KR20170057996A

KR20170057996A - Vertical-type hydroponic cultivation equipment

Info

Publication number: KR20170057996A
Application number: KR1020150161603A
Authority: KR
Inventors: 정경균
Original assignee: 정경균
Priority date: 2015-11-18
Filing date: 2015-11-18
Publication date: 2017-05-26
Also published as: KR101845228B1

Abstract

The present invention relates to a vertical hydroponic cultivation apparatus, and more particularly, to a vertical hydroponic cultivation apparatus, in which a port including a plurality of seeds is vertically installed in a single support and a nutrient solution is supplied to each port, The present invention relates to a new type of vertical hydroponic cultivation apparatus capable of smoothly regulating the supply of inflow water and sparse liquid and improving the yield of crops by increasing the utilization of space as well as promoting growth by allowing each port to receive sunlight uniformly will be.

Description

[0001] Vertical-type hydroponic cultivation equipment [0002]

More particularly, the present invention relates to a vertical hydroponic cultivation apparatus, and more particularly, to a vertical hydroponic cultivation apparatus in which a port including a plurality of seeds is vertically installed on one support, nutrients are supplied to each port through a nutrient solution pipe, The present invention relates to a new type of vertical hydroponic cultivation apparatus capable of smoothly regulating the supply of inflow water and sparse liquid and improving the yield of crops by increasing the utilization of space as well as promoting growth by allowing each port to receive sunlight uniformly will be.

Generally, hydroponic cultivation refers to a method of cultivating a plant by using a culture medium made of water and a water-soluble nutrient by using an artificial pond or a container capable of supporting the plant without using soil, soilless culture, water culture. The advantage of hydroponics is the ability to directly observe the condition and growth of roots, produce uncontaminated clean vegetables and plants continuously, and mass-produce commercially. Multipurpose indoor hydroponic cultivation equipment can be cultivated easily by anyone in the house, and it also plays a role of cultivating emotions and utilizing it as a living gardening.

Plants that can be hydroponically cultivated include hydroponics such as cucumber, tomato, red pepper, paprika and strawberry, lettuce, lettuce, lettuce, kale, parsley It is possible to cultivate hydroponics such as leafy vegetables, chrysanthemums, roses, gerberas, lilies, begonia, anthurium, etc., flowers, ginsengs and some medicinal plants.

However, the hydroponic cultivation as described above has the effect of preventing the occurrence of the lumbar disease of workers by allowing the plants to grow at a certain height from the ground, but the crops can not be cultivated in various layers, There is a difficult problem.

In order to solve the above problems, the stepwise hydroponic cultivation apparatus of Patent Registration No. 10-0533170 (registered on Nov. 26, 2005)

A sloping channel (30) installed parallel to each other at regular intervals;

A cultivation pipe (10) laid stepwise across the channel (30) and having a plurality of installation holes (12) formed on its upper surface;

A reservoir (40) installed below the water channel (30) to store water flowing along the water channel (30); And a pump 50 for discharging the water introduced through the inflow pipe 51 connected to the reservoir 40 to the upper part of the water channel 30 through the discharge pipe 52,

And a supply hole 11 is formed at both ends of the cultivation pipe 10 by cutting the upper half of the pipe so that water supplied along the water channel 30 is supplied.

However, since the cascade hydroponic cultivation apparatus has a limited space utilization, the operation range of the worker is narrow and the operation efficiency is lowered. In particular, the water flow can be maintained by the pump, but in order to supply the nutrients to the respective ports, To be manually supplied to each port.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and it is an object of the present invention to improve the yield of a farmhouse by efficiently using a cultivation space of a farmhouse, such as a house facility, It is another object of the present invention to provide a new type of hydroponic cultivation apparatus capable of promoting growth by preventing crops from getting sunlight evenly through vertical hydroponic cultivation and preventing a worker from losing their back and maintaining a pleasant cultivation environment.

In order to achieve this object,

According to an aspect of the present invention,

(10) having a bottom mounted on the ground and having a plurality of horizontal bars (12) and vertical bars (11) connected to each other;

A supply pipe 20 fixed to the upper part of the support table 10,

A discharge pipe (30) fixed to a lower portion of the support (10) and vertically positioned with the supply pipe (20);

A plurality of nozzles 41 and a discharge port 42 are formed on the surface of the supply pipe 20 so that the nutrient solution formed between the supply pipe 20 and the discharge pipe 30 can be discharged to the discharge pipe 30 A plurality of drop tubes (40)

And a plurality of ports 50 mounted on the nozzle 41 and the discharge pipe 42 of the drip tube 40 and supplied with the nutrient solution to the culture soil contained therein.

The nozzle 41 has a body 411 having a screw thread 412 formed on the outer surface thereof and a hole 413 formed on both sides thereof.

A spring 414 formed in the body 411 and a stopper 415 having one side of the tightly fitting part 4151 close to the spring 414 and a protrusion 4152 integrally formed on the other side, And,

An engaging plate 416 screwed to the thread 412 of the body 411;

And a sealing O-ring 417 fitted to the outer surface of the protrusion 4152.

The check valve 60 is further provided at a portion where the discharge port 42 and the drop pipe 40 are connected to prevent the nutrient solution from flowing into the discharge port 42 of the drop pipe 40.

A locking protrusion 55 is further formed at a portion where the insertion groove 53 of the port 50 is formed so that the locking protrusion 55 can be fixed at a lower portion of the locking plate 416 of the nozzle 41 to be coupled.

As described above, the vertical hydroponic cultivation apparatus according to the present invention includes a plurality of support rods in a limited cultivation facility space such as a house, a port including seeds is vertically installed in the support rods, nutrients It is possible to efficiently utilize the limited cultivation space, thereby improving the yield of crops. In particular, it has the effect of enhancing the quality of crops by growing the crops to be grown under sufficient sunlight.

In addition, an injection port capable of supplying a zero-liquid solution can be connected to a port vertically formed on a support, and the nutrient can be easily supplied to the port, and the supply pipe not connected to the port is naturally blocked to prevent leakage of nutrient solution. The environment can be maintained.

1 is a perspective view of a vertical hydroponic cultivation apparatus according to the present invention;
Fig. 2 is an enlarged perspective view of the vertical hydroponic cultivation apparatus according to the present invention. Fig.
Fig. 3 is an enlarged cross-sectional view of the vertical hydroponic cultivation apparatus according to the present invention,
FIG. 4 is an enlarged cross-sectional view of a vertical hydroponic cultivation apparatus according to the present invention,
FIG. 5 is a perspective view of a vertical hydroponic cultivation apparatus according to the present invention,

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

FIG. 1 is a perspective view of a vertical hydroponic cultivation apparatus according to the present invention, FIG. 2 is an enlarged perspective view of a vertical hydroponic cultivation apparatus according to the present invention, FIG. 3 is a vertical hydro flotation apparatus according to the present invention, FIG. 4 is an enlarged cross-sectional view showing a state in which a vertical hydroponic cultivation apparatus according to the present invention is combined with a soil bed. FIG.

As shown in the figure, the vertical type hydroponic cultivation apparatus 100 according to the present invention includes a support platform 10 that is largely placed on the ground, a supply pipe 20 fixed to the upper portion of the support platform 10, and a discharge pipe 30 A plurality of drip tubes 40 connected between the supply tube 20 and the discharge tube 30 and having a plurality of nozzles 41 and a discharge port 42 and a port 50 connected to the nozzle 41 .

The support base 10 is a structure for fixing the installation form of the supply pipe 20, the discharge pipe 30 and the drop pipe 40. The support bar 10 integrally forms the horizontal bars 12 on the upper side of the vertical bars 11 on both sides So that the drop pipe 40 can be positioned vertically from the ground.

The supply pipe 20 is fixed to the transverse bar 12 of the supporter 10 by a band 21 so that the nutrient solution flows into the supply pipe 20 and a plurality of drop pipes 40 communicate with each other.

The drain pipe 30 is connected to a lower portion of the drop pipe 40 connected to the supply pipe 20 so that the nutrient solution flowing into the drop pipe 40 is discharged to the outside of the inflow pipe. do.

A plurality of nozzles 41 and an outlet 42 are assembled to the outside of the drip tube 40 so that the nutrient solution flowing in the drip tube 40 flows into the port 50 to be coupled to the nozzle 41, Circulated and then discharged through the discharge port 42 again.

The nozzle 41 has a hole 413 formed on both sides thereof with a thread 412 formed on the outer surface of the cylindrical body 411 and the spring 414 and the stopper 415 are accommodated in the inside thereof, The plate 416 is screwed.

The cap 415 has an annular adhered portion 4151 and a protrusion 4152 integrally formed at a central portion thereof and the sealing plate 4153 is inserted into an edge of the protrusion 4152.

The locking plate 416 assembled to the thread 412 of the body 411 inserts a sealing O-ring 417 into the connection portion to prevent the nutrient solution from leaking.

The discharge port 42 is formed with a hopper-shaped receiving portion 421 having one side connected to the drop pipe 40 and the other side to which the port 50 is seated. 42) so that they can flow into the piping tube.

In addition, a check valve 60 is further provided at a portion where the discharge port 42 and the drop pipe 40 are connected to prevent the nutrient solution of the drop pipe 40 from flowing into the discharge port 42.

The port 50 has a structure in which seeds are planted in the state that the culture soil is accommodated therein. Specifically, a plurality of discharge holes 52 are formed in the lower part of the housing 51 of the housing shape, and the insertion grooves 53 ) Are formed integrally with each other.

A locking protrusion 55 and a plurality of inflow holes 56 are formed in the insertion groove 53.

The port 50 which is fastened to the drip tube 40 as described above is formed such that the nutrient solution is introduced into and discharged from the port 50 through the nozzle 41 and the outlet port 42, The environment to be cultivated is formed together with the culture soil.

The following is a detailed description of the fastening process of the drip tube 40 and the port 50 according to the present invention with reference to FIGS. 3 to 4. FIG.

Fig. 3 shows a state in which the drip tube and the port are separated.

As shown in the drawing, the nozzle 41 formed in the drop pipe 40 is tightly attached to the inner surface of the body 411 at one end by the spring 414 inside, thereby preventing the nutrient solution from leaking out .

4, the port 50 is fastened to the nozzle 41, so that the fastening plate 416 of the nozzle 41 is inserted into the insertion groove 53 of the port 50. As a result, The end of the stopper 415 of the nozzle 41 is retracted while pressing the pressure of the spring 414 in a state of being in close contact with the portion of the inlet hole 56 of the port 50, And the zero liquid medicine in the drop pipe 40 flows into the port 50 through the nozzle 41 through the hole 413 formed on both sides of the body 411 by opening the hole 413 of the body 411. [

The port 50 fastened to the nozzle 41 has a shape in which the fastening plate 416 of the nozzle 41 is wrapped by the fastening surface 54 and at the same time, And the lower portion of the port 50 is surrounded by the receiving portion 421 of the discharge port 42, so that the fastened state can be safely maintained.

In addition, the inflowing spiral liquid is mixed with the culture soil to help the seeds grow, and the rest is discharged to the discharge port 42 through the discharge hole 52 formed in the lower part of the port 50, Thereby preventing clogging of the cultivated soil.

The nutrient solution flowing through the interior of the drip tube 40 can be accurately supplied to the port without leaking through the tightening relationship between the drip tube 40 and the port 50 as described above and the excessive supply is naturally prevented, Can be provided.

Further, when the port (50) is not fastened to the nozzle (41), the nozzle is automatically closed to prevent the leakage of the nutrient solution.

The nutrient solution is introduced into the supply pipe 20 and supplied to the respective ports 50 through the plurality of nozzles 41 formed in the drop pipe 40 and then discharged through the discharge pipe 30. [ It is preferable to connect the circulation motor (not shown) by connecting the supply pipe 20 and the discharge pipe 30 so that the nutrient solution circulates and can be partially introduced into the port 50 through the nozzle 41.

On the other hand, Fig. 5 shows another embodiment of the port.

In this embodiment, when the port has a wide bed shape, a plurality of insertion grooves that can be fastened to the nozzles can be formed on one side of the port, and the ports of the wide bed can be securely fastened to the nozzles by fastening them together with the nozzles of the neighboring drop pipe .

The present invention has been described with reference to the embodiments shown in the attached drawings, but it will be understood that various modifications and other embodiments are possible for those skilled in the art.

10: support 11: vertical bar
12: horizontal bar 20: supply pipe
30: discharge pipe 40: drip pipe
41: nozzle 411: body
412: thread 413: hole
414: spring 415: stopper
416: Retaining plate 42: Outlet
421: receiving portion 50: port
51: Housing 52: Exhaust hole
53: grooved groove 54:
55: stopper 56: inflow hole

Claims

(10) having a bottom mounted on the ground and having a plurality of horizontal bars (12) and vertical bars (11) connected to each other;
A supply pipe 20 fixed to the upper part of the support table 10,
A discharge pipe (30) fixed to a lower portion of the support (10) and vertically positioned with the supply pipe (20);
A plurality of nozzles 41 and a discharge port 42 are formed on the surface of the supply pipe 20 so that the nutrient solution formed between the supply pipe 20 and the discharge pipe 30 can be discharged to the discharge pipe 30 A plurality of drop tubes (40)
And a plurality of ports (50) mounted on the nozzle (41) and the discharge pipe (42) of the drip tube (40) to supply the nutrient solution to the culture soil contained therein.

The method according to claim 1,
The nozzle 41 has a body 411 having a screw thread 412 formed on the outer surface thereof and a hole 413 formed on both sides thereof.
A spring 414 formed in the body 411 and a cap 415 having one side of the tightly fitting part 4151 close to the spring 414 and a protrusion 4152 integrally formed on the other side, And,
An engaging plate 416 screwed to the thread 412 of the body 411;
And a sealing O-ring (417) fitted to an outer surface of the protrusion (4152).

The method according to claim 1,
And a check valve (60) at a portion where the discharge port (42) and the drop pipe (40) are connected to prevent the nutrient solution of the drop pipe (40) from flowing into the discharge port Cultivation device.

The method according to claim 1,
A locking protrusion 55 is further formed at a portion where the insertion groove 53 of the port 50 is formed so that the locking protrusion 55 can be fixed at the lower portion of the locking plate 416 of the nozzle 41 to be coupled. Hydroponic cultivation equipment.