KR102525351B1 - Greenhouse for hydroponic spray cultivation stacked in vertical multilayers - Google Patents

Abstract

The present invention relates to a greenhouse for hydroponic spray cultivation that is stacked in vertical multi-layers, and more particularly, since crops can be grown in a multi-layered space room, the cultivation area of crops can be integrated, and the growth state and harvest time of crops can be integrated. can be monitored in real time in one place, increasing crop cultivation work efficiency, thereby increasing productivity and efficiency, and using self-generation systems such as wind power generation, solar heat exchanger, photovoltaic power generation, and heat storage. As a result, maintenance costs and crop cultivation costs are reduced.

Description

Greenhouse for hydroponic spray cultivation stacked in vertical multilayers}

The present invention relates to a greenhouse for hydroponic spray cultivation that is stacked in vertical multi-layers, and more particularly, since crops can be grown in a multi-layered space room, the cultivation area of crops can be integrated, and the growth state and harvest time of crops can be integrated. It relates to a greenhouse for hydroponic spray cultivation that is stacked in vertical multi-layers that increases crop cultivation work efficiency because it can monitor in real time in one place, thereby increasing productivity and efficiency.

In general, crops such as farm products and flowers promote growth and development in an appropriate environment and climate. Depending on the type of crop, the proper level of illumination, length of day and night, temperature, humidity, etc. must be maintained to grow normally.

Recently, crops are grown by artificially manipulating the environment and climate using plastic greenhouses or glass buildings.

Therefore, even in regions with cold climates, tropical fruits and vegetables can be produced, and specific fruits and vegetables can be grown regardless of the season.

However, in the prior art, seeds or seedlings are directly planted in the soil in a plastic greenhouse or glass building, grown, and harvested fruits or vegetables grown while moving around, requiring a lot of labor and labor time for growing and harvesting crops.

In addition, in the prior art, since the growth state and harvest time of crops must be determined by walking after entering a plastic greenhouse or glass building, more labor and labor time are required for growing and harvesting crops.

In addition, in the prior art, since temperature, humidity, etc. are controlled by manual manipulation of devices in a plastic greenhouse or glass building, it is difficult to maintain optimal conditions for the development and growth of specific crops.

In addition, since crops are grown in conventional plastic greenhouses or glass buildings, it is difficult to integrate crop cultivation areas.

In addition, the conventional vinyl house or glass building is formed in a flat tunnel or horizontal shape, requiring a lot of cultivation land, and installing a lot of vinyl houses to increase the yield of crops, so installation, maintenance costs and installation land increase, crops Productivity is reduced due to the decrease in cultivation work efficiency.

Korean Patent Registration No. 10-2134635

The present invention has been made to solve the above conventional problems,

Since crops can be grown in multi-layered space rooms, the cultivation area of crops can be integrated, and crop cultivation work efficiency can be increased because the growth status and harvest time of crops can be monitored in real time in one place. It is an object to provide a vinyl house for hydroponic spray cultivation that is stacked in vertical multi-layers that increase productivity and efficiency.

In addition, by using a self-generation system such as a wind power generation unit, a solar heat exchange unit, a solar power generation unit, and a heat storage unit, the purpose is to provide a vertically multi-layered hydroponic greenhouse that reduces maintenance costs and crop cultivation costs. there is.

In order to achieve the above object, the present invention is a body portion in which a frame is formed so that space rooms are stacked in a vertical multi-layer structure, and a vinyl film is formed on the outside of the frame;

a space portion vertically formed on one side of the main body portion through which an interior passes, and an elevating device selectively connected to each space room is formed in the through portion;

a wind power generator installed on the uppermost surface of the main body and generating power by being rotated by external wind power and wind power discharged to the outside from within the main body;

a solar heat exchange unit installed on one side of the exterior of the main body unit to transfer the heat source exchanged with solar heat to the heat storage unit;

A heat storage unit formed in the lower ground of the body unit, filled with a heat storage material to store heat by exchanging heat with a heat source transmitted from the solar heat exchange unit, and supplying the heat source stored in the heat storage material to the inside of the body unit for temperature control;

a rainwater storage unit formed in the lower ground of the body unit to collect and store external rainwater and to supply the stored rainwater to crops grown in the space room of the body unit;

It relates to a plastic greenhouse for hydroponic spray cultivation that is stacked in vertical multi-layers, characterized in that it comprises a; .

In addition, the wind power generation unit of the present invention, and a first blade portion in which a plurality of first blades are formed vertically so as to be rotated by external wind power that is transported horizontally;

a second blade unit in which a plurality of second wings are formed inclined in a horizontal direction so as to be rotated by wind power discharged through a through-hole formed in an uppermost surface of the main body unit;

a wind power shaft formed at the center of the first blade unit and the second blade unit and connected to the first blade unit and the second blade unit and rotated by the rotation of the first blade unit and the second blade unit;

It relates to a greenhouse for hydroponic spray cultivation that is stacked in vertical multi-layers, characterized in that it comprises a; generator connected to the wind power rotation shaft and generated by the rotational force of the wind power rotation shaft.

In addition, a wind blocking film is formed on the outer periphery of the first blade unit of the present invention so that external wind power flows only to one side of the first blade unit,

The wind blocking film is formed to block only 1/4 of the outer periphery of the first blade unit, and the wind blocking film is connected to a support connected to an upper portion of the first blade unit,

The support is connected to the upper part of the first blade unit by a bearing device and is horizontally rotatable, and a vertical multi-layer tail is formed on the upper part of the support to rotate the wind shield in the direction in which the external wind blows. It relates to a vinyl house for hydroponic spray cultivation that is laminated with.

In addition, a plurality of shafts are formed on the outer part of the first wing of the first blade part and the second wing of the second blade part of the present invention to rotate according to the first wing and the second wing, a magnet is installed on the shaft, and the magnet It relates to a vinyl house for hydroponic spray cultivation that is stacked in vertical multi-layers, characterized in that coil parts are formed on both sides of the shaft and power is generated by the rotational force of the shaft.

In addition, the solar heat exchanger of the present invention is formed from one outer side of the body part to the inside of the heat storage part through the space part, and after the air filled inside exchanges heat with solar heat, heat exchange with the heat storage material of the heat storage part to supply a heat source. A heat exchange pipe;

a heat exchange reflector formed behind the heat exchange pipe provided on one outer side of the main body unit and curved to collect solar heat toward the heat exchange pipe;

It relates to a plastic greenhouse for hydroponic spray cultivation that is stacked in vertical multi-layers, characterized in that it comprises a; first blowing fan communicating with one side of the heat exchange pipe to circulate air in the heat exchange pipe.

In addition, the light blocking unit of the present invention, and the rotary motor installed on the outside of the main body;

a motor rotation shaft connected to the rotation motor and rotated by the rotation motor;

a light shielding net that shields the outside of the vinyl film of the main body unit while being unwound and wound up and down or left and right in accordance with the direction of rotation of the motor rotation shaft in a state wound around the motor rotation shaft;

a holder installed at an end of the light-shielding network to apply a load to the light-shielding network while maintaining the light-shielding network in a flatly spread state;

It relates to a vinyl house for hydroponic spray cultivation that is stacked in vertical multi-layers, characterized in that it comprises a; .

In addition, the vinyl film of the present invention is formed by winding vinyl around a vinyl frame several times, then manufacturing several vinyl frames wrapped with vinyl, connecting the plurality of vinyl frames in a manner of assembling each other and installing them on the outside of the frame, It relates to a vinyl house for hydroponic spray cultivation that is laminated in vertical multi-layers, characterized in that a foam insulation for closing the gap is further formed between the vinyl film 12 and the frame.

As described above, the vertical multi-layered hydroponic greenhouse of the present invention can grow crops in a multi-layered space, so that the cultivation area of crops can be integrated, and the growth state and harvest time of crops can be integrated. can be monitored in real time in one place, increasing crop cultivation work efficiency, thereby increasing productivity and efficiency.

In addition, by using a self-generation system such as a wind power generation unit, a solar heat exchange unit, a solar power generation unit, and a heat storage unit, there is an effect of reducing maintenance costs and crop cultivation costs.

1 is an overall perspective view showing a vinyl house for hydroponic spray cultivation stacked in vertical multi-layers according to an embodiment of the present invention;
2 is a cross-sectional view showing the uppermost body portion according to an embodiment of the present invention;
Figure 3 is a schematic diagram showing a wind power generator according to an embodiment of the present invention,
4 is a perspective view showing an upper portion of a first blade unit according to an embodiment of the present invention;
5 is a schematic diagram showing a solar heat exchange unit connected to a heat storage unit according to an embodiment of the present invention;
6 is a front view showing a light shielding unit installed in a main body according to an embodiment of the present invention.

The present invention having such characteristics will be more clearly explained through the preferred embodiments thereof.

Before describing various embodiments of the present invention in detail with reference to the accompanying drawings, it will be appreciated that the application is not limited to the details of the configuration and arrangement of components described in the following detailed description or shown in the drawings. will be. The invention is capable of being implemented and practiced in other embodiments and of being carried out in various ways. Also, device or element orientation (e.g., "front", "back", "up", "down", "top", "bottom") The expressions and predicates used herein with respect to terms such as ", "left", "right", "lateral", etc. are only used to simplify the description of the present invention and related devices. Or it will be appreciated that it does not indicate or imply that an element simply must have a particular orientation. Also, terms such as “first” and “second” are used herein and in the appended claims for descriptive purposes and are not intended to indicate or imply relative importance or significance.

Therefore, since the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention, various alternatives may be used at the time of this application. It should be understood that there may be equivalents and variations.

1 is an overall perspective view showing a plastic greenhouse for hydroponic spray cultivation stacked in vertical multi-layers according to an embodiment of the present invention, FIG. 2 is a cross-sectional view showing the uppermost body part according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view of the present invention. A schematic diagram showing a wind power generation unit according to an embodiment of, Figure 4 is a perspective view showing the top of the first blade unit according to an embodiment of the present invention, Figure 5 is connected to the heat storage unit according to an embodiment of the present invention It is a schematic diagram showing a solar heat exchanger, and FIG. 6 is a front view showing a light shielding unit installed in a main body according to an embodiment of the present invention.

As shown in FIGS. 1 to 6, the vertical multi-layered plastic greenhouse for hydroponic cultivation of the present invention includes a body part 10, a space part 20, a wind power generation part 30, and a solar heat exchanger part. (40), a heat storage unit (50), a rain water storage unit (60), and a light blocking unit (70). At this time, the body part 10, the space part 20, the wind power generator 30, the solar heat exchanger 40, the heat storage unit 50, the rainwater storage unit 60, and the light blocking unit (70) is automatically controlled by the controller 100.

As shown in FIGS. 1 to 2 and 6, the body portion 10 is composed of a frame 11 and a vinyl film 12, and the frame 11 of the body portion 10 is vertically stacked. The space room is made up of several layers, and the frame 11 is assembled by fitting into a frame, that is, by combining and stacking the frame 11 of another layer on top of the frame 11 of one layer. At this time, an entrance is further formed in the body part 10 of the first floor.

Here, the vinyl film 12 is formed on the outside of the frame 11 to protect the crops grown in the space room from the outside by bordering the inside and outside of the frame 11. At this time, the vinyl film 12 is formed by winding vinyl around a vinyl frame several times, then manufacturing several vinyl frames wrapped with vinyl, and connecting the plurality of vinyl frames in a manner of assembling each other to form the outer side of the frame 11. install on At this time, a foam insulation material (not shown) is further formed between the vinyl film 12 and the frame 11 to close the gap.

In addition, a separate bottom plate 13 is formed in the space room, and crops for hydroponic cultivation are provided on the bottom plate 13, and the bottom plate 13 rotates with the rail so that sunlight is evenly transmitted to the entire crop. It is configured to be rotated by a motor.

In addition, in the space room, a mist supply device (not shown) connected to the underground water or external water supply facility or rainwater storage unit 60 is further formed on top of the crops for hydroponic cultivation, and the mist supply device can be sprayed to supply water to crops or control the temperature in the space room.

Here, a roof 14 is formed at the top of the frame 11, and the roof 14 is formed in various shapes such as a dome, a triangle, a plane, and an inclined surface, and the roof 14 has rainwater that can collect rainwater. A receiver 15 is further formed, and the rainwater receiver 15 is connected to the rainwater storage unit 60 by a pipe or the like, and the collected rainwater is transferred to the rainwater storage unit 60.

In addition, a through hole 16 through which air in the body part 10 is discharged to the outside is further formed on one surface of the roof 14 of the main body part 10, and the through hole 16 is a wind power generator 30 ) and the air discharged in communication affects the wind power generation unit 30.

In addition, a ventilation window 17 is formed on the outer periphery of the uppermost layer of the body portion 10 by a vinyl film 12, and the vinyl film 12 of the ventilation window 17 is connected by a hinge device to operate manually or by a motor. It can be opened and closed to ventilate the inside of the body portion 10 . At this time, a blowing fan (not shown) capable of transporting the air in the body portion 10 upward is further formed on the uppermost ceiling of the body portion 10, and the air in the body portion 10 is blown by the blowing fan. It is discharged through the ventilation window 17 or through hole 16.

Here, in order for the air in the main body 10 to be transported upward, a plurality of through holes 18 are formed in the bottom plate 13 so that the air can be transported upward in the space rooms of each floor.

Meanwhile, a temperature and humidity control device (not shown) capable of adjusting internal temperature and humidity is separately formed in the space room, and the temperature and humidity control device is automatically controlled by the control unit 100.

As shown in FIGS. 1 and 5, the space portion 20 is formed vertically on the outer surface of one side of the main body portion 10 and penetrates the inside, and is selectively connected to each space room in the penetrated interior. An elevating device 21 is formed. At this time, the elevator device 21 is similar to a normal elevator, so no separate description is required.

Here, an opening and closing door (not shown) is formed on the first floor in the space part 20 to open and close on both sides, so that a user can get on the elevator 21 with an object from the ground or enter the first floor of the body part 10. In addition, an opening and closing door is formed on each floor of the body unit 10 according to the space room, and it is possible to enter each floor of the space room using the elevating device 21.

In addition, in the space part 20, a separate space is secured in addition to the elevating device 21, and various pipes, electricity installed on the roof 14 of the body part 10 and connected to a space room or facilities installed on the ground or underground Facilities and the like are provided through.

As shown in FIGS. 1 and 3 to 4, the wind power generation unit 30 is installed on the uppermost surface of the body portion 10, and the wind power of the external wind and the body portion 10 are discharged to the outside. It is composed of a first blade unit 31, a second blade unit 32, a wind power shaft 33, and a generator 34 so as to be rotated and generated by wind power.

The first blade unit 31 is formed vertically with a plurality of first wings 31a so as to be rotated by external wind power transported horizontally. The plurality of first wings 31a are formed along the edge of a cylindrical frame. It is formed spaced apart from each other, and the first wing (31a) is formed curved so that the wind power of the external wind is well transmitted.

The second blade part 32 is rotated by wind power discharged through the through hole 16 formed through the roof 14 of the body part 10 between the through hole 16 and the first blade part 31. In the second blade part 32, a plurality of second wings 32a are formed in the horizontal direction on the top of the cylindrical frame.

Here, the second wing 32a is formed in a horizontal direction but inclined in a curved or spiral shape so that the second blade part 32 is rotated by the wind power discharged vertically from the lower through-hole 16, so that the second wing 32a is formed vertically The second blade unit 32 can be horizontally rotated by the wind power of.

The wind power rotation shaft 33 is formed vertically at the center of the frame of the first blade unit 31 and the second blade unit 32 to connect the first blade unit 31 and the second blade unit 32, and at the same time The rotational force of the first blade unit 31 and the second blade unit 32 is transmitted.

The generator 34 is a device that is connected to the wind power shaft 33 and generates power by rotational force transmitted from the wind power rotation shaft 33, and the generator 34 is a generator that generates power by normal rotational force, so a separate configuration and structure and functions are not described. At this time, the electricity generated and charged by the generator 34 is supplied to facilities provided in the vinyl house.

On the other hand, on the outer periphery of the first blade unit 31, as shown in FIG. 4, the wind force of the external wind is introduced only to one side of the first blade unit 31 to rotate the first blade unit 31 in only one direction to generate rotational force. The wind blocking film 35 is formed so as to increase, and the wind blocking film 35 is formed to block only 1/4 of the outer periphery of the first blade unit 31.

Here, the wind blocking film 35 is connected to a support 36 connected to an upper portion of the first blade unit 31, and the support 36 has a bearing device (not shown) on the upper portion of the frame of the first blade unit 31. It is connected by a) and is horizontally rotatable, and on the opposite side of the wind shield 35 of the upper part of the support 36, the tail blade 37 rotates the wind shield 35 toward the direction in which the wind of the external wind blows. ) is formed.

In addition, the tail fins 37 are formed in a vertically erected shape, and when an external wind blows, the position changes in a straight line with the direction in which the wind blows. At this time, by rotating the support 36, the wind blocking film 35 ) Also rotated along the outer periphery of the first blade unit 31 is provided in the direction in which the wind blows.

On the other hand, a plurality of shafts 38 are formed on the outer sides of the first wing 31a of the first blade part 31 and the second wing 32a of the second blade part 32, so that the first wing 31a and It is rotated according to the second wing 32a, the magnet 38a is installed on the shaft 38, and the coil part 39 is formed on both sides of the magnet 38a, so that the magnet is operated by the rotational force of the shaft 38. Electric power is generated and generated in 38a and coil unit 39. At this time, the amount of power generation increases according to the number of shafts 38 and coil units 39 on which the magnets 38a are installed.

As shown in FIGS. 1 and 5, the solar heat exchanger 40 is a system device that is installed on one outer side of the main body 10 and transmits a heat source exchanged with solar heat to the heat storage unit, and the main body 10 It is installed on the roof of the exterior or on the upper part of the space to smoothly exchange heat with solar heat.

Here, the solar heat exchange unit 40 includes a heat exchange pipe 41 for supplying a heat source by exchanging heat with the heat storage material of the heat storage unit 50 after the air filled therein exchanges heat with solar heat; a heat exchange reflector 42 formed behind the heat exchange pipe 41 provided on one outer side of the main body 10 and curved to collect solar heat toward the heat exchange pipe 41; It is composed of a first blowing fan 43 communicating with one side of the heat exchange pipe 41 to circulate air in the heat exchange pipe 41 .

In addition, the heat exchange pipe 41 is formed in a zigzag shape on one outer side of the body portion 10, and then vertically penetrates through the space portion 20 to form the inside of the heat storage unit 50, and the heat storage unit ( The heat exchange pipe 41 in 50) is also formed in a zigzag shape and communicates with the heat exchange pipe 41 formed in a zigzag shape on one outer side of the main body 10, so that internal air is circulated. At this time, the heat exchange pipe 41 formed on one outer side of the body part 10 among the heat exchange pipes 41 is painted or coated in a dark color to absorb a large amount of solar heat.

On the other hand, a solar power generation unit (not shown) is further provided on one outer side of the main body unit 10 in addition to the solar heat exchange unit 40, and power generated by sunlight is also supplied to facilities provided in the vinyl house to generate self-power. can supply

As shown in FIGS. 1 and 5, the heat storage unit 50 is formed on the lower side of the main body 10 and exchanges heat with a heat source transmitted from the solar heat exchange unit 40, and the heat exchange The heat source is stored in a heat storage material such as stones or pebbles filled inside the heat storage unit 50, and the heat stored in the heat storage material is supplied to the inside of the main body 10 for temperature control.

Here, the heat exchange pipe 41 of the solar heat exchanger 40 is provided through the heat storage unit 50 in a zigzag form, and the remaining space is filled with the heat storage material, and the heat source and the heat storage material transferred in the heat exchange pipe 41 exchange heat. To store the heat source in the heat storage unit (50).

In addition, the heat storage unit 50 can control the temperature in the body unit 10 by supplying air stored in an internal heat source to the main body unit 10 by means of a blowing pipe (not shown) and a blowing fan (not shown) communicated with each other. there is. At this time, the blower pipe communicates the inside of the heat storage unit 50 and the inside of the main body unit 10, and opening and closing dampers (not shown) are installed at each inlet and outlet to be opened and closed by the control unit 100, Heat source supply of the heat storage unit 50 may be adjusted.

As shown in FIG. 1, the rainwater storage unit 60 is formed below the ground or outside of the body portion 10 and is installed on the roof 14 of the body portion 10. The collected rainwater is transported and stored inside, and the stored rainwater is supplied to the crops grown in the space room of the body part 10 by the mist supply device.

As shown in FIGS. 1 and 6 , the light blocking part 70 is installed on the outside of the body part 10 and rotates to be driven up and down or left and right to adjust the light irradiated into the body part 10. It is composed of a motor 71, a motor rotation shaft 72, a light shielding net 73, a holder 74, and a jolder 75.

Here, the rotary motor 71 is installed on the outside of the main body 10, and is installed in line with the vertical or horizontal movement of the light shielding net 73, and the motor rotary shaft 72 is connected to the rotary motor 71. It is rotated by the rotation motor 71.

In addition, the light shielding net 73 is unwound and wound in the up and down (vertical) or left and right (horizontal) directions according to the rotational direction of the motor rotation shaft 72 while being wound around the motor rotation shaft 72. The outside of the vinyl film 12 of (10) is shielded.

In addition, the holder 74 is installed at the end of the light shielding net 73 to apply a load to the light shielding net 73 to maintain the light shielding net 73 in a flat spread state, and at both ends of the holder 74 A bundling ring 76 for fixing the unfolded light shielding net 73 is further formed so that a rope, wire, etc. tied to the outside can be bound.

In addition, a plurality of the joldae 75 are installed spaced apart from each other in the longitudinal direction of the light blocking network 73 in the middle of the light blocking network 73 to maintain the light blocking network 73 in a flat spread state.

On the other hand, a plurality of connecting rings 78 are formed on one surface of the light blocking net 73 in the longitudinal and transverse directions, and an obstacle holding the light blocking net 73 when the light blocking net 73 is wound or unwound is formed on the motor rotation shaft 72. Since the group 77 protrudes and the locking protrusion 77 of the motor rotation shaft 72 is inserted into the connecting ring 78 of the light shielding net 73, the light shielding net 73 can be easily wound and unwound. can

10: main body 11: frame
12: vinyl film 13: bottom plate
14: roof 15: rain gutter
16: through hole 17: ventilation window
18: through hole
20: space unit 21: lifting device
30: wind power generation unit 31: first blade unit
32: second blade unit 33: wind power shaft
34: generator 35: wind shield
36: support 37: tail wing
38: shaft 39: coil unit
40: solar heat exchange unit 41: heat exchange pipe
42: heat exchange reflector 43: first blowing fan
50: heat storage unit 60: rainwater storage unit
70: light blocking part 71: rotation motor
72: motor rotation shaft 73: light shielding network
74: retainer 75: jolder
76: tie loop 77: stumbling block
78: link
100: control unit

Claims (7)

a body portion 10 having a frame 11 formed so that space rooms are stacked in a vertical multi-layer structure and a vinyl film 12 formed outside the frame 11;
a space part 20 formed vertically on one side of the main body part 10 and passing through the inside, and having an elevating device 21 selectively connected to each space room formed therein;
Doedoe installed on the uppermost surface of the body portion 10, the wind power generation unit 30 is rotated by external wind power and wind power discharged to the outside from within the body portion 10 to generate power;
A solar heat exchange unit 40 installed on one outer side of the main body unit 10 to transfer a heat source exchanged with solar heat to the heat storage unit 50;
A heat storage material is formed in the lower ground of the body part 10 to exchange heat with a heat source transmitted from the solar heat exchanger 40 and store heat, and the heat storage material is stored inside the body part 10. A heat storage unit 50 supplied for temperature control;
A rainwater storage unit 60 formed in the lower ground of the main body unit 10 to collect and store external rainwater and to supply the stored rainwater to crops grown in the space room of the main body unit 10;
It is configured to include; a light blocking unit 70 installed on the outside of the body unit 10 and driven up and down or left and right to adjust the light irradiated into the body unit 10,
The wind power generation unit 30 includes a first blade unit 31 in which a plurality of first blades 31a are vertically formed so as to be rotated by external wind power transported horizontally;
a second blade unit 32 in which a plurality of second wings 32a are inclined in a horizontal direction so as to be rotated by wind power discharged through a through-hole 16 formed through the uppermost surface of the main body unit 10;
It is formed in the center of the first blade part 31 and the second blade part 32 to connect the first blade part 31 and the second blade part 32, and at the same time the first blade part 31 and the 2 and the wind power rotation shaft 33 rotated by the rotational force of the blade unit 32;
A generator 34 connected to the wind power rotation shaft 33 and generated by the rotational force of the wind power rotation shaft 33;
A vinyl house for hydroponic spray cultivation that is laminated in a vertical multi-layer, characterized in that it comprises a.
According to claim 1,
A wind blocking film 35 is formed on the outer periphery of the first blade unit 31 so that external wind power flows only to one side of the first blade unit 31,
The wind blocking film 35 is formed to block only 1/4 of the outer periphery of the first blade part 31, and the wind blocking film 35 is a support 36 connected to the upper part of the first blade part 31. ) is connected to,
The support 36 is connected to the upper portion of the first blade unit 31 by a bearing device and can rotate horizontally, and the upper portion of the support 36 rotates the wind shield 35 in the direction in which external wind blows. A vinyl house for hydroponic spray cultivation that is stacked in vertical multi-layers, characterized in that the tail (37) is formed so as to.
According to claim 1,
A plurality of shafts 38 are formed on the outside of the first wing 31a of the first blade part 31 and the second wing 32a of the second blade part 32 so that the first wing 31a and the second wing 32a are formed. It is rotated according to the wing 32a, the magnet 38a is installed on the shaft 38, and the coil part 39 is formed on both sides of the magnet 38a to generate power by the rotational force of the shaft 38. A greenhouse for hydroponic spray cultivation that is characterized by being stacked in vertical multi-layers.
a body portion 10 having a frame 11 formed so that space rooms are stacked in a vertical multi-layer structure and a vinyl film 12 formed outside the frame 11;
a space part 20 formed vertically on one side of the main body part 10 and passing through the inside, and having an elevating device 21 selectively connected to each space room formed therein;
Doedoe installed on the uppermost surface of the body portion 10, the wind power generation unit 30 is rotated by external wind power and wind power discharged to the outside from within the body portion 10 to generate power;
A solar heat exchange unit 40 installed on one outer side of the main body unit 10 to transfer a heat source exchanged with solar heat to the heat storage unit 50;
A heat storage material is formed in the lower ground of the body part 10 to exchange heat with a heat source transmitted from the solar heat exchanger 40 and store heat, and the heat storage material is stored inside the body part 10. A heat storage unit 50 supplied for temperature control;
A rainwater storage unit 60 formed in the lower ground of the main body unit 10 to collect and store external rainwater and to supply the stored rainwater to crops grown in the space room of the main body unit 10;
It is configured to include; a light blocking unit 70 installed on the outside of the body unit 10 and driven up and down or left and right to adjust the light irradiated into the body unit 10,
The solar heat exchanger 40 is formed from one outer side of the main body 10 to the inside of the heat storage unit 50 through the space, and after the air filled therein exchanges heat with solar heat, the heat storage unit 50 heats up. a heat exchange pipe 41 supplying a heat source by exchanging heat with the ash;
a heat exchange reflector 42 formed behind the heat exchange pipe 41 provided on one outer side of the main body 10 and curved to collect solar heat toward the heat exchange pipe 41;
a first blowing fan 43 communicating with one side of the heat exchange pipe 41 to circulate air within the heat exchange pipe 41;
A vinyl house for hydroponic spray cultivation that is laminated in a vertical multi-layer, characterized in that comprising a.
a body portion 10 having a frame 11 formed so that space rooms are stacked in a vertical multi-layer structure and a vinyl film 12 formed outside the frame 11;
a space part 20 formed vertically on one side of the main body part 10 and passing through the inside, and having an elevating device 21 selectively connected to each space room formed therein;
Doedoe installed on the uppermost surface of the body portion 10, the wind power generation unit 30 is rotated by external wind power and wind power discharged to the outside from within the body portion 10 to generate power;
A solar heat exchange unit 40 installed on one outer side of the main body unit 10 to transfer a heat source exchanged with solar heat to the heat storage unit 50;
A heat storage material is formed in the lower ground of the body part 10 to exchange heat with a heat source transmitted from the solar heat exchanger 40 and store heat, and the heat storage material is stored inside the body part 10. A heat storage unit 50 supplied for temperature control;
A rainwater storage unit 60 formed in the lower ground of the main body unit 10 to collect and store external rainwater and to supply the stored rainwater to crops grown in the space room of the main body unit 10;
It is configured to include; a light blocking unit 70 installed on the outside of the body unit 10 and driven up and down or left and right to adjust the light irradiated into the body unit 10,
The light blocking part 70 includes a rotary motor 71 installed outside the body part 10;
a motor rotation shaft 72 connected to the rotation motor 71 and rotated by the rotation motor 71;
A light shielding network that shields the outside of the vinyl film 12 of the main body 10 while being wound around the motor rotational shaft 72 and being unwound and wound up and down or left and right according to the direction of rotation of the motor rotational shaft 72. (73) and;
a holder 74 installed at an end of the light-shielding net 73 to apply a load to the light-shielding net 73 while maintaining the light-shielding net 73 in a flatly spread state;
Jolders 75 installed in the middle of the light-shielding net 73 and spaced apart from each other in the longitudinal direction of the light-shielding net 73 to maintain the light-shielding net 73 in a flatly spread state;
A vinyl house for hydroponic spray cultivation that is laminated in a vertical multi-layer, characterized in that it comprises a.
According to any one of claims 1 to 5,
The vinyl film 12 is formed by wrapping vinyl around a vinyl frame several times, manufacturing several vinyl frames wrapped with vinyl, connecting the plurality of vinyl frames in a mutually assembling manner, and installing them on the outside of the frame 11. And, between the vinyl film 12 and the frame 11, a foam insulation for closing the gap is further formed.
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