KR20140088760A - Fogponics system - Google Patents

Abstract

One embodiment of the spray culture system according to the present invention comprises: a nutrient solution supply unit through which a nutrient solution is supplied; A cultivation bed installed above the nutrient solution supply unit and having an inlet for receiving the nutrient solution from the nutrient solution supply unit and an outlet for discharging the nutrient solution; And a nutrient solution discharge section in which the growth bed is installed on the upper side and the spray nutrient solution discharged from the outlet is collected.
According to the present invention, it is possible to uniformly supply the sprayed nutrient solution to the entire planted plants while using a few ultrasonic vibration modules rather than a general sprayed seedling cultivation system, thereby saving initial facility cost and maintenance cost for cultivating the sprayed seeds.

Description

{Fogponics system}

An embodiment of the present invention relates to a spray culture system, and more particularly, to a spray culture system in which the number of ultrasonic modules for spraying a nutrient solution is reduced to enhance the utility of a plant.

It should be noted that the following description merely provides background information related to the present embodiment and does not constitute the prior art.

In general, there are many ways to grow plants using nutrients. Namely, there is a hydroponics method in which a plant is grown using a liquid nutrient solution, and a spray cultivation method in which a plant is grown using a nutrient solution sprayed with a nutrient solution.

The aerobic cultivation is carried out using aeroponics, which grow plants using sprayed nutrients, which are formed using general sprayers, fogponics, which grow plants using spray nutrients formed using ultrasonic modules, . Fogphonics has a small particle size of sprayed liquid used compared to aeroponics. Therefore, the spraying liquid in Pogphonix has a relatively small effect of gravity compared with aeroponics, so that the nutrient solution can be supplied to the whole plants to be supplied evenly.

A spraying apparatus for spraying a nutrient solution using a fog-phonix device, that is, an ultrasonic vibration module, generally includes a storage bed in which plants are planted and cultivated, a liquid nutrient solution is stored, and ultrasound And is configured such that liquid nutrient solution is sprayed by the vibration module.

However, in such a configuration, since one ultrasonic vibration module sprays all of the nutrient solution stored in the cultivation bed, the nutrient solution in the vicinity of the ultrasonic vibration module is actively sprayed, but the nutrient solution located far from the ultrasonic vibration module is not actively sprayed .

Due to the imbalance of the spray, among the plants planted on the growing bed, the plants in the vicinity of the ultrasonic vibration module are supplied with abundant nutrient solution to promote growth. However, in the plants located far from the ultrasonic vibration module, So that the growth can be suppressed.

Imbalance in plant growth caused by imbalance in spraying is likely to produce crops with low commercial value.

There is a method of mounting a plurality of ultrasonic vibration modules on a cultivation bed to reduce the disparity of spraying, but there is a problem that the installation cost of the spraying plant grows up.

Another method of reducing spray imbalance is to increase the vertical length of the growing bed to widen the distance between the plant and the liquid nutrient solution so that the sprayed nutrient solution is evenly distributed throughout the growing bed. However, this method is disadvantageous in terms of facility cost due to enlargement of a growing bed, and there is a problem that a space for cultivation can be enlarged excessively.

SUMMARY OF THE INVENTION An object of the present invention is to provide a spray culture system using a small number of ultrasonic vibration modules in order to solve the above problems and having a structure capable of uniformly supplying the sprayed liquid to plants.

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 spray culture system according to the present invention comprises: a nutrient solution supply unit through which a nutrient solution is supplied; A cultivation bed installed above the nutrient solution supply unit and having an inlet for receiving the nutrient solution from the nutrient solution supply unit and an outlet for discharging the nutrient solution; And a nutrient solution discharge section in which the growth bed is installed on the upper side and the spray nutrient solution discharged from the outlet is collected.

One embodiment of the spray culture system according to the present invention may further include a nutrient solution storage part for collecting the nutrient solution discharged from the nutrient solution discharge part.

At this time, the outlet of the nutrient solution reservoir is connected to the inlet of the nutrient solution reservoir, the outlet of the nutrient solution reservoir is connected to the inlet of the growth bed, the outlet of the growth bed is connected to the inlet of the nutrient solution outlet, And the outlet of the negative portion may be connected to the inlet of the nutrient solution reservoir.

The nutrient solution supply section and the nutrient solution discharge section may each have a guide section, and the growth bed may be mounted on the nutrient solution supply section and the nutrient solution discharge section so as to be slidably guided by the respective guide sections.

The growth bed may be a plurality of aligned between the nutrient solution supply portion and the nutrient solution discharge portion.

The nutrient solution supply unit or the nutrient solution discharge unit may include a conduit through which the nutrient solution flows and has an opening formed in a longitudinal direction on an upper side thereof; A support portion formed along the longitudinal direction of the conduit and supporting the conduit; And a first seat portion extending from the opening portion and having a lower end of the one side of the growth bed.

One embodiment of the spray culture system according to the present invention may further include a second placement part positioned between the first placement part and the opening part.

The inlet and outlet of the growth bed may be through holes formed on both sides of the lower side of the growth bed to correspond to the opening.

And a guide portion extending upward from one side of the upper portion of the channel to guide sliding movement of the side of the upgraded bed.

And a reinforcing support portion extending from one side of the upper portion of the channel and connected to the support portion.

The pulp nutrient solution supplied to the nutrient supply part may be one which is vaporized by the ultrasonic module.

The growth bed may be provided in multiple stages.

Also, the nutrient solution supply unit and the nutrient solution discharge unit may be provided in multiple stages.

At this time, the nutrient solution supply portion and the nutrient solution discharge portion may be arranged and fixed in a vertical direction on a frame constituted by a skeleton of a hexahedron.

Another embodiment of the spray culture system according to the present invention comprises: a first spray fluid pipe to which a spray nutrient solution vaporized by an ultrasonic module is supplied; A cultivation bed having one side connected to the first sprayed liquid pipe to receive the nascent nutrient solution from a nutrient solution supply hole formed in the first sprayed nutrient solution pipe and planting the plant; A second spray fluid pipe connected to the other side of the cultivation bed, in which a nutrient solution discharge hole is formed and the spray nutrient solution discharged from the cultivation bed is collected; A pair of coupling members respectively coupled to the first spray fluid pipe and the second spray fluid pipe; And a frame for fixing the pair of engagement members.

The first spray fluid pipe and the second spray fluid pipe may be arranged vertically and vertically.

Another embodiment of the spray culture system according to the present invention is characterized in that it comprises a nutrient supply part extending in the longitudinal direction and having an opening through which the nutrient solution is discharged to the upper side; A nutrient solution discharging portion extending in the longitudinal direction and provided on the opposite side of the nutrient solution supplying portion and having an opening through which the nutrient solution flows into the upper side; A cultivation bed which is slidably installed on the nutrient solution supply unit and the nutrient solution discharge unit and receives the sprayed nutrient solution from the nutrient solution supply unit and discharges the sprayed nutrient solution to the nutrient solution discharge unit; And an ultrasonic module for converting the nutrient solution for plant cultivation into the nutrient solution for spraying.

In this case, the nutrient solution discharging unit may further include a nutrient solution storing unit for collecting the nutrient solution discharged from the nutrient solution discharging unit, and the nutrient solution collected in the nutrient solution storing unit may be supplied to the ultrasonic module.

The spraying culture system of the above-described embodiment is capable of uniformly supplying the sprayed liquid to the entire planted plants while using a small number of ultrasonic vibration modules in a general spraying culture system, thereby saving initial facility cost and maintenance cost for spraying There is an effect that can be.

In addition, the installation and handling of the cultivation bed is simplified and the operator's convenience can be improved.

1 is a perspective view showing a nutrient solution supply unit, a cultivation bed, and a nutrient solution discharge unit of a spray culture system according to an embodiment of the present invention.
2 is an enlarged cross-sectional view illustrating a nutrient solution supply unit or a nutrient solution discharge unit used in a spray culture system according to an embodiment of the present invention.
FIG. 3 is a perspective view illustrating a cultivation bed used in a spray culture system according to an embodiment of the present invention.
FIG. 4 is a perspective view illustrating a part of a spray culture system according to an embodiment of the present invention.
FIG. 5 is a schematic view showing a spray culture system according to an embodiment of the present invention. FIG.
FIG. 6 is a schematic view showing a part of a spray culture system 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 showing a nutrient solution supply unit 100, a cultivation bed 200, and a nutrient solution discharge unit 300 of a spray culture system according to an embodiment of the present invention.

The nutrient solution supply unit 100 is a space through which the nutrient solution sprayed from the ultrasonic module 600 (see FIG. 5) is supplied and flows, and the supplied nutrient solution flows into the cultivation bed 200 again.

The cultivation bed 200 is installed above the nutrient solution supply unit 100 and receives the nutrient solution from the nutrient solution supply unit 100. The nutrient solution flows through the cultivation bed 200 and flows into the nutrient solution discharging part 300. Some nutrient solution is absorbed by plants planted in the cultivation bed 200 and only the remaining nutrient solution flows out to the nutrient solution discharging part 300 . Plants cultivated in the cultivation bed 200 are supplied with the nutrient solution continuously supplied in the cultivation bed 200, and grow as nourishing nutrients.

The nutrient solution discharging portion 300 is a place where the nutrient solution not absorbed by the vegetation flows out and is collected. At this time, the nutrient solution collected in the nutrient solution discharge part 300 is disturbed by the influence of the plant roots and the structure of the cultivation bed 200, so that most of the nutrient solution is liquefied from the mist.

The liquefied nutrient solution collected in the nutrient solution discharge unit 300 is circulated again and supplied to the nutrient solution supply unit 100 through the ultrasonic module 600.

As shown in FIG. 1, the nutrient solution supply unit 100 and the nutrient solution discharge unit 300 have a symmetrical structure around the cultivation bed 200.

The nutrient solution supplying unit 100 and the nutrient solution discharging unit 300 each have a guide unit 550 (see FIG. 2). The spraying apparatus includes a plurality of cultivation beds 200, 200 are mounted on the nutrient solution supply unit 100 and the nutrient solution discharge unit 300 and are guided by the respective guide units 550 so as to be slidable. Because of this structure, the operator can easily perform operations such as sowing, transplanting and harvesting the plant in the cultivation bed 200, thereby improving the convenience of the operator.

2 is an enlarged sectional view showing a nutrient solution supply unit 100 or a nutrient solution discharge unit 300 used in the spray culture system according to an embodiment of the present invention.

As described above, since the nutrient solution supply unit 100 and the nutrient solution discharge unit 300 are symmetrical with respect to the growth bed 200, the structure of the nutrient solution supply unit 100 will be described below.

The nutrient solution supply unit 100 includes a channel 500, an opening 510, a support 520, a first seating unit 530, a second seating unit 540, a guide unit 550, and a reinforcing support unit 560 do.

The conduit 500 is a long passage, and the nutrient solution sprayed by the ultrasonic module 600 flows through one end thereof, while the other end is blocked so that the nutrient solution is not discharged. An opening 510 is formed in the upper portion.

The opening 510 is formed along the longitudinal direction at one side of the upper part of the conduit 500 and becomes a passage through which the nutrient solution injected into the conduit 500 is discharged and flows back to the growth bed 200.

The supporting part 520 is formed along the longitudinal direction of the conduit 500 and supports the conduit 500. The support 520 and the conduit 500 may be integrally formed by injection molding or extrusion molding. In the case of a metal material, the support 520 and the conduit 500 may be welded or bolted, Any method can be used as long as it can stably support the channel 500.

The first seating portion 530 extends from the opening 510 and has a front end bent. The lower end of one side of the growth bed 200 is seated on the front end of the first seating portion 530 and the growth bed 200 is supported by the first seating portion 530. At this time, the growth bed 200 is slidable on the first seating portion 530.

The second seating portion 540 is positioned between the first seating portion 530 and the opening 510 and serves to support the growth bed 200 together with the first seating portion 530. At this time, the growth bed 200 is slidable on the second seating portion 540.

The first seating part 530 and the second seating part 540 serve to form the flow direction of the opening part 510 so that the nutrient solution can be introduced into or discharged from the cultivation bed 200 from the pipeline 500 do. That is, the first seating portion 530 and the second seating portion 540 are formed such that the opening portion 510 is formed in the right-upward direction in the nutrient solution supplying portion 100 so that the nutrient solution in a misty state flows from the nutrient solution supplying portion 100 to the cultivation bed 200 And the opening portion 510 is formed in the left upper side in the nanoparticle discharging portion so that the nutrient solution in which most of the liquid is liquefied is discharged from the cultivation bed 200 to the nutrient solution supply portion 100 by gravity.

The guide portion 550 is a surface extending upward from one side of the upper part of the channel 500 and sliding on the side surface of the growth bed 200. The side of the cultivation bed 200 moves while sliding on the guide part 550 so that the guide part 550 serves to guide the back and forth movement of the cultivation bed 200.

The reinforcing supporter 560 extends from one side of the upper portion of the conduit 500 and is connected to the supporter 520. The conduit 500, the first seating portion 530, the second seating portion 540, So as not to be bent. 2, one end of the reinforcing supporting portion 560 is coupled to the end of the guide portion 550. However, if the reinforcing supporting portion 560 can perform its own role, Can be combined.

The nutrient solution discharging unit 300 has the same configuration except that it is symmetrical with the nutrient solution supplying unit 100. The nutrient solution discharging unit 300 discharges the nutrient solution not absorbed by the plant through the opening 510 from the growing bed 200, . At this time, most of the nutrient solution collected in the conduit 500 is again liquefied from the mist state.

FIG. 3 is a perspective view showing a cultivation bed 200 used in a spray culture system according to an embodiment of the present invention.

In the cultivation bed 200, plants are planted and grown, and the nutrient solution supplied from the nutrient solution supply unit 100 flows into the nutrient solution supply unit 100 and is discharged to the nutrient solution discharge unit 300.

The passage through which the nutrient solution flows into or out of the cultivation bed 200 is the through-hole 210 formed at the lower end of the cultivation bed 200. The through holes 210 are formed on both sides of the lower end of the growth bed 200. The through holes 210 correspond to the openings 510 of the nutrient solution supply unit 100 and the openings 510 of the nutrient solution discharge unit 300, .

The growth bed side 220 slides on the guide part 550 (see FIG. 2), and the growth bed 200 moves along the guide part 550 along the longitudinal direction of the nutrient solution supply part 100 and the nutrient solution discharge part 300 Move.

FIG. 4 is a perspective view illustrating a part of a spray culture system according to an embodiment of the present invention.

The opening 510 formed in the conduit 500 communicates with the through hole 210 when the growth bed 200 is placed on the nutrient solution supply unit 100. Therefore, the nutrient solution flows into the cultivation bed 200 through the nutrient solution supply unit 100, the opening 510, and the through hole 210 in order.

The nutrient solution discharging unit 300 has the same configuration except that it is symmetrical with the nutrient solution supplying unit 100. The nutrient solution discharging unit 300 discharges the nutrient solution not absorbed by the plant through the opening 510 from the growing bed 200, . Therefore, the nutrient solution flows out to the nutrient solution discharge unit 300 sequentially through the cultivation bed 200, the through hole 210 and the opening 510.

FIG. 5 is a schematic view showing a spray culture system according to an embodiment of the present invention. FIG.

The cultivation bed 200 is aligned in the longitudinal direction of the nutrient solution supply unit 100 and the nutrient solution discharge unit 300. Also, the nutrient solution supply unit 100 and the nutrient solution discharge unit 300 are provided in multiple stages, and a plurality of growth beds 200 are arranged at each stage. In addition, a lighting device 400 is provided under the cultivation bed 200 at each stage to supply light required for growing the plants. Although the planar illumination device 400 is shown as one embodiment of the illumination device 400, various types of illumination devices 400 may be used in consideration of the cultivation place, installation cost, and the like.

At this time, the nutrient solution supply unit 100 and the nutrient solution discharge unit 300 are vertically arranged and fixed to the frame 700. The frame 700 is formed as a skeleton of a hexahedron, but may be formed in any form as long as the nutrient solution supply unit 100 and the nutrient solution discharge unit 300 can be fixed.

The nutrient solution storage section 800 is a place where the nutrient solution supply section 100 or the nutrient solution discharge section 300 is stored.

The ultrasonic module 600 is installed between the nutrient solution storage part 800 and the nutrient solution supply part 100 and supplies the nutrient solution in the liquid state from the nutrient solution storage part 800 to spray the nutrient solution using the ultrasonic vibration, Converts to nutrient solution.

The connection pipe connects the ultrasonic module 600 and the nutrient solution supply unit 100 or connects the nutrient solution discharge unit 300 and the nutrient solution storage unit 800. The nutrient solution discharged from the ultrasonic module 600 is recovered to the nutrient solution reservoir 800 through the connection pipe.

Therefore, the nutrient solution is circulated in turn through the nutrient solution reservoir 800, the ultrasonic module, the nutrient solution supply unit 100, the cultivation bed 200, and the nutrient solution discharge unit 300, and is absorbed by plants planted in the cultivation bed 200.

FIG. 6 is a schematic view showing a part of a spray culture system according to an embodiment of the present invention.

In order to smoothly supply and discharge the nutrient solution in the nutrient solution supply unit 100 and the nutrient solution discharge unit 300, one side of the conduit 500 is connected to the connection pipe and the other side is closed. This is because the nutrient solution flows in one direction in the nutrient solution supply unit 100 and the nutrient solution discharge unit 300 so that the nutrient solution is supplied to each cultivating bed 200 in order or the nutrient solution is discharged from each cultivating bed 200.

As shown in the figure for smooth flow of the nutrient solution, one side of the conduit 500 of the nutrient solution supply unit 100 is connected to the connection pipe, and the nutrient solution is supplied and the other side is closed. In addition, one side of the conduit 500 of the nutrient solution discharge unit 300 is connected to the connection pipe, the nutrient solution is discharged, and the other side is closed.

At this time, in order to uniformly supply the nutrient solutions to the plurality of cultivation beds 200, the open side end and the closed side end of the conduit 500 of the nutrient solution supply unit 100 and the nutrient solution discharge unit 300 should be opposed to each other . Accordingly, the front side of the conduit 500 of the nutrient supply part 100 is opened and the rear side is closed, while the conduit 500 of the nutrient solution discharge part 300 is closed so that the rear side is opened.

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:
200: Growing Bed
210: Through hole
220: Growing bed side
300: nutrient solution discharge portion
400: Lighting device
500: channel
510: opening
520: Support
530: first seat portion
540: second seat portion
550: guide portion
560: reinforcement support
600: Ultrasonic Module
700: frame
800: Nutrient solution reservoir

Claims (17)

A nutrient solution supply unit through which the nutrient solution is supplied;
A cultivation bed installed above the nutrient solution supply unit and having an inlet for receiving the nutrient solution from the nutrient solution supply unit and an outlet for discharging the nutrient solution; And
Wherein the growth bed is provided on the upper side, and the nutrient solution discharge portion
Lt; / RTI > The method according to claim 1,
Further comprising: a nutrient solution storing portion for collecting the nutrient solution discharged from the nutrient solution discharging portion,
The outlet of the nutrient solution reservoir is connected to the inlet of the nutrient solution reservoir, the outlet of the nutrient solution reservoir is connected to the inlet of the growth bed, the outlet of the growth bed is connected to the inlet of the nutrient solution outlet, Is connected to the inlet of the nutrient solution reservoir. The method according to claim 1,
The nutrient solution supply unit and the nutrient solution discharge unit are,
Wherein the cultivation bed is mounted on the nutrient solution supply unit and the nutrient solution discharge unit, and is guided by the respective guide units to be slidable. The method according to claim 1,
The cultivation bed comprises:
And a plurality of the nutrient solution supply units and the nutrient solution discharge units are aligned. The method according to claim 1,
The nutrient supply part or the nutrient solution discharge part,
A conduit through which the nutrient solution flows and has an opening formed in a longitudinal direction on one side of the top;
A support portion formed along the longitudinal direction of the conduit and supporting the conduit; And
A first seating part extending from the opening and having a lower end of one side of the raised bed,
Lt; / RTI > 6. The method of claim 5,
Further comprising a second seating portion positioned between the first seating portion and the opening portion. The method according to claim 6,
The inlet and the outlet of the cultivation bed are connected to each other,
And a through hole formed on both sides of the lower end of the growth bed to correspond to the opening. 6. The method of claim 5,
And a guiding part extending upward from one side of the upper part of the channel to guide the sliding movement of the side of the upgrading bed. 6. The method of claim 5,
And a reinforcing support portion extending from one side of the upper portion of the channel and connected to the support portion. The method according to claim 1,
Wherein the nutrient solution supplied to the nutrient solution supply unit is vaporized by the ultrasonic module. The method according to claim 1,
The cultivation bed comprises:
Wherein the multi-stage cultivation system comprises a plurality of stages. The method according to claim 1,
The nutrient solution supply unit and the nutrient solution discharge unit are,
Wherein the multi-stage cultivation system comprises a plurality of stages. 13. The method of claim 12,
The nutrient solution supply unit and the nutrient solution discharge unit are,
Wherein the frame is vertically arranged and fixed to a frame constituted by a skeleton of a hexahedron. A first spray fluid pipe to which a spray nutrient solution vaporized by the ultrasonic module is supplied;
A cultivation bed having one side connected to the first sprayed liquid pipe to receive the nascent nutrient solution from a nutrient solution supply hole formed in the first sprayed nutrient solution pipe and planting the plant;
A second spray fluid pipe connected to the other side of the cultivation bed, in which a nutrient solution discharge hole is formed and the spray nutrient solution discharged from the cultivation bed is collected;
A pair of coupling members respectively coupled to the first spray fluid pipe and the second spray fluid pipe; And
A frame for fixing the pair of engagement members
/ RTI > wherein the plant is cultivated. 15. The method of claim 14,
Wherein the first spraying liquid pipe and the second spraying liquid pipe are vertically aligned. A nutrient supply part extending in the longitudinal direction and having an opening through which the nutrient solution is discharged to the upper side;
A nutrient solution discharging portion extending in the longitudinal direction and provided on the opposite side of the nutrient solution supplying portion and having an opening through which the nutrient solution flows into the upper side;
A cultivation bed which is slidably installed on the nutrient solution supply unit and the nutrient solution discharge unit and receives the sprayed nutrient solution from the nutrient solution supply unit and discharges the sprayed nutrient solution to the nutrient solution discharge unit; And
An ultrasonic module for converting a nutrient solution for plant cultivation into the nutrient solution for spraying
/ RTI > wherein the plant is cultivated. 17. The method of claim 16,
Further comprising a nutrient solution reservoir for collecting the nutrient solution discharged from the nutrient solution discharging portion, wherein the nutrient solution collected in the nutrient solution reservoir is supplied to the ultrasonic module.

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