KR20200129848A - Aquaponics Cultivation Apparatus - Google Patents

Abstract

The present invention relates to a crop cultivation apparatus using aquaponics. The present invention installs a plurality of pots on a cultivation bed and accommodates gravel for fixing crops in the pots when cultivating through aquaponics, and thus can achieve an effect of reducing the cost by reducing the amount of gravel used in cultivating crops through aquaponic methods.

Description

Aquaponics Cultivation Apparatus}

The present invention relates to a crop cultivation apparatus using aqua phonics.

Recently, the cultivation method of organic cultivation without the use of pesticides is in the spotlight. For this reason, aquaponics farming method, which grows crops through excrement generated while farming fish farming, is used by farms.

At present, attempts are being made to cultivate wasabi in Japan, which was entirely dependent on imports. However, wasabi is a very temperature sensitive crop, so it is very important to keep the water temperature at an appropriate temperature, especially in case of hydroponics.

Therefore, crops such as horseradish were not cultivated through aquaponics. In the case of conventional wasabi facility cultivation, it is difficult to precisely control irrigation and nutrient solution control, and because it is not possible to precisely control the growing environment, it is a situation that produces land-based wasabi leaves mainly for leaves.

An object of the present invention is to provide an aquaponics crop cultivation apparatus capable of cultivating a temperature-sensitive crop such as wasabi through organic matter generated during aquaculture.

The aquaponics cultivation apparatus according to the present invention for achieving the above object includes a fish farming tank, a bio filter tank, a cultivation bed, a cultivation pot, and a circulation pump.

The fish farming tank is a square structure with an open top to allow fish farming.

The biofilter tank receives the nutrient solution from the fish farming tank, changes the composition of the nutrient solution by bacteria cultured inside and discharges it.

The cultivation bed receives the nutrient solution discharged from the biofilter tank. The cultivation bed includes a stepped cradle so that at least some of the plurality of cultivation ports are mounted higher than other portions.

The cultivation pot is installed inside the cultivation bed, and is composed of a plurality of pieces formed to accommodate the gravel for fixing the growing crop and allow nutrient solution in the cultivation bed to flow out.

At least one hole for inflow and outflow of the nutrient solution is formed in the cultivation port. The at least one hole includes a pair of holes formed at positions opposite to each other with respect to the rearrangement port.

At least a portion of the plurality of cultivation ports includes an inlet through which the nutrient solution is introduced and an outlet through which the inflowed nutrient solution is discharged, and flows through the inlet of the cultivation ports mounted at a lower place of the nutrient solution discharged from the outlets of the cultivation ports mounted higher. do. A discharge pipe protruding outward is formed at the discharge port.

The circulation pump supplies the nutrient solution to the cultivation bed.

The present invention is installed inside the biofilter tank, and further includes a water temperature controller that controls the water temperature of the nutrient solution.

The crop includes horseradish, which is a low temperature cultivation crop of 18 degrees or less, and aquaculture may be a fish species farmed in a low temperature nutrient solution of 18 degrees or less.

According to the aquaponics crop cultivation apparatus having the structure as described above, when farming through aqua phonics, a plurality of pots are installed on the cultivation bed and the gravel for fixing the crops in the pots is accommodated. It is possible to achieve the effect of reducing the cost by reducing the amount of gravel used when cultivating crops through cultivation.

In addition, since the crops are respectively accommodated and cultivated in the cultivation pot, it is possible to achieve an effect that is easy to partially remove the crops having diseases or pests or to move them to another cultivation bed.

And, by making the cultivation bed stepwise, the pots are arranged in a stepwise fashion, and when the nutrient solution is irrigated in the highest pot, the nutrient solution is sequentially supplied to the potted plants below through the discharge passage formed in the potted plant, thereby reducing the size of the circulation pump. Can achieve.

In addition, through aquaculture that can be farmed at low temperatures, crops that need to be hydroponically cultivated at low temperatures, such as horseradish, can be cultivated through the Yakuaponics farming method.

1 is a view showing an aquaponics crop cultivation apparatus according to an embodiment of the present invention.
Figure 2 is a view showing the top of the aquaponics crop cultivation apparatus according to an embodiment of the present invention.
3 is an AA cross-sectional view of FIG. 2.
4 is a view showing an aqua phonics cultivation apparatus according to another embodiment of the present invention.
5 is a view showing the upper portion of the aqua phonics cultivation apparatus according to another embodiment of the present invention.
6 is a cross-sectional view taken along BB of FIG. 5.

Hereinafter, an aquaponics crop cultivation apparatus according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

The aquaponics cultivation apparatus according to the present invention includes a fish farming tank 100, a bio filter tank 110, a cultivation bed 120, a cultivation port 130, and a circulation pump 140.

The fish farming tank 100 has a rectangular structure with an open top so that fish farming can be cultured. Several fish (not shown) are raised in the fish farming tank 100, and the fish may be a fish species farmed in a low temperature nutrient solution of 18 degrees or less. In this embodiment, the fish farming may be at least one of trout and carp.

The bio filter tank 110 has a rectangular box shape with an open top surface. The biofilter tank 110 converts ammonia contained in the nutrient solution into nitrate by bacteria cultured inside the biofilter tank 110 before being supplied to the cultivation bed 120 by receiving the nutrient solution from the fish farming tank 100. Play a role. A medium (not shown) made of a plastic material is accommodated in the biofilter tank 110. The medium may be composed of a plurality. Bacteria live in the medium and are cultured by oxygen supplied into the biofilter tank 110. Oxygen is oxygen contained in the air, and air is supplied by an air pump 240 to be described later.

A connection pipe 150 is formed between the biofilter tank 110 and the fish farming tank 100, and the connection pipe 150 is installed at the top. The connection pipe 150 connects the upper portion of the biofilter tank 110 and the fish farming tank 100, so that even if the bio filter tank 110 is broken or the connection of the pipe is poor and water leaks, the fish farming tank 100 ), because the water level can be kept constant, it is possible to prevent the death of fish farming due to leakage.

The cultivation bed 120 receives a nutrient solution from the bio filter tank 110. The cultivation bed 120 is formed with a width greater than the vertical width as shown in FIGS. 1 to 6 and the upper surface is opened, and the frame 160 is formed on the upper side and a wall made of a transparent material on the frame 160 (Not shown on the drawing) can be installed. Therefore, the cultivation bed 120 may have a closed structure like a cultivation chamber such as a greenhouse.

In the case of the cultivation bed 120 having a closed structure, it can be constructed as a semi-automated facility using a pedestal (not shown), etc. so that the worker can efficiently manage/harvest/inject crops.

Two light-shielding films (not shown in the drawings) having a light-shielding effect of 70% and 90% are disposed on the upper skylight of the frame 160 and can be controlled so as not to be affected by light heat.

Additionally, an imaging unit camera (not shown) may be additionally installed on the frame 160 to check the growth of wasabi and the state of the root zone.

The cultivation port 130 is installed inside the cultivation bed 120, and includes a plurality of pebbles 270 for fixing the growing crops therein so that the nutrient solution in the cultivation bed 120 can flow out. In the present embodiment, the crop may be wasabi, which is a crop grown at a low temperature of 18 degrees or less, and hereinafter, wasabi among crops that can be cultivated in an aquaponics crop cultivation apparatus will be described as an example.

At least one hole 170 for inflow and outflow of the nutrient solution is formed in the regrowth port 130. The at least one hole 170 includes a pair of holes 170 formed at positions opposite to each other with respect to the rearrangement port 130. In the present embodiment, a plurality of holes 170 may be formed on the side of the cultivation port 130, and in another embodiment, the cultivation port 130 may be formed of a mesh (net). In this embodiment, the nutrient solution circulates through the cultivation bed 120 and the cultivation port 130 is immersed in the circulated nutrient solution. In this case, the wasabi is fixed by the gravel 270 contained in the cultivation port 130, and since the hole 170 is formed on the side of the cultivation port 130 or made of a mesh, the nutrient solution flows into the cultivation port 130 and It is discharged.

The cultivation method of the above method has a different effect from the method of growing crops by spreading the gravel 270 on the cultivation bed 120. When wasabi is grown in the cultivation pot 130, it is easy to remove the wasabi, which is a problem. It works.

When wasabi is cultivated by laying the gravel 270 on the cultivation bed 120, when there is a problem (such as a disease or pest) in the wasabi and the crop needs to be removed, the gravel 270 should be dug up and the wasabi removed. In this case, in the process of digging the gravel 270, other wasabi may be damaged, and problems such as poor marketability may occur. However, by using the cultivation pot 130, the amount of gravel 270 to be used can be reduced, and when the wasabi is removed from the cultivation bed 120, only the cultivation pot 130 is taken out to easily remove the wasabi in question from the cultivation bed 120. Because it can be removed, it will not damage other crops during the removal process.

Next, a process of circulating nutrient solution in the aquaponics crop cultivation apparatus will be described with reference to FIG. 2. Aquaponics crop cultivation apparatus is connected to the aquaculture tank 100 and the biofilter tank 110 through a connection pipe 150, and the supply pipe 190 is the lower portion of the biofilter tank 110 and the circulation pump 140 It is connected to the inlet 200 of. The filter 250 is installed in the supply pipe 190, and the cultivation bed 120 is connected to the fish farming tank 100 through the recovery pipe 260.

When the circulation pump 140 is operated, the aqua phonics crop cultivation apparatus moves the nutrient solution in the bio filter tank 110 to the cultivation bed 120 through the supply pipe 190. In addition, as the nutrient solution flows from the cultivation bed 120 to the inside of the cultivation port 130 and moves in the direction of the arrow, it contacts the crops grown in the cultivation port 130.

The nutrient solution moved from one end of the cultivation bed 120 to the other end flows back into the aquaculture tank 100 through the recovery pipe 260. The recovery pipe 260 is connected to the lower portion of the fish farming tank 100. As the nutrient solution introduced from the cultivation bed 120 flows into the fish farming tank 100, the water level of the fish farming tank 100 rises, and when the water level is above a certain level, the nutrient solution is discharged through the connection pipe 150 as mentioned above. The nutrient solution introduced and introduced into the biofilter tank 110 is again introduced into the cultivation bed 120 through the circulation pump 140 and the filter 250, and the above-described circulation process is repeated.

In another embodiment, the cultivation bed includes a stepped cradle 180 such that at least some of the plurality of cultivation ports 130 are mounted higher than other portions. In addition, a distribution pipe 191 may be installed on the top of the cultivation bed so that the nutrient solution flows downward from the top of the cultivation bed. The distribution pipe 191 is installed on the top of the stepped cradle 180 to supply the nutrient solution to the inlet 200 of the cultivation port 130 installed at the highest position. The distribution pipe 191 is connected to the supply pipe 190.

The inlet 200 includes an open upper surface of the cultivation port 130. As in this embodiment, the stepped cradle 180 may have a pyramid shape having a high center.

At least a part of the plurality of cultivation ports 130 installed on the stepped cradle 180 includes an inlet 200 through which nutrient solution is introduced and an outlet 210 through which the introduced nutrient solution is discharged, and a higher cultivation port ( The nutrient solution discharged from the outlet 210 of 130 is introduced through the inlet 200 of the cultivation ports 130 mounted at a low place. A discharge pipe 220 protruding outward is formed at the discharge port 210. The plurality of cultivation ports 130 are arranged in a stepwise manner on the stepped cradle 180.

Next, a process of circulating nutrient solution in the aquaponics crop cultivation apparatus of another embodiment will be described with reference to FIGS. 5 and 6. Referring to FIG. 6, when the nutrient solution is supplied to the first cultivation port 130 at the top, the nutrient solution rises to a certain level and reaches the location where the outlet 210 is formed. Supply nutrient solution to (200). Like the first cultivation port 130, the second cultivation port 130 also supplies the nutrient solution to the upper inlet 200 of the third cultivation port 130 through the discharge pipe 220 when the nutrient solution rises above a certain level. do. The discharge port 210 and the discharge pipe 220 may be formed in the lowermost cultivation port 130 in the same way as the first or second cultivation port 130, but in this embodiment, only the discharge port 210 is formed for space utilization. Can be. In addition, the re-establishment port 130 made of a mesh may be used, like the re-establishment port 130 mentioned above.

In this embodiment, the stepped cradle 180 is configured in three stages, but the number of stages may be increased or decreased according to the size of the cultivation bed 120 or the size of the cultivation port 130.

The circulation pump 140 supplies the nutrient solution to the cultivation bed 120. The circulation pump 140 is controlled to continuously circulate so that the nutrient solution does not accumulate in the cultivation bed 120 in this embodiment, and according to the embodiment, the circulation pump 140 repeats operation and stop to reduce electricity consumption. The nutrient solution can be circulated while being controlled as possible.

In addition, in the present invention, an air pump 240 for supplying oxygen to fish farming may be installed. The air pump 240 serves to increase the oxygen concentration in the nutrient solution by supplying air to the fish farming tank 100 and the bio filter tank 110.

The present invention is installed inside the fish farming tank, and further includes a water temperature controller 280 for adjusting the water temperature of the nutrient solution. In this case, if aquaculture is a temperature sensitive fish, it may be directly installed in the aquaculture tank 100 for fine water temperature control. The water temperature controller 280 is connected to the control unit 230.

According to an embodiment, the water temperature controller 280 is installed inside the biofilter tank 110 and may adjust the water temperature of the nutrient solution.

The aquaponics crop cultivation apparatus includes a control unit 230, and the wasabi production control through the control unit 230 serves to help the wasabi to be planted and grown in a hydroponic state.

The control unit 230 includes atmospheric environment control, irrigation environment control, and sensor control.

Atmospheric environment control can be connected to air conditioners, chillers, boilers, etc. to increase or decrease the atmosphere suitable for the wasabi growing environment. The air conditioning unit (not shown) is in contact with the air circulation unit, and the air circulation unit creates a flow so that the air inside the cultivation bed can be continuously rotated. When such a flow occurs, the atmospheric environment can be precisely controlled by contacting the heating and cooling unit.

The irrigation environment control precisely controls the flow rate/flow rate/temperature/saturated oxygen level suitable for wasabi cultivation by incorporating a heat source device such as a chiller or a boiler and a circulation pump 140. In hydroponic wasabi cultivation, an environment with a flow rate of 15 cm/sec or more, a flow rate of 0.6 L/sec or more, and an illuminance of 10000 lux or less is implemented so that the roots can be harvested.

The sensor control determines whether or not to operate the atmosphere and irrigation environment by acquiring the temperature and humidity inside the cultivation bed 120 and various environmental sensor information values. By adjusting the control values of various environmental parts by the acquired sensor values, an environment suitable for hydroponic wasabi is realized. At least one of temperature, humidity, carbon dioxide, amount of light, amount of saturated oxygen, EC and DO may be measured through the sensor.

100: fish farming tank
110: bio filter tank
120: cultivation bed
130: re-port
140: circulation pump
150: connection pipe
160: frame
170: hall
180: step mount
190: supply pipe
191: distribution pipe
200: inlet
210: outlet
220: discharge pipe
230: control unit
240: air pump
250: filter
260: recovery pipe
270: gravel
280: water temperature controller

Claims (8)

Aquaculture tanks for aquaculture;
A biofilter tank that receives the nutrient solution from the fish farming tank and changes the components of the nutrient solution by bacteria cultivated therein;
A cultivation bed receiving the nutrient solution discharged from the biofilter tank;
A plurality of cultivation ports installed inside the cultivation bed, receiving gravel for fixing growing crops therein, and allowing nutrient solution in the cultivation bed to flow out; And
Circulation pump supplying the nutrient solution to the cultivation bed
Aqua phonics cultivation apparatus comprising a. The method of claim 1,
Aquaphonics cultivation apparatus, characterized in that at least one hole is formed in the cultivation port for inflow and outflow of the nutrient solution. The method of claim 2,
The at least one hole is an aqua phonics cultivation apparatus including a pair of holes formed at opposite positions with respect to the cultivation port. The method of claim 1,
The cultivation bed is an aqua phonics cultivation apparatus, characterized in that it comprises a stepped cradle so that at least a portion of the plurality of cultivation ports are mounted higher than other portions. The method of claim 4,
At least a part of the plurality of cultivation ports includes an inlet through which the nutrient solution is introduced and an outlet through which the introduced nutrient solution is discharged, Aqua phonics cultivation device introduced through the inlet. The method of claim 5,
Aqua phonics cultivation apparatus, characterized in that the discharge pipe is formed in the discharge port protruding outward. The method according to any one of claims 1 to 6,
The crop contains wasabi, which is a low-temperature cultivation crop of 18 degrees or less,
Aqua phonics cultivation apparatus, characterized in that the fish farmed in a low temperature nutrient solution of 18 degrees or less. The method of claim 7,
An aqua phonics cultivation apparatus, which is installed inside the bio-filter tank and further comprises a water temperature controller that adjusts the water temperature of the nutrient solution.

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