KR102462301B1 - Buoyance body for floating structure - Google Patents

Abstract

According to the present invention, a buoyance body for a floating structure comprises: a support member (3) on top of which a floating structure is fixedly installed; an air reservoir (4) provided below the support member (3), integrally coupled to the support member (3), and having therein a first chamber (1) filled with air; and a ballast water reservoir (18) installed below the air reservoir (4), and having therein a second chamber (2) filled with ballast water to prevent overturning. The buoyance body for a floating structure, having this structure, minimizes the loss of durability of the air reservoir (4) due to the expansion and contraction of the air reservoir (4) due to a change in external temperature, thereby having improved dimensional stability, durability, and rigidity. In addition, the buoyance body for a floating structure can prevent conduction through the second chamber (2) filled with ballast water, thereby preventing the floating structure from being flooded.

Description

Buoyance body for floating structure

The present invention relates to a buoyancy body for a water structure that supports and fixes the water structure on water.

In general, in order to install a structure on water, a buoyancy body for floating the structure on water and a mooring device for fixing the position of the buoyancy body are required.

On the other hand, there was a problem that the shape of the previously released buoyancy body may change according to the external temperature change.

For example, the previously released buoyancy body has a problem of being deformed or damaged over time as the durability is weakened while repeating expansion and contraction countless times due to the change in the internal air pressure of the buoyant body due to the change in external temperature, strong wind, There was a problem that the structure could be submerged by overturning due to high waves.

On the other hand, as a prior art of the present invention, "buoyancy body for floating photovoltaic structure" of Patent Application No. "10-2020-0147780" has been filed and registered, and the buoyancy body for floating photovoltaic structure is the first on the lower side. an upper body having a groove formed thereon, and a lower body joined to the upper body and having a second groove formed on the upper side thereof, wherein the inlet rim of the first groove and the inlet rim of the second groove are contacted and joined to each other, The first fusion protrusion and the first sealing protrusion are formed on the inlet rim of the first groove extending toward the lower body and sequentially from the inside to the outside. A second fusion protrusion and a second sealing protrusion are formed to face each of the first sealing protrusions.

Republic of Korea Patent Registration No. "10-2332895" (2021.12.01)

Accordingly, the present invention is to provide a buoyancy body for aquatic structures with improved dimensional safety, durability, and rigidity by minimizing contraction and expansion caused by external temperature changes in order to solve the above problems.

In addition, another object of the present invention is to provide a buoyancy body for water structures that are not conducted even in typhoons or high waves.

The buoyancy body for a water structure according to the present invention for achieving the above object includes a support member 3 on which the water structure is fixedly installed; an air reservoir 4 integrally coupled to the supporting member 3 at a lower portion of the supporting member 3 and having a first chamber 1 filled with air therein; and a ballast water reservoir 18 installed in the lower portion of the air reservoir 4 and equipped with a second chamber 2 filled with ballast water to prevent overturning therein. On the side of the air reservoir 4, a ventilation hole 5 is formed to allow air to enter and exit the first chamber 1 through the side of the air reservoir 4, so that the air reservoir 4 due to external temperature change It is possible to minimize the loss of durability of the air reservoir 4 due to the expansion and contraction action. One or more ventilation holes 5 are formed on the side of the air reservoir 4 . The air reservoir 4 has a cylindrical shape, and the outer and inner circumferential surfaces of the air reservoir 4 have a height of the air reservoir 4 to improve dimensional safety, durability and rigidity of the air reservoir 4 . A first concave-convex portion 7 extending longitudinally in the direction is formed, and two or more first concave-convex portions 7 are formed on the outer circumferential surface and the inner circumferential surface of the air reservoir 4 . A sediment outlet 19 for discharging the sediment inside the ballast water reservoir 18 to the outside of the ballast water reservoir 18 is formed on the side or lower portion of the ballast water reservoir 18 . One or more sediment outlets 19 are formed on the side or lower portion of the ballast water reservoir 18 . Second concave and convex portions extending lengthwise in the height direction of the ballast water reservoir 18 in order to improve the dimensional safety, durability and rigidity of the ballast water reservoir 18 on the outer circumferential surface and the inner circumferential surface of the ballast water reservoir 18 20 is formed, and two or more second concavo-convex portions 20 are formed on the outer circumferential surface and the inner circumferential surface of the ballast water reservoir 18 . The ceiling portion 21 of the second concave and convex portion 20 formed on the outer circumferential surface of the ballast water reservoir 18 and recessed in the inner direction of the ballast water reservoir 18 is processed into a flat plate shape, and has a flat plate shape. A bolt passage hole 22 is penetrated through the ceiling portion 21 of the second concave and convex portion 20 processed with the bolt 24 so that the bolt 24 passes, and the air reservoir 4 facing the bolt passage hole 22 is A bolt 24 is fitted on the bottom surface, and a bolt fixing means 23 having a screw tab is machined on the inner circumferential surface, and the ballast water reservoir is provided in the bolt through hole 22 and the bolt fixing means 23 facing each other. A bolt (24) is fastened to fix (18) and the air reservoir (4). The upper surface of the ballast water reservoir 18 is opened, and the lower part of the air reservoir 4 is introduced into the ballast water reservoir 18 through the open upper surface of the ballast water reservoir 18, and the air reservoir ( 4) is placed on the upper end of the second concave-convex portion 20 protruding inwardly from the inner circumferential surface of the ballast water reservoir 18 . In addition, the present invention provides a lower extension plate 26 extending outwardly of the air reservoir 4 from the side of the air reservoir 4 and arranged in parallel with the support member 3, and the support member 3 ) and the lower extension plate 26, the upper end is fixed to the support member (3) and the lower end further includes a connecting plate (27) fixed to the lower extension plate (26). The ventilation hole (5) is formed on the side of the air reservoir (4) disposed between the support member (3) and the lower extension plate (26). A second ventilation hole is formed in the support member 3 to let air in and out of the first chamber 1, and the durability of the air reservoir 4 is achieved by the contraction and expansion action of the air reservoir 4 due to the change in external temperature. To minimize this loss, one or more second ventilation holes are formed in the support member 3 .

The buoyancy body for aquatic structures according to the present invention having such a configuration is a first chamber on the side of the air storage container (4) so as to minimize the contraction and expansion of the buoyancy body generated by the pressure difference inside the buoyancy body due to an external temperature change. By forming the ventilation holes 5 through which air can pass in and out of (1), it is possible to minimize the loss of durability of the air reservoir 4 due to the contraction and expansion action of the air reservoir 4 due to external temperature change. .

In addition, it is possible to improve the dimensional stability, durability, and rigidity of the buoyancy body by forming the uneven portion outside the buoyancy body.

In addition, by mounting the ballast water reservoir 18 filled with ballast water in the lower part of the buoyancy body, it is possible to prevent the buoyancy body from being conducted to strong winds or high waves, thereby preventing the water structure fixedly installed on the buoyancy body from being submerged.

In addition, by forming a sediment outlet 19 capable of discharging the sediment inside the ballast water reservoir 18 on the outer circumferential surface of the ballast water reservoir 18, the sediment is accumulated inside the ballast water reservoir 18, and the weight of the sediment It is possible to prevent the buoyancy body and the water structure from being submerged.

1 is a perspective view of the present invention;
2 is a cross-sectional view of the present invention;
3 is a front view of the present invention;
4 is an exploded view of the present invention;
Figure 5 is a view for explaining the upper heat-sealed fixing member,
6 is a view for explaining the lower heat-sealed fixing member,
Figure 7 is a view for explaining the bolt mounted on the ceiling portion of the second concavo-convex portion,
8 is a state diagram in which the present invention is installed adjacent to two or more.

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

As shown in Figures 1 to 2, the buoyancy body for a water structure according to the present invention includes a support member 3 on which the water structure is fixedly installed; an air reservoir 4 integrally coupled to the supporting member 3 at a lower portion of the supporting member 3 and having a first chamber 1 filled with air therein; and a ballast water reservoir 18 installed in the lower portion of the air reservoir 4 and equipped with a second chamber 2 filled with ballast water to prevent overturning therein.

As shown in Figure 1, the upper surface of the support member 3 is equipped with two or more bolt fixing holes 28 for bolting the water structure.

As shown in FIG. 3, a vent 5 is formed on the side of the air reservoir 4 to let air in and out of the first chamber 1 through the side of the air reservoir 4 to change the external temperature. It is possible to minimize the loss of durability of the air reservoir (4) by the expansion and contraction action of the air reservoir (4) by the.

One or more ventilation holes 5 are formed on the side of the air reservoir 4 .

A sediment outlet 19 for discharging the sediment inside the ballast water reservoir 18 to the outside of the ballast water reservoir 18 is formed on the side or lower side of the ballast water reservoir 18 as shown in FIG. 3 .

One or more sediment outlets 19 are formed on the side or lower portion of the ballast water reservoir 18 .

In addition, as shown in FIG. 3 , the present invention has a lower extension plate 26 extending outwardly of the air reservoir 4 from the side of the air reservoir 4 and arranged in parallel with the support member 3 . ) and a connecting plate 27 installed between the support member 3 and the lower extension plate 26, the upper end being fixed to the support member 3 and the lower end fixed to the lower extension plate 26 do.

The ventilation hole (5) is formed on the side of the air reservoir (4) disposed between the support member (3) and the lower extension plate (26).

Reinforcing means (6) is mounted between the lower extension plate (26) and the air reservoir (4) to strengthen the coupling between the lower extension plate (26) and the air reservoir (4), and the reinforcement means (6) As shown in FIG. 3 , as a plate in the form of a right-angled triangle, one side is fixed to the bottom surface of the lower extension plate 26 , and the other side is fixed to the side surface of the air reservoir 4 .

As shown in Figure 4, the air reservoir 4 has a cylindrical shape on the outer circumferential surface and the inner circumferential surface of the air reservoir 4, in order to improve the dimensional safety, durability and rigidity of the air reservoir 4 A first concave and convex portion 7 extending lengthwise in the height direction of the air reservoir 4 is formed, and the first concave and convex portion 7 is at least two on the outer circumferential surface and the inner circumferential surface of the air reservoir 4 . is formed

As shown in FIG. 4 , the air reservoir 4 is integrally coupled with the support member 3 at the lower portion of the support member 3 and has a space formed therein and an upper air reservoir 8 with an open bottom. ) and a lower air storage container 9 having an open upper surface formed therein with a space portion.

The top surface of the ballast water reservoir 18 is opened, and the lower part of the air reservoir 4 is the ballast water reservoir 18 through the open upper surface of the ballast water reservoir 18 as shown in FIG. 4 . is drawn in, and the bottom surface of the air reservoir 4 is placed on the upper end of the second concave-convex portion 20 protruding inward of the ballast water reservoir 18 from the inner circumferential surface of the ballast water reservoir 18 .

As shown in FIG. 4, on the outer circumferential surface and the inner circumferential surface of the ballast water reservoir 18, the height direction of the ballast water reservoir 18 to improve dimensional safety, durability and rigidity of the ballast water reservoir 18 A second concave-convex portion 20 extending in length is formed, and two or more second concave-convex portions 20 are formed on the outer circumferential surface and the inner circumferential surface of the ballast water reservoir 18 .

As shown in FIG. 5 , on the bottom of the upper air reservoir 8 , an upper heat-sealed fixing member 10 integrally coupled to the bottom of the upper air reservoir 8 and formed along the bottom of the upper air reservoir 8 . ) is mounted, and is integrally coupled to the upper surface of the lower air reservoir 9 as shown in FIG. 6 on the upper surface of the lower air reservoir 9, and is formed along the upper surface of the lower air reservoir 9 The upper heat-sealed fixing member 10 and the lower heat-sealed fixing member 11 to be heat-sealed is mounted.

As shown in FIG. 5, the upper heat-sealed fixing member 10 has an upper ring-shaped body 12 installed along the bottom of the upper air reservoir 8 in a ring shape, and the upper ring-shaped body 12 ) from the bottom surface of the upper ring-shaped protrusion 13 protruding in the direction of the lower heat-sealing fixing member 11 and protruding in a ring shape, and the upper ring-shaped body outside the radius of the upper ring-shaped protrusion 13 . An upper ring-shaped groove 14 having a ring shape is included as a groove formed on the underside of (12).

As shown in FIG. 6 , the lower heat-sealed fixing member 11 includes a lower ring-shaped body 15 installed along the upper surface of the lower air reservoir 9 in the form of a ring, and the lower ring-shaped body 15 . ) from the upper surface of the lower ring-shaped protrusion 16 protruding in the direction of the upper heat-sealing fixing member 10 and protruding in a ring shape, and a lower ring-shaped body outside the radius of the lower ring-shaped protrusion 16 . (15) includes a lower ring-shaped groove (17) formed on the upper surface.

In addition, the ceiling portion 21 of the second concave-convex portion 20 formed on the outer circumferential surface of the ballast water storage container 18 and recessed in the inner direction of the ballast water storage container 18 is as shown in FIG. 7 . As shown in FIG. 2, in the ceiling portion 21 of the second concave-convex portion 20 processed in a flat plate shape and processed in a flat plate shape, a bolt through hole 22 is penetrated so that the bolt 24 passes through, and , A bolt 24 is fitted on the bottom surface of the air storage container 4 facing the bolt through hole 22, and a bolt fixing means 23 having a screw tap processed on the inner circumferential surface is provided.

Bolts 24 are fastened to the bolt through hole 22 and the bolt fixing means 23 facing each other to fix the ballast water reservoir 18 and the air reservoir 4 .

A second ventilation hole is formed in the support member 3 to allow air to pass in and out of the first chamber 1, so that the durability of the air reservoir 4 is caused by the expansion and contraction action of the air reservoir 4 due to a change in external temperature. To minimize this loss, one or more second ventilation holes are formed in the support member 3 .

The buoyancy body for aquatic structures according to the present invention having such a configuration is a first chamber on the side of the air storage container (4) so as to minimize the contraction and expansion of the buoyancy body generated by the pressure difference inside the buoyancy body due to an external temperature change. By forming the ventilation holes 5 through which air can pass in and out of (1), it is possible to minimize the loss of durability of the air reservoir 4 due to the contraction and expansion action of the air reservoir 4 due to external temperature change. .

In addition, it is possible to improve the dimensional stability, durability, and rigidity of the buoyancy body by forming the uneven portion outside the buoyancy body.

In addition, by mounting the ballast water reservoir 18 filled with ballast water in the lower part of the buoyancy body, it is possible to prevent the buoyancy body from being conducted to strong winds or high waves, thereby preventing the water structure fixedly installed on the buoyancy body from being submerged.

In addition, by forming a sediment outlet 19 capable of discharging the sediment inside the ballast water reservoir 18 on the outer circumferential surface of the ballast water reservoir 18, the sediment is accumulated inside the ballast water reservoir 18, and the weight of the sediment It is possible to prevent the buoyancy body and the water structure from being submerged.

1. First chamber 2. Second chamber
3. Support member 4. Air reservoir
5. Vents 6. Reinforcement means
7. First concave-convex part 8. Upper air reservoir
9. Lower air reservoir 10. Upper heat-sealed fixing member
11. Lower heat-sealed fixing member 12. Upper ring-shaped body
13. Upper ring-shaped protrusion 14. Upper ring-shaped groove
15. Lower ring-shaped body 16. Lower ring-shaped protruding jaw
17. Lower ring groove 18. Ballast water reservoir
19. Sediment outlet 20. Second concave-convex part
21. Ceiling 22. Bolt through hole
23. Bolt fastening means 24. Bolt
26. Lower extension plate 27. Connection plate
28. Bolt fixing hole

Claims (9)

a support member 3 on which the water structure is fixedly installed;
an air reservoir 4 integrally coupled to the supporting member 3 at a lower portion of the supporting member 3 and having a first chamber 1 filled with air therein;
and a ballast water reservoir 18 installed in the lower part of the air reservoir 4 and equipped with a second chamber 2 filled with ballast water to prevent overturning therein,
The air reservoir 4 has a cylindrical shape, and a first concavo-convex portion 7 extending longitudinally in the height direction of the air reservoir 4 is formed on the outer circumferential surface and the inner circumferential surface of the air reservoir 4,
The first concave-convex portion 7 is a buoyancy body for water structures, characterized in that two or more are formed on the outer circumferential surface and the inner circumferential surface of the air reservoir (4).
The method of claim 1,
On the side of the air reservoir 4, a ventilation hole 5 is formed to allow air to enter and exit the first chamber 1 through the side of the air reservoir 4, so that the air reservoir 4 due to external temperature change Minimize the loss of durability of the air reservoir 4 due to the expansion and contraction action,
A lower extension plate 26 extending from the side of the air reservoir 4 to the outside of the air reservoir 4 and arranged in parallel with the support member 3;
Further comprising a connecting plate 27 installed between the support member 3 and the lower extension plate 26, the upper end fixed to the support member 3 and the lower end fixed to the lower extension plate 26,
The vent (5) is a buoyancy body for a water structure, characterized in that formed on the side of the air reservoir (4) disposed between the support member (3) and the lower extension plate (26).
3. The method of claim 2,
The vent (5) is a buoyancy body for water structures, characterized in that at least one formed on the side of the air storage tank (4).
delete The method of claim 1,
A buoyancy body for a water structure, characterized in that a sediment outlet 19 for discharging the sediment inside the ballast water reservoir 18 to the outside of the ballast water reservoir 18 is formed on the side or lower side of the ballast water reservoir 18 .
6. The method of claim 5,
The sediment outlet 19 is a buoyancy body for a water structure, characterized in that at least one formed on the side or the lower portion of the ballast water storage tank (18).
The method of claim 1,
A second concave-convex portion 20 extending longitudinally in the height direction of the ballast water reservoir 18 is formed on the outer circumferential surface and the inner circumferential surface of the ballast water reservoir 18,
The second concave-convex portion 20 is a buoyancy body for water structures, characterized in that two or more are formed on the outer circumferential surface and the inner circumferential surface of the ballast water storage container (18).
8. The method of claim 7,
The ceiling portion 21 of the second concave-convex portion 20 formed on the outer circumferential surface of the ballast water storage container 18 and recessed in the inner direction of the ballast water storage container 18 is processed into a flat plate shape,
A bolt through hole 22 is penetrated through the ceiling portion 21 of the second concave-convex portion 20 processed in the form of a flat plate so that the bolt 24 passes through,
A bolt 24 is fitted on the bottom surface of the air storage container 4 facing the bolt through hole 22, and a bolt fixing means 23 having a screw tab processed on the inner circumferential surface is provided,
A bolt 24 is fastened to the bolt through hole 22 and the bolt fixing means 23 facing each other to fix the ballast water reservoir 18 and the air reservoir 4,
The upper surface of the ballast water reservoir 18 is open,
The lower portion of the air reservoir (4) is introduced into the ballast water reservoir (18) through the open upper surface of the ballast water reservoir (18),
The lower surface of the air reservoir (4) is placed on the upper end of the second concave-convex portion (20) protruding inwardly of the ballast water reservoir (18) from the inner circumferential surface of the ballast water reservoir (18) Buoyancy body for water structures.
The method of claim 1,
A second ventilation hole is formed in the support member 3 to allow air to pass in and out of the first chamber 1, so that the durability of the air reservoir 4 is caused by the expansion and contraction action of the air reservoir 4 due to a change in external temperature. to minimize this loss,
The second ventilation hole is a buoyancy body for a water structure, characterized in that one or more formed in the support member (3).

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