JP6964845B2 - Plant cultivation system - Google Patents

Description

The present invention provides a system for cultivating plants regardless of the influence of the place, a system for cultivating vegetables suitable for the user's health condition by an optimum method, and an optimum condition setting for various conditions for cultivating plants. Regarding the cultivation system to be found.

Conventionally, a technique for artificially controlling the cultivation conditions of plants such as vegetables by using an artificial light source such as an LED has been proposed. For example, Patent Document 1 describes a system for monitoring and controlling a plant growing environment such as light and temperature in a closed space such as a room not only at a cultivation place but also from a distance using a terminal device.

Japanese Unexamined Patent Publication No. 2014-217309

The above-mentioned prior art effectively monitors and controls the plant at the plant cultivation site and the plant at a location other than the plant cultivation site (hereinafter referred to as "distant"). Information can be provided to the trainer. Although this technique can provide a plant cultivation system that is highly convenient for growers, it cannot be compared with the growth status of other growers only by telling the current growth status of the relevant cultivation. Moreover, the optimization of cultivation cannot be achieved. In addition, it was impossible to easily provide information on cultivation that matches the user's situation.

The present invention has been made in response to such conventional circumstances, and an object of the present invention is a cultivation system that can easily cultivate a plant that matches a user's nutritional status, for example. In addition, we aim to realize a plant cultivation system that can find the optimum cultivation conditions by utilizing AI while there are many parameters in plant cultivation, and further evolve daily from the cultivation condition data and growth data collected daily. The target is a plant cultivation system.

(First viewpoint)
According to the first aspect of the present invention, a lighting means for cultivating a plant, an illumination light control means for controlling the illumination light, a fertilizer supply means for supplying fertilizer to the plant, and a fertilizer supply for controlling the fertilizer supply. A plant cultivation system characterized by being composed of control means is provided.

The plant cultivation system may further include a water supply means for supplying water to the plant and a water supply control means for controlling the water supply for controlling the water supply means.

The fertilizer supply means may supply the water of the water supply means.

The fertilizer supply control means for controlling the fertilizer supply may be capable of selectively controlling the type of fertilizer.

The fertilizer supply means may be composed of a fertilizer cartridge in which fertilizer is adjusted according to a purpose, and the type of fertilizer may be controlled by selecting the fertilizer cartridge to control the type of fertilizer to be supplied to the plant.
Here, the plant cultivation system is connected to a network, and a server and a product supply center are provided in the network, and the server acquires fertilizer data of the user plant cultivation system and needs to add fertilizer. The fertilizer cartridge delivery information may be sent from the server center to the product supply center, and the product supply center may perform the fertilizer cartridge delivery process to the user of the corresponding user system.
Further, a user ID is assigned to the cultivation system of the user, the server center generates a consumable ID in the fertilizer cartridge sent to the user in correspondence with the user ID, and the product supply center generates the consumable ID. Even if the user cultivation system is provided with a fertilizer cartridge reading means and has a determination means for determining whether or not it matches the consumables ID generated at the server center by associating the fertilizer cartridge ID to be actually delivered. good.

The plant cultivation system is connected to a network, a server is provided in the network, and the illumination light control means and the fertilizer supply control means are controlled from the network or necessary information is downloaded from the server through the network and downloaded data. It may be controlled by, or it may be controlled directly from the server through the network.

The plant cultivation system may be provided with plant cultivation monitoring means and further connected to a network, the network may be provided with a server, and the sensor data may be transmitted to the server.
Here, the plant cultivation monitoring means may include a growth monitoring means.
Further, the growth monitoring means may be composed of a camera and may monitor the growth by analyzing the image acquired by the camera.
The plant cultivation monitoring means has an abnormality determining means, and may transmit a warning signal to a user terminal when an abnormality occurs.
The plant cultivation monitoring means has a fertilizer remaining amount measuring means for measuring the remaining amount of fertilizer, and when the remaining amount of fertilizer is below a certain level, a fertilizer remaining amount signal may be transmitted to the user terminal.
The plant cultivation monitoring means has a fertilizer remaining amount measuring means for measuring the remaining amount of fertilizer, and when the remaining amount of fertilizer is below a certain level, the user may be requested to send a new fertilizer.
The monitoring means may be accessible from a user terminal connected to the net, and the user may be able to confirm the state of the plant through the monitoring means.

The plant cultivation system may be connected to a network, and a server may be provided on the network and the server may have a user data collecting means for collecting data of each user plant cultivation system.
Here, the user data collecting means for collecting the data of the user system may include plant growth data.
Further, the growth data may be collected by acquiring and analyzing an image with a camera provided in the user system.
The analysis may analyze the height, area, or both data of the plant.
The user data collecting means for collecting the data of the user system may include the data collected by the sensor on the cultivation conditions of the plants of each user system.
The sensor may be at least one sensor selected from temperature, humidity, illuminance, carbon dioxide concentration, air volume, and pH of water.
The server center may have a user data analysis means for analyzing the data collected through the user data collection means.
The user data analysis means may have an optimum condition search means for comparing the data of each user and searching for the optimum conditions for plant growth.
The optimum condition search means may further include a user contribution calculation means for calculating the ratio of each data of each user's plant cultivation system contributing to the searched optimum conditions.
The contribution calculation means may calculate the similarity between the searched optimum condition and the condition of the corresponding user.
The user system has a user evaluation input means for collecting user evaluations, and the data collected by the user data collecting means may include the data collected by the user evaluation input means.
The user's evaluation may be the texture of the user.

The user can set various conditions to be controlled by the plant cultivation system, and the user may be able to set directly on the user plant cultivation system.
Here, the various conditions of the control target may include fertilizer and illumination light, and may further control temperature, humidity, water, carbon dioxide concentration, and wind as necessary.

The user can set various conditions of the plant cultivation system, and the user may be able to set various conditions from the user terminal through the network.
Here, it is assumed that the user inputs the user's request from the user terminal, analyzes the request on the server, searches for the optimum cultivation condition for the user, sets the cultivation condition, and cultivates under the cultivation condition in the user cultivation system. May be good

The fertilizer supply control means may be characterized in that the type and supply amount of fertilizer can be controlled.
Here, the control of the type of fertilizer may be performed by providing a fertilizer cartridge having a plurality of different types of fertilizer in the user system and selecting the fertilizer cartridge to select the type of fertilizer.

The plant cultivation system may further include temperature control means for controlling the temperature.

The illumination light may be a red LED, an infrared LED, a blue LED, a green LED, an ultraviolet LED, sunlight guided by an optical fiber, or a combination thereof.
Here, the plant cultivation system is connected to a network, a server is provided in the network, and the illumination light control means controls from the network or downloads necessary information from the server through the network and controls with the downloaded data. Alternatively, it may be controlled directly from the server through the network.

The plant cultivation system may further include gaseous carbon dioxide control means for controlling the carbon dioxide concentration in the air.
Here, the plant cultivation system is connected to a network, a server is provided in the network, and the gaseous carbon dioxide control means controls from the network or downloads necessary information from the server through the network, and uses the downloaded data. It may be controlled or controlled directly from the server through the network.

The plant cultivation system may further include carbon dioxide solubilization control means for adding carbon dioxide to water.
Here, the carbon dioxide solubilization control means may add carbon dioxide by a carbon dioxide cartridge (cylinder).

The plant cultivation system is connected to a network, a server is provided in the network, and the carbon dioxide water solubilization control means controls from the network or downloads necessary information from the server through the network and controls with the downloaded data. Alternatively, it may be controlled directly from the server through the network.

The plant cultivation system may further have a replaceable medium.
The plant cultivation system may be connected to a network, and a server may be provided in the network so that the user can input the type of medium and transmit the type of medium to the server.

The plant cultivation system may further include a humidity adjusting means and a humidity adjusting controlling means for controlling the humidity adjusting means.
Here, the plant cultivation system is connected to a network, a server is provided in the network, and the humidity control control means controls from the network or downloads necessary information from the server through the network and controls with the downloaded data. Alternatively, it may be controlled directly from the server via the network.

The plant cultivation system may further include a blowing means and a blowing control means for controlling the blowing means.
The plant cultivation system is connected to a network, a server is provided in the network, and the ventilation control means controls from the network or downloads necessary information from the server through the network, and controls with the downloaded data, or from the server. It may be controlled directly through the network.

(Second perspective)
According to the second aspect of the present invention, a lighting means for cultivating a plant, an illumination light control means for controlling the illumination light, and a cultivation data collection for collecting plant cultivation data including data on a growth state of the plant-cultivated plant. It is composed of a plurality of plant cultivation systems composed of means, the plant cultivation system is connected to a network, a server center is provided on the network, and the server center collects data of the plant cultivation system of each user. A plant cultivation system characterized by having a means for collecting user data to be collected is provided.

In the second aspect, the collected data is quantified so that the data of one or more cultivation conditions, one or more plant growth states, or both of the above growth state data can be compared with others. It may be data.

(Third perspective)
According to the third aspect of the present invention, it includes data on a lighting means for cultivating a plant, an illumination light control means for controlling the illumination light, one or more cultivation conditions for the plant cultivation, and one or more plant growth states. Cultivation to collect data It is composed of a plurality of plant cultivation systems composed of data collecting means, the plant cultivation system is connected to a network, a server center is provided on the network, and each user's in the server center is provided. Provided is a plant cultivation system characterized by having a user data collecting means for collecting data of the plant cultivation system.

From the third viewpoint, the data in the growth state may be quantified data so as to be comparable to others.

Further, the plant cultivation system may further include a water supply means for supplying water to the plant and a water supply control means for controlling the water supply for controlling the water supply means.

The plant cultivation system may further include a fertilizer supply means for supplying fertilizer to the plant and a fertilizer supply control means for controlling the fertilizer supply.
Here, the fertilizer supply means may supply the water of the water supply means.
The fertilizer supply control means for controlling the fertilizer supply may be capable of selectively controlling the type of fertilizer.
The fertilizer supply means may be composed of a fertilizer cartridge in which fertilizer is adjusted according to a purpose, and the type of fertilizer may be controlled by selecting the fertilizer cartridge to control the type of fertilizer to be supplied to the plant.
A user ID is assigned to the cultivation system of the user, the server center generates a consumable ID in the fertilizer cartridge sent to the user in correspondence with the user ID, and the product supply center actually matches the consumable ID. The user cultivation system may be provided with a fertilizer cartridge reading means and have a determination means for determining whether or not it matches the consumables ID generated at the server center by associating with the fertilizer cartridge ID to be delivered.
A product supply center is further provided in the network, and the server acquires fertilizer data of the user plant cultivation system, and when it is necessary to add fertilizer, the server center sends fertilizer cartridge delivery information to the product supply center to produce products. The supply center may deliver the fertilizer cartridge to the user of the corresponding user system.
A user ID is assigned to the cultivation system of the user, the server center generates a consumable ID in the fertilizer cartridge sent to the user in correspondence with the user ID, and the product supply center actually matches the consumable ID. The user cultivation system may be provided with a fertilizer cartridge reading means and have a determination means for determining whether or not it matches the consumables ID generated at the server center by associating with the fertilizer cartridge ID to be delivered.

The plant cultivation system may download the necessary information on the plant cultivation control conditions from the server through the network and control it with the downloaded data, or may directly control the plant cultivation control conditions from the server through the network.

The plant cultivation system may download the necessary information on the plant cultivation control conditions from the server through the network and control it with the downloaded data, or may directly control the plant cultivation control conditions from the server through the network.

The user may be able to access from a user terminal connected to the net, and the user may be able to access and confirm the data of the plant by accessing the server.

The data on the growth state of the plant may be the data obtained by the plant cultivation system of the user or the growth monitoring means provided in the server.
Here, the growth monitoring means may be configured by a camera and may monitor growth by analyzing an image acquired by the camera.

The user can set various conditions to be controlled by the plant cultivation system, and the user may be able to set various conditions directly on the user plant cultivation system or from a user terminal through a network.
Here, the various conditions of the control target may include illumination light, and may further control fertilizer, temperature, humidity, water, carbon dioxide concentration, and wind as necessary.

The plant cultivation monitoring means has an abnormality determining means, and may transmit a warning signal to a user terminal when an abnormality occurs.

The plant cultivation system has a fertilizer remaining amount measuring means for measuring the remaining amount of fertilizer, and when the remaining amount of fertilizer is below a certain level, the plant cultivation system transmits a fertilizer remaining amount signal to a user terminal via a network. Has a fertilizer remaining amount measuring means for measuring the remaining amount of fertilizer, and when the remaining amount of fertilizer is below a certain level, the user may be requested to send a new fertilizer.

The user data collecting means for collecting the data of the user system may include plant growth data.
Here, the growth data may be collected by acquiring and analyzing an image with a camera provided in the user system.
Here, the analysis may analyze the height, area, or both data of the corresponding plant.

The user data collecting means for collecting the data of the user system may include the data collected by the sensor on the cultivation conditions of the plants of each user system.
Here, the sensor may be at least one sensor selected from temperature, humidity, illuminance, carbon dioxide concentration, air volume, and pH of water.

The server center may have a user data analysis means for analyzing the data collected through the user data collection means.
Here, the user data analysis means may have an optimum condition search means for comparing the data of each user and searching for the optimum conditions for plant growth.
Further, the optimum condition search means may further have a user contribution calculation means for calculating the ratio of each data of each user's plant cultivation system contributing to the searched optimum condition.
The contribution calculation means may calculate the similarity between the searched optimum condition and the condition of the corresponding user.

The user system has a user evaluation input means for collecting user evaluations, and the data collected by the user data collecting means may include the data collected by the user evaluation input means.
The user's evaluation may be the texture of the user.

The fertilizer supply control means may be capable of controlling the type and supply amount of fertilizer.
Here, the control of the type of fertilizer may be performed by providing a fertilizer cartridge having a plurality of different types of fertilizer in the user system and selecting the fertilizer cartridge to select the type of fertilizer.

The plant cultivation system may further include temperature control means for controlling the temperature.

The illumination light may be a red LED, an infrared LED, a blue LED, a green LED, an ultraviolet LED, sunlight guided by an optical fiber, or a combination thereof.
Here, the plant cultivation system is connected to a network, a server is provided in the network, and the illumination light control means controls from the network or downloads necessary information from the server through the network and controls with the downloaded data. Alternatively, it may be controlled directly from the server through the network.

The plant cultivation system may further include gaseous carbon dioxide control means for controlling the carbon dioxide concentration in the air.
Here, the carbon dioxide control means may be supplied by a gaseous carbon dioxide cartridge (cylinder).
Further, the plant cultivation system is connected to a network, a server is provided in the network, and the gas carbon dioxide control means controls from the network or downloads necessary information from the server through the network and controls with the downloaded data. Alternatively, it may be controlled directly from the server via the network.

The plant cultivation system may further include carbon dioxide solubilization control means for adding carbon dioxide to water.
Here, the carbon dioxide water solubilization control means may add oxygen by a carbon dioxide cartridge (cylinder).

The plant cultivation system is connected to a network, a server is provided in the network, and the carbon dioxide water solubilization control means controls from the network or downloads necessary information from the server through the network and controls with the downloaded data. Alternatively, it may be controlled directly from the server through the network.

The plant cultivation system may further have a replaceable medium.
Here, the plant cultivation system may be connected to a network, the network may be provided with a server, and the user may be able to input the type of medium through the network.

The plant cultivation system may further include a humidity adjusting means and a humidity adjusting controlling means for controlling the humidity adjusting means.
Here, the plant cultivation system is connected to a network, a server is provided in the network, and the humidity control control means controls from the network or downloads necessary information from the server through the network and controls with the downloaded data. Alternatively, it may be controlled directly from the server via the network.

The plant cultivation system may further include a blowing means and a blowing control means for controlling the blowing means.
Here, the plant cultivation system is connected to a network, a server is provided in the network, and the ventilation control means controls from the network or downloads necessary information from the server through the network and controls with the downloaded data. Alternatively, it may be controlled directly from the server through the network.

As described above, according to the present invention, it is possible to easily realize plant cultivation that matches the health condition of the user. Furthermore, even if there are many parameters that affect the plant growth environment, it is possible to realize a cultivation system that can find the optimum cultivation conditions by utilizing AI and the like.

FIG. 1 is a diagram schematically showing the entire system of the present invention. FIG. 2 is a block diagram of a user cultivation system. FIG. 3 is a diagram schematically showing an outline of a user cultivation system and a server center. FIG. 4 is a configuration diagram illustrating a water supply / fertilizer supply section. FIG. 5 is a sequence diagram showing the operation between the device, the system, and each center that acquires and optimizes each data of the user system. FIG. 6 is a sequence diagram showing the flow of information when the plant collected by the user is evaluated. FIG. 7 is an example of a screen for inputting an evaluation of odor from a smartphone. FIG. 8 is a block diagram showing the format of the database used for optimization. FIG. 9 is a sequence diagram illustrating abnormal transmission. FIG. 10 is a flowchart illustrating the detection of abnormality. FIG. 11 is a sequence diagram showing an operation when the user confirms the cultivation status. FIG. 12 is an example of a confirmation request screen and a confirmation screen of the smartphone. FIG. 13 is a sequence diagram when the user sets the cultivation conditions by himself / herself. FIG. 14 is an example of an input screen for inputting how to apply the irradiation light. FIG. 15 is a sequence diagram illustrating the operation of the consumables delivery system. FIG. 16 is a flowchart illustrating the detection of the remaining amount of fertilizer and the consumables shipping process. FIG. 17 is an example of a smartphone screen on which "consumables can be shipped" is transmitted. FIG. 18 is a flowchart showing a distribution operation when a profit is generated under the optimum cultivation conditions. FIG. 19 is a sequence diagram showing an operation when a user's request is input and cultivation conditions are set based on the request. FIG. 20 is a flowchart showing the operation of searching for the optimum cultivation conditions.

An example of the best mode for carrying out the present invention will be described in detail below with reference to the drawings. FIG. 1 schematically shows the entire system of the present invention, and 1 is a user's cultivation system. This system includes blue, red, infrared and other LEDs that supply cultivation light, their control units, and a fertilizer cartridge. Fertilizer supply unit and its control unit, water tank and its control unit, image sensor, temperature sensor, humidity sensor, carbon dioxide gas sensor, optical sensor and their processing units, each control unit and processing unit It is equipped with a central processing unit that integrates the above, and a communication control unit that connects to a communication line and performs communication processing with the outside.
Here, although not shown, a humidity adjusting device for controlling the humidity is provided to control the humidity. Humidity can be adjusted by using a humidifier or a drying device that removes moisture from the air, if necessary.
Similarly, although not shown, a function such as providing a blower to control the movement of the wind may be added as needed.

Reference numeral 2 denotes a server center, which includes a data storage unit 6. The server center has a communication function that connects to a communication line to exchange various data, a function that collects, stores, and manages user data, and a function that compares the collected various cultivation data and searches for the optimum cultivation conditions under various conditions. , A function to generate cultivation control data matching each condition from the searched optimum cultivation conditions, a function to distribute the generated optimum control data, and a research mode in which the user sets various cultivation conditions by himself / herself as needed. A researcher contribution calculation function that calculates how much the corresponding user contributed under the optimal conditions searched in the case, and when the remaining amount of fertilizer etc. of each user is grasped and the remaining amount falls below a certain level, the corresponding user On the other hand, it has functions such as a function to generate necessary consumables delivery data.

The search for optimal cultivation conditions is for each temperature profile, light profile, fertilization profile, water supply profile (except for hydroponics), carbon dioxide profile, humidity profile, wind (air movement) profile, and medium type for each cultivation. Each condition may be selected as necessary, and the optimum condition may be obtained by comparing the result data such as growth rate, yield, and each user's evaluation.

For example, if some systems such as a temperature control function and a carbon dioxide concentration control function are expensive, the user may select controllable items according to his / her own situation. Since the condition control in this case differs depending on the user's cultivation system, it is sufficient to select only the controllable elements of the user cultivation system according to the necessary user's circumstances and search for the optimum conditions for the control items.

The product supply center of 3 has a function of shipping fertilizer cartridges and the like based on the necessary consumables delivery data generated at the server center of 2.

4 is a user terminal such as a smartphone, and the user of 5 can check the status of his / her cultivation system via a communication line, and when there is an abnormality, the server center sends abnormality information to the corresponding user. Notify the status and the above contents.

Next, the user's cultivation system will be described with reference to FIGS. 2 and 3. FIG. 2 is a block diagram of a user cultivation system, where 20 is a user system, 21 is a central processing unit that integrates various processes, 22 is an IR (far infrared) LED control unit, and 23 is an R (red) LED control unit. 24 is a B (blue) LED control unit 25 is a communication control unit, 26 is a fertilizer cartridge 1 control unit, 27 is a fertilizer cartridge 2 control unit, 28 is an image acquisition unit for observing growth, and 29 is a temperature acquisition unit. , 30 is a carbon dioxide concentration acquisition unit, 31 is a humidity acquisition unit, 32 is an acquisition unit for each light amount (each wavelength), 33 is a temperature control unit, 34 is a water tank control unit, 35 is a medium water supply tank control unit, 36. Is a carbon dioxide control unit.
Here, the light is IR, R, and B LEDs, but for example, sunlight introduced by an optical fiber or ultraviolet rays for studying adverse effects may be provided. Further, since the functions such as temperature control and carbon dioxide concentration control are expensive, a cultivation system that omits temperature control and carbon dioxide concentration control may be used in order to provide an inexpensive system.

FIG. 3 is a diagram schematically showing an outline of a user cultivation system and a server center. Here, 31 is a cultivation box, 32 is a PC (print circuit board) 33 equipped with each LED, various sensors, and a control / processing unit, 33 is a water supply / fertilizer supply unit, and 34 is soil, sand, fiber aggregate, porous material, etc. Freely changeable medium or water medium for hydroponics, 35 are LEDs such as IR (infrared), R (red), B (blue), 36 is the server center, 37 is the heating composed of Perche. The cooling unit and 38 are carbon dioxide supply units. Here, since the medium cannot be sufficiently identified by the sensor, the user may input the type of medium and the like.

FIG. 4 is an explanatory diagram of the water supply / fertilizer supply section, in which liquid fertilizer is used. 5.41 is a fertilizer cartridge holding liquid fertilizer in a tank, 42 is a water tank, and 43 is a medium water supply tank (fertilizer). (On), 44 is a solenoid valve, and 45 is a carbon dioxide cartridge. Here, control is performed based on control information from the control unit of the fertilizer cartridge 1 of FIG. 2, the control unit of the fertilizer cartridge 2 of 27, and the carbon dioxide control unit of 36. The fertilizer does not have to be a liquid fertilizer, and a solid fertilizer may be supplied with water from a water supply means to dissolve the fertilizer component in water.

Next, each case of the information flow will be described. FIG. 5 captures and optimizes user system data, namely temperature profile, optical profile, fertilization profile, water supply profile, carbon dioxide profile, and plant growth data, yield data, and media type data as needed. It is a sequence diagram which showed the operation between a device, a system, and each center. The optimization will be described later. Here, as shown in the figure, cultivation data is acquired at the server center through a communication line, optimization is performed, and the obtained optimization data is distributed to the user's cultivation system based on the distributed data in the user's cultivation system. Control various cultivation conditions. Here, the temperature profile, each optical profile, the fertilization profile, the water supply profile, the carbon dioxide profile, and the type data of the medium are collected, but it is sufficient to acquire the data corresponding to the cultivation system of each user. That is, if the medium is exclusively for hydroponics, it is not necessary to acquire the data of the medium one by one, and the water supply data is also not necessary. In addition, it is not necessary to collect data for functions that are not installed in the user cultivation system.

Next, the flow of information when the user evaluates the collected plants will be described. FIG. 6 is a sequence diagram showing the flow of the information, and the user evaluation method will be described later. As in FIG. 4, each data of the user system, that is, temperature profile, each optical profile, fertilization profile, water supply profile, carbon dioxide profile, growth data, yield data, and medium type data are acquired. Furthermore, the user inputs evaluation data from the user terminal, and the server center acquires this data. Then, it is optimized based on the data acquired from the user cultivation system here and the user evaluation data from the user terminal. Here, as shown in the figure, cultivation data is acquired at the server center through a communication line, optimization is performed, and the obtained optimization data is distributed to the user's cultivation system based on the distributed data in the user's cultivation system. Control various cultivation conditions.

Next, the user evaluation method will be described. When evaluating the taste and odor of a cultivated plant, the user inputs an evaluation of odor from a smartphone from a smartphone as shown in FIG. 7, and similarly selects an evaluation of taste from five stages. This input data is sent to the server center.

Next, the optimization method will be described. As shown in FIG. 8, the format of the data to be input to the database is to assign a cultivation ID for each cultivation cultivated by each user, and for the corresponding cultivation ID, the user name, the target plant name, the temperature profile, the optical profile, and the fertilization profile. , Water supply profile, carbon dioxide profile, and if necessary, each cultivation condition such as the type of medium, and the data format of user evaluation such as plant growth rate, yield, and if necessary, odor and taste. The server center performs optimization processing for data in this format. As described above, the data of a large number of cultivation IDs are compared and analyzed to search for the optimum data. That is, the optimum condition is to compare each cultivation ID and find a cultivation condition that obtains the maximum value of growth rate, yield, and user evaluation.

Next, abnormal transmission will be described. FIG. 9 illustrates the flow, and when an abnormality is detected at the server center (2 in FIG. 1) that collects data of the user cultivation system (1 in FIG. 1), the abnormality state is transmitted to the user terminal. FIG. 10 explains the detection of an abnormality. Data is called from the data storage unit 1001 (6 in FIG. 1) of the user cultivation system of the server center by 1002, and the current data is compared with the abnormality threshold by 1003 to see if there is an abnormality. If it is determined and there is an abnormality, 1004 is used to perform transmission processing to the corresponding user terminal.

Next, a case where the user confirms the cultivation situation will be described, and the state is shown in the sequence diagram of FIG. The data of the user's cultivation system (1 of FIG. 1) is transmitted to the server center (2 of FIG. 1) at predetermined intervals and stored in the database of the server center (6 of FIG. 1). As shown in the confirmation request screen of the smartphone of FIG. 12A, the user makes a status confirmation request from the user terminal (4 of FIG. 1). Here the user is the temperature for the last 24 hours. Requesting size and image. Then, the status confirmation request is sent to the server center, the necessary information is taken out from the database, and the necessary information is sent to the user terminal. The confirmation screen is changed to (b) in Fig. 12.

Next, a case where the user sets the cultivation conditions by himself / herself will be described, and the state is shown in the sequence diagram of FIG. The user inputs a condition from the user terminal (5 in FIG. 1) and sends the information to the server center. An example of using a smartphone in the user's condition setting is shown in FIG. 14A. Here, the light irradiation pattern is pattern C, and the fertilizer is K-rich or Ca-rich. The corresponding data is stored in the database of the server center (6 in FIG. 1) and transmitted to the user cultivation system as needed. Next, an example of using a personal computer as a terminal is shown in FIG. 14 (b), but here it is a screen for inputting how to apply irradiation light. The B LED is a blue LED, the R LED is a red LED, and the IR LED is an infrared LED. There is a one-cycle time input field at the bottom, where you can enter the one-cycle time. What is the irradiation timing of each LED? Set with each slider of B LED, R LED, and IR LED.

In this embodiment, the setting is made from the user terminal (smartphone, personal computer), but the cultivation conditions may be directly input to the user cultivation system. In this case, the cultivation conditions are directly stored in the user system and the corresponding information is transmitted to the server center as needed. In addition, although irradiation light and fertilizer supply are set here, the figure is not limited to this, and the temperature is shown in the case of a cultivation system with a temperature control function, and the carbon dioxide concentration is shown in the case of a cultivation system with a carbon dioxide gas control function. Although not shown, the air volume may be set in the case of a cultivation system with an air volume control function, and the humidity may be set in the case of a cultivation system with a humidity control function.

Next, the delivery system for consumables will be described, and the state is shown in the sequence diagram of FIG. When the server center (2 in Fig. 1) that collects the data of the user cultivation system (1 in Fig. 1) detects that the remaining amount of fertilizer is low, it sends "Consumables shipping availability" to the user terminal. However, an example of the screen is shown in FIG. Here, the fertilizer cartridge type A is running low, and a screen is shown in which the purpose is transmitted to the user terminal and the user requests shipping of two fertilizer cartridges. FIG. 16 explains the detection of the remaining amount of fertilizer and the processing of shipping consumables. Data is called from the database 1601 (6 in FIG. 1) of the user cultivation system of the server center by 1602 and compared with the remaining amount threshold of fertilizer by 1603. It is determined whether or not the remaining amount is less than or equal to the specified value, and if it is less than or equal to the specified value, transmission processing to the corresponding user terminal is performed at 1604. Since the user requests the shipment of two fertilizer cartridges, the server center processes them, sends them as consumables shipment data to the product supply center, and the product supply center processes the shipment. Although the fertilizer cartridge has been described here, the present invention is not limited to this, and a carbon dioxide gas cartridge or the like may be used. Further, when the medium is an artificial medium or the like and the artificial medium monitoring function is provided and deterioration of the artificial medium is observed, the artificial medium may be used.

Next, a method of calculating the contribution of each user in optimizing the cultivation conditions will be described. Participation of a large number of users, that is, each user sets his / her own cultivation conditions, searches for the optimum cultivation conditions based on the results, and finds the optimum cultivation conditions. If you know whether you have contributed to the above, it will motivate the user, and if you make a profit under the optimum cultivation conditions, you can distribute it. Although the flow of the operation is shown in FIG. 18, the degree of contribution of the corresponding user may be obtained by calculating the similarity between the corresponding user cultivation condition of 1801 and the optimum cultivation condition found of 1802.

Next, a case where the user inputs a user's request and sets the cultivation conditions from the request will be described instead of the case where the user sets directly. FIG. 19 is a sequence diagram illustrating the situation, in which the user's request is input from the user terminal, transmitted to the server center, the user's optimum cultivation conditions are searched for at the server center, and the optimum cultivation conditions are transmitted to the user cultivation system to be transmitted to the user cultivation system. Cultivate in. The flowchart of FIG. 20 shows the state of searching for the optimum cultivation conditions of the corresponding user. Here, the request of the user in 2002 was analyzed in 2003, and the database of 2001 in 2004 (6 in FIG. 1) was referred to to perform the optimum cultivation in 2005. The conditions are set.

The system of the present invention can be applied to a research facility in an agricultural research institute that seeks cultivation conditions suitable for various purposes such as a user's health condition. Even if there are many parameters that affect the plant growth environment, if data is collected from many users connected to the network, it is possible to find the optimum cultivation conditions using AI etc., so networked individual users It is possible to apply it to the cultivation system of, for example, to make a cultivation system that can easily extract the cultivation conditions of plants that match the health condition of the user.

1 User cultivation system 2 Server center 3 Product supply center 4 User terminal 5 User 6 Database

Claims (4)

In fertilizer cartridge suppliers
The step of adjusting the fertilizer of the fertilizer cartridge for the purpose of matching the health condition of the user who grows the plant,
In the user who grows the plant,
A step of mounting the fertilizer cartridge on the user's cultivation device, a fertilizer supply step of supplying fertilizer from the fertilizer cartridge to the plant, and a fertilizer supply control step of controlling the fertilizer supply. and <br/> illumination control step of controlling the illumination step <br/> the illumination light which irradiates illumination light for growing plants,
A plant cultivation method characterized by being composed of. The plant cultivation method further comprises a water supply step of supplying water to the plant.
The fertilizer supply step is included in the water supply step and
The plant cultivation method according to claim 1 , further comprising a step of selecting the fertilizer cartridge from a plurality of the fertilizer cartridges. In the fertilizer supply control step, a fertilizer cartridge having a plurality of different types of fertilizer is further provided in the user's cultivation apparatus, and when the user cultivates a plant, the fertilizer is selected by selecting the fertilizer cartridge. The plant cultivation method according to claim 2, wherein the supply is controlled. In the user who grows the plant,
The plant cultivation method according to claim 1, further comprising a fertilizer cartridge replacement step of replacing the fertilizer cartridge by consuming fertilizer.

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