KR102324524B1 - Buoy of hollow type - Google Patents

Abstract

The present invention relates to a hollow buoy and, more specifically, to a hollow buoy floated on the sea and displaying a specific location so that an observer can identify the location. According to the present invention, the hollow buoy comprises: a buoyancy body including a main body part having a buoyancy space formed therein, and a nozzle accommodating part drawn in from one side of the main body part to a predetermined depth to form a nozzle accommodating space and an injection hole communicating the buoyancy space; an air injection unit installed in the injection hole to inject high-pressure air into the buoyancy space of the buoyancy body; a sealing unit installed in the main body part to seal the nozzle accommodating space; and at least one ring part installed on the main body part or the sealing unit.

Description

Buoy of hollow type

The present invention relates to a hollow buoy, and more particularly, to a hollow buoy that floats on the sea and displays a specific location so that an observer can identify it.

A buoy is a floating structure that is floated on the sea and is used to mark the location of various fish farms, nets, marine fish, or routes for safe navigation of ships. Buoy, also called buoy or buoy, includes anchor buoy, bell buoy, cylindrical buoy, light buoy, mooring buoy, lozenge buoy, columnar buoy, life buoy, and the like.

The buoy is divided into a buoy using a foamed resin manufactured by molding a foamable resin such as styrofoam into a predetermined shape, and a hollow buoy having an outer wall made of a plastic material and having a buoyancy space inside.

The buoy using foamed resin easily corrodes when exposed to seawater or sunlight for a long time, or absorbs seawater to weaken its buoyancy, so frequent replacement is required. may occur. Therefore, in recent years, the demand for hollow buoyancy manufactured to provide a sealed buoyancy space inside is increasing.

Republic of Korea Patent No. 10-1740918 and Patent No. 10-1861759 disclose a method for manufacturing a hollow buoy and a buoy for fishing in which a hemispherical upper body and a lower body are combined to form a buoyancy space therein. .

The conventional hollow buoy as described above is lighter in weight than the buoy using foamed resin and does not absorb seawater like the buoy using foamed resin, so that corrosion is prevented, and contaminants are not leaked when damaged. There is this.

However, when the conventional hollow buoy is crushed due to the impact of waves or a collision with a floating object floating in the sea, visibility can be reduced, and when the components constituting the buoyancy space are deformed, the sealing force that closes the buoyancy space decreases. It has a problem that the buoyancy function may be lost due to the inflow of seawater.

Republic of Korea Patent No. 10-1740918: Manufacturing method of hollow buoy Republic of Korea Patent Registration No. 10-1861759: Buoy for Fishing

The present invention provides a hollow buoy that prevents the visibility from being reduced and prevents the components constituting the buoyancy space from being deformed by preventing it from being crushed due to the impact with waves or floating objects in order to solve the above problems. has a purpose

In order to solve the above technical problem, the hollow buoy according to the present invention includes a body part having a buoyancy space formed therein, and an injection port that is introduced to a predetermined depth from one side of the body to form a nozzle receiving space and communicates with the buoyancy space. a buoyancy body including a nozzle receiving part formed therethrough; an air injection unit installed in the injection port to inject high-pressure air into the buoyancy space of the buoyancy body; a sealing unit installed in the main body to seal the nozzle accommodating space; and at least one ring part installed on the body part or the sealing unit.

According to an aspect of the present invention, the sealing unit is formed to have a wider width than the nozzle accommodating part, and is formed in a plate shape in close contact with the body part adjacent to the nozzle accommodating part so as to seal the nozzle accommodating space at the top of the nozzle accommodating part. do.

According to another aspect of the present invention, the air injection unit extends to a predetermined length and is installed in the injection port of the nozzle accommodating part, the nozzle part having one longitudinal side protruding from the nozzle accommodating space, and the nozzle part inside It is installed and allows the inflow of external air, but includes a check valve for blocking the outflow of the air of the buoyancy space to the outside.

In addition, the nozzle part has a screw thread formed on one outer circumferential surface in the longitudinal direction, and the sealing unit includes a sealing part installed in the body part to seal the nozzle accommodating space, and the nozzle from one surface adjacent to the nozzle accommodating space of the sealing part. It includes a coupling part extending to correspond to the depth of the receiving space, and the coupling part has a nozzle coupling groove provided with a screw thread so that the nozzle part can be screwed into the coupling part.

In the buoyancy according to the present invention, high-pressure air is filled in the buoyancy space through the air injection unit installed in the body part, so that the body part is prevented from being crushed by the pressure in the buoyancy space, and visibility is prevented from being reduced, and also due to deformation It has the advantage that the sealing force for sealing the buoyancy space is reduced to prevent the inflow of seawater.

1 is a perspective view of a hollow buoy according to a first embodiment of the present invention;
Figure 2 is a main part sectional view for explaining the sealing unit and the air injection unit of Figure 1,
3 is a sectional view of a main part for explaining a sealing unit and an air injection unit of a hollow buoyancy according to a second embodiment of the present invention.

Hereinafter, a hollow float according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 2 show a hollow float according to a first embodiment of the present invention.

Referring to the drawings, the hollow buoyancy according to the first embodiment of the present invention includes a buoyancy body 10 having a buoyancy space formed therein, and a buoyancy body 10 installed in the body to inject air into the buoyancy space of the buoyancy body 10. The air injection unit 20 so that the buoyancy body 10 is installed to prevent the external fluid from flowing into the buoyancy space of the buoyancy body 10, and the sealing unit 40, and the buoyancy body It is installed in (10) and provided with a hook portion (50) to be able to hang a rope or other binding sphere.

The buoyancy body 10 is introduced to a predetermined depth in the inner direction of the buoyancy space 12 from the main body 11 forming the buoyancy space 12 therein, and from one side of the outer wall to the nozzle accommodating space 16. and a nozzle accommodating part 15 through which an injection hole 17 communicating with the buoyancy space 12 is formed at an end in the inlet direction.

The main body 11 has a predetermined thickness, and the main body 11 is formed in a cylindrical shape in which an upper and a lower portion are rounded, and a side in a horizontal direction orthogonal to the vertical direction is circular. In the present embodiment, the main body 11 has a cylindrical shape, but it may be formed in a form having a polygonal cylindrical body such as a square or a pentagonal body or a coupling structure capable of being coupled to another body part. The body portion 11 has a flat contact end 11a formed on one side adjacent to the nozzle receiving portion 15 .

The nozzle accommodating part 15 is drawn downwardly from an upper side of the main body 11 so that a nozzle accommodating space 16 is provided therein. The nozzle receiving part 15 is formed in a cylindrical shape. A nozzle coupling part 18 extending downward in a cylindrical shape having an outer diameter smaller than that of the nozzle accommodating part 15 is installed at a lower portion of the nozzle accommodating part 15 .

The injection hole 17 is formed through the lower surface of the nozzle accommodating part 15 to communicate with the buoyancy space 12 at a position coaxial with the nozzle coupling part 18 .

The air injection unit 20 extends to a predetermined length and includes a nozzle unit 21 installed in the injection port 17 of the nozzle receiving unit 15 , the nozzle unit 21 and the nozzle receiving unit 15 . It is installed between the packing part 24 to block the inflow of external fluid into the buoyancy space, and is installed inside the nozzle part 21 to allow the inflow of external air, but the buoyancy space 12 ) includes a check valve unit 26 to block the outflow of air to the outside.

The nozzle part 21 is extended to have a predetermined length in the vertical direction and is formed in a tubular shape having a hollow part therein. The hollow part of the nozzle part 21 communicates with the buoyancy space 12 . A screw line is formed on the outer peripheral surface of the nozzle unit 21 . The nozzle unit 21 may be a general tire air injection nozzle.

The packing part 24 is formed to surround one lower side of the nozzle part 21 in the longitudinal direction. The packing part 24 extends a predetermined length in the vertical direction to have an annular cross-section having an inner diameter corresponding to the outer diameter of the nozzle part 21 . The packing part 24 is fitted to the injection hole 17 of the nozzle receiving part 15 so that the nozzle part 21 is installed in the injection hole 17 . The packing part 24 is configured for coupling the nozzle part 21 and the nozzle accommodating part 15 to have mutual airtightness, and the nozzle part 21 is directly installed in the nozzle accommodating part 15 or the When the nozzle part 21 and the nozzle accommodating part 15 are integrally configured, it may be omitted. The packing part 24 has a through-hole formed therein so that the hollow part of the nozzle part 21 communicates with the buoyancy space 12 .

The check valve unit 26 includes a pair of engaging members 27 and 28 installed on the inner circumferential surface of the nozzle unit 21 and the nozzle unit as it moves up and down in the hollow of the nozzle unit 21 . It includes a seat 29 for opening and closing 21, and a valve spring 30 installed in the hollow of the nozzle unit 21 to elastically bias the seat 29 in a direction to close the nozzle unit 21. .

The locking members 27 and 28 include a first locking member 27 and a second locking member 28 that are vertically spaced apart from the nozzle unit 21 to have a predetermined distance therebetween. The first and second locking members 27 and 28 are annular members each having an outer diameter corresponding to the inner diameter of the nozzle portion 21 and an inner diameter smaller than the inner diameter of the nozzle portion 21 . The first locking member 27 is installed on the inner upper portion of the nozzle unit 21 , and the second locking member 28 is installed at a lower portion having a predetermined distance from the first locking member 27 . The first locking member 27 and the second locking member 28 are installed to be spaced apart from each other at an interval at which the sheet 29 can be moved in the vertical direction. The first and second locking members 27 and 28 may be integrally formed with the nozzle unit 21 . The sheet 29 is formed in a circular plate shape having an outer diameter smaller than the inner diameter of the nozzle unit 21 and larger than the inner diameter of the first locking member 27 . The seat 29 is installed to be disposed between the first locking member 27 and the second locking member 28 . The valve spring 30 is a coil spring having an outer diameter corresponding to the outer diameter of the seat 29 is applied. The valve spring 30 is installed to be disposed between the seat 29 and the second locking member 28 , and a lower end thereof is supported by the second locking member 28 . And the upper end of the valve spring 30 is elastically supported to elastically bias the seat 29 upward, so that the upper end of the seat 29 is in close contact with the lower end of the first locking member 27 and the nozzle unit (21) exerts the restoring force to close the hollow part.

As described above, high-pressure air is filled in the buoyancy space 12 of the buoyancy body 10 in a state in which the nozzle unit 21 is installed in the buoyancy body 10 . A user may inject air into the buoyancy space 12 of the buoyancy body 10 by connecting a compressed air supply means (not shown) such as a compressor to the nozzle unit 21 . When high-pressure air is supplied from the compressed air supply means (not shown) while one side of the nozzle unit 21 is connected to the compressed air supply device (not shown), the sheet 29 is moved by the pressure of the air. It is pressed in the direction of compressing the valve spring (30). When the valve spring 30 is compressed, the seat 29 is separated from the lower end of the first locking member 27 and the hollow portion of the nozzle unit 21 is opened. The hollow part of the nozzle part 21 is opened, and the air supplied from the compressed air supply means (not shown) is injected into the buoyancy space 12 of the buoyancy body 10 . The buoyancy body 10 is preferably the pressure of the buoyancy space 12 is 10KGF / CM2 ~ 30KGF / CM2. When the pressure of the buoyancy space 12 of the buoyancy body 10 reaches a predetermined pressure and the compressed air supply means (not shown) is stopped, the injection of air is stopped. When the injection of air is stopped, the seat 29 is in close contact with the first locking member 27 by the restoring force exerted by the valve spring 30, and the flow path of the nozzle unit 21 is closed, so that the buoyancy body ( 10) of the buoyancy space 12 is blocked from flowing out of the air.

The check valve part 26 is mounted on the upper part of the nozzle part 21 to close the hollow part of the nozzle part 21 or a cap 33 separated by a user to open the hollow part of the nozzle part 21 . ) may be further provided. The cap 33 may be made of rubber or silicone. The cap 33 is drawn in from the other end in one direction so that one side is closed and the other side is open, and is formed in a cylindrical shape in which a cap coupling groove 34 is formed. A screw line corresponding to the screw line formed on the outer circumferential surface of the nozzle unit 21 is formed on the inner circumferential surface of the cap coupling groove 34 of the cap 33 , so that the cap 33 may be coupled to the nozzle unit 21 . .

The sealing unit 40 is formed to have a wider width than the nozzle accommodating part 15 and is adjacent to the nozzle accommodating part 15 so as to seal the nozzle accommodating space 16 at the top of the nozzle accommodating part 15 . It is formed in the shape of a plate in close contact with the main body (11).

The sealing unit 40 is installed to be attached to the close contact end (11a) of the main body (11). The sealing unit 40 has an outer diameter greater than the inner diameter of the nozzle accommodating part 15 . The sealing unit 40 is made of the same material as the main body 11 and is fused to the close contact end 11a of the main body 11 between the sealing unit 40 and the close contact end 11a. It is desirable to install it so that a gap does not occur.

The ring portion 50 is formed to protrude from the upper end of the sealing unit (40). The ring portion 50 is formed in a plate shape having a predetermined thickness. The ring portion 50 is penetrated in a direction orthogonal to the protruding direction, and a locking hole 51 is formed through which a rope, a binding tool, or a fishing gear can be hung. The ring part 50 is installed on the buoyancy body 10 by the sealing unit 40 being in close contact with the main body part 11 . Alternatively, the ring portion 50 may be formed to protrude from the outer surface of the body portion (11).

The hollow buoyancy according to the first embodiment of the present invention has a high-pressure air in the buoyancy space 12 of the buoyancy body 10 in a state in which high-pressure air is filled in the buoyancy space 12 of the buoyancy body 10. expansion force is applied. The hollow buoy according to the first embodiment of the present invention is prevented from being crushed by the impact of waves or collision with other floating objects in the state of being suspended in the sea by the expansion force of the high-pressure air. It has the advantage of preventing the visibility from being deteriorated.

In addition, in the hollow buoyancy according to the first embodiment of the present invention, the buoyancy space 12 is primarily sealed by the buoyancy body 10 and the air injection unit 20, and the sealing unit is the nozzle By sealing the accommodating space 16 secondarily, the air in the buoyancy space 12 is prevented from leaking out, as well as the external seawater is effectively prevented from flowing into the buoyancy space 12, which is the first aspect of the present invention. It has the advantage of improving the service life of the hollow float according to the embodiment.

3 shows a hollow float according to a second embodiment of the present invention. In the hollow buoyancy according to the second embodiment of the present invention, the components other than the nozzle unit 21 and the sealing unit 40 are the same as those of the first embodiment, and thus a duplicate description will be omitted.

Referring to the drawings, the nozzle unit 21 has a thread formed on an outer peripheral surface of one side in the longitudinal direction. The configuration of the nozzle unit 21 may be the same as that of the first embodiment.

The sealing unit 40 includes a sealing part 44 installed in the main body 11 to seal the nozzle accommodating space 15 , and one surface adjacent to the nozzle accommodating space 15 of the sealing part 44 . a coupling part 41 extending from the nozzle accommodating space 16 to correspond to the depth of the nozzle accommodating space 16, and a first sealing member 46 installed between the coupling part 41 and the nozzle accommodating part 15; , a second sealing member 47 installed between the sealing part 44 and the body part 11 to maintain airtightness between the sealing part 44 and the body part 11 .

The sealing part 44 is the same as the sealing unit 40 of the first embodiment.

The coupling part 41 has a nozzle opening and closing groove 43 in which one side of the nozzle part 21 exposed to the nozzle accommodating space 16 can be accommodated on the inner side of the end of the extending direction of the nozzle part 21 . The inlet is formed along the direction, and a thread corresponding to the thread of the nozzle unit 21 is provided on the inner circumferential surface of the nozzle opening and closing groove 43 .

The coupling part 41 is manufactured integrally with the sealing part 44 . The nozzle opening and closing groove 43 of the coupling part 41 is formed with the nozzle part 21 when the sealing part 41 is mounted to be accommodated in the nozzle accommodating space 16 of the nozzle accommodating part 15 . It is formed at a position forming a coaxial axis.

As the coupling part 41 is coupled with the nozzle part 21, a traction force is exerted so that the packing part 24 is pulled upward. By this traction force, the packing part 24 and the nozzle receiving part 15 are separated. It is preferable that the packing part 24 is formed in a truncated cone shape having a large diameter as it progresses downward so as to be more closely adhered.

The first sealing member 46 has a shape in which the lower end of the coupling part 41 abuts against the bottom surface of the nozzle accommodating part 15 when the coupling part 41 is mounted to be accommodated in the nozzle accommodating part 15 . is formed to correspond to In this embodiment, the first sealing member 46 has an outer diameter corresponding to the outer diameter of the coupling portion 41 and is formed in an annular plate shape with a through hole having a shape corresponding to the nozzle opening and closing groove 43 on the inside. .

The second sealing member 47 corresponds to a shape in which the lower end of the sealing portion 44 comes into contact with the main body 11 when the coupling portion 41 is mounted to be accommodated in the nozzle receiving portion 15 . is formed In this embodiment, the second sealing member 47 has an outer diameter corresponding to the outer diameter of the sealing portion 44, and has an annular plate shape with a through hole having an inner diameter corresponding to the outer diameter of the coupling portion 41 on the inside. is formed

The first and second sealing members 46 and 47 are deformed in a horizontal direction perpendicular to the direction in which the pressing force is applied by being pressed by the coupling force when the first sealing part 41 is screwed with the nozzle part 21 . And one made of rubber or Teflon material that can keep airtightness can be applied.

The hollow float according to the second embodiment of the present invention as described above has a configuration in which the coupling part 41 is screwed with the nozzle part 21, and thus the coupling part 41 is connected to the nozzle by the coupling force. Sealed so as to be in close contact with the bottom surface of the receiving part 15 and the sealing part 44 is in close contact with the body part 11 to prevent seawater or foreign substances from entering the buoyancy space 12 of the buoyancy body 10 . It has the advantage of improving power.

In addition, in the hollow buoyancy according to the second embodiment of the present invention, the user releases the coupling state of the coupling part 41 and the nozzle part 21 to remove the sealing unit 40 from the buoyancy body 10 . By being detachable, the air filled in the buoyancy space 12 of the buoyancy body 10 can be replenished or discharged, thereby having the advantage of efficiently managing the hollow buoyancy according to the second embodiment of the present invention.

In addition, in the hollow float according to the second embodiment of the present invention, a first sealing member 46 is installed between the coupling part 41 and the nozzle receiving part 15, and the second sealing part 44 ) and the second sealing member 47 is installed between the main body 11, the sealing unit 40 and the Airtightness is reinforced between the buoyancy bodies 10 to have the advantage of increasing the lifespan of the hollow buoyancy according to the second embodiment of the present invention.

The hollow buoyancy according to the present invention described above has been described with reference to an example shown in this drawing, but this is only an example, and those of ordinary skill in the art will perform various modifications and equivalent other implementations therefrom. It will be appreciated that examples are possible. Accordingly, the scope of true technical protection of the present invention should be defined by the technical spirit of the appended claims.

10: buoyancy body 11: body part
15: nozzle receiving unit 20: air injection unit
40: sealing unit 50: ring part

Claims (4)

The body portion 11 having a buoyancy space 12 formed therein, and an injection hole that is introduced to a predetermined depth from one side of the body portion 11 to form a nozzle receiving space 16 and communicates with the buoyancy space 12 ( 17) and a buoyancy body 10 including a nozzle accommodating part 15 through which is formed;
an air injection unit 20 installed in the inlet to inject high-pressure air into the buoyancy space 12 of the main body 11;
a sealing unit 40 installed in the main body 11 to seal the nozzle accommodating space 16;
at least one ring portion 50 installed in the sealing unit 40; and
The body part 11 is provided with a flat close contact end 11a on one side adjacent to the nozzle receiving part 15,
The sealing unit 40 is formed in a plate shape wider than the nozzle accommodating space 16 of the nozzle accommodating part 15 and is made of the same material as the main body 11 to form the nozzle accommodating part 15. A sealing portion 44 that is fused to the close contact end 11a of the main body 11 adjacent to the nozzle receiving portion 15 so as to seal the nozzle receiving space 16 from the upper portion, and the sealing portion 44 and a coupling portion 41 extending from one surface adjacent to the nozzle accommodating space 16 to correspond to the depth of the nozzle accommodating space 16,
The ring portion 50 is formed to protrude from the upper end of the sealing unit 40, and the engaging hole 51 is formed through,
The nozzle accommodating part 15 is introduced downward from the upper side of the main body 11 and is formed in a cylindrical shape with the nozzle accommodating space 16 provided therein. A nozzle coupling part 18 extending downward in a cylindrical shape of a small outer diameter is installed,
The injection hole 17 is formed through the lower surface of the nozzle receiving part 15 to communicate with the buoyancy space 12 at a position coaxial with the nozzle coupling part 18,
The air injection unit 20 extends to a predetermined length and is installed in the injection port 17 of the nozzle accommodating part 15 , the nozzle part 21 having one longitudinal side protruding from the nozzle accommodating space 16 . ) and is installed in the nozzle part 21, allowing the inflow of external air, but comprising a check valve part 26 that blocks the outflow of the air in the buoyancy space 12 to the outside. hollow buoy.

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