KR102624053B1 - Pneumatic Feeding System for Aquaculture Farm - Google Patents

Abstract

An aquaculture tank in which a polygonal tank bottom is surrounded by an outer tank wall of a certain height, and an internal breeding space and an upper opening are formed; A drainage device is installed at the bottom of the tank to drain breeding water and culture sludge; The drained breeding water and culture sludge move through a drain pipe connected to the drainage device to a collection unit installed at a corner of the culture tank; A pneumatic device surrounded by a pneumatic device housing is formed in the aquaculture tank, a feed receiver and a feed receiver are connected to the piston tip of the pneumatic device, and a plate-shaped moving plate connected to a feed measuring cup holder is connected to the piston of the pneumatic device at the bottom of the feed container. By providing a pneumatic automated fish farm equipped with a pneumatic automatic feed supply device that supplies the feed contained in the feed measuring cup holder to the fish tank by the reciprocating motion of the piston, the effect of reducing farm operation costs and at the same time automatically managing the farm is possible. There is.

Description

Pneumatic Feeding System for Aquaculture Farm}

The present invention relates to a pneumatic feed supply device for an automated fish farm capable of rearing and cultivating aquatic organisms. It is equipped with a pneumatic system to reduce farm operating costs and at the same time automatically manages the fish farm. It's about.

According to the latest global fisheries outlook, the supply of fishery products is expected to be insufficient. In Korea, there are also concerns about whether a stable supply of marine products will be possible in the future due to production stagnation in fisheries other than aquaculture.

Despite this stagnation in the supply of marine products, the problem of fish inflation, in which prices of marine products continue to rise, is being raised as consumption of marine products at home and abroad increases. Therefore, it is most important to have a fisheries industry base that can stably supply fishery products, a food resource, while actively responding to environmental changes.

In order to overcome the production limitations of traditional fishing, it is necessary to develop aquaculture into a high value-added industry by incorporating cutting-edge technology and new concepts. As one of the efforts to develop a new aquaculture system, the development of an automated aquaculture management system is in progress.

Accordingly, as prior literature on automated aquaculture systems, Domestic Patent Publication No. 10-2018-0084654 discloses an integrated fish farm management system using big data and artificial intelligence machine learning, and Domestic Registered Patent No. 10-1712377 discloses. Although an automated water quality analysis and remote monitoring system for aquaculture farms using image processing techniques of water quality measurement kits is disclosed, the electronic automation device system cannot last for several months and breaks down in places where there is a lot of moisture and salt corrosion is a concern, such as a fish farm. There are limitations, one electric line must be connected to each device, there is a constant risk of short circuit and fire, and the disadvantage is that it consumes a lot of energy.

Meanwhile, pneumatic systems use compressed gas to transmit and control power. Pneumatic systems generally use air as a fluid medium. Air is safer than other gases, there is no need to worry about corrosion due to salt or failure due to moisture, and it has low resistance, so it can be sent a long distance with less energy, and is a single pneumatic device. This is because multiple pneumatic automation devices can be installed on the line, there is no risk of electric leakage or fire, and it is a low-cost and easily obtainable fluid.

The components of a typical pneumatic system include an electric motor or other prime mover that supplies power, a compressor that compresses air coming from the atmosphere, an air tank that stores the required amount of compressed air, and a control valve that controls the direction, pressure, and flow rate of the air. , an actuator that converts compressed energy into mechanical energy, and a pipe that transports compressed air from one place to another.

A compressor in a pneumatic system is used to compress and supply the required amount of air. It is a device that compresses air or other gas from a low inlet pressure to a higher required pressure. Typically, it may be formed as a reciprocating piston type, rotating vane type, or rotating screw type. The compressor increases gas pressure by reducing the gas volume according to the perfect gas law.

The advantage of the pneumatic system is that compressed air can be obtained practically anywhere and compressed air can be stored in a storage tank, so it can be conveniently used in emergencies such as power outages or when safety functions are required, as well as easy installation and low cost. It is economical as it costs less.

Accordingly, the present invention is equipped with a pneumatic system, so that it can be used without problems in places with a lot of salt and moisture, is efficient for long distance transportation, and can be used in pneumatic automated fish farms where multiple automation devices can be controlled simultaneously with one pneumatic line. We would like to provide a pneumatic feed supply device for fish farms.

Domestic Patent Publication No. 10-0729567 Domestic Utility Model Publication No. 20-0358668 Domestic Patent Publication No. 10-2018-0084654 Domestic registered patent number 10-0821882

The present invention is intended to solve the problem of large energy consumption in the operation of existing automated fish farm systems, and is equipped with a pneumatic system to reduce farm operating costs and at the same time provide pneumatic feed for automated fish farms that can automatically manage the fish farm. We would like to provide a device.

In the present invention, a pneumatic device (86) is formed surrounded by pneumatic device housings (86A, 86B), a feed receiver holder (87) and a feed receiver (85) are connected to the piston tip of the pneumatic device, and a feed receiver (85) is located at the lower part of the feed receiver (85). Provides a pneumatic automatic feed supply device for a fish farm in which a plate-shaped moving plate connected to the feed measuring cup holder (88) is connected to the piston of a pneumatic device so that the feed contained in the feed measuring cup holder (88) is supplied to the aquaculture tank by the reciprocating movement of the piston. do.

The feed measuring cup holder (88) of the present invention consists of a feed measuring unit with the upper and lower portions having a certain volume open, and the feed measuring unit is configured to be equipped with a feed measuring cup (100), and the pneumatic device has a regulating piston inside. One end of the installed moving pipe is connected to the supply pipe, and an air inlet and air outlet are formed on the side of the moving pipe, so that the control piston can move in a straight direction within the moving pipe according to air injection and discharge.

A pneumatic automated fish farm according to an embodiment of the present invention includes an aquaculture tank in which a polygonal tank bottom is surrounded by an outer tank wall of a certain height, and an internal breeding space and an upper opening are formed; A drainage device is installed at the bottom of the tank to drain breeding water and culture sludge; The drained breeding water and culture sludge move through a drain pipe connected to the drainage device to a collection unit installed in the culture tank; One or more automatic pneumatic control devices branched from one pneumatic line are installed in the aquaculture tank; A pneumatic automatic feed supply device connected to the pneumatic automatic control device is connected, and the biofloc breeding water and culture sludge stored in the collection unit moves to the water treatment system through the water treatment system transfer pipe to be purified and sludge removed; The water treatment system provides a pneumatic automated fish farm in which a resupply pipe equipped with an in-line UV sterilization system is installed so that breeding water with controlled microbial density is resupplied to the aquaculture tank.

The present invention is equipped with a pneumatic system to significantly reduce electrical leakage, fire, corrosion, breakdown, and costs, while automatically managing various items such as supply of a certain amount of feed, pH control, supply of microorganisms, supply of culture medium, supply of water quality regulator, and automatic water change. There is an effect that can be done.

Figure 1 shows a schematic diagram of the pneumatic automated fish farm of the present invention.
Figure 2 shows an example of a collection unit installed in a breeding tank.
Figure 3 shows a cutaway view of the pneumatic automatic water exchange device of the drainage control device of the present invention.
Figure 4 shows a cutaway view of the pneumatic automatic water exchange device of the drainage control device of the present invention.
Figure 5 shows the pneumatic automatic feed supply device of the present invention.
Figures 6 and 7 show a pneumatic automatic feed feed device branched from one pneumatic line installed in an aquaculture tank as an example of the pneumatic automatic feed feed device of the present invention.
Figures 8 and 9 show measuring cups mounted on the feed measuring unit of the pneumatic automatic feeding device of the present invention and measuring cups for each size.

Hereinafter, the pneumatic automated fish farm and pneumatic automatic feeding device of the present invention will be described in detail with attached drawings.

Figure 1 shows a schematic diagram of the pneumatic automated fish farm of the present invention. The pneumatic automated fish farm of the present invention includes an aquaculture tank (10) in which a polygonal tank bottom is surrounded by an outer tank wall of a certain height, and an internal breeding space and an upper opening are formed; A drainage device 70 is installed at the bottom of the tank to drain breeding water and culture sludge; The drained breeding water and aquaculture sludge move through a drain pipe (40) connected to the drainage device to a collection unit (50) installed at a corner of the aquaculture tank; The aquaculture tank is equipped with a pneumatic automatic feed supply device (80) and a pneumatic automatic pH control device (90) that can automatically supply food and control the pH of the breeding water; The biofloc breeding water and aquaculture sludge stored in the collection unit are moved to the water treatment system 30 through the water treatment system transfer pipe 20, where they are purified and sludge is removed; A resupply pipe 60 is installed in the water treatment system so that purified breeding water is resupplied to the aquaculture tank.

The aquaculture tank may be installed with several pneumatic automatic control devices branched from one pneumatic line. In one embodiment, a pneumatic type that can automatically control the food supply and pH of the breeding water in one or several aquaculture tanks. Automatic feeding device; A pneumatic automatic pH control device is installed; One or more pneumatic devices selected from among microorganisms, culture medium, water quality control agent automatic supply device, and automatic water exchange device required to control biofloc water quality may be installed.

The biofloc breeding water and aquaculture sludge stored in the collection unit are moved to the water treatment system through the water treatment system transfer pipe to be purified and the sludge is removed; The water treatment system can be equipped with a resupply pipe equipped with an in-line UV sterilization system, and a device can be installed to resupply breeding water with controlled microbial density to the aquaculture tank, and the system is an automated system that operates in conjunction with a sensor and a machine. You can.

The collection unit may have a partition wall of a certain height installed perpendicular to the floor, and both side parts may be connected to the inner surface of the outer wall of the water tank to form a storage space with a triangular cross-sectional structure, and the bottom of the storage space of the collection unit may have A discharge control pipe is installed perpendicular to the floor in a pipe-structured frame and is connected to the water treatment system moving pipe to discharge the stored breeding water and aquaculture sludge in the collection section so that they can move, and on one side of the discharge control pipe, the discharge control pipe is connected to the water treatment system moving pipe. A pneumatic automatic water exchange device may be installed by forming a discharge hole through which breeding water and aquaculture sludge moves.

A piston is installed that is inserted into the upper part of the discharge control pipe to open and close the discharge hole as it moves up and down, and a case is installed with a lower opening formed to accommodate the upper part of the discharge control pipe, and the piston is installed. An air inlet and an air outlet may be installed on one side of the pneumatic water level control device, which is formed of a frame that is fixed and can move up and down in the internal space.

The pneumatic automatic feed supply device is installed at the opening of the breeding tank, and has a structure in which aquaculture feed is stored inside. The lower part has a feed storage case formed with a connection pipe connected to the feed supply pipe, and the upper side is a horizontal pipe structure for the feed storage. It may be formed by a feed supply pipe connected to the connection pipe of the case, one end of which is formed with a feed supply section through which feed is supplied toward the breeding tank, and a feed supply control device 83 installed at the other end of the feed supply pipe.

The feed supply control device includes a moving pipe in which a control piston is installed, one end of the moving pipe is connected to the feed supply pipe, and an air inlet and an air outlet are formed on the side, so that the control piston moves in a straight direction within the moving pipe according to air injection and discharge. It may be movable.

The pneumatic automatic pH control device 90 has a structure in which an internal space is stored in which a liquid or solid pH control solution is stored, and a pH control solution storage section is formed at the bottom of which a control solution supply part through which the stored pH control solution can be supplied to the breeding tank is formed. It may be composed of a case, a powder crushing device attached to the end of the pneumatic piston, and a pH adjusting device that opens and closes the adjusting liquid supply portion according to the up and down movement of the pneumatic piston.

In the internal breeding space of the aquaculture tank 10 of the present invention, breeding water and aquaculture organisms are stored, and a water temperature control device and an air blower are installed to enable the survival of the aquaculture organisms, and the breeding water is supplied by a submersible pump, an air blower, etc. It is appropriate to ensure that the water flow is formed in one direction. A drainage device 70 is installed at the center of the bottom of the tank, so that breeding water, feed waste, or aquaculture sludge consisting of excrement from aquaculture organisms can be drained according to the water flow formed. The drainage device may be formed as a drainage device installed in a typical fish farm.

As an embodiment of the present invention, the pneumatic automatic water return drainage device is a double rod frame, and the frame installed inside can move up and down inside the outer frame, and a drain hole is formed on one side of the outer frame to allow movement of the inner frame. Accordingly, the drainage hole can be closed and opened to control drainage.

When installed outside the aquaculture tank, the collection unit 50 of the present invention has a case structure with a space where breeding water and aquaculture sludge moved through the drain pipe can be stored, or when installed inside the aquaculture tank, it has a partition wall ( 51) is installed and the moved breeding water and culture sludge can be stored in the storage space formed by the outer wall and partition of the tank.

Figure 2 shows an example of a collection unit installed in an aquaculture tank. In the collection unit according to the embodiment of FIG. 2, a partition wall of a certain height is installed perpendicular to the floor, and both side parts are connected to the inner surface of the outer wall of the water tank to form a storage space with a triangular cross-sectional structure.

Movement of breeding water and culture sludge into the storage space is possible by connecting a drain pipe to the side of the partition wall. In addition, since the height of the partition wall is shorter than the height of the outer wall of the water tank, the breeding water stored in the internal breeding space can be moved to the collection unit on the overflow principle.

In an embodiment according to the present invention, the outer wall of the water tank is formed to a height of 1 m, and the partition wall is formed to a height of 80 cm, so that the breeding water stored in the storage space of the breeding tank can maintain a water level of 80 cm. As the height difference between the outer wall of the water tank and the partition wall increases, the breeding water falls into the storage space and degassing can occur simultaneously with the movement, making it possible to remove gas components contained in the breeding water.

A drainage control device 52 may be installed at the bottom of the storage space of the collection unit. The drainage control device of the present invention can be formed as a conventional automatic water change device or a pneumatic automatic water change device. In one embodiment according to the present invention, the drainage control device was installed as a pneumatic automatic water exchange device. The pneumatic automatic water exchange device is a tube-structured frame installed perpendicular to the floor, and is connected to the water treatment system moving pipe 20, including a discharge control pipe 53 that discharges the stored breeding water and aquaculture sludge in the collection section so that they can move, and the discharge. On one side of the control pipe, a discharge hole 53a is formed through which breeding water and culture sludge moves into the discharge control pipe.

In addition, a piston (55c) is inserted into the upper part of the discharge control pipe to open and close the discharge hole as it moves up and down, and a lower opening is formed to accommodate the upper part of the discharge control pipe (case installed) 54) is installed, and an air inlet 55a and an air outlet 55b can be installed on one side of the pneumatic water level control device 55, which is formed of a frame that fixes the piston and can move up and down in the internal space. there is.

Figures 3 and 4 show a cutaway view of an automatic pneumatic water exchange device according to an embodiment of the drainage control device of the present invention. The piston of the present invention moves up and down while applying a certain pressure according to the air inflow of the air inlet and the air discharge of the air outlet formed in the water level control device, and can thereby control the closing and opening of the discharge hole.

The water level control device is equipped with a pneumatic system, so air inflow and discharge can be controlled by remote control, thereby reducing energy consumption for discharging drained breeding water and sludge. In addition, a certain amount of air is distributed in the inner space of the case, so when the discharge hole is opened, the water level in the collection part can always be adjusted to a constant level according to the position of the discharge hole, so the water level can be adjusted automatically.

The discharge control pipe is connected to the water treatment system transfer pipe 20, so that the breeding water and culture sludge flowing into the discharge hole can be moved to the water treatment system. The water treatment system 30 of the present invention may be equipped with a conventional water treatment device 31 capable of removing sludge contained in biofloc breeding water.

The water treatment system of the present invention may be equipped with a water treatment device including a filtration device or a centrifugal type, but the water treatment device is not limited thereto as long as it can purify the drained biofloc breeding water and re-supply it to the breeding tank.

The filtration device according to an embodiment of the present invention is connected to the water treatment system moving pipe and includes an activated carbon filter configured in a single form or in a series or parallel form in the form of particles or fibers to filter and pass the treated water moved from the aquaculture tank. A pretreatment means, and the treated water that has passed through the pretreatment means may be made of a nano filter, a precision filter, or an ultrafilter to filter out polyvalent ions or organic substances.

As another example, a centrifugal water treatment device may be installed in the water treatment system. The centrifugal water treatment device according to an embodiment of the present invention can be installed to perform functions such as existing second hand, coagulation-chip filter, and media filter by rapidly settling and solidifying suspended solids and colloidal particles contained in treated water by centrifugal force. You can. The breeding water purified in the water treatment device can be re-supplied to the breeding tank with the density of microorganisms controlled while passing through the resupply pipe 60 into which an in-line UV sterilizer is inserted.

Figure 5 shows a feed supply device branched from one pneumatic line installed in an aquaculture tank and installed in a pneumatic automatic control device as an embodiment of the pneumatic automatic feeding device of the present invention. The pneumatic automatic feed supply device (80) can be installed in the opening of the breeding tank. The pneumatic automatic feed supply device of the present invention has a spatial structure in which aquaculture feed is stored inside the breeding tank where aquaculture organisms can feed, and includes a feed storage case 81 with a connection pipe connected to the feed supply pipe at the bottom, and a horizontal The upper side of the pipe structure is connected to the connection pipe of the feed storage case, one end is a feed supply pipe (82) forming a feed supply section through which feed is supplied toward the breeding tank, and the other end of the feed supply pipe is a feed supply control device (83). ) can be installed by installing.

The feed supply control device 83 is equipped with a pneumatic system. The feed supply control device includes a moving pipe in which a control piston is installed, and one end of the moving pipe is connected to the feed supply pipe so that the control piston can move in a straight line within the moving pipe toward the feed supply pipe.

An air inlet and an air outlet are installed on the side of the moving pipe, and the control piston moves according to the inflow and outflow of air. Accordingly, the control piston pushes the aquaculture feed stored inside the feed pipe to the feed supply section, making it possible to supply and control the feed. The movement distance of the control piston is adjusted according to the pneumatic pressure of the feed supply control device, and the feed supply is adjusted according to the set amount. This is possible.

When conventional farmed fish need food, they swim near the feeding station. Accordingly, as an embodiment, the pneumatic automatic feed supply device of the present invention is equipped with a supply amount determination system and can supply an appropriate amount of feed according to the number of aquaculture organisms swimming in the feeding station.

The supply amount determination system according to the above embodiment includes an imaging device that monitors aquaculture organisms distributed in a certain area in the aquarium, determines the amount of food supply according to the number of aquaculture organisms captured by the imaging device, and transmits a command to a pneumatic automatic feed supply device. It can be done with a management device.

Figures 6 and 7 show a pneumatic automatic feed supply device 80 branched from one pneumatic line installed at the opening of the aquaculture tank and connected to a pneumatic automatic control device as an embodiment of the pneumatic automatic feed device of the present invention. The pneumatic automatic feed supply device 80 of the present invention serves to transport and supply feed stored in the feed storage tank 81 to the breeding tank. The pneumatic automatic feed supply device 80 is formed by a pneumatic device 86 surrounded by pneumatic device housings 86A and 86B, and a feed receiver 87 and a feed receiver 85 are connected to the piston end of the pneumatic device, and feed At the bottom of the receiver (85), a feed measuring cup holder (88) and a feed measuring unit (89) are connected to the piston of the pneumatic device so that the feed contained in the feed measuring unit is supplied to the breeding tank by the reciprocating movement of the piston.

The feed receiver 85 serves to move the feed transferred from the feed storage tank 81, where the feed is stored, through the feed supply pipe 82 to the feed measuring unit 89. The feed measuring unit 89 is connected to the tip of the piston of the pneumatic device, and when the piston of the pneumatic device is contracted, the feed is stored in the feed measuring cup 100 from the feed supply pipe 82 connected to the feed receiver 85 and the piston of the pneumatic device is When expanded, it serves to transport it to a certain location.

Since the feed receiver is made of a cylindrical shape of a certain size, it is coupled to the upper part of a plate shape that can support the cylindrical shape, and is connected to and fixed with the feed receiver holder (87). Since the feed measuring unit 89 also has one end made of a cylindrical shape of a certain size, it is formed by connecting a plate shape with a certain area connected to the feed measuring unit, and the plate-shaped moving plate connected to the feed measuring unit is connected to the tip of the piston of the pneumatic device. As the piston moves, it reciprocates in a straight line at the bottom of the feed receiver (85).

Figures 8 and 9 show measuring cups mounted on the feed measuring unit 89 of the pneumatic automatic feeding device of the present invention and measuring cups for each size. The feed measuring cup 100 is mounted on the feed measuring unit 89 and is used to control the amount of feed supplied.

The feed measuring cup can be mounted alone or by stacking feed measuring cups of multiple sizes to control the amount of feed. The feed measuring cup has an open upper and lower part with a certain volume, and a groove is formed in the lower part so that it can be mounted on the feed measuring unit.

As described above, the pneumatic automatic feed supply device 80 of the present invention is connected to one or more pneumatic automatic control devices branched from one pneumatic line installed in the aquaculture tank. In addition, the branched lines are increased to control biofloc water quality. It can be installed by adding one or more pneumatic devices selected from the required automatic microorganism supply device, automatic culture solution supply device, automatic water quality control agent supply device, and automatic water exchange device.

The present invention has industrial applicability because it provides an automated system for fish farm operation to reduce labor, and the operation is controlled by a pneumatic system to save energy, thereby reducing the operational burden on related operators.

10: Aquaculture tank 20: Water treatment system transfer tube
30: water treatment system 31: water treatment device
40: drain pipe 50: collection unit
60: Resupply pipe 70: Drainage control device
80: Pneumatic automatic feed supply device 81: Feed storage tank
82: feed supply pipe 83: feed supply control device
90: Pneumatic automatic pH control device
85: Feed receiver 86: Pneumatic device housing
87: Feed receiving stand 88: Feed measuring cup holder
89: feed measuring unit 100: feed measuring cup

Claims (3)

delete A pneumatic device (86) is formed surrounded by pneumatic device housings (86A, 86B), a feed receiver holder (87) and a feed receiver (85) are connected to the piston end of the pneumatic device, and a feed measuring cup holder is placed at the bottom of the feed receiver (85). The plate-shaped moving plate connected to (88) is connected to the piston of the pneumatic device so that the feed contained in the feed measuring cup holder (88) is supplied to the aquaculture tank by the reciprocating movement of the piston,
The feed measuring cup holder (88) consists of a feed measuring unit with an open upper and lower part having a certain volume, and a pneumatic feed supply device for a fish farm, characterized in that the feed measuring cup (100) is mounted on the feed measuring unit. According to claim 2, in the pneumatic device, one end of the moving pipe in which the regulating piston is installed is connected to the supply pipe, and an air inlet and an air outlet are formed on the side of the moving pipe, so that the regulating piston can move in a straight direction within the moving pipe according to the injection and discharge of air. Pneumatic feed supply device for fish farms, characterized in that it is formed to