KR102115376B1 - Buoy - Google Patents

Abstract

The present invention relates to a buoy (B). A shape of the buoy (B) is not dented by a reinforcing material between floors (C) to be correctly maintained when the buoy (B) is fixed to various devices on the water by a rope or the like. Therefore, a rigid assembly state with the various devices can be maintained and a lifespan can be secured. Furthermore, through holes (T) are provided in the reinforcing material between the floors (C). Therefore, the weight of the buoy (B) itself can be lightened and buoyancy can be maintained. Also, a linear air pocket (N) formed along a boundary between the floors by winding of a synthetic resin foaming sheet (S) and a tubular air pocket in the through holes (T) are provided. Therefore, the buoyancy can be further maximized.

Description

Buoy {BUOY}

The present invention relates to a buoy, and more specifically, to fix the buoy on various instruments in the water phase, when tied with a rope, etc., it is not crushed by the interlayer reinforcement, and maintains its shape properly to maintain a solid assembly state with various instruments. At the same time, it is possible to guarantee the lifespan, and furthermore, it is provided with through holes in the interlayer reinforcement to maintain its buoyancy while lightening its own weight, as well as through air with a linear air pocket formed along the interlayer boundary by winding of the synthetic resin foam sheet. It is about a buoy that can maximize buoyancy by providing a cylindrical air pocket in the field.

In general, buoys are installed to fix aquaculture facilities, to guide the route to help the ship safely navigate, or to warn of the presence of dangerous objects on the voyage, such as reefs and sinking ships. It is used for various purposes, such as being used to float floating solar facilities on water.

Styrofoam buoys are the most used of the buoys. Styrofoam buoys are easily damaged due to their weak durability, and they are difficult to collect and process because they are finely crushed into granules, and lead to the death of animals, such as fish and birds, which have been mistaken for food. And damage to the natural landscape, as well as the ocean, has a huge adverse effect on the land environment.

Figure 1a is a front view of a prior art document 1 (Korean Registered Patent Publication No. 1600525; an eco-friendly buoy that surrounds and forms a Styrofoam buoy and a manufacturing method thereof), and Fig. 1b is a torso cover of the prior art document 1 It is a front sectional view in a contracted state along the outer diameter of the Styrofoam buoy, and FIG. 1C is a perspective view of a completed state of an eco-friendly buoy in Prior Art Document 1.

Prior art document 1 forms 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 has both cylindrical bodies 11 The bending groove 12 capable of fixing the rope is formed, and the outer side of the bending groove 12 is formed of a side 13 formed to be rounded.

The eco-friendly buoy 50 of the prior art document 1 for forming the entire outer diameter of the spiro foam buoy 10 is formed to be integrally joined to the body 11 and the inner part of the bending groove 12 and the side surface 13 It consists of a body cover (30). At this time, the body cover 30 is molded into a sheet form to extrude synthetic resin to have a thickness of 0.8 to 2.8 mm.

By the way, the prior art document 1 has a problem that the high density squyrofoam buoy 10 is easily damaged when the torso cover 30 is damaged, and is a major cause of environmental pollution. In particular, the torso cover 30 is formed on the cylindrical body 11 The work to be done, that is, the work of forming the body cover 30 in the form of a sheet by the synthetic resin fdkqcnf is difficult, and the productivity is significantly reduced.

Figure 2a is a perspective view showing a foam buoy according to the prior art document 2 (Republic of Korea Patent Publication No. 2016-0089904; eco-friendly foam buoy), Figure 2b is a cross-sectional view showing a foam buoy according to the prior art document 2, Figure 2c is an exploded perspective view showing the foam buoy according to the prior art document 2.

The eco-friendly foamed buoy of the prior art document 2 is intended to manufacture a product having a diameter of 200 to 3000 mm by overcoming the general technology that it is impossible to mold a thick product of 100 mm or more with foamed polypropylene as shown in FIGS. 2A to 2C. It consists of a buoyancy portion 10 and the body portion 20.

The buoyancy portion 10 is formed in a cylindrical shape, a plurality of insertion holes 11 are formed inside the buoyancy portion 10, and the insertion hole 11 is formed to be long to penetrate both end faces of the buoyancy portion 10. .

The buoyancy part 10 is formed of a foamed polystyrene (EPS, styrofoam) material, and the lung PT bottle 30 is inserted into a plurality of insertion holes 11 formed in the central part to generate more buoyancy.

The body portion 20 is molded to surround the outer periphery of the buoyancy portion 10, the body portion 20 is made of expanded polypropylene (EPP) particles, formed in a cylindrical shape, and bound grooves 21 on both sides of the outer periphery ) Is formed.

However, prior art document 2 is formed to penetrate the insertion hole 11 in the buoyancy portion 10 for buoyancy, and then has a complicated structure to insert the lung PT bottle 30, which not only significantly decreases productivity, but also inserts the hole during use. (11) PT bottle 30 comes out and has a problem of causing more environmental pollution.

Republic of Korea Registered Patent Publication No. 1600525-Eco-friendly buoy that surrounds and forms a Styrofoam buoy and its manufacturing method Republic of Korea Patent Publication No. 2016-0089904-Eco-friendly foam buoy Republic of Korea Registered Patent Publication No. 1941174-Buoy manufacturing device

The object of the present invention is to secure the buoy on various instruments in the water phase, and when tied with a rope or the like, maintain the shape properly without being distorted by the interlayer stiffener, so that it can maintain a solid assembly state with various instruments and guarantee the lifespan. In providing a buoy that can.

The object of the present invention is to provide a through-hole in the interlayer reinforcement to maintain buoyancy while lightening its own weight, as well as a linear air pocket formed along the interlayer boundary by winding of the synthetic resin foam sheet and a cylindrical air pocket in the through holes. It is to provide a buoy that can be prepared to further maximize buoyancy.

The present invention for achieving the above object,

A winding bundle provided by winding of a synthetic resin foam sheet, a surface fused layer provided by heat applied to the surface of the winding bundle, and a linear air formed along the interlayer boundary by winding of the synthetic resin foam sheet enclosed by the surface fused layer In the buoy comprising a pocket,

It is interposed along the inter-layer boundary by winding of the synthetic resin foam sheet and reinforced into the linear air pocket by heat applied to the surface of the winding bundle, and includes an interlayer stiffener covered by the surface fusing layer. It is characterized by.

In the present invention, when the buoy is secured to various fixtures in the water phase, when tied with a rope or the like, the shape is not crushed by the interlayer stiffeners, and the shape is maintained properly to maintain a solid assembly state with various fixtures and to ensure a lifetime It works.

In the present invention, when a buoy is fixed to various kinds of equipment, a uniform force is transmitted to the central direction of the winding bundle by the interlayer width direction reinforcing piece when it is tied with a rope, etc., so that it is not easily distorted and maintains its shape properly. In addition to the maintenance of, there is an effect that can guarantee the life.

In the present invention, the elastic force is exerted in the outward direction of the winding bundle by the interlayer longitudinal stiffening piece when it is tied with a rope or the like to fix the buoy to various equipments, so that it is not easily distorted and can maintain its shape properly. In addition to the maintenance of, there is an effect that can guarantee the life.

In the present invention, the elastic force is exerted in the outward direction of the winding bundle by the interlayer spiral reinforcing piece when it is tied with a rope or the like to fix the buoy to various equipments, so that it is not easily distorted and can maintain its shape properly. In addition to maintenance, there is an effect that can guarantee the life.

In the present invention, the elastic force is exerted in the outward direction of the winding bundle by the interlayer reinforcement when tying it with a rope or the like to fix the buoy to various instruments, so that it is not easily crushed and can maintain its shape properly, thereby maintaining a robust assembly state. In addition, there is an effect that can guarantee the life span.

The present invention not only maintains buoyancy while lightening its own weight by providing through holes in the interlayer reinforcement material, but also provides a linear air pocket in the through holes as well as a linear air pocket formed along the interlayer boundary by winding of the synthetic resin foam sheet. There is an effect that can maximize the buoyancy further.

1A is a front view of a Styrofoam buoy for molding prior art document 1. FIG.
Figure 1b is a front cross-sectional view of a state in which the body cover of the prior art document 1 contracted along the outer diameter of the Styrofoam buoy.
Figure 1c is a perspective view of the completion of the environmentally friendly buoy of the prior art document 1.
Figure 2a is a perspective view showing a foam buoy according to the prior art document 2.
Figure 2b is a cross-sectional view showing a foam buoy according to the prior art document 2.
Figure 2c is an exploded perspective view showing a foam buoy according to the prior art document 2.
Figure 3a is a perspective view showing a buoy according to the present invention.
Figure 3b is a photograph showing a buoy according to the present invention.
Figure 4a to 4d is a perspective view showing a buoy according to each embodiment of the present invention.
Figure 5 is a cross-sectional view showing a buoy according to another embodiment of the present invention.

A preferred embodiment of the buoy according to the present invention will be described with reference to the drawings, and a number of examples may exist, and through this embodiment, the objects, features and advantages of the present invention can be better understood. .

Figure 3a is a perspective view showing a buoy (B) according to the present invention, Figure 3b is a photograph showing a buoy (B) according to the present invention, Figures 4a to 4d are buoys (B) according to each embodiment of the present invention It is a perspective view showing.

The buoy (B) according to the present invention is a surface provided by heat applied to the surface of the winding bundle (M) and the winding bundle (M) prepared by winding the synthetic resin foam sheet (S) as shown in Figures 3a to 4d It includes a fusion layer (P) and a linear air pocket (N) formed along the interlayer boundary by winding of the synthetic resin foam sheet (S) confined by the surface fusion layer (P).

Synthetic resin foam sheet (S), for example, PE, LDPE, PP, PVC, or synthetic rubber, a mixture of a crosslinking agent and a foaming agent, and then foamed through a foaming furnace to have independent air cells (Air Cells A) applied. have.

PE (Polyethylene) is a thermoplastic resin, and is commonly used as an insulating material due to its excellent chemical resistance, electrical insulation, moisture resistance, cold resistance, and processability. LDPE (Low Density Polyethylene) is a thermoplastic resin produced by polymerizing ethylene and is transparent at room temperature (density 0.91 to 0.94) Low crystallization and excellent processability and flexibility and transparency. Used for raw materials for various types of wraps, such as agricultural and packaging transparent films, PP (Polypropylene) is a thermoplastic resin obtained by polymerizing propylene, used in futon padding thermos, PVC (Polyvinyl chloride) ) Is a thermoplastic, polyvinyl chloride or vinyl chloride resin, which is used for a wide range of products, such as film sheet molded products, and synthetic rubber is a synthetic rubber-like material or rubber-like elastic material having properties similar to natural rubber. As a thermoplastic resin, it has elastic cold resistance, fire resistance, heat resistance, oxidation resistance, and chemical resistance.

For example, PE, LDPE, PP, PVC or synthetic rubber, for example, 50wt% of a blowing agent (ADCA; azodicarbonamide) 25wt%, crosslinking agent (DCP; Di Cumyl Peroxide) 3.8wt%, furthermore, zeolite, zinc or silver antibacterial agent 21.2wt% It is possible to prepare a synthetic resin foam sheet (S) having each of the independent air cells (A) by mixing and foaming through the foaming furnace, and the synthetic resin foam sheet (S) is formed by buoyancy by the air cells (A), and zeolite It is possible to even purify water by using an antibacterial agent made of, zinc or silver.

In the present invention, after winding the synthetic resin foam sheet (S) to prepare a winding bundle (M), put heat in an unillustrated mold (for example, the underheating mold and the upper heating mold of No. 1941174, filed by the applicant of the present application) The surface fusion layer (P) is formed to complete the buoy (B), and the surface fusion layer (P) is a heat of the mold, for example, 150 to 250 ° C. When the formation time is too long and is higher than 250 ° C, the surface of the winding bundle M is melted by the heat of the mold of the surface fusion layer (P) is formed so deep that the whole is hardened], and thus it is fixedly formed, and thus the surface A linear air pocket (N) {Linear Air Pocket; along the interlayer boundary by winding of the synthetic resin foam sheet confined by the fusing layer P; Winding of the synthetic resin foam sheet forms an air pocket} continuously connected like a line along the boundary between the layers to maximize buoyancy through the combination of the air cells (A) and the linear air pocket (N). In particular, the foamed synthetic resin, That is, due to the characteristics of the synthetic resin foam sheet (S), it has a good cushioning force and does not easily break due to impact, and has a long life, which can significantly prevent environmental pollution. [In other words, it does not cause any damage in the form of particles such as styrofoam to cause environmental pollution. Can be significantly reduced].

In addition, the air content can be maximized by the linear air pocket (N) formed along the interlayer boundary by winding of the synthetic resin foam sheet (S) confined by the surface fusion layer (P), as well as buffering against external impact By making it more active, it can guarantee the buoyancy and significantly eliminate the damage to itself and damage to the opponent.

However, as described above, the buoy (B) can maximize the buoyancy by the linear air pocket (N) together with the independent air cell (A) of the synthetic resin foam sheet (S) confined with the surface fusion layer (P). , In the case of bundling (B) to various fixtures on the water, when tied with a rope (when tied with a rope, etc. along the rope groove (D) (D)), the winding bundle (M) is easily crushed and cannot maintain its shape properly It has a problem that occurs.

Accordingly, the buoy (B) according to the present invention is interposed along the interlayer boundary by winding of the synthetic resin foam sheet (S) and is surface welded while being reinforced into the linear air pocket (N) by heat applied to the surface of the winding bundle (M). The interlayer stiffener (C) covered by the layer (P) is included as a core configuration.

The interlayer reinforcing material (C) is made of the same material (for example, PE, LDPE, PP, PVC or synthetic rubber) as the synthetic resin foam sheet (S), and the range of heat applied from the mold when the surface fusion layer (P) is formed Until it is fused with the synthetic resin foam sheet (S) in the linear air pocket (N), it is reinforced into the linear air pocket (N) to further strengthen the winding bundle (M). In the case of tying it with a rope, etc. to fix it, it is preferable because it can maintain a solid assembly state with various equipments by maintaining its shape properly without being crushed by the interlayer stiffener (C), and at the same time ensure the life.

At this time, the interlayer reinforcing material (C) is composed of an interlayer width direction reinforcement piece (C1) interposed in the width direction along the interlayer boundary by winding of the synthetic resin foam sheet (S) as shown in Figure 4a buoy (B) ) When fixing with a rope to fix), uniform force is transmitted to the center direction of the winding bundle (M) by the interlayer width direction reinforcement piece (C1), so that it is not easily distorted and can maintain its shape correctly. In addition to maintaining the state, it can guarantee the lifespan].

Furthermore, the interlayer reinforcing material (C) consists of an interlayer longitudinal reinforcing piece (C2) interposed in the longitudinal direction along the interlayer boundary by winding of the synthetic resin foam sheet (S) as shown in Fig. When binding with rope to fix), the elastic force is exerted in the outward direction of the winding bundle (M) by the interlayer longitudinal reinforcement piece (C2), so that it is not easily distorted and can maintain its shape properly. In addition to maintaining the state, it can guarantee the lifespan].

Furthermore, the interlayer reinforcement (C) is composed of an interlayer spiral reinforcement piece (C3) interposed in the longitudinal direction along the interlayer boundary by winding of the synthetic resin foam sheet (S) as shown in Figure 4c buoy (B) When tied with rope to fix), elastic force is exerted in the outward direction of the winding bundle (M) by the interlayer spiral reinforcement piece (C3), so that it is not easily distorted and can maintain its shape properly. In addition to the maintenance of, it can guarantee the lifespan].

In addition, the interlayer stiffener (C) is made of an interlayer stiffener (C4) interposed in the longitudinal direction along the interlayer boundary by the winding of the synthetic resin foam sheet (S) as shown in Figure 4d bu (B) to various fixtures When tied with a rope to fix it, the elastic force is exerted in the outward direction of the winding bundle (M) by the interlayer stiffener (C4), so that it is not easily distorted and can maintain its shape correctly. In addition, it can guarantee the lifespan].

In addition, the interlayer stiffener (C) is provided with through holes (T) to maintain the buoyancy while lightening its own weight, as well as the linear air pocket (N) formed along the interlayer boundary by winding of the synthetic resin foam sheet (S) In addition, a cylindrical air pocket (T1) is provided in the through holes (T) to further maximize buoyancy.

5 is a cross-sectional view showing a buoy B according to another embodiment of the present invention.

The buoy (B) according to another embodiment of the present invention is interposed along the interlayer boundary by winding of the synthetic resin foam sheet (S) while being reinforced into the linear air pocket (N) by heat applied to the surface of the winding bundle (M) In addition to the interlayer stiffener (C) covered by the surface fusion layer (P), as shown in FIG. 5, it is drilled into the winding bundle (M) and serves as a gas ejection passageway when the surface fusion layer (P) is formed. It may include a pinhole (Q) that is closed as shown in FIG.

When the surface fusion layer (P) is formed, the gas generated in the winding bundle (M) is ejected through the pinhole (Q) and then closed to ensure the smoothness of the surface fusion layer (P) and at the same time the winding bundle ( This is to ensure the structure of the independent air cells (A) in M) and the overall uniform cushioning force.

That is, the present invention allows the gas generated in the winding bundle M to be ejected through the pinhole Q when the surface fusion layer P is formed, and then closed, and at the same time additionally causes the flexible film F to surface. Independent air cells (A) in the winding bundle (M) while ensuring the lifetime by smoothly treating the surface while more actively protecting the surface fusion layer (P) by the flexible film (F) by allowing it to adhere together to the fusion layer (P) ) To ensure the structure and overall uniform cushioning force.

The surface airtight layer (P) and the linear air pocket formed along the interlayer boundary by winding of the synthetic resin foam sheet confined with the flexible film (F) can maximize the content of air as well as buffer against external shocks. Since it can be actively realized, it is possible to significantly eliminate self-damage and damage to the opponent while ensuring buoyancy.

The present invention is installed in order to fix aquaculture facilities, to instruct a route to assist the safe navigation of ships, or to warn of the presence of dangerous objects on the sea, such as reefs and sinking ships, and to be used in industrial fields for floating water solar facilities on water It is possible.

S: Synthetic resin foam sheet M: Winding bundle
P: Surface fusion layer B: Buoy
A: Air cell N: Linear air pocket
Q: Pinhole F: Flexible film
D: Rope groove C: Interlayer reinforcement
C1: Interlayer width direction reinforcement piece C2: Interlayer length direction reinforcement piece
C3: Interlayer spiral reinforcement C4: Interlayer reinforcement
T: Through hole T1: Through air pocket

Claims (6)

The winding bundle (M) provided by winding of the synthetic resin foam sheet (S), the surface fusion layer (P) provided by heat applied to the surface of the winding bundle (M), and the surface confined by the surface fusion layer (P) In the buoy comprising a linear air pocket (N) formed along the interlayer boundary by the winding of the synthetic resin foam sheet (S),
Covered by the surface fusion layer (P) while being reinforced into the linear air pocket (N) by heat applied to the surface of the winding bundle (M) interposed along the inter-layer boundary by the winding of the synthetic resin foam sheet (S) Buoy characterized in that it comprises an interlayer reinforcement (C). According to claim 1,
The interlayer reinforcement (C) is a buoy characterized in that the interlayer width direction reinforcement piece (C1) interposed in the width direction along the interlayer boundary by the winding of the synthetic resin foam sheet (S). According to claim 1,
The interlayer reinforcing material (C) is a buoy characterized in that the interlayer longitudinal reinforcing piece (C2) interposed in the longitudinal direction along the interlayer boundary by the winding of the synthetic resin foam sheet (S). According to claim 1,
The interlayer reinforcement (C) is a buoy characterized in that the interlayer spiral reinforcement piece (C3) interposed in the longitudinal direction along the interlayer boundary by the winding of the synthetic resin foam sheet (S). According to claim 1,
The interlayer reinforcement (C) is a buoy characterized in that the interlayer reinforcement (C4) interposed in the longitudinal direction along the interlayer boundary by the winding of the synthetic resin foam sheet (S). The method according to any one of claims 2 to 5,
The interlayer reinforcement (C) is a buoy characterized in that it has a through-hole (T) for providing a cylindrical air pocket (T1).

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