KR20180003128U - Led blind type plant cultivating apparatus for water culture - Google Patents

Abstract

The present invention relates to an LED blind hydroponic cultivation apparatus. In the present invention, m (m is a natural number of 2 or more) LED modules 190 are mounted on the lower surface of the panel, and the middle blind body 120-1 located in the uppermost layer among the multi- An upper blind panel 110 providing a light source to a plurality of hydrophoric pixel units 130 inserted into the upper blind panel 120-1; (N is a natural number equal to or greater than 2 and equal to or different from m) are vertically connected in parallel to each other, and the upper surface An intermediate blind body 120-1 in which unit insertion grooves 120u for insertion of the hydroponic pixel unit 130 are formed in a row or in parallel; The lower blind panel 110 and the lower blind panel 110. The upper blind panel 110 and the lower blind panel 110 are disposed in the upper blind panel 110 and the upper blind panel 110, 120-1 are connected to both ends of the wire passing through the front and rear surfaces of the intermediate blind body 120-1. Each pair of the intermediate blind bodies 120-1 is formed on both sides of each of the intermediate blind bodies 120-1, An adjustable support wire 170 that enables tilt adjustment of each of the stages 120-1 and 120-1; And a control unit.
Thus, an eco-friendly LED element having excellent linearity is formed on a blind-shaped panel, and the efficiency of electric power can be improved by supplying water circulating upward by the pump.
In addition, it is possible to lower the pump pressure of the water supply upward by controlling the tilt of the multi-stage LED blind, and to adjust the tilt of each LED blind to provide the effect of setting the slope of the light.

Description

LED BLIND TYPE PLANT CULTIVATING APPARATUS FOR WATER CULTURE [0001]

The present invention relates to an LED blind hydroponic cultivation apparatus, and more particularly, to an LED blind which is excellent in straightness and has an environmentally friendly LED element formed on a blind panel, and improves the efficiency of electric power by supplying water circulating upward by a pump To an LED blind hydroponic cultivation apparatus.

Generally, hydroponic cultivation is a cultivation method in which plants are cultivated using a culture solution in which various necessary nutrients are dissolved in water, instead of supplying water and various nutrients required for plant growth from the soil.

Such hydroponic cultivation is known to harvest the uncontaminated clean vegetables and crops because it does not use pesticides harmful to human body, and it is known that it can obtain a large amount of yield in a relatively short period of time.

Korean Patent Registration No. 10-1384684 entitled " ROOM TYPE HYDROPONICS GROWING EQUIPMENT " Korean Patent Registration No. 10-1232643 "APPARATUS FOR GROWING HYDROPONIC VEGETABLES" Korean Patent Registration No. 10-1376178 entitled " ROTARY TYPE HYDROPONICS PLANT CULTIVATION APPARATUS "

In order to solve the above problems, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an LED device, which is excellent in straightness and has an environmentally friendly LED element formed on a blind- And to provide a blind hydroponic cultivation apparatus.

In addition, the present invention provides a LED blind hydroponic cultivation device for lowering the pump pressure of the water supply by controlling the tilt of the multi-stage LED blinds and adjusting the tilt of the LED blinds at each stage .

In addition, the present invention has a structure in which a plurality of capsule type pixel ports are refilled in each LED blind, and a circular hole is formed in the center of the bottom bottom surface, so that plant roots can be extended to the outside through the bottom surface. The present invention provides an LED blind hydroponic cultivation apparatus.

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned may be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the LED blind hydroponic cultivation apparatus according to an embodiment of the present invention includes m panels (m is a natural number of 2 or more) LED modules 190 mounted on the lower surface of the panel, An upper blind panel 110 for providing a light source to a plurality of hydrophoric pixel units 130 inserted in an intermediate blind body 120-1 located on the uppermost layer among the intermediate blind bodies 120-1 of the intermediate blind bodies 120-1; (N is a natural number equal to or greater than 2 and equal to or different from m) are vertically connected in parallel to each other, and the upper surface An intermediate blind body 120-1 in which unit insertion grooves 120u for insertion of the hydroponic pixel unit 130 are formed in a row or in parallel; The lower blind panel 110 and the lower blind panel 110. The upper blind panel 110 and the lower blind panel 110 are disposed in the upper blind panel 110 and the upper blind panel 110, 120-1 are connected to both ends of the wire passing through the front and rear surfaces of the intermediate blind body 120-1. Each pair of the intermediate blind bodies 120-1 is formed on both sides of each of the intermediate blind bodies 120-1, An adjustable support wire 170 that enables tilt adjustment of each of the stages 120-1 and 120-1; And a control unit.

At this time, the present invention is formed at the lower end of the last of the multi-stage intermediate blind bodies 120-1, and has the same shape as the intermediate blind body 120-1, and unit insertion grooves 120u are formed on the upper surface, The lower blind body 120-2 does not have the LED module 190 because it corresponds to the last stage in which another blind body is not formed; And further comprising:

The present invention also relates to a support type housing 140 formed at the lower end of the lower blind body 120-2 and having a pump with a water supply main pipe portion 160-1 and a water outlet connected to each other; And further comprising:

In addition, the hydroponic pixel unit 130 is a sealing sticker for the capsule-type pixel port 134, which is a sealing sticker with one corner not yet attached to the cover sticker 132, (131); And a cover sticker 132 adhered only to a rim portion of the capsule-shaped pixel port 134 in the form of a sticker so as not to be freely detachable by a user; And a double sticker structure of a seal sticker 131 and a cover sticker 132 can be used after removing only the seal sticker 131 when cultivating a plant.

In addition, the hydroponic pixel unit 130 includes a refill-type bio-sponge 133 having a seed inside the center hole and an inner seed bonded to the medium, And an outer rim surface for attaching the cover sticker 132 is formed on the upper surface opened by the rectangular tube structure and a circular hole is drilled in the center of the lower bottom surface so that the roots of the plant can extend out through the bottom surface A capsule-shaped pixel port 134 formed in a structure; And further comprising:

The present invention is also applicable to a case where the power supply line drawn from the fuselage housing 140 or the external power supply end is directed upwardly in parallel with the water supply main pipe portion 160-1 and at the lowermost end of the intermediate blind body 120-1 Connected to the input terminal of the intermediate blind body 120-1 through the output terminal of the intermediate blind body 120-1 and connected to the input terminal of the other intermediate blind body 120-1 located at the upper side via the output terminal An electric wiring 150 connected to the input terminal of the upper blind panel 110 located at the highest level and supplying power to the plurality of LED modules 190 through input terminals of the respective stages; Further comprising:

The upper and lower blind bodies 120-1 and 120-2 are connected to the outlet of the pump provided in the support housing 140. The upper blind panel 110, the intermediate blind body 120-1, the lower blind body 120-2, Of the blind set (100u) formed by the adjustable support wire (170) so as to extend upward from the one side or both sides of the blind assembly (100u) A water supply main pipe portion 160-1 formed of a flexible material for adjusting the height of the water supply main pipe portion 160-1; And a water supply auxiliary piping section 160-C that forms a communicating piping structure between the uppermost one of the multi-stage intermediate blind bodies 120-1 and the uppermost one of the multi-stage intermediate blind bodies 120-1 up to and including the lowermost blind body 120-2, 2); And further comprising:

The water supply auxiliary piping section 160-2 is formed in a structure communicating with one side of the uppermost one of the multi-stage intermediate blind bodies 120-1 through a linear piping structure through an EL storage do.

The water supply auxiliary piping section 160-2 is provided at the other end of the uppermost one of the multistage intermediate blind bodies 120-1 in which the water supply main pipe section 160-1 is formed, And the horizontal blind body 120-1, which is located at the uppermost position, is connected to the side of the intermediate blind body 120-1 in the horizontal direction.

Further, the water supply auxiliary piping section 160-2 provides right and left alternate piping structures with respect to the side ends in the vertical structure of each of the intermediate blind bodies 120-1 constituting the blind assembly 100u in the same manner The upper and lower piping structures between the lower blind body 120-1 and the lower blind body 120-2 and the upper and lower piping structures between the lower blind body 120-2 and the receiving housing 140 .

In addition, the adjustable support wire 170 includes a main wire 171 which is directed downward with respect to each of the four corner areas of the lower surface of the upper blind panel 110; And four lower edge blind bodies 120-1 and 120-2 with the four corner regions of the upper blind panel 110 and the lower blind panel 110 as the starting point, A height-adjusting wire 173 that has passed through the wire 172 and bent and cut outward; . ≪ / RTI >

Further, the height adjusting wire 173 is characterized in that its height is regulated through the height adjusting end 172 after being expanded to the outside.

The height adjusting wire 173 pulls the height adjusting end 172 surrounding the main wire 171 and the height adjusting wire 173 to the upper or lower side so that the respective ends of the height adjusting wire 172 are connected to the angles constituting the corresponding blind set 100u And the height of one side or both sides of the component is adjusted.

The height adjusting wire 173 is formed with a height fixing terminal 172a having a lower female thread at an upper portion of the height adjusting terminal 172 and is connected to the main wire 171 and the height adjusting wire 173 are fastened to the upper portion of the height adjusting terminal 172 where the male screw wires are formed in the adjusted state.

The LED blind hydroponic cultivation apparatus according to an embodiment of the present invention can improve the efficiency of electric power by forming an environmentally friendly LED element with excellent straightness and a blind type panel and supplying water circulating upward by the pump Effect.

In addition, the LED blind hydroponic cultivation apparatus according to another embodiment of the present invention can lower the pump pressure of the upward supply of water through the inclination adjustment of the multi-stage LED blind, adjust the tilt according to the LED blinds at each stage, This provides a possible effect.

In addition, the LED blind hydroponic cultivation apparatus according to another embodiment of the present invention is characterized in that a plurality of capsule type pixel ports are refilled into each LED blind, and a circular hole is drilled in the center of the bottom floor, It is a structure that can be extended to the outside through the surface to provide a hydroponic cultivation effect.

1 and 2 are views showing an LED blind hydroponic cultivation apparatus 100 according to an embodiment of the present invention.
3 and 4 are views for explaining the structure of the hydroponic grown pixel unit 130 in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention.
Fig. 5 is a diagram showing an example of a blind set 100u of the LED blind in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention. The blind set 100u includes a plurality of intermediate blind bodies 120-1, 120-2, FIG. 7 is a view for explaining the tilt setting by adjusting the support wire 170; FIG.
FIG. 6A is a schematic view showing an example of a multi-stage intermediate blind body 120-1 constituting a blind set 100u in an LED blind hydroponic cultivation apparatus 100 according to an embodiment of the present invention, FIG. 7 is a view for explaining tilt adjustment for each stage using the support wire 170; FIG.
6B is a view for explaining the structure of the electric wiring 150 in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention.
7 and 8 are views showing the hydroponic cultivation module 120m used in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention.
FIG. 9 and FIG. 10 are diagrams showing the components of the hydroponic cultivation module 120m used in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention.
11 is a diagram showing the connection structure of the first communication end 120m-9 and the second communication end 120m-10 of the hydroponic cultivation module 120m used in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention. Fig.
12 is a view for explaining the principle of fixing by the gasket 120m-8 frictional force in each hydraulic cultivation module 120m of Fig.
13 is a sectional view showing the sealing of the communication type water bottle 120m-3 by the coil spring 120m-6, the O-ring 120m-7 and the cork 120m-5 in each hydroponic culture module 120m of Fig. 7, Fig.
Fig. 14 is a view for explaining a water level measurement support column 120m-1 in each hydroponic culture module 120m in Fig. 7.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention unnecessarily obscure.

1 and 2 are views showing an LED blind hydroponic cultivation apparatus 100 according to an embodiment of the present invention. 3 and 4 are views for explaining the structure of the hydroponic grown pixel unit 130 in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention. Fig. 5 is a diagram showing an example of a blind set 100u of the LED blind in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention. The blind set 100u includes a plurality of intermediate blind bodies 120-1, 120-2, FIG. 7 is a view for explaining the tilt setting by adjusting the support wire 170; FIG. FIG. 6A is a schematic view showing an example of a multi-stage intermediate blind body 120-1 constituting a blind set 100u in an LED blind hydroponic cultivation apparatus 100 according to an embodiment of the present invention, FIG. 7 is a view for explaining tilt adjustment for each stage using the support wire 170; FIG. 6B is a view for explaining the structure of the electric wiring 150 in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention.

1 and 2, an LED blind hydroponic cultivation apparatus 100 includes an upper blind panel 110, an intermediate blind body 120-1, a lower blind body 120-2, a hydroponic pixel unit 130, a supporting housing 140, an electrical wiring 150, a water supply main pipe portion 160-1, a water supply auxiliary pipe portion 160-2, and an adjustable support wire 170 .

Here, the upper blind panel 110 is a rectangular panel, and six LED modules 190 are mounted on the lower surface thereof. The middle blind body 120-1, which is the uppermost one of the multi-stage intermediate blind bodies 120-1, 120-1 may provide a light source to a plurality of hydropathic pixel units 130 inserted in the haptic 120-1.

In the middle blind body 120-1, the LED module 190 is mounted on the lower surface like the upper blind panel 110. In FIG. 1 and FIG. 2, two LED modules 190 are vertically connected in parallel. However, In one embodiment, n (n is a natural number of 2 or more) may be formed in a hexahedron shape so as to fill water for hydroponic cultivation instead of a panel form so that the unit insertion grooves 120u are formed in a row .

Meanwhile, the unit insertion groove 120u formed in a row in the intermediate blind body 120-1 may be configured in such a manner that the hydroponic culture module 120m is fastened and separated as shown in FIG.

 The lower blind body 120-2 corresponds to the intermediate blind body 120-1, but the lower end does not have another blind body, so that the LED module 190 is not provided.

The hydroponic pixel unit 130 consists of a seal sticker 131, a cover sticker 132, a Rooting Sponge 133, and a capsule-shaped pixel port 134.

In this case, the hydroponic pixel unit 130 is a capsule type seal with a double sticker structure, the seal sticker 131 is a seal sticker for the capsule type pixel port 134, and one corner portion is a seal sticker 132 So that it can be easily detached by the user.

The cover sticker 132 is adhered only to the rim portion of the capsule-shaped pixel port 134 in the form of a sticker, so that the user can not freely detach it.

That is, the seal sticker 131 and the cover sticker 132 can be used after removing only the seal sticker 131 when the plant is cultivated with a double sticker structure.

The bio sponge 133 is a medium for growing crops containing seeds. The bio sponge 133 improves the growth of crops using a natural bio-sponge and provides environmental protection by natural decomposition upon disposal. Seeds are contained in the center hole of the bio sponge 133, and the seeds inside the bio sponge 133 are preferably adhered to the medium. Further, the bio sponge 133 can be replaced with a refill type.

The capsular pixel port 134 has an outer rim surface for attachment of the cover sticker 132 to the upper surface opened by a rectangular tube structure and a circular hole at the center of the lower bottom surface, It is preferable to form the structure so as to extend outwardly.

6B, the electric wiring 150 is electrically connected to the intermediate blind body 120-1 (see FIG. 6A) by a power line drawn from the receiving housing 140 or the external power supply end in parallel with the water supplying main pipe portion 160-1. And the output terminal of the intermediate blind body 120-1 is connected to the input terminal of the other intermediate blind body 120-1 located at the upper portion through an output terminal of the intermediate blind body 120-1 located at the lowermost end of the intermediate blind body 120-1, To the input terminal of the upper blind panel 110 located at the highest position in the manner that the LED modules 190 are connected to each other through the input terminals.

As shown in FIGS. 5 and 6A, the water supply main pipe portion 160-1 is connected to a discharge port of a pump provided in the receiving-type housing 140, and includes an upper blind panel 110, a plurality of intermediate blind bodies 120-1 ) And the lower blind body 120-2, and is formed in a straight piping structure upward at a position spaced outward from one side of one side of the blind assembly 100u (Fig. 5) It is preferable that the blind assembly 100u is formed of a flexible material for adjusting the height of one side or both sides of each constituent element of the blind assembly 100u.

On the other hand, the water supply main pipe portion 160-1 is formed in a structure communicating with one side of the uppermost one of the multi-stage intermediate blind bodies 120-1 through the above-described linear piping structure.

The water supply auxiliary piping section 160-2 is disposed on the other side of the uppermost one of the multistage intermediate blind bodies 120-1 in which the water supply main pipe section 160-1 is formed, And is horizontally communicated at the side of the middle blind body 120-1 located at the uppermost position through the linear piping structure.

Further, the water supply auxiliary piping section 160-2 provides right and left alternate piping structures with respect to the side ends in the vertical structure of each of the intermediate blind bodies 120-1 constituting the blind assembly 100u in the same manner, A vertical piping structure between the lower blind body 120-1 and the lower blind body 120-2 and a vertical piping structure between the lower blind body 120-2 and the receiving housing 140 It provides a structure that can be done.

The adjustable support wire 170 includes a main wire 171 directed downward with each of the four corner areas of the lower surface of the upper blind panel 110 as a starting point.

Here, the main wire 171 is provided on the front side of the multi-stage intermediate blind body 120-1 and one bottom blind body 120-2 with the four corner regions of the lower surface of the upper blind panel 110 as the starting point, As shown in the figure, are formed on both sides of each of the multi-stage intermediate blind body 120-1 and the single lower blind body 120-2, , Total two pairs are formed.

The adjustable support wire 170 is connected to each of the intermediate blind bodies 120-1 and one of the lower blind bodies 120-1 and 120-2 with each of the four corner regions of the lower surface of the upper blind panel 110 as a starting point. And a height adjusting wire 173 having a shape that is bent and cut outward after passing through height adjusting ends 172 formed by four holes. Here, the height adjusting wire 173 has a function of adjusting the height through the height adjusting end 172 after being expanded to the outside.

Through such a structure, a height adjusting end 172 for wrapping the main wire 171 and the height adjusting wire 173 is pulled up or down so that one end or both sides of each component constituting the corresponding blind set 100u And a height fixing terminal 172a having a female thread at the bottom is formed at an upper portion of the height adjusting terminal 172 so that the main wire 171 and the main wire 171 are rotated in the clockwise direction, And the height of the height adjusting wire 173 is fastened to the upper portion of the height adjusting terminal 172 where the male screw is formed in the adjusted state.

The adjustable support wire 170 can be adjusted by adjusting the inclination setting of the multi-stage intermediate blind body 120-1 and the lower blind body 120-2, which constitute the blind assembly 100u, The pump pressure of the upward supply of water can be lowered through the adjustment support wire 170 as shown in FIG. 6A.

7 is a perspective view of the hydroponic cultivation module 120m in the modified form of the intermediate blind body 120-1 and the lower blind body 120-2 in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention. And is formed in a separated manner. Fig. 8 is a view showing a perspective view (Figs. 7A and 7C), a top view (Fig. 7B), a front view (Fig. 7E) and a side view (Figs. 7D and 7F) of the hydroponic culture module 120m of Fig. FIG. 9 and FIG. 10 are diagrams showing the components of the hydroponic cultivation module 120m used in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention. 11 is a diagram showing the connection structure of the first communication end 120m-9 and the second communication end 120m-10 of the hydroponic cultivation module 120m used in the LED blind hydroponic cultivation apparatus 100 according to the embodiment of the present invention. Fig. 12 is a view for explaining the principle of fixing by the gasket 120m-8 frictional force in each hydraulic cultivation module 120m of Fig. 13 is a sectional view showing the sealing of the communication type water bottle 120m-3 by the coil spring 120m-6, the O-ring 120m-7 and the cork 120m-5 in each hydroponic culture module 120m of Fig. 7, Fig. Fig. 14 is a view for explaining a water level measurement support column 120m-1 in each hydroponic culture module 120m in Fig. 7.

7 and 8, the intermediate blind body 120-1 and the lower blind body 120-2 do not require power consumption because they do not have their own power supply, and the settings for communication with the sensor May be provided through the fastening and detachment structure of the hydroponic cultivation module 120m.

Each hydroponic culture module 120m has a unit insertion groove 120u corresponding to four ports and the hydropulsed pixel unit 130 can be inserted into all the unit insertion grooves 120u, One of the unit insertion grooves 120u may be formed with a water level measuring column 120m-1.

9, the hydroponic culture module 120m includes a unit tray 120m-2, a communicating water tank 120m-3, a cap 120m-4, a water tank 120m- Two corks 120m-5, two coil springs 120m-6, two O-rings 120m-7 and a gasket 120m- 8).

Here, the unit tray 120m-2 is formed with four unit insertion grooves 120u in a rectangular panel, and forms the upper surface of the communicating water tank 120m-3.

A first communication end 120m-9 is formed on the front surface of the communication type water bottle 120m-3 and a second communication end 120m-10 is formed on the rear surface. The first communication end 120m- A cork 120m-5 is inserted and a cork 120m-5 is inserted through an O-ring 120m-7 made of a silicone material. And a coil spring 120m-6 surrounding the outer circumferential surface of the front end portion which is not inserted into the first communication end 120m-9 of the cork 120m-5 is fixed to the inside of the cork 120m-5 So that the cork 120m-5 has an external force forward.

The first communication terminal 120m-9 may further include a cap 120m-4 for blocking the front surface to form a clogged structure with respect to the front end of the first communication terminal 120m-9, The second communication terminal 120m-10 may also be formed with a cap.

Next, referring to the second communication end 120m-10, the cylindrical partition 1 facing the inside from the rear face of the communication water basin 120m-3 to accommodate the first communication end 120m-9 And a silicone gasket 120m-8 inserted to fix the first communication end 120m-9 of the other hydroponic culture module 120m-1 inserted into the cylindrical partition wall 1 is a cylindrical And is located inside the partition wall (1).

On the other hand, in the second communicating stage 120m-10, the same shape as the wall surface of the cylindrical partition wall 1 from the backside to the inside of the communicating water passage 120m-3 described above, The front end of the cork 120m-5 is inserted into the through-hole formed in the forward direction in the separating partition 2. In a state where the cork 120m-5 is inserted into the through-hole of the second communication end 120m-10 at the second communication end 120m-10, the cork 120m-5 is fixed at the front end so that the cork 120m- The O-ring 120m-7 made of silicone is inserted into the partition wall 2 of the second communicating end 120m-10 of the cork 120m-5 between the separating partition wall 2 and the cork 120m-5. And a coil spring 120m-6 that surrounds the outer circumferential surface of the region.

In this case, it is possible to provide a pond water system for cultivating crops using only pure water (or nutrient solution) without the need for soil through the communicating water tank 120m-3, and the water storage capacity can be set to about 1 liter, Of the one hydroponic culture module 120m through the structure of the first communication end 120m-9 and the second communication end 120m-10 of the hydroponic culture module 120m having the above-described structure, The first communicating end 120m-9 of the other hydroponics culturing module 120m is connected to the communicating end 120m-10 by the assembly of the communicating water can 120m-3 as shown in FIG. Provides the advantages of.

12 is a view for explaining the principle of fixing by the gasket 120m-8 frictional force in each hydraulic cultivation module 120m of Fig. When the two hydroponic cultivation modules 120m shown in FIG. 12A are assembled before assembling the two hydroponic cultivation modules 120m shown in FIG. 12b, the fixation is performed in a fixed manner using the frictional force of the gasket 120m-8 It can be combined and detached without a separate tool.

13 is a sectional view showing the sealing of the communication type water bottle 120m-3 by the coil spring 120m-6, the O-ring 120m-7 and the cork 120m-5 in each hydroponic culture module 120m of Fig. 7, Fig. The water passage is closed by the O-ring 120m-7 with respect to the cork 120m-5 formed on the first communication end 120m-9 in the state before assembly of the two hydroponic culture modules 120m in Fig. 13a, 13b are closed by the coil spring 120m-6, and the two hydro-cultivation modules 120m of the hydro-cultivation module 120m formed at the front end after the assembling of the two hydro- The cork 120m-5 formed on the second communication end 120m-10 and the cork 120m-5 formed on the first communication end 120m-9 of the hydroponic culture module 120m formed at the rear end The water passage can be secured by the force.

On the other hand, the water level measuring span 120m-1 is formed of a PP material (having a specific gravity of 1 or less) as a water level measuring device, thereby detecting the quantity inside the communication water tank 120m-3.

That is, when the amount of water is insufficient as shown in FIG. 14A, the water level measuring pillar 120m-1 is separated from the bottom surface of the communicating water tank 120m-3 by the height h1 to the upper surface of the unit tray 120m- Can be protruded. As shown in FIG. 14B, when the amount of water is sufficient, the water level measuring column 120m-1 is separated from the bottom surface of the communicating water can 120m-3 by a height h2 higher than the height h1, -2) upper surface.

As shown in FIGS. 14C and 14D, the water level measuring pillar 120m-1 has a donut shape in cross section for user's convenience when water is injected into the communicating water reservoir 120m-3 by the user, It is possible to easily inject water through the hole.

As described above, the present specification and drawings disclose preferred embodiments of the present invention, and although specific terms have been used, they have been used in a generic sense only to facilitate description of the present invention and to facilitate understanding of the present invention And is not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the invention beside the embodiments disclosed herein are possible.

100: LED blind hydroponic cultivation device
100: upper blind panel
120-1: intermediate blind body
120-2: Lower blind body
120m: Hydroponic cultivation module (120m)
120m-1: Water level measuring column
120m-2: Unit tray
120m-3: communicating water bottle
120m-4: cap
120m-5: cork
120m-6: coil spring
120m-7: O-ring
120m-8: Gasket
120m-9: first communicating stage
120m-10: second communicating stage
130: Hydroponic pixel unit
140: Pedestal housing
150: Electrical wiring
160-1: Water supply main pipe section
160-2: Water supply auxiliary pipe section
170: Adjustable support wire

Claims (14)

(M is a natural number of 2 or more) LED modules 190 are mounted on the lower surface of the panel, and the middle blind body 120-1 located in the uppermost layer among the multi-stage intermediate blind bodies 120-1 An upper blind panel 110 for providing a light source to a plurality of hydrophoric pixel units 130 inserted in the upper blind panel 130;
(N is a natural number equal to or greater than 2 and equal to or different from m) are vertically connected in parallel to each other, and the upper surface An intermediate blind body 120-1 in which unit insertion grooves 120u for insertion of the hydroponic pixel unit 130 are formed in a row or in parallel; And
The upper blind panel 110 and the upper blind panel 110 are disposed on the upper blind panel 110 and the upper blind panel 110. The upper blind panel 110 has four corner areas, -1 are formed so as to be connected to both ends of a wire passing through the front and rear surfaces of the intermediate blind body 120-1, respectively, and each pair is formed on each side of each of the intermediate blind bodies 120-1, 120-1) and an adjustable support wire (170) for controlling the tilt of each stage; Wherein the LED blind is an LED blind.
The method according to claim 1,
A unit insertion groove 120u is formed on the upper surface of the intermediate blind body 120-1 in the same shape as the intermediate blind body 120-1 and another blind body A lower blind body 120-2 having no LED module 190 corresponding to the last stage that is not formed; Further comprising: an LED blind water hydroponics plant.
The method of claim 2,
A support housing 140 formed at a lower end of the lower blind body 120-2 and having a pump with a water supply main pipe portion 160-1 and a water outlet connected to each other; Further comprising: an LED blind water hydroponics plant.
The hydroponic pixel unit (130) according to claim 1,
A seal sticker for a capsule type pixel port (134), comprising: a seal sticker (131) which is configured such that one corner portion is not attached to the cover sticker (132) And
A cover sticker 132 adhered only to a rim portion of the capsule-shaped pixel port 134 in a sticker shape so as not to be freely detachable by the user; / RTI >
Wherein a seal sticker (131) and a cover sticker (132) have a double sticker structure and can be used after removing only the seal sticker (131) when cultivating a plant.
5. The apparatus of claim 4, wherein the hydroponic pixel unit (130)
A crop growth medium comprising seeds, comprising: a refill-type bio-sponge (133) containing seeds in a center hole and an inner seed adhered to the medium; And
An outer rim surface for attaching the cover sticker 132 is formed on the upper surface opened by the rectangular tube structure and a circular hole is formed in the center of the lower bottom surface to allow the roots of the plant to extend outward through the bottom surface A capsule-shaped pixel port 134 formed on the substrate; Further comprising: an LED blind water hydroponics plant.
The method according to claim 1,
Connected to the input terminal of the bottom end of the intermediate blind body 120-1 in the upward direction in parallel with the water supply main pipe portion 160-1 by a power supply line drawn from the support housing 140 or the external power supply end The uppermost blind body 120-1 is connected to the input terminal of the other intermediate blind body 120-1 positioned at the uppermost position through the output terminal of the intermediate blind body 120-1, (150) connected to an input terminal of the LED module (110) and supplying power to the plurality of LED modules (190) through input terminals of the respective stages; Further comprising a plurality of LED blinds.
The method of claim 3,
A blind assembly 100u which is connected to the outlet of the pump provided in the support housing 140 and is composed of an upper blind panel 110, a multi-stage intermediate blind body 120-1 and a lower blind body 120-2, The flexible support wire 170 is provided with a straight pipe structure upward at a position spaced apart from the outer side of one side of the blind assembly 100u so as to be flexible in order to adjust the height of one side or both sides of each component constituting the blind assembly 100u by the adjustable support wire 170 A water supply main pipe portion 160-1 formed of a material; And
A water supply auxiliary piping section 160-2 that forms a communication piping structure between upper and lower adjacent ones from the uppermost one of the multi-stage intermediate blind bodies 120-1 to the lowermost blind body 120-2 ); Further comprising: an LED blind water hydroponics plant.
The water supply apparatus according to claim 7, wherein the water supply auxiliary piping section (160-2)
And is connected to one side of the uppermost one of the multi-stage intermediate blind bodies (120-1) through a linear pipe structure through a storage device (110).
The water supply system according to claim 8, wherein the water supply auxiliary piping section (160-2)
An intermediate blind body 120-1 positioned at the uppermost end of the multi-stage intermediate blind body 120-1 having a water supply main pipe portion 160-1 is connected to the other end of the intermediate blind body 120-1 through a straight piping structure, 120-1) at a side of the LED blinds (120-1).
The water supply system according to claim 8, wherein the water supply auxiliary piping section (160-2)
The middle blind body 120-1 constituting the blind set 100u in the same manner provides right and left alternate piping structures with respect to the side ends in the upper and lower structures, and the middle blind body 120-1 located at the lowermost end and the lower The upper and lower piping structures between the blind bodies 120-2 and the upper and lower piping structures between the lower blind body 120-2 and the receiving housing 140. [
The method of claim 1, wherein the adjustable support wire (170)
A main wire 171 downwardly directed to each of the four corner areas of the lower surface of the upper blind panel 110; And
Four height adjusters (not shown) are provided in each of the middle blind body 120-1 and the one lower blind body 120-2 at each of the four edge areas of the lower surface of the upper blind panel 110, 172, and then bent outwardly and cut in the shape of a height-adjusting wire 173; Wherein the LED blind is an LED blind.
The method of claim 11,
Wherein the height adjusting wire (173) is adjusted to a height through the height adjustment end (172) after being expanded outward.
13. The apparatus of claim 12, wherein the height adjustment wire (173)
The height adjustment ends 172 surrounding the main wire 171 and the height adjustment wires 173 are pulled up or down to adjust the height of one side or both sides of each component constituting the corresponding blind assembly 100u Wherein the LED blind is an LED blind.
14. The apparatus of claim 13, wherein the height adjustment wire (173)
A height fixing terminal 172a is formed on the upper portion of the height adjusting terminal 172 and has a female thread on the lower portion thereof so that the main wire 171 and the height adjusting wire 173 Wherein the height adjustment mechanism is fastened to the upper portion of the height adjustment stage (172) with the male screw wire formed in the height-adjusted state.

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