KR20190026307A - Rotary-type apparatus for growing water culture plant - Google Patents

Abstract

The present invention relates to a rotary hydroponics apparatus. The rotary hydroponics apparatus includes: a first support frame (10A) and a second support frame (10B) installed at a predetermined distance from each other; a first rotary bar (20A) and a second rotary bar (20B) including a plurality of installation bars (22); a driving motor (40) rotating the first rotary bar (20A) and the second rotary bar (20B); a bed (30) including a plurality of port installation holes for planting plants; and a first pipe (24) for supplying nutrient solution into the bed (30). According to the present invention, provided is a rotary hydroponics apparatus capable of preventing waste of a nutrient solution by spraying the nutrient solution directly to the root of a plant.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a rotary-

The present invention relates to a rotary hydroponic plant cultivation apparatus.

Hydroponic cultivation is a method of cultivating plants in a culture medium without soil. Such hydroponic cultivation has recently been widely used because it can prevent the spread of the plants by the germs transmitted from the soil, has a limited restriction on the cultivation space, and is easy for the user to manage the growth of the plants.

Conventionally, hydroponic cultivation generally involves placing a hydroponic cultivation bed in a multilayered structure in a greenhouse or a greenhouse, and then planting the plant in such a bed.

However, in the hydroponic cultivation apparatus having the above structure, the light required for photosynthesis can not be uniformly transferred to the plants due to the multi-layered bed, so that the plants can not grow evenly.

When the nutrient solution is supplied on the plant, the nutrient solution absorbed by the plant is about 10%, and the remaining 90% nutrient solution is discarded. The abundant nutrients are abandoned in the greenhouse, causing mold and causing infectious diseases. Also, the abandoned nutrient solution penetrates the soil to contaminate the water quality and increase the cost to supply the nutrient solution.

KR 10-1320606 B1 KR 10-1581432 B1 KR 10-1766364 B1 KR 20-0297898 Y1

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a method and apparatus for reducing the amount of waste nutrients, The present invention has been made in view of the above problems, and it is an object of the present invention to provide a rotation type hydroponic plant cultivation apparatus capable of appropriately providing light and temperature necessary for growth of the hydroponic plant.

The rotary type hydroponic plant cultivating apparatus according to the present invention includes a first support frame 10A and a second support frame 10B extending in the longitudinal direction and spaced apart from each other by a predetermined distance, ; A first swivel base 20A and a second swivel base 20B having a plurality of mounting brackets 22 extending radially and rotatably mounted on the first support frame 10A and the second support frame 10B, ); A driving motor 40 for rotating the first swivel 20A and the second swivel 20B; A plurality of port mounting holes 22 for connecting the respective mounting brackets 22 between the first swivel 20A and the second swivel 20B and rotated by the driving motor 40 for planting plants, A bed 30 on which a plurality of grooves 31A are formed; A first piping (24) connected to the supply part (50) to supply the nutrient solution into the bed (30); Wherein the bed 30 is rotatably connected to the first and second rotating rods 20A and 20B so as to maintain a posture during rotation of the bed 30, The first piping 24 on the side of the supply part 50 and the first piping on the side of the first swivel 20A are connected to the first piping 24 on the side of the supply part 50 and the first piping on the side of the first swivel 20A, 24 are connected to each other so that the first pipe 24 on the supply part 50 and the first pipe 24 on the first swivel 20A are rotatably connected to each other.

Further, a first injection pipe (33) installed inside the bed (30) and injecting nutrient solution; And a rotary joint is connected between the first pipe on the first swivel base 20A and the first injection pipe 33 so that the first pipe on the first swivel base 20A and the first pipe on the second swivel 20A are connected to each other, And a plurality of jet holes spaced apart from each other by a predetermined distance are formed in the first jetting tube (33).

The first pipe 24 extends into the mounting base 22 and is connected to the first injection pipe 33.

A second pipe 25 connected to the supply unit 50 for supplying carbon dioxide into the bed 30; A third injection pipe 35 installed inside the bed 30 to inject carbon dioxide; And the second pipe 25 is divided into a second pipe on the side of the supply part 50 and a second pipe on the side of the first swing table 20A and the second pipe on the side of the supply part 50, A rotary joint is connected between the second pipe on the first swivel 20A side and the second pipe on the side of the supply part 50 and the second pipe on the first swivel 20A are relatively rotatably connected, A rotary joint is connected between the second pipe 25 on the side of the swivel 20A and the third spray pipe 35 so that the second pipe on the first swivel 20A side and the third spray pipe 35 So as to be relatively rotatable.

Also, an illuminance sensor 13 installed on the first swivel 20A or the second swivel 20B; A controller for adjusting the rotational speed of the driving motor 40; And the controller adjusts the rotational speed of the drive motor (40) according to the detection value of the illuminance sensor (13).

According to the present invention, it is possible to provide a rotary type hydroponic plant cultivating apparatus in which light can be uniformly supplied to plants planted in each bed, and nutrient solution is sprayed directly onto the roots of plants, thereby preventing waste of nutrient solution.

1 is a view showing a rotary hydroponic plant cultivating apparatus according to an embodiment of the present invention.
2 is a view showing a front view of Fig.
3 is a view showing a support frame and a rotating table according to an embodiment of the present invention.
4 is a detailed view of a swivel according to the present invention.
5 is a view showing a bed according to an embodiment of the present invention.
Fig. 6 is a view showing the plane of the bed of Fig. 5; Fig.
Fig. 7 is a view showing in detail the internal structure of the bed of Fig. 5;
8 is a diagram showing an example of use of a rotary hydroponic plant cultivation apparatus according to an embodiment of the present invention.
9 is a view showing an example in which nutrient solution and carbon dioxide are supplied to a bed according to an embodiment of the present invention by inserting a planting port.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, like reference numerals refer to like elements throughout. The same reference numerals in the drawings denote like elements throughout the drawings.

1 is a view showing a rotary hydroponic plant cultivating apparatus according to an embodiment of the present invention. 2 is a view showing a front view of Fig. 3 is a view showing a support frame and a rotating table according to an embodiment of the present invention. 4 is a detailed view of a swivel according to the present invention. 5 is a view showing a bed according to an embodiment of the present invention. Fig. 6 is a view showing the plane of the bed of Fig. 5; Fig. Fig. 7 is a view showing in detail the internal structure of the bed of Fig. 5; 8 is a diagram showing an example of use of a rotary hydroponic plant cultivation apparatus according to an embodiment of the present invention. 9 is a view showing an example in which nutrient solution and carbon dioxide are supplied to a bed according to an embodiment of the present invention by inserting a planting port.

The rotary type hydroponic plant cultivating apparatus 1 according to the present invention comprises a first supporting frame 10A, a second supporting frame 10B, a first rotating table 20A, a second rotating table 20B, a bed 30, A motor 40, a supply unit 50, and a controller (not shown).

The first and second support frames 10A and 10B are spaced apart at a predetermined interval. And a vertical frame 11 having a predetermined length vertically. The vertical frame 11 is provided with a bearing unit (not shown) for rotatably mounting the first and second swivel tables 20A and 20B to be described later.

The first support frame 10A is provided with a mount 12 extending upwardly from the space between the first and second support frames 10A and 10B. The mounting table 12 may be provided with an illuminance sensor 13 for sensing the amount of light irradiated to the bed 30 located above the first and second rotating tables 20A and 20B.

The first and second swivel tables 20A and 20B are rotatably mounted on the first and second support frames 10A and 10B. Between the first and second rotating tables 20A and 20B, a plurality of beds 30 to be described later are radially provided.

The first and second rotating rods 20A and 20B are provided with hubs 21 and 21 'formed in a cylindrical shape. On one side of the hubs 21, 21 ', a rotary shaft 21A is provided.

Mounting bases 22 having a predetermined length radially along the outer surfaces of the hubs 21 and 21 'are installed. At this time, the mounting table 22 may be formed as a hollow pipe (pipe) having a through hole H formed therein.

An attachment shaft 23 having a predetermined length horizontally is provided at one end of the mounting table 22. A through hole (H) is formed in the coupling shaft (23) to communicate with the through hole (H) of the mounting table (22). The coupling shaft 23 is engaged with the rotation shaft 32D of the bed 30 to be described later.

In addition, a receiving portion A is formed in one hub 21 'where the first swivel 20A is located, and the mounting stand 22 is configured to communicate with the inside of the hub 21, 21'. The first and second pipes 24 and 25 made of a flexible material may be inserted and connected to connect the rotary shaft 21A and the hub 21 ' At this time, the second pipe 25 is inserted into the first pipe 24 and can be installed in a double pipe structure. The first pipe 24 is connected to the nutrient solution reservoir 51 of the supply part 50 to supply nutrient solution and the second pipe 25 is connected to the carbon dioxide storage tank 52 of the supply part 50 to supply carbon dioxide have. And the second pipe 25 supplies oxygen when it is connected to the oxygen storage tank.

The supply unit 50 supplies the nutrient solution, carbon dioxide, and oxygen to the inside of the bed 30 through the first and second rotation tables 20A and 20B. The supply unit 50 may include a nutrient solution reservoir 51 in which nutrient solution and water are stored, and a carbon dioxide storage tank 52 in which carbon dioxide is stored. And an air compressor (not shown) or a blower (not shown) for supplying oxygen may be installed.

The nutrient solution reservoir 51 may be configured so that the nutrient solution is mixed with water at a predetermined ratio or mixed with the nutrient solution and water separately and then mixed at a predetermined ratio.

The nutrient solution reservoir 51 and the carbon dioxide reservoir tank 52 are each provided with a supply pump (not shown) and the first pipe (not shown) connected to the nutrient solution reservoir 51 through the supply line 53 using the supply pump 24, and carbon dioxide can be supplied through the second pipe 25 connected to the carbon dioxide storage tank 52. The first pipe 24 and the second pipe 25 may extend through the interior of the supply line 53.

The first pipe 24 is divided into a first pipe on the side of the supply part 50 and a first pipe on the side of the first swing table 20A and the first pipe 24 on the side of the supply part 50 and the first pipe on the side of the first swing table 20A A rotary joint 54 is connected between the first pipe 24 and the first pipe 24 on the side of the supply part 50 and the first pipe 24 on the first swivel 20A are rotatably connected. This is for preventing the supply unit 50 from rotating even if the first swivel 20A rotates.

The rotary joint 54 refers to a rotary pipe joint, and is a pipe joint for connecting the relatively rotating pipe or equipment to each other. Such a rotary joint is widely known, and a detailed description thereof will be omitted.

The second pipe 25 is also divided into a second pipe on the side of the supply part 50 and a second pipe on the side of the first swing table 20A and the second pipe on the side of the supply part 50 and the second pipe on the side of the first swing table 20A A rotary joint 54 is connected between the pipings so that the second piping on the side of the supply part 50 and the second piping on the first swivel 20A are rotatably connected to each other.

A plurality of beds 30 are radially provided in the first and second swivel tables 20A and 20B. The nutrient solution, carbon dioxide, or oxygen can be supplied from the supply part 50 into the bed 30 through the first and second pipes 24 and 25 inserted into the mounting table 22.

The bed 30 is installed so as to rotate in a state of being mounted on the first and second swivel tables 20A and 20B. Inside the bed 30, a spray tube is provided to supply nutrient solution, carbon dioxide, or oxygen. The bed 30 is relatively rotatably connected to the first and second rotation tables 20A and 20B so as to maintain the posture while rotating.

5 to 7, the bed 30 includes a bed main body 31, a shaft mounting unit 32, and first to third injection pipes 33, 34,

The bed main body 31 is formed into a tube (or tank) having a horizontal length, and a receiving space is formed therein. The lower portion of the bed main body 31 may be formed to be heavier relative to the upper side of the bed main body 31 so that the bed main body 31 can maintain its vertical position due to its own weight while being rotated. The bed main body 31 is provided with a plurality of port mounting holes 31A that are laterally spaced apart from the upper portion and the planting port 2 can be inserted into the port mounting holes 31A.

The shaft mounting unit 32 is rotatably connected to the mounting table 22 while being installed at both ends of the bed main body 31.

The shaft mounting unit 32 includes a fixed housing 32A provided on both sides of the bed main body 31 and formed with through holes (not shown) communicating with the inside of the bed main body 31, A plurality of bearings 32C and a fixed housing 32A and a cover 32B provided between the fixed housing 32A and the cover 32B and a plurality of bearings 32C installed between the fixed housing 32A and the cover 32B, And a rotary shaft 32D installed to be supported by the bearing 32C. The rotary shaft 32D is formed as a hollow tube and is connected to the coupling shaft 23 of the first and second swivel tables 20A and 20B.

The first and second spray tubes 33 and 34 are for spraying the nutrient solution and extend along the inside of the bed main body 31. Only one of the first and second injection pipes 33 and 34 may be installed. The third spray tube 35 is for spraying carbon dioxide or oxygen and extends along the inside of the bed main body 31.

The first and second connection hoses L1 and L2 may be connected to one end of the first and second injection pipes 33 and 34 and the third connection hose L3 may be connected to one end of the third injection pipe 35 .

The first pipe 24 protruding through the tip of the coupling shaft 23 is rotatably engaged with the first and second connection hoses L1 and L2 by the rotary joint J. [ The second pipe 25 is rotatably engaged with the third connection hose L3 by a rotary joint J.

A plurality of spray holes (not shown) are formed at predetermined intervals in the first and second spray tubes 33 and 34. The spray holes of the first and second spray tubes 33 and 34 are formed so as to face the roots of the plants planted in the planting pot 2 inserted into the port installation hole 31A, 33, 34) is sprayed directly onto the root of the plant. The first and second jet pipes 33 and 34 are made of a urethane hose, and a nozzle for spraying the nutrient solution into fine particles may be installed in the jet hole.

The drive motor 40 is installed in the second support frame 10B. The rotation axis of the drive motor 40 is connected directly to the rotation axis of the second rotation table 20B or is connected using a speed reducer. The drive motor 40 rotates the first and second rotation spots 20A and 20B under the control of the controller so that the plurality of beds 30 provided in the first and second rotation spots 20A and 20B are also rotated.

A controller (not shown) controls the operation of the driving motor 40 according to the amount of light sensed by the illuminance sensor 13 so that the light is uniformly irradiated onto the bed 30. Further, the controller controls the operation of a supply pump and a valve (not shown) provided in the supply unit 50 to supply the nutrient solution, carbon dioxide, or oxygen into the bed 30.

The controller can control the speed of the driving motor 40 differently according to the amount of light sensed by the illuminance sensor 13. [ For example, when the amount of light is large, the driving motor 40 is controlled so that the first and second swivel tables 20A and 20B rotate rapidly, so that the bed 30 is not exposed to strong light for a long time. When the amount of light is small, the driving motor 40 is controlled so that the first and second rotating tables 20A and 20B are rotated at a low speed so that the bed 30 can sufficiently receive light.

Hereinafter, use examples of the rotary hydroponic plant cultivation apparatus of the present invention will be described.

8 and 9, the planting port 2 in which plants are planted is inserted into the port installation hole 31A of the bed 30 installed in the first and second swivel tables 20A and 20B. At this time, a sponge of a certain thickness is used without planting coco peptides to plant plants in the planting pot (2).

The controller senses the amount of light irradiated to the bed 30 using the illuminance sensor 13. In accordance with the amount of light sensed by the illuminance sensor 13, the controller adjusts the rotational speed of the drive motor 40.

The controller controls the supply unit 50 to supply the first and second pipes 24 and 25 in the supply line 53 to the first, second and third branch pipes 33, 35, 35) to supply nutrients, carbon dioxide or oxygen.

As described above, the rotary type hydroponic plant cultivating apparatus of the present invention can appropriately provide light and temperature required for plant growth by rotating the bed and uniformly supplying light to each bed.

In addition, since the nutrient solution is injected in the form of fine particles directly toward the roots of the plant using the first and second jet tubes provided inside the bed, the nutrient solution to be discarded is scarce and waste of the nutrient solution can be reduced. In addition, the nutrient solution injected in the form of fine particles is in a state where the roots of the plant are in good condition for absorption, and there is almost no nutrient solution to be discarded, so that the nutrient solution can prevent mold or soil or water pollution caused by nutrient solution.

Further, carbon dioxide or oxygen necessary for photosynthesis and growth of plants can be appropriately supplied to the interior of the bed through the third spray tube 35 extending to the bed.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

1: hydroponic plant cultivation device 2: plant pot
10A: first support frame 10B: second support frame
11: vertical frame 12: mounting table
13: illuminance sensor 20A: first rotating table
20B: second rotating table 21, 21 ': hub
21A: rotating shaft 22: mounting base
23: coupling shaft 24: first pipe
25: second pipe 26: connecting shaft
30: bed 31: bed body
31A: Port mounting hole 32: Axle mounting unit
32A: Fixed housing 32B: Cover
32C: bearing 32D: rotating shaft
32D ': protruding portion 33: first branch pipe
34: The second branch 35: The third branch
40: drive motor 50:
51: Nutrient solution reservoir 52: Carbon dioxide storage tank
53: Supply Line A:
B: Bolt H, H ': Through hole
J: Rotary joint L1: 1st connection hose
L2: second connection hose L3: third connection hose

Claims (5)

In a rotary hydroponic plant cultivation apparatus,
A first support frame (10A) and a second support frame (10B) extending in the longitudinal direction and spaced apart from each other by a predetermined distance;
A first swivel base 20A and a second swivel base 20B having a plurality of mounting brackets 22 extending radially and rotatably mounted on the first support frame 10A and the second support frame 10B, );
A driving motor 40 for rotating the first swivel 20A and the second swivel 20B;
A plurality of port mounting holes 22 for connecting the respective mounting brackets 22 between the first swivel 20A and the second swivel 20B and rotated by the driving motor 40 for planting plants, A bed 30 on which the first electrode 31A is formed;
A first piping (24) connected to the supply part (50) to supply the nutrient solution into the bed (30);
/ RTI >
The bed 30 is relatively rotatably connected to the first and second rotating rods 20A and 20B so that the bed 30 maintains its posture while rotating,
The first pipe 24 is divided into a first pipe on the side of the supply part 50 and a first pipe on the side of the first swing table 20A and the first pipe 24 on the side of the supply part 50, A rotary joint is connected between the first pipe 24 on the side of the supply unit 50 and the first pipe 24 on the side of the supply unit 50. The first pipe 24 on the side of the supply unit 50 and the first pipe 24 on the first A rotary hydroponic plant cultivation device connected to the plant. The method according to claim 1,
A first jetting tube 33 installed inside the bed 30 and injecting nutrient solution;
Further comprising:
A rotary joint is connected between the first pipe on the first swivel base 20A and the first injection pipe 33 so that the first pipe on the first swivel base 20A and the first pipeline 33 Which is relatively rotatably connected,
And a plurality of spray holes spaced apart from each other at a predetermined interval are formed in the first spray pipe (33). 3. The method of claim 2,
Wherein the first pipe (24) extends into the interior of the mounting base (22) and is connected to the first injection pipe (33). 3. The method of claim 2,
A second pipe 25 connected to the supply unit 50 to supply carbon dioxide to the inside of the bed 30;
A third injection pipe 35 installed inside the bed 30 to inject carbon dioxide;
Further comprising:
The second pipe 25 is divided into a second pipe on the side of the supply part 50 and a second pipe on the side of the first swing table 20A and the second pipe on the side of the supply part 50 and the first swivel 20A, The second pipe on the side of the supply part 50 and the second pipe on the side of the first rotation table 20A are rotatably connected to each other,
A rotary joint is connected between the second pipe 25 on the first swivel base 20A and the third spray pipe 35 so that the second pipe on the first swivel 20A side and the third pipe 35) are connected to each other so as to be relatively rotatable. The method according to claim 1,
An illuminance sensor 13 installed above the first swivel 20A or the second swivel 20B;
A controller for adjusting the rotational speed of the driving motor 40;
Further comprising:
Wherein the controller adjusts the rotation speed of the drive motor (40) according to a detection value of the illuminance sensor (13).

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