KR20230016562A - System for operation of smart farm including cultivation module - Google Patents

Abstract

The present invention relates to a plant factory operation system including a cultivation module. More specifically, a variety of information for plant cultivation is provided to rental members of a plant factory, and it is allowed to check the current status of plants being grown in real time. Thus, efficient remote cultivation is possible even for ordinary people without knowledge of plant cultivation. By allowing rental members to sell plants grown directly through a plant factory operation system, rental members can realize profits while satisfying their needs for gardening. By allowing buyers to secure fresh agricultural products quickly and inexpensively from plant factories located in the city center, cultivation, sales, and purchasing can be carried out efficiently in one system.

Description

Plant factory operation system including cultivation module {System for operation of smart farm including cultivation module}

The present invention relates to a plant factory operation system including a cultivation module, and more specifically, to provide rental members of a plant factory with various information for plant cultivation, and to check the current state of plants in cultivation in real time, Efficient remote cultivation is possible even for ordinary people who do not have knowledge about plant cultivation, and at the same time, rental members can directly sell plants through the plant factory operation system, so that rental members can satisfy their desire for gardening while making profits. It is about a plant factory management system that enables efficient cultivation, sales, and purchase in one system by enabling buyers to secure fresh agricultural products quickly and inexpensively from plant factories located in the city.

Recently, with the spread of the well-being craze, various vegetables and fruits and vegetables such as sprouts and organic vegetables are grown and eaten in small scales in each household. Seeds are planted and cultivated.

In addition, various types of ornamental flowers are generally grown in pots to obtain a nature-friendly interior effect in homes and offices, and depending on the size of the plants, pots are displayed on the floor, shelf, window sill, etc. I do it and take care of it.

In addition, a smart farm that can remotely and automatically manage the growth environment of various plants in one place and increase production efficiency by applying information and communication technology to agricultural production / processing / distribution / consumption currently getting attention.

However, the conventional smart farm system is limited to plant cultivation in plant factories, and does not have functions such as sales, purchase, distribution, and consumption, so it has limitations in contributing to the establishment of a well-being society based on urban agriculture.

On the other hand, the prior art related to the smart farm system includes Korean Registered Patent No. 10-1168931.

The present invention has been made to solve the problems of the prior art as described above, and provides various information for plant cultivation to rental members of plant factories, and enables real-time checking of the current state of plants under cultivation, thereby cultivating plants. Efficient remote cultivation is possible even for ordinary people who do not have knowledge about gardening, and at the same time, the plants grown by rental members can be directly sold through the plant factory management system, so that rental members can satisfy their desire for gardening while realizing profits. The purpose is to provide a plant factory operation system that enables efficient cultivation, sales and purchase in one system by enabling buyers to secure fresh agricultural products quickly and inexpensively from plant factories located in the city center. there is.

A plant factory operation system including a cultivation module according to the present invention for achieving the above object is made of a structure having a certain space blocked from the outside, and a plant factory formed in a narrow space in an area close to the city center; A member terminal operated by a rental member; a purchaser terminal operated by a purchaser of the cultivated plant; a plant factory operation server that provides various types of information to the member terminals and purchaser terminals and controls each component of the plant factory by receiving a control signal transmitted from the member terminals; And it is characterized in that it is formed by including a blockchain server through trading and cultivation.

At this time, the plant factory operation server extracts and analyzes the image of the video transmitted from the camera of the plant factory, generates information on the current growth state of the corresponding plant, and provides an image analysis and image providing unit to the member terminal; It is characterized in that it includes.

In addition, the plant factory includes a modularized cultivation module in which a temperature controller, a humidity controller, a light amount controller, a nutrient solution supply device, a water supply device, a functional useful material supply device, a camera, and a cooling/heating air conditioning system (thermo-hygrostat) are integrally formed. It is characterized by including.

In addition, the plant factory management server is characterized in that it includes a virtual demand and virtual inventory predictor for establishing a cultivation plan to match demand and supply by predicting virtual demand and virtual inventory of each plant.

The plant factory management system including the cultivation module according to the present invention provides rental members of the plant factory with various information for plant cultivation, allows them to check the current state of plants under cultivation in real time, and according to the rental member's selection. It is also possible to automatically control the environmental status values and material supply of the cultivation module by the plant factory operation server, so even ordinary people without knowledge of plant cultivation can perform efficient remote cultivation.

In addition, by allowing rental members to sell plants grown directly through the plant factory operation system, rental members can fulfill their desire for gardening while realizing profits through blockchain (sales and cultivation), and buyers can secure fresh agricultural products quickly and inexpensively from plant factories located in the city center, so that cultivation, sales, and purchase can all be carried out efficiently in one system.

In addition, the customer's cultivated plants are photographed with a camera in real time, and the captured video is image-analyzed to identify the current growth status information of the plant and provide it to the rental member, enabling efficient remote cultivation.

In addition, a variety of information for cultivation is provided to the rental member, but the rental member can freely perform remote cultivation through the terminal and at the same time, interest in plant cultivation can be aroused by adding a game element.

In addition, a video (a video showing the growth process of a plant quickly) is provided through the terminal of the rental member, and the provision of various information through the terminal is delivered through the character, which shows the video captured in real time through the camera at double speed. It can arouse interest in cultivation.

In addition, by cultivating the rental member's plant cultivation in a modularized cultivation module, it is possible to directly move and grow the plants grown in the plant factory to a desired place.

In addition, information on the grower (rental member) and cultivation history data are provided to buyers of cultivated plants so that they can purchase cultivated plants with confidence. There is an effect of being able to purchase cheaply by omitting the middle distribution process.

In addition, through the blockchain-based market transaction system, the rental member's profit is created, and the rental member can purchase seeds and vegetables within the market transaction system through the profit. Therefore, the present invention can not only generate profits for rental members, but also allow rental members to purchase new seeds, vegetables, etc. with the generated profits.

In addition, it is possible to match the demand and supply of vegetables by identifying the demand for vegetables desired by the demand place in each region and performing customized cultivation of vegetables to meet the demand. Specifically, demand data for each vegetable is collected from consumers such as food factories and restaurants, along with data on the distance between the plant factory where each vegetable will be supplied and data on demand, data on predicted payment quantity, etc. are also collected and analyzed to simulate virtual demand for each plant. (order quantity) can be predicted. In addition, the virtual stock can be predicted by collecting and analyzing data related to the current stock for each plant, storage period, and freshness for each storage period. Based on the virtual demand and virtual inventory predicted through this analysis, a cultivation plan to match demand and supply can be established and provided to each plant factory, so that each consumer can receive the desired quantity of fresh vegetables on time. , Growers (rental members) of plant factories can receive distribution of vegetable delivery revenue. At this time, the plant factory compares virtual demand (order amount) with virtual inventory, preferentially recommends insufficient vegetables to growers (rental members), and provides incentives (nutrition discounts, etc.) to growers (rental members) who select the vegetables. By inducing the cultivation of vegetables, it is possible to secure the supply of vegetables, and growers (rental members) can immediately receive distribution of the profits delivered to the consumer upon completion of the cultivation of vegetables.

On the other hand, if an emergency order occurs, search is performed based on the distance between the demand place and each plant factory, vegetable inventory at each plant factory, virtual demand (order volume) forecast data, virtual inventory forecast data, etc. Desired vegetables can be supplied in a short time, and vegetables from plant factories in other regions can be replenished or newly cultivated to replenish vegetable stock in plant factories.

In addition, it is possible to provide purchasers with recommended plant data for each functional component, and provide columns of experts (doctors, trainers, oriental doctors, etc.) related to each plant.

In addition, by extracting word data from the column, it is possible to recommend an expert's column and cultivated plants in consideration of the rental member's purpose of growing plants and the rental member's current condition (health, income, etc.).

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a block diagram of a plant factory operation system including a cultivation module according to the present invention.
2 is a block diagram of a plant factory operation server in a plant factory operation system including a cultivation module according to the present invention.
3 is a block diagram of a plant factory in a plant factory operation system including a cultivation module according to the present invention.
4 is a block diagram of a member terminal and a purchaser terminal in a plant factory operating system including a cultivation module according to the present invention.
5 is a view showing the appearance of cultivation shelves in a plant factory operation system including a cultivation module according to the present invention.
6 is a view showing the state of the cultivation module in the plant factory operation system including the cultivation module according to the present invention.
7 is a diagram illustrating plant cultivation information provided by a plant factory operation system including a cultivation module according to the present invention.
8 is a diagram showing a state in which current state information of cultivated plants provided by a plant factory operation system including a cultivation module according to the present invention is displayed on a member terminal.
9 is a diagram showing a state in which plant sales information provided by a plant factory management system including a cultivation module according to the present invention is displayed on a purchaser terminal.
10 is a diagram illustrating recommended plant information provided to a purchaser in a plant factory management system including a cultivation module according to the present invention.
11 and 12 are diagrams schematically illustrating hydroponic cultivation in a plant factory operating system including a cultivation module according to the present invention.
13 is a diagram illustrating a method of analyzing an image of a plant in a plant factory operation system including a cultivation module according to the present invention.
14 is a diagram showing a state in which plant-related data is visualized in a plant factory operation system including a cultivation module according to the present invention.
15 is a view showing a state in which the seating plates of the cultivation shelves are horizontally arranged in the plant factory operation system including the cultivation module according to the present invention.
16 is a view showing a state in which wheels are formed on a cultivation shelf in a plant factory operation system including a cultivation module according to the present invention.
17 is a schematic diagram illustrating a process of rearranging cultivation shelves of a plant factory when multiple users reserve visits in the plant factory operation system including the cultivation module according to the present invention.
18 is a diagram illustrating a method of controlling demand and supply of plants in a plant factory operation system including a cultivation module according to the present invention.
19 is a diagram illustrating a method of providing plants in a situation where an emergency order occurs in a plant factory operation system including a cultivation module according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, some configurations irrelevant to the gist of the present invention will be omitted or compressed, but the omitted configurations are not necessarily unnecessary in the present invention, and can be combined and used by those skilled in the art to which the present invention belongs. can

1 is a block diagram of a plant factory operation system including a cultivation module according to the present invention, FIG. 2 is a block diagram of a plant factory operation server in the plant factory operation system including a cultivation module according to the present invention, and FIG. Figure 4 is a block diagram of a plant factory in the plant factory operation system including the cultivation module according to the present invention, Figure 4 is a block diagram of a member terminal and a purchaser terminal in the plant factory operation system including the cultivation module according to the present invention, Figure 5 is a view showing the appearance of cultivation shelves in the plant factory operation system including the cultivation module according to the present invention, and FIG. 6 is a view showing the appearance of the cultivation module in the plant factory operation system including the cultivation module according to the present invention. 7 is a view showing plant cultivation information provided by the plant factory management system including the cultivation module according to the present invention, and FIG. 8 is a cultivated plant provided by the plant factory management system including the cultivation module according to the present invention. 9 is a diagram showing a state in which current state information of is displayed on a member terminal, and FIG. 9 is a diagram showing a state in which plant sales information provided by a plant factory operation system including a cultivation module according to the present invention is displayed on a purchaser terminal, 10 is a view showing recommended plant information provided to a purchaser in the plant factory operation system including the cultivation module according to the present invention, and FIGS. 11 and 12 are in the plant factory operation system including the cultivation module according to the present invention. A diagram briefly illustrating hydroponic cultivation, FIG. 13 is a diagram showing a method of analyzing the image of a plant in a plant factory operating system including a cultivation module according to the present invention, and FIG. 14 is a diagram showing a cultivation module according to the present invention 15 is a diagram showing a state in which plant-related data is visualized in a plant factory operating system, and FIG. 15 is a diagram showing a state in which a seating plate of a cultivation shelf is horizontally arranged in a plant factory operating system including a cultivation module according to the present invention. 16 is a view showing a state in which wheels are formed on a cultivation shelf in a plant factory operation system including a cultivation module according to the present invention, and FIG. 18 is a schematic diagram showing a process in which cultivation shelves of a plant factory are rearranged when multiple users reserve a visit in a plant factory operation system including a cultivation module according to the present invention, and FIG. 18 is a plant including a cultivation module according to the present invention. 19 is a diagram showing a method of controlling the demand and supply of plants in a factory operating system, and FIG. 19 is a diagram showing a method of providing plants in a situation where an emergency order occurs in a plant factory operating system including a cultivation module according to the present invention. it is a drawing

As shown in FIGS. 1 to 19, the plant factory operation system including the cultivation module according to the present invention includes a plant factory operation server 100, a plant factory 110, a member terminal 200 and a purchaser terminal 300 It is composed of.

The plant factory 110 has a structure having a certain space blocked from the outside, and is formed in a narrow space such as a container or an office in an area close to the city center.

The plant factory 110 includes a cultivation shelf 112, a cultivation module 111, a robot arm 115, a camera 116, an environment control unit 113, and a supply control unit 114.

The cultivation shelves 112 are spaced apart at regular intervals in the interior space of the plant factory 110, and as shown in FIG. 5, a plurality of seating plates 140 on which the cultivation modules 111 are seated, and each seating A first connecting bar 120 provided so as to be rotatably coupled to the plate 140 and the first rotational shaft 121 and the second rotational shaft 131 to simultaneously rotate the plurality of seating plates 140, and It is formed including the second connecting bar 130.

The seating plate 140 is formed so that the cultivation module 111 can be stably placed on it, and a plurality of them are provided and arranged to be spaced apart at regular intervals.

The seating plate 110 may be made of various materials such as wood, plastic, steel, rubber, and glass.

Two extensions 132 are formed on one side of each seating plate 140 in a form extending to the bottom, and the extensions 132 of each seating plate 140 are constant on the second connecting bar 130. Doedoe coupled to be spaced apart by the interval, coupled rotatably by the second pivot shaft (131).

In addition, the other side of the seat plate 140 is coupled to the first connection bar 120 so as to be spaced apart by a predetermined interval, and is rotatably coupled by the first rotation shaft 121.

As described above, the first rotational shaft 121 and the second rotational shaft 131 are connected by the first connecting bar 120 and the second connecting bar 130 and provided on one line, so that a plurality of seating plates 140 ) can be rotated simultaneously.

On the other hand, although not shown in the drawing, when the seating plate 110 is arranged vertically, a support (not shown) for firmly supporting and supporting the cultivation device may be additionally provided.

As shown in FIGS. 5 and 15, the cultivation shelf 112 can be switched vertically and horizontally, so it has excellent space utilization and can be installed without space restrictions, and the manager performs various plant management tasks. It is possible to work while changing the arrangement of the cultivation shelves 112 according to circumstances, so that the management work is easy and the plant cultivation efficiency can be improved. In addition, a height adjusting device (not shown) capable of adjusting the height so that the horizontally arranged seating plate 140 can be positioned at a height that is easy for growers to manage may be further provided, and if necessary, the first connecting bar 120 and the second connecting bar 130 may be rotated at various angles and fixed at desired positions.

On the other hand, the cultivation shelf 112 of the present invention configured as described above may be configured so that vertical and horizontal switching arrangements are automatically performed, and although not shown in the drawings, the first connection bar 120 and the second connection bar 130 A device for automatically rotating may be additionally provided.

In addition, in the present invention, a recognition device (not shown) such as an NFC tag recognition device and an RFID reader may be additionally provided at the entrance of the plant factory 110, and accordingly, when a grower directly visits the plant factory 110, NFC When a tag or RFID tag is tagged on a recognition device (not shown), the cultivation shelf 112 on which the cultivation module 111 on which the grower's plant is grown is seated automatically rotates, The cultivation module 111 can be conveniently and directly managed. At this time, it is also possible to separately install a sensor (not shown) for detecting the grower's height in the cultivation shelf 112 so that the cultivation shelf 112 rotates appropriately according to the height of the grower.

The cultivation module 111 is seated on each seating plate 140 of the cultivation shelf 112 to provide a space for plant cultivation. In the present invention, each cultivation module 111 is modularized so that rental members can plant a plant factory. If you want to move and grow the plants grown in (110) to another place, you can move the cultivation module 111 itself and move it easily.

In order to modularize the cultivation module 111 as described above, the cultivation module 111 includes a temperature controller such as an air conditioner and an air conditioner controller, a humidity controller such as a humidity controller, a humidity control device controller, lighting devices such as LEDs, and a lighting device controller. The same light amount controller, nutrient solution supply device, water supply device, functional useful material supply device, etc. may be integrally provided.

On the other hand, the cultivation module 111 as described above may be provided with a QR code containing current growth state information of the plant being cultivated as shown in FIG. Growth state information and the like can be grasped through the terminal. At this time, if the growth state of the cultivated plant is not good as a result of the manager's identification through the terminal, the manager can send a notification to the member terminal 200, and the grower checks the notification through the member terminal 200 and directly uses the cultivation module 111 can be controlled to take actions appropriate to the current state of the plant, or control can be delegated to a manager. At this time, the shape or arrangement of the QR code is not limited to the state shown in FIG. 6, and may be arranged in various shapes and positions as needed.

The robot arm 115 is movably installed on the cultivation shelf 112 and is controlled by moving to each cultivation module 111 according to a control signal from the plant factory control unit 103 of the plant factory operation server 100 to be described later. Can carry out commands (cultivation (environment), sowing, harvesting, etc.).

The camera 116 photographs the plants of each cultivation module 111 in real time, transmits and stores the captured images to the database 107 of the plant factory operation server 100 to be described later, and stores them in the plant factory 110. A plurality of cultivation modules 111 may be installed in a suitable location where all of the insides of the provided cultivation modules 111 can be photographed.

The environment control unit 113 controls the temperature controller, humidity controller, and light quantity controller provided in each cultivation module 111 according to a control signal from the plant factory controller 103 of the plant factory operation server 100 to be described later, respectively. Environmental state values such as temperature, humidity, and light intensity inside the cultivation module 111 are controlled.

The supply control unit 114 supplies a nutrient solution supply device, a water supply device, and functional useful substances provided in each cultivation module 111 according to a control signal from the plant factory control unit 103 of the plant factory operation server 100, which will be described later. The device is controlled so that materials necessary for plant cultivation are supplied to the inside of each cultivation module 111 .

On the other hand, the plant factory operation server 100 is connected to the plant factory 110, the member terminal 200, and the purchaser terminal 300 through a mobile communication network or the Internet, and provides various information to the member terminal 200 and the purchaser terminal 300. Each component of the plant factory 100 is controlled by providing information and receiving a control signal transmitted from the member terminal 200 .

The plant factory operating server 100 includes a communication processing unit 101, an app providing unit 102, a plant factory control unit 103, a cultivation information providing unit 104, a transaction management unit 105, a plant information providing unit 106, It is configured to include an image analysis and video providing unit 108 and a database 107 .

The communication processing unit 101 is provided to connect the member terminal 200, the purchaser terminal 300, and the plant factory 110 with a communication channel for transmitting and receiving information.

The app provider 102 is provided to provide a dedicated application to the member terminal 200 and the purchaser terminal 300, and in the case of using only a website access method without using a dedicated application, the app provider 102 may be omitted.

The database 107 is prepared to store information for plant cultivation, plant trade information, recommended plant data for each functional ingredient, and images of the cultivation module 111 captured by the camera 116 of the plant factory 110.

The plant factory control unit 103 receives control signals transmitted from the member terminals 200 and controls the robot arm 115, the environment control unit 113, and the supply control unit 114 of the plant factory 110.

The cultivation information providing unit 104 provides the member terminal 200 with information for growing plants grown by the corresponding member, and the plant growing information includes an internal cultivation space environmental condition value, plant cultivation necessary material supply information, and cultivated plant images. As shown in FIG. 7, along with information, a period and temperature suitable for sowing each plant, a temperature suitable for growth, a planting interval for each plant, a harvest time, and the like are included. In addition, the cultivation information providing unit 104 transmits the corresponding information to the member terminal 200 when the plant cultivation is completed and the harvest time has arrived.

When information for sale of cultivated plants is transmitted from the member terminal 200, the transaction management unit 105 receives and stores the information in the database 107 and transmits it to the purchaser terminal 300 as shown in FIG. 9 for rental. Transactions between members and buyers are made.

As shown in FIG. 10, the plant information providing unit 106 provides recommended plant data for each functional ingredient (diet, anti-diabetic, anti-cancer, anti-liver disease, hypertension prevention, etc.) to the member terminal 200 and the purchaser terminal 300, respectively. Provides columns by experts (doctors, trainers, oriental doctors, etc.) related to plants. At this time, words (keywords) in the column are extracted using NLP (graph ranking algorithm and word extraction (HITS algorithm)), and again through a specific algorithm, vegetables can be recommended according to the member's condition.

The image analysis and image providing unit 108 extracts and analyzes the image of the video transmitted from the camera 116 of the plant factory 110, generates information on the current growth state of the plant, and provides it to the member terminal 200. do. That is, plant height, leaf quantity, color, shape, etc. are identified from the extracted image, and soil and hydroponic conditions (EC/Ph, etc.) are compared, and plant current growth status information is generated based on the identified information. and provided to the member terminal 200.

In addition, it is also possible to provide the real-time image captured by the camera 116 to the member terminal 200, and an image showing the captured image at double speed (an image quickly showing the growth process of a plant) is provided to the member terminal 200. It is also possible to provide through

The virtual demand and virtual inventory forecasting unit 109 collects demand data for each vegetable from demanders such as food factories and restaurants, and together with this, data on the distance between the plant factory 110 and the demander 400 where each vegetable will be supplied, prediction It is possible to predict virtual demand (order amount) for each plant by collecting and analyzing payment quantity data, etc., and predict virtual inventory by collecting and analyzing data related to current inventory, storage period, and freshness by storage period for each plant. . Through the analysis of such virtual demand and inventory, it is possible to identify the demand for vegetables desired by each region and to perform customized cultivation of vegetables to meet the demand, thereby matching the demand and supply of vegetables. A detailed description of the virtual demand and virtual inventory prediction unit 109 will be described later.

The member terminal 200 and the purchaser terminal 300 include communication units 210 and 310, displays 220 and 320, key input units 230 and 330, app operation units 240 and 340, and information provision units 250 and 350. ) and information receiving units 260 and 360. Each component may be implemented in hardware, such as a smart phone, or may be implemented in software according to the installation of a dedicated application.

The communication units 210 and 310 are provided to connect the plant factory operation server 100 and a communication channel for transmitting and receiving information.

The displays 220 and 320 include various user interfaces provided by a dedicated application or website, a cultivation information providing unit 104 of a plant factory operation server 100, a plant information providing unit 106, an image analysis and video providing unit ( 108) to output the information provided.

The key input units 230 and 330 are provided to receive user commands. According to implementation, the key input units 230 and 330 may be manufactured as touch screens integrated with the displays 220 and 320 .

The app operating units 240 and 340 are provided to control the overall functions of the plant factory operating system by operating a dedicated application received and installed from the app providing unit 102 of the plant factory operating server 100.

The information providing units 250 and 350 are provided to provide information entered into the member terminal 200 and the purchaser terminal 300 to the plant factory operation server 100 .

The information receivers 260 and 360 are provided to receive information transmitted from the plant factory operation server 100 .

Hereinafter, a method of operating a plant factory operating system including a cultivation module according to the present invention will be described in detail with reference to the drawings.

First, the rental member installs a dedicated application provided by the app provider 102 of the plant factory operation server 100 on the member terminal 200 or connects to the website and registers as a member, and then applies for renting the plant factory 110. If so, the cultivation module 111 of the plant factory 110 located in the city center is leased for a set rental period. At this time, it is also possible to additionally rent the cultivation module 111 by paying an additional cost.

Thereafter, when the rental is completed, the rental member is provided with cultivation information for each plant and functional component provided by the cultivation information providing unit 104 and the plant information providing unit 106 of the plant factory operation server 100 as shown in FIGS. 7 and 10 (Diet, anti-diabetic, anti-cancer, anti-liver disease, hypertension prevention, etc.) You can select the plants you want to grow by referring to the recommended plant data.

At this time, the cultivation information for each plant provided by the cultivation information providing unit 104 includes the internal cultivation space environmental state value, plant cultivation material supply information, cultivation plant image information, period and temperature suitable for sowing each plant, and growth information. This includes suitable temperatures, planting intervals for each plant, and harvesting time.

In addition, recommended plant data for each functional component provided by the plant information providing unit 106 includes recommended plant information for each functional component such as diet, anti-diabetic, anti-cancer, anti-liver disease, and hypertension prevention, as well as experts (doctors, trainers, oriental doctors) related to each plant. etc.), and the rental member can check the expert's column related to the plant by touching a desired plant among each plant classified by functional component as shown in FIG. 10.

When a rental member selects a plant to be cultivated, the plant factory control unit 103 of the plant factory operation server 100 controls the robot arm 115 to sow seeds of the selected plant in the leased cultivation module 111. and by controlling the environmental control unit 113 and the supply control unit 114, environmental state values such as temperature value, humidity value, and light intensity value inside the cultivation module 111 are set to be suitable for the selected plant, and each Substances necessary for cultivating the corresponding plant are supplied to the inside of the cultivation module 111 .

At this time, the plant factory control unit 103 of the plant factory operation server 100 automatically controls the environmental state value and material supply control of the cultivation module 111 to be suitable for the plant according to the selection of the rental member, or The member may directly control the plant factory operation server 100 through the member terminal 200 by referring to the information provided by the cultivation information providing unit 104 .

On the other hand, when proceeding offline rather than online, the rental member can proceed with cultivation with seeds brought by himself. In addition, rental members can choose a cultivation method suitable for the selected plants. That is, as shown in FIGS. 11 and 12, it is possible to select cultivation or hydroponic cultivation using soil, and in the case of hydroponic cultivation, non-solid cultivation without using a medium (spray hydroponic cultivation, bile hydroponic cultivation, etc.) or rock wool medium Plants can be grown through solid medium cultivation using solid medium such as coco peat medium and perlite medium.

When plant cultivation starts, the camera 116 provided in the plant factory 110 photographs the leased cultivation module 111 in real time, and transmits the captured image to the database 107 of the plant factory operation server 100. and stored, and the image analysis and image providing unit 108 of the plant factory operation server 100 provides the corresponding image to the member terminal 200. At this time, in the present invention, the image analysis and image providing unit 108 of the plant factory operation server 100 extracts and analyzes the image of the video transmitted from the camera 116 of the plant factory 110 to analyze the current growth state of the plant. Information on may be generated and provided to the member terminal 200 . That is, the plant's height, leaf quantity, color, shape, etc. are identified from the extracted image, and current growth state information of the plant is generated based on the identified information and provided to the member terminal 200 .

In addition, it is also possible to provide through the member terminal 200 an image (an image quickly showing the growth process of a plant) showing the photographed image at double speed.

As described above, in the present invention, various information for plant cultivation is provided to the rental members of the plant factory 110, the current state of the plant being grown can be checked in real time, and the cultivation module 111 is selected according to the rental member's selection. It is also possible to automatically control environmental state values and material supply by the plant factory operation server 100, so even ordinary people without knowledge about plant cultivation can perform efficient remote cultivation.

In addition, by cultivating the rental member's plants in the modularized cultivation module 111, it is possible to directly move and cultivate the plants grown in the plant factory 110 to a desired place.

In addition, as shown in FIG. 8, by conveying the provision of various information through the member terminal 200 through the character, it is possible to arouse interest in plant cultivation from the rental member, and other rental members registered as friends It is also possible to watch a video of a plant being grown.

On the other hand, when the harvest time of the corresponding plant has arrived, the cultivation information providing unit 104 of the plant factory operation server 100 transmits the corresponding information to the member terminal 200, and the corresponding plant is stored in the plant factory operation server 100. It is harvested by the robot arm 115 according to the control signal of the plant factory control unit 103.

Lease members can choose whether to directly ship the harvested plants or sell them.

If the rental member chooses direct delivery, the harvested plants will be delivered to the address selected by the rental member.

When the rental member selects sales, the transaction management unit 105 of the plant factory operation server 100 receives information for sale of the cultivated plants from the member terminal 200, stores the information in the database 107, and at the same time As shown in FIG. 9 , plants are transmitted to the purchaser terminal 300 that wants to purchase plants, so that transactions between members and buyers are made.

At this time, the purchaser recommends plant data for each functional component (diet, anti-diabetes, anti-cancer, anti-liver disease, hypertension prevention, etc.) provided as shown in FIG. 10 in the plant information provider 106 of the plant factory operation server 100 and Not only can you select the plant you want to purchase by referring to the columns of plant-related experts (doctors, trainers, oriental doctors, etc.), but also provide buyers of cultivated plants with information about growers (rental members) and cultivation history data, so you can feel at ease. Allows for purchase of cultivated plants.

As described above, in the present invention, the rental member can directly sell the plants grown by the plant factory operating system, so that the rental member can realize profits while satisfying the desire for gardening, and the buyer can buy fresh agricultural products in the city center It can be obtained quickly and inexpensively from the plant factory 110 located in , so that cultivation, sales, and purchase can all be efficiently performed in one system.

In addition, since it is possible to directly purchase plants grown in the city center through the plant factory operation system, there is an effect that the intermediate distribution process is omitted and the purchase is possible at a low price.

On the other hand, in the present invention, it is possible to collect various types of related cultivation environment data for each plant using the IoT-Edge module, and the health status of the plant can be grasped using the cultivation environment data and images collected through the camera 116. and decide when to harvest. That is, as shown in FIG. 13, the NDVI (Normalized Difference Vegetation Index) analysis, which measures the difference between near-infrared rays strongly reflected by vegetation and red light strongly absorbed by vegetation, can be performed to determine the health status and maturity of plants. The health status, maturity, and cultivation environment data for each plant are visualized and provided through an integrated interface, as shown in FIG. 14, so that they can be used for plant cultivation. Specifically, as shown in FIG. 14, environmental data such as humidity, temperature, water temperature, light, UV light, CO 2 , altitude, pressure, pH, and dissolved oxygen are visualized and shown as specific numerical values, and at the same time, classification results related to harvest determination, camera (116 ) can be visualized and provided through an integrated interface. In addition, as a result of identifying the health status of the plant, if it is found that there is an abnormality in the health of the plant or that pests and diseases have occurred, measures such as pest management using a pest control device and avoidance of physiological disorders through control of the plant's growth environment are automatically or by a manager can be taken through

In addition, by using blockchain technology, the value of each plant can be evaluated based on the growth data, transaction data, and supply data of each plant, and customers can generate profits by selling plants according to the evaluated value of each plant. In addition, customers can receive the generated profits as coins and purchase various seeds and vegetables through coins in their own market.

On the other hand, in the present invention, it is possible to match the demand and supply of vegetables by identifying the demand for vegetables desired by each region and performing customized cultivation of vegetables to meet the demand. Specifically, the virtual demand and virtual inventory prediction unit 109 of the smart farm operation server 100 collects demand data for each vegetable from demand sources such as food factories and restaurants, and together with this, the plant factory where each vegetable will be supplied (110 ) and the demand source 400, the virtual demand (order amount) for each plant can be predicted by collecting and analyzing together the data of the distance and the predicted payment quantity data. In addition, the virtual demand and virtual inventory forecasting unit 109 of the smart farm operation server 100 can predict the virtual inventory by collecting and analyzing data related to the current stock for each plant, the storage period, and the freshness for each storage period.

In addition, the virtual demand and virtual inventory forecasting unit 109 of the smart farm operation server 100 establishes a cultivation plan to match demand and supply based on the virtual demand and virtual inventory predicted through analysis, so that each plant factory 110 Accordingly, each consumer 400 can receive a desired quantity of fresh vegetables on time, and growers (rental members) of the plant factory 110 can receive distribution of vegetable delivery revenue. At this time, the plant information providing unit 106 of the smart farm operation server 100 compares virtual demand (order amount) and virtual inventory, preferentially recommends insufficient vegetables to growers (rental members), and selects the vegetables (rental members). ) can be provided with incentives (nutritional discounts, etc.) to induce the cultivation of insufficient vegetables, thereby securing the supply of vegetables, and the grower (rental member) will receive a distribution of the profits delivered to the consumer (400) immediately upon completion of the cultivation of vegetables. can

On the other hand, when an emergency order occurs, the distance between the demand source 400 and each plant factory 110 in the virtual demand and virtual inventory prediction unit 109 of the smart farm operation server 100, the vegetable inventory of each plant factory 110 , By performing a search based on virtual demand (order volume) forecast data, virtual inventory forecast data, etc., it is possible to quickly supply vegetables that the consumer 400 wants to receive urgently, and replenish vegetable stock in the plant factory 110. For this, vegetables from the plant factory 110 in other regions may be supplemented or newly grown.

Meanwhile, in the present invention, a device (not shown) for automatically rotating the first connecting bar 120 and the second connecting bar 130 is provided in the cultivation shelf 112 to convert the cultivation shelf 112 vertically and horizontally. Arrangement is made automatically, and since a recognition device (not shown) such as an NFC tag recognition device and an RFID reader is provided at the entrance of the plant factory 110, when the grower directly visits the plant factory 110, the NFC tag and RFID tag is tagged with a recognition device (not shown), the cultivation shelf 112 on which the cultivation module 111 in which the grower's plant is grown is seated is automatically rotated, and the cultivation module 111 in which the grower's own plant is grown ) can be easily managed directly. At this time, a sensor (not shown) for detecting the grower's height may be separately installed in the cultivation shelf 112 so that the cultivation shelf 112 rotates according to the height of the grower.

In addition, in the present invention, an auxiliary mobile vehicle (not shown) that can be stably moved by being docked with the cultivation shelf 112 may be additionally provided, and the cultivation shelf 112 is also docked with the auxiliary mobile vehicle (not shown). A docking device (not shown) may be additionally provided. In addition, as shown in FIG. 16, wheels 150 are formed on each of the extensions 131 on both sides of the cultivation shelf 112, so that the cultivation shelf 112 can be easily moved by an auxiliary mobile vehicle (not shown).

Accordingly, when a plurality of growers reserve a visit while a plurality of cultivation shelves 112 are arranged in the plant factory 110, an auxiliary mobile vehicle (not shown) is automatically reserved when the visit reservation time of the grower arrives. It is possible to rearrange the cultivation shelf 112 on which the cultivation module 111 of one grower is seated. Specifically, as shown in FIG. 17, when the reservation time arrives in a state where the cultivation shelves 112 numbered 1 to 9 are sequentially arranged in the inner space of the plant factory 110, the auxiliary mobile vehicle in order ( The cultivation shelves 112 (eg, cultivation shelves 112 up to No. 3, 5, and 7) on which the cultivation modules 111 of growers reserved by (not shown) are seated can be moved to the front line on the drawing. . Accordingly, the grower can easily find and manage his cultivation module 111, and even when the cultivation shelf 112 rotates and the seating plate 140 is arranged horizontally, it does not conflict with other cultivation shelves 112. can do.

As described in detail above, the plant factory operation system including the cultivation module according to the present invention provides rental members of the plant factory with various information for plant cultivation and allows them to check the current state of the plant being grown in real time, In addition, it is also possible to automatically control the environmental status values and material supply of the cultivation module by the plant factory operation server according to the selection of the rental member, so that even ordinary people without knowledge about plant cultivation can perform efficient remote cultivation.

In addition, by allowing rental members to sell plants grown directly through the plant factory management system, rental members can satisfy their desire for gardening while realizing profits, and buyers can purchase fresh agricultural products from a plant factory located in the city center. By enabling rapid and inexpensive acquisition from the environment, cultivation, sales, and purchase can all be performed efficiently in one system.

In addition, the customer's cultivated plants are photographed with a camera in real time, and the captured video is image-analyzed to identify the current growth status information of the plant and provide it to the rental member, enabling efficient remote cultivation.

In addition, various information for cultivation may be provided to the rental member, but interest in plant cultivation may be aroused by allowing the rental member to freely perform remote cultivation through the terminal.

In addition, a video (a video showing the growth process of a plant quickly) is provided through the terminal of the rental member, and the provision of various information through the terminal is delivered through the character, which shows the video captured in real time through the camera at double speed. It can arouse interest in cultivation.

In addition, by cultivating the rental member's plant cultivation in a modularized cultivation module, it is possible to directly move and grow the plants grown in the plant factory to a desired place.

In addition, information on the grower (rental member) and cultivation history data are provided to buyers of cultivated plants so that they can purchase cultivated plants with confidence. There is an effect of being able to purchase cheaply by omitting the middle distribution process.

In addition, it is possible to provide purchasers with recommended plant data for each functional component, and provide columns of experts (doctors, trainers, oriental doctors, etc.) related to each plant.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings, but since the above-described embodiments have only been described as preferred examples of the present invention, the present invention is limited to the above embodiments. It should not be understood that it is, and the scope of the present invention should be understood as the following claims and their equivalent concepts.

100: plant factory operation server
101: communication processing unit
102: App provider
103: plant factory control unit
104: cultivation information provision unit
105: transaction management department
106: plant information provision department
107: database
108: image analysis and video provision unit
109: virtual demand and virtual inventory forecasting unit
110: plant factory
111: cultivation module
112: cultivation shelf
113: environmental control unit
114: supply control unit
115: robot arm
116: camera
120: first connecting bar
121: 1st rotation axis
130: second connecting bar
131: 2nd rotation axis
132: extension
140: seating plate
150: wheel
200, 300: member terminal, purchaser terminal
210, 310: Communication Department
220, 320: display
230, 330: key input unit
240, 340: App operation department
250, 350: information provision unit
260, 360: information receiving unit
400: Demand

Claims (4)

A plant factory made of a structure having a certain space blocked from the outside and formed in a narrow space in an area close to the city center;
A member terminal operated by a rental member;
a purchaser terminal operated by a purchaser of the cultivated plant; and
A plant factory operation server that provides various information to the member terminals and purchaser terminals and controls each component of the plant factory by receiving a control signal transmitted from the member terminals; A plant factory operating system that includes
According to claim 1,
The plant factory operation server,
Cultivation module characterized in that it comprises a; image analysis and image providing unit that extracts and analyzes the image of the video transmitted from the camera of the plant factory, generates information on the current growth state of the plant, and provides it to the member terminal. A plant factory operating system comprising a.
According to claim 1,
The plant factory,
A plant factory operating system including a cultivation module comprising a modularized cultivation module in which a temperature controller, a humidity controller, a light quantity controller, a nutrient solution supply device, a water supply device, and a functional useful material supply device are integrally formed.
According to claim 1,
The plant factory operation server,
A plant factory operation system including a cultivation module comprising a; virtual demand and virtual inventory forecasting unit for establishing a cultivation plan to match demand and supply by predicting virtual demand and virtual inventory of each plant.

Images