KR20210054770A - An Optimum Growing System for Crop in Greenhouse - Google Patents

Abstract

The present invention relates to an optimal crop growth system for in greenhouse and, more specifically, to an optimal crop growth system that derives optimal growth conditions by a machine learning method using information on an environment inside and outside the greenhouse, the operation information of a greenhouse environment control device controlling the environment of the greenhouse, and growth results, and operates the greenhouse environment control device, thereby maximizing the production efficiency of crops in the greenhouse. The optimal crop growth system comprises a greenhouse environment control device and a management server.

Description

An Optimum Growing System for Crop in Greenhouse}

The present invention relates to an optimal growth system for greenhouse crops, and more particularly, by using the environment information inside and outside the greenhouse, the operation information of the greenhouse environment control device that controls the environment of the greenhouse, and the growth result accordingly, the optimum The present invention relates to an optimal growth system for greenhouse crops that maximizes the production efficiency of greenhouse crops by deriving growth conditions and enabling the operation of a greenhouse environment control device accordingly.

In general, a green house (greenhouse) plays a role in creating an environment suitable for the growth of crops through internal warmth, and is widely used in winter as well as in summer.

In addition, the greenhouse overcomes the poor growth environment that changes by season to stably cultivate and rear agricultural products, and it is possible to cultivate crops continuously throughout the year due to the facilitating and controlled cultivation of crops, and cultivation in the open field. It makes it possible to cultivate and produce special crops that do not work.

However, since it is difficult to meet the appropriate growing environment with the greenhouse itself, a system for artificially controlling the temperature and carbon dioxide concentration of the greenhouse as shown in the following patent documents has been developed and used.

However, there is a problem in that the production efficiency of crops cannot be properly increased as the environment outside the greenhouse changes every moment, the growth environment is different for each crop, and the growth of crops is affected by various environments.

(Patent Literature)

Registered Patent Publication No. 10-1745518 (registered on June 2, 2017) "Growth environment control system of crop growth facility equipped with fan coil unit for greenhouse"

The present invention was devised to solve the above problems,

The present invention uses the environmental information inside and outside the greenhouse, the operation information of the greenhouse environment control device that controls the environment of the greenhouse, and the corresponding growth results, to derive the optimal growth conditions by machine learning method, and accordingly, the greenhouse environment control device The purpose of this is to provide an optimal growth system for greenhouse crops that allows the operation to be performed, thereby maximizing the production efficiency of greenhouse crops.

The present invention allows the operation of the ventilation module, the cooling and heating module, the carbon dioxide generation module, the irrigation module, the opening and closing module according to the temperature outside the greenhouse, the humidity, the solar radiation, the temperature inside the greenhouse, the humidity, the solar radiation, carbon dioxide, soil moisture, and the soil temperature. By doing so, it is an object to provide an optimal growth system for greenhouse crops so that the greenhouse environment can be effectively controlled according to the optimal growth conditions.

An object of the present invention is to provide an optimal growth system for greenhouse crops that allows the growth conditions to be further optimized as time passes by comparing the growth results according to the optimal growth conditions at regular time intervals and updating the growth conditions. have.

The present invention calculates the growth index according to the cost consumed for the control of each growth condition and the contribution to the growth result of each growth condition, so that the selection of the growth condition to be adjusted is made, thereby enabling economic growth of greenhouse crops. The purpose is to provide a growth system.

The present invention makes it easy to install and manage a system by wirelessly receiving environmental information in a greenhouse and operation information of a greenhouse environment control device through a router of a single device capable of using an LTE VPN network from a plurality of greenhouses, The purpose is to provide an optimal growth system for greenhouse crops that can save installation and operation costs.

An object of the present invention is to provide an optimal growth system for greenhouse crops that enables smooth management of a plurality of greenhouses by distributing environmental information and operation information inside and outside a greenhouse received through a router to a plurality of management servers.

The present invention is implemented by an embodiment having the following configuration in order to achieve the above object.

According to an embodiment of the present invention, a greenhouse crop optimal growth system according to the present invention includes a greenhouse environment measuring device that measures environmental information in a greenhouse in which crops are grown, a greenhouse environment control device that artificially controls the environment in the greenhouse, It includes a management server that controls the operation of the greenhouse environment control device to suit the growing conditions of crops in the greenhouse, and the management server includes environmental information in the greenhouse, environmental information outside the greenhouse, and It is characterized in that the operation information of the greenhouse environment control device is collected, the correlation with the growth result of the crop is analyzed, and the growth conditions are set according to the analyzed correlation to control the operation of the greenhouse environment control device.

According to another embodiment of the present invention, in the system for optimal growth of greenhouse crops according to the present invention, the management server comprises: an external environment information receiving unit for collecting and storing weather information around the greenhouse; An internal environment information receiving unit for receiving environmental information in the greenhouse measured by the greenhouse environment measuring device; An operation information receiving unit for receiving operation information of the greenhouse environment control device; A growth information input unit for inputting information on the growth result of the crop; An optimal growth condition derivation unit for deriving an optimal growth condition according to the internal and external environmental information of the greenhouse, operation information of the greenhouse environment control device, and the growth result; It characterized in that it comprises a; operation control unit for controlling the operation of the greenhouse environment control device according to the derived growth conditions.

According to another embodiment of the present invention, in the system for optimal growth of greenhouse crops according to the present invention, the growth condition extraction unit is characterized in that the optimal growth conditions are derived by a machine learning technique using a circulatory neural network.

According to another embodiment of the present invention, in the system for optimal growth of greenhouse crops according to the present invention, the external environment information receiving unit collects and stores information on temperature, humidity, and insolation around the greenhouse, and the internal environment information The receiving unit receives and stores information on the temperature, humidity, insolation, carbon dioxide, soil moisture, and soil temperature in the greenhouse measured by the greenhouse environment measuring device, and the greenhouse environment control device is a ventilation module that controls ventilation in the greenhouse. Each operation information is stored by the operation information receiving unit, including a cooling/heating module for controlling temperature, a carbon dioxide generating module for generating carbon dioxide, an irrigation module for supplying water, an opening/closing module for opening and closing a part of the side or ceiling, It is characterized in that each operation is controlled by an operation control unit.

According to another embodiment of the present invention, in the greenhouse crop optimal growth system according to the present invention, the growth information input unit includes a size information input module for inputting crop size information, and photosynthesis for inputting information on the amount of photosynthesis of the crop. It characterized in that it comprises an information input module.

According to another embodiment of the present invention, in the greenhouse crop optimal growth system according to the present invention, the management server adjusts the operation of the greenhouse environment control device by the operation control unit and changes the growth conditions according to the growth result of the crop afterwards. It characterized in that it comprises a growing condition update unit.

According to another embodiment of the present invention, in the system for optimal growth of greenhouse crops according to the present invention, the growth condition update unit includes a growth result comparison module that compares growth results at regular time intervals, and an optimal growth result according to the compared growth results. It characterized in that it comprises a growing condition change module for changing the growing condition.

According to another embodiment of the present invention, in the greenhouse crop optimal growth system according to the present invention, the growth condition update unit calculates a growth index according to the cost consumed for controlling each growth condition and the contribution to the growth result. A growth index calculation module, a growth condition selection module that selects growth conditions to be adjusted according to the growth index, a growth condition comparison module that compares growth results according to the controlled growth conditions, and growth according to the growth results of each growth condition It characterized in that it comprises a growth index update module for updating the index.

According to another embodiment of the present invention, a system for optimal growth of greenhouse crops according to the present invention includes: a router for receiving and transmitting wireless signals regarding internal environment information and operation information of a greenhouse environment control device from a plurality of greenhouses; Ethernet connected to the router and transmitting internal environment information and operation information to the management server; Including, wherein the router is formed as a single device receiving radio signals from a plurality of greenhouses using an LTE VPN network. .

According to another embodiment of the present invention, the system for optimal growth of greenhouse crops according to the present invention comprises a distribution server for distributing environmental information and operation information inside and outside a greenhouse transmitted through the Ethernet to a management server for each greenhouse. It is done.

The present invention can obtain the following effects by the configuration, combination, and use relationship to be described below with the present embodiment.

The present invention uses the environmental information inside and outside the greenhouse, the operation information of the greenhouse environment control device that controls the environment of the greenhouse, and the corresponding growth results, to derive the optimal growth conditions by machine learning method, and accordingly, the greenhouse environment control device By allowing the operation to occur, there is an effect of maximizing the production efficiency of greenhouse crops.

The present invention allows the operation of the ventilation module, the cooling and heating module, the carbon dioxide generation module, the irrigation module, the opening and closing module according to the temperature outside the greenhouse, the humidity, the solar radiation, the temperature inside the greenhouse, the humidity, the solar radiation, carbon dioxide, soil moisture, and the soil temperature. By doing so, there is an effect to effectively control the greenhouse environment according to the optimal growth conditions.

The present invention has the effect of allowing the growth conditions to be further optimized as time elapses by comparing the growth results according to the optimal growth conditions at regular time intervals so that the growth conditions are updated.

The present invention has the effect of enabling economic growth by calculating the growth index according to the cost consumed for the control of each growth condition and the contribution to the growth result of each growth condition, and selecting the growth condition to be controlled. .

The present invention makes it easy to install and manage a system by wirelessly receiving environmental information in a greenhouse and operation information of a greenhouse environment control device through a router of a single device capable of using an LTE VPN network from a plurality of greenhouses, It has the effect of saving installation and operation costs.

The present invention has an effect of distributing environmental information and operation information inside and outside a greenhouse received through a router to a plurality of management servers, thereby enabling smooth management of a plurality of greenhouses.

1 is a configuration diagram of a greenhouse crop optimal growth system according to an embodiment of the present invention
Figure 2 is a block diagram showing the configuration of the greenhouse environment measuring apparatus of Figure 1
Figure 3 is a block diagram showing the configuration of the greenhouse environment control device of Figure 1
Figure 4 is a block diagram showing the configuration of the management server of Figure 1
5 is a block diagram showing the configuration of the external environment information receiving unit of FIG. 4
6 is a block diagram showing the configuration of the internal environment information receiving unit of FIG. 4
7 is a block diagram showing the configuration of the operation information receiving unit of FIG. 4
8 is a block diagram showing the configuration of the growth information input unit of FIG. 4
9 is a block diagram showing the configuration of the operation control unit of FIG. 4
10 is a block diagram showing the configuration of the growing condition updating unit of FIG. 4
11 is a configuration diagram of a greenhouse crop optimal growth system according to another embodiment of the present invention
12 is a configuration diagram of a conventional greenhouse crop optimal growth system

Hereinafter, preferred embodiments of the optimal greenhouse crop growth system according to the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, when it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. Throughout the specification, when a part "includes" a certain component, it means that other components may be further included, and other components are not excluded unless specifically stated to the contrary, and also described in the specification. Terms such as "... unit" and "... module" mean a unit that processes at least one function or operation, which may be implemented by hardware or software, or a combination of hardware and software.

Referring to Figures 1 to 10, the greenhouse crop optimal growth system according to an embodiment of the present invention, the greenhouse crop optimal growth system is a greenhouse environment measuring device that measures environmental information in the greenhouse (W) where crops are grown. (1) And, a greenhouse environment control device that artificially controls the environment in the greenhouse (W) (2), and a management that controls the operation of the greenhouse environment control device (2) to suit the growing conditions of crops in the greenhouse (W). It includes a server (3).

In particular, the greenhouse crop optimal growth system according to the present invention includes environmental information around the greenhouse (W) for a certain period of time, environmental information in the greenhouse (W) measured by the greenhouse environment measuring device (1), and the greenhouse environment control device (2). ), and the information on the growth results of the crops are stored and the correlations between them are analyzed by machine learning techniques to derive the optimal growth conditions for the crops in the greenhouse (W). In addition, the present invention enables optimal growth of crops by operating the greenhouse environment control device 2 according to the derived optimal growth conditions, and by checking the growth results of the crops at regular time intervals, optimal growth conditions and greenhouses By controlling the operating degree of the environmental control device 2, it is possible to further increase the production efficiency of crops as time passes.

The greenhouse environment measuring device (1) is a component that measures environmental information in the greenhouse (W), and the measured information is transmitted to the management server (3) and used to derive the optimal growth conditions. (W) It is also used to control the degree of operation of the greenhouse environment control device (2) to control the internal environment. The greenhouse environment measuring device 1 measures not only the temperature, humidity, solar radiation, and carbon dioxide amount in the greenhouse, but also the moisture and temperature of the soil in which crops are planted. To this end, the temperature measuring module 11 and the humidity measuring module 12 ), a humidity measurement module 13, a carbon dioxide measurement module 14, a soil moisture measurement module 15, and a soil temperature measurement module 16. The temperature measurement module 11, the humidity measurement module 12, the humidity measurement module 13, the carbon dioxide measurement module 14, the soil moisture measurement module 15, the soil temperature measurement module 16 is in the greenhouse (W). It is formed to measure information such as temperature and humidity in real time, and the measured information is transferred to and stored in the management server 3, and is used for derivation of optimal growth conditions and operation of the greenhouse environment control device 2.

The greenhouse environment control device 2 is configured to control the environment in the greenhouse (W), and controls the temperature, humidity, amount of carbon dioxide, solar radiation, soil moisture and temperature in the greenhouse (W). To this end, the greenhouse environment control device 2 may include a ventilation module 21, a cooling and heating module 22, a carbon dioxide generation module 23, an irrigation module 24, a side ceiling opening/closing module 25, and the like. In addition, other devices necessary for the growth of crops may be additionally installed.

The ventilation module 21 is configured to circulate air inside and outside the greenhouse (W), and can be operated to control temperature and humidity in the greenhouse (W), the amount of carbon dioxide, etc., and the ventilation control module 362, which will be described later. ), the operation is automatically controlled.

The cooling/heating control module 363 is configured to control the temperature in the greenhouse (W), and may also be used for humidity control. The heating/cooling control module 363 is operated by the heating control module 363.

The carbon dioxide generation module 23 is configured to generate carbon dioxide in the greenhouse (W), and is used to promote photosynthesis of crops, and the operation is controlled by the carbon dioxide control module 364.

The irrigation module 24 is configured to supply water to crops and/or soil in the greenhouse (W), and can be operated to control moisture and temperature of the soil, and also to control humidity in the greenhouse (W). Can be used. The irrigation module 24 is controlled by an irrigation control module 365, which will be described later, of the management server 3.

The side ceiling opening/closing module 25 is configured to open and close a side of the greenhouse (W) or a portion of the ceiling, and can be operated to control the amount of insolation in the greenhouse (W), by the opening and closing control module 366 The operation is regulated.

The management server 3 derives optimal growth conditions for crops according to environmental information inside and outside the greenhouse, operation information of the greenhouse environment control device 2, and the growth results of the crops, and a greenhouse environment control device ( It is a configuration that allows the operation of 2) to be controlled, and it is possible to control the growth environment for a plurality of greenhouses (W) and crops. To this end, the management server 3 receives and stores the environmental information inside and outside the greenhouse for a certain period of time, the operation information of the greenhouse environment control device 2, and the information on the growth result of the crop. Is analyzed to derive the optimal growth conditions for the crop and greenhouse. And the management server (3) operates the greenhouse environment control device (2) according to the optimal growth conditions according to the environmental information inside and outside the greenhouse received in real time, and receives the growth result information for this, and continuously updates the optimal growth conditions Let this happen. To this end, the management server 3 may include an external environment information receiving unit 31, an internal environment information receiving unit 32, an operation information receiving unit 33, an operation control unit 36, and a growing condition update unit 37. have.

The external environment information receiving unit 31 is configured to receive and store external environment information around the greenhouse (W), and to receive environmental information of the point where the greenhouse (W) is located from an external server such as the Meteorological Administration, for example. A temperature information receiving module 311 for receiving temperature, humidity, and insolation information, a humidity information receiving module 312, and an insolation information receiving module 313 may be included. However, the external environment information receiving unit 31 can collect various other information to derive the optimal growth conditions, and collect information in real time to derive the optimal growth conditions and control the greenhouse environment according to the optimal growth conditions. (2) allows the operation to be made.

The internal environment information receiving unit 32 is configured to receive and store the environment information in the greenhouse (W) measured by the greenhouse environment measuring device 1, a temperature receiving module 321, a humidity receiving module 322, Insolation receiving module 323, carbon dioxide receiving module 324, soil moisture receiving module 325, soil temperature receiving module 326 receives and stores information of temperature, humidity, insolation, carbon dioxide, soil moisture, soil temperature You can do it. The internal environment information receiving unit 32 receives and stores the environmental information in the greenhouse (W) in real time, and the optimal growth environment conditions are derived by analyzing the correlation with the growth result according to the stored information for a certain period of time. To be able to be. In addition, after the growth environment conditions are derived, the internal environment information receiving unit 32 transmits the internal environment information received in real time to the operation control unit 36 to control the operation of the greenhouse environment control device 2 according to the optimal growth conditions. To be able to be.

The operation information receiving unit 33 is configured to receive and store information on the operation of the greenhouse environment control device 2, and receive and store information on the operation degree and operation time of the greenhouse environment control device 2 . The operation information receiving unit 33 is provided by the ventilation information receiving module 331, the cooling and heating information receiving module 332, the carbon dioxide generation information receiving module 333, the irrigation information receiving module 334, the opening/closing information receiving module 335. It is possible to receive and store operation information of the ventilation module 21, the cooling and heating module 22, the carbon dioxide generation module 23, the irrigation module 24, and the side ceiling opening/closing module 25, respectively. The operation information of the greenhouse environment control devices (2) received and stored by the operation information receiving unit (33) is used to analyze the correlation with the growth results together with the environmental information inside and outside the greenhouse (W), through which optimal growth conditions To be able to derive.

The growth information input unit 34 is configured to input information on the growth result of the crop, and can be input through a separate user terminal, and can input information on the size of the crop and the amount of photosynthesis. . To this end, the growth information input unit 34 allows the size information input module 341 and the photosynthesis information input module 342 to input information on the size of the crop and the amount of photosynthesis. For example, the size information input The module 341 and the photosynthesis information input module 342 may be configured to be automatically input by a separate device that measures the size or photosynthetic amount of crops.

The optimal growth condition derivation unit 35 is configured to derive an optimum crop growth condition with good growth results for a specific crop in a specific greenhouse (W), and is received by the external environment information receiving unit 31 for a certain period of time. The greenhouse (W) external environment information, the environment information in the greenhouse (W) received by the internal environment information receiving unit 32, the operation information of the greenhouse environment control device (2) received by the operation information receiving unit (33) The correlation between the growth result information of the crop and the growth information inputted by the growth information input unit 34 is analyzed by a machine learning method to derive the optimal growth conditions. For example, the optimal growth condition derivation unit 35 may derive an optimal growth condition using a recurrent neural network model, and various deep learning models may be used. The optimal growth condition derivation unit 35 may derive the optimum growth conditions for temperature, humidity, solar radiation, carbon dioxide amount, soil moisture, soil temperature, etc. for each growth period of individual crops, and consider current environmental information. It is possible to control the operation of the greenhouse environment control device (2), and to achieve optimal control by analyzing the correlation of the operation degree of the greenhouse environment control device (2) according to the difference between the current environment information and the optimal environment information. have.

The operation control unit 36 is a configuration for controlling the operation of the greenhouse environment control device 2, and controls the operation of the greenhouse environment control device 2 according to the optimum growth conditions derived by the optimum growth condition drawing unit 35. Adjust it. The operation control unit 36 enables the operation of the greenhouse environment control device 2 according to the difference according to the optimum growth condition and the current greenhouse (W) environment, and the environment information receiving module 361, the ventilation control module ( 362), carbon dioxide control module 364, irrigation control module 365, may include an opening and closing control module 366.

The environmental information receiving module 361 is configured to receive information on the environment inside and outside the greenhouse (W), and controls the operation of the greenhouse environment control device 2 according to the difference between the received environmental information and the optimal growing conditions. .

The ventilation control module 362 is configured to control the operation of the ventilation module 21, and the operation can be adjusted according to temperature, humidity, etc., and operation set according to the difference between actual environmental information and optimal growth conditions. To the extent that the ventilation control module 362 is operated. For example, the ventilation control module 362 may allow external air to flow into the greenhouse W when the external temperature is high but the internal temperature is lower than the optimum growth condition, and the external humidity is high but the internal humidity is lower than the optimum growth condition. Even in the case, outside air can be introduced into the greenhouse (W).

The cooling/heating control module 363 is configured to control the operation of the cooling/heating module 22, and the operation is controlled according to the temperature in the greenhouse (W). The cooling/heating control module 363 may preferentially operate the ventilation module 21 in order to reduce consumed power, and when it is difficult to control the temperature by the ventilation module 21, the operation of the cooling/heating control module 363 is difficult. You can make it happen.

The carbon dioxide control module 364 is configured to control the operation of the carbon dioxide generating module 23, and when the amount of carbon dioxide in the greenhouse W is insufficient, the carbon dioxide generating module 23 is operated to reduce carbon dioxide in the greenhouse (W). Supply, and through this, smooth photosynthesis can be achieved.

The irrigation control module 365 is configured to control the operation of the irrigation module 24 and may supply water according to the moisture of the soil or the temperature of the soil.

The opening and closing control module 366 is a configuration for controlling the operation of the side ceiling opening and closing module 25, depending on the difference between the optimal growth conditions for the amount of insolation and the amount of insolation in the greenhouse (W) side or part of the ceiling. Can be opened or closed.

The growth condition update unit 37 is configured to update the optimal growth condition of the crop by observing the growth result of the crop at regular time intervals, and is updated to a condition that can derive the optimum growth result as time passes. To further increase the production efficiency of crops. In addition, the growth condition update unit 37 selects the cost for adjusting various growth conditions such as temperature, humidity, insolation, carbon dioxide, etc. and conditions that can have an optimal growth effect according to the growth result, thereby controlling the environment. By making it possible to further increase production efficiency. To this end, the growth condition update unit 37 includes a growth result comparison module 371, a growth index calculation module 372, a growth condition selection module 373, a growth condition change module 374, and a comparison module for each growth condition ( 375), may include a growth index update module (376).

The growth result comparison module 371 is a configuration that compares the growth result of a crop, which is a criterion for setting the optimal growth condition, and the growth result after a certain period of time. When the growth result does not meet the standard, the growth condition is changed. .

The growth index calculation module 372 is configured to calculate the growth index for each condition when the growth condition is changed, and calculates the growth index in consideration of the effect of the change of each growth condition and the cost consumed for the change. . For example, the growth index calculation module 372 may have a higher growth index as the cost consumed for changing the growth conditions is small and the cost-effectiveness increases.

The growth condition selection module 373 is configured to select a growth condition to be changed, and compares the growth index of each condition calculated by the growth index calculation module 372 to select a growth condition having a high growth index. Therefore, the growth condition selection module 373 allows more efficient growth conditions to be derived by first changing the growth conditions that have the most cost-effectiveness when the growth results according to the optimal growth conditions do not meet the standard. In addition, the growth condition selection module 373 excludes the growth conditions that have been previously selected and changed, and selects the growth conditions having the next growth index, and the change of the growth conditions continues until the growth results are improved.

The growth condition change module 374 is configured to change the growth condition selected by the growth condition selection module 373, and allows the operation of the greenhouse environment control device 2 to be controlled according to the changed growth condition. Therefore, the growth condition change module 374 searches for growth conditions that can bring better growth results over time in the optimal growth conditions initially derived, thereby increasing the production efficiency of greenhouse crops as time goes by. You can make it higher.

The comparison module 375 for each growing condition is configured to compare the growth results for each condition to be controlled, and allows the growth index to be changed by reflecting the growth result according to the change of each condition.

The growth index update module 376 is configured to update the growth index according to the result compared by the comparison module 375 for each growth condition. In the future, it is possible to select growth conditions accordingly.

Referring to Figures 11 to 12, the greenhouse crop optimal growth system according to another embodiment of the present invention, the greenhouse crop optimal growth system is internal environmental information and greenhouse environment control device (2) from a plurality of greenhouses (W). A router (4) for receiving and transmitting a radio signal related to the operation information of the device; Ethernet (5) connected to the router (4) to transmit internal environmental information and operation information to the management server (3); It includes a distribution server (6) for distributing the environmental information and operation information inside and outside the greenhouse (W) transmitted through the Ethernet (5) to the management server (3) for each greenhouse (W). In particular, the router 4 is formed as a single device that receives radio signals from a plurality of greenhouses using an LTE VPN network, so that the system can be installed and operated easily and economically.

In order to manage a plurality of greenhouses (W) using wireless communication in the related art, a greenhouse environment measuring device (1) and a greenhouse environment control device (2) formed in each greenhouse (W) as shown in FIG. 12. In order to receive environmental information and operation information in the greenhouse (W) from each, it was necessary to form a plurality of routers. In addition, the greenhouse environment measurement device 1 includes a temperature measurement module 11, a humidity measurement module 12, an insolation measurement module 13, a carbon dioxide measurement module 14, a soil moisture measurement module 15, and a soil temperature measurement module. (16), etc. are included, and the greenhouse environment control device (2) includes a ventilation module (21), a cooling/heating module (22), a carbon dioxide generation module (23), an irrigation module (24), and a side ceiling opening/closing module (25). Since a larger number of routers had to be installed in order to receive information wirelessly from each of the included bars, there was a problem that a lot of equipment was put into the system configuration and the installation and operation costs were excessively consumed.

Therefore, in the present invention, by using the LTE VPN network to receive various environmental information about a plurality of greenhouses (W) through the router 4 of a single device, the system configuration is made very simple, and the operation and management are also very simple. It was made to be done comfortably.

The router 4 is configured to receive environmental information in the greenhouse (W) measured from a plurality of greenhouses (W) and operation information of the greenhouse environment control device (2) through a wireless signal and transmit it to the management server (3). , It is formed as a single device capable of receiving a radio signal using an LTE VPN network. Here, the VPN (Virtual Private Network) refers to a virtual private network, and the LTE VPN refers to a network network that can use a public network that transmits and receives LTE radio signals like a leased line. Therefore, the router 4 capable of using the LTE VPN can collect weather information from a plurality of greenhouses W with a single device, and through this, it is possible to construct and operate the system at low cost. In addition, the router 4 is also connected to an external server O such as the Meteorological Agency, so that information about the external environment of the greenhouse W can also be received.

The Ethernet 5 refers to a method of a commonly used local area network, and transmits environmental information by wired connection between the router 4 and the management server 3. At this time, environmental information and the like through the Ethernet 5 are transmitted to the plurality of management servers 3 so that environmental control for the plurality of greenhouses W can be smoothly performed.

The distribution server 6 is formed between the Ethernet 5 and the management server 3 to distribute environmental information and the like to each management server 3. Since the management server (3) is formed in a plurality to enable optimal growth system control for each of a plurality of greenhouses (W), the distribution server (6) is a greenhouse environment measuring device (1) of each greenhouse (W) , The information received from the greenhouse environment control device 2 and the external environment information transmitted from the external server are distributed to and transmitted to the management server 3 for each greenhouse (W). At this time, the information transmitted from each greenhouse environment measurement device (1) and greenhouse environment control device (2) can be classified for each greenhouse (W), including identification information for each greenhouse (W), and transmitted from an external server. External environmental information can be distributed using the location information of the greenhouse (W).

Therefore, in this embodiment, it is possible to wirelessly receive environmental information from a plurality of devices of a plurality of greenhouses (W) with only a simple configuration, and information about each greenhouse (W) is distributed to a management server for each greenhouse (W). In (3), since the greenhouse environment is controlled using this, effective and economical optimal growth for a plurality of greenhouses (W) is possible.

In the above, the applicant has described various embodiments of the present invention, but such embodiments are only one embodiment embodying the technical idea of the present invention, and any changes or modifications may be made as long as the technical idea of the present invention is implemented. It should be construed as falling within the scope of.

1: Greenhouse environment measuring device
11: Temperature measurement module 12: Humidity measurement module 13: Insolation measurement module
14: carbon dioxide measurement module 15: soil moisture measurement module 16: soil temperature measurement module
2: Greenhouse environment control device
21: ventilation module 22: cooling and heating module 23: carbon dioxide generation module
24: irrigation module 25: side electric field opening and closing module
3: Management server
31: external environment information receiving unit 311: temperature information receiving module
312: humidity information receiving module 313: insolation information receiving module
32: internal environment information receiving unit 321: temperature receiving module 322: humidity receiving module
323: insolation receiving module 324: carbon dioxide receiving module 325: soil moisture receiving module
326: soil temperature receiving module 331: ventilation information receiving module 332: heating information receiving module
333: carbon dioxide generation information receiving module 334: irrigation information receiving module
335: opening and closing information receiving module 33: operation information receiving unit 34: growth information input unit
341: size information input module 342: photosynthesis information input module
35: optimal growth condition derivation unit 36: operation control unit 361: environmental information receiving module
362: ventilation control module 363: heating control module 364: carbon dioxide control module
365: irrigation control module 366: open/close control module 37: growth condition update unit
371: growth result comparison module 372: growth index calculation module 373: growth condition selection module
374: growing condition change module 375: comparison module for each growing condition
376: growth index update module
4: Router 5: Ethernet 6: Distribution Server

Claims (10)

A greenhouse environment measuring device that measures environmental information in the greenhouse where crops are grown,
A greenhouse environment control device that artificially controls the environment in the greenhouse,
It includes a management server that controls the operation of the greenhouse environment control device to suit the growing conditions of crops in the greenhouse,
The management server,
For a certain period of time, by collecting environmental information in the greenhouse measured from the greenhouse environment measuring device, environmental information outside the greenhouse, and operating information of the greenhouse environment control device, analyzing the correlation with the growth result of crops, and growing according to the analyzed correlation. Greenhouse crop optimal growth system, characterized in that to control the operation of the greenhouse environment control device by setting conditions. The method of claim 1, wherein the management server
An external environment information receiving unit that collects and stores weather information around the greenhouse; An internal environment information receiving unit for receiving environmental information in the greenhouse measured by the greenhouse environment measuring device; An operation information receiving unit for receiving operation information of the greenhouse environment control device; A growth information input unit for inputting information on the growth result of the crop; An optimal growth condition derivation unit for deriving an optimal growth condition according to the internal and external environmental information of the greenhouse, operation information of the greenhouse environment control device, and the growth result; An optimal growth system for greenhouse crops, comprising: an operation control unit that controls the operation of the greenhouse environment control device according to the derived growth conditions. The method of claim 2, wherein the growth condition extraction unit
Optimal growth system for greenhouse crops, characterized in that to derive optimal growth conditions by a machine learning technique using a circulatory neural network. The method of claim 3, wherein the external environment information receiving unit
Collect and store information on temperature, humidity, and solar radiation around the greenhouse,
The internal environment information receiving unit receives and stores information on temperature, humidity, insolation, carbon dioxide, soil moisture, and soil temperature in the greenhouse measured by the greenhouse environment measuring device,
The greenhouse environment control device,
Each operation information includes a ventilation module that controls ventilation in the greenhouse, a cooling and heating module that controls temperature, a carbon dioxide generation module that generates carbon dioxide, an irrigation module that supplies water, and an opening/closing module that opens and closes a part of the side or ceiling. An optimal growth system for greenhouse crops, characterized in that it is stored by the operation information receiving unit, and that each operation is controlled by the operation control unit. The method of claim 4, wherein the growth information input unit
A greenhouse crop optimal growth system, comprising: a size information input module for inputting crop size information, and a photosynthesis information input module for inputting information on the amount of photosynthesis of the crop. The method of claim 4, wherein the management server
And a growing condition update unit that adjusts the operation of the greenhouse environment control device by the operation control unit and changes the growing condition according to the growth result of the crop afterwards. The method of claim 6, wherein the growing condition update unit
A greenhouse crop optimal growth system, comprising: a growth result comparison module that compares growth results at regular time intervals, and a growth condition change module that changes optimal growth conditions according to the compared growth results. The method of claim 7, wherein the growing condition update unit
A growth index calculation module that calculates a growth index according to the cost and contribution to growth results for the control of each growth condition, a growth condition selection module that selects growth conditions to be adjusted according to the growth index, and the controlled growth conditions Optimal growth system for greenhouse crops, characterized in that it comprises a comparison module for each growth condition for comparing the growth results according to, and a growth index update module for updating the growth index according to the growth results for each growth condition. The method of claim 1, wherein the greenhouse crop optimal growth system
A router for receiving and transmitting wireless signals regarding internal environment information and operation information of the greenhouse environment control device from a plurality of greenhouses;
Including; Ethernet connected to the router to transmit internal environment information and operation information to the management server,
The router is a greenhouse crop optimal growth system, characterized in that formed as a single device that receives radio signals from a plurality of greenhouses using an LTE VPN network. The method of claim 9, wherein the greenhouse crop optimal growth system
The greenhouse crop optimal growth system, characterized in that it comprises a distribution server for distributing environmental information and operation information inside and outside the greenhouse transmitted through the Ethernet to a management server for each greenhouse.

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