KR101780459B1 - Assembly type smart flower bed system - Google Patents

Abstract

The present invention relates to a prefabricated smart fountain system that not only facilitates expansion and facilitates expansion but also facilitates the management of plants. The present invention relates to a prefabricated smart fountain system having a water drop hole (102) A bottom plate 104; A single hexagonal cell 108 detachably installed along the top edge of the bottom plate 104 and having a through hole 106 at the center of the cell; A hexagonal cell 110 (not shown) provided detachably along the top edge of the bottom plate 104 or detachably installed on the bottom or top surface of the single hexagonal cell 108, )and; The wireless communication auxiliary controller 112 and the wireless communication auxiliary controller 112 are provided inside the cell. The wireless communication auxiliary controller 112 and the auxiliary wireless communication controller 112 are provided in the cell, A control hexagonal cell 116 having one supply hose 114; A wireless communication motor pump 118 for supplying water or nutrient solution to the first supply hose 114 installed inside the control hexagonal cell 116; Communicates with the wireless communication auxiliary control unit 112 of the control hexagonal cell 116 and communicates with the manager smartphone 120 to turn on or off the driving of the wireless communication motor pump 118 off of the smart flower room main body.

Description

{ASSEMBLY TYPE SMART FLOWER BED SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flower bed, and more particularly, to a prefabricated flower bed system capable of facilitating expansion and facilitating plant management.

In general, flower beds are constructed by stacking bricks or stones at a certain height so as to grow plants, plants or vegetables in the ground, and then filling them with soil.

Because of the development of the industry and the urbanization, there is a shortage of land due to excessive population density, and the commercial and residential buildings are built up in a dense fashion.

Particularly, in the case of an apartment constructed in a high-rise building, since there is no more land, pollen is provided on the ovens provided at the front and back of the apartment, or a box made of styrofoam or plastic is provided, and a small amount of soil is filled therein, As an example.

In such a case, the soil supplied to the plant grows in the course of planting or vegetable growing, which causes contamination of the soil by ovulation and clogging of the drainage port.

In addition, in the case of single-family houses with some rooftops, rooftops are used as roofs. In this case, the weight of the soil and bricks constituting the flower beds is transferred to the slabs of the houses, I am crazy.

In addition, when water is supplied to plants and vegetables planted in a flowerbed, the water is not only burdened with water, but also water can not be completely discharged, thereby causing a cause of premature corrosion of the slab .

As described above, water supplied to a flower bed constructed on a roof can not be drained, so that water is submerged into the inside of the building through the roof, which causes the structure of the building to become weak.

In order to solve the above problems, the invention was filed with the Korean Intellectual Property Office with the application number 20-2004-0007772 (name of design: prefabricated building) on Mar. 20, 2004, and claims the following: The outer side surface 56 and the front and rear side surfaces 57 and 58 and the bottom surface 59 are closed and the inner side is formed with the opening portion 60 with the space 52 capable of filling the soil 51, And an opening 60 is formed on both sides of the front and rear sides 57 and 58 and the bottom surface 59 between the upper and lower bodies 53 and 53, An outer body 53 connecting the outer body 53 and the inner body 54 in a rigid state and an outer body 53 connecting the outer body 53 and the inner body 54 in a rigid state, An insertion opening 61 is formed in the inner end of the inner body 54 at the inner side of the front and rear sides 57 and 58 so as to be connected to the opening 55, 53 and the bottom surface 59 on the side of the opening 60 of the inner body 54 are provided with a waterproof protrusion 62 protruding upward so as to prevent the supplied water from flowing out, 55 are protruded so as to be inserted into the insertion openings 61 on both sides of the connection body 63. The connection body 63 is formed in the same shape as the end surface of the outer body 53 and the inner body 54, And a fastening hole 65 is formed in the insertion opening 61 and the waterproofing jaw 62, the connecting body 63 and the insertion protrusion 64 so as to be fastened by fastening means, Quot; prefabricated flower bed ".

However, the conventional prefabricated flowerpot has a complicated structure, which is not easy to expand due to inconvenient assembly, and also has a problem that plants can not be easily managed.

Accordingly, it is an object of the present invention to provide a prefabricated smart module which can easily be expanded and can easily manage a plant, To provide a flower bed system.

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

According to another aspect of the present invention, there is provided a built-

A bottom plate (104) having a water drop hole (102) at regular intervals therein;

A single hexagonal cell 108 detachably installed along the top edge of the bottom plate 104 and having a through hole 106 at the center of the cell;

A hexagonal cell 110 (not shown) provided detachably along the top edge of the bottom plate 104 or detachably installed on the bottom or top surface of the single hexagonal cell 108, )and;

The wireless communication auxiliary controller 112 and the wireless communication auxiliary controller 112 are provided inside the cell. The wireless communication auxiliary controller 112 and the auxiliary wireless communication controller 112 are provided in the cell, A control hexagonal cell 116 having one supply hose 114;

A wireless communication motor pump 118 for supplying water or nutrient solution to the first supply hose 114 installed inside the control hexagonal cell 116;

Communicates with the wireless communication auxiliary control unit 112 of the control hexagonal cell 116 and communicates with the manager smartphone 120 to turn on or off the driving of the wireless communication motor pump 118 off of the smart flower room main body.

As described above, the assembled smart flower bed system according to the present invention is easy to assemble and is easy to expand, and also has an effect of easily managing plants.

This has the effect of reducing the management cost of the assembled smart flower bed system.

Further, since the present invention can be assembled in a form desired by the user, it is possible to enhance the fun and interest.

Fig. 1 is a schematic diagram of a prefabricated smart tethering system according to the present invention,
Figs. 2A and 2B are diagrams of the smart cooking process of Fig. 1,
Figure 3a is an enlarged view of the single hexagonal cell of Figure 2a,
FIG. 3B is an enlarged view of the double hexagonal cell of FIG. 2A,
FIG. 3C is an enlarged view of the control hexagonal cell of FIG. 2A,
Figs. 4A to 4C are explanatory views of the recessed portion of the smart tabletop of Fig. 1,
5A and 5B are enlarged views of the main part of the smart flower bed of FIG. 1,
FIG. 6 is a block diagram showing the configuration of a prefabricated smart bedding system according to the present invention.
FIG. 7 is a view showing a state in which the assembled smart processing unit is installed.

Hereinafter, a preferred embodiment of the assembled smart drawing bed system according to the present invention will be described.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a schematic structural view of the assembled smart drawing bed system according to the present invention, FIGS. 2A and 2B are views showing the smart drawing stage of FIG. 1, FIG. 3A is an enlarged view of a single hexagonal cell of FIG. 2A is an enlarged view of the hexagonal cell of FIG. 2A, FIG. 3C is an enlarged view of the control hexagonal cell of FIG. 2A, FIGS. 4A to 4C are exploded views of the recessed portion of FIG. 1, FIG. 6 is a block diagram of a prefabricated smart tethering system according to the present invention.

As shown in FIGS. 1 to 6, the prefabricated smart Internet service system 100 according to the present invention includes:

A bottom plate (104) having a water drop hole (102) at regular intervals therein;

A single hexagonal cell 108 detachably installed along the top edge of the bottom plate 104 and having a through hole 106 at the center of the cell;

A hexagonal cell 110 (not shown) provided detachably along the top edge of the bottom plate 104 or detachably installed on the bottom or top surface of the single hexagonal cell 108, )and;

The wireless communication auxiliary controller 112 and the wireless communication auxiliary controller 112 are provided inside the cell. The wireless communication auxiliary controller 112 and the auxiliary wireless communication controller 112 are provided in the cell, A control hexagonal cell 116 having one supply hose 114;

A wireless communication motor pump 118 for supplying water or a nutrient solution (for example, nutrients) to the first supply hose 114 provided inside the control hexagonal cell 116;

Communicates with the wireless communication auxiliary control unit 112 of the control hexagonal cell 116 and communicates with the manager smartphone 120 to turn on or off the driving of the wireless communication motor pump 118 off of the smart flower room main body.

The control hexagonal cell (116)

A water-bearing hexagonal cell (124);

A first supply hose 114 installed at one side of the upper surface of the water receiving hexagonal cell 124;

A second supply hose 126 installed at one side of the upper surface of the water receiving hexagonal cell 124 at a predetermined interval from the first supply hose 114;

A third supply hose 128 installed at one side of the upper surface of the water receiving hexagonal cell 124 at a predetermined interval from the second supply hose 126;

Shaped distribution pipe 130 located at one side of the upper surface of the water-receiving hexagonal cell 124 and installed between the first supply hose 114 and the second supply hose 126;

The first supply hose 126 and the third supply hose 128 are disposed at one side of the upper surface of the water receiving hexagonal cell 124 at regular intervals from the first " 2 "-shaped distribution pipe 132;

Shaped distribution pipe (132) which is located at one side of the upper surface of the water-receiving hexagonal cell (124) at a predetermined interval from the second "-shaped distribution pipe (132), and which is located at the end of the third supply hose (134);

An auxiliary control unit 112 for wireless communication provided at one side of the upper surface of the water-receiving hexagonal cell 124 at a predetermined interval from the third "-shaped distribution pipe 134;

And is disposed at one end of the upper surface of the water receiving hexagonal cell 124 and is installed at the end of the first supply hose 114 and is electrically connected to the wireless communication auxiliary control unit 112 and is connected to the control signal of the wireless communication auxiliary control unit 112 A solenoid valve 138 having a discharge port 136 for discharging water or nutrient solution (for example, nutrients) supplied to the first supply hose 114 into the soil;

The discharge hose 136 is detachably mounted on the upper surface of the water receiving hexagonal cell 124 to prevent the components installed on the water receiving hexagonal cell 124 from being separated from the water receiving hollow hexagonal cell 124. In order to protrude the discharge port 136 of the solenoid valve 138, (Not shown), and a connection groove 142 (not shown) having a connection hole 140 formed on an upper surface corresponding to the first, second and third "ㅗ" -type distribution pipes 130, 132, A cover hexagonal cell 144 provided with a cover 180;

A temperature sensing sensor 146 which is provided at one side of the inner surface of the lid hexagonal cell 144 and is electrically connected to the wireless communication auxiliary control unit 112 and senses the temperature in the air according to a control signal of the wireless communication auxiliary control unit 112, Wow;

The wireless communication auxiliary control unit 112 is electrically connected to the wireless communication auxiliary control unit 112. The wireless communication auxiliary control unit 112 controls the temperature of the air A humidity sensor 148 for sensing the humidity of the air;

The wireless communication auxiliary control unit 112 is electrically connected to the wireless communication auxiliary control unit 112. The wireless communication auxiliary control unit 112 is provided at one side of the inner surface of the cover hexagonal cell 144 with a predetermined interval from the humidity sensing sensor 148, A carbon dioxide sensing sensor 150 for sensing the carbon dioxide contained in the carbon dioxide;

The control signal is electrically connected to the wireless communication auxiliary control unit 112 and is connected to the control signal of the wireless communication auxiliary control unit 112 so that the soil And a soil moisture sensor 152 for sensing the moisture of the soil.

Here, it is preferable that one side of the third "-shaped distribution pipe 134 is closed.

In addition, in the assembled smart drawing room system 100 according to the present invention,

A connecting plate 142 is screwed to the connection groove 142 of the lid hexagonal cell 144 and the connection groove 142 of the lid hexagonal cell 144 to connect the control hexagonal cell 116 and the control hexagonal cell 116 154);

Shaped distribution pipe 130 or one side of the second "-shaped distribution pipe 132 or the third" -shaped distribution pipe 130 through the connection hole 140 of the connection groove 142, (E.g., nutrients) to the first, second, and third supply hoses 114, 126, 128, which are connected to one side of the first supply hose 134.

The installation process and the use state of the assembled smart drawing room system 100 according to the present invention configured as described above will be described below.

Here, the installation process of the assembled smart flower bed system according to the present invention can be changed as much as the installer.

First, a smart flower department main controller 122 communicating with an administrator smartphone 120 at a remote location is installed.

A motor communication pump 118 for wireless communication is installed at a predetermined interval from the main control unit 122 of the smartphone in accordance with a control signal of the smartphone main control unit 122.

A single hexagonal cell 108 and a through hole 106 having a bottom plate 104 and a through hole 106 provided with a water drop hole 102 at predetermined intervals from the wireless communication motor pump 118, Including a hexagonal cell 110 having a hexagonal cell 110 and a through hole 106 and a control hexagonal cell 116 having a wireless communication auxiliary control unit 112 and a first supply hose 114 inside the cell, Install flower beds.

The wireless communication auxiliary controller 112 communicates with the smartphone main controller 122.

Here, the process of installing the control hexagonal cell 116 will be described in more detail.

After the water-receiving hexagonal cell 124 is positioned, the first supply hose 114 is installed on the upper surface of the water-receiving hexagonal cell 124. The second supply hose 126 is installed on one side of the upper surface of the water receiving hexagonal cell 124 at a predetermined interval from the first supply hose 114.

The third supply hose 128 is installed on one side of the upper surface of the water receiving hexagonal cell 124 at a predetermined interval from the second supply hose 126 and then the first supply hose 114 and the second supply hose 126 ", a first" ㅗ "shaped distribution pipe 130 is installed.

The second supply hose 128 is installed between the second supply hose 126 and the third supply hose 128. The third supply hose 128 is connected to the third supply hose 128 via a second & And a "ㅗ" shaped distribution pipe 134 is installed.

An auxiliary control unit 112 for wireless communication is installed on the upper surface of the water-receiving hexagonal cell 124 at regular intervals from the third "-shaped distribution pipe 134.

A solenoid valve 138 having a discharge port 136 is installed at the end of the first supply hose 114 and electrically connects the solenoid valve 138 to the wireless communication auxiliary control unit 112.

Then, the cover hexagonal cell 144 is positioned.

An insertion hole (not shown) is provided on the side surface of the lid hexagonal cell 144 so that a discharge port 136 of the solenoid valve 138 can protrude therefrom, and a first, second, and third A connection groove 142 is formed in correspondence with the ㅗ-shaped distribution pipe 130, 132 and 134, and a connection hole 140 is provided at the center of the connection groove 142.

A lid hexagonal cell 144 is provided on the upper surface of the water receiving hexagonal cell 124. At this time, the lid hexagonal cell 144 prevents the components installed on the upper surface of the water retention hexagonal cell 124 from being separated.

After the temperature sensing sensor 146 is installed on one side of the inner surface of the cover hexagonal cell 144, the temperature sensing sensor 146 is electrically connected to the wireless communication auxiliary control unit 112.

After the humidity sensor 148 is installed at one side of the inner surface of the lid hexagonal cell 144 at a predetermined interval from the temperature sensor 146, a humidity sensor 148 is attached to the wireless communication auxiliary controller 112 Connect electrically.

After the carbon dioxide sensing sensor 150 is installed at one side of the inner surface of the lid hexagonal cell 144 at a predetermined interval from the humidity sensor 148, the carbon dioxide sensing sensor 150 is attached to the wireless communication auxiliary controller 112 Connect electrically.

The soil moisture sensor 152 is installed on one side of the inner surface of the lid hexagonal cell 144 at a predetermined interval from the carbon dioxide sensing sensor 150 and then the soil moisture sensor 152 ) Are electrically connected.

Referring to FIG. 2A and FIG. 7,

After positioning the bottom plate 104, another bottom plate 104 is positioned on one side of the bottom plate 104.

A hexagonal hexagonal cell 110 is provided on the upper surface of the bottom plate 104 and another hexagonal hexagonal cell 110 is provided on the upper surface of the hexagonal hexagonal cell 110.

A single hexagonal cell 108 is provided on one side of the upper surface of the double hexagonal cell 110 and another single hexagonal cell 108 is provided on the upper surface of the single hexagonal cell 108.

A control hexagonal cell 116 is provided on the top surface of the single hexagonal cell 108 to provide the first formation 200.

A single hexagonal cell 108 is provided on one side of the upper surface of the hexagonal hexagonal cell 110 provided at one side of the first forming stage 200 and a single hexagonal cell 108 ).

A control hexagonal cell 116 is provided on the upper surface of the uppermost single hexagonal cell 108 to provide a second formation 202.

After the connection pipe 156 is positioned, one end of the connection pipe 156 is connected to the second "L" -shaped distribution pipe 156 through the connection hole 140 of the control hexagonal cell 116 of the first connection pipe 200, (132).

The other end of the connection pipe 156 is connected to the third "-shaped distribution pipe 134 through the connection hole 140 of the control hexagonal cell 116 of the second connection pipe 202.

After the connecting plate 154 is positioned, the connecting plate 154 connects the first feeding end 200 and the second feeding end 202 to each other.

After the bottom plate 104 is positioned on one side of the second forming stage 202, another bottom plate 104 is positioned on one side of the bottom plate 104.

A hexagonal hexagonal cell 110 is provided on the upper surface of the bottom plate 104 and another hexagonal hexagonal cell 110 is provided on the upper surface of the hexagonal hexagonal cell 110.

A single hexagonal cell 108 is provided on one side of the upper surface of the double hexagonal cell 110 and another single hexagonal cell 108 is provided on the upper surface of the single hexagonal cell 108.

After three single hexagonal cells 108 are successively provided on the upper surface of the other single hexagonal cell 108, the control hexagonal cell 116 is provided on the upper surface of the single best hexagonal cell 108, (204).

After the connection pipe 156 is positioned, one end of the connection pipe 156 is connected to the first "L" -shaped distribution pipe 156 through the connection hole 140 of the control hexagonal cell 116 of the second connection pipe 202 (130).

The other end of the connection pipe 156 is connected to the third "-shaped distribution pipe 134 through the connection hole 140 of the control hexagonal cell 116 of the third connection pipe 204.

A single hexagonal cell 108 is provided on one side of the upper surface of the hexagonal hexagonal cell 110 provided at one side of the third formation stage 204 and a single hexagonal cell 108 ).

A control hexagonal cell 116 is provided on the top surface of the single hexagonal cell 108 to form a fourth dividing line 206.

In addition, the fifth processing stage 208 and the sixth processing stage 210 are installed by the above installation method.

When the installation of the assembled smart potting system 100 according to the present invention is completed,

Gravel, earth or the like is fed into the inside of the first, second, third, fourth, fifth, and sixth stages 200, 200, 204, 206, 206, Put in soil to make.

Then, plants are planted in the soil.

The operation of the assembled smart potting system 100 according to the present invention will be described below.

For example, if plants are planted inside the first and second cooking zones 200 and 202,

The manager smartphone 120 sends a signal to the smart flower department main controller 122.

The main control unit 122 controls the wireless communication motor pump 118 and the wireless communication auxiliary control unit 112 of the first generation unit 200 and the wireless communication auxiliary control unit 112 of the second generation unit 202, Lt; / RTI > Here, the wireless communication auxiliary controller 112 performs Zigbee communication.

The wireless communication motor pump 118 supplies water or a nutrient solution (for example, nutrients) to the first supply hose 114 of the control hexagonal cell 116 of the first feeding stage 200.

The wireless communication auxiliary control unit 112 of the first processing stage 200 includes a solenoid valve 138 having a discharge port 136, a temperature sensing sensor 146, a humidity sensing sensor 148, a carbon dioxide sensing sensor 150, And sends a signal to the soil moisture sensor 152.

The solenoid valve 138 sends the water or nutrient solution supplied to the first supply hose 114 to the soil through the discharge port 136 according to the signal of the auxiliary communication control unit 112 for wireless communication.

The water or nutrient solution supplied to the first supply hose 114 is supplied to the second feeder hose 114 through the second feed pipe 132 and the connection pipe 156 of the first feeder 200, Apos; ' -shaped distribution tube 134 of the second compressor 202.

The temperature sensing sensor 146 provided at one side of the inner surface of the lid hexagonal cell 144 of the first processing stage 200 is connected to the temperature control unit 130 in accordance with the control signal of the wireless communication auxiliary control unit 112 of the first processing stage 200, Lt; / RTI >

The humidity sensing sensor 148 provided on one side of the inner surface of the lid hexagonal cell 144 of the first stage 200 senses the humidity in the air according to the control signal of the wireless communication auxiliary controller 112 of the first stage 200, Lt; / RTI >

The carbon dioxide sensing sensor 150 installed on one side of the inner surface of the lid hexagonal cell 144 of the first stage 200 is connected to the first communication terminal Lt; / RTI >

The soil moisture sensor 152 installed at one side of the inner surface of the lid hexagonal cell 144 of the first laden 200 is connected to the ground water sensor 152 of the first laden 200 in accordance with the control signal of the wireless communication auxiliary controller 112 of the first ladget 200, Sensing moisture.

On the other hand, the third "-type " distribution pipe 134 of the second feed end 202 is connected to the first feed (not shown) of the control hexagonal cell 116 of the second feed end 202, And sends it to the hose 114.

The auxiliary control unit 112 for wireless communication of the second generation stage 202 includes a solenoid valve 138 having a discharge port 136, a temperature sensing sensor 146, a humidity sensing sensor 148, a carbon dioxide sensing sensor 150, And sends a signal to the soil moisture sensor 152.

The solenoid valve 138 sends the water or nutrient solution supplied to the first supply hose 114 to the soil through the discharge port 136 according to the signal of the auxiliary communication control unit 112 for wireless communication.

Hereinafter, the description of the operation of the second flower pot 202 will be omitted.

In addition, the operations of the third, fourth, second, third, fourth, fifth, and sixth feeders 204, 206, 208, 210 are the same as those of the first feeder 200.

The foregoing description of the invention is merely exemplary of the invention and is used for the purpose of illustration only and is not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: Assembled smart flower bed system 102: Water dropping ball
104: bottom plate 106: through hole
108: single hexagonal cell 110: double hexagonal cell
112: Wireless communication auxiliary control unit 114: First supply hose
116: hexagonal cell for control 118: motor pump for wireless communication
120: Manager Smartphone 122: Smart flowerbed main part
124: water tray hexagonal cell 126: second supply hose
128: third supply hose 130: first "ㅗ" shaped distribution pipe
132: second "ㅗ" shaped distribution pipe 134: third "ㅗ" shaped distribution pipe

Claims (6)

A bottom plate (104) having a water drop hole (102) at regular intervals therein; And a single hexagonal cell (108) detachably installed along the top edge of the bottom plate (104), the single hexagonal cell (108) having a through hole (106) in the center of the cell,
A hexagonal cell 110 (not shown) provided detachably along the top edge of the bottom plate 104 or detachably installed on the bottom or top surface of the single hexagonal cell 108, )and;
The wireless communication auxiliary controller 112 and the wireless communication auxiliary controller 112 are provided inside the cell. The wireless communication auxiliary controller 112 and the auxiliary wireless communication controller 112 are provided in the cell, A control hexagonal cell 116 having one supply hose 114;
A wireless communication motor pump 118 for supplying water or nutrient solution to the first supply hose 114 installed inside the control hexagonal cell 116;
Communicates with the wireless communication auxiliary control unit 112 of the control hexagonal cell 116 and communicates with the manager smartphone 120 to turn on or off the driving of the wireless communication motor pump 118 off of the smart flower room main controller 122,
The control hexagonal cell (116)
A water-bearing hexagonal cell (124);
A first supply hose 114 installed at one side of the upper surface of the water receiving hexagonal cell 124;
A second supply hose 126 installed at one side of the upper surface of the water receiving hexagonal cell 124 at a predetermined interval from the first supply hose 114;
A third supply hose 128 installed at one side of the upper surface of the water receiving hexagonal cell 124 at a predetermined interval from the second supply hose 126;
Shaped distribution pipe 130 located at one side of the upper surface of the water-receiving hexagonal cell 124 and installed between the first supply hose 114 and the second supply hose 126;
The first supply hose 126 and the third supply hose 128 are disposed at one side of the upper surface of the water receiving hexagonal cell 124 at regular intervals from the first " 2 "-shaped distribution pipe 132;
Shaped distribution pipe (132) which is located at one side of the upper surface of the water-receiving hexagonal cell (124) at a predetermined interval from the second "-shaped distribution pipe (132), and which is located at the end of the third supply hose (134);
An auxiliary control unit 112 for wireless communication provided at one side of the upper surface of the water-receiving hexagonal cell 124 at a predetermined interval from the third "-shaped distribution pipe 134;
And is disposed at one end of the upper surface of the water receiving hexagonal cell 124 and is installed at the end of the first supply hose 114 and is electrically connected to the wireless communication auxiliary control unit 112 and is connected to the control signal of the wireless communication auxiliary control unit 112 A solenoid valve 138 having a discharge port 136 for discharging the water or nutrient solution supplied to the first supply hose 114 to the soil;
The discharge hose 136 is detachably mounted on the upper surface of the water receiving hexagonal cell 124 to prevent the components installed on the water receiving hexagonal cell 124 from being separated from the water receiving hollow hexagonal cell 124. In order to protrude the discharge port 136 of the solenoid valve 138, And a connection groove 142 having a connection hole 140 formed on an upper surface corresponding to the first, second, and third "-shaped" distribution pipes 130, 132 and 134, A cell 144;
A temperature sensing sensor 146 which is provided at one side of the inner surface of the lid hexagonal cell 144 and is electrically connected to the wireless communication auxiliary control unit 112 and senses the temperature in the air according to a control signal of the wireless communication auxiliary control unit 112, Wow;
The wireless communication auxiliary control unit 112 is electrically connected to the wireless communication auxiliary control unit 112. The wireless communication auxiliary control unit 112 controls the temperature of the air A humidity sensor 148 for sensing the humidity of the air;
The wireless communication auxiliary control unit 112 is electrically connected to the wireless communication auxiliary control unit 112. The wireless communication auxiliary control unit 112 is provided at one side of the inner surface of the cover hexagonal cell 144 with a predetermined interval from the humidity sensing sensor 148, A carbon dioxide sensing sensor 150 for sensing the carbon dioxide contained in the carbon dioxide;
The control signal is electrically connected to the wireless communication auxiliary control unit 112 and is connected to the control signal of the wireless communication auxiliary control unit 112 so that the soil And a soil moisture sensor 152 for sensing the moisture of the soil water,
One side of the third "-shaped distribution pipe 134 is closed,
A connecting plate 142 is screwed to the connection groove 142 of the lid hexagonal cell 144 and the connection groove 142 of the lid hexagonal cell 144 to connect the control hexagonal cell 116 and the control hexagonal cell 116 154);
Shaped distribution pipe 130 or one side of the second "-shaped distribution pipe 132 or the third" -shaped distribution pipe 130 through the connection hole 140 of the connection groove 142, (156) connected to one side of the first supply hose (134) and supplying water or nutrient solution to the first, second and third supply hoses (114, 126, 128) Allowing plants to be easily managed,
An auxiliary control unit 112 for radio communication provided inside the control hexagonal cell 116,
And performs Zigbee communication with the main control unit (122).









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