KR101861071B1 - Smart mushroom cultivation deviation control system and mushroom cultivation deviation control method - Google Patents

Abstract

The present invention comprises: a main control part (2) integrally managing a mushroom growth chamber (100) to maintain temperature, humidity, and carbon dioxide concentration, preset in a mushroom growth environment of the mushroom growth chamber (100) in accordance with cultivation periods; a plurality of sensing parts (4) installed in the mushroom growth chamber (100) in a longitudinal direction by comprising a temperature sensor (6), a humidity sensor (8), and a carbon dioxide concentration sensor (10) for sensing temperature, humidity, and carbon dioxide concentration in the mushroom growth chamber (100); a temperature control part (12) controlling the temperature in the mushroom growth chamber (100) through cooling and heating units (22)(20) in accordance with a growth environment preset according to mushroom growth cycles under control by the main control part (2); a humidity control part (30) controlling the humidity in the mushroom growth chamber (100) through a humidifier (32) in accordance with the growth environment preset according to mushroom growth cycles under control by the main control part (2); and a carbon dioxide concentration control part (34) controlling the carbon dioxide concentration in the mushroom growth chamber (100) through indoor air inhalation and exhalation parts in accordance with the growth environment preset according to mushroom growth cycles under control by the main control part (2). As such, the mushroom growth environment including the temperature, humidity, and carbon dioxide concentration of the mushroom growth chamber (100) is integrally controlled, and thus, the present invention is capable of cultivating high-quality mushrooms, and also, since different optimal growth environments are maintained depending on the number of cultivation days, the present invention is capable of reducing cultivation periods and increasing production.

Description

TECHNICAL FIELD [0001] The present invention relates to a mushroom grower deviation control system and a mushroom grower deviation control method using a smartphone,

The present invention relates to a mushroom grower control system, and more particularly, to a mushroom grower control system for automatically controlling the temperature, humidity, and carbon dioxide concentration for mushroom cultivation, so as to harvest mushrooms of high quality To a mushroom grower deviation control system and a mushroom grower deviation control method.

Generally, mushrooms are cultivated in cultivated houses, and cultivation is carried out by adjusting the temperature inside the cultivated house, maintaining constant humidity, and concentration of carbon dioxide.

Conventionally, these cultivation factors can not be managed collectively, and temperature, humidity, carbon dioxide concentration, etc. are individually managed. There is a problem in that such redundant facilities must be consumed as investment cost, and mushroom cultivation with constant quality is difficult due to individual control, Quality could not be expected.

In addition, the temperature, humidity, and carbon dioxide concentration for mushroom cultivation are individually controlled, so that the mushroom cultivation period is not uniform, and the productivity is lowered. When the mushroom is controlled separately, the mushroom grows beyond the error range, The quality of mushrooms becomes uneven.

In addition, the growth environment such as temperature, humidity, carbon dioxide concentration, etc. in the mushroom growers varies from one area to another, that is, the growth environment of the mushroom grower is not uniform and the quality of the mushroom produced is not uniform.

To solve these problems, it is required to develop an integrated mushroom growing room management system.

Korean Patent No. 10-1655350, "Mushroom Cultivation Apparatus"

Therefore, an object of the present invention is to provide a mushroom cultivar deviation control system and a mushroom cultivar variation control method using a smartphone, which can control the temperature, humidity and carbon dioxide concentration in the mushroom growing room by collectively controlling the mushroom .

The present invention according to the above object is to provide a mushroom growing room (100) in which a mushroom growing room (100) is integrated with a main control unit (100) for managing the mushroom growing room (100) so that the temperature, humidity, 2, a temperature sensor 6 for sensing temperature, humidity and carbon dioxide concentration in the mushroom growth chamber 100, a humidity sensor 8, and a carbon dioxide concentration sensor 10, A sensing unit 4 installed in the interior of the mushroom growth chamber 100 in a height direction to control the internal temperature of the mushroom growth chamber 100 according to a predetermined growth environment according to the growth period of the mushroom under the control of the main control unit 2, The heating unit 20 constitutes a temperature regulating unit 12 controlled by the air conditioning duct 20 and the heating unit 20 so that warm air is supplied through the air conditioning duct 26 having a plurality of holes formed in the upper and lower portions of the mushroom growing room 100, (20b), and the heater A plurality of heater units 20b and a plurality of cooling units 22 are provided so as to control the deviation of the heater units 20b and the plurality of cooling units 22. The set deviations of the plurality of heater heaters 20b and the cooling units 22 are set in the order of capacity, A humidity controller 30 for adjusting the humidity inside the mushroom growth chamber 100 by a humidifier 32 in accordance with a preset growth environment according to the growth cycle of the mushroom, A carbon dioxide concentration adjusting unit 34 for adjusting the internal carbon dioxide concentration of the mushroom growth chamber 100 according to a predetermined growth environment according to a predetermined growth environment according to a predetermined growth environment, And a smart phone capable of monitoring the growth environment and controlling the growth environment.

The present invention has the effect of cultivating high quality mushrooms by collectively and uniformly controlling the mushroom growth environment such as temperature, humidity and carbon dioxide concentration of the mushroom growth chamber in an integrated manner.

In addition, it is possible to shorten the mushroom cultivation period by maintaining the optimum growth environment according to the cultivation days of the mushroom, thereby increasing the production amount.

1 is a configuration diagram of a mushroom grower deviation control system using a smartphone according to an embodiment of the present invention;
2 to 3 are block diagrams illustrating a configuration of a mushroom grower deviation control system using a smartphone according to an embodiment of the present invention.
FIG. 4 is a diagram showing a preset growth environment for cultivating mushrooms in a growing room according to an embodiment of the present invention; FIG.
5 is a flowchart illustrating a mushroom grower deviation control method using a smartphone according to an embodiment of the present invention.

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

The mushroom grower deviation control system using the smartphone of the present invention manages the mushroom growing room 100 so that the temperature, humidity, and carbon dioxide concentration set in advance in accordance with the growing period of the mushroom growing environment in the mushroom growing room 100 can be maintained A main controller 2 and a temperature sensor 6 for sensing the temperature, humidity and carbon dioxide concentration inside the mushroom growth chamber 100, a humidity sensor 8 and a carbon dioxide concentration sensor 10, A sensing unit 4 installed in the interior of the mushroom growth chamber 100 in a height direction to control the temperature of the mushroom growth chamber 100 in accordance with a predetermined growth environment according to the growth period of the mushroom under the control of the main control unit 2, A temperature control unit 12 controlled by radiators 22 and 20 and a control unit 12 for controlling the internal humidity of the mushroom growth chamber 100 according to the growth environment preset according to the growth period of the mushroom under the control of the main control unit 2. [ The humidity controller 30, which is controlled by the humidifier 32, A carbon dioxide concentration regulator 34 for regulating the internal carbon dioxide concentration of the mushroom growth chamber 100 according to the growth environment preset according to the growth period of the mushroom under the control of the main control unit 2 by the intake / .

The main control unit 2 is installed in each growth chamber 100 where the mushroom is grown, and the temperature, humidity, and carbon dioxide concentration preset in order to grow the mushroom of good quality are adjusted to match the cultivation period, Control.

As an embodiment of the present invention, the preset values of temperature, humidity, and carbon dioxide set in advance in the main control unit 2 may be set differently according to the cultivation days as shown in FIG.

The main control unit 2 sets the temperature, humidity, and carbon dioxide concentration of the growth environment suitable for the mushroom cultivation period in advance and then sets the current temperature, humidity, and carbon dioxide concentration inside the growth chamber 100, measured by the sensing unit 4, And the measured value of the sensing unit 4 is input as a feedback signal in real time after the control, so that the real time control can be performed.

The sensing unit 4 measures the temperature, humidity, and carbon dioxide concentration in the growth chamber 100 by the temperature sensor 6, the humidity sensor 8, and the carbon dioxide concentration sensor 10, respectively, The measured value transmitted in real time is compared with a preset value in the main control unit 2 so that the inside of the growth chamber 100 can be kept constant.

The set values may be temperature, humidity, and carbon dioxide concentration values at which the mushroom can be grown in the optimal growth room (100) environment according to the cultivation period of the mushroom.

As the embodiment of the present invention, the sensing unit 4 is installed in the growth chamber 100 in the height direction, and more preferably, the three sensing units 4 are installed in the upper, middle, and lower portions.

The growth environment is controlled using the temperature, moisture, and carbon dioxide concentration measurement values in the growth chamber 100 measured by the three sensing units 4, and based on the measurement value of the sensing unit 4 installed at the center, .

The humidity control unit 30 and the carbon dioxide concentration control unit 34 that are controlled through the main control unit 2 to control the temperature, moisture, and carbon dioxide concentration in the growth chamber 100, The main control unit 2 compares a value measured by the sensing unit 4 provided at the center with a preset value.

This is because, when the values measured by the plurality of sensing units 4 are used, signal confusion due to a plurality of measurement signals occurs, which increases the probability of occurrence of errors in adjusting the growth environment.

The temperature controller 12 controls the temperature of the mushroom growth chamber 100 to a preset value under the control of the main controller 2 in order to maintain the inside of the mushroom growth chamber 100 at a constant temperature.

When the temperature inside the growth chamber 100 differs from the predetermined value by the temperature sensor 6, the main control unit 2 is operated. When the internal temperature is higher than the set temperature, the cooler 22 of the mushroom growth chamber 100 is operated And when the temperature is low, the heater 20 is operated to maintain a certain level of growth environment.

The cooling and heating devices 22 and 20 are supplied with cool air and warm air by the air conditioning ducts 26 installed in the upper and lower parts of the growth chamber 100 and a plurality of fine holes are formed in the air conditioning duct 26, So that the entire air conditioner 100 can be cooled or heated evenly.

At this time, a separate solenoid valve such as a solenoid valve operated under the control of the main control unit 2 may be installed in the air conditioning duct 26 to open / close the air inflow of the air conditioners 22 and 20, It is possible to control the inflow of cold and warm air into the air conditioning duct 26 when the air conditioner 2 and the air conditioner 22 (20) operate.

In addition, when the up / down temperature in the growth chamber is different, the upper / lower temperature in the growth chamber can be uniformly controlled by adjusting the air amount of the cooler / heater that flows into the upper / lower air conditioning duct 26.

First, the heater 20 is installed outside the growth chamber 100. The heater 20 circulates water through the hot water pipe installed at the bottom of the growth chamber 100, An ondol heating apparatus 20a for adjusting the temperature, and a heater heater 20b for supplying heat by an electric heater.

The Ondol heater 20a supplies warmth to the inside of the growth chamber 100 so that the temperature of the inside of the growth chamber 100 reaches a predetermined level. The heater heater 20b is set to a value suitable for the growth environment of the mushroom after the temperature is raised by the Ondol heater 20a. It can be operated for fine temperature control to maintain the temperature.

For example, when the temperature of the growth chamber 100 is raised to 15 ° C by the winter ondol heating apparatus 20a and the temperature is changed finely through the heater heater 20b when the preset temperature is changed according to the cultivation period of the mushroom It is to be adjusted.

In one embodiment, the Ondol heater 20a may have a capacity of 7 kW and 10 kW, and the heater radiator 20b may have four radiators with a capacity of 6 kW.

At this time, four heater heaters 20b are provided, and the heater heaters 20b are individually set to operate at different operating temperatures in order to control the deviation of the heaters.

For example, when the temperature of the growth chamber is raised to a certain level by the Ondol heater 20a, the number of the heater heaters 20b (the first, second, third and fourth heater radiators 20b-1, 20b-2, 20b-3, and 20b-4) may be installed in the first heater heater 20b -1 is -0.4 占 폚, the second heater radiator 20b-2 is -0.3 占 폚, the third heater radiator 20b-3 is -0.2 占 폚, the fourth heater radiator 20b-4 is -0.1 占 폚 20b-2, 20b-3, and 20b-4 so as to operate the respective heaters 20b-1, 20b-2, 20b-

The operating temperature setting for the deviation control may be set in order according to the size of the capacity.

The cooler 22 can be set to operate the first, second, third, and fourth coolers 22a, 22b, 22c, and 22d individually according to the deviation of the operating temperature, The capacities of 22b, 22c and 22d may be 10HP, 7.5HP, 7.5HP and 5HP.

The operating temperature of the first cooler 22a is set to operate when the temperature of the growth chamber 100 is within + 0.4 ° C at the preset temperature, the second cooler 22b is set to operate at + 0.3 ° C, The cooler 22c is set to operate at +0.2 DEG C, and the fourth cooler 22d is set to operate at + 0.1 DEG C so that each cooler 22 operates with a temperature deviation.

The operating temperature setting for the deviation control can be set in order according to the size of the capacity of the heater heater 20b or the cooler 22. That is, in the case of the cooler 22, for example, 10HP for the first cooler 22a, 7.5HP for the second cooler 22b, 7.5HP for the third cooler 22c, and 5HP for the fourth cooler 22d .

By setting the temperature for operating each of the coolers 22 to be different from each other, precise and efficient operation of the cooler 22 becomes possible.

For example, if the current set temperature of the mushroom growth chamber 100 is 15 ° C, the first, second, third, and fourth coolers 22a, The second, third, and fourth coolers 22b, 22c, and 22d are operated together to control the temperature of the growth chamber 100 to approach the set temperature within a short period of time. ) 22c and 22d are operated. When the growth temperature of the growth chamber 100 is 15.1 ° C, only the fourth cooler 22d operates to precisely control the temperature.

This deviation control is effective in reducing power consumption by reducing the number of coolers 22 that are activated as the set temperature is reached. When the temperature is close to the set temperature, only one cooler 22 is operated to precisely control the internal temperature of the growth chamber 100 It can be adjusted.

The operating temperature range of each of the coolers 22 for the deviation control is not fixed and may be changed flexibly through the main controller 2 in order to prevent overload of the cooler 22.

That is, in order to maintain the temperature inside the growth chamber 100, the fourth cooler 22d operating within the range of +0.1 degrees C may be operated from time to time to cause an overload, This can be avoided by changing it from time to time.

The humidity controller 30 compares the humidity inside the growth chamber 100 measured by the sensing unit 4 with a predetermined humidity set in advance and controls the humidifier 32 through a plurality of humidifiers 32 installed in the upper portion of the growth chamber 100, The humidity for cultivation is controlled, and the humidifier 32 is formed with a plurality of spray tubes to be sprayed in all directions.

In addition, since the humidity may decrease during cooling by the cooling device 22 described above, it is preferable to set the cooling device 22 so as to be linked with the cooling device 22 so as to be set to operate together.

The carbon dioxide concentration control unit 34 is provided with intake and exhaust ports 36 and 38 to circulate the air in the growth chamber 100 to maintain a preset carbon dioxide concentration, Adjust the humidity by the value.

In the growth chamber 100, carbon dioxide is discharged during the growing process of the mushroom to change the concentration. The inside air is discharged to the outside through the discharge port 38 or the outside air is introduced into the inside of the growth chamber 100 through the air inlet port 36 Adjust the carbon dioxide concentration.

At this time, the air introduced into the growth chamber 100 through the intake port 36 may contain a harmful component such as fine dust, which has recently become a problem, and a filter (not shown) for filtering the intake port 36 may be installed It is good to do.

For example, the filter may be a HEPA filter, and bacteria or dust of fine particles may be prevented from flowing into the growth chamber 100, thereby cultivating high quality mushrooms.

Since the internal temperature of the growth chamber 100 may change due to the inflow and outflow of air as the air in the growth chamber 100 is introduced or discharged during the circulation of the air by the intake and exhaust ports 36 and 38, It is preferable that the air conditioner 22 and the air conditioner 22 are operated together and the humidifier 32 is controlled to operate together.

That is, the heating unit 20 and the cooling unit 22 are constituted by one module, or the heating unit 20, the cooling unit 22 and the humidifier 32 are constituted by one module so as to operate in a hybrid form, So that the growth environment of the plant can be kept constant.

In the present invention, as shown in FIG. 3, the main control unit 2 installed in a plurality of mushroom growth chambers 100 may be collectively controlled and the integrated control unit 40 may be configured to monitor the growth state of the mushrooms .

The integrated control unit 40 is capable of collectively controlling a plurality of main control units 2 or changing the growth environment of a specific growth chamber 100 at a remote place, The temperature, humidity, and carbon dioxide concentration set for each day are stored in the database.

The daily growth environment control value stored in the database allows the growth environment of the growth chamber 100 in which the mushroom having excellent quality is completed after the completion of the mushroom cultivation to be applied to the other growth chamber 100, It is possible to cultivate excellent mushroom by reference.

In addition, the integrated control unit 40 can be controlled to monitor the current state of the growth chamber 100 by being connected to the integrated control unit 40 via a smart phone. The inside of the growth chamber 100 can be monitored for temperature, humidity, It is also possible to change the growth environment of the plant.

Hereinafter, a mushroom grower deviation control method using the smartphone of the present invention will be described with reference to FIG.

In the present invention, a set value corresponding to temperature, humidity, and carbon dioxide concentration, which are growth environments of mushrooms to be cultivated in each growth chamber 100, is set in advance in the main control unit 2 so that the growth environment of the growth chamber 100 And is kept within the set value range.

To this end, a sensing unit 4 including a plurality of temperature sensors 6, a humidity sensor 8, and a carbon dioxide concentration sensor 10 is installed in the growth chamber 100 at a plurality of positions, The data measured through the sensing unit 4 is transmitted to the main control unit 2 in real time.

The main control unit 2 receives the measured data from the sensing unit 4 and calculates temperature, humidity, carbon dioxide concentration, and temperature, humidity, and carbon dioxide concentration values set in advance in the optimal growth environment of the mushroom And generates an operation signal for supplementing the inside of the growth chamber 100 so as to approach the set value when an error occurs outside the set value.

The operation signal generated by the main control unit 2 may be an operation signal of the temperature control unit 12, the humidity control unit 30, and the carbon dioxide concentration control unit 34 that can control the growth environment of the growth chamber 100 .

The temperature of the growth chamber 100 is adjusted to the set temperature through the temperature regulation unit 12. When the internal temperature of the growth chamber 100 is lower than the predetermined temperature, the temperature is raised by the plurality of heaters 20 .

In view of the temperature control by the heater 20, the heated water is caused to flow through the hot water pipe installed at the bottom of the growth chamber 100 to raise the inside of the growth chamber 100 to a predetermined temperature through the ondol heating unit 20a The inside temperature is raised, and the temperature of the growth chamber 100 is further finely adjusted so as to approach the set temperature again through the heater heater 20b as the electric heater.

At this time, the warm air through the heater radiator 20b is supplied through the air ducts provided at the upper and lower portions of the growth chamber 100, and a plurality of heater radiators 20b may be installed. And the inside of the growth chamber 100 is uniformly adjusted to the set temperature by discharging warm air through the fine holes.

When the internal temperature of the growth chamber 100 becomes the set temperature or more, the temperature is lowered through the cooler 22 to maintain the set temperature, and a plurality of coolers 22 having different temperature setting deviations for operating the cooler 22 are installed .

The operating temperature of the first cooler 22a is set to be the same as the set temperature of the growth chamber 100. In this case, the first, second, third, and fourth coolers 22a, 22b, 22c, The second cooler 22b is set to operate in the range of +0.4 DEG C, the third cooler 22c is set to operate in the range of +0.2 DEG C, and the fourth cooler 22d operates in the range of +0.0 DEG C The temperature of the first heater heater 20b-1 is -0.4 占 폚, the temperature of the second heater heater 20b-2 is -0.3 占 폚, the temperature of the third heater heater 20b-3 is -0.2 占 폚 And the fourth heater heater 20b-4 are set to operate within -0.1 ° C, respectively, so that the respective coolers 22 and heater radiators 20b operate individually according to the temperature deviation through the deviation control.

Next, the humidity inside the growth chamber 100 is adjusted to a predetermined humidity through the humidity controller 30, and the humidity of the growth chamber 100 measured by the humidity sensor 8 is adjusted to exceed the set humidity , The humidifier (32) installed on the growth chamber (100) is operated to adjust the humidity so that the humidity is set to be high.

At this time, the humidifier 32 is provided with a plurality of spray tubes so that it can be sprayed in all directions, thereby efficiently controlling the humidity.

Next, the carbon dioxide concentration in the growth chamber 100 is adjusted to a preset concentration through the carbon dioxide concentration control unit 34, and the concentration of carbon dioxide changes as the mushroom grows. It will be adjusted accordingly.

When the concentration of carbon dioxide in the growth chamber 100 deviates from the set concentration, the suction and exhaust ports 36 and 38 provided in the growth chamber 100 are operated to discharge the air inside the growth chamber 100 to the outside, And flows into the chamber 100 to adjust the concentration of carbon dioxide so as to approach the set concentration.

At this time, the air introduced from the outside may contain harmful components such as fine dust, which may harm the growth of the mushroom. Accordingly, a separate filtering means such as a HEPA filter is installed in the suction port 36 to filter out the inflow air And is introduced into the growth chamber (100).

The temperature, humidity, and carbon dioxide concentration of the growth chamber 100 are adjusted by the main control unit 2 to a preset value in the growth chamber 100 for each mushroom cultivation period, The set value is stored in the database of the integrated control unit 40 and the growth environment of the growth chamber 100 in which the high quality mushrooms are produced is confirmed. It is also applied to the growth chamber 100 to set the optimum mushroom to grow.

By repeating this, it is possible to increase the quality of the mushroom by improving the quality of the mushroom by allowing the superior mushroom to be grown in each growth chamber (100).

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be determined by the scope of claims and equivalents thereof.

(2) - main control unit (4) - sensing unit
(6) - Temperature sensor (8) - Humidity sensor
(10) -Carbon dioxide concentration sensor (12) - Temperature control unit
(20) - Radiators
(20a) - Ondol radiator (20b) - Heater radiator
(22) - Air conditioner
(22a) - a first cooler (22b) - a second cooler
(22c) - a third cooling device (22d) - a fourth cooling device
(26) - Air conditioning duct (30) - Humidity control section
(32) - Humidifier (34) - Carbon dioxide concentration controller
(36) - Intake port (38) - Exhaust port
(40) - Integrated Control Department
(100) - Growing Room (200) - Mushroom Badge

Claims (8)

A main controller 2 for collectively managing the mushroom growing room 100 so that the temperature, humidity, and carbon dioxide concentration of the mushroom growing room 100 can be maintained according to the cultivation period,
A temperature sensor 6 for sensing the temperature, humidity and carbon dioxide concentration inside the mushroom growth chamber 100, a humidity sensor 8 and a carbon dioxide concentration sensor 10, A plurality of sensing units 4 installed in the direction of the sensor,
Under the control of the main control unit 2, a temperature regulating unit 12 for regulating the internal temperature of the mushroom growth chamber 100 by means of the coolers / heaters 22 and 20 in accordance with a predetermined growth environment according to the growth cycle of the mushroom However,
The radiator 20 is composed of a heater radiator 20b for supplying warm air through an air duct 26 having a plurality of holes formed in the upper and lower portions of the mushroom growth chamber 100,
A plurality of the heater radiators 20b and the plurality of coolers 22 are installed to control the deviation of the plurality of heater radiators 20b and the coolers 22 and the set deviations of the plurality of heater radiators 20b and the coolers 22 are set in the order of capacity,
The first air conditioner 22a is provided with first, second, third and fourth air conditioners 22a, 22b, 22c and 22d. The first air conditioner 22a has a temperature of +0.4 ° C, The second cooling unit 22b is set to operate in the case of +0.3 DEG C, the third cooling unit 22c in the +0.2 DEG C range and the fourth cooling unit 22d in the range of +0.1 DEG C, so that each of the coolers 22 is controlled to be varied ,
The heater heater 20b is installed as the first, second, third and fourth heater radiators 20b-1, 20b-2, 20b-3 and 20b-4, The third heater heater 20b-3 is -0.2 占 폚, the fourth heater heater 20b-4 is -0.2 占 폚, the second heater heater 20b-2 is -0.3 占 폚, the second heater heater 20b- -0.1 [deg.] C so as to control the deviation of each heater heater 20b,
A humidity controller 30 for controlling the internal humidity of the mushroom growth chamber 100 by a humidifier 32 according to a preset growth environment according to the growth period of the mushroom under the control of the main control unit 2,
A carbon dioxide concentration adjusting unit 34 for adjusting the internal carbon dioxide concentration of the mushroom growth chamber 100 according to a predetermined growth environment according to the growth period of the mushroom under the control of the main control unit 2, ,
A mushroom cultivar deviation control system using a smartphone, characterized by comprising a smartphone capable of monitoring a growth environment of a mushroom growth chamber (100) at a remote site and controlling a growth environment.
The method according to claim 1,
The heating unit 20 is provided with an Ondol heater 20a for circulating water to the hot water pipe installed at the bottom of the growth chamber 100 to adjust the temperature of the inside of the growth chamber 100 to a predetermined level Mushroom cultivar deviation control system using smartphone.
delete The method according to claim 1,
The main control unit 2 installed in a plurality of mushroom growing chambers 100 is collectively controlled and the temperature and humidity of the mushroom are controlled in accordance with the growing period of the mushroom cultivated in the growing chamber 100 while monitoring the growing condition of the mushroom , The concentration of carbon dioxide is stored in a database, and the growth environment of the growth chamber (100) in which the mushroom with high quality is produced after the mushroom cultivation is completed is applied to the other growth chamber (100) And a control unit (40). The mushroom grower deviation control system using the smartphone.
A step of presetting the temperature and humidity carbon dioxide concentration of the mushroom growth chamber (100) for growing mushroom in the main control unit (2) in advance;
A value measured by a sensing unit 4 including a temperature sensor 6, a humidity sensor 8 and a carbon dioxide concentration sensor 10 installed in the growth chamber 100 in real time to the main control unit 2 Process; and
A process of comparing the measured values of the temperature sensor 6, the humidity sensor 8 and the carbon dioxide concentration sensor 10 with a preset value in the main control unit 2 to generate an operation signal to compensate for an error, ;;
When the internal temperature of the growth chamber 100 is lower than the set temperature while the temperature is supplemented by the heater 20 by comparing the internal temperature of the growth chamber 100 and the set temperature, the temperature is raised to a certain level by the ondol heating device 20a, (20b) so as to approach the set temperature;
Controlling the plurality of coolers 22 to be sequentially operated by the deviation control so that the inside temperature of the growth chamber 100 is close to the preset temperature;
Controlling the humidifier (32) installed on the growth chamber (100) to move closer to the set humidity when the humidity inside the growth chamber (100) is out of the set humidity range;
Controlling the air in the growth chamber (100) to flow in and out through the intake and exhaust ports (36) and (38) when the concentration of carbon dioxide in the growth chamber (100)
After storing the growth environment conditions adjusted for the mushroom cultivation period in the database of the integrated control unit 40 and confirming the growth environment of the growth chamber 100 in which the mushroom was produced, ; And
And controlling the growth environment of the growth chamber (100) remotely while monitoring the growth environment set in the growth chamber (100) in real time by accessing the integrated control unit (40) through a smart phone Control method of mushroom grower deviation.
6. The method of claim 5,
The Ondol heater 20a warms the water and circulates the Ondol heater to the hot water pipe installed at the bottom of the growth chamber 100 to raise the temperature. The heater heater 20b is heated by the Ondol heater 20a, Wherein the heat generated by the heater is supplied to the air conditioning duct (26) installed at the upper and lower portions of the growth chamber (100) and finely adjusted to the set temperature.
6. The method of claim 5,
The first and second coolers 22a and 22b are controlled to have a deviation of + 0.4 ° C and + 0.3 ° C, respectively, The first heater heater 20b-1 is set to operate at a temperature of -0.4 占 폚 and the second heater heater 20b-2 ) Is -0.3 占 폚, the third heater heater (20b-3) is -0.2 占 폚, and the fourth heater heater (20b-4) is -0.1 占 폚. Deviation control method.
6. The method of claim 5,
Wherein a set deviation of the plurality of heater radiators (20b) and the coolers (22) is set in the order of capacity and controlled to be operated.

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