KR102366732B1 - high temperature and red tide prevention system for fish farm - Google Patents

Abstract

An object of the present invention is to provide a high temperature and red tide disaster prevention system for a farm that can provide optimal conditions for cultivating fish by actively coping with external water quality changes by controlling the temperature and water quality of the water delivered to the tank.
In order to achieve the above object, the fish farm high temperature and red tide disaster prevention system of the present invention is a system for managing water in a farm, a tank in which fish and water are accommodated, receives external water, supplies water to the tank, and air bubbles A water supply unit provided with a tank bubble generator for generating An air supply unit and the water tank, the tank bubbler, the water supply unit, the water supply pipe, the cooling unit, the air supply pipe, and the air supply unit supplying cooled air to the tank bubbler through an air supply pipe connected to Controls the operation of the, characterized in that it comprises a control unit capable of communicating with the outside.

Description

Aquaculture high temperature and red tide prevention system {high temperature and red tide prevention system for fish farm}

The present invention relates to a high temperature and red tide disaster prevention system for a farm, and more particularly, to a high temperature and red tide disaster prevention system for a farm that can control and control the temperature and water quality of water flowing into the farm.

Aquaculture farms are places where seaweed and seafood are grown, and can be divided into cage farms, which are farmed using cages in the sea or river, and tank-type farms, where seawater or freshwater is supplied to a tank installed on land.

The most important factors in farm management are red tides (or green algae), high temperature and deterioration of water quality due to organic pollutants. Red tides may occur due to natural purification suppression due to indiscriminate reclamation projects, water temperature rise due to abnormal weather conditions, and water stagnation due to a decrease in wind. .

Therefore, in the prior art, techniques for blocking the inflow of red tides and floating matter into the farm are used, and the examples are as follows.

Referring to Republic of Korea Patent Registration No. 10-1657290, as shown in FIG. 1 , the conventional apparatus for preventing pollution in aquaculture farms includes a pollution prevention means 10a and an air bubble supply means 20 . The pollution prevention means (10a) is installed to prevent contamination by inflow of red tides and floating matter into the aquaculture farm (1), and the air bubble supply means (20) is an aquaculture farm ( 1) It is characterized in that it is installed to float the contaminants (floating matter and suspended organisms) introduced into the sea level (S).

However, in the conventional fish farm pollution prevention device, purification occurs after external water containing red tides and floating matter is introduced into the tank in which the fish and shellfish are accommodated. There was a problem that the habitat environment of fish and shellfish affected by the water temperature could not be controlled because the configuration was not formed to maintain the temperature or to cool it to a low temperature.

Republic of Korea Patent Registration No. 10-1657290 (Registration Date 2016.09.07.)

The present invention has been devised to solve the above problems, and by maintaining and controlling the temperature and water quality of the water delivered to the tank, it actively copes with changes in external water quality and provides optimal conditions for cultivating fish. An object of the present invention is to provide a high temperature and red tide disaster prevention system.

The fish farm high temperature and red tide disaster prevention system of the present invention, in a system for managing water in a farm, receives fish and water from a tank, receives external water, supplies water to the tank, and generates air bubbles. A water supply unit provided with a generator, a cooling unit formed in a water supply pipe that delivers the water of the water supply unit to the water tank to cool the water in the water supply pipe, generates cooled air, and an air supply pipe connected to the water supply unit Control the operation of the air supply unit and the water tank, the tank bubbler, the water supply unit, the water supply pipe, the cooling unit, the air supply pipe, and the air supply unit for supplying cooled air to the tank bubbler through , it may be characterized in that it comprises a control unit capable of communicating with the outside.

Furthermore, the water tank may be formed inside the water tank, and may further include a water tank bubble generator controlled by the control unit.

Furthermore, the water tank bubble generator may be characterized in that it receives the cooling air generated from the air supply unit to generate bubbles.

Furthermore, the water supply unit includes a water storage tank in which the tank bubbler is installed, storing water received through a pump, an inlet valve formed between the water storage tank and the pump, the water storage tank and the water It may be characterized in that it comprises an outlet valve formed between the supply pipe, a water temperature sensor for measuring the temperature of the water in the water storage tank, and a red tide sensor for measuring the amount of water in the water storage tank.

Furthermore, the red tide sensor may be formed between the inlet valve and the water storage tank and between the water storage tank and the outlet valve, respectively.

Furthermore, the water supply pipe may be characterized in that it further comprises a filter for disturbing the air bubbles.

Furthermore, the water supply pipe is characterized in that it further comprises a vortex generating pin that protrudes toward the inside of the water supply pipe to generate a vortex in the water inside the water supply pipe.

Furthermore, the cooling unit may be formed by bypassing the water supply pipe, and may be characterized in that the water is cooled by blowing air into the water transferred from the water supply unit to the water tank.

Furthermore, the cooling unit may include a fan that delivers external air into the water supply pipe through rotation of the blade.

Furthermore, the fan may receive the cooled air generated by the air supply unit and deliver the cooled air to the inside of the water supply pipe.

Furthermore, the air supply unit may include an air storage tank for storing air and a heat exchanger for cooling the air transferred from the air storage tank.

Furthermore, the heat exchanger may include a refrigerant pipe through which a refrigerant object flows and a freezing chamber in which the inside is maintained at a constant temperature by the refrigerant pipe and the air transferred from the air storage tank is cooled.

Furthermore, the heat exchanger is characterized in that it further comprises an air pipe through which the air transferred from the air storage tank to the freezing chamber flows therein, and spaced apart from the refrigerant pipe by a certain distance, in which indirect cooling occurs by the refrigerant pipe. can

Furthermore, the air tube may further include a plurality of cooling fins protruding from the inner circumferential surface of the air tube toward the center of the air tube and formed at a predetermined angle to each other.

Furthermore, the fish farm high temperature and red tide disaster prevention system of the present invention detects the temperature and red tide amount of the external water delivered to the water supply unit, generates an environmental signal, and transmits the environmental signal to the control unit. It may be characterized in that it comprises.

Furthermore, the external environment sensing unit includes an external temperature sensor for measuring the temperature of external water delivered to the water supply unit, an external red tide sensor for measuring the red tide of external water transferred to the water supply unit, the external temperature sensor and the It may be characterized in that it comprises a signal generator for generating the environmental signal according to the measurement value measured by the external red light sensor, and an external communication unit for transmitting the environmental signal to the control unit.

Furthermore, the fish farm high temperature and red tide disaster prevention system of the present invention is capable of communicating with the control unit, monitoring the state of the control unit, and further comprising an external communication terminal capable of controlling the operation of the control unit can be characterized as

Furthermore, the high temperature and red tide disaster prevention system for aquaculture farms of the present invention may further include a microorganism supply unit connected to the water supply pipe to supply microorganisms to the water tank.

The fish farm high temperature and red tide disaster prevention system of the present invention can maintain the temperature of the water delivered to the water tank at a constant temperature or cool it to a low temperature, and the water containing suspended matter can be purified by the tank bubble generator, so that the water supply unit, cooling It is possible to deliver purified low-temperature water to the water tank through the part and the air supply unit, thereby providing optimal conditions for cultivating fish.

In addition, when delivering purified water from a single water supply unit to a plurality of water tanks, it can be delivered while maintaining a low temperature through the cooling unit, thereby minimizing the distance limitation between the water supply unit and the water tank, and using a single water supply unit It is possible to supply purified, low-temperature water to the dog's tank, which has the effect of saving the operating cost of the farm.

1 is a cross-sectional view of a conventional aquaculture farm pollution prevention device;
2 is a configuration diagram of a high temperature and red tide disaster prevention system in a farm according to an embodiment of the present invention;
3 is a block diagram of the air supply pipe of the present invention;
4 is a block diagram of a cooling unit of the present invention;
5 is a cross-sectional view of a heat exchanger of the present invention;
6 is a cross-sectional view of the air pipe of the present invention
7 is a connection diagram of a control unit of the present invention;
8 is a configuration diagram of a high temperature and red tide disaster prevention system for a farm according to another embodiment of the present invention;

Hereinafter, the technical idea of the present invention will be described in more detail with reference to the accompanying drawings. Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to conventional or dictionary meanings, and the inventor should properly understand the concept of the term in order to best describe his invention. Based on the principle that it can be defined, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention and do not represent all the technical spirit of the present invention, so at the time of the present application, various It should be understood that there may be variations.

Hereinafter, the technical idea of the present invention will be described in more detail with reference to the accompanying drawings. Since the accompanying drawings are merely examples shown in order to explain the technical idea of the present invention in more detail, the technical idea of the present invention is not limited to the form of the accompanying drawings.

2, the high temperature and red tide disaster prevention system 10 of the aquaculture farm of the present invention is a system for managing water in a farm, a water tank 100 in which fish and water are accommodated, and receives external water, the water tank ( A water supply unit 200 in which a tank bubble generator 210 for supplying water to 100) and generating bubbles is formed, and a water supply pipe 300 for delivering water from the water supply unit 200 to the water tank 100. Formed, the cooling unit 400 for cooling the water in the water supply pipe 300, and generates the cooled air, and through the air supply pipe 600 connected to the water supply unit 200, the tank bubbler 210 ) for supplying cooled air to the air supply unit 500 and the water tank 100, the tank bubble generator 210, the water supply unit 200, the water supply pipe 300, the cooling unit 400, It controls the operation of the air supply pipe 600 and the air supply unit 500, characterized in that it comprises a control unit 800 capable of communicating with the outside.

The water tank 100 is a space for cultivating fish, and it is preferable that an outlet through which the water introduced into the water tank 100 can be discharged is formed, and the shape of the tank 100 generally used for fish culture can be applied.

The tank bubble generator 210 is a device for generating bubbles using the cooled air received from the air inlet, and it is preferable that the water supply unit 200 generates microbubbles in the water received from the outside. . The tank bubble generator 210 may generate microbubbles in the water delivered to the water supply unit 200 in a state in which the suspended matter is contained, and float the suspended matter to the surface of the water to remove it.

The cooling unit 400 is formed in the water supply pipe 300 through which the water of the water supply pipe 300 is transferred to the water tank 100 , and the water transferred from the water supply unit 200 to the water tank 100 . In the configuration of cooling the water, as the movement path of the water delivered from the water supply unit 200 becomes longer due to the distance between the water supply unit 200 and the water tank 100, the temperature of the water delivered from the water supply unit 200 increases. It is possible to maintain the water temperature by preventing it from happening, and there is an effect that can additionally cool the water flowing through the water supply pipe 300 .

When water is transferred from the water supply pipe 300 to the water tank 100 , it is preferable that the water in the water supply pipe 300 falls to the water tank 100 and is delivered, and the cooling unit 400 is It is preferable to cool the water in the water supply pipe 300 by being formed at a point before the fall.

The air supply unit 500 cools the air so that the tank bubbler 210 can generate bubbles using the cooled air, and delivers the cooled air to the tank bubbler 210. , the tank bubble generator 210 receiving the cooled air from the air supply unit 500 may maintain the water temperature of the water supply unit 200 below a certain temperature or cool the water to a low temperature.

The control unit 800 includes the water tank 100 , the tank bubble generator 210 , the water supply unit 200 , the water supply pipe 300 , the cooling unit 400 , the air supply pipe 600 and the As a configuration for controlling the operation of the air supply unit 500, the water tank 100, the tank bubble generator 210, the water supply unit 200, the water supply pipe 300, the cooling unit 400, the It may be formed by being attached to any one of the air supply pipe 600 and the air supply unit 500 , or it may be formed separately from the outside, and the water tank 100 , the tank bubbler 210 , and the water It is preferable that all of the operation of the supply unit 200 , the water supply pipe 300 , the cooling unit 400 , the air supply pipe 600 , and the air supply unit 500 be electrically connected to control.

In addition, the control unit 800 is formed to be able to communicate with the outside, and according to a control signal transmitted from the outside, the water tank 100, the tank bubble generator 210, the water supply unit 200, the water supply pipe. (300), the operation of the cooling unit 400, the air supply pipe 600, and the air supply unit 500 may be controlled.

The water tank 100, the tank bubble generator 210, the water supply unit 200, the water supply pipe 300, the cooling unit 400, the air supply pipe 600, and the air supply unit 500 The fish farm high temperature and red tide disaster prevention system 10 of the present invention comprising the can maintain the temperature of the water delivered to the water tank 100 at a constant temperature or cool it to a low temperature, and the water containing the suspended matter generates bubbles in the tank Since it can be purified by the device 210, the low-temperature water purified through the water supply unit 200, the cooling unit 400 and the air supply unit 500 can be delivered to the water tank 100, so that fish It has the effect of providing optimal conditions for cultivating

In addition, the water tank 100 may be formed in the water tank 100 and may further include a water tank bubble generator 110 controlled by the control unit 800 . Through the water tank bubble generator 110 to the water tank 100, sufficient oxygen is supplied to the water inside the water tank 100 in which the fish are cultured, and the water inside the water tank 100 is stagnant and the water temperature rises. can prevent The water tank bubble generator 110 is preferably formed at the bottom of the water tank 100 , at this time, is formed on the bottom of the water tank 100 and rotates, and agitates the water inside the water tank 100 . The impeller unit may be formed.

In addition, the water tank bubble generator 110 may be characterized in that it receives the cooled air generated by the air supply unit 500 to generate bubbles. When air bubbles are generated by receiving the cooled air from 500), there is an effect of preventing the temperature of the water inside the water tank 100 from rising.

In addition, the water supply unit 200 includes a water storage tank 220 , the water storage tank 220 and the pump in which the tank bubble generator 210 is installed, and stores the water received through the pump 221 . The inlet valve 230 formed between 221, the outlet valve 240 formed between the water storage tank 220 and the water supply pipe 300, and the water temperature of the water storage tank 220 are measured It may be characterized in that it includes a water temperature sensor 250 and a red tide sensor 260 for measuring the water red tide amount of the water storage tank 220 .

The red tide sensor 260 is a sensor that detects water quality, water temperature, or color, and has a structure in which the sensor responds according to a preset value, and a sensor capable of detecting the amount of red tide may be applied.

The water storage tank 220 is configured to receive and store external seawater or fresh water through the pump 221 , and the tank bubbler 210 is installed therein.

The inlet valve 230 is configured to control opening and closing of the water delivered to the water storage tank 220 through the pump 221 under the control of the controller 800 .

The outlet valve 240 is configured to control the opening and closing of water transferred from the water storage tank 220 to the water supply pipe 300 under the control of the controller 800 .

The water temperature sensor 250 is formed in the water storage tank 220 , measures the temperature of water stored in the water storage tank 220 , and transmits the measured value to the controller 800 .

The red tide sensor 260 is formed in the water storage tank 220, measures the red tide amount of water stored in the water storage tank 220, and transmits the measured value to the controller 800. .

The control unit 800 controls the inlet valve 230 , the outlet valve 240 , and the tank bubbler 210 according to values measured by the water temperature sensor 250 and the red tide sensor 260 . operation can be controlled.

When the value measured by the water temperature sensor 250 is greater than or equal to a certain value, the tank bubble generator 210 may be operated to lower the water temperature inside the water storage tank 220 , and the water temperature sensor 250 may measure When the value obtained is less than a predetermined value, the operation of the tank bubbler 210 may be stopped.

In addition, when the value measured by the red tide sensor 260 is greater than or equal to a certain value, the tank bubbler 210 is operated as well as the operation step of the tank bubbler 210 is strongly adjusted to , and when the value measured by the red tide sensor 260 is less than a predetermined value, the bubble generator may be stopped or the operation step of the tank bubbler 210 may be slightly adjusted.

In this case, the red tide sensor 260 may be formed between the inlet valve 230 and the water storage tank 220 and between the water storage tank 220 and the outlet valve 240, respectively. there is. Through the arrangement of the red tide sensor 260 as described above, the red tide sensor 260 installed between the inlet valve 230 and the water storage tank 220 is used to store the water in the water storage tank 220 . The red tide amount of the incoming external water can be measured, and when the red tide amount of the external water exceeds the range that the water storage tank 220 can purify, the inlet valve 230 is shut off to close the water storage tank ( 220) It is possible to prevent contamination of the water inside. In addition, the red tide amount of water transferred from the water storage tank 220 to the water tank 100 using the red tide sensor 260 installed between the water storage tank 220 and the outlet valve 240 . can be measured, and when the red tide amount of the water in the water storage tank 220 exceeds the range that can be delivered to the water tank 100, the outlet valve 240 is blocked, It is possible to prevent contamination of water and further purify the water in the water storage tank 220 .

Also, the air supply unit 500 may include an air storage tank 510 for storing air and a heat exchanger 520 for cooling the air transferred from the air storage tank 510 .

The air storage tank 510 is configured to store and store air received from the outside, and the air stored in the air storage tank 510 is transferred to the heat exchanger 520 .

The heat exchanger 520 is configured to cool the air received from the air storage tank 510, and the air cooled through the heat exchanger 520 is the tank bubbler 210 and the water tank bubbler ( 110) can be transferred. As shown in FIG. 2 , the heat exchanger 520 may include an air radiator, a dryer, a cooler, or a single heat exchange device.

Referring to FIG. 3 , the water supply pipe 300 may further include a filter unit 310 for filtering the water transmitted from the water supply unit 200 .

The inside of the filter unit 310 is formed in a Laval structure, so that the water delivered from the water supply unit 200 can pass through the Laval structure of the filter unit 310 with an increased flow rate. there is.

In addition, the water supply pipe 300 protrudes toward the inside of the water supply pipe 300, and further comprises a vortex generating pin 320 for generating a vortex in the water inside the water supply pipe 300. can

The vortex generating pin 320 generates a vortex in the water inside the water supply pipe 300 to increase the flow rate, and uses the impact generated by the vortex to generate finer bubbles, vortex is generated and small water droplets evaporate It is possible to lower the water temperature of the water delivered to the water tank 100 by using the heat of vaporization.

Referring to FIG. 4 , the cooling unit 400 is formed by bypassing the water supply pipe 300 , and blows air into the water transferred from the water supply unit 200 to the water tank 100 to cool the water. It may be characterized by When the cooling unit 400 is bypassed and connected to the water supply pipe 300 , the water inside the water supply pipe 300 maintains the water temperature inside the water supply pipe 300 through friction with external air or , can be cooled.

At this time, the cooling unit 400 may be characterized in that it includes a fan 410 that delivers external air to the inside of the water supply pipe 300 through the rotation of the blade. The speed of air delivered to the water flowing inside the water supply pipe 300 through the fan 410 increases, so that the water inside the water supply pipe 300 can be cooled faster.

In addition, the fan 410 may receive the cooled air generated by the air supply unit 500 and deliver the cooled air into the water supply pipe 300 . When the fan 410 delivers the cooled air produced by the air supply unit 500 to the water flowing inside the water supply pipe 300 , the temperature is determined by the distance between the water supply unit 200 and the water tank 100 . It is possible to lower the temperature of the raised water, so that the temperature of the water supplied to the water tank 100 can be maintained at a low temperature.

Referring to FIG. 5 , in the heat exchanger 520 , the inside of the heat exchanger 520 is maintained at a constant temperature by the refrigerant pipe 521 and the refrigerant pipe 521 through which a refrigerant object flows, and the air transferred from the air storage tank 510 . It may be characterized in that it comprises a freezing chamber 522 to be cooled. The freezing compartment 522 forms a sealed space, and the air inside the freezing compartment 522 is cooled by the refrigerant pipe 521 formed in the sealed space of the freezing compartment 522 , and the freezing compartment 522 . ) The cooled air inside may be delivered to the tank bubbler 210 , the water tank bubbler 110 and the cooling unit 400 along the air supply pipe 600 .

In addition, in the heat exchanger 520 , the air transferred from the air storage tank 510 to the freezing chamber 522 flows therein, and is spaced apart from the refrigerant tube 521 by a predetermined distance to the refrigerant tube 521 . An air pipe 523 through which indirect cooling occurs may be further included. The air pipe 523 is formed adjacent to the refrigerant pipe 521 and is indirectly cooled from the refrigerant pipe 521 , so that the air can be cooled faster. The air cooled through the air pipe 523 may be delivered to the air supply pipe 600 to be delivered to the tank bubbler 210 , the water tank bubbler 110 , and the cooling unit 400 . The air tube 523 is formed adjacent to the refrigerant tube 521, and a plurality of air tubes may be formed to transfer more air.

6, the air pipe 523 protrudes from the inner circumferential surface of the air pipe 523 toward the center of the air pipe 523 and further includes a plurality of cooling fins 524 formed at a predetermined angle to each other. It can be characterized by being made. The plurality of cooling fins 524 transmits the cooling effect of the refrigerant pipe 521 and the freezing chamber 522 to the air inside the air pipe 523 as a whole, so that the air inside the air pipe 523 is evenly distributed as a whole. In a configuration that allows cooling, it may be formed entirely on the inner circumferential surface of the air pipe 523 along the length of the air pipe 523 .

Referring to FIG. 7 , the fish farm high temperature and red tide disaster prevention system 10 of the present invention detects the temperature and red tide amount of external water delivered to the water supply unit 200, generates an environmental signal, and transmits the environmental signal to the It may be characterized in that it further includes an external environment sensing unit 900 that is transmitted to the control unit 800 .

The external environment sensing unit 900 is formed in the sea or river with seawater or fresh water delivered to the water supply unit 200 , and detects the temperature and red tide amount of water flowing into the water supply unit 200 . Generates the environmental signal according to the temperature and red tide of water, and transmits the environmental signal to the control unit 800, so that the control unit 800 according to the environmental condition of the water flowing into the water supply unit 200, the control unit ( 800) and is a configuration to operate the connected components.

Through the external environment sensing unit 900, the high temperature and red tide disaster prevention system 10 of the present invention has an effect that the operation is controlled according to the external environment.

At this time, the external environment sensor 900 measures the external temperature sensor 910 that measures the temperature of the external water delivered to the water supply unit 200 , and measures the amount of red tide of the external water delivered to the water supply unit 200 . The external red light sensor 920, the external temperature sensor 910, and the signal generator 930 for generating the environmental signal according to the measured values measured by the external red light sensor 920, and the environmental signal It may be characterized in that it comprises an external communication unit 940 for transmitting to the control unit (800).

In addition, the fish farm high temperature and red tide disaster prevention system 10 of the present invention can communicate with the control unit 800 , monitor the state of the control unit 800 , and control the operation of the control unit 800 . It may be characterized in that it further comprises an external communication terminal 1000 that can be controlled.

The external communication terminal 1000 can output a screen such as a mobile phone, a tablet PC, a notebook computer, and a computer, and any device can be applied as long as an input unit is formed and communication is possible.

When the external communication terminal 1000 communicates with the control unit 800 , it is preferable that a dedicated application or program capable of outputting information transmitted and received from each other on a screen is used.

Through the external communication terminal 1000, an outside administrator can check the temperature and red tide amount of water flowing into the water supply unit 200 or the water tank 100 in real time, and the operation of the control unit 800 can be controlled remotely, so it is effective to prevent disasters in the farm due to high temperatures or red tides in advance.

Referring to FIG. 8 , the high temperature and red tide disaster prevention system 10 of the aquaculture farm of the present invention further includes a microorganism supply unit 700 connected to the water supply pipe 300 and supplying microorganisms to the water tank 100 . can be characterized.

The microorganism supply unit 700 may include a microorganism supply tank in which microorganisms for purifying water are introduced and stored, and a microorganism supply pipe 300 that transfers microorganisms from the microorganism supply tank to the water supply pipe 300 , The microorganism supply pipe 300 may be opened and closed by a valve.

The microorganism supply unit 700 is configured to allow the water transferred from the water supply unit 200 to the water tank 100 to be additionally purified, and the valve of the microorganism supply pipe 300 is controlled according to the control unit 800 . It is preferable to be

When the bubbles generated in the tank bubbler 110 and the tank bubbler 210 are discharged as normal bubbles having a diameter of 1 mm or more, they rise rapidly above the water surface and rupture, have high diffusivity, and agitation of water There is a characteristic that this is possible. In addition, when the generated bubbles are discharged as microbubbles having a diameter of 100 μm to 1000 μm, they rise somewhat slowly above the water surface and rupture, and have high diffusivity. In addition, when the generated bubbles are discharged as microbubbles having a diameter of 10 μm to 100 μm, they rise slowly above the water surface and burst, have low diffusivity, but can generate functions for sterilization and cleaning, and the amount of dissolved oxygen in water has the property to increase The diameter of the bubbles generated by the water tank bubbler 110 and the tank bubbler 210 according to the present invention can be changed by design, and the tank bubbler 110 and the tank according to the present invention The bubble generator 210 may discharge the bubble shape of any one of normal bubbles, microbubbles, and microbubbles by changing the design conditions of the nozzles to which the cooled air is sprayed according to the design of the device designer.

The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention as claimed in the claims.

10: Farm high temperature and red tide disaster prevention system
100: water tank 110: water tank bubble generator
200: water supply 210: tank bubble generator
220: water storage tank 221: pump
230: inlet valve 240: outlet valve
250: water temperature sensor 260: red light sensor
300: water supply pipe 310: filter unit
320: vortex generating pin
400: cooling unit 410: fan
500: air supply 510: air storage tank
520: heat exchanger 521: refrigerant pipe
522: freezer 523: air tube
524: cooling fin
600: air supply pipe
700: microorganism supply unit
800: control unit
900: external environment sensing unit 910: external temperature sensor
920: external red light sensor 930: signal generator
940: external communication unit
1000: external communication terminal

Claims (18)

In a system for managing water in a farm,
a tank containing fish and water;
a water supply unit provided with a tank bubbler that receives external water, supplies water to the water tank, and generates bubbles;
a cooling unit formed in a water supply pipe that delivers the water of the water supply unit to the water tank to cool the water in the water supply pipe;
an air supply unit generating cooled air and supplying the cooled air to the tank bubbler through an air supply pipe connected to the water supply unit; and
A control unit that controls the operation of the water tank, the tank bubbler, the water supply unit, the water supply pipe, the cooling unit, the air supply pipe, and the air supply unit, and is capable of communicating with the outside; includes;
The air supply unit,
air storage tank to store air; and
a heat exchanger for cooling the air delivered from the air storage tank;
is made, including
the heat exchanger,
a refrigerant pipe through which a refrigerant object flows; and
a freezing chamber in which the inside is maintained at a constant temperature by the refrigerant pipe and the air delivered from the air storage tank is cooled;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it comprises a. According to claim 1, The water tank,
a water tank bubble generator that is formed inside the water tank and is controlled by the control unit;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it further comprises a. According to claim 2, wherein the water tank bubble generator,
High temperature and red tide disaster prevention system for aquaculture farms, characterized in that it generates bubbles by receiving the cooling air generated from the air supply unit. According to claim 1, wherein the water supply unit,
a water storage tank in which the tank bubble generator is installed, and storing the water received through the pump;
an inlet valve formed between the water storage tank and the pump;
an outlet valve formed between the water storage tank and the water supply pipe;
a water temperature sensor for measuring the water temperature of the water storage tank;
a red tide sensor for measuring the water red tide amount of the water storage tank;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it comprises a. According to claim 4, wherein the red light sensor,
Aquaculture high temperature and red tide disaster prevention system, characterized in that formed between the inlet valve and the water storage tank and between the water storage tank and the outlet valve, respectively. According to claim 1, wherein the water supply pipe,
a filter unit for disturbing air bubbles;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it further comprises a. According to claim 1, wherein the water supply pipe,
a vortex generating pin protruding toward the inside of the water supply pipe to generate a vortex in the water inside the water supply pipe;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it further comprises a. According to claim 1, wherein the cooling unit,
A high temperature and red tide disaster prevention system for aquaculture farms formed by bypassing the water supply pipe, and cooling the water by blowing air into the water transferred from the water supply unit to the water tank. The method of claim 8, wherein the cooling unit,
a fan passing outside air into the water supply pipe through rotation of the blades;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it comprises a. 10. The method of claim 9, wherein the fan,
High temperature and red tide disaster prevention system for aquaculture farms, characterized in that receiving the cooled air generated by the air supply unit, and delivering the cooled air to the inside of the water supply pipe. delete delete According to claim 1, wherein the heat exchanger,
an air pipe through which air transferred from the air storage tank to the freezing chamber flows therein, and spaced apart from the refrigerant pipe by a predetermined distance, in which indirect cooling occurs by the refrigerant pipe;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it further comprises a. The method of claim 13, wherein the air pipe,
a plurality of cooling fins protruding from the inner circumferential surface of the air tube toward the center of the air tube and formed at a predetermined angle to each other;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it further comprises a. The method of claim 1,
an external environment sensing unit sensing the temperature and red tide amount of external water transmitted to the water supply unit, generating an environmental signal, and transmitting the environmental signal to the control unit;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it further comprises a. The method of claim 15, wherein the external environment sensing unit,
an external temperature sensor for measuring the temperature of external water transferred to the water supply unit;
an external red tide sensor for measuring a red tide amount of external water delivered to the water supply unit;
a signal generator configured to generate the environmental signal according to the measured values measured by the external temperature sensor and the external red light sensor; and
an external communication unit transmitting the environmental signal to the control unit;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it comprises a. 16. The method according to any one of claims 1 to 15,
an external communication terminal capable of communicating with the control unit, monitoring a state of the control unit, and controlling the operation of the control unit;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it further comprises a. The method of claim 1,
a microorganism supply unit connected to the water supply pipe to supply microorganisms to the water tank;
Aquaculture high temperature and red tide disaster prevention system, characterized in that it further comprises a.

Images