KR20220084636A - Devices and systems that reduce the humidity inside the greenhouse without heating and cooling devices - Google Patents

Abstract

An intake unit for introducing air from outside the greenhouse into the inside of the greenhouse, located inside the greenhouse, at least one panel in which air outside the greenhouse is introduced into the internal space to cause moisture condensation on the external surface, into the inside of the at least one panel and an exhaust unit for discharging the introduced air outside the greenhouse back to the outside of the greenhouse. Accordingly, by reducing the humidity without lowering the temperature inside the greenhouse, it is possible to reduce the occurrence of dew condensation on the crops.

Description

DEVICES AND SYSTEMS THAT REDUCE THE HUMIDITY INSIDE THE GREENHOUSE WITHOUT HEATING AND COOLING DEVICES

The present invention relates to a humidity reduction device for controlling humidity in a greenhouse.

The domestic facility horticultural cultivation area is about 53,000ha, of which 67.2% are non-heated greenhouses. In winter, the relative humidity inside a non-heated greenhouse rises to 100%, and condensation occurs on crops at night and at dawn.

Currently, agricultural dehumidifiers have been developed, but they consume a lot of energy as a cooling type dehumidifier.

It is an object of the present invention to provide a device for reducing the humidity inside a greenhouse without a separate air-conditioning device.

A humidity reduction apparatus according to an embodiment of the present invention includes: an intake unit for introducing air from outside the greenhouse into the inside of the greenhouse; at least one panel located inside the greenhouse, through which air from the outside of the greenhouse is introduced into the internal space to cause moisture condensation on the external surface; and an exhaust unit for discharging the air outside the greenhouse introduced into the at least one panel to the outside of the greenhouse again.

In one embodiment, the intake unit, the intake fan for introducing the air outside the greenhouse into the interior of the greenhouse; an externally connected intake pipe connecting the outside of the greenhouse and the inside of the greenhouse so that the intake fan can easily introduce air outside the greenhouse; and an intake fan accommodating part in which the intake fan is disposed.

In an embodiment, the exhaust unit includes: an exhaust fan for discharging the air outside the greenhouse introduced into the at least one panel to the outside of the greenhouse; an externally connected exhaust pipe connecting the outside of the greenhouse and the inside of the greenhouse so that the exhaust fan can easily exhaust the air inside the at least one panel; and an exhaust fan accommodating part in which the exhaust fan is disposed.

In an embodiment, the intake unit and the at least one panel are each connected through at least one intake pipe, and the exhaust unit and the at least one panel are each connected through at least one exhaust pipe.

In one embodiment, at least one intake pipe connecting the inside of the at least one intake pipe and the at least one panel-panel connector; and at least one exhaust pipe connecting the at least one exhaust pipe and the inside of the at least one panel to a panel connector.

In one embodiment, the at least one intake pipe-panel connector each includes an intake valve, and the at least one exhaust pipe-panel connector each includes an exhaust valve.

In one embodiment, the intake valve regulates the amount of air outside the greenhouse introduced into the at least one panel, and the exhaust valve is the exhaust valve outside the greenhouse discharged from the at least one panel to the exhaust pipe. Adjust the amount of air.

In one embodiment, the at least one intake pipe may include first to third intake pipes; The at least one exhaust pipe includes first to third exhaust pipes.

In one embodiment, any one of the at least one panel, one side is connected to the first intake pipe, the other side is connected to the first exhaust pipe.

In an embodiment, the at least one panel may include: a first panel connected to the first intake pipe and the first exhaust pipe; a second panel connected to the second intake pipe and the second exhaust pipe; and a third panel connected to the third intake pipe and the third exhaust pipe.

In an embodiment, the at least one intake pipe-panel connection pipe includes: first to third intake pipe connecting the first intake pipe and the first panel-panel connection pipe; fourth to sixth intake pipe connecting the second intake pipe and the second panel-panel connecting pipe; and seventh to ninth intake pipes connecting the third intake pipe and the third panel to the panel connecting pipe.

In an embodiment, the at least one exhaust pipe-panel connector includes: first to third exhaust pipe connecting the first exhaust pipe and the first panel to the panel connector; fourth to sixth exhaust pipes connecting the second exhaust pipe and the second panel-panel connector; and seventh to ninth exhaust pipes connecting the third exhaust pipe and the third panel-panel connector.

In one embodiment, the first panel may include: first to third panels 1_1 to 1_3 respectively connected to the first to third intake pipe-panel connector and the first to third exhaust pipe-panel connector; 2_1 to 2_3 panels respectively connected to the fourth to sixth intake pipe-panel connector and the fourth to sixth exhaust pipe-panel connector; and 3_1 to 3_3 panels respectively connected to the seventh to ninth intake pipe-panel connector and the seventh to ninth exhaust pipe-panel connector.

In one embodiment, in the inside of the at least one panel, the intake pipe-panel connector and the exhaust pipe- further comprising an internal connector for connecting the panel connector.

In one embodiment, the control unit further includes a control unit for controlling the operation of the intake fan and the exhaust fan.

In an embodiment, the intake fan and the exhaust fan have a maximum wind pressure of 400pa, and there are a plurality of each.

A humidity reduction apparatus according to another embodiment of the present invention includes: an intake unit for introducing air from outside the greenhouse into the inside of the greenhouse; first to third panels located inside the greenhouse, the air outside the greenhouse is introduced into the internal space to cause moisture condensation on the external surface; and an exhaust unit for discharging the air outside the greenhouse introduced into the at least one panel back to the outside of the greenhouse, wherein the intake unit and the first to third panels are connected through first to third intake pipes, respectively and the exhaust unit and the first to third panels are connected through first to third exhaust pipes, respectively.

In one embodiment, the first to third intake pipes are connected to the first to third panels through at least one intake pipe-panel connection pipe, and the first to third exhaust pipes are at least one exhaust pipe- It is connected to the first to third panels through a panel connector.

A humidity reduction system according to an embodiment of the present invention includes: an intake unit for introducing air from outside the greenhouse into the inside of the greenhouse; at least one panel located inside the greenhouse, through which air from the outside of the greenhouse is introduced into the internal space to cause moisture condensation on the external surface; an exhaust unit for discharging the air outside the greenhouse introduced into the at least one panel back to the outside of the greenhouse; a control unit for controlling the inlet and outlet operations of the intake and exhaust air outside the greenhouse; a server capable of communicating with the control unit; and a user terminal capable of communicating with the control unit through the server.

The humidity reduction apparatus according to an embodiment of the present invention may reduce humidity without lowering the temperature inside the greenhouse. Accordingly, it is possible to reduce the occurrence of condensation on crops.

1 is a view showing a side view of an apparatus for reducing humidity according to an embodiment of the present invention.
2A is a view showing a rear view of a humidity reduction device according to an embodiment of the present invention.
2B is a view showing a front view of a humidity reducing device according to an embodiment of the present invention.
3A is a view showing a side view of an apparatus for reducing humidity according to another embodiment of the present invention.
3B is a view showing a rear view of a humidity reduction device according to another embodiment of the present invention.
4A is a view showing a side view in which each panel of the humidity reduction device according to another embodiment of the present invention is separated.
4B is a view showing a plan view in which each panel of the humidity reduction device according to another embodiment of the present invention is separated.
Figure 5a is a view showing a side view of the humidity reduction device according to another embodiment of the present invention is added with an internal connection pipe.
Figure 5b is a view showing a rear view of the humidity reduction device according to another embodiment of the present invention is added with an internal connection pipe.
6 is a block diagram to which a control unit of a humidity reduction device according to an embodiment of the present invention is added.
7 is a graph showing changes in temperature, relative humidity, and absolute humidity when the humidity reduction device according to an embodiment of the present invention is used.
8 is a diagram illustrating an example in which the shipment amount measurement system according to an embodiment of the present invention is applied to a smart farm.

The present invention relates to a humidity reduction device for preventing dew condensation and moisture damage of crops by reducing absolute humidity without a separate heating device in an unheated greenhouse where it is difficult to control relative humidity because there is no heating device.

More specifically, the present invention can induce heat exchange between the device inside the greenhouse and the excessively humid air in the greenhouse by introducing cold air from the outside in the winter into the device inside the greenhouse. Accordingly, it is possible to reduce the absolute humidity in the greenhouse by inducing moisture condensation in the device inside the greenhouse.

That is, since the humidity reduction device of the present invention uses cold outside air in winter, a separate cooler or a heating device that consumes a lot of energy is unnecessary. This can be expected to prevent condensation on crops due to excessive moisture in an unheated greenhouse, thereby reducing the labor required for damp control, reducing the cost of quarantine and improving crop productivity.

Hereinafter, the present disclosure will be described with reference to the accompanying drawings. The present disclosure can make various changes and can have various embodiments, and specific embodiments are illustrated in the drawings and the related detailed description is described. However, this is not intended to limit the present disclosure to specific embodiments, and should be understood to include all modifications and/or equivalents or substitutes included in the spirit and scope of the present disclosure. In connection with the description of the drawings, like reference numerals have been used for like elements.

In the present disclosure, expressions such as “first,” “second,” “first,” or “second,” may modify various components of the disclosure, but do not limit the components. For example, the above expressions do not limit the order and/or importance of corresponding components. The above expressions may be used to distinguish one component from another. For example, both the first user device and the second user device are user devices, and represent different user devices. For example, without departing from the scope of the present disclosure, a first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

1 is a view showing a side view of an apparatus for reducing humidity according to an embodiment of the present invention.

Referring to FIG. 1 , the humidity reduction apparatus 100 according to an embodiment of the present invention includes an intake part 110 , an intake pipe 120 , a panel 130 , an exhaust pipe 140 , and an exhaust part 150 . do.

The intake unit 110 may introduce air from the outside of the greenhouse 10 into the inside of the greenhouse 20 . For example, the intake unit 110 may include an intake fan 111 for introducing air from the outside of the greenhouse 10 into the interior 20 of the greenhouse, and the intake fan 111 to easily introduce air from outside the greenhouse 10 . It may include an externally connected intake pipe 113 connecting the outside of the greenhouse 10 and the inside of the greenhouse 20 , and an intake fan accommodating part 115 in which the intake fan 111 is disposed.

Here, the intake fan 111 operates through power, and the wind pressure pa may operate up to 300 pa. In addition, the intake fan 111 is disposed inside the intake fan accommodating part 115 to introduce air from the outside of the greenhouse 10 through the internal space of the externally connected intake pipe 113 through the externally connected intake pipe 113 . can At this time, the intake fan 111 reaches the intake fan accommodating part 115 so that the air from the outside of the greenhouse 10 can move from the intake fan accommodating part 115 to the inside of the panel 130. of air may be moved to the panel 130 through the intake pipe 120 .

In one embodiment, in the humidity reduction apparatus 100 of the present invention, when the intake air amount of the intake fan 111 is insufficient, a plurality of intake fans 111 may be disposed. In this case, the plurality of intake fans 111 may be disposed in series or in parallel inside the intake fan accommodating part 115 to improve the wind pressure pa of the intake part 110 .

The externally connected intake pipe 113 may have one end located outside the greenhouse 10 and the other end connected to the intake fan receiving unit 115 located inside the greenhouse 20 . Accordingly, the air outside the greenhouse 10 can be easily moved toward the panel 130 inside the greenhouse by the intake fan 111 located inside the intake fan accommodating part 115 .

The intake fan accommodating part 115 may have one side connected to the externally connected intake pipe 113 and the other side connected to the intake pipe 120 . Also, an intake fan 111 may be disposed therein. Accordingly, the intake fan accommodating part 115 may move the air outside the greenhouse 10 introduced through the externally connected intake pipe 113 to the intake pipe 120 by operating the intake fan 111 .

In one embodiment, the intake fan accommodating part 115 may have a space therein for arranging a plurality of intake fans 111 in series or in parallel.

The intake pipe 120 may connect the intake unit 110 and the panel 130 . For example, the intake pipe 120 connects the intake fan accommodating part 115 of the intake part 110 and the inside of the panel 130, and the intake part 110 introduces the outside of the greenhouse through the intake fan 111 ( 10) may move the air toward the inside of the panel 130 .

The panel 130 is located inside the greenhouse 20 , and air from the outside of the greenhouse 10 flows into the inner space of the panel 130 , so that moisture condensation can be made on the outer surface of the panel 130 . For example, one side of the panel 130 is connected to the intake pipe 120 so that air from the outside of the greenhouse 10 introduced through the intake unit 110 may be introduced into the inner space of the panel 130 . Accordingly, cold air from the outside of the greenhouse 10 in winter flows into the inner space of the panel 130 so that water vapor inside the greenhouse 20 may be condensed on the surface of the panel 130 .

In addition, the other side of the panel 130 is connected to the exhaust pipe 140 , so that air from the outside of the greenhouse 10 introduced through the intake part 110 and the intake pipe 120 may move to the exhaust pipe 140 .

In one embodiment, the material of the panel 130 is a material with high thermal conductivity, and may be any one of aluminum, copper, stainless steel, and graphene.

In the exhaust pipe 140 , the air outside the greenhouse 10 , which has been introduced into the internal space of the panel 130 located inside the greenhouse 20 through the intake unit 110 and the intake pipe 120 , is returned to the outside of the greenhouse 10 . The panel 130 and the exhaust unit 150 may be connected to be discharged. For example, the exhaust pipe 140 may connect the inside of the panel 130 and the exhaust part 150 to move air inside the panel 130 to the exhaust part 150 .

The exhaust unit 150 may discharge the air outside the greenhouse 10 introduced into the panel 130 back to the outside of the greenhouse 10 . For example, the exhaust unit 150 is an exhaust fan 151 for discharging air from the outside of the greenhouse 10 introduced into the inside of the panel 130 to the outside of the greenhouse, and the exhaust fan 151 is installed inside the panel 130 . It may include an externally connected exhaust pipe 153 connecting the outside of the greenhouse 10 and the inside of the greenhouse 20 to allow air to be easily discharged, and an exhaust fan accommodating part 155 in which the exhaust fan 151 is disposed.

Here, the exhaust fan 151 operates through power, and the wind pressure pa may operate up to 300 pa. In addition, the exhaust fan 151 is disposed inside the exhaust fan accommodating part 155 , and exhausts the air inside the greenhouse 20 through the internal space of the externally connected exhaust pipe 153 through the externally connected intake pipe 153 . can do it At this time, the exhaust fan 151 is installed in the exhaust fan accommodating part 155 so that air inside the panel 130 located inside the greenhouse 20 can move from the exhaust fan accommodating part 155 to the outside of the greenhouse 10 . The air inside the panel 130 that has reached may be discharged to the outside of the greenhouse 10 through the external connection exhaust pipe 153 .

In one embodiment, in the humidity reduction apparatus 100 of the present invention, when the exhaust amount of the exhaust fan 151 is insufficient, a plurality of exhaust fans 151 may be disposed. In this case, the plurality of exhaust fans 151 may be disposed in series or in parallel inside the exhaust fan accommodating part 155 to improve the wind pressure pa of the exhaust part 150 .

As described above, the humidity reduction device 100 of the present invention introduces cold air from the outside of the greenhouse 10 into the panel 130 made of a material having a high heat transfer rate in a non-heating greenhouse, so that the high humidity inside the greenhouse 20 ) can condense air. Accordingly, the humidity inside the greenhouse 20 can be reduced without a change in the temperature of the inside of the greenhouse 20 .

2A is a view showing a rear view of a humidity reduction device according to an embodiment of the present invention.

2B is a view showing a front view of a humidity reducing device according to an embodiment of the present invention.

2A and 2B , the intake pipe 120 , the panel 130 , and the exhaust pipe 140 of the humidity reduction apparatus 100 according to an embodiment of the present invention may be formed in plurality. However, this is an example, and the intake pipe 120 , the panel 130 , and the exhaust pipe 140 of the humidity reduction device 100 may be formed of at least one or more.

Hereinafter, a case in which the intake pipe 120 , the panel 130 , and the exhaust pipe 140 of the humidity reducing apparatus 100 according to an embodiment of the present invention are each composed of three will be described as an example.

First, the plurality of intake pipes 120_1, 120_2, and 120_3 include a first intake pipe 120_1, a second intake pipe 120_2, and a third intake pipe 120_3, and a plurality of panels 130_1, 130_2, 130_3 ) includes a first panel 130_1 , a second panel 130_2 , and a third panel 130_3 . In addition, the plurality of exhaust pipes 140_1 , 140_2 , and 140_3 include a first exhaust pipe 140_1 , a second exhaust pipe 140_2 , and a third exhaust pipe 140_3 .

The first intake pipe 120_1 , the second intake pipe 120_2 , and the third intake pipe 120_3 have one end connected to the intake fan receiving part 115 of the intake part 110 , and the first intake pipe 120_1 . The other end of the first panel 130_1 , the other end of the second intake pipe 120_2 may be connected to the second panel 130_2 , and the other end of the third intake pipe 120_3 may be connected to the third panel 130_3 . Accordingly, the air outside the greenhouse 10 introduced through the first intake pipe 120_1 flows into the first panel 130_1, and the air outside the greenhouse 10 introduced through the second intake pipe 120_2. is introduced into the second panel 130_2 , and air outside the greenhouse 10 introduced through the third intake pipe 120_3 may be introduced into the third panel 130_3 .

The air outside the greenhouse 10 introduced into the first panel 130_1 , the second panel 130_2 , and the third panel 130_3 is the first exhaust pipe 140_1 by the operation of the intake fan 111 and the exhaust fan 151 . ), the second exhaust pipe 140_2 and the third exhaust pipe 140_3 may be moved. In this case, the first exhaust pipe 140_1 may be connected to the first panel 130_1 , the second exhaust pipe 140_2 may be connected to the second panel 130_2 , and the third exhaust pipe 140_3 may be connected to the third panel 130_3 . Accordingly, the air outside the greenhouse 10 introduced into the first panel 130_1 is discharged through the first exhaust pipe 140_1, and the air outside the greenhouse 10 introduced into the second panel 130_2 is the second The air outside the greenhouse 10 discharged through the exhaust pipe 140_2 and introduced into the third panel 130_3 may be discharged through the third exhaust pipe 140_3 .

That is, one end of each of the first to third exhaust pipes 140_1 , 140_2 and 140_3 may be connected to the first to third panels 130_1 , 130_2 , and 130_3 . In addition, the other ends of the first to third exhaust pipes 140_1 , 140_2 , and 140_3 may all be connected to the exhaust fan accommodating part 155 of the exhaust part 150 . Accordingly, the air outside the greenhouse 10 introduced into the first to third panels 130_1, 130_2, 130_3 is moved to the exhaust unit 150 through the first to third exhaust pipes 140_1, 140_2, and 140_3. can

Here, the air outside the greenhouse 10 moved to the exhaust unit 150 may be discharged to the outside of the greenhouse 10 through the external connection exhaust pipe 153 . Therefore, the humidity reduction device 100 of the present invention introduces air from the outside of the greenhouse 10 that is lower than the temperature of the inside of the greenhouse 20 into the inside of the panel 130 made of a material having high thermal conductivity, and the surface of the panel 130 . may lead to moisture condensation. Accordingly, it is possible to reduce the absolute humidity inside the greenhouse 20 .

Also, referring to FIGS. 2A and 2B , the humidity reduction apparatus 100 according to an embodiment of the present invention may further include a frame 190 having a predetermined height so that the panel 130 can be disposed to be spaced apart from the ground. can

In addition, the frame 190 may be provided with two layers, so that the panel 130 is positioned on the second layer. Accordingly, the panel 130 may be disposed at a predetermined interval inside the frame 190 .

3A is a view showing a side view of an apparatus for reducing humidity according to another embodiment of the present invention.

3B is a view showing a rear view of a humidity reduction device according to another embodiment of the present invention.

The humidity reduction apparatus 200 of FIGS. 3A and 3B is similar to the humidity reduction apparatus 100 of FIGS. 1, 2A and 2B . Accordingly, the same or similar components are denoted by the same or similar reference numerals, and overlapping descriptions will be omitted for the sake of brevity.

3A and 3B , in the humidity reduction apparatus 200 according to another embodiment of the present invention, at least one intake pipe connecting at least one intake pipe 120 and at least one panel 130 is a panel-panel a connector pipe 125 and at least one exhaust pipe-panel connector 145 connecting the at least one exhaust pipe 140 and the at least one panel 130 .

Here, the at least one intake pipe-panel connecting pipe 125 each includes an intake valve 123 , and the at least one exhaust pipe-panel connecting pipe 145 includes an exhaust valve 143 , respectively.

Accordingly, in the moisture reduction apparatus 100 according to an embodiment of the present invention, at least one intake pipe-panel connection pipe 125 controls each intake valve 123 provided to flow into the inside of the panel 130 . The amount of air outside the greenhouse 10 can be adjusted. In addition, the amount of air outside the greenhouse 10 discharged from the inside of the panel 130 may be controlled by adjusting each exhaust valve 143 provided in the exhaust pipe-panel connection pipe 145 .

For example, in the case of the first panel 130_1 connected to the first intake pipe 120_1 , the first to third intake pipes connected to the first intake pipe 120_1 - one side of the panel connection pipes 125_1a, 125_1b, 125_1c is connected, the inside of the first panel 130_1 and the other side of the first to third intake pipe-panel connection pipes 125_1a, 125_1b, 125_1c are connected to the outside of the greenhouse introduced into the first intake pipe 120_1 ( 10) air may be introduced into the first panel 130_1 through the first to third intake pipe-panel connection pipes 125_1a, 125_1b, and 125_1c.

In addition, the first to third intake pipe-panel connection pipes 125_1a, 125_1b, and 125_1c include intake valves 123_1a, 123_1b, and 123_1c, respectively. Accordingly, by adjusting the intake valves 123_1a, 123_1b, and 123_1c, the amount of air flowing into the first panel 130_1 outside the greenhouse 10 may be adjusted.

In the case of the first exhaust pipe 140_1 connected to the first panel 130_1 , one side of the first to third exhaust pipes-panel connection pipes 145_1a, 145_1b, 145_1c is connected to the first exhaust pipe 140_1, and the first panel The inside of 130_1 and the first to third exhaust pipes-panel connection pipes 145_1a, 145_1b, and 145_1c are connected to the other side of the first panel 130_1, so that the air outside the greenhouse 10 inside the first panel 130_1 is removed from the first to third exhaust pipes. The third exhaust pipe may move to the first exhaust pipe 140_1 through the panel connecting pipes 145_1a, 145_1b, and 145_1c.

In addition, the first to third exhaust pipe-panel connecting pipes 145_1a, 145_1b, and 145_1c include evacuation valves 143_1a, 143_1b, and 143_1c, respectively. Accordingly, the amount of air outside the greenhouse 10 discharged from the first panel 130_1 may be adjusted by adjusting the exhaust valves 143_1a, 143_1b, and 143_1c.

The humidity reduction device 200 according to another embodiment of the present invention includes the first to third intake pipes connecting the first intake pipe 120_1 and the first panel 130_1 described above-panel connection pipes 125_1a, 125_1b, 125_1c) and the first to third exhaust pipes connecting the first exhaust pipe 140_1 and the first panel 130_1 to the panel connecting pipes 145_1a, 145_1b, 145_1c, the second intake pipe 120_2 and the second The fourth to sixth intake pipes connecting the panel 130_2-panel connecting pipes 125_2a, 125_2b, 125_2c, and fourth to sixth exhaust pipes connecting the second exhaust pipe 140_2 and the second panel 130_2 to the panel-panel Connection tubes 145_2a, 145_2b, and 145_2c may be included.

In addition, the humidity reduction device 200 includes seventh to ninth intake pipes connecting the third intake pipe 120_3 and the third panel 130_3 to the panel connection pipes 125_3a, 125_3b, 125_3c, and the third exhaust pipe 140_3 ) and seventh to ninth exhaust pipes connecting the third panel 130_3 to the panel connecting pipes 145_3a, 145_3b, and 145_3c.

Here, the plurality of intake pipe-panel connection pipes 125_2a, 125_2b, 125_2c, 125_3a, 125_3b, and 125_3c are the first to third intake pipe-panel connection pipes 125_1a, 125_1b, and 125_1c, respectively, in the same manner as the intake valve 123_2a. , 123_2b, 123_2c, 123_3a, 123_3b, 123_3c). In addition, the plurality of exhaust pipe-panel connecting pipes 145_2a, 145_2b, 145_2c, 145_3a, 145_3b, and 145_3c are the first to third exhaust pipe-panel connecting pipes 145_1a, 145_1b, and 145_1c, respectively, in the same manner as the exhaust valves 143_2a and 143_2b. , 143_2c, 143_3a, 143_3b, 143_3c).

However, these are exemplary, and the intake pipe 120 , the panel 130 , the exhaust pipe 140 , the intake pipe-panel connection pipe 125 , the exhaust pipe-panel connection pipe 145 , and the intake valve 123 of the present invention. And it will be understood that the number of exhaust valves 143 is not limited.

4A is a view showing a side view in which each panel of the humidity reduction device according to another embodiment of the present invention is separated.

4B is a view showing a plan view in which each panel of the humidity reduction device according to another embodiment of the present invention is separated.

In the humidity reduction device 200 of FIGS. 4A and 4B , the panel 130 of the humidity reduction device 200 of FIGS. 3A and 3B is each intake pipe-panel connector 125 and exhaust pipe-panel connector 145 . ) is an embodiment showing a case in which the panel 130 is separated so that one panel 130 can be connected to each other. Accordingly, the same or similar components are denoted by the same or similar reference numerals, and overlapping descriptions will be omitted for the sake of brevity.

For example, the first panel 130_1 includes a first intake pipe-panel connection pipe 125_1a and a first exhaust pipe-panel connection pipe 145_1a connecting a first_1 panel 130_1a and a second intake pipe-panel connection. The first_2 panel 130_1b connecting the pipe 125_1b and the second exhaust pipe-panel connector 145_1b and the third intake pipe-panel connector 125_1c and the third exhaust pipe-panel connector 145_1c are connected A first_3 panel 130_1c may be included.

Accordingly, since the area of the outer surface of the panel 130 in contact with the air inside the greenhouse 20 can be increased, the amount of air in the greenhouse 20 condensing on the outer surface of the panel 130 is increased. can

The second panel 130_2 and the third panel 130_1 also, in the same manner as the first panel 130_1 , each of the intake pipe-panel connector 125 and the exhaust pipe-panel connector 145 are connected to each panel. Separation may be possible into (130_2a, 130_2b, 130_2c, 130_3a, 130_3b, 130_3c).

For example, the second panel 130_2 includes the fourth intake pipe-panel connection pipe 125_2a and the fourth exhaust pipe-panel connection pipe 145_2a, the second_1 panel 130_2a connecting the panel connection pipe 130_2a, and the fifth intake pipe-panel connection pipe. The second_2 panel 130_2b connecting the pipe 125_2b and the fifth exhaust pipe-panel connector 145_2b and the sixth intake pipe-panel connector 125_2c and the sixth exhaust pipe-panel connector 145_2c are connected A 2_3 panel 130_2c may be included.

In addition, the third panel 130_3 includes a third panel 130_3a connecting the seventh intake pipe-panel connector 125_3a and the seventh exhaust pipe-panel connector 145_3a, and an eighth intake pipe-panel connector ( 125_3b) and a third_2 panel 130_3b connecting the eighth exhaust pipe-panel connector 145_3b, and a third_3 third connecting the ninth intake pipe-panel connector 125_3c and the ninth exhaust pipe-panel connector 145_3c A panel 130_3c may be included.

That is, each of the first panel 130_1 , the second panel 130_2 , and the third panel 130_3 is divided into three panels, so that a total of nine panels may exist. Accordingly, a contact area between the air inside the greenhouse 20 and the panel 130 may increase. Accordingly, the amount of moisture condensed on the panel 130 is increased, and thus, efficient moisture condensation can be achieved.

In addition, the plurality of intake pipe-panel connection pipes 125_1a, 125_1b, 125_1c, 125_2a, 125_2b, 125_2c, 125_3a, 125_3b, and 125_3c are respectively the intake valves 123_1a, 123_1b, 123_1c, _3b, 2a, 123_2a, 123_2a, 123_2a, 123_3c. 123_3c) may be included. In addition, the plurality of exhaust pipe-panel connecting pipes 145_1a, 145_1b, 145_1c, 145_2a, 145_2b, 145_2c, 145_3a, 145_3b, 145_3c are respectively exhaust valves 143_1a, 143_1b, 143_1c, 143_3a, 143_2c, _143_2a, 143_2c, _143_2a, 143_2c, respectively. ) may be included.

Accordingly, it is possible to adjust the amount of air outside the greenhouse 10 that is introduced to and discharged from each panel through each valve.

Figure 5a is a view showing a side view of the humidity reduction device according to another embodiment of the present invention is added with an internal connection pipe.

Figure 5b is a view showing a rear view of the humidity reduction device according to another embodiment of the present invention is added with an internal connection pipe.

Referring to FIGS. 3A, 3B, 5A and 5B , in the humidity reduction device 200 according to another embodiment of the present invention, the intake pipe-panel connector 125 and the exhaust pipe-panel in the interior of the panel 130 . It may further include an internal connector 135 to which the connector 145 is connected.

The internal connection pipe 135 may be configured to connect the plurality of intake pipe-panel coupling pipes 125_1a, 125_1b, and 125_1c and the plurality of exhaust pipe-panel coupling pipes 145_1a, 145_1b, and 145_1c to the inside of the panel 130 . . In this case, air can be effectively introduced and discharged through the pipe-type internal connection pipe 135 .

For example, the internal connection pipe 135 existing inside the first panel 130_1 is a first internal connection connecting the first intake pipe-panel coupling pipe 125_1a and the first exhaust pipe-panel coupling pipe 145_1a. The pipe 135_1a, the second intake pipe-panel connector 125_1b and the second exhaust pipe-panel connector 145_1b, a second internal connector 135_1b and a third intake pipe-panel connector 125_1c are connected to each other. and a third internal connection pipe 135_1c connecting the third exhaust pipe-panel connection pipe 145_1c.

Accordingly, the internal connection tubes 135_2a, 135_2b, 135_2c, 135_3a, 135_3b, and 135_3c may be provided in the second panel 130_2 and the third panel 130_3 as well.

6 is a block diagram to which a control unit of a humidity reduction device according to an embodiment of the present invention is added.

1, 2A, 2B and 6 , the humidity reduction apparatus 100 according to an embodiment of the present invention includes an intake unit 110 , a panel 130 , an exhaust unit 150 , and a control unit 170 . ) is included.

The controller 170 may control the air intake and exhaust operations of the intake unit 110 and the exhaust unit 150 outside the greenhouse 10 .

In more detail, the controller 170 may control the operation of the intake fan 111 and the exhaust fan 151 of the intake unit 110 and the exhaust unit 150 .

The control unit 170 may control the wind pressure pa of the intake fan 111 and the exhaust fan 151, and the wind pressure pa of the intake fan 111 and the exhaust fan 151 may be controlled from 0 to 400 pa. have. In addition, the control unit 170 may adjust the rotation directions of the intake fan 111 and the exhaust fan 151 , the exhaust unit 150 introduces air from the outside of the greenhouse 10 , and the intake unit 110 causes the panel ( 130) It can be adjusted so that the air inside can be discharged. However, it will be understood that this is an example, and the technical spirit of the present invention is not limited thereto.

7 is a graph showing changes in temperature, relative humidity, and absolute humidity when the humidity reduction device according to an embodiment of the present invention is used.

Referring to FIG. 7 , when the humidity reduction apparatus according to an embodiment of the present invention is used, changes in temperature, humidity, and absolute humidity of the greenhouse can be checked over time.

In a greenhouse with an initial temperature of 14.1℃, relative humidity of 93.0%, and absolute humidity of 11.29g/m ³ , the temperature after operating the humidity reduction device of the present invention for 2 hours: 14.0℃, relative humidity 86.7%, absolute humidity 10.46g You can see the change to /m ³ .

This can be confirmed that the absolute humidity of the greenhouse decreased by 0.83 g/m ³ and the temperature decreased by 0.1°C. Accordingly, when moisture condensation is induced by using cold water (eg, a radiator), it is possible to prevent a lot of moisture condensed, but the temperature in the greenhouse drops, which may cause damage to crops due to cold.

In addition, since the air panel type moisture condensation is made, moisture condensation can be induced and absolute humidity can be reduced in an unheated greenhouse without a heating device without lowering the temperature inside the greenhouse.

Therefore, it is a system that induces moisture condensation and reduces absolute humidity in the air by injecting cold air from the outside in the winter season into the greenhouse. effect can be expected.

8 is a view showing an example in which the humidity reduction system according to an embodiment of the present application is applied to a smart farm.

Referring to FIG. 8 , the humidity reduction system can also be applied to the smart farm 1000 . The smart farm 1000 may include a humidity reduction system, a server 300 , and a user terminal 400 . The humidity reduction system includes an intake unit 110 , at least one panel 130 , an exhaust unit 150 , and a control unit 170 , and includes an intake unit 110 , at least one panel 130 , and an exhaust unit 150 . ) and the control unit 170 are the same as the intake unit 110, at least one panel 130, the exhaust unit 150, and the control unit 170 disclosed in Figs. will be omitted. In one embodiment of the present invention, the moisture reduction system may be disposed inside or outside a crop cultivation facility such as a greenhouse, a plant factory, or a plastic house. The control unit 170 of the humidity reduction system may communicate with the user terminal 400 through the server 300 .

For example, the user terminal 400 is a smartphone (Smartphone), a smart pad (Smart Pad), a tablet PC, a wearable device, PCS (Personal Communication System), GSM (Global System for Mobile communication), PDC (Personal Digital Cellular) , PHS (Personal Handyphone System), PDA (Personal Digital Assistant), IMT (International Mobile Telecommunication)-2000, CDMA (Code Division Multiple Access)-2000, W-CDMA (W-Code Division Multiple Access), Wibro (WirelessBroadband Internet) It may be any kind of wireless communication device such as a terminal, a desktop computer, and a stationary terminal such as a smart TV.

The server 300 connects the user terminal 400 and the control unit 170 of the humidity reduction system to enable communication with each other.

As described above, the present invention has been described with reference to the illustrated drawings, but the present invention is not limited by the embodiments and drawings disclosed in this specification, and various methods can be obtained by those skilled in the art within the scope of the technical spirit of the present invention. It is obvious that variations can be made. In addition, although the effects according to the configuration of the present invention have not been explicitly described and described while describing the embodiments of the present invention, it is natural that the effects predictable by the configuration should also be recognized.

100, 200: humidity reduction device
110: intake
120: intake pipe
130: panel
140: exhaust pipe
150: exhaust
170: control unit

Claims (19)

an intake unit for introducing air from outside the greenhouse into the inside of the greenhouse;
at least one panel located inside the greenhouse, through which air from the outside of the greenhouse is introduced into the internal space to cause moisture condensation on the external surface;
and an exhaust unit for discharging the air outside the greenhouse introduced into the at least one panel to the outside of the greenhouse again. According to claim 1,
The intake unit,
an intake fan for introducing air outside the greenhouse into the greenhouse;
an externally connected intake pipe connecting the outside of the greenhouse and the inside of the greenhouse so that the intake fan can easily introduce air outside the greenhouse; and
and an intake fan accommodating part in which the intake fan is disposed. According to claim 1,
The exhaust unit,
an exhaust fan for discharging the air outside the greenhouse introduced into the at least one panel to the outside of the greenhouse;
an externally connected exhaust pipe connecting the outside of the greenhouse and the inside of the greenhouse so that the exhaust fan can easily exhaust the air inside the at least one panel; and
and an exhaust fan accommodating part in which the exhaust fan is disposed. According to claim 1,
The intake unit and the at least one panel are respectively connected through at least one intake pipe,
The exhaust unit and the at least one panel are respectively connected through at least one exhaust pipe. 5. The method of claim 4,
at least one intake pipe-panel connector connecting the at least one intake pipe and the inside of the at least one panel; and
and at least one exhaust pipe connecting the at least one exhaust pipe and the inside of the at least one panel to a panel connector. 6. The method of claim 5,
the at least one intake pipe-panel connecting pipe each includes an intake valve,
wherein the at least one exhaust pipe-panel connector each includes an exhaust valve. 7. The method of claim 6,
The intake valve controls the amount of air outside the greenhouse flowing into the interior of the at least one panel,
The exhaust valve controls an amount of air outside the greenhouse discharged from the at least one panel to the exhaust pipe. 6. The method of claim 5,
The at least one intake pipe may include first to third intake pipes;
The at least one exhaust pipe includes first to third exhaust pipes. 9. The method of claim 8,
Any one of the at least one panel, one side is connected to the first intake pipe, the other side is connected to the first exhaust pipe, humidity reduction device. 9. The method of claim 8,
the at least one panel,
a first panel connected to the first intake pipe and the first exhaust pipe;
a second panel connected to the second intake pipe and the second exhaust pipe; and
and a third panel connected to the third intake pipe and the third exhaust pipe. 11. The method of claim 10,
The at least one intake pipe-panel connector,
first to third intake pipe connecting the first intake pipe and the first panel-panel connecting pipe;
fourth to sixth intake pipe connecting the second intake pipe and the second panel-panel connecting pipe; and
7th to ninth intake pipe connecting the third intake pipe and the third panel-panel connecting pipe, the humidity reduction device comprising a. 12. The method of claim 11,
The at least one exhaust pipe-panel connector,
first to third exhaust pipes connecting the first exhaust pipe and the first panel-panel connector;
fourth to sixth exhaust pipes connecting the second exhaust pipe and the second panel-panel connector; and
The third exhaust pipe and seventh to ninth exhaust pipes connecting the third panel-panel connector, comprising: a humidity reduction device. 13. The method of claim 12,
The first panel,
1_1 to 1_3 panels respectively connected to the first to third intake pipe-panel connector and the first to third exhaust pipe-panel connector;
2_1 to 2_3 panels respectively connected to the fourth to sixth intake pipe-panel connector and the fourth to sixth exhaust pipe-panel connector; and
The seventh to ninth intake pipe-panel connector and the seventh to ninth exhaust pipe-panel connector and 3_1 to 3_3 panels respectively connected to the panel connector, the humidity reduction device comprising a. 6. The method of claim 5,
In the interior of the at least one panel, the intake pipe-panel connector and the exhaust pipe-an internal connector for connecting the panel connector, the humidity reduction device further comprising. 3. The method of claim 2,
Humidity reduction device further comprising a control unit for controlling the operation of the intake fan and the exhaust fan. 3. The method of claim 2,
A maximum wind pressure of the intake fan and the exhaust fan is 300pa, and a plurality of each of the intake fan and the exhaust fan are present. an intake unit for introducing air from outside the greenhouse into the inside of the greenhouse;
first to third panels located inside the greenhouse, the air outside the greenhouse is introduced into the internal space to cause moisture condensation on the external surface;
And an exhaust unit for discharging the air outside the greenhouse introduced into the inside of the at least one panel back to the outside of the greenhouse,
The intake portion and the first to third panels are respectively connected through first to third intake pipes,
The exhaust unit and the first to third panels are connected through first to third exhaust pipes, respectively. 18. The method of claim 17,
The first to third intake pipes are connected to the first to third panels through at least one intake pipe-panel connection pipe,
The first to third exhaust pipes are connected to the first to third panels through at least one exhaust pipe-panel connecting pipe. an intake unit for introducing air from outside the greenhouse into the inside of the greenhouse;
at least one panel located inside the greenhouse, through which air from the outside of the greenhouse is introduced into the internal space to cause moisture condensation on the external surface;
an exhaust unit for discharging the air outside the greenhouse introduced into the at least one panel back to the outside of the greenhouse;
a control unit for controlling the inlet and outlet operations of the intake and exhaust air outside the greenhouse;
a server capable of communicating with the control unit; and
A humidity reduction system comprising a user terminal capable of communicating with the control unit through the server.

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