KR101551748B1 - Plant Culture Appratus and Operating Method thereof - Google Patents

Abstract

An embodiment of the present invention relates to a plant cultivation apparatus and an operation method thereof for aquaponix which can simultaneously circulate water by a single pump and supply oxygen to a fish and is easy to install and move.

Description

TECHNICAL FIELD The present invention relates to a plant cultivation apparatus,

An embodiment of the present invention relates to a plant cultivation apparatus and an operation method thereof for aquaponix which can simultaneously circulate water by a single pump and supply oxygen to a fish and is easy to install and move.

The contents described in this section merely provide background information on the embodiment of the present invention and do not constitute the prior art.

There are many ways to grow organic plants. Aquaponics is a combination of acuaculture, which means fish, and hydroponics, which means hydroponic cultivation of plants. It uses fish excrement as a nutrient for plants and naturally cleansed water by biological action of plants. It is a method of cultivation of artificial plants used for cultivation. Aqua phonix is a plant cultivation method that has recently emerged in that it can cultivate organic plants while simultaneously cultivating fish cultures and hydroponics in an environmentally friendly manner.

On the other hand, fish excrements are composed mainly of ammonia or ammonium, unlike humans or other animals. In particular, ammonia, when mixed with water, forms ammonium by combining with hydrogen ions or oxonium ions contained in water.

Unlike the elements secreted by humans or other animals, these ammonium or ammonia are not suitable for use directly as plant nutrients. Therefore, in order to use ammonia or ammonia contained in fish excrement as a nutrient of plants, it is necessary to convert it into nitrate using a chemical and biological mechanism. There is a bio filter as a device for making such a conversion. Biofilters provide an environment in which bacteria can live and use bacteria to convert ammonium or ammonia to nitrate, and are commonly used in aquaponics.

Such an aquaponix device can be used for gardening and office buildings because it has the advantage of simultaneously cultivating and cultivating the plant.

However, the aquaponix apparatus is expensive in terms of installation and maintenance because it is generally large in a fish tank, a biofilter necessary for supplying nutrients to plants, and the like. In particular, the pump should use a water pump to circulate water between the water tank and the planting site and an air pump to provide oxygen to the fish in the water tank. As a result, the aqua phonics device has a disadvantage that it takes up a large area to be burdened for use in the home or office, and the electric charge is increased due to the use of two kinds of pumps.

Water pumps are usually installed inside a water tank. In this case, if the electric wiring that supplies electric power to the water pump is short-circuited, electricity may flow into the water tank to cause the fish inhabiting the water tank to be shut down, There is a number.

Therefore, it is an object of the present invention to provide a plant cultivation apparatus and an operation method thereof for aquaponix which can simultaneously circulate water with a single pump and supply oxygen to fish, and is easy to install and move have.

The technical object of the present invention is not limited to the above-mentioned technical objects and other technical objects which are not mentioned can be clearly understood by those skilled in the art from the following description will be.

One embodiment of the plant cultivation apparatus comprises a water tank in which a fish is inhabited; A pump for discharging a part of water contained in the water tank to the outside of the water tank; a filter for purifying water discharged to the outside of the water tank; A tray having a culture medium to be cultivated; And a coupling unit for coupling the water tub and the tray so as to move integrally with each other.

The pump is provided with an air pump for injecting air into the water tank. One end of the air pump is connected to the air pump. The other end of the pump is submerged in the water tank. The air pumped from the air pump forms air bubbles, And a pipe for discharging part of the water to the outside of the water tank.

Wherein the piping comprises: a small-diameter pipe having one end connected to the air pump and the other end pushed into the water tank to supply air pumped from the air pump into the water tank; And an upper end connected to the upper portion of the tray and a lower end immersed in the water tank, and installed to surround a part of the small-diameter pipe. The air bubbles formed by the air introduced from the air pump and the air bubbles are discharged to the outside of the water tank And a large shower that provides a path for water to rise.

Another embodiment of the plant cultivation apparatus comprises a water tank in which the fish is inhabited; An air pump for pumping air into the water tank; A pipe connected to the air pump at one end and immersed at the other end in the water tank and supplying air from the air pump to the water tank and discharging the water in the water tank to the outside of the water tank; And a tray disposed on the upper part of the water tank and provided with the air pump and having a filter for purifying water discharged to the outside of the water tank and a medium for growing plants using at least a part of the purified water in the filter as a culture liquid, .

One embodiment of a method of operating a plant cultivation device comprises: introducing air from an air pump into a water bath; A part of the water in the water tank is discharged to the outside of the water tank as the air introduced into the water tank from the air pump forms bubbles and rises; A part of the water discharged to the outside of the water tank is introduced into a filter disposed in the upper part of the water tank, and the remaining water is impregnated in a medium placed in the upper part of the water tank; Wherein the water introduced into the filter is at least partially purified by bacteria; And allowing the water having passed through the filter to flow into the water tank.

The plant cultivation apparatus and its operation method of the above-described embodiment can circulate water and supply oxygen to fish simultaneously with one pump, thereby reducing the amount of electricity used, and various devices for aquaponics can be integrated and installed And the pump is installed outside the water tank, so that it is possible to reduce the malfunction of the fish dead and the pump due to the short circuit.

1 is a perspective view illustrating a plant cultivation apparatus according to an embodiment of the present invention.
2 is a front sectional view showing a plant cultivation apparatus according to an embodiment of the present invention.
3 is a partial cross-sectional view of a portion of a piping used in the illustrated plant cultivation apparatus according to an embodiment of the present invention.
FIG. 4 is a perspective view of a plant cultivation apparatus according to an embodiment of the present invention, in which a top plate is removed.
FIG. 5 is a perspective view illustrating the cultivation of plants in the culture medium and the culture medium in the plant cultivation apparatus according to an embodiment of the present invention.
6 is a flowchart illustrating an operation method of a plant cultivation apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms specifically defined in consideration of the constitution and operation of the present invention are only for explaining the embodiments of the present invention, and do not limit the scope of the present invention.

1 is a perspective view illustrating a plant cultivation apparatus according to an embodiment of the present invention. 2 is a front sectional view showing a plant cultivation apparatus according to an embodiment of the present invention. 3 is a partial cross-sectional view of a portion of a pipe 400 used in the illustrated plant cultivation apparatus according to an embodiment of the present invention.

The plant cultivation apparatus includes a water tank 100, a tray 200, a coupling unit 300, and a pipe 400.

The water tank 100 is a space in which the fish live, and at least a portion of the water is filled with water so that the fish can live there. The water filled in the water tank 100 passes through the filter 220 and the medium 230 disposed in the tray 200 by the air pump 210 and is cultivated in the filter 230 and the bacteria in the filter 220 The excrements and the like of the fish generated in the water are purified and then introduced into the water tank 100 again. Therefore, in the plant cultivation apparatus, it is not necessary to frequently change the water in the water tank 100 in order to allow fish to live there.

The tray 200 is disposed on the upper part of the water tub 100 and is movably coupled to the water tub 100 by an engaging part 300. The tray 200 includes an air pump 210, a filter 220, a medium 230 And includes a casing 240, a lower plate 250, an upper plate 260, and a flow guide unit 270.

The air pump 210 is provided in the tray 200 and injects air into the water tub 100. At least a part of the water filled in the water tub 100 by the air injected into the water tub 100 is supplied to the large- The water flowing into the tray 200 flows into the water tank 100 through the filter 220 or the medium 230. The water in the water tank 200 flows into the water tank 200 through the filter 220 or the medium 230. [

The plant cultivation apparatus of the present invention uses the air pump 210 to repeatedly circulate water in the water tub 100 for plant cultivation and purification throughout the plant cultivation apparatus and at the same time, And supplies oxygen necessary for growth. Therefore, compared with the case of using the air pump 210 for supplying oxygen and the water pump for circulating water, it is advantageous in terms of power efficiency, space efficiency, installation cost, and maintenance cost.

The filter 220 is provided in the tray 200 and serves to purify excretion contained in water discharged to the outside of the water tub 100. Bacteria are inhabited in the filter 220, and bacteria convert ammonia, ammonium, etc. contained in fish excrement into nitrite or nitrate. Nitrite is an organic matter that is the nutrient of plants grown in the medium 230.

Specifically, bacteria in the filter 220 convert ammonium or ammonia contained in water introduced from the water tank 100 into nitrite, and convert the nitrite to nitrate. Bacteria that convert ammonium or ammonia to nitrite are, for example, nitrosomonas, and bacteria that convert nitrite to nitrate, for example nitrospira. Therefore, various kinds of bacteria such as Nitrosomonas and Nitrospora can be contained in the filling material.

The filter 220 is formed of an invasive material so that it can contain water and is made of a porous material that is inexpensive, is not easily corroded by water and organic matter, is easily replaceable, and has a space for bacteria It is appropriate to use. For example, it is appropriate to use a sponge made of a material such as rubber or synthetic resin as the filter 220.

The culture medium 230 is provided in the tray 200 and at least a part of the water discharged to the outside of the water tub 100 is impregnated and the plant is cultivated. More details regarding the structure and role of the medium 230 will be described later with reference to Fig.

The casing 240 is a portion in which the air pump 210 and the filter 220 are disposed and both sides thereof are coupled to the coupling portion 300 so that the tray 200 including the casing 240 and the water tub 100 are integrated Thereby making it possible to construct a plant cultivation apparatus of the present invention which is more compact and more convenient to move than a general aquaponics plant cultivation apparatus.

The lower plate 250 is coupled to the lower end of the casing 240 and is a portion where the air pump 210 and the filter 220 are placed and a first large-diameter insertion hole 251 is formed. Unlike the upper plate 260, the lower plate 250 may be formed integrally with the casing 240, since the lower plate 250 has little need to separate the casing 240 from the upper plate 260. The first large-diameter tube insertion hole 251 is formed in the lower plate 250 and is a portion into which the large-diameter tube 420 is inserted.

The upper plate 260 closes the upper portion of the casing 240 and is provided with a medium 230 thereon and has a second large-diameter tube insertion hole 261 and a liquid inlet 262.

The second large-diameter tube insertion hole 261 is formed in the upper plate 260 and is a portion into which the large-diameter tube 420 is inserted together with the first large-diameter tube insertion hole 251. That is, the large-diameter pipe 420 passes through the first large-diameter pipe insertion hole 251 and the second large-diameter pipe insertion hole 261 to discharge the water in the water tub 100 to the upper surface of the upper plate 260.

The liquid inlet 262 is provided in the upper plate 260 and the water discharged from the large-diameter pipe 420 flows into the filter 220. At least a part of the water discharged into the large-diameter pipe 420 flows along the upper plate 260 and flows into the filter 220 located below the upper plate 260 through the liquid inlet 262, Is biochemically purified as described above by bacteria. The liquid inlet 262 may be provided in an appropriate size and number in accordance with the flow rate of the water flowing into the filter 220, the size of the plant cultivation apparatus, and the like.

The channel guide unit 270 is installed between the second large-diameter tube insertion hole 261 and the liquid inlet 262 and the water discharged from the large-diameter tube 420 is passed through the filter 220 or the medium 230 And has a liquid through hole (271). The channel guide unit 270 is disposed across the upper plate 260 on the upper plate 260 in the form of a bar to form a portion where the medium 230 is installed together with the casing 240.

The liquid through hole 271 is a portion through which the water of the water tank 100 that is discharged from the upper end of the large-diameter pipe 420 and flows to the liquid inlet port 262 passes. A plurality of liquid through holes 271 are formed along the longitudinal direction of the flow path guide portion 270. This structure is similar to that of the flow path guide portion 270 in the case of the medium 230 provided at the portion formed by the casing 240 and the flow path guide portion 270 It is to supply water evenly.

The coupling part 300 serves to connect the water tray 100 and the tray 200 so that they can move integrally. The plant cultivation apparatus of the present invention is constructed by combining the water tank 100 with the air pump 210, the filter 220 and the tray 200 provided with the medium 230 by the coupling unit 300, The mobility is further improved as compared with the plant cultivation apparatus.

The pipe 400 is connected to the air pump 210 at one end and the other end is locked to the water tank 100. The air pumped from the air pump 210 forms air bubbles B, And discharges a part of the water of the water tank 100 to the outside of the water tank 100, and includes a small-sized pipe 410 and a large pipe 420.

The small-diameter pipe 410 provides a passage through which air having one end connected to the air pump 210 and the other end pumped from the air pump 210 into the water tub 100 flows into the water tub 100, As shown in Figs. 2 and 3, it refers to a small-diameter pipe passage 411. Fig.

The upper end of the large-diameter pipe 420 is connected to the upper plate 260 on the upper side of the tray 200, the lower end of the large pipe 420 is locked to the water tub 100, and is installed to surround a part of the small- The air bubbles B and the air bubbles B formed by the inflow air together with the water to be discharged to the outside of the water tub 100 are raised and as shown in Figures 2 and 3, (421).

The lower end of the small-diameter pipe 410 is located above the lower end of the large-diameter pipe 420, and the small-diameter pipe 410 is connected to the large- The air bubbles B formed by the air flowing into the water tank 100 from the air pump 210 are formed between the lower end of the large diameter pipe 410 and the lower end of the large diameter pipe 420, .

The air flowing into the water tank 100 from the air pump 210 forms a bubble B when passing through the water in the water tank 100 and passes through the small-diameter pipe passage 411. The air bubbles B are not spread widely in the water tank 100 but are raised through the large-sized pipe path 421 due to the space portion 430 formed at the lower end of the small- The water adjacent to the air bubble B also rises as the air bubble B rises and the water adjacent to the air bubble B is also discharged to the upper end of the large diameter pipe 420 as the air bubble B is discharged to the upper end of the large- And flows onto the top plate 260 of the tray 200 to enter the medium 230 or the filter 220.

4 is a perspective view illustrating a state in which the upper plate 260 is removed in the plant cultivation apparatus according to an embodiment of the present invention.

The outer diameter of the large-diameter pipe 420 is smaller than the inner diameter of the first large-diameter pipe insertion hole 251 formed in the lower plate 250 and the difference between the outer diameter of the large pipe 420 and the inner diameter of the first large-diameter pipe insertion hole 251 And the air gap C serves as a passage through which the water discharged from the filter 220 flows into the water tub 100. [ On the other hand, the water that has passed through the medium 230 passes through the filter 220 through the liquid inlet 262, and then flows into the water tub 100 through the gap C.

Therefore, all the water that has passed through the filter 220 or the medium 230 flows into the water tub 100 through the gap C, so that the water flowing into the water tub 100 So that it flows down on the outer surface of the large-diameter pipe 420. In such a structure, since the water is kept quiet and flows down to the water tank 100, the phenomenon of splashing water on the water tank 100 can be remarkably reduced. When the water drop is splashed in the water tank 100, the water droplets that are splashed fall outside the plant growing apparatus, and the water droplets that have fallen to the outside may damage the aesthetics or harm to the outside environment of the plant cultivation apparatus. In addition, if water droplets that are splashed are adhered to a glass wall that does not occupy water in the water tank 100, green algae and the like may be present in the water pool, thereby damaging the aesthetic appearance of the water tank 100, It can harm the health of. The plant cultivation apparatus of the present invention can drastically reduce the phenomenon of splashing water droplets, so that the above-mentioned various disadvantages can be remarkably reduced.

FIG. 5 is a perspective view illustrating the cultivation of plants in the medium 230 and the medium 230 in the plant cultivation apparatus according to an embodiment of the present invention.

The medium 230 may be impregnated with water, the impregnated water may contain a nitrate salt, and the nitrate may be used as a nutrient. The medium 230 is formed of an invasive material that can contain impregnated water for a long time and is inexpensive, does not easily corrode to water and organic matter, is easily replaceable, and it is appropriate that the roots of the plant can be fixed Do. For example, it is appropriate to use a cotton-like synthetic resin, and more preferably to use cotton-like polyethylene.

The water in which the nitrate is generated by the filter 220 is repeatedly circulated in the water tank 100, the medium 230 and the filter 220 in the medium 230 so that a sufficient amount of nitrate The water containing the water can be supplied to the medium 230.

The plant cultivation apparatus of the present invention can cultivate various kinds of various plants. However, in order to make use of the mobility and compact structure, which is one of the effects of the present invention, the plant cultivation apparatus of the present invention is more suitable for cultivating young plants that are not mature since cotyledons are formed rather than large- Do.

6 is a flowchart illustrating an operation method of a plant cultivation apparatus according to an embodiment of the present invention.

The method of operating the plant cultivation apparatus includes a step S110 of flowing air into the water tub 100, a step S120 of discharging the water of the water tub 100 to the outside, a step S120 of flowing water into the filter 220, A step S140 of purifying the water introduced into the filter 220 and a step 150 of introducing the water that has passed through the filter 220 into the water tank 100 in step S130.

Air is introduced into the water tub 100 from the air pump 210 through the small-diameter pipe passage 411 in step S110 in which air flows into the water tub 100. [

The air introduced into the water tub 100 from the air pump 210 forms air bubbles B and flows into the small-diameter pipe passage 411 and the space portion 430 A part of the water in the water tub 100 is discharged to the upper plate 260 located in the upper part of the water tub 100. As shown in FIG.

A part of the water discharged to the outside of the water tub 100 flows into the filter 220 disposed on the upper part of the water tub 100 in the step S130 in which water flows into the filter 220 and impregnates the medium 230, The water is impregnated into the medium 230 disposed on the water tank 100.

In step S140 where the water introduced into the filter 220 is purified, at least a part of the water that flows into the filter 220 or flows into the filter 220 through the medium 230, Some are converted to nitrates by bacteria. At this time, the water that has passed through the medium 230 is partially purified by various plants, which harm the health of the fish by the cultivated plants.

The water having passed through the filter 220 flows into the water tank 100 in step 150 and the water having passed through the step S140 in which the water flowing into the filter 220 is purified passes through the filter 220, (C) to the water tub 100 again.

When the above-described steps are repeatedly performed, nitrate salts as plant nutrients are accumulated in the medium 230, and at least a part of the toxic substances contained in the fish excrement is removed in the water tank 100.

While only a few are described above in connection with the embodiments of the present invention, various other forms of implementation are possible. The technical contents of the embodiments described above may be combined in various forms other than the mutually incompatible technologies, and may be implemented in a new embodiment through the same.

100: Tank 200: Tray
210: air pump 220: filter
230: medium 240: casing
250: lower plate 251: first large landscape insertion hole
260: upper plate 261: second large landscape insertion hole
262: liquid inlet port 270:
271: liquid through hole 300:
400: piping 410: small landscape
411: Small-scale scenic route 420: Great scenery
421: large-scale pipe 430:
B: air bubble C: air gap

Claims (14)

A fish tank;
A pump for discharging a part of water contained in the water tank to the outside of the water tank; a filter for purifying water discharged to the outside of the water tank; A tray having a culture medium to be cultivated; And
And a coupling portion for coupling the water tray and the tray so as to move integrally with each other,
Wherein the pump is provided with an air pump for injecting air into the water tank,
And a pipe for discharging a part of the water of the water tank to the outside of the water tank as the air pumped from the air pump forms a bubble and the other end is connected to the air pump and the other end is locked to the water tank Plant cultivation apparatus. delete The method according to claim 1,
In the above-described piping,
A small-diameter pipe connected to the air pump at one end thereof, the other end of which is pushed into the water tank to provide a passage through which air pumped from the air pump flows into the water tank; And
A bubble formed by the air introduced from the air pump and a water discharged to the outside of the water tank together with the bubbles are provided so as to surround a part of the small- Great landscape that provides this ascending aisle
The plant cultivation apparatus comprising: The method of claim 3,
The small-diameter pipe is installed so as to pass through the large-diameter pipe, and the lower end of the small-diameter pipe is located on the upper side of the lower end of the large pipe, and flows from the air pump to the water tank between the lower end of the small- Wherein a space part for allowing air bubbles formed by air to rise through the large-diameter pipe is formed. The method of claim 3,
The tray may include:
A casing in which the air pump and the filter are disposed;
A lower plate coupled to a lower end of the casing, in which the air pump and the filter are placed;
An upper plate which closes an upper portion of the casing and has the medium on the upper side; And
A water guide portion for guiding the water discharged from the large-sized pipe to flow to a site where the filter or the medium is installed,
Wherein the plant cultivation apparatus comprises: 6. The method of claim 5,
The lower plate,
Wherein a first large-diameter insertion hole into which the large-diameter tube is inserted is formed, and an outer diameter of the large-diameter tube is smaller than an inner diameter of the first large-diameter tube insertion hole. The method according to claim 6,
The filter or the water passing through the medium passes through a space formed between the outer diameter of the large-diameter tube and the inner diameter of the first large-diameter tube insertion hole, flows into the water tub, flows on the outer surface of the large tube, Wherein the plant is cultivated in a plant. 6. The method of claim 5,
The above-
And a second large-diameter pipe insertion hole into which the large-diameter pipe is inserted, and at least one liquid inlet through which water discharged from the large-diameter pipe flows into the filter is provided. 9. The method of claim 8,
The flow-
A liquid passage hole through which the water of the water tank, which is discharged from the upper end of the large-sized pipe inserted into the second large-diameter pipe insertion hole and flows into the liquid inlet, passes through the second large- Wherein the plant cultivation apparatus comprises: The method according to claim 1,
The filter includes:
Characterized in that it comprises bacteria which are formed of an invasive material and convert ammonia or ammonium contained in fish excrement into nitrite or nitrate. 11. The method of claim 10,
Wherein the conversion of ammonium or ammonia to nitrite in said bacteria is nitrosomonas and the conversion of nitrite to nitrate is nitrospira. The method according to claim 1,
The above-
Characterized in that it is formed of an invasive polyethylene material. delete delete

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