KR20230158895A - Cultivation System Of Greenhouse Having Evaporative Cooling Function And Cultivation Method Of Greenhouse using the same - Google Patents

Abstract

The present invention provides an evaporative cooling function that lowers the temperature inside the greenhouse by installing an air duct and a spray nozzle inside the greenhouse, introducing air into the greenhouse through the air duct, and spraying water through the spray nozzle to enable evaporative cooling. It relates to a greenhouse cultivation system equipped with and a greenhouse cultivation method using the same.
According to the greenhouse cultivation system with an evaporative cooling function and the greenhouse cultivation method using the same according to the present invention, it is possible to lower the temperature in the greenhouse using only simple structures such as air ducts and spray nozzles, and the temperature inside the greenhouse is It is effective in controlling and maintaining humidity and CO ₂ concentration in conditions suitable for crop cultivation.

Description

Greenhouse cultivation system with evaporative cooling function and greenhouse cultivation method using the same {Cultivation System Of Greenhouse Having Evaporative Cooling Function And Cultivation Method Of Greenhouse using the same}

The present invention relates to a greenhouse cultivation system and a greenhouse cultivation method. More specifically, the present invention relates to a greenhouse cultivation system and a greenhouse cultivation method. More specifically, an air duct and a spray nozzle are installed inside the greenhouse, air is introduced into the greenhouse through the air duct, and water is sprayed through the spray nozzle to evaporate. This relates to a greenhouse cultivation system equipped with an evaporative cooling function that can lower the temperature inside the greenhouse by allowing cooling to proceed, and a greenhouse cultivation method using the same.

In general, the growth and development of crops is largely governed by light and temperature. Crops not only accumulate materials through photosynthesis, but also grow using energy generated from metabolic processes. Ultimately, if there is not enough light or the temperature is not appropriate, the growth of crops will inevitably be slow. Accordingly, facility cultivation houses or greenhouses have been used to continuously cultivate crops industrially without being affected by the season.

However, during the summer, strong sunlight shines on cultivation facilities such as glass greenhouses or vinyl greenhouses for a long time during the day, and there is a problem that the internal temperature of the facility cultivation house or greenhouse rises excessively, so it is necessary to lower the internal temperature of the greenhouse accordingly. .

In particular, as abnormal climates become more frequent due to global warming and high temperatures persist for long periods of time, cultivation of crops such as psychrophilic leafy vegetables in high temperature periods is becoming very difficult.

Meanwhile, although light is an essential environmental factor for crop cultivation, excessive temperature rise in facilities due to strong light makes crop cultivation difficult, so the development of various methods to lower the temperature in facilities has been required.

One of the methods to lower the temperature of the facility is ventilation. Ventilation is a method of forcibly expelling air heated by sunlight from a glass greenhouse, etc., making it easy to install and inexpensive to install. However, it has the disadvantage of having a small cooling capacity.

Additionally, evaporative cooling methods such as Fan & Fog, Fan & Mist, and Fan & Pad require high equipment costs and have the potential to increase indoor humidity.

Although electric cooling is technically possible, it is difficult to cover energy costs and is therefore only used for special purposes.

Additionally, because temperature rise is closely related to increase in light amount, shading technology is used to block sunlight, which is a factor in temperature rise. However, even if shading suppresses the temperature rise to some extent, fixed shading of a shading net with a certain shading rate or shading applied with shading material may have a disadvantageous effect on crop growth due to an excessive decrease in the amount of light due to shading when the amount of light is insufficient due to a poor climate. There was a problem.

Evaporative cooling methods such as Fan & Fog, Fan & Mist, and Fan & Pad have also been used, but these methods incur excessive initial installation costs, and the water usage for cooling is excessive compared to the water usage for plant cultivation. As a result, there is a problem that indoor humidity increases and may actually interfere with crop cultivation.

The technical problem to be solved by the present invention is to install an air duct and a spray nozzle inside the greenhouse, introduce air into the greenhouse through the air duct, and spray water through the spray nozzle to allow evaporative cooling to occur, thereby reducing the temperature inside the greenhouse. The goal is to provide a greenhouse cultivation system with an evaporative cooling function that can reduce , and a greenhouse cultivation method using the same.

In order to solve the above problem, a greenhouse cultivation system with an evaporative cooling function according to the present invention is a greenhouse cultivation system for growing crops in a greenhouse, comprising: a storage tank for storing evaporation water; a pressurizing pump that pressurizes the evaporated water in the storage tank and supplies it to the greenhouse; an evaporation water supply line having a plurality of nozzles with orifices and supplying the evaporation water delivered by the pressure pump into the greenhouse; An air duct installed along the length of the greenhouse to supply external air and supply air into the greenhouse through air discharge holes formed at predetermined intervals in the lower part; and an air duct T that supplies outside air into the air duct by an axial fan, wherein outside air discharged through the air discharge hole of the air duct is sprayed from the nozzle located adjacent to the air discharge hole. It is characterized in that it is mixed with water droplets of the evaporated water to control the temperature in the greenhouse by evaporative cooling.

In order to solve the above problem, a greenhouse cultivation method using a greenhouse cultivation system equipped with an evaporative cooling function according to the present invention is a greenhouse cultivation method equipped with a cooling mode, a control mode, and a ventilation mode. The greenhouse cultivation method uses evaporation water. Storage tank for storing; a pressurizing pump that pressurizes the evaporated water in the storage tank and supplies it to the greenhouse; an evaporation water supply line having a plurality of nozzles with orifices and supplying the evaporation water delivered by the pressure pump into the greenhouse; An air duct installed along the length of the greenhouse to supply external air and supply air into the greenhouse through air discharge holes formed at predetermined intervals in the lower part; and an air duct T that supplies outside air into the air duct by an axial fan, wherein outside air discharged through the air discharge hole of the air duct is sprayed from the nozzle located adjacent to the air discharge hole. It is characterized by using a greenhouse cultivation system equipped with an evaporative cooling function that adjusts the temperature in the greenhouse by evaporative cooling by mixing with water droplets of the evaporated water.

The greenhouse cultivation system with an evaporative cooling function and the greenhouse cultivation method using the same according to the present invention have the advantage of being able to lower the temperature in the greenhouse by using only simple structures such as air ducts and spray nozzles inside the greenhouse.

In addition, by providing a temperature sensor, a relative humidity sensor, and a CO ₂ concentration sensor, the temperature, humidity, and CO ₂ concentration within the greenhouse can be controlled and maintained in conditions suitable for crop cultivation.

Figure 1 is a diagram schematically showing the configuration of a greenhouse cultivation system equipped with an evaporative cooling function according to the present invention.
Figure 2 is a cross-sectional view taken along line AA' of Figure 1.
Figure 3 is a diagram showing an axial flow fan of a greenhouse cultivation system equipped with an evaporative cooling function according to the present invention.
Figure 4 is a diagram showing the evaporation water supply line of a greenhouse cultivation system equipped with an evaporative cooling function according to the present invention.
Figure 5 is a diagram showing the air outlet of a greenhouse cultivation system equipped with an evaporative cooling function according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a diagram schematically showing the configuration of a greenhouse cultivation system equipped with an evaporative cooling function according to the present invention, and Figure 2 is a cross-sectional view taken along line A-A' of Figure 1.

Referring to Figures 1 and 2, the greenhouse cultivation system 100 equipped with an evaporative cooling function according to the present invention includes a storage tank 11, a chemical tank 12, a three-way valve 13, and a pressure pump 14. , filter (15), ozone generator (16), greenhouse border (21), axial fan (22), air duct (23), air discharge hole (24), evaporation water supply line (25), air outlet (28) , including a beam 29, a sensor unit 30, and an air duct tee 31.

The storage tank 11 stores evaporation water for growing crops in the greenhouse. The chemical tank 12 stores chemicals for pest control mixed with water. The pressurizing pump 14 adjusts the three-way valve 13 to pressurize the evaporated water in the storage tank 11 or the pesticide in the chemical tank 12 and supply it to the greenhouse.

The filter 15 removes contaminants contained in the evaporation water delivered by the pressure pump 14. The ozone generator 16 generates ozone and supplies ozone gas to the evaporation water delivered by the pressure pump. The ozone gas generated from the ozone generator (16) is introduced into the evaporation water supply pipe (17) pressurized through the pressurization pump (14) using a Venturi pipe, and the ozone is dissolved in water so that the ozone dissolved water has a deodorizing and sterilizing effect. It can prevent crop pests and provide sterilizing effects.

Meanwhile, although not shown in FIGS. 1 and 2, the greenhouse cultivation system 100 with an evaporative cooling function according to the present invention further includes a pressure regulator for adjusting the pressure of the evaporation water delivered by the pressure pump 14. It can be included.

The greenhouse boundary 21 is made of a translucent material such as vinyl or synthetic resin and serves to surround and seal the greenhouse.

The axial fan 22 is located outside the greenhouse boundary 21 and supplies external air to the air duct tee 31 at a flow rate of 4000 m ³ /h and a pressure of 150 Pa. Figure 3 is a diagram showing an axial flow fan of a greenhouse cultivation system equipped with an evaporative cooling function according to the present invention.

Meanwhile, the greenhouse cultivation system 100 with an evaporative cooling function according to the present invention includes an ultraviolet sterilizing device 22a that sterilizes the external air supplied into the air duct tee 31 through the axial flow fan 22 with ultraviolet rays. ) may further be included.

At this time, the ultraviolet sterilizing device 22a further includes a manifold (not shown) through which external air flowing in through the axial fan 22 passes, and an ultraviolet sterilizing lamp (not shown) installed within the manifold. You can.

The air duct 23 is installed in the longitudinal direction of the greenhouse, supplies external air, and supplies air into the greenhouse through air discharge holes 24 formed at predetermined intervals at the bottom. The air duct 23 takes the form of a pipe with a length of 30 m to 40 m and a cross section of 450 mm x 400 mm. In addition, it is preferable to form 6 to 10 air ducts 23 along the length of the greenhouse at a height of 3 m to 4 m from the ground inside the greenhouse using beams 29. When the air duct 23 is installed at a height of 3 m to 4 m above the ground inside the greenhouse, the air that comes in from the outside and is discharged through the air discharge hole 24 in the air duct 23 comes into direct contact with the crops in the greenhouse. It has the effect of preventing cold damage.

The air duct tee 31 serves to supply external air into the air duct 23 by the axial fan 22. The inlet of the air duct tee 31 is formed in a cylindrical shape with a diameter of 500 mm, and the two outlets have the shape of a pipe of 450 mm x 400 mm. Meanwhile, the length of the air duct tee 31 is preferably 0.8 m to 1.2 m.

The air discharge hole 24 is formed in the lower part of the air duct 23 along the entire length of the air duct 23. At this time, the air discharge hole 24 has a size of 100 mm x 200 mm and is formed at intervals of 1.5 m. At this time, it is desirable that the long axis of the air discharge hole 24 be formed in a direction perpendicular to the axis of the air duct 23. Additionally, it is desirable to form 8 to 12 air discharge holes 24 in one air duct 23.

It is preferable that a semicircular arch member is formed at the entrance of the air discharge hole 24 so that the air discharged into the greenhouse through the semicircular arch member can form a turbulent flow.

The evaporation water supply line 25 is provided with a plurality of nozzles 25a having orifices, and the evaporation water delivered by the pressure pump 12 is supplied into the greenhouse in the form of a spray through the orifices of the plurality of nozzles 25a. Spray.

The greenhouse cultivation system 100 with an evaporative cooling function according to the present invention allows external air discharged in turbulent form through the semicircular arch member of the air discharge hole 24 of the air duct 23 to be discharged through the air discharge hole ( 24) is mixed with water droplets of the evaporation water sprayed in the form of a spray from the nozzle 25a located adjacent to 24), and the temperature in the greenhouse is controlled by evaporative cooling.

Meanwhile, the discharge direction of the air through the air discharge hole 24 and the spray direction of the evaporation water through the nozzle 25a are directed in the same direction, so that the spray mist of the nozzle is discharged from the air discharge hole 24. By promoting the diffusion of air, evaporation can easily occur.

In addition, the air discharge hole 24 and the nozzle 25a are installed so that the spray direction is downward in the direction of gravity, so that the cold air formed by evaporation is directed to the bottom where the plants are, and the air heated inside the greenhouse is blown by natural convection and the blower. It naturally moves upward due to pressure, making it easy to control humidity inside the greenhouse.

Figure 4 is a diagram showing the evaporation water supply line of a greenhouse cultivation system equipped with an evaporative cooling function according to the present invention.

As shown in Figure 4, the evaporation water supply line 25 of the greenhouse cultivation system equipped with an evaporative cooling function according to the present invention is made of a polymer tube with a diameter of 8 mm. Evaporation water is supplied into the polymer tube-shaped evaporation water supply line 25 by the pressure pump 14.

The evaporation water supply line 25 of the greenhouse cultivation system with an evaporative cooling function according to the present invention is cut at the air discharge hole 24 of the air duct 23 and a nozzle 25a with an orifice at the cut portion. This is installed. The nozzle 25a is preferably a spray nozzle capable of spraying the evaporation water flowing inside the evaporation water supply line 25 into the greenhouse.

The evaporation water sprayed by the nozzle 25a exists as a spray 26 inside the greenhouse and forms a stratified boundary 27 at the lower and upper parts of the greenhouse.

An air outlet 28 is formed at the top of the greenhouse to discharge hot air inside the greenhouse to the outside.

Figure 5 is a diagram showing the air outlet of a greenhouse cultivation system equipped with an evaporative cooling function according to the present invention.

The air outlet 28 is formed in the shape of a square pillar at the top of the greenhouse. At this time, the upper part 28a of the air outlet is sealed, and an inertial grid through which internal air can be discharged is formed on the four-directional side surfaces 28b.

When the air inside the greenhouse becomes hot and the pressure inside the greenhouse rises, the air outlet 28 opens the inertial grid formed on the four-way side 28b, so that the hot indoor air is discharged to the outside, and the pressure inside the greenhouse increases. It is desirable to have a check valve structure that closes again when it is lowered again.

That is, the air outlet 28 is designed to exclude free air flow from the ventilation system and to automatically close when the fan is not operating. The air outlet 28 is made of moisture-proof nylon material, and is preferably installed vertically with the inertial grid facing downward.

Meanwhile, the humidity and temperature inside the greenhouse can be controlled by adjusting the flow rate of the evaporation water supplied into the evaporation water supply line 25 by the pressurized pump 14 and the evaporation water sprayed into the greenhouse by the nozzle 25a. You can. In addition, the greenhouse cultivation system with an evaporative cooling function according to the present invention may further include a sensor unit 30 capable of measuring the temperature, relative humidity, and carbon dioxide (CO ₂ ) concentration inside the greenhouse.

Additionally, in the greenhouse cultivation system equipped with an evaporative cooling function according to the present invention, a carbon dioxide supply line is connected to the evaporation water supply line 25 and a check valve is installed to supply carbon dioxide (CO ₂ ) into the evaporation water supply line 25. You can. Carbon dioxide (CO ₂ ) can be supplied from the cylinder through a reducer and solenoid control valve. At this time, the operating pressure of the reducer is preferably 5 bar or less and the concentration of carbon dioxide (CO ₂ ) is preferably controlled to be maintained in the range of 800 to 2000 ppm.

Additionally, in order to suppress the occurrence of bacteria in the plant environment, the water sprayed by the nozzle 25a of the evaporation water supply line 25 can be ozonated.

While the greenhouse cultivation system with the evaporative cooling function according to the present invention is operating, the greenhouse entrance and air outlet 28 are kept closed.

On the other hand, the greenhouse cultivation method using a greenhouse cultivation system with an evaporative cooling function according to the present invention is a greenhouse cultivation method with a cooling mode, a pest control mode, and a ventilation mode, and the greenhouse cultivation method includes a storage tank for storing evaporation water. ; a pressurizing pump that pressurizes the evaporated water in the storage tank and supplies it to the greenhouse; an evaporation water supply line having a plurality of nozzles with orifices and supplying the evaporation water delivered by the pressure pump into the greenhouse; An air duct installed along the length of the greenhouse to supply external air and supply air into the greenhouse through air discharge holes formed at predetermined intervals in the lower part; and an air duct T that supplies outside air into the air duct by an axial fan, wherein outside air discharged through the air discharge hole of the air duct is sprayed from the nozzle located adjacent to the air discharge hole. It is characterized by using a greenhouse cultivation system equipped with an evaporative cooling function that adjusts the temperature in the greenhouse by evaporative cooling by mixing with water droplets of the evaporated water.

In the cooling mode, the axial fan and the pressure pump are operated to cool the air in the greenhouse.

In the control mode, the axial flow fan is stopped and the control agent delivered by the pressure pump is supplied. At this time, it is preferable to supply the pesticide stored in the chemical tank and spray it on the crops through the evaporation water supply line.

In the ventilation mode, the pressurizing pump is stopped and the axial flow fan is operated to introduce outside air and remove moisture from the greenhouse.

Meanwhile, when operating in the control mode, it is preferable to supply the ozone generated from the ozone generator through the Venturi pipe to the evaporation water supply pipe to dissolve it, and then spray it on crops through the evaporation water supply line to block pests.

A greenhouse cultivation method using a greenhouse cultivation system with an evaporative cooling function according to the present invention can control the operations of the cooling mode, the pest control mode, and the ventilation mode using a control unit.

As described above, according to the greenhouse cultivation system with an evaporative cooling function according to the present invention and the greenhouse cultivation method using the same, air brought in from the outside by a fan is discharged into the greenhouse through a semicircular arch member formed at the entrance of the air discharge hole. By being discharged while being formed, mixing with the water droplets of the evaporation water sprayed from the nozzle becomes easy, which has the advantage of greatly improving the evaporation effect.

That is, the evaporative cooling effect can be further improved by forming turbulence when air is discharged from the air duct through the air discharge hole and creating fog using a plurality of nozzles adjacent to the air discharge hole.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and can be implemented in various embodiments based on the basic concept of the present invention defined in the following claims. These embodiments also fall within the scope of the present invention.

Claims (16)

In a greenhouse cultivation system for growing crops in a greenhouse,
A storage tank for storing evaporation water;
a pressurizing pump that pressurizes the evaporated water in the storage tank and supplies it to the greenhouse;
an evaporation water supply line having a plurality of nozzles with orifices and supplying the evaporation water delivered by the pressure pump into the greenhouse;
An air duct installed along the length of the greenhouse to supply external air and supply air into the greenhouse through air discharge holes formed at predetermined intervals in the lower part; and
An air duct T that supplies outside air into the air duct by an axial fan,
The outside air discharged through the air discharge hole of the air duct is mixed with water droplets of the evaporation water sprayed from the nozzle located adjacent to the air discharge hole to control the temperature in the greenhouse by evaporative cooling. A greenhouse cultivation system with an evaporative cooling function. According to claim 1,
a filter for removing contaminants contained in the evaporation water delivered by the pressurization pump;
a pressure regulator that adjusts the pressure of the evaporation water delivered by the pressurization pump; and
A greenhouse cultivation system with an evaporative cooling function, further comprising an ozone generator that supplies ozone gas to the evaporation water delivered by the pressurization pump. According to claim 1,
A greenhouse cultivation system with an evaporative cooling function, wherein the direction of air discharge through the air discharge hole and the spray direction of the evaporative water through the nozzle are the same. According to claim 1,
A greenhouse cultivation system with an evaporative cooling function, further comprising an ultraviolet sterilizing device that sterilizes external air supplied into the air duct through the axial fan with ultraviolet rays. The method of claim 4, wherein the ultraviolet sterilizing device
a manifold through which external air introduced through the axial fan passes; and
A greenhouse cultivation system with an evaporative cooling function, further comprising an ultraviolet sterilizing lamp installed in the manifold. According to claim 1,
A chemical tank that stores chemicals for pest control mixed with water; and
A greenhouse cultivation system with an evaporative cooling function, further comprising a three-way valve whose first inlet is connected to the storage tank, the second inlet is connected to the chemical tank, and the outlet is connected to the pressurizing pump. The method of claim 1, wherein the air discharge hole is
A greenhouse cultivation system with an evaporative cooling function, characterized in that a semicircular arch member is formed at the entrance and the air discharged into the greenhouse through the semicircular arch member is formed in a square shape to form turbulence. According to clause 7,
A greenhouse cultivation system with an evaporative cooling function, characterized in that evaporative cooling occurs by mixing turbulent air passing through the arch member and water droplets of the evaporative water sprayed from the nozzle. According to claim 1,
It further includes an air outlet formed in the shape of a square pillar at the top of the greenhouse through which the heated indoor air inside the greenhouse is discharged to the outside,
The air outlet is characterized in that it is in the form of an inertial grid with a check valve function that opens when the indoor air becomes hot and the pressure inside the greenhouse rises, thereby discharging the hot indoor air to the outside, and closes when the pressure inside the greenhouse decreases again. A greenhouse cultivation system equipped with an evaporative cooling function. The method of claim 1, wherein the air duct is
A greenhouse cultivation system with an evaporative cooling function, which is installed at a height of 2m to 3m from the greenhouse floor to prevent cold damage from occurring when air flowing in from the outside and discharged through the air discharge hole comes into direct contact with the crops in the greenhouse. The method of claim 1, wherein the air duct is
A greenhouse cultivation system with an evaporative cooling function, further comprising a sensor unit capable of detecting and controlling temperature, humidity, and CO ₂ concentration inside the greenhouse. In a greenhouse cultivation method equipped with a cooling mode, a pest control mode, and a ventilation mode,
The greenhouse cultivation method is a greenhouse cultivation method using a greenhouse cultivation system with an evaporative cooling function, characterized in that the greenhouse cultivation system with an evaporative cooling function according to any one of claims 1 to 11. In clause 12
In the cooling mode, the axial flow fan and the pressure pump are operated to cool the air in the greenhouse,
In the control mode, the axial flow fan is stopped and the control agent delivered by the pressurized pump is supplied.
A greenhouse cultivation method using a greenhouse cultivation system with an evaporative cooling function, characterized in that in the ventilation mode, the pressure pump is stopped and the axial flow fan is operated to introduce outside air and remove moisture from the greenhouse. According to claim 13,
A greenhouse cultivation method using a greenhouse cultivation system with an evaporative cooling function, characterized in that the operations of the cooling mode, the pest control mode, and the ventilation mode are controlled using a control unit. According to claim 13,
When operating in the control mode, ozone generated from the ozone generator is supplied to the evaporation water supply pipe through a venturi pipe, dissolved in the evaporation water, and then sprayed on crops through the evaporation water supply line to block pests. Greenhouse cultivation method using a functional greenhouse cultivation system. According to claim 13,
A greenhouse cultivation method using a greenhouse cultivation system with an evaporative cooling function, characterized in that when operating in the control mode, the pesticide stored in the chemical tank is supplied and sprayed on crops through the evaporation water supply line.