KR20190040570A - Aquaponics system - Google Patents

Abstract

The present invention provides an aquaponics system comprising a water tank in which fish are inhabited; a plant growing unit in which a flow space, through which nutrient solution flows, can be formed on the lower side and a plant can be arranged on the upper side; a supply passage unit through which the nutrient solution flows from the water tank to the plant growing unit; and a return passage unit for flowing the nutrient solution from the plant growing unit into the water tank.

Description

AQUA PHONICS SYSTEM {AQUAPONICS SYSTEM}

The present invention relates to an improved aquaponics system.

Recently, aquaponix has become a popular spot for hydroponic cultivation.

Aqua phonics is a hydroponic cultivation method in which water contained in a fish tank is dissolved or water containing excreta is used as a nutrient solution.

As a hydroponic cultivation using such aqua phonix, there is a registered patent No. 10-1370075 (title of the invention: a plant cultivation system and a cultivation method thereof).

In the prior art, the nutrient solution supplied from the water tank 100 is firstly passed through a filter 200, passed through a solid filter 300, then fed to a plant cultivation apparatus 400, And a system in which the nutrient solution is recovered and supplied to the water tank 100 is placed.

However, such a conventional aqua phonix system has a disadvantage in that it takes a lot of procedure and time to once supply the nutrient solution to plants, and it is difficult to plan a large amount of hydroponic cultivation.

In addition, the conventional aquaponix system has the problem that the fish can be killed according to the condition of the recovered nutrient solution because the nutrient solution is recovered without any procedure and supplied again to the water tank.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an aqua plant which can control a nutrient solution circulating between a water tank and a plant growing unit, To provide a Knicks system.

In order to achieve the above object, the present invention provides a water tank in which a fish is inhabited; A plant growing section in which a flow space in which a nutrient solution flows can be formed on the lower side and a plant can be arranged on the upper side; A supply passage portion for flowing the nutrient solution from the water tank to the plant growing portion; And a return flow path for flowing the nutrient solution from the plant growing section to the water tank.

Further, it may further comprise a mesh provided on the upper side of the water tank to prevent the fish from escaping.

Further, a plurality of the water tanks may be disposed, and the piping of the supply passage portion and the return passage portion may be branched and disposed in the respective tanks.

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

In addition, the water tank may have a polyhedron in which the inside is empty and at least one side has a plurality of blocking holes, and the supply passage portion or the return passage portion may be disposed so as to communicate with the inside of the polyhedron.

In addition, the plant growing section may include a cultivating plate having at least one seating groove formed therein; And a port positioned in the seating groove.

Also, the plant regulating section may be arranged such that a plurality of the reed plates are sequentially disposed, and a reed plate on which germinated plants or pots with seeds for germination are placed is adjacent to the regeneration flow path portion.

The plant growing section includes a first plant growing section and a second plant growing section. The supply flow path section is disposed on one side of the first plant growing section, the return flow path section is disposed on one side of the second plant growing section, And a circulation channel part having one end and the other end connected to the other side of each of the first plant growing part and the second plant growing part.

The regeneration flow path portion further includes a first sensor for measuring ammonia in the nutrient solution and a shutoff valve for shutting off the flow path, and when the value of ammonia measured by the first sensor exceeds a predetermined value, Can be blocked.

The return flow path portion may further include a second sensor for measuring the amount of dissolved oxygen in the nutrient solution and an air pump for supplying air. When the value of the dissolved oxygen amount measured by the second sensor does not reach a preset value The air pump can be driven.

In the present invention, the amount of dissolved oxygen or ammonia concentration in the nutrient solution which is circulated through the plant growing section and is recovered can be measured by measuring the circulation rate or circulation amount of the nutrient solution, So that mass production of plants and death of fish can be prevented.

1 is a schematic diagram of an aquaponics system according to an embodiment of the present invention.
2 is an enlarged view of a water tank and a polyhedron according to an embodiment of the present invention;
3 is a schematic side cross-sectional view of a plant growing section 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 defined otherwise, all terms used herein are the same as the generic meanings of the terms understood by those of ordinary skill in the art, and where the terms used herein contradict the general meaning of the term, they shall be as defined herein.

It is to be understood, however, that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Fig. 1 is a schematic diagram of an aquaponics system according to an embodiment of the present invention. Fig. 2 is an enlarged view of a water tank and a polyhedron according to an embodiment of the present invention. Fig. 3 is a schematic view of a plant grower according to an embodiment of the present invention Fig.

1 to 3, an aquaponix system according to an embodiment of the present invention may include a water tank 100, a plant growing unit 200, and a flow path unit 300.

The water tub 100 is shaped like an open top so that fish can be inhabited therein, and a plurality of water can be arranged.

It is preferable that the fish cultured in the water tank 100 is selected to be relatively insensitive to ammonia or dissolved oxygen.

Also, although the water tank 100 is sufficiently sized to accommodate a plurality of fishes, a plurality of water tanks 100 may be disposed for supplying a large amount of nutrients.

In addition, two plant growing units 200 to be described later can be connected to each of the water tanks 100, and the water tank 100 can be independently used to prevent culling of various kinds of fishes, .

The apparatus may further include a mesh 110 installed at an upper side of the water tank 100 to prevent fish from escaping from the water tank 100 to prevent the fish from escaping from the water.

In order to prevent the fish from escaping and to prevent solid foreign matter from flowing into the supply channel unit 310, the water tank 100 is provided with a plurality of holes 121, (120) may be disposed.

The polyhedron 120 may include a first hole 122 through which the supply passage 310 may be disposed and a second hole through which the return flow passage 320 may be disposed, 123 may be formed.

In the plant growing unit 200, a fluid space through which the nutrient solution flows can be formed on the lower side, and plants can be arranged on the upper side.

More specifically, the plant growing unit 200 includes a reed plate 201 in which at least one landing groove 203 is formed, and a port 202 in which the plants are planted in the landing groove 203 .

The pot 202 may be formed of a mixture of vermiculite and coconut fiber in an amount of about 4: 6 without using an external soil.

The larger the number of the seating grooves 203 and the ports 202, the larger the number of plants can be produced. However, if the seating grooves 203 and the ports 202 are too large, the plants may be dense and the productivity may be deteriorated.

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

The repositioning plate 201 having a size of 1200 mm x 600 mm may have approximately 30 to 40 seating grooves 203. The repositioning plate 201 having a size of 600 mm x 600 mm may have approximately 50 to 60 seats Grooves 203 may be formed, and the ports 202 may be positioned in the seating grooves 203, respectively.

Ammonia contained in the nutrient solution supplied from the water tank 100 can be used as nutrients of plants by sequentially changing nitrite to nitrate. Bacteria inhabiting the root of the plant in the port 202 have such a role can do.

Therefore, in the plant growing unit 200, a plurality of the reed plates 201 may be sequentially arranged. In this case, the plants having roots grown adjacent to the supply path unit 310 are arranged, Or a regrowth plate 201 on which a port 202 for planting seeds for germination is placed may be disposed adjacent to the return flow path portion 320.

The plant growing unit 200 may include a first plant growing unit 210 and a second plant growing unit 220, and may include an nth plant growing unit.

The flow channel unit 300 includes a supply channel unit 310 for flowing the nutrient solution from the water tank 100 to the plant growing unit 200 and a return flow unit 310 for flowing the nutrient solution from the plant growing unit 200 into the water tank 100. [ And may include a flow path portion 320.

When a plurality of the water tanks 100 are provided, the piping of the supply passage portion 310 and the return passage portion 320 may be branched to the respective tanks 100.

In addition, a drive pump 311 may be installed in the supply passage 310 or the return passage 320 for flowing the nutrient solution.

Since the nutrient solution flowing through the driving pump 311 does not contain fish or solid foreign matter by the polyhedron 120, the nutrient solution can be directly supplied to the plant growing unit 200 without any complicated procedure .

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

When the polyhedron 120 is installed in the water tank 100, the supply passage 310 or the return flow passage 320 may be arranged to communicate with the inside of the polyhedron 120.

Specifically, the supply passage portion 310 may be disposed in the first hole 122 of the polyhedron 120, and the return flow passage portion 320 may be disposed in the second hole 123 of the polyhedron 120 .

When a plurality of plant growing units 200 are installed, the supply channel unit 310 and the return channel unit 320 may be installed in parallel in each plant growing unit 200.

Alternatively, for example, when the first plant growing unit 210 and the second plant growing unit 220 are disposed, the supply path unit 310 is disposed on one side of the first plant growing unit 210 The return flow path portion 320 is disposed on one side of the second plant growing portion 220 and one end and the other end of the second plant growing portion 220 are disposed on the other side of the first plant growing portion 210 and the second plant growing portion 220, And may further include a circulation channel unit 330 connected thereto.

That is, the plurality of plant growing units 200 can be installed in series, and in this case, the nutrients in the nutrient solution are lost and can be determined within a range that does not affect the development of the plant.

In addition, the return flow path unit 320 may include a technical idea for controlling the condition of the nutrient solution to be returned to the water tank 100 to protect the fish in the water tank 100.

The return flow path portion 320 further includes a first sensor 321 for measuring ammonia in the nutrient solution and a shutoff valve 322 for shutting off the flow path, The shutoff valve 322 may be shut off if the ammonia level exceeds a predetermined value.

Alternatively, depending on the ammonia level measured by the first sensor 321, the amount of the nutrient solution returned by varying the degree of opening of the shutoff valve 322 may be controlled.

As another example, the return flow path portion 320 further includes a second sensor 323 for measuring the amount of dissolved oxygen in the nutrient solution, and an air pump 324 for supplying air, wherein the second sensor 323 measures The air pump 324 can be driven when the value of the dissolved oxygen amount does not reach the predetermined value.

Also, the amount of dissolved oxygen can be controlled by varying the driving degree of the air pump 324 according to the dissolved oxygen amount measured by the second sensor 323.

That is, the aquaponix system according to the embodiment of the present invention can supply the nutrient solution to the plant growing unit 200 in a large amount, and can control the condition of the nutrient solution returned to the water tank 100 to protect the fish in the water tank 100 By doing so, it is possible to achieve two advantages, both in terms of water quality and mass production.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined by the appended claims. Range and its equivalent range.

100: water tank 110: mesh
120: Polyhedron 121: Blocking ball
122: first hole 123: second hole
200: Plant growing section 201: Cultivating plate
202: port 203: seat groove
210: first plant growing section 220: second plant growing section
300: channel portion 310: supply channel portion
311: drive pump 320: return flow path
321: first sensor 322: shut-off valve
323: second sensor 324: air pump
330: circulation flow portion

Claims (10)

A water tank in which fish are inhabited;
A plant growing section in which a flow space in which a nutrient solution flows can be formed on the lower side and a plant can be arranged on the upper side;
A supply passage portion for flowing the nutrient solution from the water tank to the plant growing portion; And
And a return flow path for flowing the nutrient solution from the plant growing section to the water tank.
The method according to claim 1,
And a mesh provided on the upper side of the water tank to prevent the fish from escaping.
The method according to claim 1,
A plurality of water tanks are arranged,
Wherein the pipe of the supply passage portion and the pipe of the return passage portion are branched from each other in the respective water tanks.
The method according to claim 1,
And a drive pump for flowing the nutrient solution is installed in the supply passage portion or the return passage portion.
The method according to claim 1,
The water tank is provided with a polyhedron in which the inside is empty and at least one side of which is formed with a plurality of blocking holes,
And the supply passage portion or the return passage portion is disposed in communication with the inside of the polyhedron.
The method according to claim 1,
The plant grower includes:
At least one of which is formed with a seating groove; And
And a port positioned in the seating groove.
The method according to claim 6,
Wherein the plurality of reed plates are sequentially arranged in the plant regulating part,
And a reed plate on which a germinated plant or a seed planted with seeds for germination is placed is arranged adjacent to the return flow path portion.
The method according to claim 1,
The plant growing section includes a first plant growing section and a second plant growing section,
Wherein the supply flow path portion is disposed on one side of the first plant growing portion,
Wherein the return flow path portion is disposed on one side of the second plant growing portion,
Further comprising a circulation channel part having one end and the other end connected to the other side of each of the first plant growing part and the second plant growing part.
The method according to claim 1,
Wherein the return flow path portion further comprises a first sensor for measuring ammonia in the nutrient solution, and a shutoff valve for shutting off the flow path,
Wherein the shutoff valve is shut off when the value of ammonia measured by the first sensor exceeds a predetermined value.
The method according to claim 1,
Wherein the return flow path portion further comprises a second sensor for measuring dissolved oxygen amount in the nutrient solution, and an air pump for supplying air,
Wherein the air pump is driven when the value of the dissolved oxygen amount measured by the second sensor does not reach a predetermined value.

Images