KR101406410B1 - Greenhouse for inhibiting Dew Condensation and Method for controlling the same - Google Patents

Abstract

The condensation occurrence suppressing greenhouse according to an embodiment of the present invention includes a frame for forming a skeleton of a greenhouse; At least one covering portion covering an upper portion of the frame; At least one curtain portion disposed to be openable and closable at a lower portion of the covering portion; And a dehumidifying portion for removing moisture in the air in the space between the covering portion and the curtain portion, thereby effectively suppressing the occurrence of condensation in the greenhouse, ensuring a sufficient light transmittance in the greenhouse, and improving the growth of the crop.

Description

[0001] The present invention relates to a greenhouse for suppressing condensation,

A condensation occurrence suppression greenhouse and a control method of such a greenhouse are disclosed. More specifically, it is possible to efficiently remove condensation occurring in a space between a covering portion covering an upper portion of a greenhouse and a curtain portion below the covering portion, thereby suppressing condensation occurring inside the roof covering portion of the greenhouse A condensation-suppressing greenhouse capable of preventing condensation from dropping into a crop in a greenhouse and securing sufficient photosynthetic effective photon quantities, and a control method of such a greenhouse.

Greenhouses such as greenhouses have high airtightness and high light transmittance, which not only provides excellent thermal insulation, but also has a low cost of installation because of its light weight.

A greenhouse such as a general vinyl house is composed of a column frame vertically installed on the ground and a roof frame installed in the form of a semicircle on the top of the column frame. The top of each frame is covered with a covering material such as a vinyl film .

Curtains may be provided between the top cover of the greenhouse and the crop to maintain additional warmth of the crop.
For example, Korean Patent Laid-Open Publication No. 10-2009-0060466 (entitled "Horticultural Facilities Air Curtain Heating Curtain Device") published on June 15, 2009 discloses a greenhouse provided with a curtain for keeping warm, Japanese Unexamined Patent Application Publication No. 10-2004-0034027 (entitled "Greenhouse Curtain Opening / Closing Device") published April 28 discloses a greenhouse having a curtain.
The relative humidity change in the space between the curtain and the covering material of the greenhouse starts to increase as the temperature decreases in the afternoon, and after the curtain is closed, it reaches a certain value after 100% and reaches a constant value.

However, if condensation occurs at night in the space between the covering material and the curtain, the light transmittance to the inside of the greenhouse is suppressed, and the growth of crops is deteriorated. If the condensation water falls on the crop, the probability of disease occurrence is increased.

An object of an embodiment of the present invention is to provide a condensation occurrence suppression greenhouse effectively suppressing condensation that may occur in a space between a covering material and a curtain inside a greenhouse, and a control method thereof.

It is another object of the present invention to provide a condensation-suppressing greenhouse capable of ensuring a relatively simple and low-cost efficient light transmittance by additionally providing a means for generating condensation in a general greenhouse, and a control method thereof .

A condensation occurrence suppressing greenhouse according to an embodiment of the present invention includes a frame for forming a greenhouse skeleton, at least one covering portion for covering an upper portion of the frame, at least one curtain portion for opening and closing at a lower portion of the covering portion, And a dehumidifying portion for removing moisture in the air in the space between the covering portion and the curtain portion.

Wherein the dehumidifier is a low temperature dehumidifier, the low temperature dehumidifier includes a dehumidifier main body, an air inflow pipe and a dry air outlet pipe, the dehumidifier main body is disposed at a lower portion of the curtain portion, The dry air outlet of the air outlet pipe may be arranged to communicate with the space between the covering portion and the curtain portion.

The covering part includes a first covering material contacting the outside of the greenhouse and a second covering material disposed under the first covering material, and a dehumidifying sheet for absorbing moisture may be provided on the lower surface of the second covering material.

The curtain portion may include a first curtain and a second curtain disposed under the first curtain, and a moisture-absorbing dehumidifying sheet may be provided on the upper surface of the first curtain.

A control method of a greenhouse for suppressing the occurrence of condensation according to an embodiment of the present invention is a control method for a greenhouse having a space between a covering portion for covering the upper portion of the greenhouse and a curtain portion for opening and closing at a lower portion of the covering portion Wherein the curtain portion is closed, simultaneously with the closing of the curtain portion, simultaneously removing moisture in the air in a space between the covering portion and the curtain portion, opening the curtain portion, and opening the curtain portion, And stopping the removal of moisture in the air in the space between the curtain part and the curtain part.

The step of closing the curtain part and starting the removal of moisture in the air in the space between the covering part and the curtain part can be performed after sunset by sensing the sunset.

The step of opening the curtain part and stopping the removal of moisture in the air in the space between the covering part and the curtain part may be performed after sunrise by sensing the sunrise.

According to the embodiment of the present invention, when condensation occurs in a space between a covering material and a curtain inside a greenhouse, such a condensation problem may adversely affect the development of the crop by making the light transmittance worse, so that the occurrence of such condensation can be effectively suppressed have.

Further, according to the embodiment of the present invention, there is an effect that moisture removal at a low temperature can be realized relatively easily and economically.

Also, according to the embodiment of the present invention, there is an advantage that the light transmittance can be efficiently secured by suppressing the occurrence of condensation through installation of additional components without major structural change of the existing greenhouse.

FIG. 1 is a graph showing the humidity and the temperature according to time between a covering portion and a curtain portion in a greenhouse.
2 is a front structural view of a condensation occurrence suppression greenhouse according to an embodiment of the present invention.
3 is a front structural view of a condensation occurrence suppression greenhouse according to a modification of the present invention.
4 is a flowchart showing a control method of a greenhouse for suppressing the occurrence of condensation according to an embodiment of the present invention.

Hereinafter, configurations and applications according to embodiments of the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE INVENTION The following description is one of many aspects of the claimed invention and the following description forms part of a detailed description of the present invention.

In the following description, well-known functions or constructions are not described in detail for the sake of clarity and conciseness.

The dew condensation suppression greenhouse 10 according to the embodiment of the present invention includes a frame, a covering portion 100, a curtain portion 200, and a dehumidifying portion 400.

The frame forms the skeleton of the greenhouse, and the covering portion 100 covers the upper portion of the frame. The curtain portion 200 is disposed to be openable and closable at the lower portion of the covering portion 100 and specifically disposed between the covering portion 100 and the crop to provide an additional sealing to the outside of the crop to provide an improved warming effect. With such a structure, a space 300 is formed between the covering portion 100 and the curtain portion 200.

1 is a graph showing a relative humidity, an absolute humidity, an internal temperature of the space 300 between the covering portion 100 and the curtain portion 200 of the condensation occurrence suppression greenhouse 10 according to an embodiment of the present invention, And the change of the dew point temperature with time. More specifically, FIG. 1 shows changes in humidity, temperature, and the like in a state in which the dehumidifying part 400 of the condensation occurrence suppression greenhouse 10 according to the embodiment of the present invention is not operated.

Referring to FIG. 1, the change of the relative humidity begins to increase as the temperature decreases in the afternoon, and after the curtain unit 200 is closed, a predetermined time is elapsed, and then a certain value is maintained after reaching 100%. Later, the relative humidity decreases with sunrise in the morning as temperature increases. This is because even if the absolute humidity is the same, the relative humidity increases as the temperature decreases.

Since the temperature of the covering portion 100 starts to become lower than the dew point temperature of the air, condensation occurs in the covering portion 100, so the water vapor in the air decreases and the absolute humidity starts to decrease and keeps a constant value. do.

When the curtain part 200 is opened in the morning, dew drops formed on the roof of the greenhouse 10 begin to fall on the floor. These dew drops start to form as the temperature of the covering part 100 begins to become lower than the dew point temperature in the evening, It is the dew drop that occurred during.

The temperature of the covering portion 100 starts to be lower than the dew point temperature at the time of closing the curtain portion 200. Therefore, the curtain portion 200 is closed and at the same time, the cover portion 100 is closed using the low temperature dehumidifier 400, Moisture contained in the air in the space 300 between the curtain part 200 and the curtain part 200 can be removed to suppress condensation occurring on the inside of the inner covering material of the roof of the greenhouse 10.

The condensation occurrence suppression greenhouse 10 according to the embodiment of the present invention will be described in more detail with reference to FIGS. 2 and 3. FIG.

2 is a front structural view of the condensation generation suppressing greenhouse 10 according to the embodiment of the present invention.

Referring to FIG. 2, the frame of the greenhouse 10 forms a frame, for example, such a frame includes a column frame vertically installed on the ground, a roof frame coupled to the upper end of the column frame, A transverse frame mounted between the frame and the roof frame, and an interspinous frame. Each frame can be made to facilitate load distribution by further combining the frames between each frame to improve the structural strength.

A covering portion 100 is formed on the upper portion of the frame so that the inside of the greenhouse 10 is kept warm. The covering portion 100 may include a plurality of covering materials, and the cover materials are formed in a layered structure, so that the inside of the greenhouse 10 can have a further improved warming effect.

For example, the covering portion 100 includes a first covering material 110, which is an outer covering material contacting the outside of the greenhouse, and a second covering material 120, which is disposed under the first covering material 110 and is an inner covering material .

The curtain portion 200 is disposed under the second covering material 120, specifically, between the second covering material 120 and the crop. The curtain portion 200 may provide additional warmth to the crop and may be configured to be openable and closable to allow the greenhouse 10 to secure sufficient light transmission during the daytime and provide additional warmth to the crop at night.

The curtain portion 200 may be formed of a plurality of curtains. For example, the curtain portion 200 may include a first curtain 210 positioned below the second cover 120 and a second curtain 220 disposed below the first curtain 210. Both the first curtain 210 and the second curtain 220 can be configured to be openable and closable.

A space 300 is formed between the second covering material 120 and the first curtain 210, and moisture is present in the air of the space 300. This moisture may cause condensation to form on the surface of the second covering material 120 or the first curtain 210 when the temperature of the second covering material 120 or the first curtain 210 falls below the dew point temperature at night .

1, when the greenhouse 10 is assumed to be a three-interlocking greenhouse having a span width of about 7 m, an eave height of about 3 m, a center height of about 4.9 m, and a length of about 50 m, And the covering portion 100 may be about 1330 m < ³ >. The inside temperature between the curtain portion 200 and the covering portion 100 of the roof of the greenhouse 10 is 25 ° C and the relative humidity is 52% at about 17:00 when the curtain portion 200 is closed, Becomes almost equal to the temperature of the covering portion (100) and condensation starts. At this time, the absolute humidity between the curtain part 200 and the covering part 100 is about 0.010283 kg · kg ^-1 and the total amount of water vapor is about 16 L. The absolute humidity should be kept lower than 0.003621kg · kg ^-1 in order to keep the dew point temperature lower than -0.5 ° C, which is the cover temperature, at about 5 ° C, at which the internal temperature becomes the lowest at 3 ° C, The amount of water vapor is about 6L. Therefore, in this case, the amount of water vapor to be removed in order to prevent condensation is 10 L in total.

Depending on the environmental conditions of the greenhouse 10, the amount of water vapor to be removed in order to prevent condensation will be somewhat different. However, as shown in the calculation results, it can be seen that the total amount of water vapor to be removed is not large compared to the greenhouse 10 scale.

Referring again to FIG. 2, a low temperature dehumidifier 400, which is a dehumidifier, may be provided to suppress such condensation. The low temperature dehumidifier 400 may include a dehumidifier main body 410, an air inlet pipe 420, an air inlet 430, a drying air outlet pipe 440, and a drying air outlet 450.

The air inlet pipe 420 is connected to one end of the dehumidifier main body 410 and is connected to one end of the dehumidifier main body 410 so as to be connected to the curtain portion 200, Extends into the space (300). The other end of the air inlet pipe 420 is provided with an air inlet 430 and the air inlet 430 is disposed in the space 300. The dry air outlet pipe 440 is connected to one end of the dehumidifier main body 410 and the dry air outlet 450 at the other end of the dry air outlet pipe 440 is disposed in the space 300. Accordingly, the moisture contained in the air can be efficiently removed while the air in the space 300 passes through the dehumidifier main body 410.

More specifically, the moisture in the space 300 between the curtain part 200 and the covering part 100 is removed at the same time as closing the curtain part 200. In other words, the low temperature dehumidifier 400 can remove moisture at a low temperature, Thereby reducing the dew point temperature of the air and effectively suppressing the occurrence of condensation on the inside of the second covering material 120.

The moisture removal in the air in the space 300 of the low temperature dehumidifier 400 can be configured in a cooling manner.

When the low temperature dehumidifier 400 is configured to be cooled, the moisture in the air in the space 300 is condensed with water to control the moisture. To condense water vapor, it is necessary to lower the temperature of the air below the dew point, so that the refrigerant is used for cooling. The humid air is sucked through the fan and then passed through the evaporator using refrigerant. The temperature of the air passing through the evaporator is lowered, and the dew point of the air is reached, and the water vapor in the air is converted into water, and the water is trapped in the cooling tube and gathered in the water tank. The dehumidified dry air can be released after it has been warmed back through the condenser. The higher the relative humidity in the space 300, the more easily the water vapor in the air changes into water, so that the dehumidifying effect is excellent.

The dehumidifying part is not limited to the low temperature dehumidifier 400, and for example, the dehumidifying part may be configured as a dry type.

When the dehumidifying part is constituted by a dry type, the absorbent, which is a chemical, is used and absorbs or adsorbs moisture in the air in the space 300. If the absorbent can not absorb the moisture any more, the absorbent is heated again, and the separated moisture is sent out of the dehumidifying part and the absorbent is used again. As the absorbent, silica gel, alumina gel, molecular sieves, and the like, which are excellent porous materials capable of adsorbing moisture, can be used.

Fig. 3 shows a front structural view of a condensation generation suppressing greenhouse 10 according to a modification of the present invention.

A dehumidifying sheet 122 for absorbing moisture may be provided on the lower surface of the second covering material 120 of the greenhouse 10. The dehumidifying sheet 122 may be integrally formed with the second covering material 120. The dehumidifying sheet 122 may additionally prevent formation of condensation on the lower surface of the second covering material 120. [ The dehumidifying sheet 122 may be made of a nonwoven fabric or various hydrophilic materials capable of absorbing moisture.

In addition, a dehumidifying sheet 212 capable of absorbing moisture may be provided on the upper surface of the first curtain 210. The dehumidifying sheet 212 may be integrally formed with the first curtain 210 and the dehumidifying sheet 212 may additionally prevent formation of condensation that may occur on the upper surface of the first curtain 210. The dehumidifying sheet 212 may be made of a nonwoven fabric or various hydrophilic materials capable of absorbing moisture.

4 is a flowchart showing a control method of the condensation occurrence suppression greenhouse according to the embodiment of the present invention.

Referring to FIG. 4, when the sunset or the light emission efficiency becomes bad, the curtain portion 200 is closed (S510). As the curtain portion 200 is closed and condensation may occur in the space 300, the low temperature dehumidifier 400 starts to remove moisture in the space 300 (S520).

The dehumidification by the low temperature dehumidifier 400 is generally performed during the night. Accordingly, after the sunrise, the curtain portion 200 is opened (S530). When the curtain part 200 is opened, the low temperature dehumidifier 400 stops the moisture removal (S540).

The operation of the low temperature dehumidifier 400 can be performed manually or automatically by a sensor.

When the low temperature dehumidifier 400 is automatically operated, the greenhouse 10 may include a light sensor, which senses day and night and sends a sunset or sunrise signal to the low temperature dehumidifier 400 To the control unit.

The curtain portion 200 of the greenhouse 10 is closed and the low temperature dehumidifier 400 is operated at the same time as the curtain portion 200 is closed so that the humidity in the space 300 It starts to be removed.

The curtain portion 200 of the greenhouse 10 is opened and the operation of the low temperature dehumidifier 400 is stopped at the same time the curtain portion 200 is opened, The removal is terminated.

Also, a relative humidity sensor may be used as the sensor, in which case the relative humidity sensor measures the relative humidity in the space 300, and after the curtain unit 200 is closed, It is possible to configure the low temperature dehumidifier 400 to operate.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

10: Condensation inhibition greenhouse
100:
110: first covering material
120: Second covering material
122: dehumidifying sheet
200: Curtain portion
210: 1st curtain
212: dehumidifying sheet
220: second curtain
300: space between the covering portion and the curtain portion
400: Low temperature dehumidifier
410: dehumidifier body
420: air inflow pipe
430: Air inlet
440: Dry air outlet piping
450: Dry air outlet

Claims (7)

A frame forming the framework of the greenhouse;
At least one covering portion covering an upper portion of the frame;
At least one curtain portion disposed to be openable and closable at a lower portion of the covering portion; And
A dehumidifying portion for removing moisture in the air between the covering portion and the curtain portion;
/ RTI >
Wherein the curtain portion includes a first curtain and a second curtain disposed under the first curtain, and a dehumidifying sheet for absorbing moisture is provided on an upper surface of the first curtain.
The method according to claim 1,
Wherein the dehumidifier is a low temperature dehumidifier and the low temperature dehumidifier includes a dehumidifier main body, an air inlet pipe and a dry air outlet pipe, the dehumidifier main body is disposed at a lower portion of the curtain portion, Wherein the drying air outlet of the air outflow pipe communicates with the space between the covering portion and the curtain portion.
The method according to claim 1,
Wherein the covering portion includes a first covering material contacting the outside of the greenhouse and a second covering material disposed below the first covering material, and a dehumidifying sheet for absorbing moisture is provided on the lower surface of the second covering material.
delete A control method for a greenhouse having a space between a covering portion for covering an upper portion of a greenhouse and a curtain portion for opening and closing at a lower portion of the covering portion,
Closing the curtain portion;
Removing moisture in the air in the space between the covering portion and the curtain portion simultaneously with the closing of the curtain portion;
Opening the curtain portion; And
Stopping the removal of moisture in the air in the space between the covering portion and the curtain portion simultaneously with opening of the curtain portion;
And a control unit for controlling the greenhouse to suppress condensation.
6. The method of claim 5,
Detecting the sunset so that after the sunset, the curtain portion is closed, and condensation is prevented from being generated in the air in the space between the covering portion and the curtain portion.
6. The method of claim 5,
A control method for a greenhouse according to any one of claims 1 to 3, wherein the curtain portion is opened after sunrise and condensation is stopped to stop moisture removal in the air between the covering portion and the curtain portion.

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