KR102538044B1 - Smart rpc integrated management system - Google Patents

Abstract

A smart RPC integrated management system for integrated management of the operation of a plurality of RPCs scattered in various regions is disclosed. The smart RPC integrated management system of the present invention is a production management system that collects data on overall production from warehousing to shipping of coarse grains and processes them into information for decision-making, information on each facility in RPC, and information related to inspection. Facility maintenance system that collects facility diagnosis and maintenance-related information, collects energy demand status by monitoring energy consumption by each facility in RPC, and minimizes energy consumption of each facility based on the collected energy demand status The energy management system that generates and transmits control commands for the energy management system and remotely collects and stores RPC data sensed from each facility within the RPC, processes the stored RPC data into information serviced through a web or app application, and transmits it to the user device. includes an RPC cloud system that

Description

Smart RPC integrated management system {SMART RPC INTEGRATED MANAGEMENT SYSTEM}

The present invention relates to a smart RPC integrated management system, and more particularly, to a smart RPC integrated management system capable of efficiently integrating and managing facilities and quantities by remotely monitoring a microprocessing plant in an IoT environment operated nationwide. .

The RPC (Rice Processing Complex) is a rice processing complex that handles the entire process of rice, from the importation of harvested rice through sorting, weighing, quality inspection, drying, storage, and milling, to product shipment, sales, and by-product processing, at the individual farm level. It refers to a facility that processes batches with a large-scale automated process rather than a large-scale automation process, and aims to reduce rural labor, reduce rice loss, reduce costs, improve rice quality, and improve distribution structure.

On the other hand, in the existing milling method, the harvested rice is packed with a combine, binder, sickle, etc., transported to a drying facility, and then dried. Quality inspection is carried out in the packaged state, it is stored in the warehouse by grade, stored for a certain period of time, and then temporarily stored in the warehouse of the milling plant through the process of shipping, loading, transporting, and unloading, and then transported to the milling facility to be processed. In the case of RPC, the harvested rice is directly transported to the treatment plant by a product transport vehicle, and then processed in batches through processes such as drying, storage, milling, and packaging.

There are about 750 such RPCs nationwide. Previously, each RPC independently analyzed, aggregated, and managed the input information and production and processing information of the product, so the government gathered this information together to set up policies related to rice supply and demand. It was difficult to derive or use to improve quality control measures. Even from the consumer's point of view, it was difficult to check information about when and where the rice I purchased was milled and whether it was milled in an appropriate way.

In addition, there is a problem in that production management of rice is not efficient due to the absence of an efficient management system for the process of purchasing and shipping rice. In particular, since a systematic database and a program that can manage it integratedly are not established, it is possible to easily manage incoming and outgoing, inventory management, checkbook inquiry, etc. method was absent.

The purpose of the present invention is to collect the overall data from systematic quality control of produced rice and order to production of finished products, and overall matters of RPCs distributed nationwide, from facility maintenance and energy management to production facilities. It is to provide an RPC integrated management system that can be managed in an integrated and efficient manner.

The RPC integrated management system according to an embodiment of the present invention for achieving the above object is a plurality of RPCs scattered in various regions, for decision-making by collecting data on the overall production from warehousing to shipment of coarse grains. A production management system that processes information, a facility maintenance system that collects information and inspection-related information of each facility within the RPC and provides information related to facility diagnosis and maintenance, and energy demand status by monitoring the energy consumption of each facility within the RPC. An energy management system that collects and generates and transmits a control command for minimizing energy consumption of each facility based on the collected energy demand status, and remotely collects and stores RPC data sensed from each facility in the RPC and an RPC cloud system that processes the stored RPC data into information serviced through a web or app application and transmits it to a user device.

At this time, the production management system is connected to the purchase management unit that manages the purchase of coarse grains through weighing scales and hopper scales, and is connected to the purchase management unit to process grains from the purchased coarse grains and to manage yield and by-products through condensation meters. It may include a management unit, a warehouse management unit connected to the production management unit to manage trading and shipment of produced grains, and an inventory management unit connected to the warehouse management unit to manage stocks of the purchased coarse grains and produced grains. .

In addition, the production management unit may receive moisture and weight information of brown rice and moisture and weight information of white rice from the link system, and manage yield calculation information of the brown rice and white rice through this.

In addition, the facility maintenance system includes a facility maintenance unit that collects information on each facility in the RPC, inspection-related information, and repair management information, diagnoses the performance of each facility in the RPC, and provides consulting-related information for the operation of the RPC. It may include an operation management unit that provides and an ICT convergence unit that provides a service for real-time control of each facility through a web or app application for maintenance of each facility within the RPC.

In addition, when the energy management system detects that all of the facilities included in one process are stopped from among a plurality of facilities classified for each process in the RPC through a sensor, the dust collector incidental to the operation of the facilities in the one process, and The operation of the blower may also be automatically stopped, and operation of the dust collector and the blower may be resumed when the operation of at least one of the facilities in the process starts.

In addition, the RPC cloud system includes an RPC cloud center that remotely receives RPC data from the RPC, at least one IoT sensor installed in each facility of the RPC, a plurality of IoT modules that collect data obtained from the IoT sensor, A data collection and operation server for collecting, processing, and operating data input from the plurality of IoT modules, and a DB server for storing the collected and processed RPC data, and the RPC cloud center includes weather conditions for each region where the RPC is installed. A cloud DB server that collects and stores data and RPC data transmitted from the data collection and operation server through a wired/wireless communication network, government purchase policy establishment information using weather data and RPC data stored in the cloud DB server as parameters, and the RPC A production/quality management plan and an AI server that artificially processes and creates product information provided to consumers, and a web that processes the artificially processed information from the AI server into information serviced through a web or app application and transmits it to a user device /App Can include an application service providing server.

According to various embodiments of the present invention as described above, systematic quality control of produced rice and overall data from orders to production of finished products are aggregated, and maintenance of production facilities and energy management are conducted nationwide. It is possible to provide an RPC integrated management system capable of managing overall distributed RPCs in an integrated and efficient manner.

Accordingly, it is possible to optimize and use input elements such as raw materials, labor, and energy by efficiently managing facilities and quantities and establishing a production and distribution linkage system. In addition, it is possible to improve quality and provide stable services by securing trust in RPC unit facility maintenance, facility maintenance, and operation management, and ultimately improve agricultural productivity and increase farmers' actual profits.

In order to more fully understand the drawings cited in the detailed description of the present invention, a brief description of each drawing is provided.
1 is a block diagram briefly showing the configuration of a smart RPC integrated management system according to an embodiment of the present invention;
2 is a diagram for explaining a management model for solution resolution of u-RPC according to an embodiment of the present invention;
3 is a diagram showing an application screen serviced in a user device to manage u-RPC according to an embodiment of the present invention;
4 is a block diagram briefly showing the configuration of a production management system according to an embodiment of the present invention;
5 is a block diagram for explaining the production and inventory management process of grains and by-products according to an embodiment of the present invention;
6 is a block diagram for explaining information managed in a production management system according to a process according to an embodiment of the present invention;
7 is a block diagram for explaining an operation sequence of a production management program according to an embodiment of the present invention;
8 is a block diagram for explaining a process of an energy management system according to an embodiment of the present invention;
9 is a block diagram illustrating the configuration of an RPC cloud system according to an embodiment of the present invention;
10 is a block diagram briefly illustrating the configuration of a cloud DB server according to an embodiment of the present invention;
11 is a conceptual diagram of AI-based data processing of an RPC cloud center according to an embodiment of the present invention;
12 is a diagram for explaining a service outline of an RPC cloud system according to an embodiment of the present invention.

First, terms used in the present specification and claims are general terms in consideration of functions in various embodiments of the present invention. However, these terms may vary depending on the intention of a technician working in the field, legal or technical interpretation, and the emergence of new technologies. Also, some terms may be terms arbitrarily selected by the applicant. These terms may be interpreted as the meanings defined in this specification, and if there is no specific term definition, they may be interpreted based on the overall content of this specification and common technical knowledge in the art.

In addition, the same reference numerals or numerals in each drawing attached to this specification indicate parts or components that perform substantially the same function. For convenience of explanation and understanding, the same reference numerals or symbols will be used in different embodiments. That is, even if all components having the same reference numerals are shown in a plurality of drawings, the plurality of drawings do not mean one embodiment.

Also, in the present specification and claims, terms including ordinal numbers such as 'first' and 'second' may be used to distinguish between elements. These ordinal numbers are used to distinguish the same or similar components from each other, and the meaning of the term should not be limitedly interpreted due to the use of these ordinal numbers. For example, elements combined with such ordinal numbers should not be construed as limiting the use order or arrangement order by the number. If necessary, each ordinal number may be used interchangeably.

In this specification, singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, terms such as 'comprise' or 'comprise' are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other It should be understood that the presence or addition of features, numbers, steps, operations, components, parts, or combinations thereof is not precluded.

Also, in an embodiment of the present invention, when a part is said to be connected to another part, this includes not only a direct connection but also an indirect connection through another medium. In addition, the meaning that a certain part includes a certain component means that it may further include other components rather than excluding other components unless otherwise specified.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

1 is a block diagram briefly showing the configuration of a smart RPC integrated management system according to an embodiment of the present invention.

The smart RPC integrated management system 1000 includes a production management system 100, a facility maintenance system 200, an energy management system 300, and an RPC cloud system 400.

In the RPC, the production management system 100 is a component that collects data on overall production from warehousing to shipping of coarse grains and processes them into information for decision-making. The production management system 100 is a purchase management unit that manages the purchase of coarse grains through weighing scales and hopper scales, a production management unit that is connected to the purchase management unit, processes grains from the purchased coarse grains, and manages the yield and by-products through the feed system, It may include a warehouse management unit that is connected to the production management unit and manages trading and shipment of produced grains, and an inventory management unit that is connected to the warehouse management unit and manages stocks of purchased coarse grains and produced grains.

At this time, the production management unit may receive moisture and weight information of brown rice and moisture and weight information of white rice from the lead meter, and manage yield calculation information of brown rice and white rice through this.

The facility maintenance system 200 is a configuration that provides facility diagnosis and maintenance-related information by collecting information and inspection-related information of each facility in the RPC.

Facility maintenance system 200 includes a facility maintenance department that collects information on equipment in the RPC cabinet, inspection-related information, and repair management information, an operation management unit that diagnoses the performance of each facility in the RPC and provides consulting-related information for RPC operation, It may include an ICT convergence unit that provides a service for real-time control of each facility through a web or app application for maintenance of each facility within the RPC.

The energy management system 300 monitors the energy consumption of each facility in the RPC, collects the energy demand status, and generates and transmits a control command to minimize energy consumption of each facility based on the collected energy demand status. .

When the energy management system 300 detects that all of the facilities included in one process are stopped from among a plurality of facilities classified for each process in the RPC through a sensor, the dust collector and blower incidental to the operation of the facilities in one process Operation is also automatically stopped, and when the operation of at least one of the facilities in a process starts, the operation of the dust collector and the blower can be resumed.

The RPC cloud system 400 remotely collects and stores RPC data sensed from each facility in the RPC, processes the stored RPC data into information serviced through a web or app application, and transmits it to a user device.

Specifically, the RPC cloud system 400 includes an RPC cloud center that remotely receives RPC data from RPC, at least one IoT sensor installed in each facility of the RPC, a plurality of IoT modules that collect data obtained from the IoT sensor, It may include a data collection and operation server for collecting, processing and operating data input from a plurality of IoT modules, and a DB server for storing the collected and processed RPC data.

Here, the RPC cloud center is a cloud DB server that collects and stores weather data by region where RPC is installed and RPC data transmitted from a data collection and operation server through a wired/wireless communication network, and weather data and RPC data stored in the cloud DB server as parameters. An AI server that artificially processes and creates government purchase policy establishment information, RPC production/quality control measures, and product information provided to consumers, and artificially processed information from the AI server is processed into information serviced through web or app applications. and a web/app application service providing server for transmitting to the user device.

Hereinafter, each configuration and operation of the smart RPC integrated management system 1000 will be described in detail with reference to the drawings.

2 is a diagram for explaining a management model for solution resolution of u-RPC according to an embodiment of the present invention.

The existing RPC, which was managed in an analog method by inputting simple numbers, suffered from poor contract cultivation, inability to manage yield, quality, and loss in real time, lack of a systematic recall system, insufficient tracking of rice production history, limitations in establishing a quality management system, etc. There were many problems.

Therefore, the smart RPC integrated management system (1000) of the present invention is digital in all stages, from rice production planning to cultivation management, post-harvest import, purchase settlement, order management, raw material inventory management, brand grain shipment, history management, etc. Ubiquitous RPC (u-RPC) grafted with management can be applied.

u-RPC is a field mapping that supports electronic mapping and farmland registration of contract cultivation, mobile/web-based production and cultivation information monitoring system, DSC facility and quantity management system (MMI, PCL), raw material, order, Integrated production, yield, loss, and history management system, history management system that generates LOT numbers and manages history, mobile-based consumer history and quality confirmation system, remote comprehensive management system of RPC, and online synthesis of taste, dignity, and ingredients A quality measurement system is provided.

Specifically, u-RPC is a production/receipt management model u-TIMSP (Trace-ability & Intake Management System of Paddy), a processing management model E-YICS (Extended-Yield & Inventory Management System), and a quality management model RTQMS (Real-Ability & Intake Management System). Time Quality Management System) can be established.

u-TIMSP manages cultivation contract, cultivation and evaluation in the field, and manages import/purchase and drying/storage in DSC/RPC. Specifically, u-TIMSP is information related to seedling/transplanting/fertilization. It manages information such as variety, production area, producer, soil management, seedling management, weed control, pest control, fertilization management, harvest date, and control/harvest/shipment information. As information related to, it is possible to judge maturity and harvest time.

In addition, u-TIMSP is information related to delivery in DSC/RPC, and manages information such as delivery date, delivery amount, drying date, dryer type, storage date, and storage facility type, and as information related to drying/storage, moisture content, Information such as selection index, reproduction rate, protein content, sizing rate, variety purity, drying temperature, moisture content, copper content rate, storage temperature, moisture content, fatty acid value, germination rate, etc. can be managed.

u-TIMSP can establish a DB of production and cultivation history information and a preliminary quality management system using mobile/web/RF cards, and provide field mapping, site evaluation and farming guidance services using GIS/LBS. there is.

E-YICS performs order management, warehousing management, inventory management, by-product management, history management, yield management, release management and business management.

E-YICS covers the processing and packaging/shipping procedures of brown rice and white rice, processing date, processing LOT number, type of processing facility, packaging date, packaging size, grade, type of packaging paper, packaging weight, shipping location, shelf life period. (Expiration date) can be comprehensively managed.

E-YICS is an automatic yield and inventory management system using MMI/PLC, DSC remote management system using TCP/IP Ethernet communication, traceability system using Fuzzy/QR/Bar code, and raw material quality (germination rate, germination rate, Dignity, ingredients) prediction system can be established, and as shown in FIG. 3, a Mobile/Web-based history and inventory management DB/APP can be provided to the user. As shown in the screen shown in FIG. 3, the application provided to the user can provide a menu 30 for overall inquiry of product release management, product release history, product/by-product inventory management, and packaging/box provision management status. there is.

RTQMS performs quality, whiteness, CBB INDEX, water content management, consumer product history, and quality information inquiry. RTQMS can provide product history/quality information to consumers through online quality measuring devices associated with tags attached to individual products. For example, information on grain temperature, moisture content, whiteness, CBB index, hail and protein content, appearance quality, complete rice ratio, and the like can be provided to consumers. In addition, product history information, quality information, self-life (freshness), and distribution temperature information may be provided.

In addition, RTQMS can provide a mobile/web-based consumer history inquiry service by establishing a quality monitoring system during distribution, a rating measurement system (grade, whiteness, CBB index, etc.) using NIR/Vision, and an order/inventory inquiry system for managers. there is.

Accordingly, a production/distribution linkage system between RPC and the production organization is established, and real-time management of yield, quality, and loss through network construction becomes possible. In addition, since real-time integrated management of raw materials, orders, production, yield, and loss is possible, and a system for tracking rice production history in bulk can be established, efficient management of imports and efficient management of facilities and quantities can be achieved. there is.

4 is a block diagram briefly showing the configuration of a production management system according to an embodiment of the present invention.

The production management system 100 of the present invention is composed of a purchase management unit 110, a production management unit 120, a warehouse management unit 130, and an inventory management unit 140.

The purchase management unit 110 is a component that manages the purchase status of coarse grains through weighing scales and hopper scales. Specifically, the acquisition management unit 110 manages a plurality of weighbridges and hopper scales based on ID information read from barcodes attached to the weighbridges and hopper scales through a barcode reader.

When the coarse grains are received, the purchase management unit 110 registers the current status of storage and manages information on current status of purchase. The import purchase status information may include purchase-related information such as purchase contract management contracted with the farmhouse, purchased coarse grain quantity, purchase shortfall, purchase settlement cost, variety management, variety inventory management, and farmhouse management. Through this, you can inquire about the current status of import purchases.

In addition, the purchase management unit 110 may receive truck weight information, tolerance weight information, raw material weight information, and storage date from the weighbridge, and input coarse grain weight information, moisture information, variety information, and customer information from the hopper scale. can receive

The production management unit 120 is connected to the purchase management unit 110 to process grains from the purchased coarse grains and to manage yield and by-products through a condensation system.

The production management unit 120 may receive moisture and weight information of brown rice and moisture and weight information of white rice from the link system, and manage yield calculation information of brown rice and white rice through the input.

The grains processed through the condensation system go through the inventory management, packaging and shipping process, and the remaining by-products go through the by-product inventory management and shipping process. Here, by-products may include shrimmi, seolmi, and halibut.

The warehouse management unit 130 is connected to the production management unit 120 and is configured to manage the transaction and shipment of the produced grains.

The release management unit 130 may generate a transaction statement including return information according to a release instruction input through the manager device. The transaction statement generated here can be used as sales status information for business management. Warehouse management unit 130 may also manage the shipment of by-products as well as the shipment of grains produced.

The shipping management unit 130 may manage information about the shipping destination, shipment amount, shipping amount, shipping date, monthly storage fee and unloading fee of the produced grains, and provide inquiry and output services for monthly storage fee and unloading fee.

The inventory management unit 140 is connected to the warehouse management unit 130 to manage stocks of purchased coarse grains and produced whole grains. The inventory management unit 140 may manage stock status for each condition and base date inventory at the point in time when grain production is completed, and may manage by-product inventory status at the point in time when by-products are produced.

Base date inventory and by-product inventory may be automatically adjusted according to the transaction statement and by-product shipment status generated by the shipping management unit 130, and raw material inventory may be automatically adjusted according to the warehousing status and carry-in purchase status information registered in the purchase management unit 110. there is.

On the other hand, the intelligent grain production management system 100 according to an embodiment of the present invention may further include a packaging management unit 150. The packaging management unit 150 may receive input of the number of packages, the number of loads, and the number of loads of grains that have been produced from the packaging machine, and manage packaging status information.

In addition, the packaging management unit 150 may manage the state of stocking and shipping of packaging materials by item and the stock state therefrom.

Figure 5 is a block diagram for explaining the production and inventory management process of grains and by-products according to an embodiment of the present invention.

When the processing instruction is registered through the manager device, the coarse grain warehousing HMI (52) controls the warehousing (53) processing of the coarse grain according to the registered processing instruction, and the warehousing coarse grain is produced as grain and by-products through the grain processing process ( 55) can be.

In the processing instructions, the total amount of coarse grains, the total amount of whole grains, the yield, the quota by type of by-products, and the amount of production by type of by-products may be set as processing conditions.

The packaging management unit HMI 54 may perform an operation of processing the produced grains into the packaging material 56 . Packing materials are stored in the packaging management unit 150, shipped, and inventory status is managed.

Some of the produced grains and by-products go through grain inventory management (57) and by-product inventory management (58), and the grains and by-products can be transported (59) to the shipping location according to the shipment amount according to the processing instruction.

6 is a block diagram for explaining information managed in a production management system according to a process according to an embodiment of the present invention.

As shown in FIG. 6, the manager PC 160 includes a vehicle counter 111, a raw material inlet 112, a raw material input condenser 121, a brown rice condenser 122, a by-product management unit 123, and a polished rice condenser 124 and the packaging management unit 150 can be connected sequentially to transmit commands or data. 121, the brown rice condensation system 122, the by-product management unit 123, the white rice condensation system 124, and the packaging management unit 150 may receive and store information managed.

First, the manager PC 160 receives information and processing conditions such as processing instructions, product name/variety information, yield, transportation date, quality level, and customer information, and among them, control information corresponding to the vehicle weighing stand 111 is transmitted to the vehicle weighing stand. (111). According to the control information received from the manager PC 160, the vehicle weighing stand 111 automatically obtains and manages information about the target vehicle number, gross weight, empty vehicle weight, loading weight, and warehousing date of the vehicle weighing stand 111. can

When coarse grains are brought in to the raw material input flow meter 121 through the raw material inlet 112, the raw material input flow meter 121 automatically obtains information on the current weight, cumulative weight, measurement frequency, and measurement date of the raw material coarse grains. · Can be managed. The brown rice condensation meter 122 can also automatically acquire and manage information on the current weight of first-processed brown rice, the cumulative weight of brown rice, the number of times of measurement of brown rice, and the date of measurement.

The by-products produced through the brown rice condensation system 122 are managed by receiving information about the type of by-product and the date on which the type of by-product was input from the by-product management unit 123.

The glutinous rice flow meter 124 can automatically obtain and manage information on the current weight of the secondarily processed white rice, the cumulative weight of the white rice, the number of times of measuring the white rice, and the measurement date.

The reproduction rate can be calculated from the raw material input condensation system 121 and the brown rice condensation system 122, and the polishing rate can be calculated from the brown rice condensation system 122 and the polished rice condensation system 124. Information on the milling yield may be generated through the calculated reproduction ratio and polishing ratio.

The packaging management unit 150 may automatically store information on the number of packages, the number of loadings, the number of loadings, and a work date, or may be manually input and stored.

7 is a block diagram for explaining an operation sequence of a production management program according to an embodiment of the present invention.

First, the manager PC 160 is registered with reference information 71. The reference information 71 may include information about product names, types of by-products, names and types of packaging materials, and the like. Among them, information on the product name and type of by-product is registered in the processing instruction sheet (72), and information on the name and type of packaging material is transmitted to the packaging management unit 150 and can be recorded as information for packaging management (46). there is.

The packaging management unit 150 may manage warehousing, shipping, and inventory of packaging materials.

When processing instructions are registered, coarse grains and grains are added, and grains can be processed into products and by-products. By-products can be managed by the by-products HMI 78.

When the grain production 77 is completed, the packaging management unit 150 controls the manual packaging machine or the automatic packaging machine to register packing materials, and through this grain processing process, the number of grains increases, the amount of packaging materials decreases, Inventory management 74 may update the current status through inventory-related information indicating that by-products have increased.

Similarly, when the warehousing of coarse grains is registered, the current status of the stock management 74 may be updated through inventory-related information indicating that coarse grains have increased. In the warehousing registration process, warehousing schedule management, warehousing schedule inquiry, and warehousing completion inquiry may be performed. Such warehousing status can be managed by the warehousing department HMI.

Operations such as registration/deletion of transportation instructions, inquiry/output of transportation instructions, and the like can be performed through the transportation management 75 for coarse grains and grains shipped out of stock.

In addition, it is possible to perform daily output 79 such as grain storage ledger and coarse grain storage ledger.

The manager can manage basic information such as common codes, grain codes, customer information, warehouse information, and storage charges through the production management program.

The common code is information on the grain type, bag, area, etc., and is a code for registering and setting the grain type, bag, and area (paper feed) used for warehouse management.

The grain code is a code that indicates loading and unloading charges (loading/unloading charges, input/output charges) for each type of grain, bag, and set/whole grain loaded in the warehouse.

Warehouse information includes information on the name and person in charge of the currently managed warehouse, and storage fee management information shows management information on storage fees by region feed, grain grade, and warehouse classification (normal/low temperature) based on the registered grain code. .

In addition, the manager can manage warehousing/shipping management and inventory transfer (warehouse, grain code, region, and yearly warehousing) status. At this time, when registering the amount of grain according to the grade of grain for each criterion item, the registered loading and unloading fee at the time of registration may be stored together.

Inventory transfer can be predicted as 0 unloading charges, and 0 unloading charges can be registered.

In addition, the manager can compare and adjust the current inventory inquiry and physical inventory based on the warehouse standard. Here, the difference from inventory transfer in warehousing and warehousing management is that if inventory transfer is inventory transfer from warehouse to warehouse, inventory management may refer to a document and actual quantity adjustment function of current warehouse inventory.

In addition, the manager can perform inquiry/output of the record through the manager PC 160. First, by creating a grain storage and storage confirmation form, it is possible to query and output monthly storage fee information calculated based on the registered storage fee unit price by calculating the warehouse storage date after searching for the input / output information based on the selected month.

In addition, after searching for input/output information for each grain based on the selected month, the warehouse storage date can be calculated and monthly storage fee information calculated based on the registered storage fee unit price can be inquired.

In addition, through the grain operation confirmation, it is possible to inquire/output the unit price of loading and unloading costs for each grain based on the selected month, and after checking the input/output information based on the selected month, the amount of grain input/output is calculated and registered. You can search or print the information on the loading charge calculated based on the set loading charge unit price.

8 is a block diagram for explaining a process of an energy management system according to an embodiment of the present invention.

The energy management system 300 of the present invention collects and analyzes data from individual facilities such as a color sorter, a shipbuilding machine, a rice mill, a rice milling machine, a stone crusher, an elevator, a conveyor belt, and a motor (S810). Thereafter, the analyzed data is transmitted to the driving management/driving support system (S820), and through this, it is possible to control the on/off of each facility through the PLC (S830).

For example, in the dry storage unit electricity saving process control, in the case of the input port of the dry storage unit, it is controlled to operate after a certain period of time has elapsed after motion detection through a sensor, and when the input unit of the dry storage unit is operated, the vortex hood, elevator and The lower chain conveyor can be operated. When a certain time elapses after the sensor detection is released, the operation of the vortex hood, the elevator, and the lower chain conveyor may be stopped.

In the case of the blower of the dust collection part, the dust collector for the inlet, transport facility, shipbuilding machine, and wind power separator automatically stops and waits after a certain period of time when all the machines in the corresponding process stop, and restarts automatically when even one machine in the corresponding process is started. can be set so that In addition, by installing a pressure gauge in the dryer dust collector, it can be operated (air pulsing, dust removal) when the set pressure or higher is reached, and automatically stopped when it goes below the set pressure.

In the provincial government's electricity-saving process control, in the case of a dust collector blower, the brown rice dust collector automatically stops and waits after a certain period of time when all machines in the brown rice production process are stopped, and can be automatically restarted when any machine in the process is driven. .

In the case of the stone crusher and the rice husk tuyere dust collector, if both the stone crusher and the rice husk tuyere are stopped, they are automatically stopped after a certain period of time and can be automatically restarted when at least one machine in the process is operated.

In the case of the polished rice dust collector, when all the machines in the rice production process are stopped, it automatically stops and waits after a certain period of time, and can be automatically restarted when even one machine in the process is operated.

In the case of the rice mill and dust collector, when both the rice mill and the dust collector are stopped, they are automatically stopped after a certain period of time and can be automatically restarted when any machine in the process is operated.

In the case of a centrifugal filter dust collector, a pressure gauge is installed in the machine to operate (air pulsing, exhaustion) when the set pressure or higher is reached, and can be automatically stopped when it goes below the set pressure.

9 is a block diagram illustrating the configuration of an RPC cloud system according to an embodiment of the present invention. The RPC cloud system 400 includes a plurality of rice processing facilities 1-n scattered in various regions, an RPC cloud center 410 remotely receiving RPC data from the rice processing facilities 1 to n, and a plurality of rice grains. A wired/wireless communication network 420 configured to allow the general processing facilities 1 to n and the RPC cloud center 410 to communicate with each other is included.

Rice processing facilities (1 to n) are at least one IoT-based sensor installed in each facility, and a plurality of IoT modules (11 to 16 ), a data collection and operation server 17 that collects, processes and operates data input from a plurality of IoT modules 11 to 16, and a DB server 18 in which collected and processed data is stored.

The RPC cloud center 410 collects weather information 411 data for each region where the rice processing facilities 1 to n are installed and various data transmitted from each rice processing facility 1 to n through a wired and wireless communication network 420. The data collection server 413 for storing, weather information for each region 411 and the cloud DB server 412 and cloud DB server 412 for managing/storing RPC data transmitted from each of the rice processing plants 1 to n. The AI server 414 and AI server 414 automatically process and generate the government's purchase policy establishment information using the stored data as parameters, production/quality control measures of the rice processing plant, and product information provided to consumers artificially. It includes a web/app application service providing server that processes the processed information into information serviced through a web or app application and transmits it to the user device 500.

The data collection and operation server 17, the data collection server 413, and the web/app application service providing server 415 include a communication module connected to the wired/wireless communication network 420.

The facilities of the rice processing plant (1~n) include ⅰ) dry storage facilities such as silos, wind power separators, shipbuilding machines, hopper scales, grain dryers, dust collection facilities, hoppers, oil gauges, and storage tanks, ii) raw material stone crushers, Rice processing facilities such as brown rice, rice hull tuyere, brown rice separator, rice mill, milling machine, color/foreign material sorter, etc., iii) rice quality judgment system, iv) rice weighing machine, automatic vinyl packing machine, high-speed packing machine, vinyl adhesive machine, etc. Examples include packaging facilities, v) dust collection facilities such as centrifugal filter dust collectors, energy-saving integrated dust collectors, cyclones, and vortex hoods, and ⅵ) by-product treatment machines such as rice hull expansion facilities, carbonized rice hull production facilities, and rice bran pellet forming facilities. there is.

As illustrated in FIG. 9, the plurality of IoT modules 11 to 16 include a hopper scale, a fuel flow meter, a rice mill / milling machine, a color / foreign matter sorter, a quality judgment system, and a weighing and packaging facility, respectively, but in addition to the above facilities It may be implemented as all or part of or further include them.

These multiple IoT modules (11 to 16) collect, store, and analyze data from each process facility in the rice processing plant (1 to n), monitor it in real time, and track facility control, yield and inventory production management, and cultivation and processing history. configured to be able to

IoT sensors installed in the above facilities include carbon dioxide (CO ₂ ) sensor, moisture sensor, temperature sensor, humidity sensor, level gauge, air pressure sensor, differential pressure sensor, weight sensor, dust sensor, shape sensor, CCD, moisture content sensor, A speed sensor, a magnetic sensor, a heat sensor, an infrared (NIR) sensor, a distance measurement sensor, an ultrasonic sensor, an odor sensor, a limit sensor, and the like may be exemplified, and may include at least one of these.

IoT sensors and IoT modules 11 to 16 may be connected through wired or wireless communication means such as Ethernet, WiFi, ZIGBEE, Bluetooth, Beacon, and RFID (NFC RFID, UHF RFID, etc.).

The IoT modules 11 to 16 may collect data obtained from IoT sensors provided in each facility of the rice comprehensive processing plants 1 to n, and transmit and process data to the data collection and operation server 17. The data collection and operation server 17 may store the collected data in the DB server 18, perform pre-processing on the collected data, and transmit the collected data to the RPC cloud center 410 through the wired/wireless communication network 420.

Since the collected data may contain missing values due to errors that occurred during the data collection process, the data collection and operation server 17 performs preprocessing including data cleaning and filtering to It is desirable to ensure that there is no distortion in the analysis results.

The data collection and operation server 17 may transmit and process preprocessed RPC data to the RPC cloud center 410 .

The cloud DB server 412 of the RPC cloud center 410 collects and transmits data from the operation server 17 through the wired/wireless communication network 420 and weather information 411 for each region where a plurality of rice processing plants 1 to n are installed. RPC data can be collected and stored.

At this time, the cloud DB server 412 may include information such as the location, facilities, and amount of processed rice processing facilities 1 to n scattered in various regions. Specifically, as shown in FIG. 10, the RPC facility maintenance DB includes facility status by RPC, facility information, repair history, schedule management, performance management, DB construction and analysis information by type, and RPC operation DB includes RPC-specific operation Diagnosis (line balance, process analysis, performance, quality, environmental characteristics) information, optimal operating condition analysis information by type/facility, etc. are included, and the weather information DB can include weather information of the area where RPC is installed. In the grower DB, all production steps from rice cultivation to harvest, such as grower (farmhouse) information, field information, cultivation history (variety, work history - sowing, transplanting, fertilization, harvesting), and import to the Rice Complex Processing Center (RPC) after harvest All history information up to that point may be included. The manager DB may include information such as remote facility control, yield, inventory management, real-time quality control, and the like, and the RPC operator DB may include operator information of rice processing plants 1 to n. The service team DB is dispatched to the rice processing plant (1~n) and manages the name and contact information of A/S technicians belonging to the management system in charge of repair/replacement of equipment, regular inspection schedule, preparation/submission of inspection report, and emergency A/S Receipt/response information is included, and consumer DB uses QR code to track product history - cultivation information (grower - farmhouse, year of production), processing information (processor - Nonghyup, milling date), quality information (grade, ingredient) Inquiry information, etc. may be included.

11 is a conceptual diagram of AI-based data processing of an RPC cloud center according to an embodiment of the present invention.

The AI server 414 receives weather data stored in the cloud DB server 412 and SMART RPC (1), u-RPC (2), private RPC (3), Nonghyup RPC (4), and government provincial government RPC (5). Parameters for generating specific information to be provided to the information consumer may be extracted from the received RPC data, and the specific information may be automatically generated by artificially processing the specific information based on the extracted parameters.

Here, the information demander may include an RPC operator 41, an RPC manager 42, a related government agency 43, a related research institute 44, and a consumer 45.

The RPC data received by the AI server 414 is the basis of big data for data analysis, and can act to enable effective repetitive learning by combining with machine learning, especially deep learning.

Parameters extracted from the AI server 414 may serve as training data for the AI server 414 to find a labeled result by supervised learning by classification or regression. Based on the parameters, the AI server 414 is capable of predicting rice production this fall, generating information for determining an appropriate purchase price, or information for establishing an active product shipment plan.

Meanwhile, the web/app application service providing server 415 may process the information artificially processed by the AI server 414 into comprehensive rice information serviced through a web or app application and transmit it to the user device 500.

In this case, the user device 500 may be implemented as a portable terminal such as a smart phone, a laptop computer, a tablet PC, and the like, including a personal computer (PC).

The web/app application service providing server 415 may provide a platform through which the user devices 500 of the information consumers 41 to 45 can check necessary comprehensive rice information through a website or an app.

12 is a diagram for explaining a service outline of an RPC cloud system according to an embodiment of the present invention.

As shown in FIG. 12, the information related to the import of rice collected from the IoT modules 11 and 12 specifically includes purchase quantity information by region, purchase quantity information by variety, purchase quantity information by period, internal and external quality information, yield information, etc. RPC data analyzed by the data collection and operation server 17 may include yield and quality analysis information by region, yield and quality analysis information by variety, prediction information on optimal harvest time, crop condition analysis information by year, and rice by region. Production strategy prediction information and information on identifying optimal cultivars for each region may be included.

In addition, the production and processing-related information collected from the IoT module (13 to 16) is specifically information on the input unit status information, drying unit status information, silo storage unit status information, brown rice production status information, polished rice production status information, and packaging unit It may include shipment status information and brown/glutinous rice quality information, etc., and the RPC data analyzed by the data collection and operation server 17 from this is facility operation rate/energy consumption analysis information, oil consumption analysis information during drying, and appropriate drying cost It can include calculation information, brown rice yield analysis information, processing status analysis information by condition, shipping and sales status analysis information by condition, government grain processing price analysis information, etc.

Meanwhile, information processed from the RPC cloud center 410 may be provided as comprehensive rice information to government agencies 43, grain processing distributors 41 and 42, and consumers 45 through web or applications.

The government agency 43 predicts rice production through the comprehensive rice information received from the RPC cloud center 410, analyzes crop conditions by period, establishes an appropriate government purchase quantity plan, derives an appropriate purchase price, improves government purchase policy, and appropriate government Policies to contribute to grain toll processing fees, cultivation guidance and grain policy improvement, safe food supply, high-quality rice export expansion, and public health promotion can be established.

Grain processing distributors (41, 42) such as Nonghyup and Rice Complex Processing Center improve rice cultivation history management through the rice comprehensive information received from the RPC Cloud Center (20), manage rice production history, and purchase raw grains by condition It can make it possible to establish strategies, establish advanced quality management plans, establish active product shipment plans, establish customer-tailored marketing strategies, improve contract cultivation farming guidance, produce high-quality rice, and easily track causes in case of customer claims.

The consumer 45 can check product information through the comprehensive rice information received from the RPC cloud center 410 or select and purchase safe food. Accordingly, the consumption of high-quality rice by consumers can ultimately be increased.

Meanwhile, although preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible by those skilled in the art, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

1000: Smart RPC integrated management system 100: Production management system
200: facility maintenance system 300: energy management system
400: RPC cloud system

Claims (6)

In the smart RPC integrated management system for integrated management of the operation of multiple RPCs scattered in various regions,
In the RPC, a production management system that collects data on overall production from warehousing to shipping of coarse grains and processes them into information for decision-making;
a facility maintenance system that collects information and inspection-related information of each facility in the RPC and provides facility diagnosis and maintenance-related information;
An energy management system for monitoring the energy consumption of each facility in the RPC, collecting energy demand status, and generating and transmitting a control command for minimizing energy consumption of each facility based on the collected energy demand status; and
An RPC cloud system that remotely collects and stores RPC data sensed from each facility in the RPC, processes the stored RPC data into information serviced through a web or app application, and transmits it to a user device,
The production management system,
A purchase management unit that manages the purchase of coarse grains through weighbridges and hopper scales;
a production management unit that is connected to the purchase management unit, processes grains from the purchased coarse grains, and manages yield and by-products through a condensation system;
A release management unit that is connected to the production management unit and manages the transaction and shipment of the produced grains;
an inventory management unit that is connected to the warehouse management unit and manages stocks of the purchased coarse grains and produced grains; and
It includes; a packaging management unit that manages packaging status information by receiving inputs of the number of packages, the number of loads, and the number of loads of grains produced from the packaging machine;
The purchase management department,
The weight information of the truck and the weight information of the empty vehicle are provided from the weighbridge,
The delivery management department,
Manages information on monthly storage and unloading costs for grains produced,
The packaging management department,
Manages the status of stocking and shipping of packaging materials by item, and inventory status.
The energy management system,
When the operation of the input port of the dry storage unit is detected through the sensor, the vortex hood, elevator and lower chain conveyor of the input port of the dry storage unit are operated. Stop the operation of the lower chain conveyor,
The energy management system,
Through the sensor, if the pressure of the centrifugal filter is higher than the set pressure, the centrifugal filter is operated, and if the pressure of the centrifugal filter is lower than the set pressure, the centrifugal filter is stopped,
The RPC cloud system,
an RPC cloud center remotely receiving RPC data from the RPC;
At least one IoT sensor installed in each facility of the RPC;
A plurality of IoT modules for collecting data obtained from the IoT sensor;
A data collection and operation server for collecting, processing, and operating data input from the plurality of IoT modules; and
Including; DB server in which the collected and processed RPC data is stored,
The RPC cloud center,
a cloud DB server for collecting and storing weather data for each region where the RPC is installed and RPC data transmitted from the data collection and operation server through a wired/wireless communication network;
An AI server that artificially processes and generates government purchase policy establishment information using weather data and RPC data stored in the cloud DB server as parameters, production/quality management plans of the RPC, and product information provided to consumers; and
A web / app application service providing server that processes the artificially processed information in the AI server into information serviced through a web or app application and transmits it to a user device;
The AI server,
Parameters for generating specific information to be provided to information consumers are extracted from meteorological data stored in the cloud DB server and RPC data received from private RPCs, Nonghyup RPCs, and government RPCs, and specific information is generated based on the extracted parameters. It is created by artificial processing,
The information consumer is a smart RPC integrated management system including RPC operators, RPC managers, related government agencies, related research institutes, and consumers. delete According to claim 1,
The production management department,
Smart RPC integrated management system, characterized in that for receiving the moisture and weight information of brown rice and the moisture and weight information of white rice from the condensation meter, and managing the yield calculation information of the brown rice and white rice through this. According to claim 1,
The facility maintenance system,
a facility maintenance unit that collects information on each facility in the RPC, inspection-related information, and repair management information;
an operation management unit diagnosing the performance of each facility in the RPC and providing information related to consulting for the operation of the RPC; and
Smart RPC integrated management system comprising: an ICT convergence unit providing a service for real-time control of each facility through a web or app application for maintenance of each facility in the RPC. According to claim 1,
The energy management system,
When the sensor detects that all of the facilities included in one process among the plurality of facilities classified for each process in the RPC are stopped, the operation of the dust collector and the blower incidental to the operation of the facilities in the one process are also automatically stopped. And, when the operation of at least one of the facilities in the process starts, the operation of the dust collector and the blower is resumed. delete

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