KR20200076948A - Buoy for aquaculture - Google Patents

Abstract

The present invention relates to a buoy for aquaculture, which enables a worker to easily perform air injection work by inserting an air injection needle into a packing member fitted into a body portion and injecting air into the body portion, and most of all, which is capable of minimizing air injected into the body portion from being discharged to the outside during a process of the air injection work. A packing member is fitted into an insertion groove of a body portion such that an air injection needle for injecting air into a hollow portion of the body portion may be penetrated, and is made of a material having elasticity that can restore a shape by elastic restoring force. Thus, it is possible to prevent air injected into the hollow portion from being discharged to the outside through a space formed while the air injection needle penetrates the packing member.

Description

Buoy for aquaculture

The present invention relates to a buoy for aquaculture, and more specifically, by inserting an air injection needle into a packing member fitted to the body portion, so that air can be injected into the body portion, so that an operator can perform an air injection operation easily. First of all, it relates to a buoy for aquaculture that minimizes the discharge of air injected into the body portion to the outside during the air injection process.

In general, the buoy used at the time of marine landmark is used to mark the route of the ship or to indicate the area and location of various fishing gear used in aquaculture such as fish, seaweed, seaweed, and abalone.

On the other hand, these conventional buoys are made to be wrapped around a rope around the outer circumference to connect to a number of other support members or to connect to a number of other buoys, and the main ones are made of styrofoam material to have buoyancy.

However, in the case of a buoy made of styrofoam, the physical properties of the styrofoam itself are weak, and when used for a long time, there is a problem that the outer periphery of the buoy wound around the rope can be easily cracked or damaged by other external factors such as waves or wind.

In addition, as described above, the damaged buoys can no longer be wrapped by ropes, and the buoyancy caused by the damage is also reduced and must be discarded, and the debris of the damaged buoys covers the sea surface and not only harms the aesthetics of the sea, but also causes seawater pollution. There was a problem causing.

Due to this problem, in recent years, many buoys have been developed to be used by injecting air therein, and the structure thereof is also used in various ways.

First, looking at the prior art,

An air tube in which an air inlet is formed and a portion of air is filled in a part of registration number 10-1880486; A buoy molded body formed with a binding groove portion, welded from a side member and a side welding portion at one end, and formed with a cylindrical portion; A reinforcing member positioned at the inner diameter of the binding groove portion and the cylindrical portion and formed with a groove guide portion on one side of a circular matrix; An eco-friendly buoy that wraps both sides of the air tube with a pair of buoy molded bodies and welds a central weld at a portion where the cylindrical portion overlaps; It relates to an environmentally friendly buoy consisting of a buoy molded body incorporating an air pressure regulating air tube, characterized in that by filling the air with the air inlet, the buoyancy is controlled and fixed with a sealing member.

Looking at the above-described conventional technology, although it is possible to control the buoyancy by injecting air into the buoy, after injecting air through the air inlet, it is injected inside in the process of coupling the sealing member to the air inlet The air is made of a structure that is easily discharged to the outside through the air inlet, and there is a troublesome problem such as setting the amount of air to be injected and injecting it in consideration of the air to be discharged.

The present invention has been devised to solve the problems of the prior art described above, and the packing member is configured to fit into the insertion hole of the body part, but configured to allow the air injection needle to inject air into the hollow part of the body part to penetrate, and to provide elastic restoring force. The buoy for aquaculture is made of a material having a resilient shape that can be restored by the air injection needle to prevent the air injected into the hollow part from being discharged to the outside through the space formed through the packing member. It was completed as a technical task with the emphasis on providing.

According to the present invention for achieving the above object, a hollow portion is formed inside, and a body portion in which an insertion hole communicating with the hollow portion is formed on one side of the outer circumference, and the inside air of the hollow portion is formed in the insertion hole In the buoy for aquaculture consisting of a packing member to prevent discharge to the outside, the packing member is configured to fit into the insertion hole, but is configured to allow an air injection needle to inject air into the hollow portion of the body, through the When the air injection needle is separated from the packing member, the air injection needle is made of a material having elasticity to prevent the air injected into the hollow part from being discharged to the outside through the space formed through the packing member. The problem is to be solved by providing a buoy for aquaculture, which is characterized in that the shape can be restored by elastic restoring force.

According to the buoy for aquaculture according to the present invention, the packing member body is maintained while maintaining the original purpose of displaying the route of the ship or the area and position of various fishing gear used for aquaculture such as fish, seaweed, seaweed, and abalone. After inserting into the part first, the air injection needle can be penetrated through the packing member and air can be injected into the hollow part of the body, minimizing the discharge of air injected into the body part into the outside during the existing air injection process. It is a useful invention that can improve the operational efficiency.

1 is a front view showing a preferred embodiment of the present invention
Figure 2 is a sectional front view showing that the packing member is fitted in the body portion of the configuration of the inventors buoys
Figure 3 is a cross-sectional front view showing that the air injection needle is inserted into the packing member of the configuration of the buoy for aquaculture inventors
Figure 4 is an enlarged view showing that the air is injected into the hollow through the air injection needle shown in Figure 3
Figure 5 is an enlarged view showing that the air injection needle shown in Figure 3 is separated from the packing member
6 is a front sectional view showing another embodiment of the present invention
7 is a front view showing another embodiment of the present invention
8 is a plan view showing another embodiment of the present invention and a flat cross-sectional view showing (A ㅡ A') of FIG. 7

The present invention is to insert the air injection needle into the packing member fitted to the body portion so that air can be injected into the body portion so that the operator can easily perform the air injection operation, and above all, the body portion in the air injection operation process A buoy for aquaculture is provided to minimize the discharge of air injected inside.

Hereinafter, with reference to Figures 1 to 8 for the preferred configuration and operation of the present invention for achieving the above object in connection with the accompanying drawings will be described.

First of all, referring to FIGS. 1 to 5 before explaining the present invention, a hollow portion 110 is formed inside and an insertion hole 120 communicating with the hollow portion 110 on one side of the outer circumference. In the buoy for aquaculture consisting of the body portion 100 is formed and the packing member 200 is configured in the insertion hole 120 to prevent the internal air of the hollow portion 110 is discharged to the outside, The packing member 200 is configured to fit into the insertion hole 120, but is configured to allow an air injection needle (n) for injecting air into the hollow portion 110 of the body portion 100 to pass through, and the air When the injection needle (n) is separated from the packing member 200, the air injected into the interior of the hollow portion 110 through the space formed by the air injection needle (n) passing through the packing member 200 is external It is composed of a material having elasticity to prevent it from being discharged, and is configured to be able to restore shape by elastic restoring force.

First, a conventional buoy for aquaculture is composed of a body portion 100 and a packing member 200.

As shown in FIG. 1, the body portion 100 is formed with a hollow portion 110 through which air is injected and filled, and penetrates from the outside to the inside on one side of the outer circumference to communicate with the hollow portion 110. The insertion hole 120 is formed.

Here, the body portion 100 may be made of a variety of synthetic resin materials, such as plastic material, which is to improve the problem of causing damage to the conventional styrofoam buoy easily broken.

That is, by injecting and filling the hollow portion 110 with air, the buoyancy of the body portion 100 can be adjusted, and the body portion 100 made of a plastic material is prevented from being deformed by atmospheric pressure and water pressure. Is to do.

In addition, as shown in FIGS. 1 and 2, the packing member 200 is configured in the insertion hole 120 to prevent the air injected into the hollow portion 110 from being discharged to the outside.

On the other hand, the conventional form buoy configured as described above, after injecting air through the insertion hole 120 of the body portion 100, the packing member 200 in the insertion hole 120 to configure Although the air injected into the hollow portion 110 is prevented from being discharged through the insertion hole 120, the interior of the hollow portion 110 is connected to and coupled to the packing member 200 in the insertion hole 120 Since the air injected into the structure is made to be discharged to the outside through the insertion hole 120, there is a cumbersome problem, such as having to set the amount of air injected in consideration of the air discharged in order to adjust the buoyancy of the buoy to a set value. .

If the present invention configured as described above in more detail,

The present invention in the buoy for aquaculture,

3, 4, and 5, the packing member 200 is configured to fit into the insertion hole 120, but an air injection needle (n) that injects air into the hollow portion 110 of the body portion 100 ) Is configured to be penetrated, and when the air injection needle (n) is separated from the packing member 200, the air injection needle (n) passes through the packing member 200 through a space formed through the hollow It is made of a material having elasticity to prevent the air injected into the interior of the (110) from being discharged to the outside, and is configured to be capable of restoring shape by an elastic restoring force.

Here, the packing member 200 has the same diameter as the diameter of the lower end inserted into the insertion hole 120 so as to be configured to fit into the insertion hole 120 or the insertion hole ( It is preferably formed larger than the diameter of 120).

That is, the packing member 200 is configured to forcibly fit into the insertion hole 120 to prevent air injected into the hollow portion 110 from being discharged to the outside through the insertion hole 120.

In addition, the packing member 200 is preferably made of a rubber material having elasticity so that the air injection needle (n) for injecting air into the hollow portion 110 of the body portion 100 can be penetrated.

That is, when the air injection needle (n) is separated from the packing member (200), the packing member (200) is a space formed by the air injection needle (n) passing through the packing member (200) (air injection needle) The hole formed by (n) is filled with the shape restored by the elastic restoring force of the packing member 200 made of an elastic material, thereby penetrating the air injection needle (n) through the packing member 200 Even if the air injection needle (n) is separated from the packing member 200 after injecting air into the hollow portion 110, the air injected into the hollow portion 110 is prevented from being discharged to the outside. It is possible.

As illustrated in FIG. 6, a locking portion 210 is formed at a lower end of the packing member 200 to be locked to an inner upper side of the body portion 100.

That is, although the locking member 210 is primarily fixed because the packing member 200 is fitted into the insertion hole 120, the packing member 200 is physically and internally acting from the outside. When separated from the insertion hole 120 of the body portion 100 by air pressure, so that the locking portion 210 formed at the bottom of the packing member 200 is engaged with the inner upper surface of the body portion 100 The packing member 200 is secondarily fixed to the insertion hole 120 to prevent separation from the insertion hole 120.

As shown in Figures 1 and 2, the outer periphery of the body portion 100 is formed along the outer periphery of the body portion 100, a plurality of locking grooves 130 are formed to form a predetermined interval spaced upward and downward. .

That is, the locking groove 130 is positioned by placing the rope inside the locking groove 130 where an operator binds a buoy for aquaculture to a separate support member or interconnects a plurality of aquaculture buoys. It is formed so as to easily wrap the body portion 100 and work.

In addition, a through-hole 140 is formed on one side of the outer circumference of the body portion 100 as illustrated in FIGS. 7 and 8.

Here, the through-hole 140 is preferably interpolated to a certain depth on one side of the outer periphery of the body portion 100, and is formed on one side and the other side so as to face each other around the center of the body portion 100 It is preferable that each is formed, so that the operator can connect the form buoys to separate support members or connect the ropes provided for interconnecting a plurality of form buoys into the respective through holes 140. By doing so, it is possible to prevent the rope from deviating from the body portion 100.

In addition, as shown in FIG. 7, the gripping parts 150 are formed on the upper and lower parts of the body part 100 so that an operator can grip them.

Here, the gripping portion 150 may be formed on one side and the other side so as to face each other with respect to the center portion in the upper and lower portions of the body portion 100, which is two workers are the body portion 100 The two gripping parts 150 formed on the upper part and the two gripping parts 150 formed on the lower part of the body part are respectively gripped so that the inventors can easily transport the buoy for aquaculture. .

According to the buoy for aquaculture according to the present invention, the packing member body is maintained while maintaining the original purpose of displaying the route of the ship or the area and position of various fishing gear used for aquaculture such as fish, seaweed, seaweed, and abalone. After inserting into the part first, the air injection needle can be penetrated through the packing member and air can be injected into the hollow part of the body, minimizing the discharge of air injected into the body part into the outside during the existing air injection process. It is a useful invention that can improve the operational efficiency.

100: body
110: hollow
120: insertion hole
130: jam groove
140: through hole
150: gripping part
200: packing member
210: hook
n: Air injection needle

Claims (3)

The hollow portion 110 is formed inside, and the body portion 100 is formed in the insertion hole 120 communicating with the hollow portion 110 on one side of the outer circumference, and the insertion hole 120 is formed in the hollow In the buoy for aquaculture consisting of a packing member 200 to prevent the internal air of the unit 110 is discharged to the outside,
The packing member 200 is configured to fit into the insertion hole 120, but is configured to allow an air injection needle (n) for injecting air into the hollow portion 110 of the body portion 100 to pass through, and the air When the injection needle (n) is separated from the packing member 200, the air injected into the hollow portion 110 through the space formed by the air injection needle (n) passing through the packing member 200 is external It is composed of a material having elasticity so that it can be prevented from being discharged.
According to claim 1,
At the bottom of the packing member 200, a buoy for aquaculture, characterized in that a locking portion 210 is formed on the inner upper surface of the body portion 100.
According to claim 1,
In the body portion 100,
It is formed along the outer periphery of the body portion 100, a plurality of locking grooves 130 to form a predetermined interval spaced upward and downward, and
The through hole 140 is formed through the outer periphery side of the body portion 100,
A buoy for aquaculture, characterized in that the upper and lower parts of the body part 100 are configured to include gripping parts 150 which are respectively formed to be gripped by an operator.

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