KR20220008587A - System for Farming Shellfish - Google Patents

Abstract

The present invention relates to a fish and shellfish farming system in which a swirling flow is generated at an inner lower part of a circular water tank by fed water so that pollutants in the water tank are smoothly guided and discharged to the center of the bottom of the water tank, and thus, the pollutants are automatically discharged to the outside without removing an aquaculture plate, and in which during a farming process, air is supplied from a lower side of the aquaculture plate so as to prevent the death of shellfish (especially Semisulcospira libertina) so that the mass farming of shellfish is possible. The fish and shellfish farming system, according to the present invention, comprises: a cone-shaped water tank having a bottom surface that is concave downward; an aquaculture plate installed to be spaced apart from the bottom surface of the water tank by a certain distance and configured to accommodate shellfish to be cultivated; a support unit configured to support the aquaculture plate so that the aquaculture plate is supported while being spaced apart from the bottom surface of the water tank by the certain distance; a water feeding unit installed at the bottom of the water tank and configured to inject water into the water tank so as to generate a swirling flow in the water of the water tank; an air injection unit installed to be able to rotate with respect to a vertical axis between the bottom surface of the water tank and the support unit and including an air blade with a plurality of air injection holes that blow out air; a rotation unit configured to rotate the air injection unit with respect to the vertical axis; and a discharge unit communicating with the center at the bottom surface of the water tank and configured to discharge water and pollutants to the outside.

Description

Fish and shellfish farming system {System for Farming Shellfish}

The present invention relates to a fish and shellfish culture system, and in particular, after putting a cultured wave plate accommodating fish and shellfish such as mint or abalone, sea cucumber, etc. into a water tank, a swirling flow is generated by water supply from the lower part of the tank, without removing the cultured wave plate It relates to a fish and shellfish culture system that can automatically discharge contaminants from the bottom of a tank to the outside and prevent the death of fish and shellfish by supplying air from the bottom of the culture wave plate during the culture process.

Based on the technology of abalone farming, which is a similar shellfish, from 20 years ago, abalone farming was attempted mainly by regional inland water research institutes using abalone-cultured waves in a land-water-type water tank.

However, the growth rate, size and ecology of abalone is different from that of abalone, and cage culture is not possible due to the possibility of loss in rivers.

As a result, there was a problem that continued to occur in onshore tank culture. In the case of shellfish that are generally cultured in tanks, for example, scallops or young abalone, a large number of cultured slabs were installed inside the tank to secure a large area for attachment. Install and fill out the form. Adhesive diatoms are cultivated on these aquaculture plates and used as food for the snails, but the cultured adherent diatoms are all consumed as food within one month and no longer supply food.

To compensate for this, feed has to be supplied, but because the aquaculture plate is a vertically erected plate and the surface is smooth, all the supplied feed falls to the bottom of the tank. The contamination of the bottom of the tank becomes very serious.

Therefore, it should be cleaned frequently to keep the water quality clean, but it is very difficult to clean under the condition that aquaculture waveboards, which are generally used for food culture and mass production, are installed inside the aquaculture tank.

In general, the aquaculture tank used for cultivating various fish in onshore farms is widely applied to a circular tank with a pipe-type water level control mechanism installed in the inner center of the tank body. For this reason, we prefer a narrow channel type tank that is easier to manage than a round tank.

However, suction vacuum cleaners cannot be used because they are brittle, and they use a method of cleaning at the flow rate after levitating pollutants with the inclination of the tank or air bubbles, but the effect of removing pollutants over time is insufficient, so they are reluctant to supply feed and eventually die of starvation or polluted aquaculture water to lose or to lose.

In such a situation, it is known only as a problem with feed, and feeds for scallops are being developed. However, as aquaculture fishermen saw an increase in mortality due to the rotting feed falling to the bottom of the tank, they could not continue to be used and feed that had not been used properly disappeared.

Registered Patent No. 10-2068772 (Registered on January 15, 2020) Registered Patent No. 10-1293737 (Registered on July 31, 2013) Patent Publication No. 10-2015-0004968 (published on January 14, 2015)

The present invention is to solve the above problems, and an object of the present invention is to generate a swirling flow by supplying water from the lower part of the inside of a large circular water tank to smoothly induce and discharge pollutants in the water tank to the center of the bottom. Contaminants can be automatically discharged to the outside without removing the aquaculture plate, and air is supplied from the bottom of the culture plate during the culture process to prevent the death of fish and shellfish (for example, scallops, abalone, sea cucumber, etc.) It relates to a fish and shellfish culture system capable of mass culture of shellfish.

A fish and shellfish culture system according to the present invention for achieving the above object, the bottom surface is made of a concave concave to the bottom; a culture wave plate installed to be spaced apart from the bottom surface of the water tank by a certain distance and accommodated shellfish to be cultured; a support unit for supporting the cultured wave plate to be spaced apart from the bottom surface of the water tank by a predetermined distance; a water supply unit installed in the lower part of the water tank to generate a swirling flow in the water in the water tank by spraying water into the water tank; an air jet unit having an air blade rotatably installed about a vertical axis between the bottom surface of the water tank and the support unit, and having a plurality of air jet ports for jetting air; a rotation unit for rotating the air injection unit about a vertical axis; and a discharge unit communicating with the center of the bottom surface of the water tank to discharge water and pollutants to the outside.

The water supply unit may include: a first water supply unit installed to extend along an edge of the lower portion of the water tank and spraying water into the water tank to generate a swirling flow at the lower periphery of the water tank; and a second water supply unit installed between the first water supply unit and the center of the bottom surface of the water tank in the circumferential direction to generate a swirling flow in the radial middle of the water tank by spraying water into the water tank.

The first water supply unit is formed in a ring shape extending along the edge of the bottom surface of the water tank and is connected to an external water supply pipe to receive a first water supply header, and a predetermined interval along the circumferential direction to the first water supply header and a first water supply nozzle that is arranged in a direction and installed inclined at a certain angle with respect to the circumferential direction to spray water in the first water supply header into the water tank,

The second water supply unit has a ring shape having a smaller radius than the first water supply header, is installed on the bottom surface of the water tank, is connected to an external water supply pipe to receive water, and the second water supply header; It may include a second water supply nozzle arranged at regular intervals along the circumferential direction and inclined at a predetermined angle with respect to the circumferential direction to spray water in the second water supply header into the water tank.

The support unit may include a plurality of lattice frames installed to cross the lower part of the water tank in a lattice form, and a mesh installed at the upper end of the lattice frame.

The discharge unit includes a discharge pipe having one end connected to the center of the bottom surface of the water tank to discharge water and pollutants to the outside, and the other end connected to the other end of the discharge pipe to receive water and pollutants discharged from the discharge pipe. a water level control pipe installed to extend upward through the bottom surface of the auxiliary tank to discharge water and contaminants filled above a certain water level in the auxiliary tank to the outside; and from the outside of the auxiliary tank It may include a drain tank connected to the lower end of the water level control pipe for storing water and contaminants discharged through the upper end of the water level control pipe.

The air jet unit is installed on the upper side of the center of the bottom surface of the water tank, an inlet port is installed on one side, and an outlet port communicating with the inlet port on the upper surface is a mount member formed to open upward, and one end of the water tank is outside. A supply pipe connected to an air supply device installed in the air supply and the other end is connected to the inlet port to supply air into the mount member, rotatably installed about an axis perpendicular to the outlet port of the mount member and by the rotation unit It may include a hub having an air supply passage communicating with the outlet port while rotating, and a blade coupler installed on an outer surface of the hub in communication with the air supply passage and to which the air blade is connected.

The rotation unit may include a motor installed outside the upper end of the water tank, and a power transmission pin connected to the shaft of the motor to receive power from the motor to rotate, and the lower end to be coupled to the center of the upper surface of the hub. .

Alternatively, the rotation unit may include a plurality of rotary blades arranged on the outer surface of the hub in a circumferential direction, a pressure nozzle installed outside the hub to spray high-pressure water toward the rotary blade, and a high pressure to the pressure nozzle It may include a pump for supplying water to. Here, the pump may be a small submersible pump.

The air blade may include a porous blade made of a porous material in which a plurality of air nozzles in the form of micropores are formed, and a blade socket connected to an inner end of the porous blade and connected to a portion for supplying air.

According to the present invention, water is sprayed by the first water supply unit and the second water supply unit at the edge and the middle portion of the bottom surface of the water tank to generate a swirling flow, and pollutants accumulated in the lower part of the water tank by the swirling flow It is guided toward the outlet of the center of the water tank and can be automatically discharged to the outside, so that the water quality of the water tank can always be maintained in a clean state.

Therefore, since a sufficient amount of feed can be continuously given, it is advantageous for the growth of fish and shellfish such as scallops and has an advantageous effect on mass production.

In addition, as the air blade of the air jet unit rotates continuously at a constant speed, air can be continuously supplied to the culture wave plate over the entire area of the water tank. Therefore, it is possible to continuously supply a large amount of air to the fish and shellfish gathered in the net and the cultured wave plate, so it is advantageous for the growth of scallops and has the effect of preventing mass death.

1 is a perspective view showing the removal of some components of the fish and shellfish culture system according to an embodiment of the present invention.
2 is a plan view of a fish and shellfish culture system according to an embodiment of the present invention.
3 is a cross-sectional view of a fish and shellfish culture system according to an embodiment of the present invention.
4 is a plan view showing a portion of the water supply unit of the fish and shellfish culture system according to an embodiment of the present invention.
5 is a perspective view of a main part of a support unit of a fish and shellfish culture system according to an embodiment of the present invention.
Figure 6 is a plan view showing an embodiment of the air injection unit of the fish and shellfish culture system according to the present invention.
7 is a cross-sectional view of the air injection unit shown in FIG.
8 is a perspective view of an air blade constituting the air injection unit shown in FIG. 6 .
9 is a perspective view of a main part showing another embodiment of the fish and shellfish culture system according to the present invention.
10 is a cross-sectional view of the main part of the fish and shellfish culture system shown in FIG.

The configuration shown in the embodiments and drawings described in this specification is only a preferred example of the disclosed invention, and there may be various modifications that can replace the embodiments and drawings of the present specification at the time of filing of the present application.

Hereinafter, the fish and shellfish culture system will be described in detail according to the embodiments described below with reference to the accompanying drawings. In the drawings, like reference numerals denote like elements.

1 to 8 are views showing an embodiment of a culture system for cultivating mussels as shellfish. The fish and shellfish culture system of this embodiment is installed to be spaced apart from the tank 10 and the bottom surface of the tank 10 by a certain distance. A plurality of cultured wave plates 30, a support unit for supporting the cultured wave plates 30 to be spaced apart from the bottom surface of the water tank 10 by a certain distance, are installed to extend along the lower edge of the water tank 10 and are installed in the water tank (10) The first water supply unit that sprays water inward to generate a swirling flow at the lower periphery of the water tank 10, and is installed in a ring shape between the first water supply unit and the center of the bottom surface of the water tank 10 to the inside of the water tank 10 A second water supply unit that sprays water to generate a swirling flow in the radial middle part of the water tank 10, an air spray unit that is installed rotatably around a vertical axis on the bottom surface of the water tank 10 to spray air; It includes a rotation unit that rotates the air injection unit about a vertical axis, and a discharge unit that communicates with the center of the bottom surface of the water tank to discharge water and pollutants to the outside.

The water tank 10 is a circular water tank with an open upper surface, and the bottom surface 11 of the water tank 10 is concave downwardly. In the center of the bottom surface 11 of the water tank 10, a discharge port 12 communicating with the discharge unit is formed to penetrate downward. Accordingly, the pollutants guided to the center of the bottom surface 11 of the water tank 10 are discharged to the discharge unit through the discharge port 12 together with water.

The cultured wave plate 30 is a plurality of flat plates installed vertically for growing scallops, and the 'fish and shellfish growth plate' disclosed in Patent Registration No. 10-1635712 developed by the present applicant can be applied. The culture wave plate 30 is installed to be submerged in the water in the water tank 10 in a state spaced apart from the bottom surface 11 of the water tank 10 by a predetermined distance by the support unit.

As described above, the support unit is for installing a plurality of cultured wave plates 30 spaced apart from the bottom surface 11 of the water tank 10 by a predetermined distance, so as to cross the lower portion of the water tank 10 in a grid form. A plurality of lattice frames 21 are installed, and a mesh 22 installed at the upper end of the lattice frame 21 is included. The grid frame 21 has a rectangular bar shape in which a plurality of connecting slits 21a are formed at regular intervals along the longitudinal direction at the upper end and the lower end, and the connecting slits 21a of any one grid frame 21 intersecting at right angles to each other. ) while inserting into the connection slit 21a of the other grid frame 21, the plurality of grid frames 21 can be connected to cross at right angles.

When it is difficult to support the load of the culture wave plate 30 with only the plurality of grid frames 21, a plurality of high-strength support bars 23 are installed to cross the lower part of the water tank 10, and a plurality of support bars ( 23) By seating the grid frame 21 on top, it is possible to firmly support the culture wave plate 30 .

The net 22 is installed on the grid frame 21 to support the cultured wave plate 30, and the scallops accommodated in the cultured wave plate 30 fall downward through the opening of the grid frame 21 to the water tank ( 10) to prevent sinking to the bottom surface. To this end, the net 22 may be configured as a net having a hole smaller than the size of the dasseulgi.

The first water supply unit and the second water supply unit are installed radially inside the water tank 10 so that the pollutants deposited on the bottom surface 11 of the water tank 10 can be smoothly discharged through the outlet 12 at the center. The water is sprayed with a vortex to create a swirling flow at the same time as the water supply. At this time, it is preferable that the first water supply unit and the second water supply unit spray water at a slightly oblique angle with respect to the radial direction so that the swirling flow can be generated more smoothly.

In this embodiment, the first water supply unit is formed in a circular ring shape extending along the edge of the bottom surface 11 of the water tank 10 and is connected to an external water supply device and a water supply pipe 43 through a water supply pipe 43 to receive water. The first water supply header 41 and the first water supply header 41 are arranged at regular intervals along the circumferential direction and inclined at a constant angle with respect to the circumferential direction to collect the water in the first water supply header 41 into the water tank (10). ) includes a plurality of first water supply nozzles 42 for spraying into the.

The second water supply unit is in the form of a circular ring having a smaller radius than the first water supply header 41, is installed on the bottom surface of the water tank 10, and is connected to an external water supply device and a water supply pipe 53 via a water supply pipe 53, The second water supply header 51 receiving water, and the second water supply header 51 are arranged at regular intervals along the circumferential direction and inclined at a constant angle with respect to the circumferential direction, so that water in the second water supply header 51 is installed. It includes a second water supply nozzle 52 for spraying into the water tank (10).

In this way, the first water supply nozzle 42 and the second water supply nozzle 52 spray water obliquely at a certain angle with respect to the radial direction, thereby generating a swirling flow in the outer and middle portions on the bottom surface 11 of the water tank 10 . generate In this way, when the first water supply unit and the second water supply unit are disposed on the periphery and the middle portion respectively on the bottom surface 11 of the water tank 10 and spray water, even if the diameter of the water tank 10 is enlarged to 3m or more Since it is possible to smoothly generate a swirling flow on the bottom surface 11 of the water tank 10 to induce contaminants to the center over the entire bottom surface 11, it provides a more advantageous advantage for mass production.

As described above, the lower end of the cultured wave board 30 is placed on and supported on the mesh 22 , and a large number of scallions are gathered in the mesh 22 . Accordingly, by spraying air from the lower side of the mesh 22 to the upper side using the air jet unit, oxygen can be supplied to the dasseulgi to prevent death.

The air injection unit is a plurality of air blades 65 rotate about a vertical axis so as to supply air to the entire cultured wave plate 30 placed on the grid frame 21 and the mesh 22 to spray air upwards. is composed 6 to 8, the air injection unit is installed on the upper side of the center of the bottom surface 11 of the water tank 10, the inlet port 61a is installed on one side, and the inlet port (61a) is installed on the upper surface ( The mounting member 61 formed so that the outlet port 61b communicating with the 61a) is opened upward, one end is connected to an air supply device (not shown) installed outside the water tank 10, and the other end is the inlet port ( The air supply pipe 67 connected to 61a) for supplying air into the mount member 61, is rotatably installed about an axis perpendicular to the outlet port 61b of the mount member 61, and rotates by the rotation unit A hub 62 having an air supply passage 62a communicating with the outlet port 61b is formed, and the air blade 65 is installed on the outer surface of the hub 62 in communication with the air supply passage 62a. It may include a blade coupler 63 to be connected.

The mount member 61 is fixedly installed at a predetermined interval on the upper side of the outlet 12 , and a plurality of openings 61c are formed so that water and contaminants can be smoothly discharged through the outlet 12 . has been The inlet port 61a of the mount member 61 is watertightly connected to the air supply pipe 67 that is connected to an air supply device (not shown) such as an air compressor through the bottom surface 11 of the water tank 10 to supply air. are supplied

The hub 62 is rotatably installed about an axis perpendicular to the outlet port 61b of the mount member 61 . At the center of the hub 62, an air supply passage 62a communicating with the outlet port 61b is formed to open downward, and on the outer surface of the hub 62, a plurality of blade couplers 63 communicating with the air supply passage 62a. ) is formed to extend outward. The blade coupler 63 is formed in the form of a hollow circular rod, and a vent hole 63a for spraying air to the outside is formed at the outer end of the blade coupler to pass through. In the center of the upper surface of the hub 62, a pin coupling boss 64 for connection with the rotation unit is formed to extend upward.

The air blade 65 is in the form of a hollow circular rod, and one end is fitted and coupled to the blade coupler 63 . Accordingly, the air introduced through the air supply passage 62a of the hub 62 flows into the air blade 65 through the vent hole 63a of the blade coupler 63 and then in the air blade 65 along the longitudinal direction. It is sprayed to the outside through the formed plurality of air injection holes (66).

The air nozzles 66 of the air blade 65 may be arranged at regular intervals along the longitudinal direction at the upper end of the air blade 65 . Alternatively, the air blade 65 itself is made of a porous material in which innumerable fine pore-shaped air injection holes 66 are formed to eject a large amount of air bubbles, or as shown in FIG. 8, micro-pore-shaped air injection holes 66 It may be made of a composite structure including a porous blade 65a made of a porous material on which is formed, and a blade socket 65b in the form of a pipe made of a hard resin or metal material such as PVC. The blade socket 65b is connected to the inner end of the porous blade 65a and is inserted into and coupled to the blade coupler 63 of the hub 62 for supplying air. As shown in the figure, a plurality of air injection holes 66 may be formed in the blade socket 65b, but differently, the air injection holes 66 are provided in the blade socket 65b so that all air can be ejected through the porous blade 65a. 66) may not be formed.

The rotation unit for rotating the hub 62 and the air blade 65 of the air injection unit includes a motor 71 installed outside the upper end of the water tank 10, and the motor 71 connected to the shaft of the motor ( It rotates by receiving power from the hub 62 and includes a power transmission pin 72 coupled to a pin coupling boss 64 formed in the center of the upper surface of the hub 62 .

Therefore, when power is applied to the motor 71 and rotates in one direction, rotational force is transmitted to the hub 62 through the power transmission pin 72 , so that the hub 62 and the air blade 65 rotate about a vertical axis. It rotates in the water tank (10). At this time, when air is supplied to the air blade 65, the air is ejected through the air blade 65, and the ejected air is supplied to the mesh 22 and the culture wave plate 30 of the support unit immediately above the upper side and is continuously supplied to the shredder. can supply a large amount of air.

The rotation unit of this embodiment is configured to rotate the air blade 65 using the power of the motor 71, but as shown in FIGS. 9 and 10 in another embodiment, the air blade 65 using the jet force of water ) can also be rotated. In the rotation unit of this embodiment, a plurality of rotation blades 75 are arranged along the circumferential direction on the outer surface of the hub 62 to which the air blade 65 is connected, and the rotation blades 75 are arranged on the outside of the hub 62. A pressure nozzle 76 for spraying high-pressure water toward and a submersible pump 77 for pumping water to the pressure nozzle 76 are installed, and the water sprayed at high pressure through the pressure nozzle 76 is supplied to the rotary blade 75 ) may rotate the hub 62 and the air blade 65 by applying pressure in the circumferential direction.

Of course, as in this embodiment, water can be supplied to the pressure nozzle 76 by installing the submersible pump 77 inside the water tank 10, but differently, the pump is installed outside the water tank 10, and the pump and the pressure nozzle ( 76) may be connected to a pipe or a hose to supply water at high pressure to the pressure nozzle 76.

1 and 3, the configuration of the discharge unit for discharging water and contaminants from the water tank 10 is shown, and the discharge unit has one end connected to the center of the bottom surface of the water tank 10, A discharge pipe 91 for discharging pollutants to the outside, an auxiliary tank 92 connected to the other end of the discharge pipe 91 for accommodating water and pollutants discharged from the discharge pipe 91, and an auxiliary tank A water level control pipe 93 that is installed to extend upward through the bottom surface of the auxiliary tank 92 and discharges water and contaminants that are filled above a certain level in the auxiliary tank 92 to the outside, and the auxiliary tank 92 It may include a drain tank 95 connected to the lower end of the water level adjusting pipe 93 from the outside to store water and pollutants discharged through the upper end of the water level adjusting pipe 93 . A drain pipe 96 is connected to the upper portion of the drain tank 95 to discharge the water collected in the drain tank 95 to a designated place outside.

The fish and shellfish culture system of the present invention operates as follows.

A plurality of cultured scallops 30 in which the shellfish to be cultured (in this embodiment) are accommodated are put into the water tank 10 filled with water at a predetermined water level and placed on the net 22.

Then, by operating the water supply device to supply water to the first water supply header 41 and the second water supply header 51, the first water supply nozzle 42 of the first water supply header 41 and the second water supply header 51 When water is sprayed into the water tank through the second water supply nozzle 52, a swirling flow is generated in the space between the bottom surface of the water tank 10 and the grid frame 21 supporting the culture wave plate 30, which is accumulated on the floor. Contaminants are guided to the center of the bottom surface 11 of the water tank 10 together with the water.

Water and pollutants guided to the bottom surface of the water tank 10 are discharged to the discharge pipe 91 of the discharge unit through the discharge port 12, and then introduced into the external auxiliary tank 92, and then the auxiliary tank 92 ) when the water level reaches the upper end of the water level control pipe (93), it flows into the water level control pipe (93), is discharged to the drain tank (95), and then is discharged to the outside by the drain pipe (96).

As such, the contaminants accumulated in the lower part of the water tank 10 can be automatically discharged to the outside, so that the water quality of the water tank 10 can always be maintained in a clean state. In addition, the water level in the water tank 10 may be constantly maintained by the water level control pipe 93 of the auxiliary tank 92 .

As described above, during the generation of swirl flow through water supply and automatic discharge of pollutants, the hub 62 and the air blade 65 of the air injection unit continuously rotate at a constant speed by the rotation unit while the air blade ( 65) blows the air through. The blown out air is supplied to the cloves gathered in the upper net 22 and the cultured wave plate 30 to help the growth of the cloves, and to prevent death.

As described above, according to the present invention, water is sprayed by the first water supply unit and the second water supply unit at the edge and the middle portion of the bottom surface 11 of the water tank 10 to generate a swirling flow. Contaminants accumulated in the lower part of the water tank by the flow are guided toward the outlet 12 of the center of the water tank 10 and automatically discharged to the outside, so that the water quality of the water tank can always be maintained in a clean state. Therefore, even if the feed is continuously given, the remaining feed can be directly discharged to the outside without decaying in the water tank 10, and it is advantageous for the growth of the sageum, and an advantage for mass production can be obtained.

In addition, while the air blade of the air injection unit continuously rotates at a constant speed, it is possible to continuously supply air to the culture wave plate 30 over the entire area of the water tank 10 . Therefore, a large amount of air is supplied to the cloves gathered in the net and the cultured wave board, so it is advantageous for the growth of the cloves and prevents mass death.

On the other hand, although the above-described embodiment exemplifies culturing of scallops as shellfish in a land tank, it goes without saying that the present invention can be equally or similarly applied to culturing fish and shellfish such as abalone or sea cucumber.

Although preferred embodiments of the present invention have been described above, various changes, modifications and equivalents may be used in the present invention. It is clear that the present invention can be equally applied by appropriately modifying the above embodiments. Accordingly, the above description is not intended to limit the scope of the present invention, which is defined by the limits of the following claims.

10: water tank 11: bottom surface
12: outlet 21: grid frame
22: mesh 23: support bar
30: aquaculture plate 41: first water header
42: first water supply nozzle 51: second water supply header
52: second water supply nozzle 61: mount member
61a: inlet port 61b: outlet port
62: hub 62a: air supply flow path
63: blade coupler 64: pin coupling boss
65: air blade 65a: porous blade
65b: blade socket 66: air nozzle
67: supply pipe 71: motor
72: power transmission pin 75: rotary blade
76: pressure nozzle 77: submersible pump
91: discharge pipe 92: auxiliary tank
93: water level control pipe 95: drain tank
96: drain pipe

Claims (9)

a water tank having a bottom concave concave;
a culture wave plate installed to be spaced apart from the bottom surface of the water tank by a certain distance and accommodated shellfish to be cultured;
a support unit for supporting the cultured wave plate to be spaced apart from the bottom surface of the water tank by a predetermined distance;
a water supply unit installed in the lower part of the water tank to generate a swirling flow in the water in the water tank by spraying water into the water tank;
an air jet unit having an air blade that is rotatably installed about a vertical axis between the bottom surface of the water tank and the support unit, and has a plurality of air jet ports for jetting air;
a rotation unit rotating the air injection unit about a vertical axis; and,
a discharge unit communicating with the center of the bottom surface of the water tank to discharge water and pollutants to the outside;
A fish and shellfish farming system comprising a. According to claim 1, wherein the water supply unit,
a first water supply unit installed to extend along the edge of the lower portion of the water tank and spraying water into the water tank to generate a swirling flow at the lower periphery of the water tank;
a second water supply unit installed in the circumferential direction between the first water supply unit and the center of the bottom surface of the water tank to spray water into the water tank to generate a swirling flow in the radial middle part of the water tank;
A fish and shellfish farming system comprising a. According to claim 2, wherein the first water supply unit is made of a ring shape extending along the edge of the bottom surface of the water tank and is connected to an external water supply pipe to receive water supplied to the first water supply header; It includes a first water supply nozzle arranged at regular intervals along the circumferential direction and installed inclined at a constant angle with respect to the circumferential direction to spray water in the first water supply header into the water tank,
The second water supply unit has a ring shape having a smaller radius than the first water supply header, is installed on the bottom surface of the water tank, is connected to an external water supply pipe to receive water, and the second water supply header; A fish and shellfish culture system comprising a second water supply nozzle arranged at regular intervals along the circumferential direction and installed inclined at a certain angle with respect to the circumferential direction to spray the water in the second water supply header into the water tank. According to claim 1, wherein the support unit is a fish and shellfish culture system comprising a plurality of lattice frames installed to cross the lower part of the tank in a lattice form, and a mesh installed at the upper end of the lattice frame. According to claim 1, wherein the discharge unit, one end of the discharge pipe is connected to the center of the bottom surface of the water tank to discharge water and pollutants to the outside, the other end of the discharge pipe is connected to the discharge pipe An auxiliary tank for accommodating water and pollutants, and a water level control pipe installed to extend upward through the bottom surface of the auxiliary tank to discharge water and pollutants filled above a certain water level in the auxiliary tank to the outside; A fish and shellfish culture system including a drain tank that is connected to the lower end of the water level control pipe from the outside of the auxiliary tank and stores water and contaminants discharged through the upper end of the water level control pipe. The mounting member according to claim 1, wherein the air jet unit is installed above the center of the bottom surface of the water tank, an inlet port is installed on one side, and an outlet port communicating with the inlet port is formed on the upper surface to open upward. , A supply pipe having one end connected to an air supply device installed outside the water tank and the other end connected to the inlet port to supply air into the mount member, rotatably installed around an axis perpendicular to the outlet port of the mount member A fish and shellfish culture system comprising: a hub rotating by the rotating unit and having an air supply passage communicating with the outlet port formed therein; and a blade coupler installed in communication with the air supply passage on the outer surface of the hub and connected to the air blade. The power transmission of claim 6 , wherein the rotation unit includes a motor installed outside the upper end of the water tank, connected to the shaft of the motor, receiving power from the motor to rotate, and the lower end being coupled to the center of the upper surface of the hub. A fish and shellfish farming system including fins. 7. The method of claim 6, wherein the rotation unit comprises: a plurality of rotary blades arranged along the circumferential direction on the outer surface of the hub; A fish and shellfish culture system comprising a pump for supplying water at high pressure to the pressure nozzle. The blade socket according to claim 1, wherein the air blade is connected to a porous blade made of a porous material in which a plurality of air nozzles in the form of micropores are formed, and the inner end of the porous blade is connected to a portion for supplying air. A fish and shellfish farming system comprising a.

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