KR102144957B1 - Buoy - Google Patents

Abstract

The present invention relates to a buoy that not only maximizes cushioning force by an inner horizontal interlayer bundle (100) and an outer vertical interlayer bundle (200), but also guarantees rigidity in the horizontal and vertical directions at the same time, so that the buoy prevents crushing in the horizontal direction (if the buoy is easily crushed, seawater penetrates due to damage to the outermost surface fusion layer (200a), which shortens the lifespan) when the buoy is tied with a rope, thereby enabling stronger coupling when installed with marine facilities.

Description

Buoy{BUOY}

The present invention relates to a buoy, and more specifically, maximizes the cushioning force by the inner and horizontal interlayer bundles and the outer vertical interlayer bundle, as well as ensuring the rigidity in the horizontal direction and the vertical direction at the same time, and when binding with a rope, especially in the horizontal direction. It is related to a buoy that enables a stronger bond when installed with marine facilities by preventing the crushing of the water (if it is easily crushed, the seawater penetrates due to the breakage of the outermost surface fusion layer, which shortens the lifespan).

In general, buoys are installed to fix the facilities of aquaculture farms, instruct the route to help safe navigation of the ship, or to warn of the presence of dangerous substances such as reefs and sunken ships, and also to hold fishing nets or to mark the location of fishing nets. It is used for various purposes, such as being used to float an aquatic solar facility on the water.

Among the buoys, styrofoam buoys are the most widely used.Styrofoam buoys are easily damaged due to poor durability, and are not only difficult to collect and dispose of because they are crushed into granules. It has a negative impact on the marine and terrestrial environments, such as damage to the natural landscape and the sea.

FIG. 1A is a front view of an eco-friendly buoy wrapped around a styrofoam buoy according to Prior Art Document 1 (Korean Patent Publication No. 1600525) and a styrofoam buoy applied to the manufacturing method thereof, and FIG. 1B is a front view of the body cover of Prior Art Document 1 It is a front cross-sectional view of a contracted state along the outer diameter of the buoy, and FIG. 1C is a perspective view of a completed state of the eco-friendly buoy of Prior Art Document 1.

Prior Art Document 1 is to form a high-density Styrofoam buoy 10 by foaming in a mold by supplying a polyethylene raw material as shown in FIGS. 1A to 1C, and the high-density Styrofoam buoy 10 is a cylindrical body 11 A bending groove 12 capable of fixing the rope on both sides is formed, and the side surface 13 is formed to have a rounded corner outside the bending groove 12.

The eco-friendly buoy 50 for molding by wrapping the entire outer diameter of the Styrofoam buoy 10 is a body cover 30 that is integrally joined at the inner part of the body 11 and the bending groove 12 and the side 13 Done.

The body cover 30 is formed into a sheet shape to have a thickness of 0.8 to 2.8 mm by extruding a synthetic resin.

By the way, prior art document 1 has a limitation that cannot avoid the problem that the high-density Styrofoam buoy 10 is easily damaged when the body cover 30 is damaged, which is the main cause of environmental pollution.

2 is a schematic front view showing a buoy manufacturing apparatus according to Prior Art Document 2 (Korea Patent Publication No. 1941174) patented by the applicant of the present application, and FIGS. 3A to 3G are schematic right sides of the buoy manufacturing apparatus according to Prior Art Document 2 It is a process chart showing the operation process based on the diagram.

The buoy manufacturing apparatus according to Prior Art Document 2 has a center piston 12 that is vertically moved by a hydraulic pump 11 as shown in FIGS. 2 to 3G and has posts 13 erected at each corner. A horizontal piston 22 that is supported by the base 10 and the posts 13 and is moved up and down according to the vertical movement of the center piston 12 and is moved back and forth by the hydraulic pump 11 while having the horizontal rail 21 A lifting plate 20 having a, an underheating mold 30 mounted on a horizontal rail 21 and moving forward and backward according to the horizontal piston 22, and an upper frame fixed to the upper end of the posts 13 The center fixing ram 41 assembled in 40, the upper heating mold 50 and the horizontal piston 22, which are mounted on the center fixing ram 41 and merged when the underheating mold 30 is raised, move forward The underheating mold (30) is moved forward and the synthetic resin foam (M) is inserted, and then the horizontal piston (22) is moved backward to move the underheating mold (30) backward and the hydraulic pump (11) is driven to the center. By raising the piston 12, the underheating mold 30 is incorporated into the upper heating mold 50 to form a surface fusion layer (P) along the all-round surface of the synthetic resin foam bundle (M) to form a buoy (B). After completion, the center piston 12 is lowered by the drive of the hydraulic pump 11 so that the underheating mold 30 is separated from the upper heating mold 50 and the horizontal piston 22 is moved forward. It includes a controller 60 for controlling the buoy B to be demolded while the heating mold 30 is advanced.

The applicant of the present application intends to propose a buoy of the present invention with reference to the buoy manufacturing apparatus according to the prior art document 2 while overcoming the disadvantages of the prior art document 1.

Republic of Korea Patent Publication No. 1600525-An eco-friendly buoy wrapped around a Styrofoam buoy and its manufacturing method Republic of Korea Patent Publication No. 1941174-Buoy manufacturing device

It is an object of the present invention to maximize the cushioning force by the inner horizontal interlayer bundle and the outer vertical interlayer bundle, as well as guarantee the rigidity in the horizontal and vertical directions at the same time, so that when tied with a rope, it is particularly crushed in the horizontal direction. In this case, it is intended to provide a buoy that enables a stronger bonding when installing with marine facilities by preventing the seawater from penetrating due to damage of the outermost surface fusion layer and shortening the lifespan].

It is an object of the present invention to reinforce the strength of the horizontal state as a horizontal interlayer stiffener together with the synthetic resin foamed discs of the inner horizontal interlayer bundle, and at the same time reinforce the strength of the vertical state as a synthetic resin foam sheet of the outer vertical interlayer bundle. When trying to support the structure, it is possible to increase the assemblability with a solid bundle of ropes, and in particular, even if the outermost surface fusion layer is damaged by an external impact, the air cell in the inner horizontal interlayer bundle by the outer surface fusion layer is maintained as it is. By preserving buoyancy, it is possible to prevent inundation of marine facilities in advance, and furthermore, the gap between the horizontal interlayer reinforcement and the gap between the vertical layers allows more air to be contained together with the air cells, thus maximizing buoyancy. It is in the provision of a buoy.

An object of the present invention is to maximize the buoyancy by the air contained in the horizontal air cap, and even if seawater penetrates into the outer vertical interlayer bundle and the inner horizontal interlayer bundle due to breakage of the outermost surface fusion layer and the outer surface fusion layer, horizontal air It is to provide a buoy to prevent environmental pollution by preventing or delaying the phenomenon that the buoy is submerged into the sea as much as possible by maintaining a minimum buoyancy by the air embedded in the cap.

It is an object of the present invention as a detailed configuration of synthetic resin foam discs that constitute the inner horizontal interlayer bundle, while embedding the inner horizontal interlayer bundle covered with the outer surface fusion layer in the outer vertical interlayer bundle covered with the outermost surface fusion layer. In addition to the inner synthetic resin foam disks having vertical holes, the outer synthetic resin foam disks stacked on both sides of the inner synthetic resin foam disks are used to further maximize the air content of the vertical holes to maximize buoyancy. It is to provide a buoy to allow.

An object of the present invention is to allow vertical holes of different sizes and different shapes to be positioned differently when stacking synthetic resin foamed disks to prepare a disk bundle, so that the pressure applied when binding the rope is applied in the inner horizontal interlayer bundle. It is to provide a buoy to prevent the buoy from being crushed as much as possible by making it dispersed.

An object of the present invention is to protect the outer surface fusion layer of the inner horizontal interlayer bundle by inserting the upper and lower synthetic resin foam covers into the upper and lower inner grooves, so that no matter where damage occurs in the outermost surface fusion layer, the outer surface fusion layer can be completely preserved. It is to provide a buoy to be able to.

It is an object of the present invention to laminate the upper and lower synthetic resin foam covers with the upper and lower interlayer thermoplastic flexible films interposed therebetween in order to actively protect the outer surface fusion layer of the inner horizontal interlayer bundle, and at the same time, the synthetic resin foam sheet is wound together with the outer interlayer thermoplastic flexible film. In other words, the inner horizontal interlayer bundles are stacked together with the stacking of synthetic resin foam disks and the winding of the synthetic resin foam sheets with the upper and lower layers of the thermoplastic flexible film and the outer layer interlayer thermoplastic flexible film, so that the assembly workability as well as the assembly between the inner horizontal layers It is to provide a buoy to maximize the lifespan as well as productivity by realizing protection at the same time.

The present invention for achieving the above object,

Inner horizontal interlayer bundles in which the primary foamed synthetic resin foam disks are laminated together with the horizontal interlayer reinforcement material, placed in the first heating mold, and secondly foamed to have an outer surface fusion layer,

The outermost surface of the outermost surface by winding the first foamed synthetic resin foam sheet along the outer edge of the inner horizontal interlayer bundle to form a vertical interlayer gap orthogonal to the horizontal interlayer reinforcement material into the second heating mold while third foaming. Including the outer vertical interlayer bundles to have a fusion layer is a basic feature of the technical construction.

The present invention not only maximizes the cushioning force by the inner horizontal interlayer bundle and the outer vertical interlayer bundle, but also ensures the rigidity in the horizontal and vertical directions at the same time, so that when tied with a rope, it is particularly crushed in the horizontal direction. By preventing the seawater from penetrating due to the damage of the outer surface fusion layer and shortening the lifespan], there is an effect of enabling a stronger bond when installing with marine facilities.

The present invention reinforces the strength of the horizontal state as a horizontal interlayer stiffener along with the synthetic resin foam disks of the inner horizontal interlayer bundle, and at the same time reinforces the strength of the vertical state as a synthetic resin foam sheet of the outer vertical interlayer bundle to support heavy marine facilities. In addition, it is possible to increase the assembleability with a solid bundle of ropes when making a rope, and in particular, even if the outermost surface fusion layer is damaged by an external impact, the air cells in the inner horizontal interlayer bundle by the outer surface fusion layer are maintained as it is to increase the buoyancy. Preservation enables the inundation of marine facilities to be prevented in advance, and furthermore, the gap between the horizontal interlayer reinforcement and the vertical interlayer gap allows more air to be contained together with the air cells, thereby maximizing buoyancy. There is.

The present invention maximizes buoyancy by the air contained in the horizontal air cap, as well as damage to the outermost surface fusion layer and the outer surface fusion layer, even if seawater penetrates into the outer vertical interlayer bundle and the inner horizontal interlayer bundle. By maintaining a minimum buoyancy by the built-in air, it is effective to prevent or delay the phenomenon of the buoy being submerged into the sea as much as possible to prevent environmental pollution.

The present invention is a vertical hole as a detailed configuration of synthetic resin foam discs that constitute the inner horizontal interlayer bundle while embedding the inner horizontal interlayer bundle covered with the outer surface fusion layer in the outer vertical interlayer bundle covered with the outermost surface fusion layer. In addition to the inner synthetic resin foam discs having a sizing, the outer synthetic resin foam discs stacked on both sides of these inner synthetic resin foam discs are made to further maximize the air content rate by the vertical hole to maximize the buoyancy. It works.

The present invention allows vertical holes of different sizes and different shapes to be positioned differently when stacking synthetic resin foam disks to prepare a disk bundle, so that the pressure applied when binding the rope is dispersed in the inner horizontal interlayer bundle. By doing so, there is an effect of preventing the buoy from being crushed as much as possible.

In the present invention, the upper and lower synthetic resin foam covers are inserted into the upper and lower inner grooves, so that the outer surface fusion layer of the inner horizontal interlayer bundle can be protected in all directions, so that no matter where damage occurs in the outermost surface fusion layer, the outer surface fusion layer is completely protected. There is an effect that can be preserved.

In the present invention, in order to actively protect the outer surface fusion layer of the inner horizontal interlayer bundle, the upper and lower synthetic resin foam covers are laminated with the upper and lower interlayer thermoplastic flexible film interposed therebetween, and the synthetic resin foam sheet is wound together with the outer interlayer thermal plastic flexible film, That is, the inner horizontal interlayer bundles are stacked together with the stacking of the synthetic resin foam originals and the winding of the synthetic resin foam sheet with the upper and lower layers of the thermoplastic flexible film and the outer layer interlayer thermoplastic flexible film, so that the assembly workability as well as the protection of the inner and horizontal layers are protected. At the same time, it has the effect of maximizing productivity and life.

1A is a front view of an eco-friendly buoy wrapped around a styrofoam buoy according to Prior Art Document 1, and a styrofoam buoy applied to the manufacturing method thereof.
1B is a front cross-sectional view of a state in which the body cover of Prior Art Document 1 is contracted along the outer diameter of the Styrofoam buoy.
Figure 1c is a perspective view of the completed state of the eco-friendly buoy of Prior Art Document 1.
2 is a schematic front view showing a buoy manufacturing apparatus according to Prior Art Document 2.
3A to 3G are process diagrams showing an operation process based on a schematic right side view of the buoy manufacturing apparatus according to Prior Art Document 2;
Figure 4a is an exploded perspective view showing a buoy according to the first embodiment of the present invention.
Figure 4b is a vertical exploded cross-sectional view showing a buoy according to the first embodiment of the present invention.
5A is an exploded perspective view showing a buoy according to a second embodiment of the present invention.
5B is a vertical exploded cross-sectional view showing a buoy according to a second embodiment of the present invention.
6A is an exploded perspective view showing a buoy according to a third embodiment of the present invention.
6B is a vertical exploded cross-sectional view showing a buoy according to a third embodiment of the present invention.

Preferred embodiments of the buoy according to the present invention will be described with reference to the drawings, and there may be a plurality of embodiments thereof, and the objects, features and advantages of the present invention can be better understood through these embodiments. .

4A is an exploded perspective view showing a buoy according to a first embodiment of the present invention, and FIG. 4B is a vertical exploded cross-sectional view showing a buoy according to the first embodiment of the present invention.

The buoy according to the first embodiment of the present invention comprises a disk bundle 110 in which the primary foamed synthetic resin foam disks 111 are stacked to form a horizontal interlayer gap 111d as shown in FIGS. 4A and 4B. 1 Inner horizontal interlayer bundle 100 to have an outer surface fusion layer (100a) by placing it in a heating mold [the underheating mold and upper heating mold of the prior art document 2 patented by the applicant of the present application can be applied] ), and the first foamed synthetic resin foam sheet 211 along the outer edge of the inner horizontal interlayer bundle 100 to form a vertical interlayer gap 211d perpendicular to the horizontal interlayer gap 111d. Outer made to have the outermost surface fusion layer (200a) by putting it in the second heating mold [the underheating mold and upper heating mold of the prior art document 2 patented by the applicant of the present application can be applied by making it larger] It includes a vertical interlayer bundle 200.

The synthetic resin foam disk 111 and the synthetic resin foam sheet 211 are made by mixing a crosslinking agent and a foaming agent with PE, LDPE, PP, PVC or synthetic rubber, and then first foaming through a foaming furnace. Air Cell-First foamed synthetic resin Since the foam disc 111 and the synthetic resin foam sheet 211 have an air cell, it is not mentioned in the claims].

PE (Polyethylene) is a thermoplastic resin, which has excellent chemical resistance, electrical insulation, moisture-proof, cold resistance, and workability, and is commonly used as an insulating material. LDPE (Low Density Polyethylene) is a thermoplastic resin manufactured by polymerizing ethylene and is a transparent solid (density) It is used as a raw material for various wraps for agricultural and packaging transparent films due to its low crystallization of 0.91∼0.94), and it is used as a raw material for various wraps, etc., for agricultural use and packaging. Polypropylene (PP) is a thermoplastic resin obtained by polymerizing propylene. PVC (Polyvinyl chloride) is a thermoplastic plastic, polyvinyl chloride or vinyl chloride resin, which is used in a wide range of products such as films and sheets, and synthetic rubber is a synthetic rubber-like substance that has properties similar to natural rubber. It is a thermoplastic resin that can be a rubber-like elastic body. It has elastic cold resistance, fire resistance, heat resistance, oxidation resistance, and chemical resistance, so it is used in the manufacture of wire, shoes, stationery, and bags.

Such PE, LDPE, PP, PVC or synthetic rubber, for example, 50 wt% of a foaming agent (ADCA; azodicarbonamide) 25 wt%, a crosslinking agent (DCP; Di Cumyl Peroxide) 3.8 wt%, and furthermore, an antimicrobial agent made of zeolite zinc or silver 21.2 wt% By mixing and first foaming through a foaming furnace, a synthetic resin foam disk 111 and a synthetic resin foam sheet 211 having respective independent air cells can be provided.

Specifically, the buoy according to the first embodiment of the present invention maximizes the cushioning force by the inner horizontal interlayer bundle 100 and the outer vertical interlayer bundle 200 as shown in FIGS. 4A and 4B, as well as in the horizontal direction. And by ensuring the rigidity in the vertical direction at the same time, it prevents crushing in the horizontal direction, especially when tied with a rope (if crushed easily, seawater penetrates due to the damage of the outermost surface fusion layer 200a, which shortens the lifespan). When it is installed with marine facilities, it enables more intense bonding.

For reference, in the case of rolled toilet paper, the support force in the vertical direction is strong, but the support force in the horizontal direction is very weak, so that deformation of the shape easily occurs when pressing or applying pressure by hand, for example, a synthetic resin foam sheet 211 When the buoy is completed by winding the bay, the support force in the horizontal direction is extremely weak, and especially when it is combined with marine facilities, it should be able to be firmly tied with a rope.The higher the bundling strength is, the more easily crushing occurs, resulting in the outermost surface fusion layer. Considering that the penetration of seawater due to the breakage of (200a) may result in loss of the function as a buoy, as the synthetic resin foam disks 111 of the inner horizontal interlayer bundle 100 in the first embodiment of the present invention A synthetic resin foam sheet 211 of the outer vertical interlayer bundle 200 while reinforcing the strength in the horizontal state and reinforcing the strength in the vertical state together, increasing the assemblability with a sturdy bundle of ropes when trying to support heavy marine facilities. At the same time, even if the outermost surface fusion layer 200a is damaged by an external impact, the air cell in the inner horizontal interlayer bundle 100 by the outer surface fusion layer 100a is maintained as it is to preserve buoyancy. It is possible to prevent flooding of facilities in advance, and furthermore, the horizontal interlayer gap 111d and the vertical interlayer gap 211d allow more air to be contained together with the air cells to maximize buoyancy. It becomes desirable.

Furthermore, the synthetic resin foam discs 111 include inner synthetic resin foam discs 111a having vertical holes 111b and outer synthetic resin foam discs 111c stacked on both sides of the inner synthetic resin foam discs 111a.

The inner horizontal interlayer bundle 100 covered with the outer surface fusion layer 100a is embedded in the outer vertical interlayer bundle 200 covered with the outermost surface fusion layer 200a, and the inner horizontal interlayer bundle 100 As a detailed configuration of the synthetic resin foam discs 111 to be constituted, the outer synthetic resin foam discs 111c stacked on both sides of the inner synthetic resin foam discs 111a with vertical holes 111b as well as the inner synthetic resin foam discs 111a By maximizing the content of air by the vertical hole 111b, it is possible to maximize the buoyancy and ensure the maximum.

At this time, the vertical holes 111b are formed in different sizes and different shapes at different positions on the synthetic resin foam disks 111, so that when the synthetic resin foam disks 111 are stacked to provide the disk bundles 110 The vertical holes 111b of different sizes and different shapes can be positioned differently so that the pressure applied when binding the rope is dispersed in the inner horizontal interlayer bundle 100, thereby preventing the buoy from being crushed as much as possible. There will be.

Conversely, if the vertical holes 111b are positioned identically to the synthetic resin foam disks 111 in the same size and shape, the pressure applied when binding the rope must be concentrated in the same vertical hole 111b, causing the buoy to collapse. Can not be actively prevented.

Preferably, the synthetic resin foam sheet 211 is provided longer in the vertical direction than the stacking height of the synthetic resin foam disc 111 and has upper and lower inner grooves 211e above and below the inner horizontal interlayer bundle 100, and the upper and lower inner grooves ( The upper and lower synthetic resin foam covers 300 are fitted to 211e).

By inserting the upper and lower synthetic resin foam covers 300 into the upper and lower inner grooves 211e, it is possible to protect the outer surface fusion layer 100a of the inner horizontal interlayer bundle 100 in all directions, so that the outermost surface fusion layer 200a is Even if damage occurs anywhere, it is possible to completely preserve the outer surface fusion layer 100a, which is more preferable.

Further, the upper and lower synthetic resin foam covers 300 are laminated with an upper and lower interlayer thermoplastic flexible film (F1; for example, a thermoplastic PE film) interposed therebetween, and the synthetic resin foam sheet 211 is an outer interlayer thermoplastic flexible film (F2; For example, a thermoplastic PE film).

The most critical point of buoys is the loss of buoyancy that can be caused by damage due to external impact or corrosion due to natural phenomena after being installed on the sea.

In the first embodiment of the present invention, in order to preserve the air in the buoy, the outermost surface fusion layer 200a may be relied on, for example, the outermost surface fusion layer 200a due to the impact of a ship or sunlight along with seawater. If) is damaged, the air inside it will escape, as well as loss of buoyancy due to the penetration of seawater.

In consideration of this point, in the first embodiment of the present invention, in order to actively protect the outer surface fusion layer 100a of the inner horizontal interlayer bundle 100, the upper and lower synthetic resin foam covers 300 are provided with the upper and lower layers of the thermoplastic flexible film F1. ), and at the same time, the synthetic resin foam sheet 211 is wound together with the outer interlayer thermoplastic flexible film F2, that is, the inner horizontal interlayer bundle 100 is interposed between the upper and lower layers thermoplastic flexible film F1 and the outer interlayer thermoplastic. The flexible film (F2) is stacked with the synthetic resin foam original plates 111 and the synthetic resin foam sheet 211 is wound in layers and overlaps, so that the assembly workability as well as the protection of the inner horizontal interlayer bundle 100 can be realized at the same time. Thus, it is possible to maximize the life as well as productivity.

5A is an exploded perspective view showing a buoy according to a second embodiment of the present invention, and FIG. 5B is a vertical exploded cross-sectional view showing a buoy according to the second embodiment of the present invention.

In the buoy according to the second embodiment of the present invention, as shown in Figs. 5A and 5B, a first batch of disks 110 in which the first foamed synthetic resin foam disks 111 are stacked together with the horizontal interlayer stiffener 400 Inner horizontal interlayer bundle 100 having an outer surface fusion layer 100a by placing it in a heating mold [the underheating mold and upper heating mold of the prior art document 2 patented by the applicant of the present application can be applied] Wow, by winding the first foamed synthetic resin foam sheet 211 along the outer edge of the inner horizontal interlayer bundle 100 to form a vertical interlayer gap 211d orthogonal to the horizontal interlayer reinforcing material 400 to form a winding bundle. 2 The outer vertical made to have the outermost surface fusion layer (200a) by putting it in the heating mold [the underheating mold and upper heating mold of the prior art document 2 patented by the applicant of the present application can be applied by making it larger] It includes an interlayer bundle 200.

The synthetic resin foam disk 111 and the synthetic resin foam sheet 211 are made by mixing a crosslinking agent and a foaming agent with PE, LDPE, PP, PVC or synthetic rubber, and then first foaming through a foaming furnace. Air Cell-First foamed synthetic resin Since the foam disc 111 and the synthetic resin foam sheet 211 have an air cell, it is not mentioned in the claims].

The horizontal interlayer stiffener 400 is made of the same material as the synthetic resin foam disk 111 and the synthetic resin foam sheet 211 (for example, PE, LDPE, PP, PVC or synthetic rubber) to form an outer surface fusion layer (100a). When it is fused with the synthetic resin foam disk 111 to the extent of the heat applied from the first heating mold, it is reinforced into the disk bundle 110 to further strengthen the inner horizontal interlayer bundle 100. In particular, various marine When the buoy is tied to the facility with a rope, etc., it is not crushed by the horizontal interlayer stiffener 400, and its shape is properly maintained to maintain a solid assembly state and at the same time, it is desirable to ensure a lifespan.

Furthermore, the buoy according to the second embodiment of the present invention not only maximizes the cushioning force by the inner horizontal interlayer bundle 100 and the outer vertical interlayer bundle 200, but also ensures rigidity in the horizontal and vertical directions at the same time. When binding with a rope, it prevents crushing in the horizontal direction (if it is easily crushed, seawater penetrates due to the damage of the outermost surface fusion layer (200a), which shortens the lifespan), thereby providing a stronger bond when installing with marine facilities. Make it possible.

For reference, in the case of rolled toilet paper, the support force in the vertical direction is strong, but the support force in the horizontal direction is very weak, so that deformation of the shape easily occurs when pressing or applying pressure by hand, for example, a synthetic resin foam sheet 211 When the buoy is completed by winding the bay, the support force in the horizontal direction is extremely weak, and especially when it is combined with marine facilities, it should be able to be firmly tied with a rope.The higher the bundling strength is, the more easily crushing occurs, resulting in the outermost surface fusion layer. Considering that the penetration of seawater due to the breakage of (200a) may result in loss of the function as a buoy, the synthetic resin foam disks 111 of the inner horizontal interlayer bundle 100 in the second embodiment of the present invention In addition, when the horizontal interlayer reinforcement 400 reinforces the strength in the horizontal state and at the same time reinforces the vertical strength as the synthetic resin foam sheet 211 of the outer vertical interlayer bundle 200 to support heavy marine facilities. The air cell in the inner horizontal interlayer bundle 100 by the outer surface fusion layer 100a even if the outermost surface fusion layer 200a is damaged by an external impact while at the same time making it possible to increase assembly by a solid bundle of ropes As it is, it is possible to prevent inundation of marine facilities by preserving buoyancy, and furthermore, the gap between the horizontal interlayer stiffeners 400 and the vertical interlayer gap 211d can contain more air together with the air cells. It is more desirable to be able to maximize the buoyancy.

The synthetic resin foam discs 111 include inner synthetic resin foam discs 111a having vertical holes 111b, and outer synthetic resin foam discs 111c stacked on both sides of the inner synthetic resin foam discs 111a.

The inner horizontal interlayer bundle 100 covered with the outer surface fusion layer 100a is embedded in the outer vertical interlayer bundle 200 covered with the outermost surface fusion layer 200a, and the inner horizontal interlayer bundle 100 As a detailed configuration of the synthetic resin foam discs 111 to be constituted, the outer synthetic resin foam discs 111c stacked on both sides of the inner synthetic resin foam discs 111a with vertical holes 111b as well as the inner synthetic resin foam discs 111a By maximizing the content of air by the vertical hole 111b, it is possible to maximize the buoyancy and ensure the maximum.

At this time, the vertical holes 111b are formed in different sizes and different shapes at different positions on the synthetic resin foam disks 111, so that when the synthetic resin foam disks 111 are stacked to provide the disk bundles 110 The vertical holes 111b of different sizes and different shapes can be positioned differently so that the pressure applied when binding the rope is dispersed in the inner horizontal interlayer bundle 100, thereby preventing the buoy from being crushed as much as possible. There will be.

Conversely, if the vertical holes 111b are positioned identically to the synthetic resin foam disks 111 in the same size and shape, the pressure applied when binding the rope must be concentrated in the same vertical hole 111b, causing the buoy to collapse. Can not be actively prevented.

Preferably, the synthetic resin foam sheet 211 is provided longer in the vertical direction than the stacking height of the synthetic resin foam disc 111 and has upper and lower inner grooves 211e above and below the inner horizontal interlayer bundle 100, and the upper and lower inner grooves ( The upper and lower synthetic resin foam covers 300 are fitted to 211e).

The upper and lower synthetic resin foam covers 300 are fitted and covered in the upper and lower inner grooves 211e, so that the outer surface fusion layer 100a of the inner horizontal interlayer bundle 100 can be protected in all directions, so that the outermost surface fusion layer 200a is Even if damage occurs anywhere, it is possible to completely preserve the outer surface fusion layer 100a, which is more preferable.

Further, the upper and lower synthetic resin foam covers 300 are laminated with an upper and lower interlayer thermoplastic flexible film (F1; for example, a thermoplastic PE film) interposed therebetween, and the synthetic resin foam sheet 211 is an outer interlayer thermoplastic flexible film (F2; For example, a thermoplastic PE film).

The most fatal point of the buoy is the loss of buoyancy that can be caused by damage due to external shocks or corrosion due to natural phenomena after being installed in the ocean.

In the first embodiment of the present invention, in order to preserve the air in the buoy, the outermost surface fusion layer 200a may be relied on, for example, the outermost surface fusion layer 200a due to the impact of a ship or sunlight along with seawater. If) is damaged, the air inside it will escape, as well as loss of buoyancy due to the penetration of seawater.

In consideration of this point, in the second embodiment of the present invention, in order to actively protect the outer surface fusion layer 100a of the inner horizontal interlayer bundle 100, the upper and lower synthetic resin foam covers 300 are provided with the upper and lower layers of the thermoplastic flexible film (F1). ), and at the same time winding the synthetic resin foam sheet 211 with the outer interlayer thermoplastic flexible film F2, that is, the inner horizontal interlayer bundle 100 between the upper and lower layers thermoplastic flexible film F1 and the outer interlayer thermal plasticity The flexible film (F2) is stacked together with the synthetic resin foam disks 111 and the synthetic resin foam sheet 211 is wound in layers, so that the assembly workability as well as the protection of the inner horizontal interlayer bundle 100 are simultaneously realized. Thus, it is possible to maximize the life as well as productivity.

On the other hand, the horizontal interlayer stiffener 400 includes a horizontal air cap 400a containing air, and as well as maximizing the buoyancy by the air contained in the horizontal air cap 400a, the outermost surface fusion layer 200a and Even if seawater penetrates into the outer vertical interlayer bundle 200 and the inner horizontal interlayer bundle 100 due to damage of the outer surface fusion layer 100a, the air contained in the horizontal air cap 400a maintains a minimum buoyancy. By preventing or delaying the phenomenon of the buoy being submerged into the sea as much as possible, even environmental pollution can be prevented.

6A is an exploded perspective view showing a buoy according to a third embodiment of the present invention, and FIG. 6B is a vertical exploded cross-sectional view showing a buoy according to the third embodiment of the present invention.

The buoy according to the third embodiment of the present invention comprises a disk bundle 110 in which the primary foamed synthetic resin foam disks 111 are stacked to form a horizontal interlayer gap 111d as shown in FIGS. 6A and 6B. 1 Inner horizontal interlayer bundle 100 to have an outer surface fusion layer (100a) by placing it in a heating mold [the underheating mold and upper heating mold of the prior art document 2 patented by the applicant of the present application can be applied] ), and the first foamed synthetic resin foam sheet 211 along the outer edge of the inner horizontal interlayer bundle 100 to form a vertical interlayer gap 211d perpendicular to the horizontal interlayer gap 111d. Outer made to have the outermost surface fusion layer (200a) by putting it in the second heating mold [the underheating mold and upper heating mold of the prior art document 2 patented by the applicant of the present application can be applied by making it larger] Including vertical interlayer bundles 200, the synthetic resin foam discs 111 are inner synthetic resin foam discs 111a having vertical holes 111b, and outer synthetic resin foam discs stacked on both sides of the inner synthetic resin foam discs 111a It includes (111c), and further includes a vertical stiffener 500 fitted in the vertical hole (111b).

The synthetic resin foam disk 111 and the synthetic resin foam sheet 211 are made by mixing a crosslinking agent and a foaming agent with PE, LDPE, PP, PVC or synthetic rubber, and then first foaming through a foaming furnace. Air Cell-First foamed synthetic resin Since the foam disc 111 and the synthetic resin foam sheet 211 have an air cell, it is not mentioned in the claims], and the vertical stiffener 500 is a synthetic resin foam disc 111 and a synthetic resin foam sheet 211 ) Made of the same material (for example, PE, LDPE, PP, PVC or synthetic rubber) to the extent of the heat applied from the first heating mold when the outer surface fusion layer 100a is formed, the synthetic resin foam disk 111 As it is fused with, it is reinforced into the disk bundle 110 so that the inner horizontal interlayer bundle 100 can be further reinforced. In particular, in the case of binding with ropes to fix the buoys to various marine facilities at sea, the vertical reinforcement material 500 This is desirable because it is not crushed and maintains its shape correctly to maintain a solid assembly state and at the same time guarantees a lifetime.

Specifically, the buoy according to the third embodiment of the present invention maximizes the cushioning force by the inner horizontal interlayer bundle 100 and the outer vertical interlayer bundle 200 as shown in FIGS. 6A and 6B, as well as in the horizontal direction. And by ensuring the rigidity in the vertical direction at the same time, it prevents crushing in the horizontal direction, especially when tied with a rope (if crushed easily, seawater penetrates due to the damage of the outermost surface fusion layer 200a, which shortens the lifespan). When it is installed with marine facilities, it enables more intense bonding.

For reference, in the case of rolled toilet paper, the support force in the vertical direction is strong, but the support force in the horizontal direction is very weak, so that deformation of the shape easily occurs when pressing or applying pressure by hand, for example, a synthetic resin foam sheet 211 When the buoy is completed by winding the bay, the support force in the horizontal direction is extremely weak, and especially when it is combined with marine facilities, it should be able to be firmly tied with a rope.The higher the bundling strength is, the more easily crushing occurs, resulting in the outermost surface fusion layer. Considering that the penetration of seawater due to the breakage of (200a) may result in loss of the function as a buoy, as the synthetic resin foam disks 111 of the inner horizontal interlayer bundle 100 in the third embodiment of the present invention A synthetic resin foam sheet 211 of the outer vertical interlayer bundle 200 while reinforcing the strength in the horizontal state and reinforcing the strength in the vertical state together, increasing the assemblability with a sturdy bundle of ropes when trying to support heavy marine facilities. At the same time, even if the outermost surface fusion layer 200a is damaged by an external impact, the air cell in the inner horizontal interlayer bundle 100 by the outer surface fusion layer 100a is maintained as it is to preserve buoyancy. It is possible to prevent flooding of facilities in advance, and furthermore, the horizontal interlayer gap 111d and the vertical interlayer gap 211d allow more air to be contained together with the air cells to maximize buoyancy. It becomes desirable.

The inner horizontal interlayer bundle 100 covered with the outer surface fusion layer 100a is embedded in the outer vertical interlayer bundle 200 covered with the outermost surface fusion layer 200a, and the inner horizontal interlayer bundle 100 As a detailed configuration of the synthetic resin foam discs 111 to be constituted, the outer synthetic resin foam discs 111c stacked on both sides of the inner synthetic resin foam discs 111a with vertical holes 111b as well as the inner synthetic resin foam discs 111a By maximizing the content of air by the vertical hole 111b, it is possible to maximize the buoyancy, and at the same time, the vertical stiffener 500 is inserted into the vertical hole 111b. In order to further strengthen the strength in the direction and to fix the buoy to various marine facilities at sea, when tied with a rope, etc., it is not crushed by the vertical stiffener 500 and its shape is maintained correctly to maintain a solid assembly state and at the same time life. To be able to guarantee.

In addition, it is possible to quickly and firmly provide the disk bundle 110 by laminating the synthetic resin foam disk 111 by the vertical stiffener 500 inserted in the vertical hole 111b, thereby ensuring productivity, which is more preferable. .

Preferably, the synthetic resin foam sheet 211 is provided longer in the vertical direction than the stacking height of the synthetic resin foam disc 111 and has upper and lower inner grooves 211e above and below the inner horizontal interlayer bundle 100, and the upper and lower inner grooves ( The upper and lower synthetic resin foam covers 300 are fitted to 211e).

By inserting the upper and lower synthetic resin foam covers 300 into the upper and lower inner grooves 211e, it is possible to protect the outer surface fusion layer 100a of the inner horizontal interlayer bundle 100 in all directions, so that the outermost surface fusion layer 200a is It is preferable to be able to completely protect the outer surface fusion layer (100a) no matter where the damage occurs.

Further, the upper and lower synthetic resin foam covers 300 are laminated with an upper and lower interlayer thermoplastic flexible film (F1; for example, a thermoplastic PE film) interposed therebetween, and the synthetic resin foam sheet 211 is an outer interlayer thermoplastic flexible film (F2; For example, a thermoplastic PE film).

The most fatal point of the buoy is the loss of buoyancy that can be caused by damage due to external shocks or corrosion due to natural phenomena after being installed in the ocean.

In the third embodiment of the present invention, in order to preserve the air in the buoy, the outermost surface fusion layer 200a may be relied on, for example, the outermost surface fusion layer 200a due to the impact of a ship or sunlight along with seawater. If) is damaged, the air inside it will escape, as well as loss of buoyancy due to the penetration of seawater.

In consideration of this point, in the third embodiment of the present invention, in order to actively protect the outer surface fusion layer 100a of the inner horizontal interlayer bundle 100, the upper and lower synthetic resin foam covers 300 are provided with the upper and lower layers of the thermoplastic flexible film F1. ), and at the same time winding the synthetic resin foam sheet 211 with the outer interlayer thermoplastic flexible film F2, that is, the inner horizontal interlayer bundle 100 between the upper and lower layers thermoplastic flexible film F1 and the outer interlayer thermal plasticity The flexible film (F2) is stacked with the synthetic resin foam original plates 111 and the synthetic resin foam sheet 211 is wound in layers and overlaps, so that the assembly workability as well as the protection of the inner horizontal interlayer bundle 100 can be realized at the same time. Thus, it is possible to maximize the life as well as productivity.

Meanwhile, the vertical stiffener 500 includes a vertical air cap 550a containing air.

In addition to maximizing buoyancy by the air embedded in the horizontal air cap 400a, the outer vertical layer interlayer bundle 200 and the inner horizontal interlayer bundle 200 and the inner horizontal layer interlayer bundle 200 and the inner horizontal layer interlayer bundle 200 due to damage of the outermost surface fusion layer 200a and the outer surface fusion layer 100a. 100) Even if seawater penetrates into the water, it is possible to prevent or delay the phenomenon that the buoy is submerged into the sea as much as possible by maintaining a minimum buoyancy by the air contained in the horizontal air cap (400a) to prevent environmental pollution. To be.

The present invention is installed to fix aquaculture facilities and to instruct a route to help safe navigation of a ship, or to warn of the presence of nautical dangerous substances such as reefs and sunken ships, and is used in industrial fields for floating aquatic solar facilities on the water. It is possible.

100: inner horizontal interlayer bundle 100a: outer surface fusion layer
110: disk bundle 111: synthetic resin foam disk
111a: inner synthetic resin foam disk 111b: vertical hole
111c: outer synthetic resin foam disk 111d: horizontal interlayer gap
200: outer vertical interlayer bundle 200a: outermost surface fusion layer
211: synthetic resin foam sheet 211d: vertical interlayer gap
211e: upper and lower inner grooves 300: upper and lower synthetic resin foam cover
F1: Thermoplastic flexible film between upper and lower layers F2: Thermoplastic flexible film between outer layers
400: horizontal interlayer stiffener 400a: horizontal air cap
500: vertical stiffener 500a: vertical air cap

Claims (6)

The inner horizontal to have the outer surface fusion layer (100a) by placing the first foamed synthetic resin foam disk 111 together with the horizontal interlayer stiffener 400 in the first heating mold for the second foaming With the interlayer bundle (100),
The synthetic resin foam sheet 211, which was first foamed along the outer edge of the inner horizontal interlayer bundle 100, is wound to form a vertical interlayer gap 211d orthogonal to the horizontal interlayer stiffener 400 to form a winding bundle. 2 Buoy, characterized in that it comprises an outer vertical interlayer bundle 200 to have an outermost surface fusion layer (200a) while being put in the heating mold for third foaming. The method of claim 1,
The synthetic resin foam discs 111 include inner synthetic resin foam discs 111a having vertical holes 111b, and outer synthetic resin foam discs 111c stacked on both sides of the inner synthetic resin foam discs 111a. Buoy. The method of claim 2,
The vertical hole (111b) is a buoy, characterized in that formed in different sizes and different shapes at different positions on the synthetic resin foam disks (111). The method according to any one of claims 1 to 3,
The synthetic resin foam sheet 211 is provided longer in the vertical direction than the stacking height of the synthetic resin foam disc 111 and has upper and lower inner grooves 211e above and below the inner horizontal interlayer bundle 100,
A buoy, characterized in that the upper and lower synthetic resin foam covers 300 are fitted into the upper and lower inner grooves 211e. The method of claim 4,
The upper and lower synthetic resin foam covers 300 are stacked with the upper and lower interlayer thermoplastic flexible film F1 interposed therebetween,
The synthetic resin foam sheet 211 is a buoy, characterized in that it is wound together with the outer layer interlayer thermoplastic flexible film (F2). The method according to any one of claims 1 to 3,
The horizontal interlayer stiffener 400 is a buoy, characterized in that it has a horizontal air cap (400a) containing air.

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