KR20170087619A - Carbon dioxide supply system for plant cultivation in greenhouse - Google Patents

Abstract

The present invention relates to a multifunctional carbon dioxide and heating gas supply apparatus for a greenhouse,
It is possible to selectively supply heating gas and carbon dioxide simultaneously or separately according to the internal temperature of the greenhouse so that the interior heating and the carbon dioxide concentration of the greenhouse can be maintained at appropriate levels according to the season and so on, To reduce the economic burden of the product and to increase the popularity of the content.
In the process of supplying the heating gas and the carbon dioxide gas together, the heating gas generated from the heating unit is supplied to the inside of the greenhouse. When the temperature of the heating gas generated from the heating unit is lower than the proper temperature, When the temperature of the heating gas is higher than the proper temperature, it automatically detects the temperature of the heating gas and automatically controls whether the heating gas is supplied to the inside of the greenhouse,
It is possible to prevent a harmful component contained in a relatively large amount of heating gas generated at a low combustion temperature from flowing into the greenhouse and automatically control so that only a heating gas generated at a high combustion temperature and having a relatively small amount of harmful components is supplied to the greenhouse, And the quality degradation phenomenon can be prevented.
In addition, since the heating gas generated by the heating unit is supplied to a separate heat exchanger in the greenhouse without being lost as it is, it is discharged into the outside air, so that it is utilized for heating in the greenhouse. This is what you can do.
In the winter, carbon dioxide is supplied indirectly through the heating gas and indirectly heated by the heating gas. As the heating gas is partially transferred through the carbon dioxide supply path and supplied through the individual path, some of the heating gas is directly The rest of the heating gas supplied to the inside of the greenhouse can be indirectly supplied to the inside of the greenhouse without being directly supplied to the inside of the greenhouse, so that the temperature of the inside of the greenhouse can be indirectly increased. This is a way to solve the problems that have arisen.
By forming a plurality of filter portions on the path through which the heating gas is supplied, the harmful components contained in the heating gas are filtered through the filter portion as much as possible, so that the phenomenon that the dust, etc. contained in the heating gas is left on the wall of the heating gas moving duct can be minimized So that the contamination of the inner surface of the mobile duct can be minimized and heat loss can be reduced.
In addition, it is possible to detect and check the carbon dioxide concentration in the greenhouse in real time, and automatically set the appropriate amount of carbon dioxide necessary at that time based on this, so that the carbon dioxide supply amount can be automatically adjusted accordingly,
It is possible to supply appropriate carbon dioxide according to the concentration of carbon dioxide in the corresponding greenhouse at any time, thereby preventing the phenomenon that carbon dioxide is supplied in an insufficient amount or is supplied excessively.
It automatically memorizes the carbon dioxide supply which is different every time zone, and automatically adjusts the carbon dioxide supply according to the supply of sunlight according to the time zone based on this, so that the appropriate amount of carbon dioxide As shown in Fig.
In addition, by checking the humidity and temperature in the greenhouse in real time and automatically adjusting the required amount of carbon dioxide to be supplied, it is possible to supply the correct amount of carbon dioxide in a variety of conditions, It is a content.
In addition, it can check the sunlight amount according to the day's weather in real time, and automatically adjusts and supplies the carbon dioxide supply according to the changed carbon dioxide supply, so that the carbon dioxide supply can be accurately realized in a variety of conditions.
It controls the automatic supply of heating gas according to the temperature of the heating gas, the control of automatic supply of heating gas and carbon dioxide according to the temperature and humidity inside the greenhouse, automatic control of the supply of heating gas and carbon dioxide according to the time, And the automatic control of the supply of carbon dioxide can be wirelessly controlled through the control unit and the Bluetooth transmission / reception unit, so that the structure can be simplified as a whole, making it easy to manufacture and easy to install.

Description

[0001] The present invention relates to a carbon dioxide supply system for plant cultivation in a greenhouse,

The present invention provides an appropriate level of carbon dioxide necessary for growth of a crop in a greenhouse for cultivating crops. In a heating heater for supplying carbon dioxide, the concentration of a harmful component generated during incomplete combustion is detected This prevents carbon dioxide from being supplied to the greenhouse by the incomplete combustion of the fuel when the carbon dioxide is supplied. It also prevents the indoor air pollution by supplying the carbon dioxide generated at the appropriate level of complete combustion. To help crops grow,

It is possible to automatically check the amount of carbon dioxide required for different time zones during the time between the sunrise and the sunset and during nighttime so that the appropriate amount of carbon dioxide can be supplied at the corresponding time point so that the carbon dioxide supply control as a whole can be automatically performed,

It is a technology that maximizes crop cultivation efficiency by detecting real-time atmospheric humidity and temperature by time of day, checking the required amount of carbon dioxide according to it, and controlling automatic supply.

In general, proper growth of crops requires adequate levels of sunlight and moisture as well as adequate levels of carbon dioxide.

Therefore, in the case of a greenhouse where crops are cultivated in an enclosed space outside, separate control of sunlight, moisture and carbon dioxide is necessary.

Particularly, in the case of carbon dioxide, since the amount of carbon dioxide in the greenhouse is rapidly consumed during the process of photosynthesis of the crop in the daytime, it is necessary to control the supply of carbon dioxide at each time of day as well as during the day.

Recently, a supply means for supplying carbon dioxide separately to a greenhouse has been proposed. For example, a carbon dioxide gas generated by evaporating carbon dioxide in a liquid phase is supplied to the atmosphere in a greenhouse. In another form, a separate fuel is burned There is a method in which the generated heating gas is supplied to the inside of the greenhouse so that the carbon dioxide contained in the heating gas is distributed to the atmosphere in the greenhouse.

However, the method of supplying the liquid phase carbon dioxide by evaporation requires handling of the liquid phase carbon dioxide and the conditions for burning it are very difficult, and the equipment for this is inevitably complex and expensive so that it can not be used in general farmhouses.

Since the method of using the carbon dioxide contained in the heating gas by supplying the heating gas of the fuel includes not only the carbon dioxide but also various harmful components generated by burning the fuel in the heating gas generated by the combustion of the fuel,

The method of using the carbon dioxide contained in the heating gas by supplying the unconditional heating gas regardless of the combustion temperature of the combustion gas is as follows. When the combustion temperature of the fuel is low, the concentration of harmful components such as carbon dioxide and carbon monoxide If the heating gas is introduced into the enclosed greenhouse unconditionally, the air quality in the greenhouse becomes very bad, which causes the crop to interfere with the growth of the greenhouse. .

Therefore, since the air in the greenhouse must be ventilated by opening the entrance of the greenhouse from time to time, the ambient temperature in the greenhouse is unnecessarily lowered in the winter season, and a vicious cycle in which the heating gas supply is further increased I can not help it.

This method is suitable only for the winter season when it is necessary to compensate the inside temperature of the greenhouse, but it is basically impossible to use in the summer when the atmospheric temperature is high. Therefore, in the actual farmhouse, such a combustion type carbon dioxide supplying device and a liquid carbon dioxide supplying device And it is necessary to use them in alternating seasons.

In addition, since there is no function of detecting the concentration of harmful components and the concentration of carbon dioxide contained in the heating gas, the heating gas generated regardless of the combustion temperature is supplied unconditionally into the greenhouse.

In addition, there is no function of checking the concentration of carbon dioxide in the greenhouses, and since the time and temperature of the supply of carbon dioxide are set depending on the experience of the operator, it is possible to accurately determine the proper amount of carbon dioxide It is highly possible that acidification of crops will occur due to excessive carbon dioxide supply depending on the case, and an accurate and systematic cultivation system for the cultivation of the crop can not be provided

In addition, since the carbon dioxide in the greenhouse is consumed in the process of photosynthesis for the carbon assimilation, the amount of carbon dioxide supplied depends on the amount of sunlight required for photosynthesis. As a result, the time zone between noon and noon The amount of carbon dioxide required for each time zone during the nighttime between the time zone and the sunset is inevitably wrong.

The amount of carbon dioxide required during the night after sunset is relatively small, and the amount of carbon dioxide required at the time of sunrise and after sunset is very high, and the amount of carbon dioxide required at the time between noon and sunset is slightly lower.

However, in the past, there has not been proposed a structure capable of supplying the necessary amount of carbon dioxide at the same time of day, and since the worker arbitrarily determines the amount of carbon dioxide to be supplied based on experience and the like, the concentration of carbon dioxide in the greenhouse is irregular And thus it is difficult to realize an accurate crop cultivation environment.

In addition, the amount of carbon dioxide required for photosynthesis is set differently depending on the sunlight supplied by the day, the humidity in the greenhouse and the temperature in the greenhouse.

However, in the past, the adjustment of the carbon dioxide supply according to the weather and the humidity and temperature of the greenhouse has been made only by the experience of the operator, and no technology has been proposed to automatically check and adjust the carbon dioxide supply accordingly.

In other words, in the past, only the heating gas is supplied to the inside of the greenhouse to utilize the carbon dioxide contained in the heating gas for the cultivation of the crop. The supply of the heating gas, that is, the supply time and the supply time of the carbon dioxide, Experience and so on, but it does not have any technology that automatically checks the weather and the air condition in the greenhouse, and controls and adjusts the appropriate amount of carbon dioxide supplied accordingly.

Therefore, it is impossible to establish an accurate cultivation environment of crops because the total amount of carbon dioxide to be supplied is not accurate.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art,

First, basically, the heating gas and the carbon dioxide are selectively supplied simultaneously or separately according to the internal temperature of the greenhouse, so that the internal heating and the carbon dioxide concentration in the greenhouse can be maintained at proper levels at all times according to the season and the like. Which can reduce the conventional economic burden due to the necessity to increase the popularity of the product and propose a carbon dioxide supply system for plant cultivation in the greenhouse.

Second, in the process of supplying the heating gas and the carbon dioxide gas, when the heating gas generated from the heating unit is supplied to the inside of the greenhouse, when the temperature of the heating gas generated from the heating unit is lower than the proper temperature, When the temperature of the heating gas is higher than the proper temperature, it automatically detects the temperature of the heating gas to be automatically supplied to the inside of the greenhouse,

It is possible to prevent a harmful component contained in a relatively large amount of heating gas generated at a low combustion temperature from flowing into the greenhouse and automatically control so that only a heating gas generated at a high combustion temperature and having a relatively small amount of harmful components is supplied to the greenhouse, And to prevent the degradation of the quality of the greenhouse.

Third, since the heating gas generated by the heating unit is supplied to a separate heat exchanger in the greenhouse without discharging the gas below the proper temperature, it is discharged to the outside air. As a result, This paper proposes a carbon dioxide supply system for plant cultivation in a greenhouse that enables reduction of CO2 emissions.

Fourth, carbon dioxide is supplied indirectly to the heating gas through a separate path when the carbon dioxide is supplied in the winter season. As the heating gas is partially transferred through the carbon dioxide supply path and supplied through the individual path, some of the heating gas is selectively Directly to the interior of the greenhouse, the rest of the heating gas is not directly supplied to the inside of the greenhouse. Instead, it is supplied to a separate radiator or the like to indirectly raise the temperature of the air inside the greenhouse. Thus, heating gas is supplied unconditionally to the inside of the greenhouse, This paper proposes a carbon dioxide supply system for plant cultivation in a greenhouse to solve the problems that have arisen.

Fifth, since a plurality of filter portions are formed on the path through which the heating gas is supplied, the harmful components contained in the heating gas are filtered through the filter portion as much as possible, thereby minimizing the phenomenon that dust or the like contained in the heating gas is left on the wall of the heating gas moving duct This paper proposes a carbon dioxide supply system for plant cultivation in a greenhouse that can reduce the heat loss by minimizing the contamination of the inner surface of the mobile duct.

Sixth, it is possible to detect and check the carbon dioxide concentration in the greenhouse in real time, and automatically set the appropriate amount of carbon dioxide to be used at that time based on this, so that the carbon dioxide supply amount can be automatically adjusted accordingly,

It suggests a carbon dioxide supply system for plant cultivation in a greenhouse where proper carbon dioxide can be supplied according to the concentration of carbon dioxide in the corresponding greenhouse so that the phenomenon such as insufficient supply or excessive supply of carbon dioxide can be prevented.

Seventh, it automatically memorizes the carbon dioxide supply amount which is different every time zone and automatically adjusts the carbon dioxide supply amount according to the supply level of sunlight according to the time zone on the basis of it, so that the proper amount of carbon dioxide This paper proposes a carbon dioxide supply system for plant cultivation in a greenhouse that can be automatically regulated and supplied.

Eighth, it checks the humidity and temperature in the greenhouse in real time and automatically adjusts the required amount of carbon dioxide to be supplied based on this, so that the amount of carbon dioxide can be supplied in a precise amount under various conditions, We propose a carbon dioxide supply system for growing plants in a greenhouse.

Ninth, it checks the sunlight irradiation amount according to the day's weather in real time and automatically adjusts and supplies the carbon dioxide supply amount according to the changed carbon dioxide supply amount, thereby making it possible to accurately implement the carbon dioxide supply amount according to various conditions. Supply device.

Tenth, control of automatic supply of heating gas according to the temperature of heating gas, control of automatic supply of heating gas and carbon dioxide according to the internal temperature and humidity of the greenhouse, automatic control of supply of heating gas and carbon dioxide according to time, A carbon dioxide supply system for plant cultivation in a greenhouse is provided so that the automatic control of the supply of heating gas and carbon dioxide can be wirelessly controlled through the control unit and the Bluetooth transmission / reception unit, do.

According to the present invention,

A first installation space is formed at a rear side with respect to the first partition, a second installation space is formed at a front side of the first installation space, and a plurality A third partition wall is formed on the rear side of the third installation space and a fourth partition wall is formed on the rear side of the third partition wall, A heating case having an installation space formed at an upper side of the second installation space and a discharge port formed at the upper side of the second installation space, a storage tank having a fuel injection port formed at an upper portion thereof, A fuel storage box located within a first installation space, a second fuel storage box located in a second installation space of the heating case and connected to the fuel storage box through a fuel supply pipe Wherein the ignition means is configured to ignite the fuel discharged from the fuel storage box and supply the fuel discharged from the fuel storage tank along with the fuel supply pipe to generate a flame, And the upper end of the funnel structure is attached and fixed so as to surround the perforations of the second diaphragm, and the lower end of the funnel structure is vertically coaxial with the upper end of the funnel, And the upper and lower lengths thereof are arranged in the third installation space and are provided in the same number as the respective through holes of the second partition wall, A part of which is located in the outlet of the heating case And a plurality of heating gas distribution pipes or hollow tubes in the form of a duct which is drawn out to the outside of the heating case in a state in which the upper end portion is not located in the discharge port and the lower end is positioned at the outlet of the heating case A heating gas supply duct connected to the heating chamber and having an upper end penetrating the greenhouse and a hollow gas duct formed in the interior of the greenhouse and having one end connected to a point between the heating case and the greenhouse among the heating gas supply ducts, And the air discharge induction duct is disposed in a form blocking the connection point between the heating gas supply duct and the air discharge induction duct, It is possible to rotate around the department. A first opening and closing unit for selectively opening and closing the connecting point between the heating gas supply duct and the atmospheric air discharge induction duct so that the heating gas traveling along the heating gas supply duct is selectively introduced into the atmospheric air discharge induction duct only when necessary, A first motor connected to the first opening and closing part to rotate the first opening and closing part, and a plurality of non-woven filters arranged in a staggered fashion at upper and lower positions of the first opening and closing part in the air discharge induction duct, A first auxiliary filter portion passing through the one opening and closing portion to filter out harmful substances such as various dusts contained in the heating gas introduced into the atmospheric air discharge induction duct, a non-woven filter type filter, A plurality of heat exchangers are disposed at positions between the duct and the outlet of the heating case at an interval And a main filter part for filtering the harmful components such as various dusts contained in the heating gas while passing through the exhaust port through the exhaust port, a plate material type, and a point between the first opening and closing part and the greenhouse in the heating gas supply duct Wherein the first opening and closing part is pivoted to open the movement path of the heating gas to open and close the path of the heating gas while the first opening and closing part is blocking the corresponding point, A second opening and closing part for turning off the traveling path of the heating gas so as to block the heating gas from being supplied to the greenhouse, a nonwoven fabric filter, and a second opening and closing part of the heating gas supply duct, And a plurality of second open / close devices A second auxiliary filter portion for filtering harmful substances such as various dusts contained in the heating gas passing through the fishermen, a piping type, and is located in the third installation space, and the lower end portion passes through the front surface of the third installation space of the heating case And the upper portion penetrates the upper end portion of the heating case in a state of being formed into a coil shape in which the heating gas distribution pipe is wound around the heating gas distribution pipe in a spiral shape as a whole and the second auxiliary filter portion and the second opening / A carbon dioxide supply pipe which is connected to a point between the carbon dioxide supply pipe and the carbon dioxide supply pipe to supply external air containing carbon dioxide to the heating gas supply duct, And the carbon dioxide contained in the outside air is absorbed by the above- And a second Bluetooth transmitting / receiving unit, wherein the first motor and the second Bluetooth transmitting / receiving unit are located in a fourth installation space of the heating case and are wirelessly connected to the intake unit through the first Bluetooth transmitting / A control unit which is connected to the second motor via a second Bluetooth transmission / reception unit, a control unit which is located in a second installation space of the heating case, and is wirelessly connected to the control unit through a fourth Bluetooth transmission / reception unit, The temperature of the heating gas distribution pipe in the state of being connected to the surface of the heating gas distribution pipe located in the outlet of the heating case is checked in real time to determine whether the heating gas temperature inside the heating gas distribution pipe is an appropriate level temperature, Signal to the control unit, the corresponding temperature is lower than the proper level When the right control unit sends an operation signal to the first motor via the second Bluetooth transmitting and receiving unit, the first opening and closing unit is rotated by the first motor to open the inlet of the atmospheric air discharge induction duct, and at the same time, So that the heating gas discharged through the heating case outlet can not be supplied to the greenhouse and is guided to be discharged to the outside through the air discharge induction duct. When the temperature of the heating gas distribution pipe is at an appropriate level, The first opening and closing part closes the inlet of the atmospheric emission inducing duct, whereas when the control part sends an operation signal to the second motor via the second Bluetooth transmitting and receiving part, the second opening and closing part is rotated by the second motor, So that the heating gas is moved to the greenhouse through the second opening and closing part A temperature sensor for detecting the temperature of the room gas, a wireless communication unit connected to the control unit through a fifth Bluetooth transceiver unit located in the inner space of the greenhouse, and sensing the temperature and humidity of the greenhouse in real time and transmitting the temperature and humidity to the control unit. If the control unit sends an operation signal to the intake unit through the first Bluetooth transmission / reception unit, the intake unit is activated so that the outside air and the carbon dioxide contained in the air are supplied to the inside of the greenhouse through the carbon dioxide supply pipe and the heating gas supply duct The control unit stops the operation of the intake unit to automatically supply the outside air and the carbon dioxide contained in the outside air when the temperature and the humidity are appropriate, In the state of being located within the installation space, A time zone between the sunrise time and the noon time point, a time zone between the noon time point and the sunset time, and a time zone between the sunset time and the sunrise time after the sunset so as to give a signal to the control unit every predetermined time, A timer sensor for automatically activating the ignition unit to supply the heating gas and the carbon dioxide contained in the outside air to the inside of the greenhouse at the time point, and a timer sensor located inside the greenhouse and wirelessly connected to the control unit through a separate sixth Bluetooth transceiver Wherein the control unit detects an illuminance of sunlight irradiated inside the greenhouse in real time and transmits the detection signal to the control unit. When the control unit transmits an operation signal to the intake unit, Carbon dioxide passes through the carbon dioxide supply pipe A green light sensor for detecting a concentration of carbon dioxide contained in the greenhouse air, and a controller for detecting the concentration of carbon dioxide contained in the greenhouse air in real time When the control unit transmits an operation signal to the intake unit when the concentration of carbon dioxide is less than an appropriate level as the detection signal is transmitted to the normal control unit, external air is automatically supplied to the inside of the greenhouse through the carbon dioxide supply pipe by the intake unit A carbon dioxide concentration sensor for allowing the carbon dioxide contained in the outside air to be supplied to the inside of the greenhouse, and an upper end of each of the heating gas distribution pipes is drawn out of the heating case without being present in the outlet of the heating caseA radiator connected to the heating gas distribution pipe and partially heated by the heating gas distribution pipe to flow into the radiator and indirectly heating the air in the greenhouse to raise the temperature, and in a state where one end is connected to the other side of the radiator And the other end is connected to the first installation space of the heating case so that the heating gas that has passed through the radiator flows into the second installation space again and flows into each heating gas distribution pipe located inside the heating case again And a heating gas circulation pipe for circulating the heating gas.

According to the present invention,

First, since the heating gas and the carbon dioxide can be supplied simultaneously or individually in one heating case, the structure for heating and carbon dioxide supply inside the greenhouse can be simplified, the economic effect can be obtained, and the popularity of the product can be improved have.

Second, as the temperature of the heating gas is detected in real time by the heating gas temperature sensor during the process of generating the heating gas by burning the fuel in the heating case, it is judged that the fuel is incompletely burned when the temperature is lower than the proper level The first opening / closing part and the second opening / closing part are operated through the control part so that the heating gas is discharged to the outside through the air discharge induction duct without being supplied to the greenhouse during the movement of the heating gas through the heating gas supply duct,

On the contrary, when the temperature of the heating gas measured by the heating gas temperature sensor is at an appropriate level, it is determined that the fuel is burned in a state close to complete combustion, and at the same time, the control unit operates the first opening and closing part and the second opening and closing part, As the heating gas in a state of low content is automatically introduced into the greenhouse through the main gas supply duct,

It is possible to prevent the harmful components contained in the heating gas generated by the incomplete combustion from being introduced into the greenhouse, thereby minimizing the air pollution inside the greenhouse, preventing the health deterioration of the workers, preventing the occurrence of obstacles to the growth of the crops, It is possible to prevent the heating efficiency from being lowered due to the ventilation inside the greenhouse.

Third, since the heating gas generated from the heating unit is directly supplied to the greenhouse through each heating gas distribution pipe, and a part of the heating gas is separately supplied to the radiator, all the heating gas is directly supplied to the inside of the greenhouse. The temperature of the radiator can be prevented from being excessively increased by controlling the temperature of the radiator as the heating is indirectly performed by exchanging heat with the air inside the greenhouse through the radiator.

In addition, the heating gas, which has passed through the radiator and is heat-exchanged with the air in the greenhouse, is supplied into the first installation space of the heating case through the circulation circulation tube and is heated again after being heated. Thus, heating efficiency of the heating gas is improved, The heating efficiency is improved.

Fourthly, since the carbon dioxide supply pipe is arranged in a spiral form surrounding the respective heating gas distribution pipes, the external air introduced into the carbon dioxide supply pipe through the intake unit is indirectly heated and supplied by the heat of the heating gas distribution pipe Therefore, even if the amount of the heating gas supplied to the radiator is increased, the heated outside air is directly supplied to the interior of the greenhouse to some extent, so that the proper heating efficiency inside the greenhouse can be sufficiently maintained during the carbon dioxide supply process.

In particular, since the carbon dioxide supply pipe surrounds the heating gas distribution pipe in the form of a spiral, the heat and heat exchange time generated from each heating gas distribution pipe during the passage of the external air through the carbon dioxide supply pipe are much increased, In the course of supplying the carbon dioxide contained in the greenhouse, the outside air can be supplied to the greenhouse with sufficient heating.

Fifth, since the main filter portion and the second auxiliary filter portion are formed in the heating gas supply duct, harmful components such as various dusts contained in the heating gas supplied to the greenhouse through the heating gas supply duct can be supplied in a filtered state, It is possible to minimize the air quality degradation phenomenon,

Since the first auxiliary filter unit is installed inside the atmospheric air discharge induction duct, when the heating gas generated in the incomplete combustion state of the fuel is discharged to the outside air through the air discharge induction duct, the harmful components contained in the heating gas are filtered So that air pollution can be minimized.

Sixth, the carbon dioxide concentration sensor checks the concentration of carbon dioxide inside the greenhouse in real time, and when the concentration of carbon dioxide is less than the proper level, the intake part is operated through the control part so that the outside air is supplied automatically so that the carbon dioxide contained in the outside air The automatic supply of carbon dioxide can be controlled according to the internal environment of the greenhouse, so that the concentration of carbon dioxide in the greenhouse can be maintained at an appropriate level at all times.

Seventh, by allowing the outside air to flow into the inside of the greenhouse every time set by the timer sensor, the carbon dioxide contained in the outside air is supplied, so that the optimum level of carbon dioxide is automatically controlled at the time when the photosynthesis of the crop is actively performed, So that the concentration of carbon dioxide in the greenhouse can be maintained at an appropriate level at all times.

Eighth, the temperature and humidity sensor senses the humidity and temperature in the greenhouse in real time, and if the temperature and humidity are below appropriate levels, the outside air is supplied to the inside of the greenhouse through the control unit and the intake unit so that the carbon dioxide contained in the outside air can be used So that the concentration of carbon dioxide in the greenhouse can be maintained at an appropriate level at all times.

Ninth, the illuminance sensor senses the illuminance of the sunlight irradiated into the greenhouse in real time, and when the illuminance is lower than the proper level, the outside air is automatically supplied through the control unit and the intake unit, and carbon dioxide contained in the outside air can be used The concentration of carbon dioxide can always be maintained at an appropriate level in accordance with the environment in the greenhouse.

The control unit is wirelessly connected to the intake unit, the first motor, the second motor, the ignition unit, the temperature / humidity sensor, the carbon dioxide concentration sensor, and the illuminance sensor via the first Bluetooth transmitting / receiving unit through the seventh Bluetooth transmitting / Control of automatic supply of heating gas according to temperature of gas, control of automatic supply of heating gas and carbon dioxide according to temperature and humidity inside the greenhouse, automatic control of supply of heating gas and carbon dioxide according to the time of day and heating gas and carbon dioxide It is possible to simplify the manufacturing and minimize the occurrence of the failure since the electric wiring is minimized during manufacture.

1 is a conceptual diagram illustrating a control connection structure between a control unit and each component;
2 is a schematic view showing the entire structure
Figure 3 is a partially enlarged schematic view of Figure 2
FIG. 4 is a schematic view showing a state in which a heating gas containing a large amount of harmful components is introduced into an air discharge induction duct
5 is a schematic view showing a state in which a normal heating gas passes through a main gas supply duct

Hereinafter, the present invention will be described more specifically based on the drawings.

1 to 5, the carbon dioxide supply system for plant cultivation in a greenhouse according to the present invention includes a heating case 2, a fuel storage box 12, an ignition part 14, a heat induction piece 15, The main gas supply duct 17, the atmospheric air discharge induction duct 18, the main filter unit 22, the first opening / closing unit 19, the first motor 20, The second motor 24, the second auxiliary filter 25, the intake unit 27, the carbon dioxide supply pipe 26, the control unit 28, the first Bluetooth transmitter / receiver unit 21, the second switch unit 23, The second Bluetooth transmitting and receiving unit 30, the third Bluetooth transmitting and receiving unit 31, the heating gas temperature sensor 32, the fourth Bluetooth transmitting and receiving unit 33, the temperature and humidity sensor 34, A timer sensor 36, an illumination sensor 37, a sixth Bluetooth transceiver 38, a carbon dioxide concentration sensor 39, a seventh Bluetooth transceiver 40, a radiator 41, And a gas circulation pipe (42).

First, the heating case 2 functions to generate a heating gas for supplying the inside of the greenhouse 1 and to introduce outside air into the heating chamber 2, Castors and the like may be installed.

A first partition wall 7 is formed at a lower midpoint inside the heating case 2 and a first installation space 3 for installing a fuel storage box 12 to be described later is provided at a rear side of the first partition wall 7, And a second installation space 4 is formed on the front side of the first installation space 3 with respect to the first partition 7 in such a manner that the ignition part 14 is installed and the fuel is burned.

A second partition wall 8 having a plurality of through holes 9 arranged in a spaced relation is formed in the upper part of the second installation space 4 and a second installation space 4 A third installation space 5 for installing a heating gas distribution pipe 16 and a carbon dioxide supply pipe 26 to be described later is formed on the upper side and a third partition 10 is formed on the rear side of the third installation space 5 And a fourth installation space in which a control unit 28, which will be described later, as well as various electric circuit devices and the like are installed, is formed on the rear side of the third partition 10.

In this heating case 2, a fuel storage box 12 is provided.

The fuel storage box 12 serves to store the fuel for generating the heating gas and supply the fuel to the ignition part 14 described later. The fuel storage box 12 is in the form of a storage tank in which four sides are closed and a fuel injection port is formed in the upper part. Is filled with fuel for combustion.

At this time, on the front side of the fuel storage box 12, a fuel supply pipe 13 for supplying the fuel in the fuel storage box 12 to the ignition part 14 to be described later is extended toward the front side and the fuel supply pipe 13 is extended forward And the end portion is located in the second installation space (4) in a state of passing through the first partition (7).

In this state, the ignition portion is provided in the second installation space (4).

The ignition unit 14 generates the heating gas substantially by burning the fuel in the fuel storage box 12 and performs the function of heating the carbon dioxide. The ignition unit 14 instantaneously generates sparks instantaneously using general electricity, ignites the fuel, And is located in the second installation space (4) of the heat case (2).

Therefore, when the fuel in the fuel storage box 12 is first supplied to the ignition part 14 and ignited at the same time, the flame is formed to face the second installation space 4, And is raised upwardly at the same time as it is generated.

In this state, the heat induction piece 15 is formed in the second installation space 4.

The heat induction piece 15 is for guiding the flame and the heating gas generated on the ignition part 14 to be concentrated as much as possible upwards without spreading in all directions and to be concentratedly introduced into a heating gas distribution pipe 16 to be described later. The upper part of the second partition wall 8 is fixed to the lower surface of the second partition wall 8 in such a manner as to surround the periphery of the through hole 9 of the second partition wall 8, The flame and the heating gas generated in the ignition part 14 are generated and at the same time they are raised upward in the heat induction piece 15 and are concentratedly introduced into the respective through holes 9 do.

In this state, the second partition wall 8 is provided with a heating gas distribution pipe 16.

The heating gas distribution pipe 16 supplies the heating gas generated in the heating induction piece 15 directly to the inside of the greenhouse 1 or to a separate heating device such as a radiator 41 located in the greenhouse 1 (9) of the second partition (8), and the second partition (8) is provided in the third installation space (5) And the lower end portions are formed to extend upward in a state in which they are inserted into the respective through holes 9.

At this time, in some of the heating gas distribution pipes 16, the upper end portion is located in the upper outlet 11 of the heating case 2, and the remaining heating gas distribution pipe 16 is located in the heating case 2) is connected to a heating device such as a radiator 41 which is drawn out to the outside and is located inside the greenhouse 1,

A part of the heating gas is discharged through the discharge port 11 of the heating case 2 and moves along the main gas supply duct 17 to be directly supplied into the greenhouse 1, And is supplied to the radiator 41. [0064]

In this state, the heating case 2 is provided with the main gas supply duct 17.

The main gas supply duct 17 serves as a movement path of the heating gas discharged from the heating gas distribution pipe 16 for directly sending the heating gas into the greenhouse 1 and a heating gas And also functions to control the heating gas supply such as discharging it to the outside,

A duct having a hollow tube shape and having a lower end connected to the outlet 11 of the heating case 2 in a state of being positioned on the upper side outside the heating case 2 and an upper end passing through the greenhouse 1, .

An air discharge induction duct 18 is connected to the main gas supply duct 17.

When the fuel is not burned at a sufficiently high temperature in the process of burning the fuel on the ignition part 14 and generating the heated gas, the concentration of harmful components such as carbon monoxide is relatively high in the generated heated gas. When the heated gas is directly supplied to the air in the greenhouse 1 through the main gas supply duct 17, the air inside the greenhouse is deteriorated,

The air discharge induction duct 18 serves as a path for discharging the heated gas to the outside air before being supplied into the greenhouse 1 in the process of moving along the main gas supply duct 17 with a high content of harmful components However,

Like the main gas supply duct 17, is connected in such a manner that one end of the main gas supply duct 17 is connected to the point between the heat case 2 and the greenhouse 1 among the main gas supply ducts 17.

Therefore, the heating gas generated in the incomplete combustion state of the fuel flows along the main gas supply duct 17 and flows into the air discharge induction duct 18 by the first opening and closing part 19 and the second opening and closing part 23, And is discharged to the outside and is destroyed.

In this state, the first opening and closing part 19 is provided in the air discharge induction duct 18.

The first opening and closing part 19 adjusts the movement path of the heating gas generated by the incomplete combustion of the fuel and moves along the main gas supply duct 17 to move the air discharge induction duct 18 without moving toward the greenhouse 1, And guiding the gas to flow smoothly into the greenhouse by blocking the flow of the normal heating gas into the air discharge induction duct 18,

And is disposed in the form of a plate member and intercepts a connection point between the main gas supply duct 17 and the atmospheric ventilation induction duct 18. The main gas supply duct 17 and the air discharge induction duct 18 18) of the main gas supply duct, the heating gas flowing along the main gas supply duct is selectively introduced into the atmospheric air discharge induction duct (18).

The first opening and closing part 19 has a structure in which the hinge part is connected to the first motor 20 so that the entire first opening and closing part 19 is rotated by the driving force of the first motor 20.

In this state, the first auxiliary filter unit 21 is installed in the air discharge induction duct 18.

The first auxiliary filter unit 21 functions as a dust collecting filter for filtering dust and the like contained in the heating gas passing through the atmospheric air discharge induction duct 18. The first auxiliary filter unit 21 is a nonwoven filter type filter, A plurality of zigzags are arranged at upper and lower positions on the first opening and closing part 19 and a harmful component such as dust contained in the heating gas flowing into the atmospheric air discharge induction duct 18 through the first opening and closing part 19 is filtered .

At this time, since the first sub filter unit 21 is arranged in a zigzag fashion as shown in the drawing, the heating gas moves in a zigzag form in the course of passing through the first sub filter unit 21, The contact ratio between the heating gas 21 and the heating gas is also improved, so that the effect of collecting the heating gas is further improved.

In this state, the main gas supply duct (17) is provided with the main filter unit (22).

The main filter unit 22 functions to primarily filter out harmful components such as dust contained in the heating gas moving along the main gas supply duct 17 and is a nonwoven filter type filter, 17 are disposed at a position between the atmospheric air discharge induction duct 18 and the discharge port of the heating case 2 with a distance therebetween.

Accordingly, the heating gas discharged through the discharge port 11 sequentially passes through each of the main filter portions 22, so that harmful components such as various dusts contained in the heating gas are filtered out.

At this time, the main filter portions 22 are also arranged in a zigzag fashion as shown in the figure, so that the heating gas moves in a zigzag fashion in the process of passing through each main filter portion 22, The contact ratio between the heating gases is also improved, so that the filtering effect of the heating gas is further improved.

In this state, the main gas supply duct 17 is further provided with a second opening and closing part 23.

The second opening / closing part 23 serves to induce the heating gas, which is normally burned in the fuel so that the content of the harmful components is small, to be normally supplied along the main gas supply duct 17 and supplied to the inside of the greenhouse. On the contrary, In the case of a high heating gas, the main gas supply duct 17 is blocked from passing therethrough and guided to the air discharge induction duct 18,

Like shape as the first opening and closing part 19 and is located inside the main gas supply duct 17 so as to block the point between the first opening and closing part 19 and the greenhouse 1 but is rotatable about the hinge part, And opens and closes the movement path of the heating gas.

Therefore, when the first opening and closing part 19 is closed, the traveling path of the heating gas is opened and the first opening and closing part 19 is rotated to open the inlet of the atmospheric air discharge induction duct 18, So that the heating gas is prevented from being supplied to the greenhouse 1.

In this state, the second auxiliary filter unit 25 is installed in the main gas supply duct 17.

The second auxiliary filter unit 25 functions to filter the harmful components such as dust and the like by secondly filtering the heating gas immediately before being supplied into the greenhouse 1 through the second opening and closing unit 23,

Like filter such as the first auxiliary filter unit 21 and a plurality of the main gas supply ducts 17 are disposed at a position between the second opening and closing unit 23 and the greenhouse at a distance in the fore and aft direction and the second opening and closing control unit 28, Such as various kinds of dusts contained in the heated gas passing through the filter.

At this time, the second auxiliary filter unit 25 is also arranged in a vertically zigzag manner as shown in the figure, so that the heating gas is moved in a zigzag form in the process of passing through each second auxiliary filter unit 25, The contact ratio between the portion 25 and the heated gas is also improved, so that the filtering effect of the heated gas is further improved.

In this state, the carbon dioxide supply pipe 26 is further provided in the heating case 2.

The carbon dioxide supply pipe 26 serves as a path for the carbon dioxide to sufficiently supply the carbon dioxide necessary for growth of the crop to the air inside the greenhouse. The carbon dioxide supply pipe 26 is entirely in the form of a pipe and is located in the third installation space 5, And a coil shape in which the entire periphery of the heating gas distribution pipe 16 is wound in a spiral form in a state of being exposed to the outside through the front surface of the third installation space 5 of the heater 2.

In this state, the upper end passes through the upper end of the heating case 2 and is connected to a point between the second auxiliary filter portion 25 and the second opening / closing portion 23 of the main gas supply duct to communicate with the outside air containing carbon dioxide To the main gas supply duct (17).

That is, the carbon dioxide moving through the carbon dioxide supply pipe 26 flows into the main gas supply duct 17 through a path different from the heating gas.

In this state, the carbon dioxide supply pipe 26 is further provided with an intake unit 27.

The intake unit 27 forcibly introduces the outside air into the carbon dioxide supply pipe 26 so that the outside air moves along the carbon dioxide supply pipe 26 and supplies the outside air to the inside of the greenhouse 1 so that the carbon dioxide contained in the outside air flows into the greenhouse 1) to be used internally, having a substantial carbon dioxide supply function,

And has a structure in which the external air is forcibly drawn into the carbon dioxide supply pipe 26 while being in the form of a general intake fan and connected to the front end of the carbon dioxide supply pipe 26.

Therefore, in the process of supplying outside air to the inside of the greenhouse, the carbon dioxide contained in the outside air is also distributed in the air inside the greenhouse.

In this state, the heating case 2 is further provided with a control unit 28. [

The control unit 28 functions as an automatic supply control of the heating gas and an automatic supply control of the carbon dioxide and is formed in a general microcomputer form and is located in the fourth installation space 6 of the heating case 2.

The control unit is connected to the intake unit 27, the first motor 20, the second motor 24, and various sensors described below to integrally control the operation of the components.

At this time, the control unit 28 is wirelessly connected to the intake unit 27 through a separate first Bluetooth transceiver unit 29.

For reference, the Bluetooth transceiver is a technology used for wireless connection between various electronic devices such as mobile phones, and transmits / receives operating signals to / from each other wirelessly by mutually transmitting / receiving specific frequencies.

In the present invention, the control unit and each component are mutually wirelessly connected to each other using a Bluetooth transmission / reception unit so that mutual operation control signals are transmitted and received.

The control unit 28 is wirelessly connected to the first motor 20 of the first opening and closing unit 19 through the second Bluetooth transmitting and receiving unit 30 and the second motor 24 of the second opening and closing unit 23, The operation of the intake unit 27 and the operation of the first motor 20 and the second motor 24 can be performed wirelessly by the wireless transmitting / receiving unit 31, .

In this state, the heating case 2 is provided with a heating gas temperature sensor 32.

The heating gas temperature sensor 32 senses the temperature of the heating gas in real time during the passage of the heating gas generated by the ignition unit through each heating gas distribution pipe 16 and detects the temperature of the heating gas at an appropriate level By knowing whether the heating gas is caused by the incomplete combustion of the fuel or by burning in a state close to the complete combustion,

And is wirelessly connected to the control unit 28 through a fourth Bluetooth transmitting / receiving unit 33, which is located in the third installation space 5 of the heating case 2.

In this state, the heating gas temperature sensor 32 is connected to the surface of the heating gas distribution pipe 16 located at the outlet 11 of the heating case 2, The temperature of the surface of the gas distribution pipe 16 is checked in real time and it is determined whether the temperature of the heating gas inside the heating gas distribution pipe 16 is an appropriate level and then the determination signal is transmitted to the control unit 28 .

Accordingly, when the temperature is less than the proper level, the control unit 28 determines that the corresponding heating gas is generated due to incomplete combustion of the fuel, and that the content of harmful components such as various dusts and carbon monoxide is high. At the same time, the second Bluetooth transmitting / To the first motor (20).

The first opening and closing part 19 is rotated by the first motor 20 to open the inlet of the air discharge induction duct 18 and the second opening and closing part 23 blocks the inside of the main gas supply duct 17 The heating gas passing through the discharge port 11 of the heating case 2 can not be supplied to the greenhouse 1 and is guided to be discharged to the outside through the air discharge induction duct 18. [

On the contrary, when the temperature of the heating gas distribution pipe 16 is at an appropriate level, the control unit 28 determines that the content of the harmful component is appropriate level by burning the heating gas in a state close to the complete combustion of the fuel, The opening and closing part 19 closes the inlet of the atmospheric ventilation induction duct 18 while an operation signal is sent to the second motor 24 through the third Bluetooth transmitting and receiving part 31 to be closed by the second motor 24, (23) is turned and the inside of the main gas supply duct (17) is opened so that the heated gas passes through the second opening and closing part (23) and moves into the greenhouse (1).

By detecting the temperature of the heating gas distribution pipe 16, the content of the harmful components contained in the heating gas is automatically determined, and the heating gas is supplied to the inside of the greenhouse 1, So that the air quality inside the greenhouse can be prevented from being lowered due to irrelevant supply of the heating gas.

In this state, a temperature / humidity sensor 34 is installed inside the greenhouse 1.

The temperature and humidity sensor 34 checks the temperature and humidity of the inside of the greenhouse 1 in real time and the control unit determines the amount of carbon dioxide required for the greenhouse according to the temperature and the humidity to automatically control the operation of the intake unit 27 In addition,

And is connected to the control unit 28 through a fifth Bluetooth transmitting / receiving unit 35. The temperature and humidity inside the greenhouse 1 are controlled in real time And transmits the detection result to the control unit 28.

If it is determined that additional supply of carbon dioxide in the greenhouse is required because the temperature and the humidity do not reach an appropriate level, the control unit 28 sends an operation signal to the intake unit 27 through the first Bluetooth transmission / So that the carbon dioxide contained in the outside air and the outside air is automatically supplied to the inside of the greenhouse through the carbon dioxide supply pipe 26 and the main gas supply duct 17. [

On the contrary, when it is determined that the temperature and the humidity are at an appropriate level and the additional supply of carbon dioxide is not necessary, the control unit 28 stops the operation of the intake unit 27 so that the supply of the carbon dioxide contained in the outside air and the outside air It has a structure to induce the automatic shut-off.

In this state, a timer sensor 36 is further connected to the control unit 28.

The timer sensor 36 functions to induce automatic supply and cutoff of carbon dioxide contained in the outside air and the outside air in each time zone. The timer sensor 36 is formed as a general electronic timer, And is electrically connected to the control unit 28. [

At this time, since the timer sensor 36 is located near the control unit 28, the timer sensor 36 selects a wireless connection using Bluetooth or a wired connection to be connected to the controller.

Accordingly, the timer sensor 36 divides the time zone between the sunrise time and the noon time point, the time zone between the noon time point and the sunset time, and the time point between the sunset time and the sunrise, And the control unit 28 automatically operates the intake unit 27 and the ignition unit 14 to automatically supply the heating gas and the carbon dioxide contained in the outside air to the inside of the greenhouse at that time.

In this state, the greenhouse 1 is further provided with an illuminance detection sensor 37.

The illuminance sensor 37 checks the illuminance of sunlight irradiated into the greenhouse 1 in real time and transmits the signal to the control unit 28 so that the control unit predicts the degree of photosynthesis of the crop according to the illuminance, It is judged whether or not the carbon dioxide is additionally supplied and the carbon dioxide is supplied automatically.

And is connected to the control unit 28 through a separate sixth Bluetooth transmitting / receiving unit 38. The first and second Bluetooth transmitting / Detects the illuminance in real time, and transmits the detection signal to the controller 28.

Therefore, when the illuminance of the sunlight exceeds a proper level, it is determined that the photosynthesis of the crop is actively performed and the consumption of carbon dioxide is actively consumed by the crop, so that the control unit 28 transmits an operation signal to the intake unit 27 Carbon dioxide contained in the outside air and the outside air is automatically supplied to the interior of the greenhouse through the carbon dioxide supply pipe 26 by the intake unit 27.

In this state, the carbon dioxide concentration sensor 39 is further installed in the greenhouse 1. [

The carbon dioxide concentration sensor 39 checks the concentration of carbon dioxide contained in the greenhouse 1 in real time and transmits the signal to the controller 28 so that the carbon dioxide is automatically supplied when the concentration of carbon dioxide is less than a proper level In this case,

A sensor for checking the carbon dioxide concentration contained in the air and is located inside the greenhouse 1 and is wirelessly connected to the control unit 28 through a separate seventh Bluetooth transceiver 40 and is connected to the inside air of the greenhouse 1 And detects the concentration of carbon dioxide in real time and transmits the detection signal to the control unit 28. [

Therefore, if the control unit transmits an operation signal to the intake unit 27 when the concentration of carbon dioxide in the greenhouse 1 is less than an appropriate level, the outside air is automatically introduced into the greenhouse 1 through the carbon dioxide supply pipe 26 by the intake unit 27, So that the carbon dioxide contained in the outside air is automatically supplied to the inside of the greenhouse 1.

The heating gas circulation pipe 42 is connected to the radiator 41 through the heating gas distribution pipe 16. The heating gas circulation pipe 42 is connected to the radiator 41, The heating gas that has undergone the heating function of the air inside the greenhouse is heat-exchanged with the inside of the greenhouse from the inside of the radiator 41, passes through the radiator 41, and then passes through the heating gas circulation pipe 42, 2 is supplied again into the installation space 4, heated by the new heating gas, and then introduced into the heating gas distribution pipe to be reused.

As a result, the heating gas, which always has a certain warmth, is not lost and can be reused, so that the energy saving effect can be enhanced.

1: greenhouse 2: heating case
3: first installation space 4: second installation space
5: Third installation space 6: Fourth installation space
7: first partition 8: second partition
9: through hole 10: third partition
11: Outlet 12: Fuel storage box
13: fuel supply pipe 14: ignition part
15: heat induction piece 16: heating gas distribution pipe
17: main gas supply duct 18: air discharge induction duct
19: first opening and closing part 20: first motor
21: first auxiliary filter unit 22: main filter unit
23: second opening and closing part 24: second motor
25: second auxiliary filter unit 26: carbon dioxide supply pipe
27: intake unit 28: control unit
29: first Bluetooth transmitting / receiving unit 30: second Bluetooth transmitting /
31: Third Bluetooth transmitting / receiving unit 32: Heating gas temperature sensor
33: fourth Bluetooth transceiver 34: temperature / humidity sensor
35: fifth Bluetooth transceiver 36: timer sensor
37: illuminance sensor 38: sixth Bluetooth transmitter / receiver
39: carbon dioxide concentration sensor 40: seventh Bluetooth transceiver
41: Radiator 42: Heating gas circulation tube

Claims (1)

A first installation space is formed at a rear side with respect to the first partition, a second installation space is formed at a front side of the first installation space, and a plurality A third partition wall is formed on the rear side of the third installation space and a fourth partition wall is formed on the rear side of the third partition wall, A heating case having an installation space formed therein and a discharge port formed above the second installation space,
A fuel storage tank in which a fuel filling port is formed at a top portion of the fuel tank, a fuel tank for storing combustion liquid fuel in the tank tank, and a fuel storage tank located in a first installation space of the heating tank.
An ignition part which is located in a second installation space of the heating case and is connected to the fuel storage box through a fuel supply pipe and is supplied with the fuel discharged from the fuel storage box along the fuel supply pipe and is ignited to generate a flame,
A first partition wall extending downward from the lower surface of the second partition and having a top end opening and a diameter increasing from an upper end to a lower end of the second installation space, And a lower end portion of which is attached and fixed so as to surround the upper end portion,
And a plurality of through holes formed in the third installation space and having the same number as the respective through holes of the second partition, the lower ends of the first and second partition walls being upwardly inserted into the respective through holes, A plurality of heating gas distribution pipes, each having an upper end located in an outlet of the heating case and a part of which is drawn out of the heating case in a state in which the upper end is not located in the outlet,
A heating gas supply duct in which a lower end portion is connected to an outlet of the heating case and an upper end portion is located inside the greenhouse through a greenhouse in a state of being in the form of a hollow tube,
The duct is connected to the heating gas supply duct to communicate with the heating case and the greenhouse so as to selectively block the movement of the heating gas moving through the heating gas supply duct, Air induction induction ducts to induce,
And a connecting point between the heating gas supply duct and the atmospheric ventilation induction duct is opened and closed by rotating the connecting point between the heating gas supply duct and the atmospheric ventilation induction duct during the turning process, A first opening and closing part for selectively controlling the heating gas moving along the heating gas supply duct to be introduced into the atmospheric air discharge induction duct only at a necessary time,
A first motor connected to the first opening and closing part to rotate the first opening and closing part,
And a plurality of air ducts arranged in a staggered manner at upper and lower portions of the interior of the air discharge induction ducts at upper and lower portions of the air discharge induction ducts. The air flows into the atmospheric air discharge induction duct through the first opening / A first auxiliary filter unit for filtering harmful substances such as various dusts,
Wherein the plurality of heating gas supply ducts are disposed at a position between the atmospheric ventilation induction duct and the outlet of the heating case in the front and rear of the heating gas supply duct, A main filter unit for filtering harmful substances such as various dusts,
Wherein the first opening / closing part is located at a position between the first opening and closing part and the greenhouse, and is rotatable around the hinge part in the heating gas supply duct, The first opening / closing unit is rotated to shut off the traveling path of the heating gas to block the supply of the heating gas to the greenhouse, 2 opening / closing part,
And a plurality of dust collecting ducts disposed in a space between the second opening and closing part and the greenhouse and spaced apart from each other at the front and rear of the heating gas supply duct, A second auxiliary filter unit for filtering the first auxiliary filter unit,
In a state of being in the form of a pipe which is in the form of a pipe and which is located in the third installation space and whose lower end is exposed to the outside through the front side of the third installation space of the heating case and which spirally surrounds the heating gas distribution pipe as a whole And an upper end portion of the heating gas supply duct is connected to a portion between the second auxiliary filter portion and the second opening / closing portion of the heating gas supply duct through the upper end portion of the heating case upper end portion to supply the outside air containing carbon dioxide to the heating gas supply duct. ,
An intake unit attached to the outside surface of the heating case and connected to the lower end of the heating case of the carbon dioxide supply pipe to draw in outside air to force carbon dioxide contained in the outside air into the carbon dioxide supply pipe,
The first motor is connected to the first motor via a second Bluetooth transmission / reception unit. The second motor is connected to the second motor via a second Bluetooth transmission / reception unit. A wirelessly connected control unit,
And the upper portion of each of the heating gas distribution pipes is located on the surface of the heating gas distribution pipe located in the outlet of the heating case, the upper portion of each of the heating gas distribution pipes being located in the second installation space of the heating case, wirelessly connected to the control unit through a separate fourth Bluetooth transmission / The temperature of the heating gas distribution pipe in the connected state is checked in real time to determine whether the temperature of the heating gas inside the heating gas distribution pipe is an appropriate level, and when the corresponding temperature is less than a proper level When the control unit sends an operation signal to the first motor through the second Bluetooth transmitting and receiving unit, the first opening and closing unit is rotated by the first motor to open the air discharge induction duct inlet, and the second opening and closing unit is connected to the heating gas supply duct So as to maintain the state of blocking the inside, The control unit controls the first opening / closing unit to block the inlet of the atmospheric discharge induction duct when the temperature of the heating gas distribution pipe is at an appropriate level, while the control unit prevents the heating gas to be discharged to the outside through the atmospheric discharge induction duct without being supplied to the greenhouse. The second opening and closing part is rotated by the second motor to open the inside of the heating gas supply duct so that the heating gas is moved to the greenhouse through the second opening and closing part by the second motor, Heating gas temperature sensor for induction,
The control unit is wirelessly connected to the control unit via a separate fifth Bluetooth transceiver unit and detects the temperature and humidity of the corresponding greenhouse in real time and transmits the sensed temperature and humidity to the control unit. When the temperature and humidity are less than appropriate levels, Transmits the operation signal to the intake unit through the first Bluetooth transmission / reception unit, the intake unit is operated to automatically supply the outside air and the carbon dioxide contained in the air to the inside of the greenhouse through the carbon dioxide supply pipe and the heating gas supply duct, When the temperature and the humidity are at an appropriate level, the control unit stops the operation of the intake unit to induce automatic supply of the carbon dioxide contained in the outside air and the outside air,
A time zone between the sunrise time and the noon time point, a time zone between the noon time point and the sunset time, and a time zone between the sunset time and the sunset time, The control unit automatically activates the intake unit and the ignition unit to guide the heating gas and the carbon dioxide contained in the outside air to the inside of the greenhouse at the time,
And a control unit connected to the control unit through a separate sixth Bluetooth transceiver unit. The control unit senses the illuminance of the sunlight irradiated inside the greenhouse in real time and transmits a corresponding detection signal to the control unit, And an illuminance sensor for automatically supplying carbon dioxide contained in the outside air and the outside air to the inside of the greenhouse through the carbon dioxide supply pipe when the control unit transmits an operation signal to the intake unit when the illuminance is less than a proper level, ,
And is connected to the controller through a separate seventh Bluetooth transceiver unit. The controller senses the concentration of carbon dioxide contained in the air inside the greenhouse in real time and transmits a corresponding sensing signal to the controller. Therefore, , When the control unit transmits an operation signal to the intake unit, the external air is automatically supplied to the inside of the greenhouse through the carbon dioxide supply pipe by the intake unit, so that the carbon dioxide contained in the outside air is supplied into the greenhouse Carbon dioxide concentration sensor,
The heating gas distribution pipe is located inside the greenhouse and the upper end of each heating gas distribution pipe is connected to a heating gas distribution pipe which is not present in the discharge port of the heating case and drawn out of the heating case, A radiator for indirectly heating the air in the greenhouse to raise the temperature,
And the other end is connected to the first installation space of the heating case so that the heating gas passing through the radiator flows into the second installation space again, And the heating gas circulation pipe
Characterized in that the carbon dioxide supply system for plant cultivation in a greenhouse is provided.

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