KR20160027868A - Spray culturing system for greenhouse - Google Patents

Abstract

The present invention relates to a greenhouse spray culturing system constructed to realize the maximal close planting cultivation in a limited greenhouse space. The present invention provides a greenhouse spray culturing system which can be applied to any types of the greenhouse, which enables close planting cultivation, and which is capable of solving a problem of obtaining a work space and a lighting control amount shortage due to mutual shielding between cultivation beds. A greenhouse spray culturing system according to the present invention includes: a plurality of horizontal supporting units installed between a plurality of pillars in a greenhouse to provide horizontal supporting force; a plurality of supporting bars at least one side of which is mounted on the horizontal supporting units such that the supporting bars have a right angle to each of the horizontal supporting units from a horizontal direction, and which is constructed to be rotatable by a motor; and a plurality of cultivation beds which are mounted on the bottom of each of the supporting bars by means of a hanger unit, and which are lifted by being expanded and contracted together with the hanger unit as each of the supporting bars is rotated. The greenhouse spray culturing system is constructed to adjust the height of each of the cultivation beds in each of the supporting bar units as the cultivation beds are lifted by controlling the rotation of each of the supporting bars.

Description

{Spray culturing system for greenhouse}

The present invention relates to a greenhouse spraying system configured to achieve maximum flush cultivation in a limited greenhouse space.

Greenhouse cultivation system, in which greenhouse cultivars are grown by spraying culture instead of soil, is mainly applied to cultivation of crops at a height of about 1 m.

The higher the growth rate than the soil cultivation, the more the initial facility cost is, but the vertical space can be utilized and the location of the cultivation bed can be controlled along with the sunlight.

However, in the conventional cultivation method, it is necessary to secure a work space for moving between cultivated beds and distance between the cultivated beds is required in order to prevent mutual shielding.

Korean Patent No. 0226152 proposes a multi-stage transport facility cultivation method in which the planting material moves along the closed curve to continuously meet the same growth conditions while the greenhouse works are not moved to the center of the greenhouse, In order to make it possible to perform it conveniently in the Internet.

Although the prior art related to greenhouse cultivation has been searched for a large number, prior art related to the problem of the present invention has been hardly found, and the portable farming technology described above is that the planting material continuously moves along the closed curve in the greenhouse, It can be predicted that the waste of energy required for the movement will be severe, and the continuous movement may have a negative effect on the growth of the plant, and the initial facility cost also increases.

The present invention provides a greenhouse spraying system which can be applied to any type of greenhouse and can solve the problem of insufficient working space due to the mutual shielding between the cultivation bed and the problem of securing the work space,

The present invention relates to a method of manufacturing a greenhouse, comprising: a plurality of horizontal supports installed to provide a horizontal support force between a plurality of columns in a greenhouse; A plurality of support rods mounted at right angles to one another in the horizontal direction with respect to the respective horizontal supports and configured to be rotatable by a motor; And a plurality of raising and lowering rods mounted on the lower portion of each of the supporting rods via a hanger portion to be elevated and lowered together with the hanger portion as the supporting rods rotate, And the height of each cultivation bed can be adjusted by each supporting rod unit.

According to one aspect of the present invention, the support rod is supported at one end by a bearing provided on the horizontal support portion, and the motor and the support rod are connected to each other by a timing belt, so that a rotation force is generated in the support rod by driving the motor.

According to an aspect of the present invention, the cultivating bed is supported on the lower portion of the support bar by the row rejection, and one end of the hanger part is wound on the support bar so that the hanger part can be wound and stretched as the support bar rotates Wherein the cultivation bed includes a re-plate having a plurality of re-groves formed therein for planting the plant, and a culture unit attached to the re-plate at both sides of the re-plate so as to surround the re-plate to form a culture space for the plant, And the culture liquid is sprayed into the culture section.

According to an aspect of the present invention, the hanger portion supporting the cultivation bed is in an inverted Y-shape, the split portion supports both ends of the re-plate to balance, and the straight portion is connected to the support rod, Only the part is rolled or loosely stretched or contracted.

According to another aspect of the present invention, a sunlight tracking unit is further provided on one side of the greenhouse so as to automatically track the position of the sunlight to control the rotation of the support rod to adjust the height of the growth bed.

According to the present invention, the cultivating beds can be arranged stepwise in any direction in the front, rear, left, and right directions of the support rods, and the height of the cultivation bed can be easily adjusted.

Also, it is possible to maximize the cultivation efficiency by automatically controlling the point where the irradiation amount is maximum by combining the sunlight tracking part and automatically controlling to be a stepwise arrangement.

1 is a schematic view showing a front surface of a greenhouse dispensing system according to the present invention.
2 is a view showing the overall structure of a support rod and a horizontal support portion.
Fig. 3 is a detailed view of the coupling relationship with the portion A in Fig.
4 is a view showing an embodiment in which a growth bed is mounted on a support rod.
Fig. 5 is a cross-sectional view of the re-plate of the Fig. 4 growing bed.
6 is a view showing an embodiment in which cultivation is performed in a growing bed.
7 is a view of a solar ray tracking unit attached to the upper part of the greenhouse.

TECHNICAL FIELD The present invention relates to a greenhouse spraying system, and more particularly, to a greenhouse spraying system in which greenhouse cultivars such as strawberries are cultivated in a hermetically cultivated manner.

Hereinafter, technical features of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic view showing a front surface of a greenhouse dispenser system according to the present invention and includes a greenhouse 10, a driving unit 20, a cultivation bed 30, and a solar tracking unit 40.

Various types of greenhouses can be applied to the present invention and basically include a column 11 and a horizontal support 12 which crosses the column 11 and supports the horizontal axis.

The greenhouse 10 crosses a plurality of columns 11 and a plurality of horizontal supports 12 to form a supporting structure.

The driving unit 20 includes a motor unit 21, a support bar 22, a bearing 23, and a timing belt 24 as a part for adjusting the elevation of the cultivation bed 30.

Figure 2 is a schematic representation of the overall structure in which a plurality of support rods 22 and a plurality of horizontal supports 12 are crossed and connected.

In reality, the plurality of support rods 22 are separately separated from each other and perform the rotation operation by the individual drive portions 20, respectively.

A plurality of support rods 30 are mounted on the support rods 22 and the portion A of FIG. 2, which is the unit support rods 22, is shown in detail in FIG.

When the motor 21 is driven, the timing belt 24 drives the support rod 22 to rotate, and the support rod 22 is firmly fixed by the bearing 23.

4 shows a state in which a plurality of cultivation beds 30 are mounted on the support rods 22 and the cultivation bed 30 includes a row reject 31, a re-plate 32, a cultivation unit 33, (34), a culture solution mounting part (35), and a culture solution supply part (36).

The row rejection 31 may be implemented by a variety of materials such as wire as a configuration for mounting the cultivation bed 30 on the support bar 22 in a hanger manner and the cultivation unit 33 includes a waterproof function and a light shielding function desirable.

Shaped portion 31b is in contact with the support rod 22 so as to be in contact with the support rod 22 Only the linear portion 31b is rolled or loosely stretched or contracted when rotated.

4A is a state in which the row rejection 31 is released from the support rod 22 so that the growth bed 30 is lowered and the row rejection 31 is wound on the support rod 22, (30) is lifted up.

5, the reheating plate 32 is provided with a plurality of reheating holes 34. The reboiler plate 32 is provided under the reboiler plate 32 with a culture liquid feeder 36 mounted thereunder, And the culture liquid is sprayed into the space of the culture section (33).

The culture liquid supply unit 36 may be a pipe structure that receives the culture liquid from a separate culture liquid tank (not shown) and moves the culture liquid to the growth bed 30. The culture liquid supply unit 36 may include a spray nozzle (not shown) capable of spraying the culture liquid into the culture unit 33 Time).

The culture solution supply part 36 may be mounted on the culture solution mounting part 35 which is a groove structure under the reboiler 32.

FIG. 6 is to help understand how to plant and cultivate actual crops, and it can be seen that the crop stem such as strawberry is exposed to the outside through the planting hole 34 to open the fruit.

6 (a) and 6 (b) show a state in which the height of the cultivation bed 30 is adjusted.

The present invention proposes a technique in which the elevation of the cultivation bed 30 can be adjusted by a support bar unit and a plurality of motors 21 are mounted in units of the support rods 22, The cultivation bed 30 can be arranged in a stair-like manner, thereby enabling the cultivation to be carried out in a flat manner.

The solar tracking unit 40 includes a photosensor 41 and a control unit (not shown) to measure sunlight and drive the motor through a control unit.

The solar tracking unit 40 is installed on the upper part of the greenhouse to measure the sunlight and sense the position of the sun by the difference of the output voltage value to induce the arrangement of the proper growth bed 30 to minimize mutual shielding.

The optical sensor 41 improves the accuracy of the optical position measurement through the cross arrangement and changes the voltage due to the decrease of the resistance according to the electromotive force depending on the presence or absence of the light amount, so that the changed resistance value becomes the input value to the control unit, The height of each cultivation bed 30 is adjusted by driving each motor 21 so as to have a stepwise arrangement in which mutual shielding is minimized according to the program.

That is, according to the present invention, the cultivation bed 30 can be automatically controlled through the sunlight tracking unit 40, and manually controlled by the operator by directly switching the switches when necessary.

While the technical features of the present invention have been described above based on the specific embodiments shown in the drawings, it will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the present invention. It is self-evident.

10: Greenhouse 11: Column
12: horizontal support part 20:
21: motor part 22: support rod
23: bearing 24: timing belt
30: Growing Bed 31: Denying Row
32: Reheating plate 33: Culture unit
34: Reconstruction hole 35: Culture solution mounting part
36: Culture medium supply part 40: Solar tracking part
41: Light sensor

Claims (9)

A plurality of horizontal supports arranged to provide horizontal support forces between a plurality of columns in the greenhouse;
A plurality of support rods mounted at right angles to one another in the horizontal direction with respect to the respective horizontal supports and configured to be rotatable by a motor; And
And a plurality of lifting and lowering platforms mounted on the lower portion of each of the supporting rods via a hanger for lifting and lowering the hanger part together with the rotation of the supporting rods,
And controlling the rotation of the support rods so that the height of each cultivation bed can be adjusted for each support rod as the cultivation bed is raised and lowered. The method according to claim 1,
Wherein the support rod is supported at one end by a bearing provided on the horizontal support portion. The method according to claim 1,
Wherein the motor and the support rod are connected to each other by a timing belt to generate a rotational force in the support rod in accordance with driving of the motor. The method according to claim 1,
And the hanger part is wound around the support bar so that the hanger part can be stretched and contracted along with the rotation of the support bar. The method according to claim 1,
Wherein the cultivation bed includes a re-plate having a plurality of re-grooved holes for planting the plant, and a culture unit attached to the re-plate at both sides of the re-plate so as to surround the re-plate to form a culture space for the plant. 6. The method of claim 5,
Wherein the re-heating plate is configured to mount a culture liquid supply unit at a lower portion and spray the culture liquid to the inside of the culture unit. 6. The method of claim 5,
The hanger portion supporting the cultivation bed is in an inverted Y-shape, and the split portion supports and supports both ends of the re-plate so that the straight portion is connected to the support bar so that only the straight portion is rolled or unfolded A constructed greenhouse spray system. The method according to claim 1,
Further comprising a solar tracking unit on one side of the greenhouse,
And controlling the rotation of the support rod so as to adjust the height of the growth bed by tracking a position where the solar power is maximum. 9. The method of claim 8,
The optical sensor unit includes a plurality of optical sensors arranged in a cruciform shape inside a box to sense and control a change in voltage depending on the presence or absence of a light amount.

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