KR102290177B1 - Agricultural products distribution system based on agricultural products trading platform - Google Patents

Abstract

An agri-food distribution system based on an agri-food trading platform is provided. The agri-food distribution system includes: a smart farm device that receives and outputs agri-food cultivation history data accompanying a growing process of agri-food from a producer or through a plurality of sensors; a production history tracking server that outputs the cultivation status of the agri-food based on the agro-food cultivation history data and provides at least one of crowdfunding, pre-order, medium distribution, and consumer ordering service for agri-food according to the cultivation status; A consumer generating a user interface to use at least one of the crowdfunding, the pre-order, the badge distribution, and the consumer ordering service provided by the production history tracking server, and outputting the consumption history data input through the user interface a terminal; And it may include an integrated management server that provides an agri-food transaction service based on the agri-food transaction platform to the production history tracking server and the consumer terminal using the received agri-food cultivation history data and the consumption history data.

Description

Agri-food distribution system based on an agri-food trading platform

The present invention relates to an agri-food distribution system based on an agri-food trading platform, and more particularly, to an agri-food distribution system utilizing agri-food production history information obtainable from a smart farm.

Agriculture is an industry essential for human survival as it produces food, but it is also the slowest industry to innovate because traditional agricultural technology is maintained. In addition, concerns about future food production are increasing due to the decrease and aging of the current agricultural production population.

In response to this, various innovations in agriculture are being attempted. Smart technology that combines information and communication technology with agricultural production/processing/distribution/consumption, etc. to remotely and automatically manage the growing environment of crops and increase production efficiency. Smart farms are currently attracting attention.

Smart farms according to the prior art are mostly about the opening and closing and control technology of cultivation facilities based on environmental information such as temperature and humidity, CO2, and illuminance. technology is insufficient.

In addition, in the smart farm technology being developed so far, the development of information processing technology, information sharing technology, and information database technology required in various related fields including distribution/consumption is not sufficiently developed.

Therefore, it is required to develop a platform that connects producers and consumers producing agri-food or a platform that can perform history management and consumer management of agri-food, which must be accompanied in the agricultural and fishery product transaction process.

Korean Patent Publication No. 10-1871468 (2018.06.20)

The problem to be solved by the present invention is to develop a reliable agri-food trading platform using various data obtained from a smart farm, and to provide an agri-food distribution system, method, and apparatus using such a platform.

In addition, the problem to be solved by the present invention is to provide an agri-food distribution system, method, and apparatus capable of providing a user with information on the production history for each stage of agri-food production that cannot be forged or tampered with.

In addition, an object of the present invention is to provide an agri-food distribution system, method, and apparatus capable of tracking a consumer's purchase history and providing information on the purchase history to an agri-food producer.

According to an embodiment of the present invention, an agri-food distribution system based on an agri-food trading platform is provided. The agri-food distribution system includes: a smart farm device that receives and outputs agri-food cultivation history data accompanying the cultivation process of agri-food from a producer or through a plurality of sensors; a production history tracking server that outputs the cultivation status of the agri-food based on the agro-food cultivation history data and provides at least one of crowdfunding, pre-order, medium distribution, and consumer ordering service for agri-food according to the cultivation status; A consumer generating a user interface to use at least one of the crowdfunding, the pre-order, the badge distribution, and the consumer ordering service provided by the production history tracking server, and outputting the consumption history data input through the user interface a terminal; And it may include an integrated management server that provides an agri-food transaction service based on the agri-food transaction platform to the production history tracking server and the consumer terminal using the received agri-food cultivation history data and the consumption history data.

According to an embodiment of the present invention, a reliable agri-food trading platform can be developed using various data obtained from a smart farm, and an agri-food distribution system, method, and apparatus using such a platform can be provided.

In addition, according to an embodiment of the present invention, an agri-food distribution system, method, and apparatus that can provide a user with information about the production history of the agri-food production step that cannot be forged or tampered with may be provided.

In addition, according to an embodiment of the present invention, an agri-food distribution system, method, and apparatus can be provided that can track a consumer's purchase history and provide information on the purchase history to the agri-food producer.

Further, according to an embodiment of the present invention, an agri-food distribution system, method, and apparatus capable of authenticating eco-friendly agri-food using cultivation history information may be provided.

In addition, according to an embodiment of the present invention, an agri-food distribution system, method, and apparatus can be provided that can introduce crowdfunding to encourage stable agri-food production to agri-food producers and to obtain excellent agri-food at a reasonable price for consumers.

In addition, according to an embodiment of the present invention, an agri-food distribution system, method, and apparatus with improved reliability can be provided by storing and processing agri-food production history information and user's consumption history information using a block chain.

1 is a control block diagram of an agri-food distribution system according to an embodiment of the present invention;
2 is a diagram illustrating a user interface generated in an embodiment of the present invention;
3 is a control flowchart for explaining the agro-food eco-friendly authentication process according to an embodiment of the present invention;
4 is a control flowchart for explaining the agri-food reliability verification process according to an embodiment of the present invention;
5 is a control flowchart for explaining the agro-food crowdfunding and pre-order process according to an embodiment of the present invention;
6 is a view showing a pre-order user interface according to an embodiment of the present invention,
7A and 7B are exemplary graphs for explaining data verification according to an embodiment of the present invention,
8 is a control block diagram of an agri-food distribution system according to another embodiment of the present invention;
9 is a diagram illustrating a computing device according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

In the present specification, duplicate descriptions of the same components will be omitted.

Also, in this specification, when it is mentioned that a certain element is 'connected' or 'connected' to another element, it may be directly connected or connected to the other element, but another element in the middle. It should be understood that there may be On the other hand, in this specification, when it is mentioned that a certain element is 'directly connected' or 'directly connected' to another element, it should be understood that the other element does not exist in the middle.

In addition, the terms used herein are used only to describe specific embodiments, and are not intended to limit the present invention.

Also, in this specification, the singular expression may include the plural expression unless the context clearly dictates otherwise.

Also in this specification, terms such as 'include' or 'have' are only intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, and one or more It should be understood that the existence or addition of other features, numbers, steps, operations, components, parts or combinations thereof is not precluded in advance.

Also in this specification, the term 'and/or' includes a combination of a plurality of listed items or any of a plurality of listed items. In this specification, 'A or B' may include 'A', 'B', or 'both A and B'.

Also, in this specification, detailed descriptions of well-known functions and configurations that may obscure the gist of the present invention will be omitted.

1 is a control block diagram of an agri-food distribution system according to an embodiment of the present invention.

As shown, the agri-food distribution system 1 according to this embodiment is a smart farm device 100, a production history tracking server 200 capable of receiving data from the smart farm device 100, and generating a user interface. It may include a consumer terminal 300, a block chain 450 in which data is distributed and stored, and an integrated management server 400 that integrally manages them.

All members may be connected through a wired/wireless network, and at least one of each component may be physically or functionally merged with each other.

Recently, with the improvement of living standards and increased interest in health and the environment, interest in the quality of agri-food is also increasing. Reflecting these needs, in the case of agro-food, the demand for organic vegetables and fruits grown using only natural materials such as organic matter and microorganisms without using any synthetic chemicals such as chemical fertilizers, organic synthetic pesticides, growth regulators, herbicides, and additives. It is also increasing. However, as the production history of such agri-food is not properly managed, there is a problem in that consumers cannot understand the environment and process in which the agri-food they are purchasing is produced. In addition, from the standpoint of producers who produce and sell agri-food through proper processes, there was a difficulty in that it was not clear how to guarantee organic or consumer-desired agri-food.

The agri-food distribution system 1 according to this embodiment provides an integrated management server 400 based on the production history tracking server 200, the consumer terminal 300, and the agri-food transaction platform for solving the above-described problems.

The smart farm device 100 includes a plurality of sensors 110 and CCTV 130 as shown, and outputs agro-food cultivation history data accompanying the cultivation process of agri-food to the production history tracking server 200 .

The smart farm device 100 may include various sensors 110 for controlling environmental state values such as an environmental control module, an internal cultivation module, and a plant cultivation module (not shown). For example, the sensor 110 may include a temperature sensor, a humidity sensor, a light quantity sensor, etc. for controlling the cultivation environment of agri-food, and may include a heating/cooling sensor, a lighting sensor, and the like. In addition, the smart farm device 100 may further include a sensor capable of sensing and controlling the amount of a material required for cultivation of agri-food, for example, a nutrient solution, water, a functional useful material, and the like.

The agricultural food cultivation history data that can be generated from the sensor 110 includes at least one of cultivated items, cultivation area, cultivation quantity, cultivation process, fertilizer and irrigation data, weeding or pest data that can be received from the sensor of the smart agricultural machine, and harvest data. may contain one. Recently, a lot of data can be automatically collected without input from producers because codes or marks are used to electronically distribute and trade the seeds and seedlings of agricultural products.

On the other hand, such agricultural food cultivation history data may be input to the smart farm device 100 or the production history tracking server 200 by the producer. For example, cultivated items, cultivated area, cultivated quantity, etc. may be directly input by the producer.

Data on fertilizer and irrigation can be identified through soil condition data such as PH, EC, temperature, humidity, and weight of the medium, and the type and amount can be identified, which is data that is comparatively analyzed by the production history tracking server 200 can be used as

In addition, agro-food cultivation history data includes agrochemical-related data on agrochemical purchase information, purchase information, agrochemical usage time and pesticide usage and pesticide inventory, which are automatically input to the production history tracking server 200 through e-commerce with a purchaser. Selection/packaging data automatically input to the production history tracking server 200 from the system that automatically sorts and packs by size and state It may further include storage management data including at least one of a storage environment, storage quantity, storage period, and storage date climate information.

On the other hand, the agricultural food cultivation history data that the producer must directly input may be computerized through the farmer's work log, etc., and the computerized data may be automatically input to the smart farm device 100 or the production history tracking server 200 . For example, if work is performed using a smart agricultural machine, data on agricultural work weeding and pest management may be automatically entered into the production history tracking server 200 through the work log, and the harvest date, the weather at the time of harvest, and the harvest area And harvest data on the yield can also be collected without input from the producer.

On the other hand, the cultivation process of agri-food may be collected through the CCTV 130 installed at the agri-food cultivation site, and the video of the cultivation process collected through the CCTV 130 is displayed on the consumer terminal 200 in real time according to the request of the consumer. ) can be output.

Through this, consumers can check the growing process of agri-food in real time, so they can purchase reliable agri-food with confidence.

The production history tracking server 200 outputs the cultivation status of agri-food to the consumer terminal 300 and the integrated management server 400 based on the agri-food cultivation history data, and crowdfunding, pre-order, and medium distribution for agri-food according to the cultivation status. and a consumer ordering service.

Meanwhile, crowdfunding, pre-order, badge distribution, and consumer order services may be generated in the integrated management server 400 and provided to the consumer terminal 300 . It will be described in detail below.

The smart farm device 100 and the production history tracking server 200 may be configured as a producer terminal, and the two components may be merged into one hardware such as a terminal, a computing device, or a server.

The consumer terminal 300 generates a user interface to use at least one of crowdfunding, pre-order, badge distribution, and consumer order services provided by the production history tracking server 200 or the integrated management server 400, and provides a user interface. The consumption history data input through the integrated management server 400 may be transmitted to the production history tracking server 200 through the integrated management server 400 .

The consumer terminal 300 may include a user interface unit 310 for generating a user interface. The user interface unit 310 may be used as a generic term for a means or module for generating an interface that a user can visually or audibly recognize and receiving a user input through the generated interface.

FIG. 2 is a diagram illustrating a user interface generated in an embodiment of the present invention, and a consumer may be provided with information on agri-food produced by the producer, information on the producer, information on investment, and the like.

In addition, this user interface may include an item that can be linked with an SNS account that can be used by consumers, and feedback information on agri-food through SNS may be provided to the producer.

Consumption history data that can be provided to the integrated management server 400 and the production history tracking server 200 through the consumer terminal 300 is based on purchase history data, product reviews, compensation data, and purchase history data of agri-food and purchase time. It may include at least one of the analyzed consumption patterns.

The purchase history means information on the purchase history of agri-food when a consumer makes a purchase, and the purchase history can be viewed in real time by the producer.

On the other hand, when a consumer writes a product review in the above-described SNS or product review item after purchasing agri-food, a reward item such as a coupon may be provided.

The consumption amount of the user, that is, the consumption pattern for the sales volume and consumption period for agri-food may be converted into big data by the integrated management server 400 , statistically analyzed, and provided to the production history tracking server 200 .

In addition, the production history tracking server 200 provides analysis results on the consumption pattern for each agro-food item analyzed by the integrated management server 400 based on the consumption history data input from the consumer terminal 300 and the price trend by climate period. can receive

The integrated management server 400 provides an agri-food transaction service based on the agri-food transaction platform to the production history tracking server 200 and the consumer terminal 300 using the received agri-food cultivation history data and consumption history data.

In addition, as described above, the integrated management server 400 analyzes and compares the data collected by the sensor 110 or the direct input of the producer based on the big data data of the entire production process, so that the producer produces the amount of production for each agro-food or arable land. can be predicted, or the type and amount of fertilizer and irrigation can be identified and provided to producers by analyzing the collected soil condition data. In addition, producers can predict production according to agro-food crops, environment, and cultivated land through analysis of cultivation area and yield comparison data and analysis through big data statistical data linkage, and can efficiently manage the inventory of agri-food, fertilizer, and pesticides. . That is, the producer can efficiently manage farmhouse information through the analysis of various data provided by the integrated management server 400 and perform planned and scientific farming.

On the other hand, the integrated management server 400 may distribute and store data requiring high reliability among agro-food cultivation history data and data requiring high reliability among consumption history data on the block chain 450 . The price, transaction history, consumption pattern, important cultivation process, production volume, sales volume, etc. of agri-food are stored in the block chain 450, making it impossible to forge or falsify data, and through this, trust between producers and consumers and verified agri-food transactions are possible becomes For example, data collected for each stage of agri-food production may be stored in each block, and consumer consumption patterns may be stored in chronological order.

The integrated management server 400 analyzes the data stored on the block chain 450 to select only data with high similarity, periodically deletes unselected data, and restores only the selected data. can

In summary, the agri-food trading platform according to this embodiment stores the production history tracking data provided from the producer and the consumption history data provided from the consumer in the block chain 450 to perform reliable data management to prevent forgery and falsification of data, Establish a transaction system of a batch process method that links production to consumption. Through this, producers can sell agri-food at a higher price by securing reliability and increase the brand value of agri-food. In addition, consumers can secure reliable and safe food, and can receive agri-food at a reasonable price through the simplification of the distribution process.

3 is a control flowchart for explaining an agro-food eco-friendly authentication process (or an agri-food eco-friendly authentication method) according to an embodiment of the present invention.

In FIG. 3 , processes S310, S320, and S330 may be processes related to farming preparation, and processes S340, S341, and S342 may be processes related to a cultivation process.

As shown, for agro-food eco-friendly certification, the integrated management server 400 may analyze soil state data such as PH, EC, temperature, humidity, and weight of the medium based on big data data (S310).

Soil condition data such as PH, EC, temperature, humidity, and weight of the medium may be input from the smart farm device 100 or a smart agricultural machine used for the cultivation of agri-food, and the land condition of government agencies and municipalities related to agriculture It may also be obtained from verification and data from the agency.

If the soil condition data is analyzed based on the big data data, the recommended fertilizer type, the recommended fertilizer amount, and the recommended irrigation amount may be set (S320).

The integrated management server 400 may provide the recommended fertilizer amount and the recommended irrigation amount set in this way to the consumer terminal 300 (S330). Specifically, recommended data according to crops, such as a recommended amount of fertilizer and a recommended amount of irrigation, may be provided.

The consumer terminal 300 may compare the recommended fertilizer type, the recommended fertilizer amount, and the recommended irrigation amount with the fertilizer and irrigation data used for agro-food (S340).

For data input by a user and data acquired through a sensor of the smart farm device 100, data verification may be performed through a data-to-data verification algorithm (S341).

A smart contract related to the block chain may be generated. When data abnormality is detected through verification, it may be estimated that data input by the user has been forged or altered.

Data verified beyond data (eg, A', B', ..., n') or data verified as normal (eg, A, B, ..., n) can be distributed and stored in the blockchain. There is (S342). Through this, more transparent and reliable eco-friendly authentication data can be provided.

The user interface unit 310 may generate a user interface for displaying a comparison result, and may generate and authenticate an authentication user interface capable of performing eco-friendly authentication for agri-food based on the comparison result (S350).

For example, the authentication use interface means that when the fertilizer actually used by the producer is less than the recommended fertilizer amount, it indicates that agri-food is being produced in an eco-friendly manner, and the authentication result is provided to the production history tracking server 200 to the producer can be fed back to The certification level may be set in various grades according to the amount of fertilizer or the type of fertilizer, the type and amount of irrigation, and the like, and a preset certification score may be given to a producer certified as eco-friendly. These scores can be used as information for consumers to purchase agri-food, and producers can increase sales of agri-food through this.

4 is a control flowchart for explaining the agri-food reliability verification process (or agri-food reliability verification method) according to an embodiment of the present invention.

In order to verify the reliability of agri-food, first, the integrated management server 400 may analyze the cultivation area and yield based on big data (S410).

Through big data data analysis, the predicted production according to the crop type, environment, and cultivated land of agro-food can be derived (S420), and the sales volume based on the derived predicted production, harvest, and consumption history data is sent to the consumer terminal 300. provided (S430).

The consumer terminal 300 may compare the yield with the sales volume to determine whether the yield is greater than or equal to the sales volume (S440), and the user interface unit 310 may verify the reliability of distribution for agri-food based on the comparison result. You can create user interfaces.

If it is determined that the sales volume exceeds the yield, it may be estimated that the yield is forged or altered by the producer or other external factors (S450). This information can be fed back to producers, who can review data on yields. In addition, if it is finally confirmed that the yield is counterfeit or falsified, the consumer may lower the level of trust in the agri-food, and accordingly, the sales volume of the agri-food may decrease.

On the other hand, if it is determined that the yield is greater than or equal to the sales volume, the consumer verifies the distribution reliability of the agri-food (S460). Such verification information may also be provided to the production history tracking server 200, and may be stored and managed in the block chain 450 as main data.

On the other hand, when the distribution reliability is verified, the consumer terminal 300 may compare the yield with the expected production to determine whether the yield exceeds the expected production (S470).

Even in this case, the user interface unit 310 may generate an authentication user interface capable of authenticating the excellence of agro-food based on the comparison result.

If it is determined that the yield exceeds the expected yield, this may be interpreted as the excellent crop yield of the agri-food and the excellent cultivation condition of the producer (S480). This information can be fed back to the producer, and the producer can adjust the yield or reconsider the price of the agri-food in consideration of the price of the agri-food.

On the other hand, if it is determined that the yield is smaller than the expected production amount, this data may also be fed back to the producer and used to improve the agro-food cultivation environment (S490).

The excellence verification data of such a crop cultivation state may also be stored and managed in the block chain 450 .

The above-described distribution reliability verification determination (S440) and agri-food cultivation state excellence certification determination (S470) may be performed by the integrated management server 400 and provided to the consumer terminal 300 and the production history tracking server 200 .

5 is a control flowchart for explaining the agro-food crowdfunding and pre-order process (or agro-food crowdfunding and pre-order method) according to an embodiment of the present invention.

First, the integrated management server 400 may analyze the crop status of the agro-food according to the cultivation process based on the big data data (S510).

The crop status information analyzed in this way is compared with the cultivation process provided by the production history tracking server 200, and through this, the superiority of the crop status of agro-food can be determined (S520).

For example, as shown in FIG. 5 , it may be determined that the crop condition of the agro-food is excellent as the yield of the agri-food exceeds the expected production amount, and the development state of the agri-food at the time is superior to the agri-food of other regions or other producers The superiority of the crop condition can be judged by whether or not.

When the excellence of agro-food is recognized and information is transmitted to the consumer terminal 300, the user interface 310 of the consumer terminal 300 may purchase agri-food at a price lower than the sale price of the agri-food before the harvest of the agri-food. It is possible to create a pre-order interface or create a crowdfunding interface for funding the funds accompanying the cultivation process of agricultural plants before harvesting agricultural plants (S530).

6 is a diagram illustrating a pre-order user interface according to an embodiment of the present invention.

As shown, the consumer can check the current state of the agri-food through the video, and if he wants to purchase, he can make a purchase before harvesting the agri-food. Of course, an interface capable of crowdfunding in a form similar to that of FIG. 6 may be provided through the agri-food trading platform.

In addition, according to another embodiment of the present invention, the integrated management server 400 may provide a service for distributing badges to the consumer terminal 300 . Badge distribution is a form of weekend farm that is receiving a lot of attention from consumers living in cities, and it is possible to plant and manage recommended agri-food by receiving badges for sale online. Recently, weekend farms are often used for educational purposes for children, and the badge distribution service will be of great significance in the sense of reducing rejection of agri-food and discovering future consumers through direct experiences with vegetables and fruits.

In addition, the integrated management server 400 according to the present invention provides a coupon for agri-food transaction when a purchase review for agri-food is input through the consumer terminal 300 or a request for crowdfunding, pre-order, and distribution of badges occurs to the consumer terminal ( 300) can be transmitted. These coupons can be mileage that can be used like cash, or can be replaced with fertilizer or manure necessary for the agro-food cultivation process of the medium received.

On the other hand, according to another embodiment of the present invention, when the integrated management server 400 receives a request for distribution of the medium from the consumer terminal 300, the cultivation process for the agri-food grown in the distributed medium is performed every preset cycle to the consumer. It can be transmitted to the terminal 300 .

The information on the cultivation process may include real-time video information on agri-food as described above, and such real-time video information may increase the reliability of cultivation of agri-food.

7A and 7B are exemplary graphs for explaining data verification according to an embodiment of the present invention.

According to an embodiment of the present invention, the integrated management server 400 that has received the agricultural food cultivation history data from the production history tracking server 200 or the production history tracking server 200 may perform verification for data verification. . This may mean an algorithm for checking whether data is abnormal by comparing data input by the producer or data having time series collected from the smart farm device 100 .

When a process of determining normality or abnormality according to the data flow occurs in this way, a smart contract is generated in the block chain 450 each time, and whether such data is abnormal is stored in the block chain 450 . The smart contract is the method of payment for the contract and the reciprocal benefit is encrypted, and the process of contract execution and verification is automated with the network. It is a contract that enables safe execution based on trust. It has the advantage of high efficiency because it can solve records, cash flow and contract fulfillment on one platform through smart contracts.

7A is a diagram illustrating an example for explaining verification of agricultural food cultivation history data. Based on the illuminance data, if there are clouds during the daytime or the temperature drops despite no awning, this may mean that the illuminance data is abnormal. That is, in a normal situation, the temperature data should show a similar pattern according to the illuminance data, but otherwise, it may be determined that an error occurs in the illuminance data.

Alternatively, based on the operation time data of the nutrient solution system as shown in FIG. 7B , if the soil moisture has increased even though there is no operation of the nutrient solution device, it can be detected as data abnormality, and it can be determined as a situation in which spraying of pesticides on the soil is suspected. Producers will be able to respond subsequently to errors in data.

Alternatively, according to another example, as described above, a smart contract may be generated by comparing the expected yield compared to the cultivated area, the actual yield, the sales volume, etc., and the cultivation data may be verified by comparing the size of the crops by cultivation date. When errors in data are verified in this way, producers can find out the cause of errors and determine whether there are actual errors in the data, or solve the errors.

8 is a control block diagram of an agri-food distribution system according to another embodiment of the present invention.

As shown, the agri-food distribution system according to this embodiment may communicate with a sales server 500 that sells agri-food online or offline through a network. That is, the integrated management server 400 provides the agri-food transaction platform to the sales server 500, thereby providing the agri-food transaction data and interface according to the present invention described in FIGS. 500) can be implemented.

The sales server 500 may generate revenue according to advertisement and sales of agri-food, and some revenue may be provided to the integrated management server 400 . In addition, the consumer may purchase the agri-food through the sales server 500 and may receive a coupon or perform authentication or verification for the agri-food in the same manner as in the above-described embodiment.

As described above, according to the agro-plant distribution system according to the present invention, an agri-food transaction service that connects producers and consumers is provided, and by providing the cultivation stage and production process of agri-food to the consumer terminal, it is possible to induce an agri-food transaction with improved reliability. In addition, it is possible to increase the utilization of smart farms.

On the other hand, each device included in the agri-food distribution system described above may perform an operation related to the agri-food distribution method of the agri-food distribution system described above. Specifically, the agri-food distribution method of the agro-food distribution system may be based on procedures and functions related to the agro-food distribution system described above. For example, the agri-food distribution system can distribute and store agri-food cultivation history data accompanying the cultivation process of agri-food on the block chain. The agri-food distribution system may provide at least one of crowdfunding, pre-order, medium distribution, and consumer ordering service for agri-food according to the cultivation state of the agri-food. The agri-food distribution system uses consumption history data for at least one of crowdfunding, pre-order, medium distribution, and consumer order services for agri-food, and agri-food cultivation history data to provide an agri-food transaction service based on an agri-food trading platform. can

9 is a diagram illustrating a computing device according to an embodiment of the present invention. The computing device TN100 of FIG. 9 may be a device (eg, an integrated management server, a production history tracking server, a consumer terminal, or a smart farm device) described herein.

The computing device TN100 may include at least one processor TN110 , a transceiver device TN120 , and a memory TN130 . In addition, the computing device TN100 may further include a storage device TN140 , an input interface device TN150 , an output interface device TN160 , and the like. Components included in the computing device TN100 may be connected by a bus TN170 to communicate with each other.

The processor TN110 may execute a program command stored in at least one of the memory TN130 and the storage device TN140. The processor TN110 may mean a central processing unit (CPU), a graphics processing unit (GPU), or a dedicated processor on which methods according to an embodiment of the present invention are performed. The processor TN110 may be configured to implement procedures, functions, methods, and the like described in connection with an embodiment of the present invention. The processor TN110 may control each component of the computing device TN100 .

Each of the memory TN130 and the storage device TN140 may store various information related to the operation of the processor TN110 . Each of the memory TN130 and the storage device TN140 may be configured as at least one of a volatile storage medium and a non-volatile storage medium. For example, the memory TN130 may include at least one of a read only memory (ROM) and a random access memory (RAM).

The transceiver TN120 may transmit or receive a wired signal or a wireless signal. The transceiver TN120 may be connected to a network to perform communication.

On the other hand, the embodiment of the present invention is not implemented only through the apparatus and/or method described so far, and a program for realizing a function corresponding to the configuration of the embodiment of the present invention or a recording medium in which the program is recorded may be implemented. And, such an implementation can be easily implemented by those skilled in the art from the description of the above-described embodiments.

Although the embodiment of the present invention has been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also presented. It belongs to the scope of the invention.

Claims (12)

In the agri-food distribution system based on the agri-food trading platform,
a smart farm device for receiving and outputting agricultural food cultivation history data accompanying the agrifood cultivation process through a plurality of sensors;
a production history tracking server that outputs the cultivation status of the agri-food based on the agro-food cultivation history data and provides at least one of crowdfunding, pre-order, medium distribution, and consumer ordering service for agri-food according to the cultivation status;
A consumer generating a user interface to use at least one of the crowdfunding, the pre-order, the badge distribution, and the consumer ordering service provided by the production history tracking server, and outputting the consumption history data input through the user interface a terminal; and
An integrated management server that provides an agri-food transaction service based on the agro-food transaction platform to the production history tracking server and the consumer terminal using the received agri-food cultivation history data and the consumption history data;
The integrated management server,
By analyzing the cultivation area and yield based on big data data, the predicted production amount according to the crop type, environment, and cultivated land of the agro-food is derived, and the yield and If the yield is greater than or equal to the sales volume by comparing the sales volume, the distribution reliability of the agri-food is verified, and when the distribution reliability is verified, the yield and the expected production amount are compared, and when it is determined that the harvest amount is smaller than the expected production amount, Authenticates the excellence of the state of cultivation of crops, stores the information that verifies the distribution reliability of the agri-food, and the excellence verification data of the state of cultivation of the crops in the block chain,
The integrated management server,
Comparing the data with time series collected from the sensor, checking whether the data is abnormal, storing it in the block chain, and analyzing the nutrient solution operation time data and soil moisture data corresponding to the data having the time series property Agri-food distribution system that detects more than data if the moisture in the soil has increased even though there is no operation of the nutrient solution. According to claim 1,
The integrated management server distributes and stores the agricultural food cultivation history data and the consumption history data on a block chain,
The agricultural food cultivation history data includes at least one of cultivated items, cultivation area, cultivation quantity, cultivation process, fertilizer and irrigation data, weeding or pest data that can be received from a sensor of a smart agricultural machine, and harvest data,
The consumption history data includes at least one of purchase history data of the agri-food, product reviews, compensation data, and consumption patterns analyzed based on the purchase history data and purchase time
Agri-food distribution system. 3. The method of claim 2,
The cultivation process is collected through CCTV installed at the agricultural food cultivation site,
The video of the cultivation process collected through the CCTV is output to the consumer terminal in real time according to the request of the consumer,
The harvest data includes at least one of a harvest date received from a smart agricultural machine used for cultivation of the agri-food, weather at the time of harvest, harvest area, and yield
Agri-food distribution system. 3. The method of claim 2,
The agricultural food cultivation history data is,
Pesticide-related data on agrochemical purchase information, purchase information, pesticide use time, pesticide usage and pesticide inventory automatically input to the production history tracking server through e-commerce with a purchaser;
sorting/packing data that is automatically input to the production history tracking server from the system for automatically sorting and packaging the agri-food by size and state;
Further comprising storage management data including at least one of the storage environment, storage quantity, storage period, and storage date climate information of the agricultural food that is automatically input from the storage system of the agri-food to the production history tracking management server
Agri-food distribution system. 3. The method of claim 2,
The integrated management server analyzes soil condition data such as PH, EC, temperature, humidity, and medium weight of the medium based on big data data to set the recommended fertilizer type, recommended fertilizer amount and recommended irrigation amount, and set recommended fertilizer providing the amount and the recommended irrigation amount to the consumer terminal,
The consumer terminal compares the recommended fertilizer type, the recommended fertilizer amount, and the recommended irrigation amount with the fertilizer and irrigation data used in the agro-food, and based on the comparison result, an authentication capable of performing eco-friendly authentication for the agro-food to create a user interface
Agri-food distribution system. delete delete delete 3. The method of claim 2,
When the integrated management server receives a request for distribution of the medium from the consumer terminal, it transmits the cultivation process for agri-food grown in the distributed medium to the consumer terminal at every preset cycle.
Agri-food distribution system. 10. The method of claim 9,
The integrated management server outputs a coupon for the agri-food transaction to the consumer terminal when a purchase review for the agri-food is input through the consumer terminal or a request for the crowdfunding, the pre-order, and the distribution of the badge occurs
Agri-food distribution system. 3. The method of claim 2,
The integrated management server provides the agri-food trading platform to a sales server that provides a service for selling the agri-food online or offline
Agri-food distribution system. In the agri-food distribution method performed by the agri-food distribution system based on the agri-food trading platform,
Distributing and storing agro-food cultivation history data accompanying the cultivation process of agri-food on a block chain;
providing at least one of crowdfunding, pre-order, medium distribution, and consumer ordering service for the agro-food according to the cultivation state of the agro-food; and
Using the consumption history data for at least one of crowdfunding, pre-order, medium distribution, and consumer ordering service for the agro-food, and the agri-food cultivation history data, providing an agri-food transaction service based on an agri-food trading platform; including,
Agri-food reliability verification process and data verification process are further included,
The agri-food reliability verification process is,
By analyzing the cultivation area and yield based on big data data, the predicted production amount according to the crop type, environment, and cultivated land of the agro-food is derived, and the yield and If the yield is greater than or equal to the sales volume by comparing the sales volume, the distribution reliability of the agri-food is verified, and when the distribution reliability is verified, the yield and the expected production amount are compared, and when it is determined that the harvest amount is smaller than the expected production amount, to certify the excellence of the state of cultivation of crops,
In the distributed storage step, the information verifying the distribution reliability of the agri-food and the excellence verification data of the crop cultivation state are stored in the block chain,
The data verification process is
Compare the data with time series collected from the sensor to check whether the data is abnormal, and store it in the block chain,
The data having the time series includes nutrient solution operation time data and soil moisture data,
In the data verification process, as a result of the analysis of the nutrient solution operating time data and the soil moisture data, if the moisture in the soil increases even though the nutrient solution does not operate, the agrifood distribution method detects more than the data.

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