KR101694406B1 - Ocean floating structure with decrease function of rolling and pitching, and the manufacturing method thereof - Google Patents

Abstract

The present invention provides an FRP floating structure of a docking facility for a vessel, a deck for tourism on the water, a floating platform, or a floating fish cage, as an FRP floating member capable of storing ballast water is connected at fixed intervals on the bottom of an FRP foothold for entrance of a user. The height of the floating member arranged on the center of the bottom of the foothold is lower than that of the floating member arranged on the outer side of the bottom of the footboard, and the bottom on both sides of the each floating member protrudes to the lower side to be convex more than the bottom on the center. The forward, backward, and horizontal rolling and pitching of the floating structure due to waves are maximally reduced, so safety of using the floating structure can be improved. The FRP floating structure is applied with a manufacturing method of bonding and connecting a metal reinforcing frame, an overlay layer of the frame, and the floating member to the bottom in order by turning over the footboard prefabricated in advance. Therefore, the FRP floating structure having beautiful and clean footboards can be manufactured at low costs within a short time.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a floating structure capable of reducing vibration and a manufacturing method thereof,

A reinforcing frame is assembled on the bottom surface of a foot plate made of FRP material, and a FRP overlay layer having a predetermined thickness is laminated along the surface of the reinforcing frame to integrally form a reinforcing frame with the foot plate. And a plurality of FRP buoyant materials are integrally adhered and connected to a foot plate at a predetermined distance to be used as a deck for marine use, a deck for water tourism, a floating bridges and a cage farm, etc. .

In general, floating structures such as marine docking facilities or cage farms installed in waters such as coastal waters and lakes, bind floating materials such as styrofoam in a certain shape to the lower part of the scaffold that provides the user's access or transportation path And a railing or the like for safety of the user including the bumper means for shock mitigation or the braid for binding the net is additionally provided on the foot plate, if necessary.

If the floating structure such as the ship's docking facility or the cage culture farm is installed according to the conventional method using the buoyancy material such as styrofoam as described above, the buoyancy material is easily broken by the wave or the external impact, The debris from the buoyant material has a problem of polluting the coastal waters and the lake. Also, when the floating structure is manufactured, a lot of time and manpower must be put into work for binding the buoyant material such as styrofoam with the footstool.

In recent years, due to the problems of conventional floating structures using styrofoam or the like as a buoyant material as described above, the corrosion resistance, the mechanical strength and the recyclability are excellent, and the foot plate and the buoyant material can be easily and firmly adhered by the heat fusion method or the laminating method. Various floating structures such as a marine docking facility and a lashing cage farm are being manufactured by using PE (polyethylene) or FRP (fiber reinforced plastic) materials which can be assembled and adhered to each other.

However, even in the floating structure made of PE or FRP material, as the buoyant material provided at the lower side of the footrest has the same height, the floating structure in front, back, left and right directions, In other words, there is a problem that rolling and pitching are severely caused, thereby threatening the safety of the user. In floating structures such as decks for water tourism and floating floats, which are relatively frequently used by many people, This is a serious problem.

In order to solve the above problems, a closed space is partitioned on the inner bottom of the buoyancy material, and then a certain amount of ballast water (ballast water) is injected into the space to suppress the fluctuation phenomenon of the floating structure. However, this attempt has not been an active countermeasure to more reliably reduce the fluctuation of the floating structure.

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On the other hand, in the case of the FRP floating structure, the reinforcement frame is placed over the plurality of buoyant member upper surfaces, and then, with each buoyancy member being adhered and connected to the reinforcement frame at first, The FRP floating structure is excessively consumed in the time and cost of fabrication, and the upper surface of the footrest is not smooth and has a very rough or irregular surface, so that the appearance of the floating structure is also affected by the irregular manufacturing process There was a problem that had a bad influence.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a buoyancy compensating apparatus in which a height of a buoyant material disposed on a center side of a footrest is disposed on the outer side of a footrest And the bottom surface of each side end of each buoyant member bulges out downward from the bottom surface of the central side so that the front and rear and left and right swinging of the floating structure by the wave or the like, The main technical problem is to reduce the pitching phenomenon as much as possible.

In addition, by applying a manufacturing method in which a prefabricated footrest is turned over, and a metal reinforcing frame and the overlay layer and the buoyancy material of the frame are sequentially bonded and connected from the bottom face thereof, the FRP floating body having a more beautiful, Another technical problem is to make the structure to be manufactured at a low cost in a shorter time.

According to the present invention as a means for solving the above technical problems, a reinforcing frame is assembled on the bottom surface of a foot plate made of FRP material, an overlay layer is formed by FRP over the surface of the reinforcing frame, Wherein the buoyant member is formed into a rectangular tube shape having a "U" -shaped cross section, and the buoyant member is formed in a width direction of the foot plate Wherein a height of a buoyant disposed at a center side of the footrest is lower than a height of a buoyant disposed at an outer side of the footrest by about 10 to 30 cm, And a lateral transverse bulkhead for storing ballast water in the bottom space of the buoyant material using an injection valve is provided in the inner lower portion Installed and, it said two side ends the bottom surface of each buryeokjae may be formed as protrusions bulging the ridge downward.

The method for manufacturing a floating structure according to the present invention comprises the steps of: preparing a foot plate having a predetermined thickness by using an FRP material, and making a rectangular tubular buoyant material having a U-shaped cross section from an FRP material; A reinforcing frame disposing step of disposing a metal reinforcing frame over the bottom surface of the footrest with the floor surface of the footrest completed beforehand being facing upward; A reinforcing frame covering step of integrally fixing the reinforcing frame to the bottom surface of the footrest by forming an overlay layer for reinforcing frame coating by laminating FRP to a predetermined thickness along the surface of the reinforcing frame; And a buoyant material connecting step of integrally adhering the upper surface of the buoyant material to the bottom surface of the footrest integrally with the overlay layer of the reinforcing frame as a base in a state in which the top surface of the buoyant material faces downward, At least three buoyant materials are adhered and connected at a predetermined interval in the width direction of the footstool or the longitudinal direction of the footstep, and the height of the buoyancy material disposed at the center of the footstep is greater than the height of the buoyancy material disposed on the outer side of the footstep 10 to 30 cm, and the buoyant material is provided with transverse bulkheads for storing the ballast water in the bottom space of the buoyant material body by means of an injection valve, while the bottom surfaces of both side ends of the buoyant material body are downward A protruding portion protruding in a bulging shape is used.

According to the present invention as described above, the buoyant material portion located on the outer side of the footrest is deeply immersed in seawater rather than the buoyant material portion located at the center portion of the footrest, , The right rolling, i.e., the rolling and pitching phenomena are reduced as much as possible, thereby providing the effect of doubling the safety according to the use of the floating structure.

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On the other hand, unlike the conventional method of constructing the reinforcing frame and the foot plate sequentially from the upper face of the buoyant, the pre-manufactured foot plate is turned over and the reinforcing frame, the overlay layer and the buoyant material are sequentially bonded and connected from the bottom face thereof , It is possible to manufacture FRP floating structure having a more beautiful and clean exterior footstool in a shorter time and at a lower cost

1 is an exploded perspective view of a floating suspended structure of a rocking reduction type according to the present invention.
Figure 2 is a front view of the combined state of Figure 1;
Figure 3 is a side view of Figure 2;
4 is a sectional view taken along the line AA in Fig.
5 is a side cross-sectional view of a buoyant material used in the present invention.
FIG. 6 is an enlarged cross-sectional view of the main part of the present invention. FIG.

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

As shown in FIGS. 1 to 6, a floating structure 3 according to the present invention is mounted on a bottom surface of a footrest 1 made of FRP material, and the reinforcing frame 3 3 and a plurality of buoyant materials 5 made of FRP material are stacked on the overlay layer 4 as a base and spaced apart from each other by a predetermined distance ).

Although the overlay layer 4 is shown in FIG. 1 as a structure, the reinforcing frame 3 is assembled on the bottom surface of the footrest 1 and the FRP The overlay layer 4 may be formed with a predetermined thickness from the surface of the reinforcing frame 3 to the bottom surface of the footrest 1 as shown in FIG. 6, The frame 3 is preferably a metal pipe having a rectangular cross section, for example, a steel pipe having a dimension of 100 mm x 100 mm.

As shown in the figure, a buffer bumper (2) can be additionally provided on the periphery of the footrest (1) to prevent collision of a ship or the like, The railing 8 may be additionally provided for the safety of the stowing rope 10 and the binding of the mooring rope may be additionally provided at each corner of the stool 1 so that the stowing structure 10 of the present invention can be moored in the sea. Brackets, etc., can be additionally installed.

It is preferable that the upper surface of the footrest 1 is formed as a non-slip surface (corresponding to a checkered pattern in FIG. 1) that prevents slippage of the user, and the edge side of the footrest 1 has a predetermined width The mounting of the buffer bumper 2, the railing 8, the bracket, and the like and the assembling work of the reinforcing frame 3 can be carried out more quickly and firmly And it is preferable to coat the bottom surface of the foot plate 1 and the outer surface of the buoyancy material 5 with an antifouling paint so as not to adhere to the back cover.

As a constituent element constituting the first essential part of the present invention, each of the buoyant materials 5 is formed into a rectangular tube having a "U" -shaped cross section, and then the tubular material is uniformly spaced in the width direction or the longitudinal direction of the footrest The height of the buoyant material 5 disposed on the center side of the footrest 1 is set to be about 10 to 30 cm lower than the height of the buoyant material 5 disposed on the outer side of the footrest 1, The bottom surface of each side end of each buoyancy material 5 is formed as a protruding portion 5b bulging up to 10 to 30 cm in a downward direction compared with the center side bottom surface.

2 and 3, a portion of the buoyancy material 5 located on the outer side of the footrest 1 is disposed on the foot plate 1, on the basis of the overall arrangement state of the buoyancy material 5 installed on the bottom surface of the footrest 1. [ will that it locks (1) deeply into the sea water to the depth corresponding to the buryeokjae 5 than h ₁ and h ₂ portion positioned at the center of, through this structural improvement, before the floating structure 10, due to blue, and then And the left and right rocking, that is, the rolling and pitching phenomenon, can be minimized, thereby doubling the safety according to the use of the floating structure 10.

Defining a buryeokjae 5, the height difference (h _1, h ₂₎ of a portion positioned on the outer side of buryeokjae 5 portion and the foot plate (1) which is located at the center of the foot plate (1) as described above into 10 ~ 30cm range The function of reducing the fluctuation phenomenon of the floating structure 10 may not be achieved properly at a small height difference of less than 10 cm, and if the height difference exceeds 30 cm, the portion of the outer side buoyant material 5 is somewhat The volume and weight of the floating structure 10 are unnecessarily increased and a relatively large amount of the ballast water 13 must be injected into the outer side buoyancy material 5. [

Although a total of three buoyant members 5 are shown as being spaced at regular intervals along the longitudinal direction of the footrest 1, the buoyant members 5 having a longer length are arranged along the width direction of the footrest 1 A larger number of buoyant materials 5 may be provided in accordance with the dimensions of the footrest 1 and each buoyancy material 5 may be provided on the bottom surface of the footrest 1 or on the surface thereof The overlay layer 4 is integrally connected to the overlay layer 4 by a bonding portion 14, and the bonding portion 14 is also formed by laminating FRP.

5, it is preferable to inject a predetermined amount of ballast water into the inner lower portion of each buoyancy material 5. In order to achieve this, as shown in Fig. 5, in the lower portion of the inside of the buoyancy material body 9, And an inlet valve for injecting the ballast water 13 is provided at one lower end (left end in the figure) of the buoyancy material body 9 7, and the injection valve 7 simultaneously performs the function of a cleaning agent, such as a chemical injection for removing biological substances attached to the inside of the storage space of the ballast water 13.

At least two longitudinal longitudinal bulkheads 12 (four in the figure) are provided along the upper surface of the transverse bulkhead 11 in the upper portion of the inside of the bucky body 9 so that the buoyant body 9 The floating structure 10 is more securely used so that seawater does not flow into the entire inner space of the buoyancy material body 9 even if cracks or breakage occurs in a part of the buoyancy material body 9. The overlay layer 4) and an assembling groove 5a engaged with the reinforcing frame 3 in a concavo-convex manner.

The check valves 6 and 6a for external air circulation are installed on one side of each of the buoyant materials 5 so that the check valves 6 and 6a are connected to the external air inflow check valve 6, When the internal pressure of the buoyant material 5 is lowered, a certain amount of external air is allowed to flow into the buoyancy material 5 through the check valve 6, When the inner pressure of the buoyancy material 5 is increased, a certain amount of the inner air is discharged to the outside through the check valve 6a, so that the buoyancy is not fluctuated even for a long period of use, The safety of the structure 10 can be further maximized.

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5, when a plurality of longitudinal partition walls 12 are provided on the inner upper side of the buoyancy material body 9 so that the inner upper space of the buoyancy material body 9 is divided into a plurality of closed spaces, 6a is applied to each closed space and when the buoyancy material 5 is integrally connected to the footrest 1, the connecting portion between the buoyant material 5 and the footrest 1 is sealed The upper end face of the buoyancy material body 9 may have an open form as required.

The manufacturing method of the present invention for substantially manufacturing the floating structure 10 of the present invention having the above-described structure is a method of manufacturing the footrest 1 with a predetermined thickness (preferably about 10 mm or less) using FRP material On the other hand, after a preforming step of making a buoyancy material 5 having a "∪" -shaped cross-section in which the projecting portions 5b are formed on the bottom surfaces of both side ends is made of FRP material in accordance with the height of the buoyancy material 5, The structure is carried out in an inverted form.

In other words, the reinforcement frame disposing step of disposing the metal reinforcement frame 3 over the bottom surface of the footrest 1 is firstly roughened with the bottom surface of the footrest 1 finished in advance being directed upward The FRP is laminated with a predetermined thickness (preferably about 5 mm or less) along the surface of the reinforcing frame 3 to form an overlay layer 4 for covering the reinforcing frame 3, thereby reinforcing the bottom surface of the footing 1 After the reinforcing frame covering step of fixing the frame 3 integrally, the buoyant material connecting step of integrally gluing the respective buoyancy materials 5 to the bottom surface of the footrest 1 integrally with the overlay layer 4 as a base .

At least three buoyancy members 5 are mounted on the foot plate 1 in the width direction of the foot plate 1 as described above in a state in which the top face of the buoyancy member 5 in which the mounting groove 5a is formed faces downward, The buoyancy material 5 having a relatively low height is disposed at the center of the footrest 1 and the footrest 1 is integrally attached and connected to the footrest 1 at a predetermined interval in the longitudinal direction of the footrest 1, The buoyancy material 5 having a size 10 to 30 cm larger than the center side buoyancy material 5 is disposed on the outer side of the buoyancy material 5 and then integrally connecting the buoyancy materials 5 to the footrest 1.

After the floating structure 10 according to the present invention is manufactured through the connection of the buoyant material as described above, the floating structure 10 is turned upside down so that the footrest 1 is placed on the upper side, The ballast water 13 is injected into the ballast water 13 and the floating structure 10 is transported and installed in the sea after the injection of the ballast water 13 is completed. (6a) may be provided in advance on the buoyant material body (9) in advance when the buoyant material (5) using FRP is preliminarily manufactured.

Unlike the conventional method of constructing the reinforcing frame 3 and the foot plate 1 sequentially from the upper surface of the buoyancy material 5, when the FRP floating structure 10 is manufactured in the above-described manner, The completed pedestal 1 can be inverted and the reinforcing frame 3, the overlay layer 4 and the buoyant material 5 can be adhered and connected sequentially and sequentially from the bottom surface thereof. It is possible to provide a FRP floating structure 10 having a foot plate 1 with a more beautiful and clean appearance through the preliminary fabrication of the foot plate 1 as well as a remarkably shortened and reduced cost.

Lastly, although the floating structure 10 of the present invention described with reference to the accompanying drawings is manufactured by using the FRP material, other materials such as PE are used to form the floating structure 10 And the manufacturing method according to the present invention is also applicable to manufacturing a general type of FRP floating structure other than the shaking reduction type. It is also possible to manufacture the FRP floating structure according to the technical idea It is to be understood that it is included in the scope of course.

1: foot plate 1a: protruding portion 2: buffer bumper
2a: Assembly bolt 2b: Assembly nut 3: Reinforcing frame
4: overlay layer 5: buoyant material 5a: assembly groove
5b: projection 6,6a: check valve 7: injection valve
8: Railing 9: Buoyant material body 10: Floating structure
11: transverse bulkhead 12: longitudinal bulkhead 13: ballast water
14:

Claims (5)

A reinforcing frame 3 is assembled on the bottom surface of a foot plate 1 made of FRP material and an overlay layer 4 made of FRP is formed on the surface of the reinforcing frame 3, A float for floating structure (10) comprising a plurality of buoyant members (5) connected integrally with a footrest (1) at regular intervals with the overlay layer (4) as a base,
The buoyancy members 5 are arranged in at least three positions in the width direction of the footrest 1 or in the longitudinal direction of the footrest 1 in the form of a rectangular tube having a U-shaped cross section, The height of the buoyant material 5 disposed on the side of the foot plate 1 is set to be about 10 to 30 cm lower than the height of the buoyant material 5 disposed on the outer side of the footrest 1,
A lateral transverse bulkhead 11 for storing the ballast water 13 in the bottom space of the buoyant material 5 is provided at an inner lower portion of each of the buoyant materials 5 using an injection valve 7, Wherein the floors of both side ends of the buoyancy material (5) are formed as protrusions (5b) bulging upward in a downward direction. delete The float structure as claimed in claim 1, wherein at least two longitudinal longitudinal bulkheads (12) are provided along the upper surface of the transverse bulkhead (11) inside the respective buoyancy members (5). A method of manufacturing a floating structure (10) for a sea floor by connecting a plurality of buoyancy materials (5) to a bottom surface of a footrest (1) at regular intervals,
A prefabricating step of fabricating the footrest 1 having a predetermined thickness by using the FRP material and fabricating a rectangular tube-shaped buoyant material 5 having a "U" -shaped cross section with FRP material; A reinforcing frame disposing step of disposing a metal reinforcing frame (3) over the bottom surface of the footrest (1) in a state in which the bottom surface of the footrest (1) completed in advance is facing upward; The FRP is laminated to a predetermined thickness along the surface of the reinforcing frame 3 to form the overlay layer 4 for covering the reinforcing frame 3 so that the reinforcing frame 3 is integrally fixed A reinforcing frame covering step; The upper face of the buoyancy material 5 is integrally adhered to the bottom face of the foot plate 1 with the overlay layer 4 of the reinforcing frame 3 as a base in a state in which the upper face of the buoyancy material 5 faces downward And connecting the buoyant material to be connected to each other in sequence,
At least three buoyant members (5) are adhered and connected at a predetermined interval in the width direction of the footrest (1) or the longitudinal direction of the footrest (1) The height of the buoyant material 5 is set to be about 10 to 30 cm lower than the height of the buoyant material 5 disposed on the outer side of the footrest 1. The buoyant material 5 is held by the buoyant material body 9 A lateral transverse bulkhead 11 capable of storing the ballast water 13 is provided in the floor space of the buoyant body 9 and a protruding portion 5b in which bottom surfaces of both side ends of the buoyant body 9 are bulged downward, Wherein the floating suspension structure is formed of a material having a high thermal conductivity. The buoyancy member (5) according to claim 4, characterized in that at least two longitudinal longitudinal bulkheads (12) are provided inside the buoyant body (9) along the upper surface of the transverse bulkhead Wherein the floating structure is formed on the surface of the substrate.

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