KR100652846B1 - Remote system for controlling a plant growth over network - Google Patents

Abstract

The present invention relates to a web-based remote plant culture control system, in which the conditions of the analytical elements in the plant culture are set in advance by a plurality of plant incubators remotely to enable differentiated control of the providing elements as set. It is an object of the present invention to provide a web-based remote plant culture control system that enables remote control of different conditions depending on the type of plants put into the plant incubator.

According to the present invention, a culture chamber is provided in the inside so that different controlled remote control signals are generated for each incubator according to the plant information located therein, so that the plants can be cultured under different culture conditions for each plant. A plurality of web-based plant cultivators made by comparing the set value and the detected value and controlled to automatically adjust the set illuminance for each time zone; Remote plant culture management server that checks the sensing data for each web-based plant incubator through a monitor by communicating with each of the plurality of web-based plant incubators, and remotely controls temperature, humidity, and illumination with each web-based plant incubator. Web-based remote plant culture control system, characterized in that consisting of.

According to the present invention, a single web administrator can easily remotely control a plurality of web-based remote plant incubator from a remotely located manager PC, and the temperature and humidity are automatically set according to the humidity and temperature set in advance for each compartment. Web-based remote plant incubator can be maintained, and the illumination control is to control the illumination automatically according to the preset time period, thereby maintaining the roughness similar to the amount of sunshine to provide the optimum culture conditions.

Description

Web-based remote plant culture control system {REMOTE SYSTEM FOR CONTROLLING A PLANT GROWTH OVER NETWORK}

1 is a schematic diagram showing a schematic configuration of a web-based remote plant culture control system according to an embodiment of the present invention,

Figure 2 is a perspective view showing the appearance of the web-based remote plant incubator according to an embodiment of the present invention,

Figure 3 is a front sectional view showing the configuration of a web-based remote plant incubator according to an embodiment of the present invention,

4 is a block diagram showing a circuit configuration of a web-based remote plant incubator according to an embodiment of the present invention,

5 is a view showing a condition table for each incubator stored in a database of a web-based remote plant culture management server according to an embodiment of the present invention,

6A, 6B, and 6C are flowcharts showing signal flows of a web-based remote plant culture control system according to an embodiment of the present invention.

* Explanation of symbols for main parts of drawings *

26: lighting unit, 30: temperature sensor,

32: humidity sensor, 44: heater,

46: cooler, 80: control unit.

The present invention relates to a web-based remote plant culture control system, and more specifically, to pre-set the conditions of analytical elements in a plurality of plant incubators remotely in plant cultivation to enable differentiated control of the elements provided as set. The present invention relates to a web-based remote plant culture control system that enables remote control of different conditions depending on the type of plants put into each plant incubator.

As is well known, due to the recent development of information and communication technology, the development of information providing technology that provides real-time information to various subscribers through at least one host server through a remote data communication network is actively underway.

Based on this, in recent years, information selection technology and compression technology are being developed to more easily access peripheral technologies such as cache memory expansion technology to provide accurate information to subscribers more quickly and subscribers' tastes and preferences. It is also accelerating the development of various contents and its solutions.

On the other hand, the recent BT (Bio Technology) industry, along with IT and NT, has become an important industrial field that has a great contribution to humankind in the 21st century. BT technology has been widely studied in various fields such as cultivation of organisms, seed development, and genetic modification.In Korea, interest and investment in BT have been increasing since the late 1990s, and new drug development, genetic analysis, seed culture, etc. Much research has been done.

BT technology, which is said to be one of the advanced technologies, requires systematic techniques for accurate cultivation and analysis of the results through culture experiments. However, there is still a lack of systematic research on these techniques.

Particularly, in the field of plant cultivation, the old-fashioned experiments and cultivation, which are directly managed and cultivated by people at the house cultivation and laboratory seed cultivation level, are performed. There was a problem that could not be done properly.

The present invention has been made in view of the above-described circumstances of the prior art, and the conditions of the analytical elements in plant cultivation are set in advance by a plurality of plant incubators remotely to enable differentiated control of the providing elements as set. It is an object of the present invention to provide a web-based remote plant culture control system that enables remote control of different conditions depending on the type of plants put into each plant incubator.

In order to achieve the above object, according to a preferred embodiment of the present invention, a remote control signal differentiated for each incubator is generated according to the plant information located therein so that each plant can be cultured under different culture conditions. Is provided, the temperature and humidity control for each incubator is made by the comparison of the set value and the detection value, a plurality of web-based plant incubator that is controlled to automatically adjust the set illuminance for each time zone; Remote plant culture management server that checks the sensing data for each web-based plant incubator through a monitor by communicating with each of the plurality of web-based plant incubators, and remotely controls temperature, humidity, and illumination with each web-based plant incubator. Provided is a web-based remote plant culture control system comprising a.

Preferably, the web-based plant incubator is provided with a plant culture room for culturing the plant according to predetermined conditions at the upper end, the lower part of the plant culture room is equipped with a machine room in which various internal devices are built, The culture chamber and the machine room are partitioned by a heat transfer plate, and a web-based remote plant culture control system is provided on the bottom of the heat transfer plate, in which a cold / hot water supply line for distributing the cooling / heating circulation water in a zigzag form is provided. do.

Preferably, the web-based plant incubator is provided with a web-based remote plant culture control system, characterized in that the temperature / humidity sensor for sensing the temperature and humidity of the plant culture room therein.

Preferably, the web-based plant incubator is provided with a heater and a cooler, respectively, to adjust the temperature of the plant culture room therein, a sprayer for adjusting the humidity, a plurality of to maintain a predetermined roughness A web-based remote plant culture control system is provided wherein a light is attached to the ceiling thereof.

Preferably, the web-based plant incubator is provided with a data storage unit for storing the control data transmitted from the remote plant culture management server therein, the control of temperature, humidity, illumination according to the setting data of the data storage unit Provided is a web-based remote plant culture control system, characterized in that the control unit further comprises.

Preferably, the control unit is provided with a web-based remote plant culture control system, characterized in that the number of illumination of each lighting unit is set to be differently lit according to the type of plants embedded in each plant incubator according to the time elapsed after the start of the culture. do.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail with reference to drawings.

1 is a schematic diagram showing a schematic configuration of a web-based remote plant culture control system according to an embodiment of the present invention.

Referring to this, the web-based remote plant culture control system according to an embodiment of the present invention is to pre-set the conditions of the analysis elements in a plurality of plant incubator remotely in the plant cultivation as differentiated control of the elements provided as set It is a system that enables remote control of different conditions depending on the type of plants put in each plant incubator.

In a web-based remote plant culture control system according to an embodiment of the present invention, a remote plant culture management server (RBCMS) installed at a remote location is connected to a plurality of first to Nth plant incubators 2a to 2n and remotely located at multiple locations. Different conditions are set in advance for each of the first to Nth plant incubators 2a to 2n that are dispersed so that the first to Nth plant incubators 2a to 2n can cultivate the built-in plants according to the set conditions. System.

On the other hand, the remote plant culture management server (RBCMS) is stored in advance the optimum data for the various culture conditions of the first to the N-th plant incubator (2a to 2n) in advance, the respective culture conditions The first and second databases DB1 and DB2, which store data in advance, are built in.

In addition, the remote plant culture management server (RBCMS) is capable of remote control of the culture conditions of the first to N-th plant incubator (2a to 2n), etc., the interface network at this time is a local area network RAN network. The first to Nth plant incubators 2a to 2n store data about the culture conditions previously transmitted by the remote plant culture management server (RBCMS) in the internal memory, and are adapted to the culture condition data. When the new culture condition data is applied from the remote plant culture management server (RBCMS), the control is updated with the new culture condition data to apply the changed culture condition data. Is done.

Meanwhile, even if the web-based remote plant culture control system according to an embodiment of the present invention is the same plant, each of the first to Nth plant incubators 2a to 2n to obtain growth data according to the culture conditions, respectively. Different culture conditions can be updated to compare the results of plants incubated under different culture conditions.

Figure 2 is a perspective view showing the appearance of a web-based remote plant incubator according to an embodiment of the present invention, Figure 3 is a front sectional view showing the configuration of a web-based remote plant incubator in accordance with an embodiment of the present invention.

Referring to this, the first to N-th plant incubator (2a to 2n) and the housing (4) forming the outer appearance; A door 6 fixed to the front of the housing 4 to be opened and closed by a hinge or the like is configured, and the front of the door 6 is a viewing window 8 to visually check the state of plant culture inside the housing 4. It is provided.

In addition, a lower portion of the left end of the housing 4 is provided with a water pipe 10 for providing circulating water for temperature control through circulation control of cooling and heating water of the first to Nth plant incubators 2a to 2n. In the lower right end, the culture condition data transmission of the remote plant culture management server (RBCMS) is transmitted to the first to Nth plant incubators 2a to 2n, and the first to Nth plant incubators 2a to 2n. Communication line 12 for transmitting the sensed data from the remote plant culture management server (RBCMS) is provided.

On the other hand, in the lower predetermined portion of the housing 4, in addition to the remote control from the remote plant culture management server (RBCMS) is configured a key operation panel 14 for generating various key operation signals during the manual operation of the user, the inside An LCD 16 is displayed to display the setting and driving states of the devices, and a power button 18 for operating to turn on the power to the internal devices of the first to Nth plant incubators 2a to 2n is formed. It is done.

As shown in FIG. 3, the housing 4 has a plant culture room 20 for cultivating the plant to a predetermined condition, as shown in FIG. 3, at an upper end thereof, and a variety of interiors under the plant culture room 20. The machine room 40 in which the devices are built is provided, and the plant culture room 20 and the machine room 40 are partitioned by the heat transfer plate 22. That is, the bottom surface of the plant culture room 20 is made of a heat transfer plate (22).

Therefore, the earth and sand are disposed on the upper surface of the heat transfer plate 22 of the plant culture room 20, and the culture plants 24 are planted and cultured on the soil.

A plurality of lights 26 are attached to the inner ceiling surface of the plant culture room 20, and the lights 26 are turned on for a predetermined time and turned off for a predetermined time according to the culture condition data. The number of lights 26 to be lit is controlled differently. Therefore, it is possible to provide the culture 24 with the same environment as the actual natural light, even if the same plant to set the different illumination and lighting cycle for each plant incubator (2a to 2n) to find the optimal culture environment Culture is preferred.

In addition, both sides of the plant culture room 20 and the predetermined portion of the ceiling surface is provided with a sprayer 28 for providing moisture to the culture plant 24 side, bar of the plant cultured in each plant incubator (2a to 2n) Depending on the type, moisture is supplied to a preset value stored in flash memory.

In addition, a plurality of temperature sensors 30 are attached to both side walls of the plant culture room 20, respectively, to sense the temperature of the corresponding plant culture room 20, and a plurality of humidity sensors 32 on each side wall thereof. It is attached to measure the humidity in the plant culture room (20). By sensing the temperature and humidity of the plant culture room 20 through the temperature sensor 30 and the humidity sensor 32 it is possible to accurately maintain the temperature and humidity in the plant culture room 20 according to the set data.

On the other hand, a plurality of ventilation holes 34 are formed on the rear wall of the plant culture room 20, and the ventilation holes 34 are coupled to a ventilation duct (not shown) formed on the rear surface of the rear wall to collect the exhaust. The gas is discharged to the outside, and one end of the ventilation duct is coupled to the exhaust fan 36, and the ventilation fan 36 is attached to the upper end of one side of the housing 4.

The machine room 40 is equipped with a known cooler 46 and a heater 44 coupled to the water pipe 42 introduced through the right wall, respectively, through the cooler 46 and the heater 44. The temperature of the plant culture room 20 is adjusted by heating or cooling the circulating water introduced through the water pipe 42 to a constant temperature, and the other end of the cooler 46 and the heater 44 has a cold / hot water supply line. 48 is connected, and the cold / hot water supply line 48 is attached to the lower surface of the heat transfer plate 22 in a zigzag form.

In addition, a circuit board 50 in which various control chips are mounted is provided in the machine room 40, and external data is applied to the circuit board 50 or generated from the circuit board 50. The modem 52 for sending data to the outside is provided.

Figure 4 is a block diagram showing the circuit configuration of a web-based remote plant incubator according to an embodiment of the present invention.

Referring to this, prior to the description of the web-based remote plant incubator 2 according to an embodiment of the present invention, the remote plant culture management server (RBCMS) temperature / humidity setting button 102 and the illumination setting button 104 ), The exhaust setting button 106 and the plant selection button 108 are provided, the temperature / humidity setting button 102, the illuminance setting button 104 and the exhaust setting button 106 are remote plant incubators ( The culture conditions to be transferred to 2) are set up: temperature / humidity, illuminance, exhaust time and exhaust time interval. In addition, the plant selection button 108 selects the type of plant and extracts the optimum humidity, temperature, and lighting condition values according to each plant type stored in a flash memory or a database in advance, so that the plant can be controlled remotely. Will be selected.

According to the control signal generated from the button of the remote plant culture management server (RBCMS), the web-based remote plant incubator 2 according to an embodiment of the present invention is remotely controlled, the web-based remote plant incubator 2 ) Inside the communication interface unit 52, temperature sensing unit 30, humidity sensing unit 32, heater 44, heater driver 60, power distribution unit 56, cooler 46, cooler driver (62), water pump 58, water pump driver 64, lighting unit 26, lighting driver 66, vent fan 36, vent fan driver 68, sprayer 28, spray mechanism drive 70 ), An LCD 16, an LCD driver 72, a buzzer 74, a buzzer driver 76, a data storage unit 78, a controller 80, and a timer 80a.

The communication interface unit 52 receives a control signal of humidity, temperature, and illumination from a remote plant culture management server (RBCMS) and uses the plant embedded in the web-based remote plant incubator 2 based on the data for the corresponding culture conditions. In order to cultivate various control data reception and the transmission of the resulting data is shown an interface unit with a built-in communication module, such as a modem.

The temperature sensing unit 30 is attached to both side walls of the plant culture room 20, respectively, a means for sensing the temperature inside the culture chamber, the same configuration as the temperature sensor shown in Figure 3, the humidity sensing unit Reference numeral 32 is a means for sensing the humidity inside the culture chamber is attached to each of the plurality of side walls of the plant culture room 20, the same configuration as the humidity sensor shown in FIG.

The heater 44 is provided inside the machine room 40 and is a heating means for heating the circulating water introduced through the water pump 58 and supplying the cold / hot water supply line 48 to the heater driving unit. 60 is a configuration for driving the heater 44.

The power distribution unit 56 is a configuration for distributing AC power to each configuration, the cooler 46 is a configuration for cooling the circulating water introduced through the water pipe 42 to a constant temperature, the circulation The water changes the temperature of the heat transfer plate 22 through the cold / hot water supply line 48. In addition, the cooler driver 62 is configured to drive the cooler 46.

The water pump 58 is connected to the heater 44 and the cooler 46, respectively, to supply circulating water for controlling room temperature to the heater 44 and the cooler 46, and the water pump The drive unit 64 is a configuration for driving the water pump 58.

The lighting unit 26 is a configuration for irradiating light to the culture plant 24 planted inside the culture chamber 20, the illumination installed in the lighting unit 26 is provided with illumination of different wavelengths each culture plant 24 It is preferable to turn on the selected illumination according to the type of). The lighting driver 66 is a configuration for driving the lighting unit 26.

The ventilation fan 36 is configured to exhaust air from the culture chamber 20, the ventilation fan driver 68 is configured to drive the ventilation fan 36, and the sprayer 28 is the culture chamber. Each of the sidewalls 20 is configured to supply water to the culture plant 24, and the spraying mechanism 70 is configured to drive the sprayer 28.

The LCD 16 is a display configuration for displaying an input signal input through the key operation panel 14 or a remote control signal transmitted from the remote plant culture management server (RBCMS), and the LCD driver ( 72 is a configuration for driving the LCD 16.

The buzzer 74 is configured to generate an alarm upon abnormal control of the web-based remote plant incubator 2, and the buzzer driver 76 is configured to drive the buzzer 74.

The data storage unit 78 stores the remote control data transmitted from the remote plant culture management server (RBCMS), each control state data according to the temperature control, humidity control, lighting control signals included in the remote control data It is configured to store its own data for automatically generating control data when not storing the optimal data of the various plants, while being applied to the remote control signal from the remote plant culture management server (RBCMS). .

On the other hand, the control unit 80 is the temperature control, humidity control transmitted from the remote plant culture management server (RBCMS) according to the signal of the remote control, automatic control, manual control according to the key selection on the key operation panel 14 Each of the coolers 46, the heaters 44, and the lighting units 26 is controlled by an illumination control signal, and the temperature, humidity, and illuminance of preset values are controlled by controlling the sprayer 28 and the water pump 58. To control, automatically execute preset automatic control data according to the presence or absence of a signal transmission from the remote plant culture management server (RBCMS), and enable manual control by a manual control value input according to a manual control signal. It is a configuration for generating a control signal, the timer (80a) is included in the control unit 80 to perform a counter for each control signal to perform a control operation for a predetermined time.

FIG. 5 is a view showing a condition table for each incubator stored in a database of a web-based remote plant culture management server according to an embodiment of the present invention.

Referring to this, in the database (DB1, DB2) of the web-based remote plant culture management server according to an embodiment of the present invention, the type and roughness value, temperature value, humidity value, and allowable time data of each culture plant are provided in the table 90. Each of these control values represents the data (92, 94, 96) values according to the respective plant types.

In particular, the illumination control is set to have a time interval differently depending on the type of plants, for example, reference numeral 98 denotes a setting value of the illumination change, in the case of a specific plant so that the illumination value is changed at a predetermined time interval When active growth is possible only when it is set, the controller 80 can control the illumination of the plurality of lights of the lighting unit 26 in real time so that the required illuminance value can be changed.

The function and operation of the web-based remote plant culture control system according to an embodiment of the present invention of the above configuration will be described in detail with reference to the accompanying drawings.

6A, 6B, and 6C are flowcharts showing signal flows of a web-based remote plant culture control system according to an embodiment of the present invention.

Figure 6a shows a temperature control state through a web-based remote plant culture control system, Figure 6b shows a humidity control state through a web-based remote plant culture control system, Figure 6c shows a web-based remote plant culture control system It shows the illumination control status.

Referring to this, in the temperature control of FIG. 6A, first, the plants that the user wants to cultivate are respectively put into the plurality of web-based remote plant incubators 2. At the same time, the user operates the power button 18 of the web-based remote plant incubator 2 to turn on the power (first step: ST-1).

In that state, the user generates a temperature control signal through the remote plant culture management server (RBCMS). Then, the web-based remote plant incubator 2 receives the temperature control signal and registers the temperature set value in the database (steps 2 and 3: ST-2 and 3).

In addition, the web-based remote plant incubator 2 detects the internal temperature through the temperature sensing unit (step 4: ST-4), and determines whether the corresponding detection value is within the range of the preset value (step 5). : ST-5). If the detected temperature is less than or equal to the set value, the circulating water heated by the heater 44 is heated by the heater 44 to heat the heat transfer plate 22 through the cold / hot water supply line 48. The temperature inside the culture chamber 20 is increased (steps 6 and 7: ST-6 and 7).

In addition, the controller 80 determines whether the incubation time of the corresponding culture plant is completed, and terminates the temperature control when the incubation time is completed (eighth step: ST-8).

If the detected temperature is higher than the set value, the cooler 46 is driven to cool the heat transfer plate 22 through the cold / hot water supply line 48 by circulating water cooled in the cooler 46. The temperature inside the culture chamber 20 is lowered (steps 10 and 11: ST-10 and 11).

Similarly, the control unit 80 determines whether the incubation time of the culture plant is completed and terminates the temperature control when the incubation time is completed.

After the temperature control process, the temperature control for each of the plurality of web-based remote plant incubator (2) is carried out, the present invention, the set temperature and the internal to facilitate the temperature control for each web-based remote plant incubator (2) By detecting and comparing the temperatures separately, it is possible to determine whether to drive the heater 44 or the cooler 46, and to drive the low temperature power efficient temperature control.

In addition, Figure 6b is a flow chart for the humidity control, the web-based remote plant incubator 2 in accordance with the present invention is each of the web-based remote plant incubator (2) generated by the user through the remote plant culture management server (RBCMS) ), The web-based remote plant incubator 2 is set in the database by receiving the humidity value per step (step 20: ST-20).

In addition, the web-based remote plant incubator 2 detects the internal humidity through the humidity detecting unit (step 21: ST-21), and determines whether the corresponding detection value is within the range of the preset value (step 22). : ST-22). If the detected humidity is less than the set value, the sprayer 28 is driven to supply water to the inside of the culture chamber 20 (step 23: ST-23).

In addition, the controller 80 determines whether the incubation time of the corresponding culture plant is completed, and terminates the humidity control when the incubation time is completed (step 24: ST-24).

If the detected humidity is greater than or equal to the set value, the sprayer 28 is stopped and the ventilation fan 36 is driven to lower the humidity in the culture chamber 20 (steps 25 and 26: ST-). 25,26).

Similarly, the control unit 80 determines whether the incubation time of the culture plant is completed and terminates the humidity control when the incubation time is completed.

FIG. 6C is a flowchart for illuminance control, wherein illuminance is controlled by a plurality of the web-based remote plant incubators 2. First, a user controls each web-based remote plant through the remote plant culture management server (RBCMS). The illuminance value for each incubator 2 is set, and the irradiation time is set.

Then, the setting control value is applied to the web-based remote plant incubator 2 and registered in the database. When the illuminance and the irradiation time are set, the web-based remote plant incubator 2 turns on the fluorescent lamp of the lighting unit 26 which is a lighting device (ST 32). The timer 92a is driven from the time when the fluorescent lamp 50 is turned on to determine whether the illumination control setting time (for example, morning, noon, afternoon, night time zone) arrives (step 33: ST-33).

When the corresponding time arrives, the illuminance is adjusted by controlling the number of lighting of the fluorescent lamp 50 matching the time zone (step 34: ST-34). In addition, it is determined whether the lighting fixture off time zone (eg, the night time zone) arrives, and when the lighting fixture off time zone arrives, all the fluorescent lamps 50 are turned off (steps 35, 36: ST-35, 36).

When the lighting fixture turn-on time (eg, morning) arrives, a predetermined number of fluorescent lamps 50 are turned on again (step 37: ST-37), and it is determined whether the illuminance control off signal is applied to the illuminance control off signal. If is applied, the illumination control is no longer executed. If the illumination control off signal is not applied, the control returns to the thirty-second state.

More specifically, the illumination control according to the present invention can preset the illumination intensity for each time in the same manner as the change value of the sunlight amount, for example, only one fluorescent lamp of the lighting unit 26 is turned on during the initial driving (assuming that it is morning). After the predetermined time (for example, about 6 hours) has elapsed, all four fluorescent lamps of the lighting unit 26 are turned on (assuming noon), and after the predetermined time (for example, about 3 hours) has elapsed, the lighting unit 26 Only two fluorescent lamps are lit (assuming afternoon), and when a predetermined time (for example, about 4 hours) has elapsed, all the fluorescent lamps of the lighting unit 26 are turned off to keep the night state. If the above process is repeated again after about 10 hours have elapsed since the lighting unit 26 is turned off, it is possible to provide seeds with roughness similar to the actual amount of sunshine.

At this time, the control of the culture environment for each of the web-based remote plant incubator (2) according to an embodiment of the present invention is the temperature, humidity, roughness control process is not performed sequentially, respectively, is made at the same time.

On the other hand, the web-based remote plant culture control system according to an embodiment of the present invention is not limited only to the above-described embodiment is possible various modifications within the scope not departing from the technical gist.

As described above, the web-based remote plant culture control system according to the present invention can easily remotely control a number of web-based remote plant incubator from one manager PC remotely located, each compartment in advance Depending on the set humidity and temperature, the temperature and humidity can be automatically maintained for each web-based remote plant incubator, and the illumination control allows the illumination to be controlled automatically according to the preset time zone, thereby maintaining the illumination similar to the amount of sunshine. It is effective to provide the culture conditions of.

Claims (6)

Differently controlled remote control signals are generated for each incubator according to the plant information located inside, and a culture room is provided to allow cultivation under different culture conditions for each plant. A plurality of web-based plant cultivators made by comparing the values, and controlling the set illuminance to be automatically adjusted for each time zone; Remote plant culture management server that checks the sensing data for each web-based plant incubator through a monitor by communicating with each of the plurality of web-based plant incubators, and remotely controls temperature, humidity, and illumination with each web-based plant incubator. Web-based remote plant culture control system, characterized in that consisting of. According to claim 1, wherein the web-based plant incubator is equipped with a plant culture room for culturing the plant to the predetermined conditions at the upper end, the lower portion of the plant culture room is equipped with a machine room in which various internal devices are built The plant culture room and the machine room are partitioned by a heat transfer plate, and a web-based remote plant culture control is provided on the bottom surface of the heat transfer plate in which a cold / hot water supply line for distributing cooling / heating circulation water in a zigzag form is disposed. system. 2. The web-based remote plant culture control system according to claim 1, wherein the web-based plant incubator is provided with a temperature / humidity sensor for sensing the temperature and humidity of the plant culture room. According to claim 1, wherein the web-based plant incubator is provided with a heater and a cooler, respectively, to adjust the temperature of the plant culture room therein, a sprayer for adjusting the humidity is provided, to maintain a predetermined roughness Web-based remote plant culture control system, characterized in that a plurality of lights for the attached to the ceiling. According to claim 1, wherein the web-based plant incubator is provided with a data storage unit for storing the control data transmitted from the remote plant culture management server therein, the temperature, humidity, roughness according to the setting data of the data storage unit Web-based remote plant culture control system, characterized in that the control unit is further provided to control. 6. The web-based remote plant culture control according to claim 5, wherein the control unit is set so that the number of illumination of each lighting unit is differently lit according to the type of plants embedded in each plant incubator according to a time elapsed after the initiation time. system.

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