KR102184919B1 - Oxygen supply system of fish farming cages - Google Patents

Abstract

Dissolved oxygen supply system for the cage farm is started. The caged farm dissolved oxygen supply system comprises: an oxygen dissolved water generating tank installed in at least one oxygen water supplying cell selected from a plurality of cages; The upper part is exposed to the atmosphere and the lower part extends into the seawater through the oxygen-dissolved water producing tank, and seawater flowing into the water in the oxygen-dissolved water producing tank at one side and flowing through the lower part into the oxygen-dissolved water producing tank Seawater supply pipe having a seawater discharge pipe to be supplied; A microbubble generating device provided in the oxygen-dissolved water producing tank to supply seawater discharged and supplied from the seawater discharge pipe to the oxygen-dissolved water producing tank as dissolved oxygen water; And a pump located outside the oxygen water supply cell and pumping the oxygen dissolved water generated in the oxygen dissolved water generating tank and supplying it into the cage cell around the oxygen water supply cell.

Description

Dissolved oxygen supply system for the cage farm {OXYGEN SUPPLY SYSTEM OF FISH FARMING CAGES}

The present invention relates to a system for supplying dissolved oxygen in a caged farm, and more particularly, to a system for supplying dissolved oxygen in a caged farm for supplying dissolved oxygen water in a caged cell using low-temperature seawater.

In general, in coastal seas, aquaculture using a cage farm in which fish are cultivated inside the net by hanging a net in a bugu is actively carried out.

These cage farms allow fish to be cultivated easily in one place by preventing fish from escaping to the outside by a net hanging from the float.

Such a cage farm is a business that greatly contributes to the income increase of fishing villages by cultivating a large amount of fish in a small space, but material damage is frequently caused by the death of fish in the cage farm due to the red tide generated in the coastal sea. .

The red tide phenomenon refers to a phenomenon in which plankton suddenly multiplies in enormous numbers, changing the color of seas, rivers, canals, and lakes. The cause of the red tide phenomenon is eutrophication of water, and when an excessive amount of organic nutrients is contained, a large amount of plankton is generated.

Also, in recent years, the reduction of tidal flats due to coastal development has emerged as one cause. In other words, various organisms inhabiting the tidal flat played a role of natural purification by feeding microorganisms or plankton in the water, but the red tide phenomenon is intensifying due to the reckless reclamation project. In addition, it is known that a change in temperature due to an abnormal climate, an increase in water temperature and a decrease in wind accordingly, stagnate the flow of water and cause a red tide phenomenon.

Due to the above-described red tide phenomenon, the damage to seafood is enormous. In particular, in the case of aquaculture farms, problems such as group death of fish and shellfish due to the red tide phenomenon occur. In addition, when a person ingests fish and shellfish that died due to the red tide phenomenon or that are secondarily infected with bacteria, it has caused serious problems such as causing abdominal pain or even death.

On the other hand, as described above, the red tide phenomenon is pointed out as a major cause of the increase in the water temperature of seawater, and thus dissolved oxygen (DO) in the seawater decreases, causing collective death of fish and shellfish.

Publication Patent No. 10-2010-0022879

Therefore, the problem to be solved by the present invention is that it is possible to continuously generate dissolved oxygen water by supplying seawater at a lower temperature than the surface temperature, and by continuously supplying dissolved oxygen water to a plurality of cage cells, It is to provide a cage aquaculture dissolved oxygen supply system that enables continuous supply of oxygen to fish and shellfish and enables the removal of foreign substances attached to the net constituting a plurality of cage cells and sterilization of the net by supplying dissolved oxygen water.

A system for supplying dissolved oxygen in a cage farm according to an embodiment of the present invention comprises: an oxygen dissolved water generating tank installed in at least one oxygen water supply cell selected from a plurality of cage cells; The upper part is exposed to the atmosphere and the lower part extends into the seawater through the oxygen-dissolved water producing tank, and seawater flowing into the water in the oxygen-dissolved water producing tank at one side and flowing through the lower part into the oxygen-dissolved water producing tank Seawater supply pipe having a seawater discharge pipe to be supplied; A microbubble generating device provided in the oxygen-dissolved water producing tank to supply seawater discharged and supplied from the seawater discharge pipe to the oxygen-dissolved water producing tank as dissolved oxygen water; And a pump located outside the oxygen water supply cell and pumping the oxygen dissolved water generated in the oxygen dissolved water generating tank and supplying it into the cage cell around the oxygen water supply cell.

In one embodiment, the seawater supply pipe may be configured by combining a plurality of sub-unit pipes.

In one embodiment, it may further include a filter member accommodated in the oxygen dissolved water generating tank so as to surround the periphery of the seawater discharge pipe.

Using the caged farm dissolved oxygen supply system according to the present invention, it is possible to continuously generate dissolved oxygen water by supplying seawater at a lower temperature than the surface temperature, and by continuously supplying dissolved oxygen water to a plurality of cage cells, There is an advantage in that it is possible to continuously supply oxygen to fish and shellfish cultured in the cell, and to remove foreign substances attached to the net constituting a plurality of cage cells and sterilize the net by supplying dissolved oxygen water.

In addition, there is an advantage in that red tide and green algae generated in the cage farm can be eliminated through the supply of dissolved oxygen water.

1 is a plan view showing the configuration of a dissolved oxygen supply system for a cage farm according to an embodiment of the present invention.
2 is a cross-sectional view showing the configuration of a dissolved oxygen supply system for a cage farm according to an embodiment of the present invention.

Hereinafter, a system for supplying dissolved oxygen at a cage farm according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present invention, various modifications may be made and various forms may be applied, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form disclosed, it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention. In describing each drawing, similar reference numerals have been used for similar elements. In the accompanying drawings, the dimensions of the structures are shown to be enlarged compared to the actual size for clarity of the present invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are used only for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element.

The terms used in the present application are used only to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance the possibility of the presence or addition.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this application. Does not.

1 is a plan view showing the configuration of a dissolved oxygen supply system for a cage farm according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view showing the configuration of a dissolved oxygen supply system for a cage farm according to an embodiment of the present invention.

1 and 2, the system for supplying dissolved oxygen at a cage farm according to an embodiment of the present invention includes an oxygen dissolved water generating tank 110, a seawater supply pipe 120, a microbubble generating device 130, and a pump ( 140).

The dissolved oxygen water generating tank 110 is installed in at least one oxygen water supply cell 20 selected from among a plurality of cage cells 10. The oxygen dissolved water generating tank 110 is formed of a plate material to confine the fluid, and is provided in the form of a closed box except for the upper surface.

The seawater supply pipe 120 is provided in the form of a hollow tube. The seawater supply pipe 120 is exposed to the atmosphere at the upper end of the hollow pipe, and the lower end extends to seawater through the bottom of the oxygen dissolved water generating tank. One side of the seawater supply pipe 120 is provided with a seawater discharge pipe 121a extending into the water in the oxygen dissolved water generating tank 110 and supplying the seawater flowing through the lower end into the dissolved oxygen generating tank 110.

For example, the seawater supply pipe 120 may include a main pipe part 121 and a seawater supply depth control pipe part 122.

The main pipe part 121 is a hollow pipe with an upper end and a lower end open, and may be fixed to the oxygen dissolved water generating tank 110. That is, the upper part is exposed to the atmosphere, and the lower part extends into seawater through the bottom part of the oxygen dissolved water generating tank 110. The seawater discharge pipe () is provided on one side of the main pipe part 121.

The seawater supply depth control piping unit 122 allows the seawater to be supplied at a predetermined depth of seawater. That is, seawater is supplied at a specific depth from the surface. To this end, the seawater supply depth control pipe part 122 may be plural, and each seawater supply depth control pipe part 122 has a different length. As an example, the seawater supply pipe 120 may be selected to supply seawater at a depth of 30m, and in this case, the seawater supply depth control pipe 122 may extend from the lower end of the main pipe 121 to a depth of 30m. Can have any length.

The seawater supply depth control pipe part 122 is inserted into the inside of the main pipe part 121 through the open upper end of the main pipe part 121, and the flange part ( 122a) is provided and a support jaw 121b is provided at the lower end of the main pipe part 121, so that the inserted seawater supply depth control pipe part 122 may be located in the main pipe part 121. Although not shown, a lifting hook is provided at the upper end of the seawater supply depth control pipe part 122, and a separate equipment when inserted or withdrawn into the main pipe part 121 by connecting the lifting wire to the lifting hook, for example, It can be lifted through a crane or the like.

The microbubble generating device 130 may be provided on one side of the oxygen dissolved water generating tank 110. The microbubble generating device 130 supplies seawater discharged from the seawater discharge pipe 121a and supplied into the oxygen dissolved water generating tank 110 as oxygen dissolved water to the oxygen dissolved water generating tank 110. There is no particular limitation on the shape of the microbubble generating device 130, and any structure capable of generating dissolved oxygen water may be used. As an example, the microbubble generating device 130 may include a suction pipe 131 for pumping and inhaling seawater in the oxygen dissolved water generating tank 110 and a discharge pipe 132 for discharging the dissolved oxygen water.

The pump 140 is located outside the oxygen water supply cell 20 and pumps the oxygen dissolved water generated in the oxygen dissolved water generating tank 110 and supplies it into the cage cell 10 around the oxygen water supply cell 20 do. In order to pump dissolved oxygen water and supply it to the cage cell 10, hoses or pipes respectively connected to the dissolved oxygen water generating tank 110 and the cage cell 10 may be connected to the pump 140.

For example, to the pump 140, the oxygen-dissolved water supply for supplying the oxygen-dissolved water to the oxygen-dissolved water inlet pipe 151 and the cage cell 10 which extends to the oxygen water supply cell 20 to suck the dissolved oxygen water The pipe 152 may be connected.

The oxygen dissolved water supply pipe 152 is a mesh-shaped net that is branched from the ends of the main pipe 1521 and the main pipe 1521 extending from the pump 140 to form a rectangular parallelepiped shape of each cage cell 10 ( It may include branch pipes 1522 extending to the bottom portion of 11). The branch pipes 1522 may be provided with a nozzle unit 1522a for discharging the dissolved oxygen water, and the nozzle unit 1522a passes through the bottom surface of the net 11 and faces the inner space of the net 11. Can be extended. The dissolved oxygen water supply pipe 152 may branch to and extend to each cage cell 10.

Meanwhile, the system for supplying dissolved oxygen in a cage farm according to an embodiment of the present invention may further include a filter member 160.

The filter member 160 is accommodated in the oxygen dissolved water generating tank 110 so as to surround the seawater discharge pipe 121a and the microbubble generating device 130. For example, the filter member 160 may be provided in a hexahedral mesh shape and installed to accommodate the seawater discharge pipe 121a in the hexahedral shape. As a result, foreign matter mixed with seawater supplied through the seawater discharge pipe 121a is filtered, and clear seawater without foreign matter may be supplied into the oxygen dissolved water generating tank 110.

Hereinafter, a process of supplying dissolved oxygen water into a plurality of cage cells by using the dissolved oxygen supply system for a cage farm according to an embodiment of the present invention will be described.

First, seawater is introduced through the lower end of the seawater supply pipe 120, and the introduced seawater is supplied into the oxygen dissolved water generating tank 110 through the seawater discharge pipe 121a, so that the seawater in the oxygen dissolved water generating tank 110 Is filled. At this time, foreign matter contained in the seawater discharged into the oxygen dissolved water generating tank 110 through the seawater discharge pipe 121a is filtered through the filter member 160 accommodating the seawater discharge pipe 121a, thereby generating dissolved oxygen water. Clear seawater is supplied to the inside of the water tank 110.

In this process, the microbubble generating device 130 is operated, and the microbubble generating device 130 generates dissolved oxygen water using seawater filled in the oxygen-dissolved water producing tank 110.

As dissolved oxygen water is generated, the pump 140 is driven. The driven pump 140 pumps the oxygen dissolved water in the oxygen dissolved water generating tank 110 and supplies it to the cage cells 10 around the oxygen water supply cell 20 accommodating the oxygen dissolved water generating tank 110 Thus, oxygen is supplied to the plurality of cage cells 10.

At this time, the dissolved oxygen water is introduced through the dissolved oxygen water inlet pipe 151 and then supplied to the dissolved oxygen water supply pipe 152, and through the nozzle portion 1522a of the dissolved oxygen water supply pipe 152, the cage cell ( Dissolved oxygen water is supplied from the bottom of the net 11 of 10). In this way, the oxygen dissolved water is supplied from the bottom of the net 11 of the cage cell 10, so that it can be evenly supplied to the entire space within the cage cell 10.

In the process of pumping dissolved oxygen water and supplying it to a plurality of cage cells 10, the level of seawater filled in the oxygen dissolved water generating tank 110 gradually decreases, and in this process, the seawater supply pipe 120 Is introduced and discharged through the seawater discharge pipe 121a. This continues in the process of lowering the water level of the oxygen dissolved water generating tank 110, and accordingly, a continuous supply of seawater is made inside the oxygen dissolved water generating tank 110.

By using the dissolved oxygen supply system at the cage farm according to an embodiment of the present invention, it is possible to continuously generate dissolved oxygen water by supplying seawater at a low temperature lower than the temperature of the surface, and the dissolved oxygen water is supplied to a plurality of cage cells 10 ), it is possible to continuously supply oxygen to the fish and shellfish farmed in the cage cell 10, and remove foreign substances attached to the net constituting the plurality of cage cells 10 by supplying dissolved oxygen water and the net There is an advantage that it becomes possible to sterilize.

In addition, there is an advantage in that red tide and green algae generated in the cage farm can be eliminated through the supply of dissolved oxygen water.

The description of the presented embodiments is provided to enable any person skilled in the art to use or implement the present invention. Various modifications to these embodiments will be apparent to those of ordinary skill in the art, and the general principles defined herein can be applied to other embodiments without departing from the scope of the present invention. Thus, the present invention is not to be limited to the embodiments presented herein, but is to be construed in the widest scope consistent with the principles and novel features presented herein.

Claims (3)

Dissolved oxygen water generating tank 110 installed in at least one oxygen water supply cell 20 selected from among a plurality of cage cells 10, the upper surface is opened, and configured to confine a fluid therein;
It is installed in the dissolved oxygen water generating tank 110, the upper end is exposed to the atmosphere through the open upper surface of the dissolved oxygen water generating tank 110, and the lower end passes through the bottom of the dissolved oxygen water generating tank 110 A seawater discharge pipe (121a) that extends into seawater and extends into the water in the oxygen-dissolved water-producing tank (110) and flows into the lower portion of the oxygen-dissolved water-producing tank (110) is provided. , A seawater supply pipe 120 for supplying seawater into the oxygen dissolved water generating tank 110;
A filter member 160 that is accommodated in the oxygen dissolved water generating tank 110 so as to surround the seawater discharge pipe 121a to filter foreign substances in the seawater supplied into the oxygen dissolved water generating tank 110;
A microbubble generating device 130 provided in the dissolved oxygen water generating tank 110 and supplying the seawater discharged and supplied from the seawater discharge pipe 121a to the dissolved oxygen producing tank 110 as dissolved oxygen water;
A pump that is located outside the oxygen water supply cell 20 and pumps the oxygen dissolved water generated in the oxygen dissolved water generation tank 110 and supplies it into the cage cell 10 around the oxygen water supply cell 20 (140); And
Dissolved oxygen water supply pipe 152 including a main pipe 1521 extending from the pump 140 and a branch pipe 1522 branching from the main pipe 1521 and extending to the bottom of each cage cell 10 ), and
The seawater supply pipe 120,
It is fixed to the oxygen-dissolved water generating tank 110, the upper end and the lower end are open hollow pipes, the lower end extends into the water of seawater through the bottom of the oxygen-dissolved water generating tank 110, and the seawater discharge pipe ( The main piping unit 121 including 121a); And
Includes a seawater supply depth control pipe portion 122 inserted into the main pipe portion 121 and extending into the water of seawater lower than the position of the lower end portion of the main pipe portion 121,
A support jaw (121b) is provided at a lower end of the main pipe part (121), and a flange part (122a) is provided at an upper end of the seawater supply depth control pipe part (122), and the seawater supply depth control pipe part (122) When inserted into the interior of the main pipe portion 121 through the open upper end of the main pipe portion 121, the seawater supply depth control pipe portion 122 is configured to be located within the main pipe portion 121 Characterized by,
Dissolved oxygen supply system for Gaduri Farm. delete delete

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