KR20200014073A - A crop cultivation apparatus having aquarium - Google Patents

Abstract

Disclosed is a crop cultivation apparatus equipped with an aquarium. The crop cultivation apparatus equipped with an aquarium comprises: a water tank for fish inhabitation; and a plurality of cultivation modules disposed under the water tank and cultivating crops by using water introduced from the water tank as a culture medium, wherein water passed through the plurality of cultivation modules can be re-introduced into the water tank and used for fish inhabitation. The present invention can minimize power consumption required for apparatus operation.

Description

Crop cultivation unit equipped with an aquarium {A CROP CULTIVATION APPARATUS HAVING AQUARIUM}

The present invention relates to a crop cultivation apparatus equipped with an aquarium, and more particularly to a cabinet-type crop cultivation apparatus equipped with an aquarium and a crop cultivation module.

It takes weeks to many months in the global market and days to weeks in the domestic market for crops to reach consumers on the farm. As long as the distribution process is long, it is difficult to ensure that safe and fresh food is provided to consumers.

Consumers also eat vegetables and fruits grown by various chemical methods, which cause long-term health issues.

To solve this problem, crops can be grown directly in the home.

However, securing space for crop cultivation in modern societies is not easy. It is difficult to find unpaved land and the interior space itself is narrow as the residential environment is favored by apartments.

Crop cultivation techniques also exist in the home. Hydroponics, aquaponics, aeroponics, fogponics and the like are typical.

Hydrophonic is a method in which crops are grown in a culture medium in which the essential elements necessary for growing a crop without soil are dissolved at an appropriate concentration according to the absorption ratio. Hydrophonic, also called nutrient farming and hydroponic farming, can essentially eliminate the environment where weeds and pests can grow without soil. This method is commonly used to grow herbs and flowers.

Aquaponic is a cultivation method that combines an aquarium with this hydrophonic. Aquaphonic is based on the natural cycle. The waste that the fish emits serves as nutrition for the growing plant, and the plant provides a natural filter of the water in which the fish live. There are many DIY designs as they are the most popular.

The next step in Aquaphonic is Aerophonic. Aerophonic is cultivated by hanging crops and spraying water and nutrients onto the roots. Also known as spray cultivation method. Aerophonic is widely used to grow legumes. Suspending in the air can supply oxygen to the roots enough to solve the problem that the lack of oxygen in the root portion submerged in water, which is a disadvantage of aquaphonic is not properly supplied with nutrients. Therefore, it is faster to grow crops than other cultivation methods, and fruit can be produced in large quantities. The tank does not need to contain water, so it can be grown with only a small amount of sap and nutrients.

However, it requires a lot of initial facility costs because it must spray water and nutrients at high pressure. The roots are always exposed to the air, so it is difficult to control the root temperature as the external temperature changes frequently. There is also a significant cost and effort to repair when the nozzles that spray water and nutrients become clogged.

Fogphonic is the newest technology and uses steamed nutrients to deliver nutrients and oxygen to suspended plant roots. It is also a type of hydroponic cultivation, unlike the hydroponics of the immersion method and the aerophonic of the spray method, using a mist mist. Using an ultrasonic mist generator, the nutrient solution is vaporized into particles on the order of several micrometers and supplied to the plant.

The existing technologies described above are configured separately and have disadvantages in terms of various costs and time for operating separately.

Although Aquaphonic pursues operational efficiency in that it combines aquarium and hydroponic cultivation, it is still not integrated with other cultivation techniques, and research to integrate the cultivation techniques is very insufficient.

The inventor of the present invention has completed the present invention after a long research and trial and error to solve these problems.

An embodiment of the present invention provides a cabinet-type crop cultivation apparatus integrated with the aquarium and various crop cultivation methods.

On the other hand, other unspecified objects of the present invention will be further considered within the range that can be easily inferred from the following detailed description and effects.

Crop cultivation apparatus equipped with an aquarium according to an embodiment of the present invention, the tank for fish habitat; And a plurality of cultivation modules disposed under the tank, wherein the plurality of cultivation modules cultivate crops using the water introduced from the tank as a culture medium, wherein the water passing through the plural cultivation modules is reintroduced into the tank to form a fish. Can be used.

The plurality of cultivation modules may include two or more of a vertical farming cultivation module, an aerophonic cultivation module, a fogphonic cultivation module, and a hydrophonic cultivation module.

A first outflow line connecting the tank and a first cultivation module disposed below the tank of the plurality of cultivation modules to transfer water therebetween; A second outflow line connecting the water tank and a second cultivation module disposed directly below the first cultivation module among the plurality of cultivation modules to transfer water therebetween; And a circulation line connecting the first to second cultivation modules and the water tank to transfer water therebetween.

A circulation unit disposed directly below the second cultivation module, wherein the circulation line comprises: a first circulation line connecting the first cultivation module and the circulation unit to transfer water therebetween; A second circulation line connecting the second cultivation module and the circulation unit to transfer water therebetween; And a third circulation line connecting the circulation unit and the water tank to transfer water therebetween.

The circulation unit may further include a pump for introducing water passed through the plurality of cultivation modules into the water tank.

The pump may be disposed on the circulation line.

An inflow line for receiving water from the outside; further comprising, the pump may introduce the water introduced from the inlet line with the water passed through the plurality of cultivation module to the water tank.

Further comprising a sensing unit for detecting the water level of the water tank, if the detection result is less than the reference value may be introduced from the outside through the inlet line in accordance with the opening and closing of the valve disposed in the inlet line.

A first outflow line connecting the tank and a first cultivation module disposed below the tank of the plurality of cultivation modules to transfer water therebetween; A second outflow line connecting the water tank and a second cultivation module disposed directly below the first cultivation module among the plurality of cultivation modules to transfer water therebetween; A third outflow line connecting the water tank and a third cultivation module disposed directly below the second cultivation module of the plurality of cultivation modules to transfer water therebetween; And a circulation line connecting the first to third cultivation modules and the water tank to transfer water therebetween.

The present technology may provide a cabinet-type crop cultivation apparatus in which an aquarium and various crop cultivation methods are integrated.

In addition, the technology can provide an optimal design that can combine several cultivation methods in one aquarium.

In addition, the technology can minimize the power consumption required to operate the device.

1 is a view showing a schematic state in which a crop cultivation apparatus equipped with an aquarium according to an embodiment of the present invention is operated.
2 is a view showing a detailed configuration of a crop cultivation apparatus equipped with an aquarium according to an embodiment of the present invention.
FIG. 3A is a left side view of FIG. 2, and FIG. 3B is a view showing a right side view of FIG. 2 based on a connection relationship between cultivation modules and lines, respectively.
4 is an enlarged view of a portion A of FIG. 2 and illustrates in detail a connection relationship between the cultivation modules and the outlet lines.
5 is a view showing a detailed configuration of a crop cultivation apparatus equipped with an aquarium according to another embodiment of the present invention.
6 is a view showing a detailed configuration of a crop cultivation apparatus equipped with an aquarium according to another embodiment of the present invention.
The accompanying drawings show that they are illustrated as a reference for understanding of the technical idea of the present invention, thereby not limiting the scope of the present invention.

In the following, the most preferred embodiment of the present invention is described. In the drawings, thickness and spacing are expressed for convenience of description and may be exaggerated compared to actual physical thickness. In describing the present invention, well-known structures irrelevant to the gist of the present invention may be omitted. In adding reference numerals to the components of each drawing, it should be noted that the same components as much as possible, even if displayed on different drawings.

Figure 1 shows a schematic state in which the crop cultivation apparatus 100 is equipped with an aquarium according to an embodiment of the present invention.

As shown in FIG. 1, a crop cultivation apparatus 100 equipped with an aquarium (hereinafter, for convenience of description, referred to as a 'crop cultivation apparatus') is disposed at the top of the tank 110 and disposed below the tank. It includes several cultivation modules (120a, 120b, 130, 140).

In the drawing, the first cultivation modules 120a and 120b under the tank, the second cultivation module 130 and the third cultivation module 140 are disposed under the first cultivation modules.

Crop cultivation apparatus 100 according to an embodiment of the present invention is placed in the room to allow the user to cultivate and harvest the crop in an environmentally friendly manner. Like a refrigerator, it can be installed in the kitchen or on the veranda to provide a crop cultivation environment utilizing indoor idle space.

Thus, it is possible to make the process of reaching the consumer transparent and to provide the user with safe and fresh crops grown directly. In the past, the distribution process from the crop to the consumer can be dramatically reduced.

The tank 110 provides an environment for the habitat of fish. The tank may be an indoor aquarium.

Since the crop cultivation apparatus is placed indoors as described above, the tank 110 may be formed of a transparent material such as glass, such as an aquarium, and the fish inhabiting the inside may also be ornamental fish. The present invention is not limited to ornamental fish. And the excreta discharged by the fish in the tank serve as nutrients for cultivated crops placed under the tank.

Nutrients along with the water filled in the tank 110 is provided to the cultivated crops as a culture medium. Crops placed in the cultivation modules are grown using them.

Since the water discharged from the tank contains nutrients based on the excreta of the fish, it will be referred to as a culture solution hereinafter. That is, the culture solution is discharged from the tank and sequentially supplied to the cultivation modules disposed below it.

First, the first cultivation modules 120a and 120b disposed directly below the tank grow the crop placed therein using the culture liquid discharged from the tank.

The cultivation module 120a on the left side of the first cultivation modules may be a cultivation module of a vertical farming method. Several plants suitable for vertical farming can be grown. In the figure, although a short plant such as broccoli or sedum is shown, other plants capable of vertical farming may be grown, without being limited thereto.

Crops may be placed along the vertical pipes for introducing water from the water tank 110 to the cultivation module 120a and positioned in the cultivation module 120a. For example, a groove is formed along a vertical pipe, and the crops planted in the groove receive water and nutrients necessary for growth from a culture solution introduced into the pipe.

The cultivation module 120b on the right side of the first cultivation modules may be an aerophonic cultivation module. It is shown that legumes suitable for the aerophonic cultivation method are grown in the cultivation module 120b. However, the present invention is not limited thereto, and other plants capable of aerophonic cultivation may be grown.

Crops may be placed on a holder (not shown) and placed in the cultivation module 120b. For example, the holder is mounted at a certain height from the bottom of the cultivation module, and the crop placed on the holder is supplied with the moisture and nutrients necessary for growth from the sprayed nutrient solution in the cultivation module space with the root portion exposed to the air.

Although the first cultivation modules are referred to as a reference to 120a and 120b in total, the present invention is not limited to the number. As shown in the figure, the structure divided into two stages at the left and right may provide a space suitable for growing tall plants. In addition, the vertical long space can be secured, which is suitable for vertical farming in which crops are arranged vertically along a pipe.

Next, the second cultivation module 130 disposed below the first cultivation module grows the crop placed therein using the culture solution. The culture solution may be a culture solution introduced directly from the water bath. That is, it may be a culture solution directly introduced from the tank without passing through the first cultivation module.

The second cultivation module may be a cultivation module of the fog phonic method. Vegetables, such as lettuce suitable for the fog ponik method is shown to be grown in the second cultivation module, but is not limited to this, other plants capable of pogphonic cultivation may be grown.

The crop may be placed in a holder (not shown) and placed in the second cultivation module. For example, the holder is mounted at a certain height from the bottom of the second cultivation module, and the crop placed on the holder has the root portion exposed to the air and the moisture required for growth from the steamed nutrient solution in the second cultivation module space. You will receive nutrition.

Then, the third cultivation module 140 disposed below the second cultivation module grows the crop placed therein using the culture solution. The culture solution may be a culture solution introduced directly from the water bath. That is, it may be a culture solution directly introduced from the tank without passing through the first cultivation module or the second cultivation module.

The third cultivation module may be a hydrophonic cultivation module. Although a herb suitable for the hydrophonic method is shown to be grown in the third cultivation module, various plants capable of hydrophonic cultivation may be applied without being limited thereto.

In this case, the crop may be placed on a holder (not shown) and positioned in the third cultivation module. For example, the holder is mounted at a certain height from the bottom of the third cultivation module, and the crop placed on the holder receives the water and nutrients necessary for growth from the nutrient solution filled in the third cultivation module with the root part submerged in the culture medium. .

According to an embodiment of the present invention, the culture solution discharged from the tank disposed on the top is supplied to the first to third culture modules, respectively, while moving in the gravity direction. Then, the used culture medium is purified by the plants of the cultivation modules, and circulated back to the tank to be used for the growth of fish. The water flows back from the water tank to the cultivation modules and reintroduced into the water tank may be repeated.

If the existing aquaphonic cultivation method is limited to one cultivation method for one aquarium, the crop cultivation apparatus according to an embodiment of the present invention has a novel expansion structure in which several cultivation methods are fused to one aquarium. .

According to an embodiment of the present invention, various cultivation methods are integrated to enable the simplification of the cultivation device design and the saving of operating energy. In addition, it is installed like a refrigerator indoors and used for ornamental purposes through an aquarium and at the same time, it provides harvesting pleasure to the user through a cultivation module disposed below. Hereinafter, the connection structure between the water tank and various cultivation modules will be described in more detail with reference to FIGS. 2 to x.

2 is a view showing in more detail the configuration of the crop cultivation apparatus 100 according to an embodiment of the present invention. For convenience of description, it is shown without the fish and crop shown in FIG.

3A shows a left side view of FIG. 2, and FIG. 3B shows a right side view of FIG. 2, respectively. 3A and 3B illustrate the connection relationship between the cultivation modules and the lines.

2 and 3, the first outlet line Lo1 connecting the water tank 110 and the first cultivation module 120a on the left side, the agent connecting the water tank 110 and the second cultivation module 130 to each other. 2 outflow line Lo2, the third outflow line Lo3 connecting the tank 110 and the third cultivation module 140, and the first to third cultivation modules 120a, 120b, 130, 140 and the tank It includes a circulation line (Lc1, Lc2, Lc3, Lc4, Lc5) connecting the (110).

The crop cultivation apparatus may further include a circulation unit 150 disposed below the third cultivation module 140. Thus, the circulation lines Lc1, Lc2, Lc3, Lc4, Lc5 are circulated with the line Lc1 connecting the first cultivation module 120a and the circulation unit 150 on the left side and the first cultivation module 120b on the right side. Line (Lc2) for connecting the unit 150, the line (Lc3) for connecting the second cultivation module 130 and the circulation unit 150, the line for connecting the third cultivation module 140 and the circulation unit 150 Lc4 and a line Lc5 connecting the circulation unit 150 and the water tank 110 may be included. The first circulation line Lc1, the second circulation line Lc2, the third circulation line Lc3, the fourth circulation line Lc4, and the fifth circulation line Lc5, respectively.

For convenience of description, reference numerals 120a and 120b may be referred to as 120. Incidentally, reference numerals Lc1 to Lc5 may be referred to as Lc.

Some of the lines (Lo1, Lo2, Lo3, Lc1, Lc2, Lc3, Lc4, Lc5) are shown as being spaced apart from the bath or cultivation modules for convenience of description (e.g., Lo2, Lo3, Lc1 , Lc2, Lc3, Lc4, Lc5), but is not limited to this may be installed in a close-type or close contact with the side of the tank or cultivation modules.

Also, some of the lines are shown as being disposed on the left side of the device 100 (eg, Lo2, Lo3, Lc1), while others are shown disposed on the right side of the device 100 (eg, Lc2). , Lc3, Lc4, Lc5), but not limited thereto, the lines in the left arrangement may be arranged on the right side, and the lines in the right arrangement may be arranged on the left side.

In addition, although the first outlet line Lo1 connecting the first cultivation module 120a and the water tank 110 on the left side is illustrated as two vertical pipes, it is not limited to the number and appropriate for vertical farming of the installed scale. It may be provided in number.

In addition, the line connecting the first cultivation module 120b and the water tank 110 on the right side is not shown separately from the water tank through an injection unit S such as a screening cooler provided on the ceiling of the first cultivation module 120b. Although the culture medium is directly introduced into the first cultivation module 120b, the present invention is not limited thereto, and a pipe such as a first outlet line Lo1 may be installed in the first cultivation module 120b. For example, a horizontal pipe (not shown) is installed in the ceiling portion of the first cultivation module 120b in an embedded type or an attachment type, and the culture solution is formed from the water tank 110 through an injection unit S provided on the pipe. 1 may be introduced into the cultivation module (120b).

The first cultivation module on the left is referred to as a vertical piping method, and the first cultivation module on the right is referred to as a horizontal piping method.

Although the drawing shows that the first cultivation module includes two cultivation modules 120a of the vertical piping method on the left side and a cultivation module 120b of the horizontal piping method on the right side, the present invention is not limited thereto. May be configured of only one left method, or may be configured of only one right method.

Each line (Lo1, Lo2, Lo3, Lc1, Lc2, Lc3, Lc4, Lc5) according to an embodiment of the present invention may be configured in the form of a pipe through which the culture fluid can flow. It may be formed of a durable material that can withstand the durability of the culture and the internal pressure of the fluid. Stainless steel or plastic materials can be applied.

First, water W (ie, culture solution) is discharged from the water tank 110 to the first cultivation module 120a on the left side through the first outlet line Lo1. The outflow direction of the culture solution from the water tank 110 to the first cultivation module 120a on the left side is referred to as F1a in the drawing.

The vertical cultivation method of the first cultivation module 120a may supply the culture liquid introduced through the first outflow line to the crop through the grooves H provided on the first outflow line.

According to the exemplary embodiment of the present invention, the grooves H may be provided at regular intervals along the length direction of the first outlet line Lo1 arranged in the vertical direction. And crops are placed in the grooves H, respectively, so that the culture solution in the first outflow line can be supplied to the crops.

According to one embodiment of the present invention, a member capable of holding a culture solution such as a sponge may be provided in the first outlet line. That is, when the crop is planted with a sponge through the groove, the crop may be grown using the water absorbed by the sponge as a culture medium.

At this stage, the outflow of the culture solution may be actively performed. In other words, the culture medium filled in the tank is discharged downward by gravity along the pipe (Lo1).

Next, the culture solution from the water tank 110 is also leaked to the first cultivation module 120b on the right side. The outflow direction of the culture solution from the water tank 110 to the first cultivation module 120b is referred to as F1b in the figure.

The first cultivation module 120b of the aerophonic method sprays the culture solution introduced from the water tank 110 into the space through the injection unit S. Sprayed culture can be supplied to the crop.

Outflow of the culture solution in this step can be made manually. That is, the water filled in the tank through the injection unit (S) is injected into the space by the external force.

Thereafter, the culture solution introduced into each of the first cultivation modules 120a and 120b may be supplied to the crops and collected at the bottom, and may be re-introduced into the water tank 110 via the circulation unit 150 disposed thereunder. have.

Specifically, the culture medium filled in the bottom of the first cultivation module (120a) of the left side above the predetermined height and the culture medium filled in the bottom of the first cultivation module (120b) above the predetermined height, are disposed below them Outflow through the first circulation line (Lc1) and the second circulation line (Lc2) to the circulation unit 150, respectively, may be re-introduced into the water tank 110 by the pump (P) provided in the circulation. Each outflow direction to the circulation portion is referred to as F2a and F2b in the figure, and the reflow direction to the water tank is referred to as F3 in the figure.

Looking at the outflow process in more detail, the culture solution is discharged to the circulation unit 150 through the first circulation line (Lc1) from the first cultivation module (120a) of the left. The outflow direction is referred to as F2a in the figure.

Then, the culture solution is discharged from the first culture module 120b on the right side to the circulation unit 150 through the second circulation line Lc2. The outflow direction is referred to as F2b in the figure.

At this stage, the outflow of the culture solution may be actively performed. That is, the culture medium filled above the predetermined height in the bottom is a way that flows down itself by gravity along the pipes (Lc1, Lc2).

Therefore, the pipes Lc1 and Lc2 may be installed at an appropriate height in consideration of the level of the culture solution to be filled in the module.

For example, as shown in FIG. 4, when the level of the culture liquid to be maintained in the first cultivation module 120b is l1, the inlet port I _Lc2 of the pipe _Lc2 is installed at a position h1 corresponding to this height. Can be. For example, when the culture medium is filled only up to 3 cm from the bottom, the end of the pipe (that is, the inlet) may also be provided 3.5 cm from the bottom. The opposite end (ie the outlet) is involved in flowing the culture to the circulation, so it is sufficient if it is provided in the circulation (eg, connected to a pump). The same description can be applied to the piping Lc1 on the left side.

On the other hand, re-introduction into the bath of the culture may be done manually (power consumption). The culture solution collected from each of the cultivation modules into the circulation is collectively drawn up to the water tank by the pump.

Next, water (W) from the water tank 110 is discharged to the second cultivation module 130 through the second outlet line Lo2. The outflow direction of the culture solution from the water tank 110 to the second cultivation module 130 is referred to as F1c in the figure.

The second cultivation module 130 of the fog phonic method may vaporize the culture solution introduced through the second outflow lines Lo2 through the ultrasonic mist generator 132 provided therein. The ultrasonic mist generating unit may exist in a state of being half immersed in the culture medium filled in the second culture module. Steamed cultures are referred to by the reference V in the figures.

Thereafter, the culture fluids introduced into the second culture module 130 or the vaporized culture solution supplied to the crop may be reintroduced into the water tank 110 via the circulation unit 150 disposed thereunder.

Specifically, the culture medium which is filled to the bottom of the second cultivation module 130 to a predetermined height or more is discharged through the third circulation line (Lc3) to the circulation portion 150 disposed below, which is then provided to the circulation portion It may be re-introduced into the water tank 110 by the pump (P). The outflow direction to the circulation section is referred to as F2c in the drawing, and the reflow direction to the water tank is referred to as F3 in the drawing.

Looking at the outflow process in more detail, the culture fluid from the second culture module 130 is discharged to the circulation unit 150 through the third circulation line (Lc3). The outflow direction is referred to as F2c in the figure.

At this stage, the outflow of the culture solution can be actively performed. In other words, the culture fluid filled in the bottom of the predetermined height or more is discharged downward by gravity along the pipe (Lc3).

Therefore, the pipe Lc3 may be installed at an appropriate height in consideration of the level of the culture solution to be filled in the module.

For example, as shown in FIG. 4, when the level of the culture liquid to be maintained in the second cultivation module is l2, the inlet port I _Lc3 of the pipe Lc3 may be installed at a position h2 corresponding to the height. . For example, when the culture medium is filled only up to 5 cm from the bottom, the end of the pipe (that is, the inlet) may also be provided 5.5 cm from the bottom. The opposite end (ie the outlet) is involved in flowing the culture to the circulation, so it is sufficient if it is provided in the circulation (eg, connected to a pump).

On the other hand, re-introduction into the bath of the culture may be done manually (power consumption). The culture solution collected from each of the cultivation modules into the circulation is collectively drawn up to the water tank by the pump.

Subsequently, water W (ie, culture solution) is discharged from the water tank 110 to the third cultivation module 140 through the third outlet line Lo. The outflow direction of the culture solution from the water tank 110 to the third cultivation module 140 is referred to as F1d in the figure.

In the third cultivation module 140 of the hydrophonic method, the culture solution introduced through the third outflow line Lo3 provides water and nutrients to the internal crop in a distillation method.

Subsequently, the culture medium filled to the bottom or above a predetermined height may flow out to the circulation unit 150 disposed below it, and may be re-introduced into the water tank 110 by the pump P provided in the circulation unit. The outflow direction to the circulation section is referred to as F2d in the drawing, and the reflow direction to the water tank is referred to as F3 in the drawing.

At this stage, the outflow of the culture solution can be actively performed. In other words, the culture medium filled above the predetermined height in the bottom is a way that flows down itself by gravity along the pipe (Lc4).

Therefore, the pipe Lc4 may be installed at an appropriate height in consideration of the level of the culture solution to be filled in the module.

For example, as shown in FIG. 4, when the level of the culture solution to be maintained in the third cultivation module is l3, the inlet port I _Lc4 of the pipe Lc4 may be installed at a position h3 corresponding to the height. . For example, when the culture medium is filled only up to 6 cm from the bottom, the end of the pipe (that is, the inlet) may also be provided at a height of 6.5 cm from the bottom. The opposite end (ie the outlet) is involved in flowing the culture to the circulation, so it is sufficient if it is provided in the circulation (eg, connected to a pump).

On the other hand, re-introduction into the bath of the culture may be done manually (power consumption). Collected from each of the cultivation modules into the circulation section and then collectively pulled up to the tank by the pump.

As such, in the crop cultivation apparatus according to the embodiment of the present invention, inflowing the culture solution from the water tank to the various cultivation modules arranged below, it is sufficient that power is consumed only in the injection unit S and the pump P. . Only when the culture medium is introduced into the first cultivation module on the right and when the culture medium is pulled into the water tank from the bottom, the power required for the injection unit and the pump is consumed, and the first cultivation module, the second cultivation module, and the 3 Water flows into the cultivation module on its own by gravity. In addition, water flows into the circulation by itself.

In addition, since the tank contains a sufficient amount of water for fish breeding, the spraying unit S can spray a sufficient amount even with a small amount of power due to its own weight (horizontal pipe of the first cultivation module 120b on the right side). Consider a situation where the water is full (not shown).

In addition, since the pump P only needs to pull up the smallest amount of the culture medium after the culture medium is consumed in each of the cultivation modules, it also enables the circulation of water from the bottom to the top with less power.

On the other hand, crops grown in the cultivation modules consume the culture solution. The spent culture can be replenished by the following procedure.

According to an embodiment of the present invention, it may further include an inlet line (Li) for the introduction of fresh water into the crop cultivation device from the outside.

Inlet line (Li) may be provided in the circulation portion (150). The valve V1 may be installed in the inflow line Li.

In addition, according to an embodiment of the present invention, it may further include a detector 112 for detecting the water level of the tank (110). The sensing unit 112 may be provided in the tank 110.

When the detection unit 112 detects the water level of the tank and the detection result is lower than the reference value, the inflow line Li may be opened so that new water may be introduced into the crop cultivation apparatus 100 from the outside. The direction of inflow of fresh water is shown by In in the figure. In order to open the inlet line, the valve V1 disposed in the inlet line may be opened.

Since the valve is opened and closed using the sensing result of the sensing unit, the controller (not shown) may be involved. That is, when the control unit is connected to the sensing unit to receive the sensing result and it is determined that the predetermined reference value is not met, by opening the valve, new water can be introduced into the device from the outside through the inlet line.

For example, the amount of water flowing from the tank to the cultivation modules below is 10 ml / min, the amount of water consumed by the crops planted in the cultivation modules is 6 ml / min, and the remaining 4 ml / min of water is circulated back to the tank. When it is detected that the water level of the water tank is below the reference value, 6ml / min corresponding to the consumed amount can be replenished into the device 100 from the outside through the inlet line (Li). In this case, the sensing unit 112 and the valve V1 may be involved in the process of introducing new water.

Also, for example, when the amount of water flowing from the tank to the cultivation module below is 500 ml and the amount of water consumed by the crops planted in the cultivation modules is 200 ml, the remaining 300 ml of water is circulated back to the tank. In this case, when it is detected that the water level of the water tank is lower than the reference value, 200 ml of water corresponding to the consumed amount may be replenished into the apparatus from the outside through the inflow line.

In addition, since the controller receives the detection result of the sensing unit, when it is determined that the water level exceeds the preset reference value, the controller may close the valve so that no more water may be introduced into the device from the outside.

The above procedure can also preserve other losses, such as water losses due to evaporation.

According to the crop cultivation apparatus according to the embodiment of the present invention, it is possible to operate the entire apparatus including the tank and the various cultivation modules even with the smallest amount of circulation.

The replenishment process is also possible through the storage tank, without the inlet lines and valves described above. That is, the pump may draw water stored in the storage tank. In other words, if the above-mentioned inlet line is supplied with water from a water pipe installed in a building, water may be supplied from a storage tank capable of storing water without the water pipe.

For example, as shown in FIG. 5, a storage tank T capable of storing water in the circulation unit 150 may be provided. Then, when the water level of the water tank sensed by the detection unit 112 does not meet the reference value, new water may be introduced into the water tank from the storage tank T.

For example, the amount of water flowing from the tank to the cultivation modules below is 10 ml / min, the amount of water consumed by the crops planted in the cultivation modules is 6 ml / min, and the remaining 4 ml / min of water is circulated back to the tank. When it is detected that the water level of the water tank is below the reference value, 6ml / min of water corresponding to the consumed amount can be replenished from the storage tank (T) to the water tank (110) by the pump (P).

Also, for example, when the amount of water flowing from the tank to the cultivation module below is 500 ml and the amount of water consumed by the crops planted in the cultivation modules is 200 ml, the remaining 300 ml of water is circulated back to the tank. In this case, when it is detected that the water level of the water tank is lower than the reference value, 200 ml of water corresponding to the consumed amount may be replenished from the storage tank to the water tank by the pump.

Water in the storage tank can often be filled by the user. This structure has the advantage that it is easy to install and operate the crop cultivation device 200 in the absence of a water source such as a faucet nearby.

In addition, referring to Figure 5, the circulation unit 150 may be further provided with a battery unit (B) for supplying power to the crop cultivation apparatus. Crop cultivation apparatus may be operated by receiving power from the battery unit (B).

By providing the battery unit, the storage tank, and the pump in the circulation unit 150 disposed at the bottom, the user's ease of access and accessibility to the aquarium and the cultivation module can be improved.

In addition, as described above, since power is consumed only by the injection unit and the pump, the electric power stored in the battery unit can be sufficiently supplied with power.

6 is a view showing a detailed configuration of a crop cultivation apparatus 300 according to another embodiment of the present invention. It corresponds to FIG. 2 described above. Compared to FIG. 2, the above description may be equally applied except that the number of cultivation modules arranged is reduced. The explanation focuses on the differences.

Referring to FIG. 6, the plurality of cultivation modules disposed under the tank includes first cultivation modules 120a and 120b and a second cultivation module 130. It is configured without the third cultivation module compared to FIG. Although it may be configured without the second cultivation module compared to Figure 2, it will be described with reference to the embodiment without a third cultivation module in FIG.

Since the first and second cultivation modules 120a, 120b, and 130 are made of only the third cultivation module, the circulation line Lc includes the first to second cultivation modules 120a, 120b, and 130 and the tank 110. Connect it.

The circulation line Lc may connect the first to second cultivation modules and the water tank through the circulation unit 150. Thus, the circulation lines Lc1, Lc2, Lc3, Lc5 are lines Lc1 connecting the first cultivation module 120a and the circulation unit 150 on the left side, the first cultivation module 120b on the right side and the circulation unit ( Line (Lc2) connecting the 150, the second cultivation module 130 and the line (Lc3) for connecting the circulation unit 150 and the line (Lc5) for connecting the circulation unit 150 and the water tank (110). can do. Respectively referred to as a first circulation line Lc1, a second circulation line Lc2, a third circulation line Lc3, and a fifth circulation line Lc5.

Culture medium filled in the bottom of the first cultivation modules (120a, 120b) more than a predetermined height is discharged through the first circulation line (Lc1) and the second circulation line (Lc2) to the circulation portion 150 is disposed at the bottom Can be. Each outflow direction is referred to as F2a and F2b.

The culture medium filled in the bottom of the second cultivation module 130 by a predetermined height or more may flow out through the third circulation line Lc3 to the circulation unit 150 disposed at the bottom. The outflow direction is referred to as F2c.

In addition, the culture solution collected from each of the culture modules into the circulation unit may be collectively reintroduced into the water tank 110 through the fifth circulation line Lc5 by the pump P. The reflow direction into the bath is referred to as F3 in the figure.

Crop cultivation apparatus according to an embodiment of the present invention also has the advantage that can operate the device at low power. That is, no additional power is consumed in introducing water from the water tank to the first cultivation module and the second cultivation module on the left side. This is also the case when water is introduced from the cultivation modules to the circulation. In addition, the self-weight of the water contained in the tank can be used for the operation of the injector in the first cultivation module on the right side, and the pump circulates the water at low power since only the smallest amount of the culture medium is lifted up after the culture medium is consumed in each cultivation module. To make it possible.

Although the technical spirit of the present invention has been specifically recorded in accordance with the above-described preferred embodiments, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, one of ordinary skill in the art will appreciate that various embodiments are possible within the spirit of the present invention.

100, 200, 300: crop growing apparatus
110: tank
112: detector
120a, 120b: the first cultivation module
H: home
S: injection part
130: second cultivation module
132: ultrasonic mist generating unit
140: the third cultivation module
150: circulation
Lo1: first outflow line
Lo2: second outflow line
Lo3: third outflow line
Lc, Lc1, Lc2, Lc3, Lc4, Lc5: circulation lines
Li: Inflow Line
B: battery compartment
T: Storage Tank
P: Pump

Claims (9)

Tanks for fish habitat; And
It is disposed under the tank, a plurality of cultivation module for cultivating the crop by using each of the water introduced from the tank as a culture medium;
Water that has passed through the plurality of cultivation modules is re-introduced into the tank is used for fish habitat, crop cultivation apparatus equipped with an aquarium. The method of claim 1,
The plurality of cultivation module, two or more of a vertical farming cultivation module, an aerophonic cultivation module, a pogphonic cultivation module and a hydrophonic cultivation module, the aquarium cultivation device equipped with an aquarium. The method of claim 1,
A first outflow line connecting the tank and a first cultivation module disposed below the tank of the plurality of cultivation modules to transfer water therebetween;
A second outflow line connecting the water tank and a second cultivation module disposed directly below the first cultivation module among the plurality of cultivation modules to transfer water therebetween; And
And a circulation line for connecting the first to second cultivation modules and the water tank to transfer water therebetween. The method of claim 3,
Further comprising: a circulation unit disposed directly below the second cultivation module,
The circulation line may include a first circulation line connecting the first cultivation module and the circulation unit to transfer water therebetween;
A second circulation line connecting the second cultivation module and the circulation unit to transfer water therebetween; And
And a third circulation line connecting the circulation unit and the water tank to transfer water therebetween. The method of claim 4, wherein
The circulation unit, a crop cultivation apparatus provided with an aquarium further comprising; a pump for introducing water passed through the plurality of cultivation module into the tank. The method of claim 5,
The pump is disposed on the circulation line, crop cultivation apparatus equipped with an aquarium. The method of claim 5,
Inflow line for receiving water from the outside; further comprising,
The pump is a crop cultivation apparatus equipped with an aquarium for introducing the water introduced from the inlet line with the water passing through the plurality of cultivation module to the tank. The method of claim 7, wherein
Further comprising: a sensing unit for sensing the water level of the tank,
When the water satisfies the reference value as a result of the detection, as the water flows in from the outside through the inlet line according to the opening and closing of the valve disposed in the inlet line, crop plant equipped with an aquarium. The method of claim 1,
A first outflow line connecting the tank and a first cultivation module disposed below the tank of the plurality of cultivation modules to transfer water therebetween;
A second outflow line connecting the water tank and a second cultivation module disposed directly below the first cultivation module among the plurality of cultivation modules to transfer water therebetween;
A third outflow line connecting the water tank and a third cultivation module disposed directly below the second cultivation module among the plurality of cultivation modules to transfer water therebetween; And
And a circulation line for connecting the first to third cultivation modules and the water tank to transfer water therebetween.

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