KR200381210Y1 - Device for preventing red tide of floating net pens - Google Patents

Abstract

The present invention relates to a cage farm red tide prevention device, and more specifically, to prevent red tide to circulate the seawater in cage cages and to increase the amount of dissolved oxygen to prevent red tide by injecting air into the water in cage cages of cage cages Relates to a device.

The cage farm red tide prevention device according to the present invention, the buoy floating on the sea surface and hanging on the buoys formed by connecting several caged shells composed of a net including a drooping under the sea level bubbles in the water under the sea level in the caged shell farm In cage restraint apparatus for preventing red tide by spraying, the pump is provided on the barge located on one side of the cage farm to compress and supply air, and one end is connected to the compressed air supply side of the pump A pipe extending to each of the capillary cells, one end of the pipe connected to the pipe, and the other end of the pipe to be immersed below the inner sea level of each of the cage shell, and the air supplied to the other end of the injection pipe. It characterized in that it comprises a bubble generating nozzle for spraying the water in the bubble state The.

Description

RED TIDE OF FLOATING NET PENS}

The present invention relates to a cage farm red tide prevention device, and more specifically, to prevent red tide to circulate the seawater in cage cages and to increase the amount of dissolved oxygen to prevent red tide by injecting air into the water in cage cages of cage cages Relates to a device.

Recently, the coastal waters are causing serious damage to marine life due to the occurrence of harmful red tide. The duration of the red tide ranges from a few days to several tens of days, with seawater becoming more viscous and odorous. Because plankton's bodies decompose all at once and consume oxygen in the ocean, fish and shellfish die of gills or shortness of breath.

Since such red tide causes enormous damage to marine life, many efforts have been made to prevent and remove red tide. For example, a method of spraying ocher to seawater is used when red tide occurs.

However, this method has a disadvantage in that it cannot prevent red tide occurring in a large area at one time and requires a lot of manpower.

Meanwhile, offshore coastal farming is being actively carried out using cage farms where fish are hung in the nets to fish. However, the above-mentioned red tide causes enormous damage to the fish farmed in the cage farm. Therefore, the cage farms reduce the damage by spraying the red soil immediately around the occurrence of red tide or stopping feeding, while reducing the red tide density by extracting the bottom water.

However, the conventional method of spraying the loess around the cage farm as described above is difficult to effectively prevent red tide because it is difficult and requires a lot of manpower, and has a disadvantage that it is difficult to immediately respond when the red tide occurs.

In addition, the method of extracting the bottom water and feeding it into the cage has a limitation in decreasing the red tide density but increasing the amount of dissolved oxygen depleted by the red tide.

Furthermore, the conventional red tide prevention method of spraying the above-mentioned loess or extracting the low-rise water and feeding it into the cage is a passive method of preventing the diffusion of red tide.

The present invention is to solve the above-mentioned problems, an object of the present invention is to circulate the water in the cage cages by circulating the water in the cage circulating the water in the cage and increase the amount of dissolved oxygen to prevent red cage cage tide prevention device To provide.

In addition, an additional object of the present invention is to connect the end portions of the pipes extending along the array of caged shells to form a closed circuit by connecting the end portions of the pipes installed along the arrayed cages, so that the air pressure can be reduced even at a position far from the pump. It is to provide a cage farm red tide prevention device that can be sprayed relatively uniformly to each of the cage shell cells do not fall significantly.

In order to achieve the above object, the cage farm red tide prevention device according to the present invention, the cage floating in the sea level and the cages formed by arranging a couple of caged cells including a net hanging drooping below the sea level hanging on the cage cages A cage farm for preventing red tide by spraying bubbles into the water below the sea level in a cell, comprising: a pump installed on a barge located at one side of the cage farm for compressing and supplying air, and one end of the cage; A pipe connected to the compressed air supply side of the pump and extending to each of the caged shells, one end of the pipe connected to the pipe, and the other end of which is immersed below the inner sea level of each of the caged shells, and the other side of the spray pipe. A device that injects air supplied to the end into the air in a bubble state It characterized in that it comprises a foaming nozzle.

According to the configuration described above, the cage cage red tide prevention device according to the present invention can not only increase the amount of dissolved oxygen by spraying compressed air into the water in the cage shell, but also increase the amount of dissolved oxygen in the cage shell by the air injection and the rise of the injected air. As the seawater circulates, it is naturally exchanged with the seawater outside the caged shell. In particular, since an upward flow is formed in the water inside the cage shell as the bubble rises, the low-rise water located under the cage shell rises and flows into the cage shell.

In addition, the cage farm tide prevention device according to the present invention, the several cages are arranged in two or more rows symmetrically to the left and right, the pipe is branched left and right at the point connected to the pump branched pipe is symmetrical left and right Each of the ends of the pipes extending along each other is arranged along the array, and the other ends of the branched pipes are connected to each other.

Pipe cages connected to the pump in cage cages where the caged shells are arranged symmetrically in two or more rows are branched at the point where they are connected to the pump and the branched pipes extend along the array of caged shells. In this case, the pressure of the compressed air supplied through the branched pipe drops as it moves away from the pump. Accordingly, the further away from the pump, the weaker the amount of air and the injection pressure injected into the water in the caged shell. The present invention connects the ends of branched pipes branched from the point connected to the pump and extends along the array of caged cells to form a circulation loop so that the pressure of air flowing through the branched pipes is far from the pump. It also prevented a big drop from the point.

Hereinafter, with reference to the embodiment shown in the drawings will be described in more detail the cage cage red tide prevention device according to the present invention.

1 is a plan view conceptually illustrating a cage farm red tide prevention device according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a cross-section in A-A of FIG.

The cage farm red tide prevention device 20 according to the present invention is to prevent red tide by injecting air into the water in the cage shell (10a to 10h) constituting the cage farm (10).

Referring to the embodiment shown in the drawings, the cage farm 10 is a cage rich shell (10a to 10h) including a float 12 floating on the sea surface, and the net 13 hanging on the float 12 and drooping below the sea surface ) Is formed by connecting several. In the figure, an embodiment in which the buckle 12 is connected to the lower part of the frame 11 to be integrated with the frame 11 and the mesh 13 is pulled out below the sea level by the weight 14 is shown. . In addition, the drawing shows an embodiment in which the caged cells 10a to 10h are arranged in four rows symmetrically in two rows from side to side with respect to the barge 22 in which the pump 21 is installed.

The red tide preventing device 20 includes a pump 21, a pipe 23, a spray pipe 24, and a bubble generating nozzle 25.

The pump 21 compresses air and supplies the same through the pipe 23. The pump 21 is installed on the barge 22 located on one side of the cage farm 10. The present invention is for injecting air into high pressure water. In particular, as the bubble generating nozzle 25 is located deeper, a higher injection pressure is required. Therefore, it is preferable that the pump 21 can generate a high pressure. Meanwhile, as described above, the pump 21 is installed on the barge 22 connected to the cage farm 10 away from the land. Therefore, the drive means of the pump 21 is preferably an internal combustion engine rather than an electric motor. Internal combustion engines are particularly suitable for compressing air at high pressures due to their high output. The air compressed by the pump 21 is injected into the water by the bubble generating nozzle 25 through the pipe 23 and the injection pipe 24.

The pipe 23 extends from the pump 21 to each of the cage cells 10a to 10h to supply the air compressed by the pump 21 to each of the cage cells 10a to 10h. That is, one end of the pipe 23 is connected to the compressed air supply side of the pump 21 and extends to each of the caged cells 10a to 10h.

On the other hand, the cage rissel (10a to 10h) may be arranged in two or more rows symmetrically from side to side based on the barge 22, the pump 21 is installed. As described above, there is shown an embodiment in which the caged cells 10a to 10h are symmetrically arranged (four rows in total) in two rows, left and right. As described above, when several caged cells 10a to 10h are arranged in two or more rows symmetrically from side to side, the pipe 23 is branched from left to right at a point connected to the pump 21 to branch 23a. , 23b) are provided to extend along the array of the curd shells arranged symmetrically from side to side. That is, referring to the drawings, each of the branched pipes 23a and 23b extends along the left and right sides of each of the two rows of the caged lid cells arranged in two rows on each of the left and right sides. In general, the longer the pipe, the greater the pressure drop from the point away from the pump. The problem that the pressure drops as described above becomes more serious as the length of the pipes 21a and 21b branched and branched by the pipe 21 is increased. As a result, the amount and pressure of air injected from the branched pipes 23a and 23b to each of the caged shells are greatly reduced as the distance from the pump 21 is increased. That is, the amount and pressure of air injected into the interiors of the curd cells 21e to 21h provided with the injection pipe 24 connected to the pipes 23a and 23b branched from the pump 21 and the bubble generating nozzle 25 connected thereto are Compared to the amount and pressure of air injected into the interiors of the caged cells 21a to 21d provided with the injection pipe 24 connected to the pipes 23a and 23b branched from the pump 21 and the bubble generating nozzle 25 connected thereto. It will fall greatly. As a result, the effect of red tide prevention on the street cures 21e to 21h is greatly reduced. The present invention connects the ends of the branched pipes 21a and 21b which extend along the rows of the craniel cells arranged symmetrically as described above, so that the whole branched pipes 21a and 21b are formed as a closed loop of the circulation loop. It is characterized in that the pressure does not drop significantly even at a point away from the pump (21). Referring to the drawings, reference numeral J denotes a connection point to which the ends of the pipes 21a and 21b branched as described above are connected. The valve 28 is installed at the connection point J to block the connection point J when air is supplied only to one of the pipes 21a or 21b of the branched pipe. Similarly, each of the branched pipes 23a and 23b is provided with a valve 26 for opening and closing the supply of air at a point connected to the pump 21.

The injection pipe 24 is connected to the pipe 21 for supplying air supplied through the pipe 21 to the bubble generating nozzle 25 located in the water in each of the cage shells (10a to 10h). will be. That is, the injection pipe 24 is connected to a predetermined position of the branched pipes 21a and 21b so that at least one or more are installed in each of the caged shells 10a to 10h, and the other end is the caged shell. 10a to 10h are submerged below each inner sea level. The drawing shows an embodiment in which the injection pipes 24 are alternately connected to both sides of the branched pipes 21a and 21b. The injection pipe 24 is provided with a valve 27 for opening and closing the flow of the supplied air and adjust the amount thereof.

The bubble generating nozzle 25 is for injecting bubbles into the water in the cage lid (10a to 10h). Referring to the drawings, the bubble generating nozzle 25 is connected to the other end of the injection tube 24 and injects the supplied air into the water in a bubble state. The bubble generating nozzle 25 is preferably composed of a bubble generating tube formed with a fine hole so as to generate as much fine bubbles as possible. Bubbles injected into the water from the bubble generating nozzles 25 rise and form an upward flow in the caged cells 10a to 10h to promote the circulation of water and at the same time, some of the bubbles melt into the water and the caged cells 10a to 10h. The amount of dissolved oxygen in) increases. In particular, due to the rise of air bubbles, the low-flow water located in the lower portion of the caged shells is raised into the caged shells 10a to 10h by the upward flow formed in the water inside the caged shells 10a to 10h, and into the caged shells 10a to 10h. Since it flows in, the red density of the water inside the caged cells 10a to 10h is reduced.

By the above configuration, the cage cage red tide prevention device according to the present invention has the advantage of preventing the red tide by circulating the water in the cage cage by increasing the amount of dissolved oxygen by spraying bubbles in the cage cage shell of cage cages.

In addition, the cage cage red tide prevention device according to the present invention is connected to the end portion of the pipe installed along the arrangement of several caged shells to form a connection of the pipes in a closed circuit to air even at a position far from the pump Since the pressure does not drop significantly, it has the advantage of spraying air relatively uniformly to each of the caged shell.

The cage farm red tide prevention device described above and shown in the drawings is only one embodiment for carrying out the present invention, and should not be construed as limiting the technical spirit of the present invention. The scope of protection of the present invention is determined only by the matters described in the following Utility Model Registration Claims, and the embodiments of the present invention which have been improved and changed without departing from the gist of the present invention are obvious to those skilled in the art. As long as it is one of the protection scope of the present invention.

1 is a plan view conceptually showing a cage farm red tide prevention device according to an embodiment of the present invention

2 is a cross-sectional view showing a cross section in A-A of FIG.

<Short description of the major reference symbols>

10 cage farm

10a to 10h gadulicel

11 frames

12 floats

13 netting

14 weight

20 Red Tide Prevention Device

21 pumps

22 barge

23 Piping

23a, 23b branched piping

24 injection tubes

25 Foaming Nozzle

26,27,28 valve

J connection point

Claims (2)

A cage farm to prevent red tide by spraying bubbles into the water below the sea surface in the cage cage, formed by arranging several caged shells formed by arranging several float cages including a float floating on the sea level and a net drooping below the sea level. In the prevention device, A pump installed on a barge located at one side of the cage farm for supplying compressed air; A pipe having one end connected to the compressed air supply part of the pump and extending to each of the caged shells; An injection pipe having one end connected to the pipe and the other end immersed below the inner sea level of each of the caged shells; Confinement farm red tide prevention device characterized in that it comprises a bubble generating nozzle connected to the other end of the injection pipe injecting the supplied air in the air in the bubble state. The method of claim 1, The several caged cells are arranged in two or more rows symmetrically from side to side, The pipes are branched from side to side at the point connected to the pump so that the branched pipes respectively extend along the arrangement of the curb shells arranged symmetrically from side to side, Cage culture plant red tide prevention device, characterized in that the other end of the branched pipe is connected to each other.