KR20220007215A - No fliter aquaponics system - Google Patents

Abstract

The present invention provides a no-filter aquaponics system, which includes: a water tank in which fishes lives; a plant cultivation unit having a flow space through which a nutrient solution can flow is formed on a lower side thereof, and plants can be arranged on an upper side thereof; a supply passage for flowing the nutrient solution from the water tank to the plant cultivation unit; and a return flow path for flowing the nutrient solution from the plant cultivation unit to the water tank. Accordingly, it is possible to minimize maintenance or repair costs.

Description

NO FILTER AQUAPONICS SYSTEM

The present invention relates to a no-filter aquaponics system having an improved structure.

Recently, as one aspect of hydroponics, aquaponics is in the spotlight.

Aquaponics is a hydroponics method that uses water mixed with feces or dissolved feed in a tank where fish live as a nutrient solution for plants.

As a hydroponic culture using such aquaponics, there is registered Patent No. 10-1370075 (Title of the Invention: Plant Cultivation System and Cultivation Method Thereof).

In the prior art, the nutrient solution supplied from the water tank 100 is first passed through the filter 200, passed through the solid filter 300, and then supplied to the plant cultivation apparatus 400, and then again through the nutrient solution recovery passage 500. A system for recovering the nutrient solution and supplying it to the water tank 100 is disclosed.

However, the conventional aquaponics system including the prior art requires a lot of equipment such as a gas remover, a filter, and a solid filter between the water tank 100 and the plant cultivation medium 400, and the initial installation cost and its maintenance and repair The disadvantage is that the cost is excessive.

The present invention has been devised to solve the above problems, and an object of the present invention is to control the state of the nutrient solution circulating between the water tank and the plant cultivation unit to enable high-quality hydroponics, and at the same time, the initial installation cost, maintenance or repair It is to provide a no-filter aquaponics system that can minimize the cost.

The present invention in order to achieve the above object, a fish tank inhabited therein; A flow space through which the nutrient solution can flow is formed on the lower side, and a plant cultivation unit in which plants can be disposed on the upper side; a supply passage for flowing the nutrient solution from the water tank to the plant cultivation unit; and a return passage for flowing the nutrient solution from the plant cultivation unit to the water tank; provides a no-filter aquaponics system comprising.

In addition, it may further include a feeder installed in the water tank to supply the feed of the fish.

In addition, a first sensor for measuring ammonia in the flowing nutrient solution is disposed in the supply passage,

The feeder may increase the amount of feed supplied to the water tank when the ammonia level measured by the first sensor is less than or equal to a preset numerical range, and decrease the amount of feed supplied to the water tank when the ammonia level measured by the first sensor is equal to or greater than the preset numerical range.

In addition, the size of the feed supplied to the tank may have a diameter of 3 mm or less, and the preset level of ammonia may be 2 ppm to 4 ppm.

In addition, a driving pump for the flow of the nutrient solution may be installed in the supply passage or the return passage.

In addition, the plant cultivation unit, at least one or more seating grooves are formed, the cultivation plate is disposed to be spaced apart from the lower side of the supply passage; and a port seated in the seating groove.

In addition, a distance between the lower surface of the supply passage and the cultivation plate may be 30 cm.

In addition, a second sensor for measuring the amount of dissolved oxygen in the nutrient solution and an air pump for supplying air are disposed in the supply passage, and when the value of the amount of dissolved oxygen measured by the second sensor is smaller than a preset value, the air A pump may be driven.

In addition, the preset amount of dissolved oxygen may be 3ppm.

In addition, the plant cultivation unit includes a first plant cultivation unit and a second plant cultivation unit, the supply flow path part is disposed on one side of the first plant cultivation part, and the return flow path part is disposed on one side of the second plant cultivation part, It may further include a circulation flow passage in which one end and the other end are connected to the other side of each of the first plant culture unit and the second plant culture line.

The present invention determines the state of the nutrient solution provided to the supply passage by the sensor unit to control the amount of feed as a feeder or control the amount of dissolved oxygen as an air pump, so separate additional equipment such as a gas remover, a filter, and a solid filter It is possible to enable hydroponics without the installation of a plant, so it is possible to reduce the initial installation cost and maintenance and repair costs.

1 is a schematic diagram of a no-filter aquaponics system according to an embodiment of the present invention;
2 is a module diagram of a no-filter aquaponics system according to an embodiment of the present invention.
3 is a schematic side cross-sectional view of a plant cultivation unit according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Unless otherwise specified, all terms herein have the same general meaning as understood by those skilled in the art, and if a term used in this specification conflicts with the general meaning of the term, the definition used herein shall govern.

However, the invention to be described below is only for explaining the embodiments of the present invention and not for limiting the scope of the present invention, and the same reference numbers used throughout the specification indicate the same components.

1 is a schematic diagram of a no-filter aquaponics system according to an embodiment of the present invention, FIG. 2 is a modular diagram of a no-filter aquaponics system according to an embodiment of the present invention, and FIG. It is a schematic cross-sectional side view of the plant cultivation unit.

1 to 3 , the no-filter aquaponics system according to an embodiment of the present invention is largely a water tank 100 , a plant cultivation unit 200 , a flow path unit 300 , a sensor unit 400 , and a driving unit ( 500) may be included.

The water tank 100 has an open upper side so that fish can inhabit therein, and a plurality of tanks 100 may be disposed therein.

It is preferable to select a fish that is relatively insensitive to ammonia or dissolved oxygen as the fish cultured inside the tank 100.

In addition, the water tank 100 is formed of a size sufficient to accommodate a large number of fish, but a plurality of water tanks 100 may be disposed to supply a large amount of nutrient solution.

In addition, two or more plant cultivation units 200, which will be described later, can be connected per one tank 100, and by using the tank 100 independently in this way, curing various fish species, preventing group death of fish, and providing high-quality nutrient solution can supply

Here, in order to prevent the escape of the fish inhabiting the water tank 100, it may further include a mesh 110 installed on the upper side of the water tank 100 to prevent the fish from leaving.

The plant cultivation unit 200 is formed with a flow space at the lower side through which the nutrient solution can flow, and plants can be arranged on the upper side.

Specifically, the plant cultivation unit 200 may include a cultivation plate 201 having at least one seating groove 203 formed thereon, and a port 202 that is placed in the seating groove 203 to allow plants to grow. can

The pot 202 does not use external topsoil, but vermiculite and coconut fibers mixed in a ratio of about 4:6 can be used.

As the number of the seating grooves 203 and the port 202 increases, it is possible to produce a large amount of plants, but if there are too many, the plants are concentrated and productivity may be reduced.

For example, the cultivation plate 201 may be formed of Styrofoam, and may have a size of 1200 mm x 600 mm or a size of 600 mm x 600 mm.

Approximately 30 to 40 seating grooves 203 may be formed in the cultivation plate 201 having a size of 1200 mm x 600 mm, and approximately 50 to 60 seating grooves may be formed in the cultivation plate 201 having a size of 600 mm x 600 mm. A groove 203 may be formed, and a port 202 may be seated in each of the seating grooves 203 .

In addition, the distance between the lower surface of the supply passage 310 and the cultivation plate 201, which will be described later, may be 30 cm.

On the other hand, ammonia contained in the nutrient solution supplied from the water tank 100 must be sequentially changed from nitrite to nitrate to be used as a plant nutrient. Aerobic bacteria living near the roots of plants in the port 202 play this role. can do.

Therefore, in the plant cultivation unit 200, a plurality of the cultivation plates 201 may be sequentially arranged, in this case, a plant having grown roots is disposed adjacent to the supply passage unit 310, and the germinated plant Alternatively, the cultivation plate 201 on which the pot 202 in which seeds for germination are planted is placed may be disposed adjacent to the return flow path part 320 .

In addition, the plant cultivation unit 200 may include a first plant cultivation unit 210 and a second plant cultivation unit 220, and may include an n-th plant cultivation unit.

The flow path unit 300 includes a supply path unit 310 for flowing the nutrient solution from the water tank 100 to the plant cultivation unit 200 , and a regression for flowing the nutrient solution from the plant cultivation unit 200 to the water tank 100 . It may include a flow path part 320 .

When a plurality of water tanks 100 are installed, the pipe of the supply flow passage 310 and the pipe of the return flow passage 320 may be arranged to be branched in each water tank 100 .

In other words, when the standard of the plant culture unit 200 is determined, the nutrient solution can be supplied to the plant culture unit 200 only in the necessary water tank 100 among the plurality of water tanks 100 , and accordingly, the existing complex filtering The installation cost and operating cost of the facility can be reduced.

In addition, when a plurality of the plant cultivation units 200 are installed, the supply passage 310 and the return passage 320 may be installed in parallel in each of the plant cultivation units 200 .

Or, for example, when the first plant cultivation unit 210 and the second plant cultivation unit 220 are disposed, the supply passage 310 is disposed on one side of the first plant cultivation unit 210 and , the return flow path part 320 is disposed on one side of the second plant cultivation unit 220, and one end and the other end are at the other side of each of the first plant cultivation unit 210 and the second plant cultivation unit 220 It may further include a connected circulation passage unit 330 .

That is, the plurality of plant cultivation units 200 may be installed in series, and in this case, the nutrients of the flowing nutrient solution may be lost, and it may be determined within the limit that does not affect the growth of the plant.

The sensor unit 400 may be disposed in the supply flow path unit 310 or the return flow path unit 320 , and may include a first sensor 410 and a second sensor 420 .

The first sensor 410 may be disposed in the supply passage 310 and may measure ammonia, nitrite, or nitrate in the flowing nutrient solution.

The second sensor 420 may be disposed in the supply passage 310 and may measure the amount of dissolved oxygen in the nutrient solution.

The driving unit 500 may include a feeder 510 , a driving pump 520 , an air pump 530 , and a shut-off valve 540 , and the driving unit 500 is detected by the sensor unit 400 . It can be controlled according to the state.

The feeder 510 may be installed in the water tank 100 to supply fish feed.

The feeder 510 increases the amount of feed supplied to the water tank 100 when the ammonia level measured by the first sensor 410 is less than or equal to a preset numerical range, and increases the amount of feed supplied to the water tank 100 when the ammonia level measured by the first sensor 410 is greater than or equal to the preset numerical range. 100) can be controlled to reduce the amount of feed to be supplied.

For example, when the fish in the water tank 100 is ingested, the nutrient solution supplied to the supply passage 310 is easily decomposed by microorganisms (aerobic bacteria, etc.) when the digestion is good, so that the water tank 100 is supplied The size of the feed may be provided with a diameter of 3 mm or less.

For example, the preset level of ammonia may be 2 ppm to 4 ppm.

Also, when the first sensor 410 senses nitrite, the preset level of nitrite may be 5 ppm or less.

Also, when the first sensor 410 senses nitrate, the preset level of nitrate may be 20 ppm or less.

Since the feeder 510 controls the condition of the nutrient solution supplied to the supply passage 310, it is possible to cultivate hydroponics without the installation of additional equipment such as a gas remover, a filter, and a solid filter, so the initial installation cost and maintenance and repair costs can be reduced.

The drive pump 520 may be installed in the supply passage 310 or the return passage 320 for the flow of the nutrient solution.

The air pump 530 may be disposed in the supply passage 310 , and when the value of the dissolved oxygen amount measured by the second sensor 420 is smaller than a preset value, the air pump 530 is driven can be

When dissolved oxygen decreases, fish and shellfish die and aerobic microorganisms stop proliferation or physiological action.

Therefore, the pH of the nutrient solution is controlled to be between 6.5 and 7.5 (neutral) by the air pump 530 to create an environment in which aerobic bacteria can actively work, thereby implementing excellent hydroponics.

For example, the preset amount of dissolved oxygen may be 3 ppm.

The shut-off valve 540 may be disposed in the return flow path unit 320 , and when the first sensor 410 is disposed in the return flow path unit 320 , the measured ammonia level exceeds a preset value. In this case, the shut-off valve 540 may be blocked.

Alternatively, the amount of the returned nutrient solution may be controlled by varying the degree of opening of the shut-off valve 540 according to the ammonia level measured by the first sensor 410 .

In other words, the no-filter aquaponics system according to the embodiment of the present invention determines the state of the nutrient solution provided to the supply flow path unit 310 by the sensor unit 400 to control the amount of feed by the feeder 510 or air Since the amount of dissolved oxygen is controlled by the pump 530, it is possible to enable hydroponics without the installation of additional equipment such as a gas remover, a filter, and a solid filter, so that the initial installation cost and maintenance and repair cost can be reduced.

Above, those skilled in the art from the above description will know that various changes and modifications are possible without departing from the technical spirit of the present invention. It should be determined by the scope and its equivalent scope.

100: tank 110: mesh
200: plant cultivation unit 201: cultivation plate
202: port 203: seating groove
210: first plant cultivation unit 220: second plant cultivation unit
300: flow passage 310: supply flow passage
320: return flow path unit 330: circulation flow path unit
400: sensor unit 410: first sensor
420: second sensor 500: driving unit
510: feeder 520: drive pump
530: air pump 540: shut-off valve

Claims (10)

a tank with fish inside;
A flow space through which the nutrient solution can flow is formed on the lower side, and a plant cultivation unit in which plants can be disposed on the upper side;
a supply passage for flowing the nutrient solution from the water tank to the plant cultivation unit; and
A no-filter aquaponics system comprising a; a return passage for flowing the nutrient solution from the plant cultivation unit to the water tank.
According to claim 1,
The no-filter aquaponics system further comprising a feeder installed in the water tank to supply fish feed.
3. The method of claim 2,
A first sensor for measuring ammonia in the flowing nutrient solution is disposed in the supply passage,
The feeder increases the amount of feed supplied to the water tank when the ammonia level measured by the first sensor is less than or equal to a preset numerical range, and decreases the amount of feed supplied to the tank when the ammonia level measured by the first sensor is greater than or equal to a preset numerical range. Phoenix system.
4. The method of claim 3,
The size of the feed supplied to the water tank is 3 mm or less in diameter, and the preset ammonia level is 2 ppm to 4 ppm no-filter aquaponics system.
According to claim 1,
A no-filter aquaponics system in which a drive pump for the flow of the nutrient solution is installed in the supply passage or the return passage.
According to claim 1,
The plant cultivation unit,
a rearing plate having at least one seating groove formed thereon to be spaced apart from a lower surface of the supply passage; and
A no-filter aquaponics system comprising a; port mounted in the seating groove.
7. The method of claim 6,
A no-filter aquaponics system in which the distance between the lower side of the supply passage and the rearrangement plate is 30 cm.
According to claim 1,
A second sensor for measuring the amount of dissolved oxygen in the nutrient solution and an air pump for supplying air are disposed in the supply passage,
A no-filter aquaponics system in which the air pump is driven when the value of the amount of dissolved oxygen measured by the second sensor is smaller than a preset value.
9. The method of claim 8,
A no-filter aquaponics system with a preset amount of dissolved oxygen of 3 ppm.
According to claim 1,
The plant cultivation unit includes a first plant cultivation unit and a second plant cultivation unit,
The supply passage part is disposed on one side of the first plant cultivation part,
The return flow path part is disposed on one side of the second plant cultivation part,
The no-filter aquaponics system further comprising a circulation passage having one end and the other end connected to the other side of each of the first plant culture unit and the second plant culture line.

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