (MDPE), which is very excellent in corrosion resistance, mechanical strength, and recyclability, and easily adhered and assembled by a heat fusion method. It is being replaced by a floating structure composed of buoyancy pipes and brackets using high density polyethylene (HDPE).

One example of such a technique is disclosed in Document 1 below.

In Patent Document 1, buoyancy pipes are supported in a lower hole, and in the buoyancy pipe coupling for offshore structures that are configured to couple the scaffold members on the upper surface, repair between buoyancy pipes supported by adjacent couplings coupled to each other. In the coupling, one hole for supporting one buoyancy pipe is formed in the lower part of which both sides are inclined so that the space is accessible for maintenance, and the lower end is inclined toward the hole, and the upper scaffold members and the buoyancy pipes are provided. It is composed of a lattice structure to increase the spacing between, and a protrusion is formed on one side to provide a vertical support force for the adjacent coupling coupled to the side, while the other side is cylindrical to engage with the protrusion of the adjacent coupling Disclosed is a pipe coupling for an offshore structure in which the part is integrally formed.

Therefore, the conventional technology configured as described above maintains large buoyancy pipes at regular intervals and at the same time improves stability of the large offshore structure, and can secure the maximum spacing between buoyancy pipes at the same time. Bracket) There is an advantage that the operator can facilitate the maintenance work for buoyancy pipes that are maintained in the water by increasing the interval between the scaffold members assembled on the upper surface.

However, in the conventional technology as described above, by assembling a plurality of buoyancy pipes continuously and integrally using a cylindrical connection unit, buoyancy maintenance function as the buoyancy space of the buoyancy pipe is flooded due to damage of the connection unit by waves or the like. There was a problem of losing.

In addition, there is a problem that the pipe coupling (bracket) for the floating structure of the floating structure, the ductility value of the buoyant agent and the fixed structure of the bracket by the rolling is out of position.

An object of the present invention is to solve the problems as described above, by forming a watertight bulkhead in the connection socket connected between a plurality of buoyancy pipes, even if the buoyancy space is flooded by the breakage of the buoyancy pipe, the remaining buoyancy It is an object of the present invention to provide a buoyancy pipe connecting socket for floating structures that allows the space to be kept tight so that the buoyancy pipe can maintain its buoyancy function.

In addition, an object of the present invention is to provide a buoyancy pipe connecting socket for a floating buoyant structure that can block the separation and movement after the assembly of the buoyancy pipe and the coupling (bracket), which is a basic structural skeleton of the floating buoyant structure.

In order to achieve the above object, the buoyancy pipe connecting socket for floating structures according to the present invention has a plurality of buoyancy pipes that are buoyantly coupled to a bracket having a plurality of scaffolds coupled thereon to provide buoyancy to float the brackets at sea. A connecting socket for connecting to each other in the longitudinal direction, characterized in that it comprises a hollow body having a diameter equal to the diameter of the buoyancy pipe, and a watertight partition wall formed in the inner center of the body to partition into a plurality of buoyancy spaces. .

As described above, the buoyancy pipe connecting socket for floating structures according to the present invention is connected to the buoyancy pipes by connecting the connection socket that integrates the watertight bulkheads inside the buoyancy space even if the buoyancy space is submerged by the breakage of the buoyancy pipe. The watertightness keeps the buoyancy to prevent sinking, while being connected to the end of the buoyancy pipe to perform a function as a closing cap.

In addition, there is an effect of preventing the separation due to the rolling of the coupling (bracket), which is a structure forming the buoyant agent and the floating structure of the sea, and the function of the connecting device of the connecting material.

1 shows a general marine floating structure.

Figure 2 is a perspective view showing a buoyancy pipe connecting socket for offshore floating structures according to the present invention.

Figure 3 is a cross-sectional view showing a buoyancy pipe connecting socket for offshore floating structures according to the present invention.

Figure 4 is a cross-sectional view showing another example of the watertight bulkhead which is a component of the buoyancy pipe connecting socket for floating structures according to the present invention.

Figure 5 is a perspective view showing a connection state of the buoyancy pipe connecting socket for floating structures according to the present invention.

Figure 6 is a plan view showing an installation state of the buoyancy pipe connecting socket for floating structures according to the present invention.

The buoyancy pipe connecting socket for floating structures according to the present invention is connected to each other in the longitudinal direction through a plurality of buoyancy pipes that are penetrated through the bracket coupled to a plurality of scaffold on the top to provide buoyancy to float the bracket on the sea. As a connecting socket for the, characterized in that it comprises a hollow body having a diameter equal to the diameter of the buoyancy pipe, and a watertight partition wall formed in the inner center of the body to partition into a plurality of buoyancy space.

In addition, the outer center of the body is characterized in that the separation prevention jaw for preventing the separation of the bracket is formed.

In addition, the watertight partition wall is characterized in that formed integrally with the same material as the body.

In addition, both sides of the watertight bulkhead is characterized in that the reinforcement protrusions are formed to protrude to a certain thickness so as to butt fusion when connected to other structures to reinforce the fastening strength of the bolt.

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

1 is a view showing a general offshore floating structure, Figure 2 is a perspective view showing a buoyancy pipe connecting socket for offshore floating structures according to the present invention, Figure 3 is a buoyancy pipe connecting socket for offshore floating structures according to the present invention 4 is a cross-sectional view showing another example of the watertight bulkhead which is a component of the buoyancy pipe connecting socket for offshore floating structures according to the present invention, and FIG. 5 is a buoyancy pipe connecting socket for offshore floating structures according to the present invention. Figure 6 is a perspective view showing a connected state, Figure 6 is a plan view showing an installation state of the buoyancy pipe connecting socket for the floating structure according to the present invention.

As shown in FIG. 1, a conventional marine floating structure includes a bracket 1 made of polyethylene and a buoyancy pipe 2 penetrated to the bracket 1 to reduce the weight.

The bracket 1 has a through-hole formed so that one buoyancy pipe 2 is coupled through the lower portion, and is formed in an inverted triangle shape inclined downward so that it can be easily floated at sea and always maintain its center.

Since the bracket 1 may be coupled to each other in the lateral direction to support the plurality of buoyancy pipes 2 to form a structure, the same brackets 1 may be combined laterally with respect to various sizes of the structure to be assembled easily and quickly. Can be.

The buoyancy pipe (2) is a hollow body inside is preferably made of synthetic resin such as polyethylene.

Since the bracket 1 and the buoyancy pipe 2 are commonly used marine floating structures, detailed description thereof will be omitted.

As shown in Figures 2 and 3, the buoyancy pipe connecting socket (3) for offshore floating structures according to the present invention is coupled through the bracket (1) to which a plurality of scaffold is coupled on the top of the bracket (1) It is to include a body 31 and a watertight partition 32 to connect the plurality of buoyancy pipes (2) to each other in the longitudinal direction to provide a buoyancy to float in the.

The body 31 is a hollow body made of synthetic resin such as polyethylene and has the same diameter as the diameter of the buoyancy pipe (2).

The body 31 is preferably manufactured in various standards to correspond to the standard of the buoyancy pipe (2).

On the other hand, at the outer center of the body 31, the separation prevention jaw 311 for preventing the separation of the bracket (1) is formed. The separation prevention jaw 311 is formed at regular intervals along the circumferential direction of the outer circumferential surface of the body 31, the existing coupling due to the impact of typhoons or severe waves in the state in which the buoyancy pipe (2) is coupled to the bracket (1) It serves to fix the position so that the bracket (1) is not separated from the position.

The watertight partition wall 32 is formed in the inner center of the body 31 is partitioned into a plurality of buoyancy space, it may be formed of one or more than one.

The watertight partition wall 32 is preferably formed integrally with the same material as the body 31. The reason is that the same conditions and environment should be formed due to the characteristics of polyethylene, which is the same material as the body 31, so that the success rate of fusion is high and the partition installation environment is easy and the fusion success is perfect.

More specifically, the watertight partition wall 32 is characterized in that the same material as the high ductility value of polyethylene is fused only under the same conditions, so that even if the buoyancy space is submerged by the breakage of the buoyancy pipe 2, the remaining buoyancy space is The watertightness can prevent the sinking by maintaining buoyancy, but in the case of preparing a separate diaphragm instead of an integral body and attaching it to the inside of the body through an adhesive, the diaphragm can be easily separated and detached as a watertight bulkhead while leaving the diaphragm. It will not function.

As shown in FIG. 4, both sides of the watertight bulkhead 32 are protruded to a predetermined thickness so as to allow butt fusion upon connection with other structures, and a reinforcement protrusion 321 may be formed to reinforce the fastening strength of the bolt. Can be.

One side of the reinforcement protrusion 321 is coupled to the lifting ring 4 of the semi-circular arc shape to facilitate the lifting of the marine floating structure.

On the other side of the reinforcement protrusion 321, a plurality of nut insertion grooves 321a are formed so that the nut is inserted and fastened to the bolts, and the nut insertion grooves 321a are filled with melted synthetic resin in a state where the nut is fastened. desirable.

The lifting ring 4 is integrally formed with the fixing plate 41 fixed to one side of the reinforcement protrusion 321 by bolt fastening. At this time, the head of the bolt is inserted and fixed to the fixing plate 41 and the screw portion is fixed through the reinforcing protrusion 321 and the watertight bulkhead 32 to secure the lifting ring (4) to the reinforcing protrusion (321) by fastening with a nut. Let's do it.

As such, by forming a reinforcement protrusion 321 thicker than the thickness of the watertight partition wall 32, the fastening strength of the bolt and nut, which is a fastening member, is coupled when the lifting ring 4 is coupled.

As shown in Figure 5, the buoyancy pipe connecting socket (3) for the floating structure of the marine floating structure according to the present invention is applied to the construction of the Bujan Bridge, fish farms, marine leisure facilities, marine fishing, marine work vessels, sofas, pedestrian bridge (Taokyo) Since the number of installation of the bracket 1 and the buoyancy pipe 2 is increased or decreased according to the object, it is possible to respond quickly and conveniently to the change of the standard.

That is, when a plurality of buoyancy pipe (2) is to be used to connect by connecting each buoyancy pipe (2) on both sides of the connecting socket (3), if any one of the plurality of buoyancy pipe (2) When the buoyancy pipe is broken, even if the buoyancy space of the buoyancy pipe 2 is submerged by the watertight partition wall 32 of the connection socket 3, the remaining buoyancy space is kept watertight, thereby preventing the sinking.

As shown in FIG. 6, the connecting socket 3 connected to the end of the buoyancy pipe located at the outermost side of the buoyancy pipes 2 functions as a closing cap to maintain watertightness.

In addition, the connection socket closely connected to the bracket (1) performs the separation prevention and partition wall function of the bracket (1), the connection socket disposed in the middle performs the watertight partition wall function.

While the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the invention from this description. Therefore, the scope of the invention should be construed by the claims described to include examples of many such variations.

In the buoyancy pipe connecting socket for floating structures according to the present invention, by connecting the connection socket in which the watertight bulkheads are integrated therein between the buoyancy pipes, the buoyancy by making the remaining buoyancy space watertight even if the buoyancy space is flooded by the breakage of the buoyancy pipe. While maintaining it to prevent sinking, it is connected to the end of the buoyancy pipe can bring the effect of performing the function as a closing cap.

In addition, it can bring about the effect of preventing the separation by the rolling of the coupling (bracket), which is a structure constituting the buoyant agent and the floating structure of the sea, and the function of the connecting device of the connecting material.

Claims

A connecting socket 3 for connecting a plurality of buoyancy pipes 2 penetratingly coupled to the bracket 1 having a plurality of scaffolds thereon to provide buoyancy to float the bracket 1 at sea in the longitudinal direction. )

The body 31 is a hollow body having a diameter equal to the diameter of the buoyancy pipe (2),

Buoyancy pipe connecting socket for offshore floating structure, characterized in that it comprises a water-tight partition wall 32 formed in the inner center of the body 31 to partition into a plurality of buoyancy space.
The buoyancy pipe connecting socket for marine floating structures according to claim 1, wherein a separation preventing jaw (311) is formed at an outer center of the body (31) to prevent the bracket (1) from being separated.
The buoyancy pipe connecting socket according to claim 1, wherein the watertight partition wall (32) is integrally formed of the same material as the body (31).
The reinforcement protrusions 321 of claim 1 or 3, wherein both sides of the watertight bulkheads 32 protrude to a predetermined thickness to allow butt fusion when connected to other structures. Buoyancy pipe connecting socket for offshore floating structures, characterized in that formed.