KR100985138B1 - Apparatus For Connecting Floating Structures in Sea - Google Patents

Abstract

The present invention relates to a floating structure connecting apparatus at sea, which can be coupled to each other by using the sealing member and the connecting members in a sliding manner, so that the floating structures can be easily connected at sea without dry work at the time of joining. A seal member mounted to the inner side of the sheath tube exposed to the connection portion of the floating structure; And a seal member fitted to the seal member, and a female screw member embedded in one of the floating structures, and a male screw member embedded in the other floating structure so that the male screw member slides into the female screw member so that the floating structures are connected to each other. It provides a floating structure connecting device on the sea to enable the sliding coupling and order between the floating structure, including a connecting member. According to the present invention, the floating structures floating on the sea can be easily connected to the floating structure blocks at sea through the seal member and the connecting members, and the connection of the bonding surface can be easily slidably without a separate rubber plate at the bonding surface. Since it is possible to reduce the manufacturing process of the floating structure, it is possible to achieve an excellent effect that can reduce the manufacturing and construction costs accordingly.

Seal member, floating structure, floating structure connector, stranded wire, rubber sheet

Description

Apparatus For Connecting Floating Structures in Sea}

The present invention relates to an apparatus for connecting floating floating concrete structures to each other, and more particularly, to seal the seal member and the connecting members in advance to the sheath pipe, and to seal these seal members and connecting members from both floating structures The present invention relates to a floating structure connecting device at sea so that the floating structures can be easily connected at sea without sliding a rubber plate of the joint surface by slidingly coupling with each other.

In recent years, the use of floating bodies (floating bodies) as a floating structure at sea is increasing. Examples of such floating structures include offshore plants, container terminals, oil storage facilities, offshore tunnels, or offshore parks.

Such a floating structure is generally made of concrete, by connecting and assembling several floating concrete blocks of a rectangular parallelepiped shape having a hollow portion to form a single floating concrete structure.

Such floating concrete structures, for example, produce floating concrete blocks at a manufacturing site near the coast, launch the floating concrete blocks produced using a lifting device such as a crane, and then launch a plurality of offshore There is a method of completing floating concrete structures by connecting and assembling floating concrete blocks.

Another conventional technique is to use a floating concrete block in the dry dock (dry dock), this method is mainly used for the production of large vessels, in the dry dock (dry dock) provided on the shore near the coast It is a method of producing floating concrete blocks by making floating concrete blocks and launching the floating concrete blocks by filling the sea water by opening the gate of dry dock.

Meanwhile, another conventional technique is to manufacture a floating concrete block in a floating dock, which manufactures a floating concrete block while floating a pre-fabricated floating dock at sea, and a floating dock. After the floating concrete structures are launched from the sea to connect them to each other and assembled to complete the floating concrete structure.

In this way, the floating structures, each floating in the sea has its own buoyancy, so that they are floating in the sea, and are connected to each other integrally through the connecting devices.

For example, in the case of a relatively small floating structure, through holes 11a and 11b are formed on both sides of the connection of the floating structures 10a and 10b, and these through holes 11a. By inserting the steel bar 12, which is a tension member in the (11b), and then introducing a tension force through the fixing device 13, such as a nut, these floating structures (10a) (10b) are pressed to each other and combined.

And alternatively, as shown in Figure 1b, in the case of relatively large floating structures (10a, 10b), the sheath pipe (14a) (14b) on the upper, lower, left and right sides of each floating structure (10a) (10b) After penetrating laterally, the strand wire 15 is inserted into the sheath pipe 14a, 14b, and a tension force is introduced into the strand wire 15.

Accordingly, the floating structures 10a and 10b are compressed to each other by the tension of the strand 15, and are integrally connected to each other.

Alternatively, there is a complex connection structure of the steel bar 12 and the strand 15, which is connected to the floating structure (10a) (10b) by using the steel bar 12 on the upper side, the sheath pipe (14a) ( A composite structure is also proposed that connects the floating structures 10a and 10b using 14b) and the strand 15.

However, the conventional method of connecting the floating structures (10a) (10b) is difficult to connect the floating structures (10a) (10b) at sea, which is connected to the floating structures (10a) (10b) at sea In order to make the connection, the water of the connection part must be pumped and watertightness must be maintained to prevent water from entering.

For example, in the related art, floating structures 10a and 10b in order to dry work when joining the floating structures 10a and 10b when the floating structures 10a and 10b are connected as shown in FIGS. 1c and 1d. U-shaped rubber plate 16 is mounted on the joint surface of the sputtered water in the space between the joint surface and proceed with the dry operation.

It can be seen that such a rubber plate 16 is pressed after the four edges of the bonding surface after the bonding of the floating structure (10a, 10b) to prevent the intrusion of water.

In this case, the water inside the rubber plate 16 is removed to the outside through a separate pumping device (not shown), and after the pumping operation, the rubber plates 16 block water from flowing into the joint surface from the outside. It acts as a waterproof plate to be able to dry work (dry work) at the joint surface.

However, the conventional technology as described above is a cost and air is required for the rubber plate 16 mounting and pumping operation, and the operation of the conventional connection device at sea is also difficult to have a lot of room for improvement.

The present invention is to solve the conventional problems as described above, the object is to combine the floating structures floating on the sea by sliding to each other to be able to easily combine the floating structures at sea floating In providing a structure connecting device.

And another object of the present invention is to reduce the manufacturing process of the floating structure by reducing the need for the rubber plate for dry operation in the joint surface is not pumped, and to reduce the construction cost of the floating structure connecting device at sea In providing.

In order to achieve the above object, the present invention, in the apparatus for connecting the floating structures integrally at sea,

A seal member mounted to the inner entrance of the sheath tube exposed at the connection portion of each floating structure; And

The seal member is fitted to the seal member, and the floating structure on one side has a female screw member embedded therein, and the floating structure on the other side has a male screw member embedded therein to allow the male screw member to slide while sliding to the female screw member so that the floating structures are connected to each other. It provides a floating structure connecting device on the sea to enable the sliding coupling and order between the floating structure including a connecting member.

The present invention also preferably provides a floating structure connecting device at sea, wherein the seal member is a plurality of o-ring seals or sealing sleeves.

And the present invention preferably provides a floating structure connecting device at sea so that the sheath tube is formed of a hollow tube-shaped hole penetrating the lower portion of the floating structure.

In another aspect, the present invention preferably provides a floating structure connecting device in the sea so that the tension member including each of the stranded wire is connected to both sides thereof so that the tension force is introduced by the fixing device.

And the present invention preferably the hole is a floating structure in the sea to be closed with the opening is filled with mortar through the opening formed to communicate with the buoyancy generating space inside the floating structure after the coupling of the floating structure through the connecting member Provide a connection device.

In another aspect, the present invention preferably provides a floating structure connecting apparatus on the sea further comprises a second connecting portion for coupling the floating structures adjacent to each other on both sides of the upper portion of the floating structure.

And the present invention preferably the second connecting portion forms a hole on both sides of the upper portion of the floating structure, the steel rod is inserted into the hole is connected to the adjacent floating structure, the tension force to the steel rod through the fixing means It provides a floating structure connecting device on the sea to give a compression structure to the floating structure is attached.

In another aspect, the present invention preferably the second connecting portion forms a sheath tube on both sides of the upper portion of the floating structure, the sheath tube is connected to each other by crimping the floating structures adjacent to each other by inserting a stranded wire and applying a tension force through the fixing device To provide a floating structure connecting device at sea.

According to the present invention, the floating structures floating on the sea can be coupled to each other by sliding through the seal member and the connecting member without dry operation, and the floating structures can be easily connected at sea, and the sea connecting operation is easily performed.

In addition, according to the present invention, it is not necessary to attach the rubber plate to the floating structure because the connection of the bonding surface is easily made in a sliding manner without a separate rubber plate in the bonding surface of the floating structure. Therefore, the effect of reducing the manufacturing process of the floating structure and thereby reducing the manufacturing and construction costs is obtained.

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

Floating structure connection device 100 at sea according to the present invention is a device for connecting the floating structure (10a, 10b) integrally at sea.

As shown in FIG. 2, the floating structure connecting device 100 at sea according to the present invention is provided with a sheath tube 105a and 105b exposed at the connecting portion of each floating structure 10a and 10b. The seal member 110 is mounted to the inner side opening.

The seal member 110 is composed of a plurality of o-ring seals 112 mounted inside the sheath tubes 105a and 105b, for example.

In addition, the seal member 110 may be formed of a sealing sleeve 116 mounted on the inner side of the sheath tube 105a, 105b, as shown in FIG.

Since the structure of the sealing sleeve 116 has the same effect as the O-ring seal 112, when the connection member 130 is operated, it is effective to intrude water from the outside through the sheath pipes 105a and 105b. Prevent (order effect).

Each of the seal members 110 forms concave grooves 114 inside the sheath tubes 105a and 105b, and is fixed to the concave grooves 114, and is suspended in the seal member 110. Connecting members 130 for inserting the structural structures 10a and 10b together are inserted. The sheath tube 105a, 105b is formed as a hollow tube-shaped hole penetrating the lower portion of the floating structure (10a, 10b), respectively.

For example, the connection member 130 includes a female screw member 132 and a male screw member 134, and the female screw member 132 is positioned at one side of the floating structure 10a to form an inner side of the seal member 110. The male screw member 134 is embedded in the floating structure 10b on the other side and fitted inside the seal member 110, and the female screw member 132 and the male screw member 134 are seal members. Sliding and engaging each inside of the 110. Accordingly, the floating structures 10a and 10b are slidably connected to each other by the coupling of the female screw member 132 and the male screw member 134.

Meanwhile, the floating structure connecting device 100 according to the present invention is connected to the sheath pipes 105a and 105b from the inside of the floating structures 10a and 10b for the rotation operation of the connecting member 130. Each of the openings 140a and 140b is formed through the openings 140a and 140b. The openings 140a and 140b are formed from the buoyancy space P of the floating structures 10a and 10b toward the sheath tube 105a and 105b. will be.

Through such a structure, the worker can reach the connecting member 130 from the inside of the floating structures 10a and 10b, and the floating structures 10a and 10b are operated by the operation of the connecting member 130. Sliding coupling between) can be achieved.

At this time, the female screw and the male screw member is preferably screwed, but may be slidingly coupled in a manner of being inserted and fixed.

In addition, after the coupling members 130 are coupled as described above, the inside of the sheath tube 105a and 105b is filled with mortar M so as to communicate with the buoyancy generating space of the floating structure. It is closed with the 140b to block the inflow of water through the sheath pipes 105a and 105b, as well as to complete the coupling of the connection member 130.

After the coupling of the floating structures 10a and 10b is made through the connecting members 130 as described above, the connecting member 130 is provided through a fixing device (not shown) provided on the opposite side of the connecting member 130. By applying a tension force to the) can be achieved a firm coupling between the floating structure (10a, 10b) through the connecting member (130).

In addition, the connecting member 130 has a structure in which tension members 184 including steel bars are connected to both sides thereof so that a tension force is introduced by a fixing device (not shown).

For example, as shown in FIGS. 2 and 3, the connecting members 130 may be connected to and fixed to an end of the tension member 184, which is a steel rod, respectively, but the tension members 184 may be formed at both sides of the connecting member 130. It may be integrated and extend along the sheath tubes 105a and 105b.

Thus, the connecting member 130 and the tension member 184 to be formed integrally with each other in the construction, manufacturing, or to be installed separately connected to each other.

In addition, the tension member 184 is provided with a fixing device (not shown) at each end thereof to impart a tension force, and achieve a firm coupling between the floating structures 10a and 10b through the connection member 130. .

In addition, the present invention includes a second connection portion 170 on both sides of the upper portion of the floating structure (10a, 10b), the second connection portion 170 is a hole (hole) in the floating structure (10a) (10b) 172a and 172b, and a steel bar 174 is inserted into the holes 172a and 172b to be fixed to the floating structures 10a and 10b adjacent to each other through the fixing unit 176.

Such second connection portion 170 is to more firmly connect the floating structures (10a, 10b) adjacent to each other by applying a tension force to the steel bar 174 through the fixing means 176.

In addition, as shown in FIG. 4B, the second connection part 170 forms sheath pipes 180a and 180b on both sides of the upper part of the floating structures 10a and 10b, and the sheath pipe 180a. Inserting the strand 182 in the 180b and is a structure for imparting a tension force through a fixing device (not shown). Through the structure of the second connection unit 170 as described above, the floating structures 10a and 10b adjacent to each other are integrally connected.

Floating structure connection device 100 at sea according to the present invention configured as described above can be connected to the floating structure (10a, 10b) integrally in the sea.

Floating structure connecting device 100 in the sea according to the present invention, if you want to connect the floating structure (10a) (10b) in the floating state at sea, respectively, one floating structure (10a) (10b) to each other When adjacent to each other, the female screw member 132 and the male screw member 134 of the connection member 130 are brought into contact with each other.

In such a case, the worker enters into each of the floating structures 10a and 10b and rotates the connection member 130 through the openings 140a and 140b to engage the outside of the connection member 130. Since the seal member 110 is mounted therein, the inflow of water toward the inside of the floating structures 10a and 10b through the sheath pipes 105a and 105b is blocked even during the rotation of the connection members 130.

Since the connecting member 130 is composed of the female screw member 132 and the male screw member 134, these female screw members are formed through the openings 140a and 140b inside the floating structures 10a and 10b located at both sides. Rotating 132 and male screw members 134 causes them to be gradually screwed together so that the floating structures 10a and 10b are coupled to each other by their joining surfaces.

When the male screw members 134 are completely screwed into the female screw member 132, the joining surfaces of the floating structures 10a and 10b are joined to each other so as to be interviewed with each other. Joining of the structures 10a and 10b is complete.

After the coupling of the floating structures 10a and 10b is made through the connecting members 130 as described above, a fixing device (not shown) provided on the opposite side of the connecting member 130, for example, a female screw member ( 132 and a fixing device (not shown) at the rear ends of the male screw members 134, respectively, and by applying a tension force to the connecting member 130 between the floating structure (10a) (10b) through the connecting member 130 Tight couplings are made.

In addition, the floating structure connecting device 100 in the sea of the present invention as shown in Figure 4a, b, c, the second connecting portion 170 on both sides of the upper portion of the floating structure (10a) (10b) In addition, it is possible to firmly connect the floating structures 10a and 10b adjacent to each other by applying a tension force to the upper side of the floating structures 10a and 10b through the second connection portion 170. have.

For example, a steel rod 174 is included in the second connection portion 170, and holes 172a and 172b are formed in the floating structures 10a and 10b, and then the holes 172a and 172b are formed. The steel rods 174 in the air and the floating structures 10a and 10b adjacent to each other through the fixing means 176, and the tensioning force is applied to the steel rods 174 through the fixing means 176. It is possible to firmly connect the upper portion of the expression structure (10a, 10b).

In addition, the second connecting portion 170 is configured to form a sheath pipe 180a and 180b on both upper sides of the floating structures 10a and 10b, and a lecture line is formed on the sheath pipe 180a and 180b. After inserting 182, tension may be applied through a fixing device (not shown). Therefore, the upper portion of the floating structures 10a and 10b adjacent to each other are integrally connected to each other through the structure of the second connection unit 170.

As described above, in the present invention, when the floating structures 10a and 10b floating on the sea are to be connected as a single structure, the floating structure through the seal member 110 and the connecting member 130 in the coupling process. 10a and 10b are coupled to each other in a sliding manner.

Therefore, in order to maintain the dry state as in the prior art when connecting the floating structures (10a, 10b), the process such as installing the rubber plate 16 and pumping work is unnecessary.

As described above, according to the present invention, the connection surface of the floating structures 10a and 10b may be easily connected to each other even when there is no separate rubber plate 16, so that the sea connection work may be easily performed. The manufacturing process of the floating structure (10a) (10b) can be reduced, thereby achieving the effect of reducing the manufacturing and construction costs.

Although the present invention has been described in detail with reference to the accompanying drawings, the present invention is not limited to such a specific structure. Those skilled in the art will be able to variously modify or change the embodiments of the present invention without departing from the spirit and scope of the present invention as set forth in the claims below.

For example, although the connecting member is applied in a structure using a female screw member and a male screw member, the present invention is not limited thereto and may be connected by sliding fitting using sleeves. Nevertheless, it is intended that it be apparent in advance that all modifications or designs of simple embodiments having the same function will clearly fall within the scope of the present invention.

1 is a view showing a floating structure connecting device in the sea according to the prior art, a is a side view of the connection device using a steel bar, b is a side view of the connection device using a strand, c is a plan view of the floating structure, d is a front view of the floating structure;

2 is a side view with an o-ring seal as a seal member in a floating structure connection apparatus at sea according to the present invention;

3 is a side view with a sealing sleeve as a seal member in a floating structure connecting apparatus at sea according to the present invention;

Figure 4 is a view of the various configurations of the floating structure connecting device at sea according to the present invention, a side is a side view in combination with the rod connecting device on the upper side, b is a side view in combination with the strand on the upper side, c is a view from the upper side It is a side view combined with a strand and equipped with a sealing sleeve.

Description of the Related Art

10a, 10b .... Floating Structures 11a, 11b .... Holes

12 .... Steel rod 13 .... Fixture

14a, 14b .... Sheath Hall 15 .... Lecture

16 ... rubber plate

100 ..... Floating structure connecting device at sea according to the present invention

105a, 105b, 180a, 180b .... Sheath tube 110 .... Seal member

112 .... O-Ring Seal 114 ..... Concave Groove

116 .... Sealing sleeve 130 ..... Connecting member

132 .. No female thread 134 ..... No male thread

140a, 140b .... opening 170 ..... second connection

172a, 172b ... hole 174 ..... steel rod

176 ..... Means of Settlement 182 .....

184 ..... Tension M ..... Mortar

P ..... buoyancy space

Claims (8)

An apparatus for integrally connecting floating structures at sea, A seal member mounted to the inner entrance of the sheath tube exposed at the connection portion of each floating structure; And The seal member is fitted to the seal member, and the floating structure on one side has a female screw member embedded therein, and the floating structure on the other side has a male screw member embedded therein to allow the male screw member to slide while sliding to the female screw member so that the floating structures are connected to each other. Floating structure connecting device at sea, including a coupling member; to enable sliding coupling and order between the floating structure. The apparatus of claim 1, wherein the seal member is a plurality of o-ring seals or sealing sleeves. The floating structure connecting apparatus of claim 1, wherein the sheath tube is formed of a hollow tube-shaped hole passing through a lower portion of the floating structure. The floating structure connecting apparatus of claim 1, wherein the connecting member is connected to both sides thereof with tension members each including a stranded wire so that tension is introduced by the fixing device. 4. The floating structure connection of claim 3, wherein the hole is filled with a mortar through an opening configured to communicate with the buoyancy generating space inside the floating structure after the floating structure is coupled through the connecting member. 5. Device. 2. The floating structure connecting apparatus of claim 1, further comprising a second connection unit for coupling adjacent floating structures on both sides of an upper portion of the floating structure. The method of claim 6, wherein the second connecting portion forms a hole on both sides of the upper portion of the floating structure, a steel rod is inserted into the hole is connected to each other adjacent to the floating structure, and the tension force is applied to the steel rod through the fixing means Floating structure connecting device at sea to give a floating structure by crimp connection. The method of claim 6, wherein the second connecting portion forms a sheath tube on both sides of the upper portion of the floating structure, the sheath tube to connect the adjacent floating structures to each other by inserting a strand and applying a tension force through the fixing device Floating structure attachment at sea.

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