KR102105709B1 - floating structure - Google Patents

Abstract

The present invention relates to a marine floating structure. The marine floating structure includes: unit assembly units including a ring part in which a circular synthetic resin pipe is stored and supported in a penetrated state, a water-supply block part which is integrated with the upper part of the ring part, and a plurality of side slope plates which extend in a plate shape from both outer side surfaces of the ring part in the direction of being far away from the ring part as becoming closer to the bottom, wherein the unit assembly units are placed to be spaced in a first direction which is an extension direction of circular synthetic resin pipes through the ring part, and are mutually combined with another water-supply block part in an orthogonal direction to the first direction; a plurality of footholds coupled to the upper surface of the unit assembly units; an outermost rolling reduction plate formed in a plate shape on a side slope plate, which is placed on the outermost side of outermost unit assembly units each placed on the outermost side of the unit assembly units, to be combined with the side slope plates in the first direction to reduce rolling caused by waves; and a buoyancy assisting body coupled to the unit assembly units or circular synthetic resin pipes in a separation space formed between the unit assembly units to reinforce buoyancy. Therefore, the marine floating structure can reduce vibrations caused by waves while maximizing the use of the buoyancy of a synthetic resin pipe.

Description

Floating structure

The present invention relates to an offshore floating structure, and more particularly, to an offshore floating structure capable of reducing rolling by waves.

Buzan Bridge is a floating floating structure that is installed on the water for docking and unloading of ships.

These quay bridges are widely used as part of port facilities by facilitating the docking of ships, regardless of sea level fluctuations, especially in the high tide difference.

However, in the conventional floating bridge, the outer housing facing the water surface is formed of an iron plate material, and thus has a short life due to corrosion. Particularly, iron oxides that escape from the corroded iron plate to the water phase also have environmental problems that pollute the ocean.

In addition, the conventional floating bridge has a disadvantage in that the top plate is completely sealed with concrete, so that there is a risk of sinking due to water leakage when partial damage occurs in the lower portion, and the repair using the space inside the housing is not easy.

On the other hand, in recent years, as the marine aquaculture industry has increased, small submarine bridges for docking and working on small vessels are required, and Korean Patent Registration No. 10-1450732 discloses a composite multifunctional PB bridge with synthetic resin pipe.

By the way, the buoyant bridge divides the flotation pipe up and down, and the lower compartment space is allowed to pass, so the buoyancy is reduced by half compared to the flotation pipe having the existing cylindrical inner space, so that it floats compared to the same scale applied with the existing flotation pipe. There is a disadvantage that the performance is attenuated in half.

In particular, when considering the footbridge installed securely on the floating bridge and the allowable unloading capacity to be applied, the method of reducing the buoyancy space of the flotation pipe has a disadvantage in that it limits the utilization range by reducing the total load allowable weight.

In addition, the P-Byzan Bridge has a disadvantage in that it is difficult to fundamentally suppress rolling due to blue, that is, fluctuation, since the lowermost submerged in the water surface has a circular shape corresponding to the floating pipe.

The present invention was devised to improve the above problems, and has an object to provide a floating floating structure capable of attenuating fluctuations caused by blue waves while avoiding attenuation of buoyancy of a synthetic resin pipe.

In order to achieve the above object, the floating structure according to the present invention includes a plurality of circular synthetic resin pipes extending in a circular shape having a hollow hollow so as to form buoyancy and spaced apart from each other; The circular synthetic resin pipe is integrally formed on the upper portion of the ring portion and the ring portion that can be received and supported in a through state, and extends upwardly, but is formed in a rectangular frame shape having an extended size than the ring portion, but penetrates along the extending direction of the ring portion The water blocking block portion having a plurality of water passing holes and a plurality of side inclined plates extending in a plate shape in a direction away from the ring portion as it progresses downward from both side outer surfaces of the ring portion, and extending directions of the circular synthetic resin pipes through the ring portion Unit assembly units are arranged spaced apart from each other in the first direction, and are mutually coupled with other water-blocking portions in a direction orthogonal to the first direction; A plurality of scaffolds formed in a plate shape and coupled to the upper surfaces of the unit assembly units along the first direction; The unit assembly unit is formed in a plate shape on the side inclined plate disposed on the outermost side of the outermost unit assembly units respectively disposed on the outermost side along the second direction orthogonal to the first direction along the first direction An outermost rolling reduction plate joined to the side inclined plates to reduce rolling caused by blue; It is provided with a buoyancy aid to reinforce the buoyancy by being combined with the unit assembly unit or the circular synthetic resin pipe in a separation space formed between the unit assembly units spaced apart from each other along the first direction. The sieve is formed of a square box formed of an FRP material, and has an auxiliary buoyancy body having a closed internal buoyancy space; It is formed on the auxiliary buoyancy body and provided with a coupling body for coupling with the circular synthetic resin pipe or the unit assembly unit, and the outermost side so that a passage through which the seawater can pass is formed through the upper portion of the outermost rolling reduction board. Rolling reduction plate is coupled to the side inclined plate.

According to one aspect of the present invention, the inner side between the side inclined plates disposed on the outermost side of the outermost unit assembly unit respectively disposed on the outermost side along the second direction orthogonal to the first direction of the unit assembly unit It may be further provided with; the inner rolling reduction plate to reduce the rolling by the blue by being bonded along the first direction to the side inclined plate disposed.

According to the floating structure according to the present invention, it provides the advantage of reducing fluctuations caused by waves while making the most of the buoyancy of the synthetic resin pipe.

1 is an exploded perspective view showing a floating structure according to the present invention,
FIG. 2 is a perspective view showing a state in which the outermost rolling reduction plate of the offshore floating structure of FIG. 1 is coupled;
3 is a front view of the coupled state of the offshore structure of Figure 2,
4 is an enlarged front view of the unit assembly unit of FIG. 2,
5 is another plan view of a buoyancy relief body coupled to the offshore floating structure of FIG. 2,
Figure 6 is a front view of the coupled state of the marine floating structure according to another embodiment of the present invention.

Hereinafter, a floating floating structure according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is an exploded perspective view showing a floating structure according to the present invention, Figure 2 is a perspective view showing a state in which the outermost rolling reduction board of the floating structure of Figure 1 is combined, Figure 3 is a floating floating structure of Figure 2 4 is a front view showing an enlarged unit assembly unit of FIG. 2.

1 to 4, the floating floating structure 100 according to the present invention includes a circular synthetic resin pipe 110, a unit assembly unit 130, a scaffold 150, the outermost rolling reduction plate 170 and buoyancy assistance A sieve 180 is provided.

The circular synthetic resin pipe 110 extends in a circular shape having a hollow hollow so as to form buoyancy. Both ends of the circular synthetic resin support pipe 110 are closed to have a buoyancy by closing the hollow, and a polyethylene material (PE) may be used.

The circular synthetic resin tubes 110 are installed to be inserted along the first direction in the longitudinal direction in a through state in the ring portion 131 of the unit assembly units 130 to be described later. In the illustrated example, three unit assembly units 130 are combined in a second direction orthogonal to the first direction, and three circular synthetic resin tubes 110 are mounted to be spaced apart from each other.

The unit assembly unit 130 is formed so that the circular synthetic resin pipe 110 can be accommodated and supported, and can be mutually extended, and for convenience of explanation, the ring portion 131 and the water blocking block portion 135 and side It has a structure having an inclined plate 132.

The ring portion 131 is a portion formed such that the circular synthetic resin pipe 110 is accommodated and supported in a through state.

The water passage block portion 135 is integrally formed on the upper portion of the ring portion 131 and extends upward, but is formed in a square frame shape having an extended size than the ring portion 131, and a plurality of water passages penetrating along the extending direction of the ring portion 131 The hole 135a is formed.

When the water blocking block portion 135 is divided, the lower panel 136 and the lower panel 136 extending integrally formed from the upper portion of the ring portion 131 to have a wider width than the diameter of the ring portion 131 are horizontally formed. The vertical panel 137 extending upward from both ends and the upper panel 138 interconnecting the upper ends of the vertical panels, and vertical reinforcement extending from the bottom surface of the upper panel 138 to the upper surface of the lower panel 136 It has a structure having a horizontal reinforcement 142 extending horizontally between the flesh 141 and adjacent vertical reinforcement 141 and between the vertical panel 137 and the vertical reinforcement 141. On the upper surface of the upper panel 138, seating guide protrusions 139 protruding upward are formed spaced apart from each other in order to guide the seating of the scaffold 150, which will be described later, and suppress the separation.

In addition, the inclined reinforcement 145 is formed to be spaced apart from each other between the upper outer surface of the ring portion 131 and the lower panel 136 to be inclined to be joined. An empty space along the extending direction of the ring portion 131 in the water blocking block portion 135 becomes a water passing hole.

In addition, the vertical panel 137 on one side is formed with a protruding fitting protrusion 137a to be mutually engaged along the second direction, and the fitting protrusion 137a is provided on the opposite vertical panel 137 on the other side. Insertion groove 137b is inserted therein. In addition, insertion holes for inserting bolts, which are coupling members, are formed in the fitting protrusions 137a and the fitting grooves 137b, respectively. Therefore, the unit assembly units 130 closely along the second direction may be assembled by inserting a bolt through an insertion hole formed in the fitting protrusion 137a and the fitting groove 137b and suppressing separation with a nut.

The side inclined plate 132 extends in a plate shape in a direction away from the ring portion 131 as it progresses downward from both outer surfaces of the ring portion 131, respectively. Two of the side inclined plates 132 extend inclined downward from the middle height of the outer surface of the ring portion 131, respectively. The side inclined plate 132 partially contributes to reduction of rolling.

The inclination angle of the side slope 132 is applied to be 30 to 60 degrees with respect to the horizontal plane, and preferably to be 45 degrees.

The unit assembly units 130 are arranged along the first direction, which is the extending direction of the circular synthetic resin tubes 110 through the ring portion 131, and the other water passing block portion 135 in a direction orthogonal to the first direction. They are mutually coupled as described.

The footrest 150 is formed in a plate shape and extends along the first direction to the upper surfaces of the unit assembly units 130 and is coupled through a coupling member such as a bolt or a screw. Of course, the footrest 150 may be formed of a metal material in addition to the synthetic resin material.

The outermost rolling reduction plate 170 is formed in a plate shape. The outermost rolling reduction plate 170 is a side inclined plate disposed on the outermost side of the outermost unit assembly units 130 respectively disposed on the outermost side along a second direction orthogonal to the first direction of the unit assembly unit 130 Bonding to 132 along the first direction reduces rolling by blue.

The outermost rolling-reduction plate 170 is formed to have a width corresponding to the length along the inclined direction of the side inclined plate 132 and a length corresponding to the length of the circular synthetic resin pipe 110.

The outermost rolling reduction plate 170 may be coupled to the side joining guide plate 160 using bolts and nuts. At this time, as shown in FIG. 1, the outermost rolling reduction plate 170 is coupled to the side inclined plate 132 so that a passage A through which the seawater can pass is formed through the upper portion of the outermost rolling reduction plate 170. . The outermost rolling reduction plate 170 may be coupled to the lower side of the side inclined plate 132.

On the other hand, the bottom surface of the ring portion 131 of the unit assembly unit 130 is spaced apart from each other at equal intervals from the center of the bottom surface is formed with a plurality of contact protrusions 133 that are in contact with the ground when supported. The contact protrusion 133 is formed in a substantially rectangular shape, but is formed with a through hole 133a capable of passing along the longitudinal direction. The through hole 133a of the contact protrusion 133 also functions to suppress damage by allowing fine deformation when contacted with rocks or the like on the ground.

The contact protrusion 133 is formed such that the lower end is flush with the lower end of the side inclined plate 132 so as to share the load with the side inclined plate 132 when seated on the ground.

On the other hand, the portion where the footbridge 10 is coupled has relatively concentrated load, and a buoyancy auxiliary body 180 for reinforcing buoyancy for the load concentrated portion is formed between the unit assembly units 130 along the first direction. It is designed to reinforce the buoyancy by being combined with the unit assembly unit 130 or the circular synthetic resin pipe 110 in the spaced space 102.

The buoyancy auxiliary body 180 is formed to be coated in the form of a square box made of LF material and is formed on the auxiliary buoyancy body 181 having a closed internal buoyancy space and the auxiliary buoyancy body 181 to form a circular synthetic resin tube 110 or As a coupling body for coupling with the unit assembly unit 130, the circular synthetic resin tube 110 extends in a plate shape in the direction in which the width extends from the auxiliary buoyancy body 181 on the upper and lower surfaces of the auxiliary buoyancy body 181 and It has a structure having a flange 183 in which a coupling hole 185 that can be coupled using a binding line 187 is formed.

In addition, the flange 183 can be coupled through a coupling member such as a bolt and the lower panel 136 of the water passage block portion 135, of course.

The buoyancy auxiliary body 180 has a structure arranged between the ring portions 131 of three unit assembly units 130 assembled along the second direction. In addition, as illustrated in FIG. 5, when the portion where the load is concentrated by other elements other than the footbridge occurs, the buoyancy auxiliary body 180 is spaced apart from the circular synthetic resin pipe 110 and the unit assembly unit 130. Of course, it can be additionally mounted in the space.

Meanwhile, as shown in FIG. 6 to further reduce rolling, the outermost of the outermost unit assembly units 130 respectively disposed on the outermost side along the second direction orthogonal to the first direction among the unit assembly units 130. It is possible to mount the inner rolling reduction plate 172, which is bonded along the first direction to the side swash plates 132 disposed inside the side swash plates 132 disposed in, to reduce rolling by blue. Of course. The inner rolling reduction plate 172 is also coupled to the side inclined plate 132 such that a passage through which the seawater can pass is formed through the upper portion, similar to the coupling method of the outermost rolling reduction plate 170.

In the above description, the floating structure 100 is structured so that it can be used as a floating bridge to which the footbridge 10 can be coupled, and it can be used for other purposes while floating on the sea.

According to the floating buoyancy structure described above, while utilizing the buoyancy of the synthetic resin pipe as much as possible, by installing the outermost rolling reduction plate 170 and the inner rolling reduction plate through the side inclined plate inclined at both ends along the longitudinal direction, the blue light is generated. It provides the advantage of reducing the fluctuation.

110: circular synthetic resin tube 130: unit assembly unit
132: side inclined plate 150: scaffolding
170: outermost rolling reduction plate 172: inner rolling reduction plate
180: buoyancy aid

Claims (2)

delete A plurality of circular synthetic resin pipes extending in a circular shape having a hollow hollow and spaced apart from each other so as to form buoyancy;
The circular synthetic resin pipe is integrally formed on the upper portion of the ring portion and the ring portion that can be received and supported in a through state, and extends upwardly, but is formed in a rectangular frame shape having an extended size than the ring portion, but penetrates along the extending direction of the ring portion The water blocking block portion having a plurality of water passing holes and a plurality of side inclined plates extending in a plate shape in a direction away from the ring portion as it progresses downward from both side outer surfaces of the ring portion, and extending directions of the circular synthetic resin pipes through the ring portion Unit assembly units are arranged spaced apart from each other in the first direction, and are mutually coupled with other water-blocking portions in a direction orthogonal to the first direction;
A plurality of scaffolds formed in a plate shape and coupled to the upper surfaces of the unit assembly units along the first direction;
The unit assembly unit is formed in a plate shape on the side inclined plate disposed on the outermost side of the outermost unit assembly units respectively disposed on the outermost side along the second direction orthogonal to the first direction along the first direction An outermost rolling reduction plate joined to the side inclined plates to reduce rolling caused by blue;
It is provided with a buoyancy supplement to reinforce the buoyancy by being combined with the unit assembly unit or the circular synthetic resin pipe in a separation space formed between the unit assembly units are spaced apart from each other along the first direction;
The buoyancy auxiliary
An auxiliary buoyancy body which is formed to be coated in a quadrangular enclosure made of FRP material and has a closed internal buoyancy space;
It is provided on the auxiliary buoyancy body is formed on the coupling body for coupling with the circular synthetic resin tube or the unit assembly unit;
The outermost rolling reduction plate is coupled to the side inclined plate so that a passage through which the seawater can pass is formed through the upper portion of the outermost rolling reduction plate,
Among the unit assembly units, for side swash plates disposed inside between side swash plates disposed on the outermost side of the outermost unit assembly unit respectively disposed on the outermost side in a second direction orthogonal to the first direction, the Marine rolling structure, characterized in that it further comprises; an inner rolling reduction plate that is bonded along the first direction to reduce the rolling by the blue.

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