KR101818219B1 - Fog-generating Hydroponics Apparatus - Google Patents

Abstract

The spraying hydroponics plant has a nutrient spraying device that is placed in the subspace where the root of the nutrient crops is exposed and is as long as the distance between the end-coupling holes, spraying the nutrient solution in the form of mist. The nutrient spraying device has a blower which is connected to the first opening side of the spray tube and introduces the outside air into the inside of the first opening and discharges the introduced inside air through the second opening.

Description

[0001] Fog-generating Hydroponics Apparatus [0002]

The present invention relates to a hydroponic cultivation apparatus, and more particularly, to a hydroponic cultivation apparatus for spraying water or a nutrient solution (hereinafter referred to as a nutrient solution) in a fine particle state to supply nutrients or moisture to roots of crops.

Cropland is decreasing, but seasonal consumption is becoming more common. Hydroponic cultivation, which can be harvested at all seasons, is widely used to meet these trends. Hydroponics grows crops using only water that does not use soil but dissolves various nutrients. Hydroponic cultivation includes feeding liquids in liquid form and fog.

Patent Registration No. 1477087 discloses a spraying hydroponic cultivation apparatus that supplies a nutrient solution in the form of mist. The apparatus includes an ultrasonic disintegration unit for ultrasonically decomposing the nutrient solution into fine particles, and a circulation fan for circulating the ultrasonic decomposed nutrient solution through the vertical spray supply pipe. The spray supply pipe is vertically erected, and a spray jetting hole is provided at every predetermined height to spray the spray supplied from the lower side to the side.

The prior art is composed of a portion for generating mist-like nutrient microparticles, a portion for moving the generated nutrient microparticles, and a portion for spraying nutrient microparticles in a specific region. However, such a configuration may consume energy excessively. In addition, the conventional art has a structure in which the nutrient solution fine particles are injected laterally through a plurality of ejection holes positioned at the same height, so that it may be difficult to uniformly supply the nutrient solution fine particles to the crops arranged in a plane.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art,

Firstly, it is possible to minimize the energy consumption in supplying fog type nutrient particulates to crops,

Second, it is intended to provide a spraying hydroponic cultivation apparatus capable of uniformly feeding nutrient solution fine particles throughout the crop.

In order to accomplish the above object, the present invention provides a hydroponic cultivation apparatus comprising a case, a support frame, a nutrient spraying apparatus, and the like.

The case has a space inside.

The support frame may have a plurality of coupling apertures for engaging the crop cultivation cask.

The nutrient spray device may be disposed in a subspace where the root of the crop among the sub-spaces of the support frame is exposed. The nutrient spraying device may have a length corresponding to the distance between two engaging holes located at both ends of at least a plurality of engaging holes.

The nutrient spraying device is capable of spraying the nutrient solution in the form of mist, and can be configured to include a spray tube, a blower, a sprayer, and the like.

The spray tube has first and second openings and a hollow at both ends thereof, and the hollow can communicate the first and second openings.

The blower may be coupled to the first opening side of the atomizing tube to introduce the outside air into the interior of the first opening. The blower can discharge the introduced internal air to the outside of the atomizing tube through the hollow of the atomizing tube and through the second opening.

The atomizer may be coupled in the spray tube at the second flank side. The atomizer may crush the nutrient into fine particles and then spray the inner surface of the spray tube.

In the spraying hydroponic cultivation apparatus according to the present invention, the blower may cause a pressure difference between the first and second openings. The pressure difference can convect the fog nutrient released from the second opening from the outside of the spray tube to the first opening direction. Thereby, the blower can evenly distribute the fog nutrients to the outside along at least the longitudinal direction of the spray tube.

The spraying hydroponic cultivation apparatus according to the present invention may include a shutoff plate. The blocking plate may be disposed between the atomizer and the second opening. The blocking plate may be in the form that the edge is slightly spaced from the inner surface of the atomizing tube to partially close the hollow of the atomizing tube. The blocking plate can increase the pressure near the second opening, especially between the atomizer and the second opening.

The spraying hydroponic cultivation apparatus according to the present invention includes a nutrient bottle and a supply pipe, and may optionally include a heater, a cooler, an oxygen generator, and the like.

Nutrient bottles can store nutrients.

Feed piping can move the nutrient to the sprayer.

A heater for heating the nutrient solution, a cooler for cooling the nutrient solution, and an oxygen generator for supplying oxygen to the nutrient solution may be optionally included.

The spraying hydroponic cultivation apparatus according to the present invention may include a nutrient recovery unit. The nutrient recovery unit can be installed at the bottom of the nutrient spraying unit or at the bottom of the case.

The spraying hydroponic cultivation apparatus according to the present invention may include an extension pipe which is connected to the first opening side of the spraying tube.

In the spraying hydroponic culture apparatus according to the present invention, the nutrient spraying apparatus can be arranged horizontally and / or vertically in the case. In this case, the spraying hydroponic cultivation device may include a branch supply piping branching off the nutrients to a plurality of nutrient spraying devices.

According to the spraying hydroponic cultivation apparatus of the present invention having such a configuration, energy consumption can be minimized by moving the fog nutrients using natural convection. In addition, since the blocking plate forms a high pressure in the portion where the fog nutrient is generated, not only the efficiency of generating the fog nutrient can be increased, but also the generated mist nutrient can be ejected at a high pressure.

Further, according to the spraying hydroponic cultivation apparatus of the present invention, the fog nutrient can be evenly distributed along the longitudinal direction from the outside of the case spray tube due to the high-pressure discharge of the fog nutrient and the natural convection of the fog nutrient, It is possible to supply water and nutrition evenly throughout the crops disposed adjacent to the plant.

1 is a configuration diagram of a spraying hydroponic cultivation apparatus according to the present invention.
2 is a configuration diagram of an atomizer of a spraying hydroponic cultivation apparatus according to the present invention.
3 is a block diagram showing another embodiment of the atomizer of the spraying hydroponic cultivation apparatus according to the present invention.
4 is a configuration diagram of another embodiment of a spraying hydroponic cultivation apparatus according to the present invention.
5 is a configuration diagram of another embodiment of a spraying hydroponic cultivation apparatus according to the present invention.
FIG. 6 shows an embodiment in which an extension pipe is connected to a nutrient spraying device in a spraying hydroponic cultivation apparatus according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a spraying hydroponic cultivation apparatus according to the present invention.

1, the apparatus for spraying hydroponic culture according to the present invention includes a case 100, a support frame 200, a nutrient spraying apparatus 300, a nutrient solution bottle 400, a nutrient solution collection unit 500, A door 610, a door 700, a control unit 800, and the like.

The case 100 can be formed in various shapes such as a hexahedron and a cylinder, and the whole or part of the enclosed space can be formed inside. The case 100 is made of plastic, wood, sponge, etc., but the material is not limited, and a form frame and a plastic can be combined.

The case 100 may have a frame support for supporting the support frame 200 at a predetermined height on the inner wall thereof. The frame support may be formed by projecting a rectangular plate material along the inner wall. The support frame 200 can be fixed by coupling an edge of the support frame 200 to the frame support of the case 100.

The support frame 200 may be formed by molding an absorbent material such as hard synthetic resin or glass wool into a plate shape, or may be formed by molding a sponge material.

The support frame 200 can form a plurality of engaging holes H1 through which the crop cultivation tub 210 is inserted. The through holes H1 may be formed in a cup shape, which may be adjusted according to the shape of the crop cultivation vessel 210, and may be formed at equal intervals throughout the support frame 200.

The support frame 200 can separate the inner space of the case 100 into a plurality of sub-spaces S1 and S2. The support frame 200 is horizontally coupled to the inner wall of the case 100 and is divided into an upper sub space S1 in which leaves of the crop 220 are located and a lower sub space S2 in which roots of the crop 220 are located Can be separated. When cultivating the crop 220 with an artificial light source (not shown), the upper sub-space S1 can be configured as a closed space. However, when cultivating the crop 220 using natural light, the upper sub-space S1 may not be a closed space but may be an open space or some closed space.

The nutrient spraying device 300 can eject the nutrient solution in the form of mist. The nutrient spray device 300 may be disposed in the lower sub space S2 where the roots of the crop 220 are exposed. The nutrient solution spraying device 300 may have a length corresponding to a width between two coupling holes H1 at both ends in the longitudinal direction of the support frame 200 among at least a plurality of coupling holes. In this way, the nutrient spraying device 300 can supply the fog nutrient to the entire crop 220.

The nutrient spraying apparatus 300 may include a spraying tube 310, a blower 320, a sprayer 330, and the like.

The spraying tube 310 has first and second openings T1 and T2 at both ends in the horizontal direction and a hollow is formed between the first and second openings T1 and T2 to communicate with each other.

The blower 320 may include a blowing motor 321, a blowing fan 323, and the like. The blower 320 may allow air to flow from the first opening T1 to the second opening T2 so that the fog nut generated by the sprayer 330 can be discharged through the second opening T2. The blower 320 moves air from the first opening T1 to the second opening T2 to lower the pressure near the first opening T1 and increase the pressure near the second opening T2 , And the pressure difference between the first and second openings (T1, T2). This pressure difference may cause the fog nutrient released from the second opening T2 to move from the outside of the spray tube 310 toward the first opening T1, that is, to cause a natural convection phenomenon. This convection phenomenon can evenly distribute the fog nutrients along the longitudinal direction of the spray tube 310 from the outside of the spray tube 310 and as a result the whole of the lower subspace S2 in which the root of the crop 220 is located It is possible to evenly distribute the fog nutrients across the entire surface.

The sprayer 330 can spray the nutrient solution in a radial manner to be firstly pulverized into fine particles and further collide with the inner surface of the spraying tube 310 to achieve complete fogging of the nutrient solution. The sprayer 330 may include a spray motor 331, a rotating body 333, and the like. The detailed description of the sprayer 330 will be given later with reference to FIG.

The nutrient solution bottle 400 stores the nutrient solution and can supply the nutrient solution to the sprayer 330 through the supply pipe 610.

The pump P can be installed on one side of the liquid tank 400 or on the supply line 610 and can supply the nutrient solution from the liquid tank 400 to the sprayer 330 smoothly.

The heater 410 and the cooler 420 may be coupled to the nutrient bottle 400. The heater 410 may heat the nutrient solution, and the cooler 420 may cool the nutrient solution. The growth temperature may be different for each crop 220. Some crops can grow at 25 to 30 ° C and some crops can grow at 5 to 10 ° C. In this case, the nutrient temperature needs to be adjusted to the growth temperature of the crop 220. By the way, it is difficult if we do not overcome seasonal temperature difference in hydroponic cultivation aiming for private industry cultivation. In summer, the cooler 420 is operated to lower the temperature of the nutrient solution, and in winter, the heater 410 can be operated to increase the temperature of the nutrient solution.

The oxygen generator 430 generates oxygen and supplies it to the nutrient solution, so that the dissolved oxygen amount of the nutrient solution can be increased.

The heater 410, the cooler 420, and the oxygen generator 430 may be selectively installed depending on the environment.

The nutrient recovery unit 500 can collect the nutrient liquid in which the fog nutrient is condensed and falls downward or fogged. The nutrient solution collecting unit 500 may be installed at a lower end of the nutrient spraying apparatus 300 or at a lower end of the case 100. The nutrient solution collecting part 500 can tilt the bottom surface to collect the recovered nutrient solution in one direction. The nutrient solution recovery unit 500 may include a recovery pipe 620 to transfer the recovered nutrient solution to the nutrient solution bottle 400.

The door 700 is provided on one side of the case 100, and can selectively open and close one side of the case 100.

The control unit 800 may be installed in the case 100 or the door 700. The control unit 700 controls the blower motor 321, the spray motor 331, the pump P, the heater 410, the cooler 420, the oxygen generator (430) and so on. The control unit 800 can also control the opening and closing of the valve when the valve is provided in the supply pipe 610 and the return pipe 620. [ When the temperature sensor, the heater, and the like are installed in the case 100, the control unit 800 may control the temperature sensor and the heater to maintain the temperature in the case 100 in a predetermined range.

2 is a configuration diagram of an atomizer of a spraying hydroponic cultivation apparatus according to the present invention.

As shown in FIG. 2, the atomizer 330 can be composed of a spray motor 331, a rotating body 333, and the like.

The atomizing motor 331 can rotate the rotating shaft 333 connected to the rotating body 333 to rotate the rotating body 333. The atomizing motor 331 can be fixed to the inside of the atomizing tube 310 via the bracket 332.

The rotating body 333 can radially spray the nutrient supplied to the inside while rotating. The rotating body 333 includes a plurality of disk bodies P1 and P2 and the disk bodies P1 and P2 may have a hollow portion through which the nutrient solution flows into the inner center. The circular plates P1 and P2 may have a plurality of spouting flow paths F communicating with the inner hollow portion and extending radially and then opening at the outer surface. The jet flow path F may have a circular, elliptical, rectangular or other cross-section.

The circular plates P1 and P2 are provided with a plurality of bolt holes in the width direction and the adjacent circular plates P1 and P2 are axially coupled to each other in such a manner that the bolts inserted through the bolt holes are coupled to each other using a nut on the opposite side. can do. The shielding plate 335 can be coupled to the disk P2 which is coupled to the supply pipe 610 in the outward direction. The blocking membrane 335 can prevent the influent nutrient from leaking sideways from the disk P2. The disk P2 and the shielding film 335 may be combined with a nut formed in the disk P2 and a through hole formed in the shielding film 335 by inserting a bolt. Alternatively, the blocking film 335 may integrally constitute the rotating shaft 334 and the disk P2.

The supply pipe support 340 is formed by placing the outlet of the supply pipe 610 inside the rotating body 333, and can be formed as a frame of a 'C' shape. Both ends of the supply pipe support 340 can be coupled to the outer surface of the spray tube 310. A supply pipe 610 is installed in the supply pipe support 340 so as to support the supply pipe 610 or a supply pipe fixture 341 is provided at the center as shown in FIG. 610).

3 is a block diagram showing another embodiment of the atomizer of the spraying hydroponic cultivation apparatus according to the present invention.

As shown in FIG. 3, the supply pipe support 340 may have a shutoff plate 343. The blocking plate 343 can be configured to be coupled to the supply pipe fixture 341. The blocking plate 343 may be disposed between the rotating body 333 and the second opening T2. The blocking plate 343 may have a diameter slightly smaller than the inner diameter of the spray tube 310, and the center may be configured to completely close the second opening T2. The blocking plate 343 prevents the air blown from the blower 320 from being released through the second opening T2 and may cause an increase in pressure near the second opening T2. In addition, it is possible to increase the probability that the mist liquid discharged from the rotating body 333 collides with the inner surface of the spray tube 310 without being immediately discharged through the second opening T2. Through this action, the blocking plate 343 can increase the degree of fogging of the nutrient solution, and can discharge the fog nutrient solution through the second opening T2 at a high pressure.

4 is a configuration diagram of another embodiment of a spraying hydroponic cultivation apparatus according to the present invention.

As shown in FIG. 4, the spraying hydroponic cultivation apparatus can be constructed by horizontally arranging a plurality of the nutrient spraying apparatuses 300. In this case, the plurality of nutrient spraying apparatuses 300 can receive the nutrient solution from the nutrient solution bottle 400 via the branched supply pipe 630 branched horizontally.

5 is a configuration diagram of another embodiment of a spraying hydroponic cultivation apparatus according to the present invention.

As shown in FIG. 5, the spraying hydroponic cultivation apparatus may be constructed by arranging a plurality of the nutrient spraying apparatuses 300 horizontally and vertically. In this case, the nutrient spray apparatus 300 can supply the nutrient solution through the branch supply pipe 640 branched horizontally and vertically.

FIG. 6 shows an embodiment in which an extension pipe is connected to a nutrient spraying device in a spraying hydroponic cultivation apparatus according to the present invention.

As shown in FIG. 6, an extension pipe 900 can be connected to the nutrient spraying apparatus 300. The extension pipe 900 may be a cylindrical pipe that can be coupled to the first opening of the spray tube. The extension pipe 900 is formed in the case 100 so that the length of the nutrient spraying apparatus 300 is shorter than the length of the case 100 or the support frame 200, As shown in FIG.

Although the present invention has been described based on various embodiments, it is intended to exemplify the present invention. Those of ordinary skill in the art will appreciate that variations and modifications may be made to the embodiments based on the above embodiments. However, since the scope of the present application is determined by the following claims, such variations and modifications can be construed as being included in the following claims.

100: Case 200: Support frame
300: Nutrient spray device 310: Spray tube
320: blower 330: atomizer
340: supply pipe support 341: supply pipe fixture
343: Blocking plate 400:
500: Nutrient recovery part 610: Supply piping
620: Return pipe 630,640: Branch supply pipe
700: Door 800:
900: Extension piping

Claims (6)

In a spraying hydroponic cultivation apparatus,
A case having a space therein;
A support frame coupled to the case, the support frame having a plurality of engaging holes for engaging the crop cultivation cask; And
And a nutrient spraying device arranged in a space in which the root of the crop is exposed in the case, the nutrient spraying device having a length corresponding to at least a distance between the engaging holes located at both ends of the plurality of engaging holes,
The nutrient spraying apparatus
A spray tube having first and second fins at both ends thereof and having a hollow communicating with the first and second fins;
A blower connected to the first opening side of the spray tube for introducing outside air into the inside of the first opening and discharging the introduced inside air through the hollow opening through the second opening;
A sprayer coupled to the spray tube at the second opening side, for spraying the spray of the nutrient solution on the inner surface of the spray tube; And
And a blocking plate disposed between the atomizer and the second opening and having an edge slightly spaced from an inner surface of the atomizing tube to partially close the hollow of the atomizing tube to increase the pressure near the second opening,
The pressure difference generated between the first and second openings conveys the fog nutrient discharged from the second openings from the outside of the spraying tube in the direction of the first opening to uniformly distribute the fog nutrients from outside the spraying tube Wherein the spraying device is a spraying device. delete The method according to claim 1,
A nutrient bottle for storing the nutrient solution;
A supply pipe for moving the nutrient solution to the atomizer;
A heater for heating the nutrient solution, a cooler for cooling the nutrient solution, and an oxygen generator for supplying oxygen to the nutrient solution. The method according to claim 1,
And a nutrient solution collecting part at the lower end of the nutrient solution spraying device or at the lower end of the case. The method according to claim 1,
And an extension pipe which is connected to the first opening side of the spray tube. 5. The method according to any one of claims 1, 3, 4,
Wherein the nutrient spraying device is arranged in a plurality of horizontal and / or vertical directions in the case,
And a branch supply pipe for branching and supplying the nutrients to the plurality of nutrient spraying apparatuses.

Images