KR102642624B1 - Apparatus for carbon dioxide application in crop cutivation facility and system for carbon dioxide application - Google Patents

Abstract

The present invention relates to a carbonic acid fertilization device and a carbonic acid fertilization system within a crop cultivation facility. The carbonic acid fertilization device within a crop cultivation facility according to the present invention is spaced apart from a discharge pipe that discharges exhaust gas discharged from an energy generation device to the outside and discharges the exhaust gas from the discharge pipe. It is characterized by comprising a suction pipe for supplying carbon dioxide to the inside of the crop cultivation facility by sucking in exhaust gas and outside air, and a blower for sucking air through the suction pipe.

Description

Carbonic acid fertilization device and carbonic acid fertilization system in crop cultivation facilities {APPARATUS FOR CARBON DIOXIDE APPLICATION IN CROP CUTIVATION FACILITY AND SYSTEM FOR CARBON DIOXIDE APPLICATION}

The present invention relates to a carbonic acid fertilization device and a carbonic acid fertilization system within a crop cultivation facility. More specifically, the carbon dioxide required to grow plants inside crop cultivation facilities such as greenhouses and plant factories using exhaust gas emitted from energy generation devices within the building. It relates to carbonate fertilization devices and carbonate fertilization systems within crop cultivation facilities that supply .

As facilities for urban agriculture and smart farms, crop cultivation facilities such as greenhouses and plant factories have recently been widely installed.

In addition, heat pumps and boilers that produce thermal energy for cooling or heating with fuel such as gas are being installed inside buildings, and the number of buildings equipped with generators to use electricity inside the building is increasing. Furthermore, as the need for eco-friendly energy sources increases, fuel cells are sometimes installed inside buildings as a power source.

In order to increase crop productivity in facility cultivation such as greenhouses, an appropriate supply of carbon dioxide (CO ₂ ) is required. In facility cultivation, carbon dioxide fertilization is used to increase the quantity and quality of crop cultivation by introducing carbon dioxide gas into the facility.

By utilizing exhaust gases generated from facilities such as fuel cells, gas heat pumps, and boilers, the interior of the facility can be controlled to maintain an appropriate carbon dioxide concentration without the need for additional carbon dioxide supply devices such as carbon dioxide tanks. Additionally, in the case of fuel cells that use city gas or LPG as fuel, carbonic acid fertilization using exhaust gas is possible.

However, when the exhaust gas outlet of the fuel cell is directly connected to the inside of a facility such as a greenhouse through a pipe, and a blower is used to create a flow so that the exhaust gas of the fuel cell moves inside the facility, the back pressure in the internal flow path of the fuel cell changes. This can deteriorate the performance of the fuel cell.

In addition, according to the fuel cell installation standards of the KGS regulations related to fuel cell installation (KGS FU671 2021, facility/technology/inspection standards for hydrogen fuel use facilities), exhaust gases are discharged into the cultivation facility by directly connecting piping to the exhaust gas outlet of the fuel cell. Supply is prohibited.

Japanese Patent No. 5578469

Therefore, the purpose of the present invention is to solve this conventional problem, by arranging a suction pipe in a location spaced apart from the discharge pipe that discharges exhaust gas discharged from the energy generating device in the building to the outside, thereby removing the exhaust gas discharged from the discharge pipe and the outside air. By inhaling carbon dioxide together and supplying it to the interior of crop cultivation facilities such as greenhouses and plant factories, it does not affect the performance of energy generation devices and provides carbon dioxide fertilization devices and carbon dioxide fertilization systems within crop cultivation facilities that comply with relevant regulations. .

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The above object is, according to the present invention, an intake pipe that is spaced apart from an exhaust pipe that discharges exhaust gas discharged from an energy generating device to the outside and supplies carbon dioxide to the inside of a crop cultivation facility by sucking exhaust gas and outdoor air discharged from the discharge pipe; And it can be achieved by a carbonic acid fertilization device in a crop cultivation facility, comprising a blower that sucks air through the suction pipe.

Here, the energy generating device may be any one of a generator, boiler, heat pump, or fuel cell that generates energy used in the building using fuel such as gas.

Here, it is preferable that one end of the discharge pipe and the suction pipe that are spaced apart are arranged in the coaxial direction.

Here, a concentration sensor that measures the carbon dioxide concentration inside the crop cultivation facility and measures the carbon dioxide concentration inside the suction pipe; And it may further include a control unit that controls the flow rate or carbon dioxide concentration of air introduced through the suction pipe based on the value measured from the concentration sensor.

Here, the separation distance between the discharge pipe and the suction pipe is adjusted, and the control unit can control the separation distance between the discharge pipe and the suction pipe based on the value measured from the concentration sensor.

Here, the suction end of the suction pipe may be extended or retracted.

Here, the angle of the suction end of the suction pipe is adjusted, and the controller may control the angle of the suction end of the suction pipe based on the value measured from the concentration sensor.

Here, an external pipe connected to the suction pipe into which external air flows; and an opening control valve that controls the opening and closing amount of the external pipe, wherein the controller can control the opening and closing amount of the opening control valve based on the value measured from the concentration sensor.

In addition, the above object is, according to the present invention, a building equipped with an energy generating device that generates necessary energy within the building and a discharge pipe that discharges exhaust gas discharged from the energy generating device to the outside of the building; A crop cultivation facility that grows plants by receiving carbon dioxide emitted from the building; And a carbonic acid fertilization device including a suction pipe that is spaced apart from the discharge pipe and sucks exhaust gas and outdoor air discharged from the discharge pipe to supply carbon dioxide to the inside of the crop cultivation facility, and a blower that sucks air through the suction pipe. This can be achieved by a carbonic acid fertilization system.

According to the carbonic acid fertilization device and carbonic acid fertilization system in the crop cultivation facility of the present invention as described above, the productivity of cultivated crops is improved by using the exhaust gas emitted from the energy generating device to apply carbonic acid fertilization in crop cultivation facilities such as greenhouses and plant factories. You can do it.

In addition, there is an advantage that it does not affect the operating performance of the fuel cell, etc. and that carbonic acid fertilization can be performed using the exhaust gas discharged from the fuel cell.

In addition, there is an advantage that carbonic acid fertilization can be performed using the discharged exhaust gas while complying with the relevant regulations related to exhaust gas emissions.

In addition, it has the advantage of controlling the flow rate of air and the concentration of carbon dioxide flowing into the crop cultivation facility for carbonic acid fertilization and enabling optimal carbonic acid fertilization.

Figure 1 is a diagram showing a carbonate fertilization device and a carbonate fertilization system within a crop cultivation facility according to an embodiment of the present invention.
Figure 2 is a modified example of Figure 1.
Figure 3 is a diagram explaining an operation in which the end length of a suction pipe is changed according to an embodiment of the present invention.
Figure 4 is a diagram explaining an operation in which the end angle of a suction pipe is changed according to another embodiment of the present invention.

Specific details of the embodiments are included in the detailed description and drawings.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. The present embodiments are merely provided to ensure that the disclosure of the present invention is complete and to be understood by those skilled in the art. It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, the present invention will be described with reference to drawings for explaining a carbonate fertilization device and a carbonate fertilization system in a crop cultivation facility according to embodiments of the present invention.

Figure 1 is a diagram showing a carbonate fertilization device and a carbonate fertilization system in a crop cultivation facility according to an embodiment of the present invention, Figure 2 is a modification of Figure 1, and Figure 3 is a suction pipe according to an embodiment of the present invention. This is a diagram explaining an operation in which the end length of a is changed, and Figure 4 is a diagram explaining an operation in which the end angle of a suction pipe is changed according to another embodiment of the present invention.

A carbonate fertilization device in a crop cultivation facility according to an embodiment of the present invention may be configured to include a suction pipe 210 and a blower 220.

The suction pipe 210 is spaced apart from the discharge pipe 115, which discharges the exhaust gas discharged from the energy generator 110 to the outside, and sucks the exhaust gas discharged from the discharge pipe 115 together with the outside air to be used in crop cultivation facilities such as greenhouses and plant factories. It supplies carbon dioxide inside.

The energy generating device 110 may be a device that is placed within a building and generates energy such as heat energy and electrical energy required within the building. For example, the energy generation device 110 may be comprised of any one of a generator, boiler, heat pump, or fuel cell that emits exhaust gas containing carbon dioxide in the process of generating energy.

Accordingly, the discharge pipe 115 extends from the energy generating device 110 to the outside of the building and discharges exhaust gas outside the building.

The crop cultivation facility may be placed on the rooftop of the building where the energy generating device 110 is placed, as shown in FIG. 1, or may be placed in a separate space next to the building, as shown in FIG. 2. . The following description will take the case where the crop cultivation facility is a greenhouse as an example.

As shown, the discharge end of the discharge pipe 115 and the suction end of the suction pipe 210 may be spaced apart in a line in the coaxial direction.

The blower 220 sucks air through the suction pipe 210 and supplies it to the inside of the greenhouse. At this time, since the suction pipe 210 is spaced apart from the discharge pipe 115, exhaust gas discharged from the discharge pipe 115 and external air can be sucked in together.

Typically, the concentration of carbon dioxide contained in the exhaust gas of a fuel cell can be 5% to 20%, and the carbon dioxide concentration in the atmosphere is 400ppm. The carbon dioxide concentration required in the greenhouse is 1000 to 1500 ppm, so even if the exhaust pipe 115 and the suction pipe 210 are not directly connected and the exhaust gas discharged to the surroundings from the discharge pipe 115 is indirectly inhaled along with the outside air at a spaced location, the greenhouse Carbon dioxide of the required concentration can be sufficiently supplied.

Concentration sensors 232 and 234 may be formed to measure the carbon dioxide concentration inside the greenhouse and measure the carbon dioxide concentration supplied into the greenhouse from the inside of the suction pipe 210. Accordingly, the concentration sensors 232 and 234 may be formed inside the greenhouse and the suction pipe 210.

The control unit 250 controls the flow rate or carbon dioxide concentration of air flowing into the greenhouse through the suction pipe 210 based on the carbon dioxide concentration inside the greenhouse measured by the concentration sensors 232 and 234 and the carbon dioxide concentration supplied from the suction pipe 210. You can. If the carbon dioxide concentration inside the greenhouse is lower than the required value, the flow rate of air flowing in from the suction pipe 210 can be increased or the carbon dioxide concentration can be controlled to increase.

For example, the controller 250 may control the flow rate of air flowing into the greenhouse by controlling the speed of the blower 220. As the speed of the blower 220 increases, a greater amount of air can be introduced from the intake port.

Additionally, an opening control valve 212 that controls the opening and closing amount may be formed in the suction pipe 210. The controller 250 may control the flow rate of air flowing in from the suction pipe 210 by controlling the opening and closing amount of the opening control valve 212.

The external pipe 240 is connected to the middle part of the suction pipe 210 to introduce external air. When exhaust gas and outside air are introduced together from the end of the suction pipe 210, the concentration of carbon dioxide inhaled may be higher than the concentration required in the greenhouse. Accordingly, in the present invention, the concentration of carbon dioxide supplied to the greenhouse can be controlled by additionally introducing outdoor air with a low carbon dioxide concentration by forming a separate external pipe 240 that introduces outdoor air.

At this time, an opening control valve 242 that controls the opening and closing amount of the external pipe 240 may be formed in the external pipe 240. The controller 250 may control the opening and closing amount of the opening control valve 242 to control the concentration of carbon dioxide contained in the air flowing into the greenhouse from the suction pipe 210. If the concentration value of carbon dioxide measured from the concentration sensor 234 disposed inside the suction pipe 210 is higher than the reference value, the opening amount of the opening control valve 242 may be increased to increase the inflow of external air in order to lower the carbon dioxide concentration. You can. Conversely, when the carbon dioxide concentration value measured from the concentration sensor 234 is lower than the reference value, it is preferable to close the opening control valve 242 to prevent the carbon dioxide concentration from falling further, and as described later, the carbon dioxide concentration increases. can be controlled.

In the present invention, the separation distance between the discharge pipe 115 and the suction pipe 210 can be adjusted. For example, the discharge end of the discharge pipe 115 may be configured to move toward or away from the suction pipe 210, or the suction end of the suction pipe 210 may be configured to move toward or away from the discharge pipe 115. there is.

In this embodiment, as shown in FIG. 3, the separation distance between the suction pipe 210 and the discharge pipe 115 can be adjusted by moving the suction end of the suction pipe 210 closer or farther away from the discharge pipe 115. For example, the suction end of the suction pipe 210 is formed in a bellows shape, and the separation distance can be adjusted by extending or contracting the end. At this time, the end of the suction pipe 210 can be automatically controlled by the control unit 250.

The configuration in which the suction end of the suction pipe 210 moves to adjust the separation distance is not limited to the illustrated form and can be modified into various known forms that move the end of the pipe.

When the concentration value of carbon dioxide measured by the concentration sensor 234 inside the suction pipe 210 is lower than the reference value, the control unit 250 controls the separation distance between the suction pipe 210 and the discharge pipe 115 to become closer to obtain a higher value. Ensure that the concentration of carbon dioxide can be inhaled. Conversely, when the concentration value of carbon dioxide measured by the concentration sensor 234 is higher than the reference value, the control unit 250 controls the separation distance between the suction pipe 210 and the discharge pipe 115 to increase to a lower concentration of carbon dioxide. so that it can be inhaled.

When exhaust gas is discharged from the discharge pipe 115, as the distance from the discharge pipe 115 increases, the amount of mixing with external air increases and the concentration of carbon dioxide decreases. Therefore, in the present invention, the concentration of carbon dioxide contained in the air sucked into the suction pipe 210 can be controlled by controlling the separation distance between the discharge pipe 115 and the suction pipe 210.

Additionally, in this embodiment, the angle of the suction end of the suction pipe 210 can be adjusted as shown in FIG. 4. For example, the suction end of the suction pipe 210 is formed in a bellows shape, and the angle of the suction end of the suction pipe 210 can be adjusted by pulling to the left or right.

The configuration for adjusting the angle of the suction end of the suction pipe 210 is not limited to the form shown and can be modified into various known forms that change the angle of the end of the pipe.

If the concentration value of carbon dioxide measured by the concentration sensor 234 inside the suction pipe 210 is lower than the reference value, the control unit 250 controls the suction port of the suction pipe 210 to face the outlet of the discharge pipe 115 to obtain a higher concentration. Ensure that the concentration of carbon dioxide can be inhaled. Conversely, when the concentration value of carbon dioxide measured by the concentration sensor 234 is higher than the reference value, the control unit 250 controls the suction port of the suction pipe 210 not to face the discharge pipe 115 so that a lower concentration of carbon dioxide is inhaled. make it possible

In this way, the concentration of carbon dioxide contained in the air flowing in from the suction pipe 210 can be controlled by controlling the suction angle of the suction pipe 210.

There is a difference between Figures 1 and 2 in the case where the greenhouse is formed on the rooftop of the building and the case where the greenhouse is formed outside the building. Accordingly, in FIG. 1, the discharge end of the discharge pipe 115 and the suction end of the suction pipe 210 are arranged vertically up and down, whereas in FIG. 2, the discharge end of the discharge pipe 115 and the suction end of the suction pipe 210 are arranged in a horizontal direction. There is a difference in how it is placed. In addition, there is only a difference in the location of the condensate discharge pipes 117 and 217 that discharge condensate, but the remaining configuration is the same.

The carbonate fertilization system according to an embodiment of the present invention may be configured to include a building, a crop cultivation facility, and a carbonate fertilization device.

Inside the building, an energy generating device 110 is disposed to generate energy such as heat energy and electrical energy required within the building, and a discharge pipe 115 is formed to discharge exhaust gas discharged from the energy generating device 110 to the outside of the building. You can.

Crop cultivation facilities such as greenhouses and plant factories grow plants by receiving carbon dioxide contained in exhaust gases emitted from buildings. The crop cultivation facility may be placed on the roof of a building as shown in FIG. 1, or may be placed outside the building as shown in FIG. 2.

The carbonic acid fertilization device is spaced apart from the discharge pipe 115 and sucks the exhaust gas and outside air discharged from the discharge pipe 115 together, and supplies air containing carbon dioxide to the inside of the crop cultivation facility by supplying air through the suction pipe 210 and the suction pipe 210. It may be configured to include a blower 220 that suctions.

Since the configuration of the concentration sensors 232 and 234 and the control unit 250 to perform carbonic acid fertilization at an appropriate flow rate or concentration inside the crop cultivation facility has been described above, detailed description thereof will be omitted.

Hereinafter, the operation of the carbonate fertilization system according to the present invention will be described.

When the energy generating device 110 in the building operates, the exhaust gas is discharged to the outside through the discharge pipe 115 extending outside the building. At this time, when the energy generating device 110 is a fuel cell, the concentration of carbon dioxide contained in the exhaust gas may be approximately 5% to 20%.

At this time, by the operation of the blower 220, the exhaust gas discharged from the discharge pipe 115 and the outside air are sucked together through the suction pipe 210 spaced apart from the discharge pipe 115 to supply air containing a predetermined concentration of carbon dioxide into the greenhouse. You can.

At this time, the control unit 250 receives the measured value of the carbon dioxide concentration inside the greenhouse and the carbon dioxide concentration of the air flowing in through the suction pipe 210 through the concentration sensors 232 and 234, and supplies it to the greenhouse through the suction pipe 210. The flow rate or carbon dioxide concentration of the air can be controlled.

If the carbon dioxide concentration inside the greenhouse is lower than the reference value, the control unit 250 may increase the flow rate of air containing exhaust gas supplied to the greenhouse through the suction pipe 210 or increase the carbon dioxide concentration in the air. In addition, when the carbon dioxide concentration inside the greenhouse is higher than the standard value, the control unit 250 can reduce or block the flow rate of air containing exhaust gas supplied to the greenhouse through the suction pipe 210, or the air supplied to the greenhouse. The concentration of carbon dioxide contained in can be lowered.

For example, in order to increase the flow rate of air supplied to the greenhouse, the control unit 250 can increase the speed of the blower 220 and increase the opening amount of the opening control valve 212 formed in the suction pipe 210. .

In addition, in order to increase the concentration of carbon dioxide contained in the air supplied to the greenhouse, the separation distance between the suction end of the suction pipe 210 and the discharge end of the discharge pipe 115 is controlled to be closer, or the suction pipe 210 is directed toward the discharge end. ) The angle of the end can be controlled.

In addition, in order to lower the concentration of carbon dioxide contained in the air supplied to the greenhouse, the separation distance between the suction end of the suction pipe 210 and the suction end of the discharge pipe 115 is controlled to be further apart, or the suction pipe 210 is moved away from the discharge end. ) The angle of the end can be controlled. Furthermore, the concentration of carbon dioxide contained in the air inside the suction pipe 210 can be controlled by controlling the amount of external air flowing in from the external pipe 240.

The scope of the present invention is not limited to the above-described embodiments, but may be implemented in various forms of embodiments within the scope of the appended claims. It is considered to be within the scope of the claims of the present invention to the extent that anyone skilled in the art can make modifications without departing from the gist of the invention as claimed in the claims.

110: Energy generating device
115: discharge pipe
210: Suction pipe
212: Opening degree control valve
220: blower
232: Concentration sensor
234: Concentration sensor
240: External organ
242: Opening degree control valve
250: control unit

Claims (9)

An exhaust pipe that discharges exhaust gas from an energy generating device that directly generates the energy needed within the building to the outside is placed at a distance in the direction of exhaust gas discharge, and supplies carbon dioxide inside the crop cultivation facility by sucking in the exhaust gas and outdoor air discharged from the exhaust pipe. suction; and
It includes a blower that sucks air through the suction pipe,
In a crop cultivation facility, characterized in that the concentration of carbon dioxide is controlled by controlling the amount of exhaust gas flowing in through the suction pipe by adjusting the separation distance between the discharge pipe and the suction pipe or adjusting the angle of the suction end of the suction pipe. Carbonic acid fertilization device. According to claim 1,
The energy generating device is a carbonate fertilization device in a crop cultivation facility, characterized in that it is any one of a generator, boiler, heat pump, or fuel cell that generates energy used in the building. According to claim 1,
Carbonic acid fertilization device in a crop cultivation facility, characterized in that one end of the spaced discharge pipe and the suction pipe is arranged in the coaxial direction. According to claim 1,
A concentration sensor that measures the carbon dioxide concentration inside the crop cultivation facility and measures the carbon dioxide concentration inside the suction pipe; and
Carbonic acid fertilization device in a crop cultivation facility, further comprising a control unit that controls the flow rate or carbon dioxide concentration of air flowing in through the suction pipe based on the value measured from the concentration sensor. According to clause 4,
The control unit is a carbonic acid fertilization device in a crop cultivation facility, characterized in that it controls the separation distance between the discharge pipe and the suction pipe based on the value measured from the concentration sensor. According to clause 5,
Carbonic acid fertilization device in a crop cultivation facility, characterized in that the suction end of the suction pipe is extended or contracted. According to clause 4,
The control unit is a carbonic acid fertilization device in a crop cultivation facility, wherein the control unit controls the angle of the suction end of the suction pipe based on the value measured from the concentration sensor. According to clause 4,
an external pipe connected to the suction pipe into which external air flows; and
Further comprising an opening control valve that controls the opening and closing amount of the external pipe,
The control unit is a carbonic acid fertilization device in a crop cultivation facility, wherein the control unit controls the opening and closing amount of the opening control valve based on the value measured from the concentration sensor. A building equipped with an energy generating device that directly generates the energy needed within the building and an exhaust pipe that discharges exhaust gas discharged from the energy generating device to the outside of the building;
A crop cultivation facility that grows plants by receiving carbon dioxide emitted from the building; and
A carbonic acid fertilization device including a suction pipe that is spaced apart from the discharge pipe in the discharge direction of the exhaust gas and sucks exhaust gas and outdoor air discharged from the discharge pipe to supply carbon dioxide to the inside of the crop cultivation facility, and a blower that sucks air through the suction pipe. Contains,
Carbonic acid fertilization system, characterized in that the concentration of carbon dioxide is controlled by controlling the amount of exhaust gas flowing through the suction pipe by adjusting the separation distance between the discharge pipe and the suction pipe or by adjusting the angle of the suction end of the suction pipe.

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