WO2008023654A1

WO2008023654A1 - Production system creating system and production system creating method

Info

Publication number: WO2008023654A1
Application number: PCT/JP2007/066090
Authority: WO
Inventors: Mikio Yotsukura; Hiroshi Yokoyama
Original assignee: Class Technology Co., Ltd.
Priority date: 2006-08-25
Filing date: 2007-08-20
Publication date: 2008-02-28
Also published as: JP2008052534A

Abstract

[PROBLEMS] To provide a production management system for creating a production system of various types of products by freely combining various different types of production elements from the highest concept to the lowest one. [MEANS FOR SOLVING PROBLEMS] In a production system creating system (10), various types of binary relations needed to create a production system at an arbitrary point are extracted from a relation database (18) while referring to the binary relation production system creation time point and the production system separation time point, various types of production elements corresponding to first and second production elements forming the extracted binary relations are extracted from a classification-by-type database (17), the binary relations extracted from the relation database (18) are integrated, the production elements extracted from the classification-by-type database (17) are connected in series from the highest to lowest concept according to the integrated binary relations, and thus a production system of various types of products at an arbitrary time point is created.

Description

Specification

Production system creation system and production system creation method

Technical field

The present invention relates to a production system creation system and a production system creation method for creating a production system for various articles from a combination of production elements that branch from a superordinate concept to a subordinate concept.

Background art

[0002] There is a production management system that creates a configuration table of a mechanical device by expanding a plurality of various parts constituting the mechanical device into a tree structure (see Patent Document 1). In this system, the data number of the machine is 000, the first part number of the first part connected to the nearest lower part is set to 100, 200, 300 ..., and the first part number is connected to the nearest lower part of 100. The second part number of the second part is 110, 120, 130... And the third part number of the third part that is immediately below the second part number 110 is 111, 112, 113. The second part numbers connected to the first part number 200 are 210, 220, 230..., And the second part numbers connected to the first part number 300 are 310, 320, 330. The third part numbers connected to the second part number 210 are 211, 212, and 213, and the third part number is 311, 312, and 313. This system forms a mechanical device by connecting the first part number to the machine data number, the second part number to the first part number, and the third part number to the second part number. A plurality of parts can be developed as a tree structure Patent Document 1: Japanese Patent Laid-Open No. 2004-62526

Disclosure of the invention

Problems to be solved by the invention

[0003] In the production management system disclosed in the above publication, the component parts of a mechanical device are managed by part numbers, and the first to third parts specified by the part numbers are arranged in numerical order. A specific second part is connected immediately below the second part, and a specific third part is connected immediately below the second part. Therefore, in this system, the first to third parts arranged in a tree shape are uniquely defined, and different types of parts can be placed under the first part and the second part. Not only cannot different types of parts be placed below the parts, but also production elements other than parts cannot be incorporated, and a composition table that freely combines different types of production elements cannot be created. ,.

[0004] In addition, this system does not have data on the time when the first to third parts composition table is formed or the time when the first to third parts are removed from the composition table, so the current composition table is created. The ability to do It is not possible to create a composition table at any point in time.

[0005] An object of the present invention is a production system creation system and a production system capable of creating a production system for various articles by freely combining a plurality of different types of production elements from a superordinate concept to a subordinate concept. It is to provide a creation method. Another object of the present invention is to provide a production system creation system and a production system creation method capable of creating a production system for various articles not only at the present time but also at an arbitrary point in time going back to the past.

Means for solving the problem

[0006] The premise of the present invention for solving the above-described problem is a production system creation system that creates a production system for goods from a combination of production elements that branch from a superordinate concept to a subordinate concept.

[0007] The feature of the present invention based on the premise is that production elements are linked by an upper and lower binary relationship between an arbitrary first production element and a second production element that is immediately below it, and a production system creation system Is a type database that stores multiple production elements of different types and the time when the production system of these production elements is formed and the time of departure from the production system, and a plurality of binary relationships of different types and the production of these binary relationships A production body that has a relational database that stores the time of system formation and the time of departure from the production system, and uses these production factors to generate a production system at any point in time from the past to the present corresponding to various products. The system generation means is to be executed. This production system generation means refers to the binary system related production system formation time and the departure time from the production system, while referring to the various multiple binary relations necessary to create the production system at any time from the relational database. In addition to extraction, a variety of productions corresponding to the first and second production factors that form the extracted binary relations. The production elements are extracted from the classification database, the two relations extracted from the relational database are integrated, and the production elements extracted from the classification database are serialized from the superordinate concept to the subordinate concepts according to the integrated binary relation. By connecting them, a production system for various goods at an arbitrary point in time is generated.

As an example of the present invention, in the production system creation system, the type database is divided into a plurality of first to nth type databases, and the first to nth type numbers for specifying the types of production elements are the production elements. The production factors are stored in the 1st to nth type database based on the 1st to nth type numbers, and the type numbers of the 1st and 2nd production elements forming the binary relationship are related. The production system generation means, which is stored in the database, selects the first and second production elements corresponding to the first and second production elements that form the extracted binary relations based on the first to nth type numbers. Extracting from the nth type database and referring to the 1st to nth type numbers of the first and second production elements in the binary relation extracted from the relational database, the production factors that form these binary relations Production of the same type number Integrate multiple binary relationships extracted by combining elements.

[0009] As another example of the present invention, in the production system creation system, the 1st to n-th department numbers for classifying the production elements by department are individually set to the production elements, and the production system creation means Of the generated production systems, the department-specific production system output means that outputs the production system for each department that is formed only from the necessary production elements for each department is executed. Refer to the divisional numbers of the various production elements corresponding to the first and second production elements that form the extracted binary relationship, and create a production system that is made up of only the production elements corresponding to the same divisional number. Output.

[0010] As another example of the present invention, in the production system creation system, each production element stored in the type database can be modified retroactively to the present or the past, and the first production element and the first production element stored in the relational database are stored. (2) At least one of the production factors can be modified retroactively to the present or the past, and the production system generation means can change each production factor stored in the type database and the first and second production factors stored in the relational database. Is modified, it uses the new modified production factor and re-integrates the binary relationship using the new binary relationship formed from the modified first and second production factors. Various items according to the integrated binary relationship The production system corresponding to the product is generated again.

[0011] As another example of the present invention, in the production system creation system, it is possible to retrospectively change the production system production system formation time and the departure time from the production system, and the binary system production system formation time point. And the point of departure from the production system can be changed retrospectively.

[0012] A second aspect of the present invention for solving the above problem is that a plurality of production elements of different types are stored, and a type database storing the production system formation time and the departure time from the production system of the production elements, and Stores various binary relations between production elements linked by upper and lower binary relations between an arbitrary first production element and a second production element that is immediately below it, and a production system of these binary relations. Necessary to create a production system at any point in time, referring to the time of formation of the binary system and the time of departure from the production system, including a relational database that stores the time of formation and departure from the production system. Various binary relations are extracted from the relational database, and various production elements corresponding to the first and second production elements forming the extracted binary relations are classified into the type data. Extracting from the database, integrating those binary relationships extracted from the relational database, and connecting those production elements extracted from the type database in a series from the higher concept to the lower concept according to the integrated binary relationship This is a production system creation method that generates a production system for various articles at an arbitrary point in time, and stores and outputs the generated production system.

[0013] As an example of the production system creation method, the type database is divided into a plurality of first to n-th type databases, and the first to _n-th type numbers for specifying the types of production elements are used as the production elements. These are set individually, and the production factors are stored in the 1st to nth type databases based on the 1st to nth type numbers, and the type numbers of the 1st and 2nd production elements forming the binary relation are stored in the relational database. In the stored production system creation method, a plurality of various production elements corresponding to the first and second production elements that form the extracted binary relations are classified into the first to nth type numbers based on the first to nth type numbers. Extracting from the n-type database and referring to the first to n-th type numbers of the first and second production elements of the binary relation extracted from the relational database, the same of the production elements that form these binary relations Production factor of type number Integrating extracted their binary relation by binding.

[0014] As another example of the production system creation method, in the production system creation method, Various numbers corresponding to the 1st and 2nd production elements that form the binary relationships extracted from the relational database, with the 1st to nth division numbers to be classified by division set individually in these production factors. With reference to the 1st to nth division numbers of the production elements, the production system for each department made only from the production elements corresponding to the same division number is output.

[0015] As another example of the production system creation method, in the production system creation method, each production element stored in the type database can be modified retroactively to the present or the past, and is stored in the relational database. At least one of the 1 production element and the 2nd production element can be retroactively changed to the present or the past, and each production element stored in the type database and the first and second production elements stored in the relational database Is modified, the new modified production factor is used, and the new binary relationship formed from the modified first and second production factors is used to re-integrate the binary relationship. Then, the production system corresponding to various goods is generated again according to the integrated binary relation.

[0016] As another example of the production system creation method, in the production system creation method, the production system formation time and the departure time from the production system of the production element can be changed retrospectively, and

It is possible to retroactively change the time when the production system related to the binary system is formed and the time when it leaves the production system.

The invention's effect

[0017] According to the production system creation system and the production system creation method according to the present invention, the various binary relationships extracted from the relational database are integrated, and the various multiples extracted from the type database according to the integrated binary relationship. A production system corresponding to each article is created by connecting a series of production elements from the superordinate concept to the subordinate concept.By using the binary relation formed from the first and second production elements, A wide variety of production systems can be created by freely combining different types of production elements. The production system creation system and the production system creation method are to manage production factors in time series from the past to the present by storing the production system formation time and production system power of production factors, and the time of departure from them. By storing the binary system production system formation time and the departure time from the production system, the binary system can be managed in chronological order from the past to the present. Therefore, it is possible to create a production system at any point in the past as well as the present. This production system creation system and production system creation method allows each department to share a type database and a relational database, while creating a production system at any time that each department can share. Since the production system can be managed centrally and chronologically with the database, each department creates and manages a huge number of different production systems that do not require each department to create its own production system. You can save wasted time and effort.

[0018] Various types extracted by referring to the type numbers of the first and second production elements forming the various binary relationships extracted from the relational database and combining the production elements of the same type number The production system creation system and production system creation method that integrate the binary relations of (1) and (2) can reliably combine production elements that are related to each other, and use binary relations to freely combine multiple types of production elements. The ability to create a wide variety of combined production systems. In the production system creation system and the production system creation method, each production element is assigned to the 1st to nth type databases according to the 1st to nth type numbers set in them, and stored in these type databases. The production factors that can be shared by each department by the 1st to n-th type databases can be centrally managed for each type, and the time required for each department to manage each production element individually. And labor can be saved. In this production system creation system and production system creation method, each department shares the relational database and the 1st to nth type databases, and each department uses each production element stored in the 1st to nth type databases. A production system can be created at any point in time that can be shared, and the production system can be centrally managed by the relational database and the 1st to nth type databases.

[0019] Production system creation system and production system creation that outputs a production system for each department formed from only the necessary production elements for each department based on the 1st to nth department numbers individually set for the production elements The method outputs a production system that includes only the production elements that need to be displayed in each department, so production elements that do not need to be displayed in each department can be removed from the production system, and the utility value of each department is high. In addition, an easy-to-use production system can be provided to the department in real time. This production system creation system and production system creation method Each department can use a production system made only from the necessary production factors, and work efficiency of each department can be improved.

[0020] When the production factor stored in the type database and the first and second production factors stored in the relational database are modified retroactively to the present or the past, the modified production factor is used and The production system creation system and production system creation that re-integrate the binary relations using the new binary relations formed from the first and second production elements of the product and generate the production system again according to the integrated binary relations. The method can modify the production factor and the first and second production factors at any point in time from the past to the past by using the modified production factor and the first and second production factors. A new production system at any point in time can be created. In this production system creation system and production system creation method, the modification of the production factors can be managed centrally by the type database, and the modification of the binary relationship by the modification of the first and second production factors is related. It can be managed centrally by the database. Therefore, it is not necessary to create and manage the production system by modifying the production factors and the first and second production factors for each department, and each division individually modifies the production factors and the first and second production factors. Time and labor can be saved.

[0021] The time of production system formation and departure from the production system can be retroactively changed, and the time of formation of the binary system and the departure from the production system can be retroactively changed. Possible production system creation system and production system creation method can change the production system formation time and the departure time from the production system at any time in the past, and the changed production system formation time and departure from the production system Time points can be used to create a new production system from any time in the past to the present. This production system creation system and production system creation method is capable of centrally managing the modification of production factors at the time of formation of the production system and the time of departure from the production system using the type database, and also forms a production system related to the binary system. It is possible to centrally manage the modification at the point of departure or the point of departure from the production system using the relational database. Therefore, it is not necessary to create and manage a production system by changing the production system formation time and the departure time from the production system for each department.There is no need to manage the production system formation time or the departure time from the production system. The ability to save the time and labor of Nichidera by attending. Brief Description of Drawings

FIG. 1 is a schematic configuration diagram of a production system creation system shown as an example.

FIG. 2 is a diagram showing an example of a plurality of various production elements stored in the type database.

3] A diagram showing an example of a binary relation between production elements stored in a relational database. 4] A diagram showing an example of a binary relation between production elements stored in a relational database. [5] A diagram for explaining an example of binary relation integration performed by a computer.

[Figure 6] A diagram showing the production system by department output to each department.

FIG. 7 is a diagram showing a list of start dates and end dates for each production factor.

FIG. 8 is a diagram showing another example of various production elements stored in the type database. FIG. 9 is a diagram showing another example of the binary relationship between the production elements stored in the relation database. FIG. 10 is a diagram showing another example of the binary relation between the production elements stored in the relation database.

[11] FIG. 11 is a diagram for explaining another example of binary relation integration performed by a computer. 12], a diagram showing the production system by department output to each department after the production factors and binary relations have been changed.

[Fig. 13] A diagram showing a list of the start date and end date of each production factor after the production factor and binary relations are changed.

14] A diagram showing another example of various production elements stored in the type database. 15] A diagram showing another example of a binary relation between production elements stored in a relational database.

16] A diagram showing another example of a binary relation between production elements stored in a relational database.

[17] FIG. 17 is a diagram for explaining another example of binary relation integration performed by a computer.

[Figure 18] A diagram showing the departmental production system output to each department after the production factors and binary relations have been deleted and added.

[Figure 19] A diagram showing a list of the start and end dates for each production element after the production elements and binary relationships have been deleted and added. Explanation of symbols

10 Production system creation system

11 Computer

12 Design department

13 Manufacturing department

14 Purchasing department

15 Logistics department

16 Integrated management database

17 Type database

18 Relational database

19 Item database (1st type data-table)

20 Deliverable database (Type 2 data source)

21 Process database (Type 3 data -Tab)

22 Resource database (type 4 data-table)

23 Base database (5th type database-database)

BEST MODE FOR CARRYING OUT THE INVENTION

The details of the production system creation system and the production system creation method according to the present invention will be described below with reference to the accompanying drawings. FIG. 1 is a schematic configuration diagram of a production system creation system 10 shown as an example, and FIG. 2 is a diagram showing an example of various production elements stored in the type database 17. 3 and 4 are diagrams showing an example of binary relations between production elements stored in the relational database 18, and FIG. 5 is a diagram for explaining an example of integration of binary relations performed by the computer 11. . Figure 1 illustrates not only the overall production system that has been created, but also the production system by department that is formed from only the necessary production elements for the design department 12, manufacturing department 13, purchasing department 14, and logistics department 15. ing. Figures 1 to 5 show the status of September 30, 2005, and the present is September 30, 2005. It should be noted that all department divisions that categorize organizations such as government offices and companies are included, not limited to those shown in the figure. The production system creation system 10 includes a computer 11, an integrated management database 16 that centrally manages data such as binary relations between production factors and production factors, and Formed from. In these departments 12, 13, 14, and 15, although not shown, a terminal device (computer) connected to the computer 11 via an interface (wired or wireless) is installed.

[0025] Here, the production element is each piece of technical information (technical element) indispensable for manufacturing the article. In this embodiment, the production element is a warehouse, a product, an assembly drawing, an inspection process, an assembly process. Examples of inspection standards, parts, lines, and tools are shown (see Fig. 1 to Fig. 19). However, the production factors shown are only examples, and the production factors are not limited to these. Production factors include all those that become the technical information of goods. Products and parts belong to items (items) that are component elements of articles, inspection standards and assembly drawings belong to products (items) that are design elements of articles, and inspection and assembly processes are the process of goods. It belongs to the process (item) that is an element. Lines and tools belong to resources (items) that are resource elements of goods, and warehouses belong to bases (items) that are place elements. For goods, not only finished products but also semi-finished products can be obtained.

[0026] For each production element, a type number (first to nth type number) for specifying the type of the production element corresponding to each item is individually set. The first type number is set for each member element belonging to the item, the second type number is set for each design element belonging to the deliverable, and the third type number is set for each process element belonging to the process. Is done. A fourth type number is set for each resource element belonging to the resource, and a fifth type number is set for the base element belonging to the base. The items to which production factors belong are not limited to items, processes, deliverables, resources, or bases. The item to which the production element belongs includes all the other items necessary for manufacturing the article, and the sixth to nth type numbers that specify it are set for the other items. Each production element is individually assigned a department number (1st to nth department number) to classify the elements by department. In this embodiment, the department number of the design department 12 is the first, the department number of the manufacturing department 13 is the second, the department number of the purchasing department 14 is the third, and the logistics department 15 No. 4 is the division number.

The computer 11 has a central processing unit (CPU or MPU) and a storage device, and has a built-in large-capacity hard disk. Although not shown in the figure, the computer 11 has an input device such as a mouse and an output device such as a display or printer as an interface ( (Wired or wireless). A production system creation program for executing each means of the system 10 is stored in the internal address file of the storage device. The production system creation program is installed in a storage device of the computer 11 from an optical disk (storage medium) such as a CD-ROM that stores the production system creation program. In addition to the optical disk, a semiconductor memory or a magnetic disk can also be used as the storage medium.

[0028] When the production system creation program is installed in the computer 11, the storage device of the computer 11 or the hard disk built in the computer 11 belongs to the models of items such as items, deliverables, processes, bases, etc. Stored are various types of production element models, type numbers corresponding to these types of items, department models, and department-specific numbers indicating each department. Furthermore, a database file serving as an integrated management database 16 (first to fifth type database 17 and relational database 18 described later) is created on the hard disk built in the computer 11. The computer 11 extracts necessary data from the storage device and the integrated management database 16 and stores the data in the storage device and the integrated management database 16 as necessary. In this system 10, in addition to existing events and production factors, new events, new production factors, and new departments can be freely set, and production systems can be created using these new production factors. . New events, new production factors, and new divisions are input from the input device to the computer 11 and stored in a storage device or hard disk. In System 10, existing events, production factors, and departments can be deleted from storage devices and hard disks, and newly created new events, production factors, and new divisions can be deleted from storage devices, hard disk drives, and other companies. You can also

[0029] The central processing unit of the computer 11 activates a production system creation program stored in the internal address file of the storage device, and integrates a plurality of binary relationships of different types according to the program, Production system generating means for generating in real time a production system corresponding to each article based on the integrated binary relation in real time or in the past, and a production body storing the generated production system in its storage device or hard disk The system storage means, the production system output means for outputting the generated production system via the output device, and the departmental production system output means for outputting the production system for each department are executed. The central processing unit is the first modification means that retrospectively modifies the production factors, and the binary relationship is retroactively modified. The first modification means to retroactively change the start date of production factors (at the time of production system formation of production factors) and the end date of production factors (at the time of departure of production factors from the production system). Execute the second change means to retroactively change the start date of binary relations (at the time of formation of the production system of binary relations) and the end date of binary relations (at the time of withdrawal from the production system of binary relations) The In addition, input devices such as a keyboard and a mouse and output devices such as a display and a printer are connected to terminal devices installed in each department.

[0030] The integrated management database 16 is formed of a type database 17 (first to nth type database) that stores data relating to each production element, and a relation database 18 that stores a binary relation between production elements. ing. The integrated management database 16 transfers data to the computer 11 based on a data transfer command from the computer 11 and stores data based on a data storage command from the computer 11. The data is modified based on the data modification instruction from the computer 11. The type database 17 corresponds to the item database 19 (first type database) corresponding to the first type number, the deliverable database 20 (second type database) corresponding to the second type number, and the third type number. Divided into process database 21 (third type database), resource database 22 (fourth type database) corresponding to the fourth type number, and base database 23 (fifth type database) corresponding to the fifth type number Has been. In addition, there are cases in which the 6th to nth type databases are stored in the hard disk, which stores other production elements that are indispensable for the manufacture of goods, without being limited to the type database 17 and classified according to the type. .

[0031] An example of a procedure for storing data relating to a plurality of various production elements, which are technical information of the article (1), in the type database 17 and an example of a procedure for storing a binary relation between the production elements in the relational database 18 Is described as follows. Data related to warehouse (A), product (G), assembly drawing (P), assembly process (S), parts), line (δ), warehouse (倉庫) Data entered on January 1st. When an item is selected from the type displayed on the display, the item input area that will be the production element input area on the display, the department classification input area that corresponds to the item input area, and the start date input area that is the point of formation of the production system for the production element , The end of production elements leaving the production system An end date input area and a production element input area to be ended are displayed. Enter the product (G), part (<<) and their product number (G), («) (type identification number) in the item input area via the input device, and the product (G), part in the division classification input area. In addition to entering the division category (<<), the start date and end date of the product (G) and part (α) are entered in the start date input area and end date input area. The computer 11 refers to the type, production factor, and type number stored in the storage device or hard disk, determines that the product (G) and part (α) belong to the item, and determines that the product (G) and part (a ) Is assigned the item data classification (PC001) (first type number), and based on the entered department classification, product (G) and parts (<<) are assigned department numbers (1, 2, 3, 4).

[0032] The computer 11 is a product (G) item data category (PC001), department number (1, 2, 3, 4), a product number (G) that identifies the product (G), and the start of the product (G). Product data such as date (January 1, 2005), product (G) end date (1), etc. is stored in the main file of the item database 19, and the part (item data category (PC001) and department number (1 , 2, 3), part number (α), part number (α), part) start date (January 1, 2005), part) end date (1), etc. Store in 19 main files. The product data includes the contents of the product (G) (name, description of use, durable years, price, delivery date, etc.), and the parts data includes the contents of the parts (name, production location, instructions for use, durable years, Price, delivery date, etc.).

[0033] When a product is selected from the types displayed on the display, the product input area that is the production element input area on the display, the department category input area corresponding to the product input area, and the production system of the production system The start date input area, the end date input area when the production element leaves the production system, and the production element input area to be ended are displayed. Enter the assembly drawing (P) and its product number (P) (type identification number) in the product input area via the input device, and enter the division of the assembly drawing (P) in the division classification input area. Then, enter the start date and end date of the assembly drawing (P) in the start date input area and end date input area. The computer 11 refers to the item, production element, and type number stored in the storage device or hard disk, determines that the assembly drawing (P) belongs to the product, and outputs the product data classification (PC002) to the assembly drawing (P). ) (Second type number) is attached, and the department number (1, 2) is attached to the assembly drawing (P) based on the input department classification. The computer displays the product data category (PC002), division number (1, 2), assembly number (P), product number (P), assembly Assembly drawing data such as the start date of the figure (P) (January 1, 2005) and the end date (1) of the assembly drawing (P) are stored in the main file of the deliverable database 20. The assembly drawing data includes the contents of the assembly drawing (P) (drawing details, creation department, usage instructions, etc.).

[0034] When a process is selected from the type displayed on the display, it is the process input area that becomes the production element input area on the display, the division input area that corresponds to the process input area, and the production element production system The start date entry area, the end date entry area that is the point of departure from the production system of the production element, and the production element entry area to be finished are displayed. Enter the assembly process (S) and its product number (S) (type identification number) in the process input area via the input device, and enter the department classification of the assembly process (S) in the department classification input area. Enter the start date and end date of the assembly process (S) in the date input area and end date input area. The computer 11 refers to the item, production element, and type number stored in the storage device or hard disk, determines that the assembly process (S) belongs to the process, and enters the process data classification (PC003) in the assembly process (S). (Third type number) is attached, and the department number (2) is assigned to the assembly process (S) based on the input department classification. The computer uses the assembly process (S) process data category (PC003), department number (2), part number (S) that identifies the assembly process (S), and start date of the assembly process (S) (January 2005 Date), assembly drawing data such as the end date (1) of the assembly process (S) is stored in the main file of the process database 21. The assembly process data includes the details of the assembly process (S) (process details, assembly location, usage instructions, etc.).

[0035] When a resource is selected from the type displayed on the display, the resource input area that is the production element input area on the display, the division input area corresponding to the resource input area, and the production system of the production elements are formed The start date entry area, the end date entry area that is the point of departure from the production system of the production element, and the production element entry area to be finished are displayed. Enter the line (δ) and its product number (δ) (type identification number) in the resource input area via the input device, enter the division of line (δ) in the division input area, and start date input area Enter the start date and end date of the line (δ) in the end date input area. The computer 11 refers to the item, production factor, and type number stored in the storage device or hard disk, determines that the line (δ) belongs to the resource, and assigns the resource data classification (PC004) (No. 4) to the line (δ). Type number), and a part of the line (δ) based on the entered division Give the gate number (1, 2). The computer uses the resource data classification (PC004) of the line (δ), the division number (1, 2), the part number (δ) that identifies the line (δ), the start date of the line (δ) (January 1, 2005 ), Line data such as the end date (1) of the line (δ) is stored in the main file of the resource database 22. The line data includes the contents of the line (δ) (the name of the line, the location of the line, etc.).

[0036] When a base is selected from the types displayed on the display, the base input area that is the production element input area on the display, the division input area corresponding to the base input area, and the production system of the production elements are formed The start date entry area, the end date entry area that is the point of departure from the production system of the production element, and the production element entry area to be finished are displayed. Enter the warehouse (Α) and its product number (Α) (type identification number) in the base input area via the input device, enter the department category of warehouse (Α) in the department input area, and enter the start date input area. And enter the start date and end date of the warehouse (Α) in the end date input area. The computer 1 1 refers to the item, production factor, and type number stored in the storage device or hard disk, determines that the warehouse (Α) belongs to the base, and stores the data (PC00 5) in the warehouse (Α). (5th type number) is attached, and the department number (4) is assigned to the warehouse (Α) based on the entered department classification. Computer 1 1 is the base data category (PC005) of warehouse (Α), departmental number (4), product number (Α) that identifies warehouse (Α), and start date of warehouse (倉庫) (January 1, 2005 Store the warehouse data such as the end date (1) of the warehouse (Α) in the main file of the base database 23. The warehouse data includes the contents of warehouse (Α) (warehouse name, warehouse location, etc.). As of January 1, 2005, warehouses (Α), products (G), assembly drawings (Ρ), assembly processes (S), parts (a), in (δ) are the components of the production system. Their end date is blank (one).

[0037] The relation database 18 stores the upper and lower binary relations (parent-child relation) as data of the manufacturing department 13 and the upper and lower binary relations (parent-child relation) as data of the distribution department 15. In the binary relationship, production factors are linked by an arbitrary first production factor (parent production factor) and a second production factor (child production factor) that is immediately below the first production factor. The binary relation identifies the second production factor from the first production factor and the first production factor from the second production factor. On January 1, 2005, a binary relationship between warehouse (Α) and product (G), a binary relationship between product (G) and assembly drawing (図), product (G) and assembly process (S) Binary relationship between the assembly process (S) and the part (α) Stores binary relations, binary relations between assembly process (S) and line (δ).

[0038] When a relationship is selected from the items displayed on the display, the display shows the relationship at the time when the production system of the relationship area (1) to the relationship area (η), the sector classification input area, and the binary relationship is formed. The start date input area, the relation end date input area that is the point of departure from the binary relation production system, and the end target binary relation input area are displayed. Enter the warehouse (Α) and product (G) in the related area (1) via the input device, and enter the department classification (4) in the department classification input area corresponding to the related area (1). Next, the product number (Α) (type identification number) that identifies the warehouse (Α) as the parent product number (first production factor), the base number (PC005) (the fifth type number) as the parent data classification, the child product number Enter the product number (G) (type identification number) that identifies the product (G) as the (second production factor), and the item number (PC001) (first type number) as the child data category. In addition, enter the start date (January 1, 2005) and end date (one) of the relationship between the warehouse (Α) and the product (G) in the relationship start date input area and the relationship end date input area. To do. When these data are input, the computer 11 stores the data in the relational database 18. In relational database 18, warehouse (Α) and product (G) are linked, and warehouse (Α) and product (G) are linked based on the binary relationship.

[0039] The product (G) and the assembly drawing (Ρ) are input to the relation area (2), and the department classification (2) is input to the department classification input area corresponding to the relation area (2). Next, the product number (G) that identifies the product (G) as the parent product number (first production factor), the item number (PC001) (first type number) as the parent data category, and the child product number (second production factor) Enter the part number (Ρ) (type identification number) that identifies the assembly drawing (Ρ) and the item number (PC002) (second type number) as the child data category. In addition, enter the start date (January 1, 2005) and end date (-) of the binary relationship between product (G) and assembly drawing (Ρ) in the relationship start date input area and relationship end date input area. To do. When these data are input, the computer 11 stores the data in the relational database 18. In relational database 18, product (G) and assembly drawing (Ρ) are linked, and product (G) and assembly drawing (Ρ) are linked based on the binary relationship.

[0040] The product (G) and the assembly process (S) are input to the related area (3), and the department category (2) is input to the department category input area corresponding to the related area (3). Next, the product number (G) that identifies the product (G) as the parent product number (first production factor), and the item number (PC001) (first type number as the parent data category) No.), the part number (S) (type identification number) that identifies the assembly process (S) as the sub part number (second production factor), and the process number (PC003) (third type number) as the sub data classification. In addition, enter the start date (January 1, 2005) and end date (one) of the binary relationship between product (G) and assembly process (S) in the relationship start date input area and relationship end date input area. To do. When these data are input, the computer 11 stores the data in the relational database 18. In the relational database 18, the product (G) and the assembly process (S) are linked, and the product (G) and the assembly process (S) are linked based on the binary relation.

[0041] The assembly process (S) and the part (α) are input to the related area (4), and the department category (2) is input to the department category input area corresponding to the related area (4). Next, the part number (S) that identifies the assembly process (S) as the parent part number (first production factor), the process number (PC003) (third type number) as the parent data classification, and the child part number (second production) Enter the part number (α) (type identification number) that identifies the part) as the element and the item number (PC001) (first type number) as the child data category. In addition, enter the start date (January 1, 2005) and end date (one) of the binary relationship between the assembly process (S) and the part (α) in the relationship start date input area and the relationship end date input area. . When these data are input, the computer 11 stores the data in the relational database 18. In the relational database 18, the assembly process (S) and the part (α) are linked, and the assembly process (S) and the part (α) are linked based on the binary relation.

[0042] The assembly process (S) and the line (δ) are input to the relation area (5), and the department classification (2) is input to the department classification input area corresponding to the relation area (5). Next, the part number (S) that identifies the assembly process (S) as the parent part number (first production element), the process number (PC003) (third type number) as the parent data classification, and the child part number (second production element) Enter the product number (δ) (type identification number) that identifies the line (δ) and the item number (PC001) (first type number) as the child data category. In addition, enter the start date (January 1, 2005) and end date (one) of the binary relationship between assembly process (S) and line (δ) in the relationship start date input area and relationship end date input area. To do. When these data are input, the computer 11 stores the data in the relational database 18. In the relational database 18, the assembly process (S) and the line (δ) are linked to the force S, and the assembly process (S) and the line (δ) are linked based on the binary relation!

[0043] The binary relation between the warehouse (Α) and the product (G) is the data of the logistics department 15 depending on the department category. Be treated. Binary relationship between product (G) and assembly drawing (P), Binary relationship between product (G) and assembly process (S), Binary relationship between assembly process (S) and part (α), assembly The binary relation between the process (S) and the line (δ) is handled as data for the manufacturing department 13 by department classification. As of January 1, 2005, the binary relationship between warehouse (Α) and product (G), the binary relationship between product (G) and assembly drawing (Ρ), product (G) and assembly process (S ), The binary relationship between the assembly process (S) and the part (α), and the binary relationship between the assembly process (S) and the line (δ) are the components of the production system. The term relationship end date is blank (one).

[0044] On April 1, 2005, data on parts (0), assembly drawing (Q), line (ε), and tool (Θ) was stored in type database 17, and product (G) and assembly drawing were stored. (Q) binary relation, assembly process (S) and parts (/ 3) binary relation, assembly process (S) and line (δ) binary relation, assembly process (S) and tool The binary relation with (Θ) is stored in the relational database 18. An example of the storage procedure for each data and each of the binary-related databases 17 and 18 on April 1, 2005 is as follows.

[0045] The assembly drawing (Q) and its product number (Q) (type identification number) are input to the product input area displayed on the display via the input device, and the assembly drawing (Q) is input to the division classification input area. Enter the division and enter the start date and end date of the assembly drawing (Q) in the start date input area and end date input area. Furthermore, the assembly drawing (Ρ) and its end date are entered in the end production element input area displayed on the display. The computer 11 refers to the items, production factors, and type numbers stored in the storage device or hard disk, determines that the assembly drawing (Q) belongs to the product, and outputs the product data classification (Q) to the assembly drawing (Q). PC002) (second type number) is attached, and the departmental number (1, 2) is attached to the assembly drawing (Q) based on the input department classification. The computer 11 outputs the assembly drawing (Q) product data category (PC002), division number (1, 2), part number (Q) identifying the assembly drawing (Q), and start date of the assembly drawing (Q) (2005 1 April), assembly drawing data such as assembly drawing (Q) end date (-), and assembly drawing (Ρ) end date (March 31, 2005) are stored in the main file of deliverable database 20 To do. The assembly drawing data includes the contents of the assembly drawing (Q) (drawing details, creation department, usage instructions, etc.).

[0046] A part (/ 3) and its product number are input to the item input area displayed on the display via the input device

Enter (Type identification number), and enter the division (/ 3) division in the division input area. The start date and end date of the part (β) are entered in the start date input area and end date input area. Further, the part (α) and its end date are input to the end target production element input area displayed on the display. The computer 11 refers to the item, production element, and type number stored in the storage device or hard disk, determines that the part (/ 3) belongs to the item, and sets the item data classification (PC001) to the part (/ 3). ) (1st type number) is attached, and the part number (1, 2, 3) is assigned to the part (/ 3) based on the entered department classification. The computer 1 1 includes the item data classification (PC001) of the part (/ 3), the division number (1, 2, 3), the part number (/ 3) specifying the part (/ 3), and the part (/ 3). Parts data such as start date (April 1, 2005), end date (-) of parts (/ 3), end date of parts (α) (March 31, 2005) in main file of item database 19 Store. The parts data includes the contents of parts (/ 3) (name, production location, usage instructions, durable years, price, delivery date, etc.).

[0047] The line (ε) and its product number (ε) (type identification number) are input to the resource input area displayed on the display via the input device, and the department classification of the line (ε) is input to the department classification input area. In addition, enter the start date and end date of the line (ε) in the start date input area and end date input area. In addition, the line (δ) and its end date are input to the production target entry area for termination displayed on the display. The computer 11 refers to the item, production factor, and type number stored in the storage device or hard disk, determines that the line (ε) belongs to the resource, and assigns the resource data classification (PC004) (No. 1) to the line (ε). (4 type number), and the division number (1, 2) is assigned to the line (ε) based on the entered division classification. The computer 1 1 is the start date (April 1, 2005) of the resource data classification (PC004) of the line (ε), the division number (1, 2), the part number identifying the line (ε), and the line) The line data such as the end date (-) of the line (ε) and the end date (March 31, 2005) of the line (δ) are stored in the main file of the resource database 22. The line data includes the contents of the line (ε) (line name, line location, etc.).

[0048] The tool (Θ) and its part number are input to the resource input area displayed on the display via the input device.

Enter (Θ) (type identification number), enter the division of the tool (Θ) in the division division input area, and start and end of the tool (Θ) in the start date input area and end date input area Enter the date. Computer 1 1 is stored on a storage device or hard disk The tool (Θ) is determined to belong to the resource, the tool (Θ) is assigned the resource data category (PC004) (fourth category number), and the entered department category is referenced. The division number (1, 2) is assigned to the tool (Θ). The computer 11 uses the resource data classification (PC004) of the tool (Θ), the division number (1, 2), the part number (Θ) that identifies the tool (Θ), and the start date of the tool (Θ) (2005 4 The tool data such as the end date (1) of the tool (Θ) and the tool (Θ) are stored in the resource database 22 main file. The tool data includes the contents of the tool (Θ) (tool usage, price, durability, etc.). As of April 1, 2005, assembly drawings (Q), parts (β), lines), tools (Θ) are the components of the production system, so assembly drawings (Q), parts (/ 3), lines The end date of (ε), tool (Θ) is blank (one). Assembly drawings (Ρ), parts), and lines (δ) will be removed from the formation of the production system on March 31, 2005, depending on the end date.

[0049] Enter the product (G) and assembly drawing (Q) in the relation area (6) displayed on the display, and enter the department classification (2) in the department classification input area corresponding to the relation area (6). . Next, the product number (G) that identifies the product (G) as the parent product number (first production factor), the item number (PC001) (first type number) as the parent data category, and the child product number (second production factor) Enter the part number (Q) (type identification number) and the product number (PC002) (second type number) as the child data category. In addition, enter the start date (April 1, 2005) and end date (one) of the relationship between the product (G) and assembly drawing (Q) in the relationship start date input area and relationship end date input area. Then enter the binary relationship between the product (G) and the assembly drawing (Ρ) and its end date (March 31, 2005) in the input target binary relationship input area. When these data are input, the computer 11 stores the data in the relational database 18. In relational database 18, product (G) and assembly drawing (Q) are linked, and based on binary relationship! /, Product (G) and assembly drawing (Q) are linked.

[0050] Enter the assembly process (S) and parts (/ 3) in the relation area (7) displayed on the display, and set the department classification (2) in the department classification input area corresponding to the relation area (7). input. Next, the part number (S) that identifies the assembly process (S) as the parent part number (first production factor), the process number (PC003) (third type number) as the parent data classification, and the child part number (second production) Part number (/ 3) (type identification number) that identifies the part (/ 3) as the element, and item number (PC001) (first type as the child data category) Number). In addition, the start date (April 1, 2005) and end date (one) of the binary relationship between assembly process (S) and parts (/ 3) are entered in the relationship start date input area and the relationship end date input area. Enter the binary relation between the assembly process (S) and the part (α) and the end date (March 31, 2005) in the binary relation input area. When these data are input, the computer 11 stores the data in the relational database 18. In the relational database 18, the assembly process (S) and the part (/ 3) are linked to the force S, and the assembly process (S) and the part (/ 3) are linked based on the binary relation.

[0051] Enter the assembly process (S) and the line (ε) in the relation area (8) displayed on the display, and enter the department classification (2) in the department classification input area corresponding to the relation area (8). . Next, the part number (S) that identifies the assembly process (S) as the parent part number (first production element), the process number (PC003) (third type number) as the parent data classification, and the child part number (second production element) Enter the part number (ε) (type identification number) that identifies the line ( _ε ) and the resource number (PC004) (fourth type number) as the child data category. In addition, enter the start date (April 1, 2005) and end date (one) of the binary relationship between the assembly process (S) and the line (ε) in the relationship start date input area and the relationship end date input area. Then, enter the binary relationship between the assembly process (S) and the line (δ) and its end date (March 31, 2005) in the termination target binary relationship input area. When these data are input, the converter 11 stores the data in the relational database 18. In the relational database 18, the assembly process (S), the line (ε), and the force S are linked, and the assembly process (S) and the line) are linked based on the binary relation.

[0052] Enter the assembly process (S) and tool (Θ) in the relation area (9) displayed on the display, and enter the department classification (2) in the department classification input area corresponding to the relation area (9). To do. Next, the part number (S) that identifies the assembly process (S) as the parent part number (first production factor), the process number (PC003) (third type number) as the parent data classification, and the child part number (second production) Enter the part number (Θ) (type identification number) that identifies the tool (Θ) as the element and the resource number (PC004) (fourth type number) as the child data category. In addition, the start date (April 1, 2005) and end date (one) of the binary relationship between assembly process (S) and tool (Θ) are entered in the relationship start date input area and the relationship end date input area. To help. When these data are input, the computer 11 stores the data in the relational database 18. In relational database 18, assembly process (S) and tool (Θ) are linked. The assembly process (S) and the tool (θ) are linked based on the binary relation.

[0053] Two-term relationship between product (G) and assembly drawing (Q), two-term relationship between assembly process (S) and part (/ 3), two terms between assembly process (S) and line (ε) The binary relation between the relationship, assembly process (S) and tool (Θ) is handled as data of the manufacturing department 13 by department classification. As of April 1, 2005, the binary relationship between product (G) and assembly drawing (Q), the binary relationship between assembly process (S) and parts (/ 3), assembly process (S) and line ( Since the binary relationship with ε) and the binary relationship between the assembly process (S) and the tool (Θ) are the components of the production system, the end date of these binary relationships is blank (one). The binary relationship between the product (G) and the assembly drawing (Ρ), the binary relationship between the assembly process (S) and the part (α), and the binary relationship between the assembly process (S) and the line (δ) are complete. By March 31st, 2005, the production system was separated from the formation factor (withdrawal).

[0054] On June 1, 2005, data on the warehouse (Β), assembly drawing (R), assembly process (Τ), and parts (γ) were stored in the type database 17, and the warehouse (Β) Binary relationship with product (G), Binary relationship between product (G) and assembly drawing (R), Binary relationship between product (G) and assembly process (Τ), assembly process (Τ) and parts The binary relation between (γ), the binary relation between assembly process (Τ) and line (ε), and the binary relation between assembly process (Τ) and tool (Θ) are stored in relational database 18. An example of the storage procedure for each data and each of the databases related to binary data 17, 18 as of June 1, 2005 is as follows.

[0055] Warehouse (Β) and its product number via the input device in the base input area displayed on the display

(Β) Enter (Type ID), enter the division of warehouse (Β) in the division input area, and start and end of warehouse (Β) in the start date input area and end date input area Enter the day. In addition, the warehouse (Α) and its end date are entered in the production target entry area for termination displayed on the display. The computer 11 refers to the item, production factor, and type number stored in the storage device or hard disk, determines that the warehouse (Β) belongs to the base, and stores the base data classification (PC005) (No. 5) in the warehouse (Β). Type number), and the department number (4) is assigned to the warehouse (Β) based on the entered division classification. Computer 11, warehouse (Β) based data classification (PC005) and the departmental number (4), part number that identifies the warehouse (Β) (Β), the start date of the warehouse (Β) ⁽² 005 June 1 ), Warehouse data such as warehouse (日) end date (1), etc. and warehouse (Α) end date (May 31, 2005) are stored in the main file of base database 23 . The warehouse data includes the contents of warehouse (B) (warehouse name, warehouse location, etc.).

[0056] The assembly drawing (R) and its product number (R) (type identification number) are input to the item input area displayed on the display via the input device, and the assembly drawing (R) is input to the division classification input area. Enter the department category and enter the start date and end date of the assembly drawing (R) in the start date input area and end date input area. Further, the assembly drawing (Q) and its end date are entered in the production element input area for completion displayed on the display. The computer 11 refers to the item, production factor, and type number stored in the storage device or hard disk, determines that the assembly drawing (R) belongs to the product, and outputs the product data classification (PC002) to the assembly drawing (R). (Second type number) is attached, and the division number (1, 2) is attached to the assembly drawing (R) based on the input department classification. The computer 11 uses the product data category (PC002), department number (1, 2) of the assembly drawing (R), the part number (R) that identifies the assembly drawing (R), and the start date of the assembly drawing (R) ( As of June 1, 2005), assembly drawing data such as the end date (-) of assembly drawing (P), and the end date (May 31, 2005) of assembly drawing (Q) in the main file of fruit database 20 Store. The assembly drawing data includes the contents of the assembly drawing (R) (details of drawing, creation department, usage instructions, etc.).

[0057] The assembly process (T) and its product number (T) (type identification number) are entered in the item input area displayed on the display via the input device, and the assembly process (T) department is entered in the department category input area. In addition to entering the category, enter the start date and end date of the assembly process (T) in the start date input area and end date input area. Further, the assembly process (S) and its end date are entered in the end target production element input area displayed on the display. The computer 11 refers to the items, production factors, and type numbers stored in the storage device or hard disk, and

(T) is determined to belong to the process, the process data category (PC003) (3rd type number) is assigned to the assembly process (T), and the department number (E) is assigned to the assembly process (T) based on the entered department category. Add 2). The computer 11 displays the assembly process (T) process data category (PC003), department number (2), product number (T) identifying the assembly process (T), and start date of the assembly process (T) (June 2005 1), the assembly process data such as the end date (1) of the assembly process (T) and the end date (May 31, 2005) of the assembly process (S) are stored in the main file of the process database 21. The process data includes the contents of the assembly process (T) (process details, assembly location, usage instructions, etc.).

[0058] Parts ( _Ί ) and their product _numbers via the input device in the item input area displayed on the display (Γ) (type identification number) input and, end with enter and the department classification of the part (γ) into the department classification input area, the start date of the parts _(Ί) to the start date input area and the end date input area Enter the date. Further, the part (/ 3) and its end date are entered in the end target production element input area displayed on the display. The computer 11 refers to the item, production factor, and type number stored in the storage device or hard disk, determines that the part (γ) belongs to the item, and sets the item data classification (PC001) (No. 1 type number), and a part number (1, 2, 3) is assigned to the part (γ) based on the entered department category. The computer 11 uses the item data category (PC001) of the part (γ), the division number (1, 2, 3), the part number (γ) that identifies the part (γ), and the start date of the part (Ί) (2005 June 1), part data such as the end date (-) of the part (γ), and the end date (May 31, 2005) of the part (β) are stored in the main file of the item database 19. The part data includes the contents of the part (γ) (name, production location, usage instructions, durable years, amount of money, delivery date, etc.). As of June 1, 2005, warehouse (Β), assembly drawing (R), assembly process (Τ), and parts (γ) are the components of the production system, so warehouse (Β), assembly drawing (R) Therefore, the end date of assembly process (iii) and part (γ) is blank (one). The warehouse (Α), assembly drawing (Q), assembly process (S), and parts (/ 3) will be removed from the formation of the production system on May 31, 2005 depending on the end date.

[0059] The warehouse (Β) and the product (G) are input to the relation area (10) displayed on the display, and the department classification (4) is input to the department classification input area corresponding to the relation area (10). Next, the product number (Β) that identifies the warehouse (Β) as the parent product number (first production factor), the base number (PC005) (fifth type number) as the parent data category, the child product number (second production factor) ) Enter the product number (G) (type identification number) that identifies the product (G), and the item number (PC001) (first type number) as the child data category. In addition, enter the start date (June 1, 2005) and end date (one) of the binary relationship between warehouse (Β) and product (G) in the relationship start date input area and relationship end date input area, Enter the binary relationship between the warehouse (Α) and the product (G) and its end date (May 31, 2005) in the binary target relationship input area. When these data are input, the computer 11 stores the data in the relational database 18. In the relational database 18, the warehouse (Β) and the product (G) are linked, and the warehouse (Β) and the product (G) are linked based on the binary relation.

[0060] Enter the product (G) and assembly drawing (R) in the relationship area (11) displayed on the display, and Enter the department classification (2) in the department classification input area corresponding to the staff area (11). Next, the product number (G) that identifies the product (G) as the parent product number (first production factor), the product number (PC001) (first type number) as the parent data category, and the child product number (second production factor) Enter the part number (R) (type identification number) that identifies the assembly drawing (R) and the product number (PC002) (second type number) as the child data category. In addition, enter the start date (June 1, 2005) and end date (one) of the binary relationship between the product (G) and assembly drawing (R) in the relationship start date input area and the relationship end date input area. Then, enter the binary relationship between the product (G) and assembly drawing (Q) and the end date (May 31, 2005) in the input target binary relationship input area. When these data are input, the computer 11 stores the data in the relational database 18. In relational database 18, product (G) and assembly drawing (R) are linked, and product (G) and assembly drawing (R) are linked based on binary relations.

[0061] Enter the product (G) and assembly process (T) in the relation area (12) displayed on the display, and enter the department classification (2) in the department classification input area corresponding to the relation area (12). . Next, the product number (G) that identifies the product (G) as the parent product number (first production factor), the item number (PC001) (first type number) as the parent data category, and the child product number (second production factor) Enter the part number (T) (type identification number) that identifies the assembly process (T), and the process number (PC003) (third type number) as a child data category. In addition, enter the start date (June 1, 2005) and end date (one) of the binary relationship between the product (G) and the assembly process (T) in the relationship start date input area and the relationship end date input area. Then, enter the binary relationship between the product (G) and assembly process (S) and its end date (May 31, 2005) in the binary target entry area. When the data is input, the computer 11 stores the data in the relational database 18. In the relational database 18, the product (G) and the assembly process (T) are linked, and the product (G) and the assembly process (T) are linked based on the binary relation.

[0062] Enter the assembly process (T) and parts (γ) in the relation area (13) displayed on the display, and enter the department classification (2) in the department classification input area corresponding to the relation area (13). . Next, the part number (Τ) that identifies the assembly process (Τ) as the parent part number (first production element), the process number (PC003) (third type number) as the parent data classification, and the child part number (second production element) The part number (γ) (type identification number) that identifies the part (γ) as the item number (PC001) (No. 1 Type). In addition, enter the start date (June 1, 2005) and end date (one) of the binary relationship between the assembly process (T) and the part (γ) in the relationship start date input area and relationship end date input area. Then, the binary relationship between the assembly process (S) and the part (13) and its end date (May 31, 2005) are entered in the binary target relationship input area. When these data are input, the computer 11 stores the data in the relational database 18. In the relational database 18, the assembly process (Τ) and the part (γ) are linked to the force S, and the assembly process (Τ) and the part () are linked based on the binary relation.

[0063] Enter the assembly process (Τ) and line (ε) in the relation area (14) displayed on the display, and enter the department classification (2) in the department classification input area corresponding to the relation area (14). . Next, the part number (Τ) that identifies the assembly process (Τ) as the parent part number (first production element), the process number (PC003) (third type number) as the parent data classification, and the child part number (second production element) Enter the part number (ε) (type identification number) that identifies the line ( _ε ) and the resource number (PC004) (fourth type number) as the child data category. In addition, enter the start date (June 1, 2005) and end date (-) of the binary relationship between assembly process (Τ) and line (ε) in the relationship start date input area and relationship end date input area. Enter the binary relationship between the assembly process (S) and the line (ε) and the end date (May 31, 2005) in the input target binary relationship input area. When these data are input, the converter 11 stores the data in the relational database 18. In the relational database 18, the assembly process (Τ) and the line (ε) are linked to the force S, and the assembly process (Τ) and the line) are linked based on the binary relation.

[0064] Enter the assembly process (Τ) and tool (Θ) in the relation area (15) displayed on the display, and enter the department classification (2) in the department classification input area corresponding to the relation area (15). . Next, the part number (Τ) that identifies the assembly process (Τ) as the parent part number (first production element), the process number (PC003) (third type number) as the parent data classification, and the child part number (second production element) Enter the part number (Θ) (type identification number) that identifies the tool (Θ) and the resource number (PC004) (fourth type number) as the child data category. In addition, enter the start date (June 1, 2005) and end date (one) of the binary relationship between the assembly process (Τ) and the tool (Θ) in the relationship start date input area and relationship end date input area. Then, enter the binary relationship between the assembly process (S) and the tool (Θ) and its end date (May 31, 2005) in the binary target entry area. Enter those data, computer 11 stores the data in the relational database 18. In the relational database 18, the assembly process (T) and the tool (Θ) are linked, and the assembly process (T) and the tool (Θ) are linked based on the binary relation.

[0065] The binary relation between the warehouse (B) and the product (G) is handled as data of the logistics department 15 by department classification. Two-term relationship between product (G) and assembly drawing (R), two-term relationship between product (G) and assembly process (T), two-term relationship between assembly process (T) and part (γ), assembly The binomial relationship between the process (と) and the line (ε) and the binomial relationship between the assembly process (Τ) and the tool (Θ) are handled as data for the manufacturing department 13 depending on the division. As of June 1, 2005, binary relationship between warehouse (Β) and product (G), binary relationship between product (G) and assembly drawing (R), product (G) and assembly process (Τ) Binary relation between assembly process (Τ) and part (Ί), Binary relation between assembly process (Τ) and line ( _ε ), Assembly process (Τ) and tool (Θ) Since the binary relations of (1) and (2) are the elements of the production system, the end date of these binary relations is blank (1). Two-term relationship between warehouse (Α) and product (G), two-term relationship between product (G) and assembly drawing (Q), two-term relationship between product (G) and assembly process (S), assembly process ( The binary relationship between S) and the part (13), the binary relationship between the assembly process (S) and the line (ε), and the binary relationship between the assembly process (S) and the tool (Θ) are Depending on the setting, it will deviate from the components of the production system on May 31, 2005 (separation).

[0066] In this system 10, a plurality of binary relationships of different types (by department, by category, by element) extracted from the relational database 18 are integrated, and the first to fifth type databases are integrated according to the integrated binary relationship. A production system corresponding to the article (1) is created by connecting a plurality of different types of production elements extracted from 19, 20, 21, 22 and 23 in series from the superordinate concept to the subordinate concept. Based on FIG. 5, the integration of various binary relations and generation of the production system for the article (1) performed by the computer 11 are described as follows. It is assumed that the production system shown in Figure 5 was generated on September 30, 2005.

[0067] When an instruction to generate a production system as of September 30, 2005 is given via the input device, the computer 11 refers to the start date and end date of the binary relation, and as of September 30, 2005. In this example, the binary relations that form the production system are extracted from the relational database 18 and the production factors that form the extracted binary relations are referred to by referring to the start and end dates of the production elements. Extract from 5 types database 19, 20, 21, 22, 23 . Next, the computer 11 integrates the extracted binary relations, and connects the various extracted production elements in a series from the superordinate concept to the subordinate concept according to the integrated binary relation. Create a production system for goods (1) on the date of. The production system generation on September 30 is specifically explained as follows.

[0068] The computer 11 extracts a binary relation between the warehouse (B) and the product (G) from the relational database 18 as the logistics department data. Computer 11 replaces the base number (PC005) of the parent data classification of warehouse (B) with the base data classification (PC005) of base database 23, and based on the part number (B) and the base data classification (PC005)! / Then, the data of the warehouse (B) is extracted from the base database 23. Computer 11 replaces the item number (PC 001) in the child data category of product (G) with the item data category (PC001) in item database 19, and the item database based on the item number (G) and item data category (PC001). Extract product (G) data from 19.

[0069] The computer 11 extracts the binary relation between the product (G) and the assembly drawing (R) from the relational database 18 as manufacturing department data, and outputs the product number of the child data classification of the assembly drawing (R). Replace (PC002) with the product data category (PC002) in the product database 20, and based on the product number (R) and product data category (PC002), the assembly database (R) Extract data. The computer 11 extracts the binary relation between the product (G) and the assembly process (T) from the relational database 18, and sets the process number (PC003) of the child data category of the assembly process (T) to the process data in the process database 21. The data is read as the category (PC003), and the assembly process (T) data is extracted from the process database 21 based on the part number (T) and the process data category (PC003).

[0070] The computer 11 extracts the binary relation between the assembly process (T) and the part (γ) from the relational database 18, and also uses the item number (PC001) of the child data classification of the part (γ) as the item database 19 The item data category (PC001) is read, and the part data ( _Ί ) is extracted from the item database 19 based on the product number (γ) and the item data category ( _ΡC001 ). The computer 11 extracts the binary relationship between the assembly process (Τ) and the line (ε) from the relational database 18, and also sets the resource number (PC004) of the child data classification of the line (ε) as the resource data base. Replaced with 22 resource data classification (PC004), part number (ε) and resource data classification (PC004) ) And the line (ε) data is extracted from the resource database 22. The computer 1 1 extracts the binary relation between the assembly process (Τ) and the tool (Θ) from the relational database 18, and sets the resource number (PC004) of the child data classification of the tool (Θ) to the resource in the resource database 22. The data is replaced with the data category (PC004), and the tool (Θ) data is extracted from the resource database 22 based on the product number (Θ) and the resource data category (PC004).

[0071] When various binary relations between production elements are extracted from the relational database 18 and various production elements forming a binary relation are extracted from the type database 17, the computer 11 1 has the binary relations. By referring to the parent data category of the first production element and the child data category of the second production element to be formed, the various two 2 extracted by combining the production elements of the same data category in the binary relationship Integrate term relationships. Specifically, the binary relationship between warehouse (Β) and product (G), the binary relationship between product (G) and assembly drawing (R), and the relationship between product (G) and assembly process (Τ). Among the item relationships, the product (G) is judged to be the same and common production factor from the data classification (PC001) and the product number (G), and the product (G) is combined in the two terms relationship, and the warehouse (Β) The product (G) is connected to the lower level, and the assembly drawing (R) and assembly process (Τ) are connected in parallel to the lower level of the product (G).

[0072] Next, the binary relationship between the assembly process (Τ) and the part (γ), the binary relationship between the assembly process (Τ) and the line (ε), the assembly process (Τ) and the tool (Θ) Among the two terms, the assembly process (Τ) is judged as the same common production element from the data classification (PC003) and the part number (Τ), and the assembly process (Τ) is combined in these two terms to assemble The part (γ), the line (ε), and the tool (Θ) are connected in parallel to the lower part of the process (Τ). Furthermore, the system of warehouse (Β), product (G), assembly drawing (R), assembly process (Τ) and assembly process (Τ), part (γ), line (ε), tool (Θ) Of these, the assembly process (Τ) is judged to be the same production element from the data classification (PC003) and the part number (Τ), and the assembly process (Τ) is combined in those systems. As a result, the warehouse (Β) is placed at the top, the product (G) is located immediately below it, and the assembly drawing (R) and assembly process (Τ) are located immediately below the product (G). A system (technical information system) in which parts (γ), lines ( _ε ), and tools (Θ) are located immediately below (ii) is integrated, and these binary relationships are integrated (binary relationship integration means).

[0073] When the binary relations are integrated, the computer 1 1 incorporates each production element into the system based on the integrated binary relations, and each of the plurality of production elements is moved from the superordinate concept toward the subordinate concept. Generate a production system that leads to a series (production system generation means). In the created production system, as shown in Fig. 5, the warehouse (B) is at the top, and products (G), assembly drawings (R), assembly processes (T), parts (γ), (Ε) and tools (Θ) are arranged. The computer 11 stores the production system of the generated article (1) in a storage device or a hard disk (production system storage means), and outputs the production system of the generated article (1) through the output device (production system output) means). After creating the production system for the article (1), the production system for the article (2) to the article (η) is created, and the production system for the created article (2) to the article (η) is stored in the storage device or It can be stored on a hard disk (production system storage means), and any of the production systems of created articles (1) to articles (η) can be output via an output device (production system output means). In creating a new product production system, not only can existing production factors and binary relationships be used, but also a variety of newly defined production factors can be used. The binary relation of can be used.

FIG. 6 is a diagram showing the divisional production system output to each of the divisions 12, 13, 14, and 15. In this system, 10 is output only from the output devices installed in each department 12, 13, 14, 15 as the production elements represented by solid lines in Fig. 6, and the production elements represented by dotted lines are output in principle. I can't. The computer 1 1 transfers the entire production system created to the terminal devices installed in each department 12, 13, 14, 15, and based on the department numbers (1, 2, 3, 4), The production system for each department formed from only the necessary production factors for each of 13, 14, 15 is displayed on the display installed in each department 12, 13, 1 4, 15 (the production system for each department), and the department A different production system is printed on the printers installed in each department 12, 13, 14 and 15 (division-specific production system output means).

[0075] For example, as shown in FIGS. 1 and 6, the display installed in the design department 12 has a product (G), assembly drawing (R), part (γ), line with department number 1 set. The production system of the article (1) formed from (ε) is displayed, the warehouse (Β) with department number 4 set, the assembly process (Τ) with department number 2 set, and the department number 2, Tools set to 3 (Θ) are not displayed. Product (G), assembly drawing (R), assembly process (Τ), part (γ), line (ε), tool (Θ) with division number 2 set on the display installed in manufacturing department 13 The production system of the product (1) formed from is displayed, and the warehouse (Β) with department number 4 is not displayed . In addition, the display installed in the purchasing department 14 displays the production system of goods (1) formed from products (G), parts (γ) and tools (Θ) with department number 3 set. Warehouses with department number 4 (番号), assembly drawings (R) and lines (ε) with department numbers 1 and 2 and assembly processes (Τ) with department number 2 are not displayed. . The display installed in the logistics department 15 displays the production system of goods (1) formed from warehouses (倉庫) and products (G) with department numbers 4 set. , 3 set assembly drawing (R), assembly process (Τ), part (γ), line (Θ), tool (ε) is not displayed. However, in each department 12, 13, 14, and 15, it is possible to select the entire display and to display the entire production system on the display with the power S.

FIG. 7 is a diagram showing a list of the start date and the end date of each production factor. Figure 7 shows the period from January 1 to September 30, 2005. With this system 10, it is possible to create a production system at an arbitrary point in time. For example, as shown in Fig. 7, when an instruction to generate a production system on February 15 or May 15 is issued via the input device, computer 1 1 will start and end the binary relationship. While referring to the database, we extracted various binary relations that will form the production system on February 15th and May 15th from the relational database 18, while referring to the start date and end date of the production factor. Then, the production factors that form the extracted binary relationship are extracted from the first to fifth type databases 19, 20, 21, 22, 22, and 23. Next, the computer 1 1 integrates the extracted binary relations and connects the various extracted production elements in a series from the superordinate concept to the subordinate concept in accordance with the integrated binary relation. The production system of goods (1) on the date of The creation of the production system on February 15 is explained as follows.

[0077] When an instruction to generate a production system as of February 15, 2005 is issued via the input device, the computer 1 1 refers to the start date and end date of the production factors and binary relations, and From the relational database 18, the binary relations that form the production system as of the 15th are extracted from the relational database 18, and the production elements that form the extracted binary relations are extracted from the type database 17. The computer 11 extracts the binary relation between the warehouse (Α) and the product (G) from the relational database 18 as logistics department data. Computer 11 replaces the base number (PC005) of the parent data category of the warehouse (Α) with the site data category (PC005) of the site database 23. Based on the part number (A) and the base data classification (PC005), the warehouse (A) data is extracted from the base database 23. Computer 11 replaces the item number (PC001) of the child data category of product (G) with the item data category (PC001) of item database 19, and the item database based on the item number (G) and item data category (PC001) Extract product (G) data from 19.

[0078] The computer 11 extracts the binary relationship between the product (G) and the assembly drawing (P) from the relational database 18 as manufacturing department data, and outputs the product number of the child data category of the assembly drawing (P). Replace (PC002) with the product data category (PC002) in the product database 20, and based on the product number (P) and product data category (PC002), the assembly database (P) Extract data. The computer 11 extracts the binary relation between the product (G) and the assembly process (S) from the relational database 18 and sets the process number (PC003) of the child data category of the assembly process (S) to the process data in the process database 21. The data is read as the category (PC003), and the data of the assembly process (S) is extracted from the process database 21 based on the product number (S) and the process data category (PC003).

[0079] The computer 11 extracts the binary relation between the assembly process (S) and the part (α) from the relational database 18, and also uses the item number (PC001) of the child data classification of the part (α) as the item database 19 The item data classification (PC001) is read, and the part (α) data is extracted from the item database 19 based on the part number) and the item data classification (Ρ C001). The computer 11 extracts the binary relationship between the assembly process (S) and the line (δ) from the relational database 18, and sets the resource number (PC004) of the child data classification of the line (δ) to the resource data in the resource database 22. The term (PC004) is read, and the data of the line (δ) is extracted from the resource database 22 based on the product number (δ) and the resource data category (PC004).

[0080] The computer 11 has a binary relationship between the warehouse (Α) and the product (G), a binary relationship between the product (G) and the assembly drawing (Ρ), and the relationship between the product (G) and the assembly process (S). Of the binary relationships, the product (G) is judged to be the same production factor from the data category (PC001) and the product number (G), and the product (G) is combined in the binary relationship, and the warehouse (Α) The product (G) is connected to the lower level of the product, and the assembly drawing (Ρ) and the assembly process (S) are connected in parallel to the lower level of the product (G). Next, of the binary relationship between the assembly process (S) and the part (α), and the binary relationship between the assembly process (S) and the line (δ), the data classification (PC003) and the part number (S) The assembly process (S) is determined to be the same common production factor, and the assembly process (s) is combined in the binary relation between them, and the parts (α) and lines (δ) are subordinate to the assembly process (s). Are connected in parallel.

. In addition, the system of warehouse (Α), product (G), assembly drawing (Ρ), assembly process (S) and assembly process (S), component (α), line (δ), data classification The assembly process (S) is judged as the same common production element from (PC003) and the product number (S), and the assembly process (S) is combined in these systems. As a result, the warehouse (Α) is placed at the top, the product (G) is positioned immediately below it, and the assembly drawing (Ρ) and assembly process (S) are positioned immediately below the product (G). A system (technical information system) in which parts and lines (δ) are located immediately below (S) is constructed, and these binary relationships are integrated (binary relationship integration means).

[0081] When the binary relationship is integrated, the computer 11 incorporates each production element into a system based on the integrated binary relationship, and a production system in which a plurality of various production elements are connected from the superordinate concept to the subordinate concept. Generate (production system generation means). In the created production system, as shown in Fig. 7, the warehouse (Α) is at the top, and products (G), assembly drawings (Ρ), assembly processes (S), parts (α), (Δ) are lined up.

Next, the generation of the production system on May 15 will be described as follows. When the production system is instructed through the input device on May 15, 2005, the computer 11 refers to the production element and the start date and end date of the binary relation. The binary relations that currently form the production system are extracted from the relational database 18, and the production elements that form the extracted binary relations are extracted from the type database 17.

[0083] The computer 11 extracts the binary relation between the warehouse (Α) and the product (G) from the relational database 18 as the logistics department data. Computer 11 replaces the base number (PC005) of the parent data category of the warehouse (Α) with the base data category (PC005) of the base database 23, and based on the product number (Α) and the base data category (PC005)! / Then, the warehouse (Α) data is extracted from the base database 23. Computer 11 replaces the item number (PC 001) in the child data category of product (G) with the item data category (PC001) in item database 19, and the item database based on the item number (G) and item data category (PC001). Extract product (G) data from 19.

[0084] The computer 11 combines the product (G) from the relational database 18 as manufacturing department data. Extract the binary relationship with the drawing (Q), replace the product number (PC002) in the child data category of the assembly drawing (Q) with the product data category (PC002) in the product database 20, and replace the product number ( Based on Q) and the product data category (PC002), extract the data of the assembly chart (Q) from the product database 20. The computer 11 extracts the binary relation between the product (G) and the assembly process (S) from the relational database 18 and sets the process number (PC003) of the child data category of the assembly process (S) in the process database 21. Read the data classification (PC003), and extract the assembly process (S) data from the process database 21 based on the part number (S) and the process data classification (PC003).

[0085] The computer 11 extracts the binary relation between the assembly process (S) and the part (/ 3) from the relational database 18, and uses the item number (PC001) of the child data classification of the part (/ 3) as the item data. Based on the item data classification (PC001) of the base 19 and based on the part number (/ 3) and the item data classification (PC001), the part (β) data is extracted from the item database 19. The computer 11 extracts the binary relation between the assembly process (S) and the line (ε) from the relational database 18, and sets the resource number (PC004) of the child data classification of the line (ε) to the resource data in the resource database 22. The term (PC004) is read, and the line (ε) data is extracted from the resource database 22 based on the product number (ε) and the resource data category (PC004). The computer 11 extracts the binary relation between the assembly process (S) and the tool (Θ) from the relational database 18, and uses the resource number (PC004) of the child data category of the tool (Θ) as the resource data of the resource database 22. The term (PC004) is read, and the tool (Θ) data is extracted from the resource database 22 based on the product number (Θ) and the resource data category (PC004).

[0086] The computer 11 has a binary relationship between the warehouse (Α) and the product (G), a binary relationship between the product (G) and the assembly drawing (Q), and a relationship between the product (G) and the assembly process (S). Of the binary relationships, the product (G) is judged to be the same production factor from the data category (PC001) and the product number (G), and the product (G) is combined in the binary relationship, and the warehouse (Α) The product (G) is connected to the lower level of the product, and the assembly drawing (Q) and the assembly process (S) are connected in parallel to the lower level of the product (G). Next, the binary relationship between the assembly process (S) and the part (/ 3), the binary relationship between the assembly process (S) and the line (ε), and the binary term between the assembly process (S) and the tool (Θ) Of the relationships, the assembly process (S) is determined as the same production element from the data classification (PC003) and the part number (S), and the assembly process (S) is combined in the two-term relationship, and the assembly process is performed. Under (S) The part (β), line (e) and tool (Θ) are connected in parallel. Furthermore, warehouse (A), product (G), assembly drawing (Q), assembly process (S) system and assembly process (S), parts (/ 3), line (ε), tool (Θ) system and Among them, the assembly process (S) is judged as the same production element from the data classification (PC003) and the product number (S), and the assembly process (S) is combined in those systems. As a result, the warehouse (Α) is placed at the top, the product (G) is located immediately below it, and the assembly drawing (Q) and assembly process (S) are located immediately below the product (G). Build a system (technical information system) where parts (β), lines (e), and tools (Θ) are positioned immediately below the assembly process (S), and integrate these binary relationships (binary relationship integration means) ).

[0087] When the binary relationship is integrated, the computer 11 incorporates each production element into the system based on the integrated binary relationship, and a production system in which a plurality of various production elements are connected from the superordinate concept toward the subordinate concept. Generate (production system generation means). In the created production system, as shown in Fig. 6, the warehouse (A) is the highest, and the products (G), assembly drawings (Q), assembly processes (S), parts (/ 3), Lines (ε) and tools (Θ) are arranged.

[0088] The production system creation system 10 and the production system creation method extract various types of production elements necessary for creating a production system from a plurality of type databases 17 in which production elements are classified and stored for each type. Extracting various binary relations from the relational database 18, integrating multiple binary relations of different types, and subtracting those production elements extracted from the type database 17 from its superordinate concept according to the integrated binary relations Since a production system corresponding to each article is created by connecting them in a series toward the concept, multiple types of production elements of different types can be obtained by using the binary relation formed from the first and second production elements. A wide variety of production systems can be created by freely combining them.

[0089] The production system creation system 10 and the production system creation method store the start date of the production element (when the production system of the production element is formed) and the end date of the production element (when the production element leaves the production system) Thus, the production factors can be managed from the past to the present, and in time series, the binary relation start date (when the binary relation production system is formed) and the binary relation end date (binary relation) ), The binary relations can be managed from the past to the present and managed in a time series, so production at any point in the past, not just the present. A scheme can be created now. Production system creation system 10 and In the production system creation method, each production element is assigned to the first to fifth type databases 19, 20, 21, 22 and 23 according to the first to fifth type numbers set to them. , 20, 21, 22, 23, so each production element that can be shared by Xiamen 12, 13, 14, 15 according to the 1st to 5th type databases 1 9, 20, 21, 22, 23 Can be managed centrally for each type and the production elements can be managed in each department 12, 13, 14, 15 it can.

[0090] The production system creation system 10 and the production system creation method are as follows. Each department 12, 13, 14, 15 shares the relational database 18 and the first to fifth type databases 19, 20, 21, 22, 22, 23. From the production factors stored in these type databases 19, 20, 21, 22, 22, 23, a production system can be created at any point in time that each department 12, 13, 14, 15 can share. And the first to fifth type databases 19, 20, 21, 22 and 23 to provide the created production system in real time to each department 12, 13, 14, 15 while managing the production system in an integrated manner. be able to. In addition, the production system creation system 10 and the production system creation method are based on divisions 1 to 4 (numbers 1 to n) assigned individually to production factors. Since the production system for each department formed from only the necessary production elements is output every 15th, production elements that are not required to be displayed in each department 12, 13, 14, 15 can be excluded from the production system. Each department 12, 13, 14, and 15 can provide a real-time production system with high utility value and ease of use. The production system creation system 10 and the production system creation method allow each department 12, 13, 14, 15 to use a production system created from only the necessary production elements. Each department 12, 13, 14 , 15 working efficiency can be improved.

FIG. 8 is a diagram showing another example of various production elements stored in the type database 17, and FIGS. 9 and 10 are binary relations between the production elements stored in the relational database 18. It is a figure which shows another example of a staff. FIG. 11 is a diagram for explaining another example of the binary relation integration performed by the computer 11. Figures 8 to 11 show the status of September 30, 2005. In the embodiment shown in FIGS. 8 to 11, some of the production elements stored in the main file of the type database 17 are retroactively changed (modified) (first modifying means), and the relational database 18. Part of the first or second production element stored in the main file Changed (modified) retroactively (second modification means), production element start date (production element production system formation time) and production element end date (production element departure from production system) ) Is retroactively changed (first change means), the binary relationship start date (when the binary relationship production system is formed), and the binary relationship end date (when the binary relationship relationship leaves the production system) ) Has been retroactively changed (second change means). In this system 10, each production factor stored in the type database 17 can be retroactively changed via the input device, and the first production factor and the second production factor stored in the relational database 18 can be reduced. One can be retroactively modified. The modification of the production factor and the modification of the first or second production factor include the change, the effort P, and the deletion.

[0092] An example of the change in production factors stored in the type database 17 is shown in Fig. 2, from warehouse (B) to warehouse (C), assembly process (T) to assembly process (U), and parts. The case where (γ) is changed to a component) and the tool (Θ) is changed to a tool (λ) will be described as an example as follows. The start date of the production factor and the end date of the production factor are as follows: the assembly drawing (Ρ) end date is March 31st, and February 28th is the assembly drawing (Q) start date On March 1st, the assembly drawing (Q) is completed. The power of the month 31st of March is changed to June 30, and the power of the assembly drawing (R) is changed to 1st of July. . The start date for binary relations and the end date for binary relations have been changed along with changes in production factors, binary relations, and start and end dates of production elements.

[0093] When a change is selected from the items displayed on the display, the production element change area, department division input area, production element start date input area, production element end date input area, relationship change area, The binary relation start date input area and binary relation end date input area are displayed. Enter the warehouse (Β) before the change in the old base area of the production element change area, and enter the new warehouse (C) and its product number (C) (type identification number) in the new base area. Enter the division (4) of the warehouse (C) in the division division input area corresponding to the base area (1). Next, the start date and end date of the warehouse (C) are input to the start date input area and the end date input area via the input device. After entering these data, the change instruction of the production factor is inputted from the input device, the computer 11, the data in the data warehouse stored in the site database ² 3 main file (beta) Warehouse (C) Rewrite to Computer 11 is the resource data category (PC005) of warehouse (C) and department Warehouse data such as number (4), product number (C) identifying warehouse (C), start date of warehouse (C) (June 1, 2005), end date of warehouse (C) (1), etc. Store in database 23 main file. The warehouse data includes the contents of the warehouse (C) (warehouse name, warehouse location, etc.). The computer 11 stores and saves the data of the warehouse (B) in a subfile of the base database 23.

[0094] The assembly process (T) before the change is entered in the old process area (1), and the assembly process (U) after the change and its product number (U) (type identification number) are entered in the new process area (1). At the same time, the department category (2) of the assembly process (U) is entered in the department category entry area corresponding to the new process area (1). Next, the start date and end date of the assembly process (U) are input to the start date input area and the end date input area via the input device. When a production element change instruction is input from the input device, the computer 11 rewrites the data of the assembly process (T) stored in the main file of the process database 21 with the data of the assembly process (U). The computer 11 displays the assembly process (U) process data classification (PC003), department number (2), part number (U) that identifies the assembly process (U), and start date of the assembly process (U) (June 2005 1) and the assembly process data such as the end date (1) of the assembly process (U) is stored in the main file of the process database 21. The assembly process data includes the contents of the assembly process (U) (process details, assembly location, usage instructions, etc.). The computer 11 stores and saves the assembly process (T) data in a subfile of the process database 21.

[0095] Enter the part (γ) before the change in the old item area (1) and the part after the change in the new process area (1)

) And its product number) (type identification number) and the department classification (1, 2, 3) of the part (7)) in the department classification input area corresponding to the new process area (1). Next, the start date and end date of the part () are input to the start date input area and end date input area via the input device. When the production element change instruction is input from the input device, the computer 11 rewrites the data of the part ( _Ί ) stored in the main file of the item database 19 with the data of the part (η). The computer 11 uses the item data category (PC001) of the part (7)), the department number (1, 2, 3), the part number (7)) that identifies the part (7)), and the start date of the part (7)) (June 1, 2005) and the part data such as the end date (1) of the part (7)) are stored in the main file of the item database 19. The part data includes the contents of the part (name, production location, usage instructions, durable years, amount of money, delivery date, etc.). The computer 11 stores the part (γ) data Store and save in subfile of eye database 19.

[0096] Enter the old tool (Θ) in the old resource area (1) and the new tool in the new resource area (1)

(λ) and its product number (λ) (type identification number) are entered, and the department classification (1, 2) of the tool (λ) is entered in the department classification input area corresponding to the new resource area (1). Next, the start date and end date of the tool (λ) are input to the start date input area and the end date input area via the input device. When the production element change instruction is input from the input device, the computer 11 rewrites the data of the tool (Θ) stored in the main file of the resource database 22 with the data of the tool (λ). The computer 11 uses the resource data classification (PC004) of the tool (λ), the division number (1, 2, 3), the part number (λ) that identifies the tool (λ), and the start date of the tool (λ) (June 2005) Tool data such as the end date (1) of the tool (λ) and the tool (λ) are stored in the main file of the resource database 22. The tool data includes the contents of the tool (λ) (the use of the tool, the price, the durability, etc.). The computer 11 stores and saves the tool (Θ) data in a subfile of the resource database 22. Note that the departmental numbers of the line (δ) and the line (ε) are changed from (1, 2) to (1, 2, 3).

[0097] The first production factor and the second production factor were changed with the change of the production factor on September 30, 2005, and the binary relation between the production factors was changed accordingly. In this embodiment, the binary relationship between the warehouse (Β) and the product (G) is the binary relationship between the warehouse (C) and the product (G), and the product (G) and the assembly process (Τ) The binary relationship is the binary relationship between the product (G) and the assembly process (U), and the binary relationship between the assembly process (Τ) and the line (ε) is the 2 relationship between the assembly process (U) and the line (ε). The binary relationship between the assembly process (Τ) and the part (γ) is the binary relationship between the assembly process (U) and the line (7)), and the assembly process (Τ) and the tool (Θ) The binary relationship is changed to the binary relationship between the assembly process (U) and the tool (λ). An example of changing the first and second production factors stored in the relational database 18 is as follows.

[0098] Of the relationship change areas displayed on the display, enter the old warehouse (Β) in the old first production factor area (1) and the new warehouse (生産) in the new production factor area (1). Enter C), enter the product number (C) (type identification number) that identifies the warehouse (C) as the parent product number, and the base number (PC005) (fifth type number) as the parent data category. Next, enter the department category (4) in the department category entry area corresponding to the new first production factor area (1), and enter the new first production factor area (1). Enter the start date (June 1, 2005) and end date (-) of the binary relationship between warehouse (C) and product (G) in the corresponding relationship start date input area and relationship end date input area . After inputting these data, when a change instruction for binary relations is input from the input device, the computer 11 stores the binary relation between the warehouse (B) and the product (G) stored in the main file of the relational database 18. To a binary relationship between warehouse (C) and product (G). The binary relation between the warehouse (B) and the product (G) is stored and saved in a subfile of the relational database 18. The relational database 18 includes the part number (C) that identifies the warehouse (C) as the parent part number (first production factor), the base number (PC005) (fifth type number) that is the parent data category of the warehouse (C), the child The product number (G) that identifies the product (G) is stored as the product number (second production factor), and the item number (PC001) (first type number) that is a child data classification of the product (G) is stored. As a result, warehouse (C) and product (G) are linked, and warehouse (C) and product (G) are linked based on the binary relationship.

[0099] Enter the assembly process (T) before the change in the old second production element area (1), and enter the assembly process (U) after the change in the new second production element area (1). Enter the part number (U) (type identification number) that identifies the assembly process (U) and the process number (PC003) (third type number) as the child data category. Next, enter the department classification (2) in the department classification input area corresponding to the new second production element area (1), the relation start date input area and the relation end date corresponding to the new second production element area (1). In the input area, enter the start date (June 1, 2005) and end date (one) of the binary relationship between product (G) and assembly process (U). When an instruction to change the binary relationship is input from the input device, the computer 11 converts the binary relationship between the product (G) and the assembly process (T) stored in the main file of the relationship database 18 to the product (G). Change to binary relationship with assembly process (U). The binary relationship between the product (G) and the assembly process (T) is stored and stored in a subfile of the relational database 18. The relational database 18 includes the product number (G) that identifies the product (G) as the parent product number (first production factor), the item number (PC001) (first type number) that is the parent data classification of the product (G), the child The part number (U) that identifies the assembly process (U) and the process number (PC003) (third type number) that is a sub-data category of the assembly process (U) are stored as the part number (second production factor). As a result, the product (G) and the assembly process (U) are linked to the force S, and the product (G) and the assembly process (U) are linked based on the binary relationship.

[0100] It should be noted that the display is assembled with the change from the assembly process (T) to the assembly process (U). A message is displayed to change the binary relation between the standing process (T) and the line (ε) to the binary relation between the assembly process (U) and the line (ε). Accordingly, the start date of the binary relationship between the assembly process (U) and the line (ε) in the relationship start date input area and the relationship end date input area corresponding to the new second production factor area (1) (June 2005) Enter the month 1) and end date (-). Computer 11 changes the binary relationship between assembly process (Τ) and line (ε) stored in the main file of relational database 18 to the binary relationship between assembly process (U) and line (ε) To do. The binary relation between the assembly process (Τ) and the line ( _ε ) is stored and saved in a subfile of the relational database 18. The relational database 18 contains the part number (U) that identifies the assembly process (U) as the parent part number (first production factor), the process number (PC003) (third type number) that is the parent data category of the assembly process (U) ), The product number (ε) that identifies the line (ε) as the child product number (second production factor), and the resource number (PC004) (fourth type number) that is the child data classification of the line (ε) are stored. As a result, the assembly process (U) and the line (ε) are linked to the force S, and the assembly process (U) and the line (ε) are linked based on the binary relation.

Enter the old part (γ) in the old second production factor area (2) and the new second production factor area (2).

Enter the changed part (7)) in), specify the part number (7)) (type identification number) as the child part number, and the item number (PC00 1) (first Type). Next, enter the department classification (2) in the department classification input area corresponding to the new second production element area (2), and end the relationship start date input area corresponding to the new second production element area (2). In the date input area, enter the start date (June 1, 2005) and end date (one) of the binary relationship between the assembly process (U) and the part (η). When an instruction to change the binary relation is input from the input device, the computer 1 1 converts the binary relation between the assembly process (Τ) and the part (7) stored in the main file of the relation database 18 into the assembly process. Change to a binary relationship between (U) and part (η). The binary relation between the assembly process (Τ) and the part (γ) is stored and saved in a subfile of the relational database 18. The relationship database 1 8 includes the product number (U) that identifies the assembly process (U) as the parent product number (first production factor), and the process number (PC003) (third type) that is the parent data category of the assembly process (U). Item number (PC001) (first type number) that is a sub-data segment of the part number (7]) and the part (7)) that identifies the part (7)) as the subpart number (second production factor) Stored. As a result, the assembly process (U) and the part (η) are linked to the force S, and the assembly process (U) and the part (η) are linked based on the binary relation. To do.

[0102] Enter the old tool (Θ) in the old second production element area (4), enter the new tool (λ) in the new second production element area (4), and enter the tool ( Enter the product number (λ) (type identification number) that identifies λ) and the resource number (PC004) (fourth type number) as a child data category. Next, enter the department category (2) in the department category input area corresponding to the new second production factor area (4), and the relationship start date entry area and relationship end corresponding to the new second production factor area (4). In the date input area, enter the start date (June 1, 2005) and end date (one) of the binary relationship between the assembly process (U) and the tool (λ). When an instruction to change the binary relationship is input from the input device, the computer 11 converts the binary relationship between the assembly process (Τ) and the tool (Θ) stored in the main file of the relationship database 18 into the assembly process (U ) And tool (λ), and delete the binary relationship between assembly process (S) and tool (Θ). The binary relation between the assembly process (Τ) and the tool (Θ) and the binary relation between the assembly process (S) and the tool (Θ) are stored and saved in a subfile of the relational database 18. In the relational database 18, the assembly process (U) is identified as the parent product number (first production factor), the product number (U), and the process number (PC003) (third type number) that is the parent data classification of the assembly process (U) The product number (λ) for specifying the tool (λ) as the child product number (second production factor), and the resource number (PC004) (fourth type number), which is the child data classification of the tool (λ), are stored. As a result, the assembly process (U) and the tool (λ) are linked to the force S, and the assembly process (U) and the tool (λ) are linked based on the binary relation! The binary relationship between the warehouse (C) and the product (G) is handled as data in the logistics sector 15 by sector classification (4). Binary relationship between product (G) and assembly process (U), binary relationship between assembly process (U) and line (ε), binary relationship between assembly process (U) and line (7)), assembly The binary relationship between the process (U) and the tool (λ) is handled as data of the manufacturing department 13 by the department classification (2).

[0103] Based on Fig. 11, after the production factors and binary relationships were changed, the computer 11 integrated multiple binary relationships and the production system of goods (1) on September 30, 2005 The generation and are explained as follows. Note that the production system shown in Fig. 11 was generated on September 30, 2005. When the production system and the binary relation are changed, and the production system is instructed via the input device, the computer 11 uses the changed new production element to change the first and (2) While integrating all binary relationships including new binary relationships formed from production factors, Generate the production system again. Specifically, it is as follows.

[0104] When an instruction to generate a production system as of September 30, 2005 is issued via the input device, the computer 11 refers to the production element and the start date and end date of the binary relation, and The binary relations that form the production system as of today are extracted from the relational database 18, and the production elements that form the extracted binary relations are extracted from the type database 17. The computer 11 extracts the binary relation between the warehouse (C) and the product (G) from the relational database 18 as logistics department data. Computer 11 replaces the base number (PC005) of the parent data classification of warehouse (C) with the base data classification (PC005) of base database 23, and based on the part number (C) and base data classification (PC005)! / Then, the data of the warehouse (C) is extracted from the base database 23. Computer 11 replaces the item number (PC 001) in the child data category of product (G) with the item data category (PC001) in item database 19, and the item database based on the item number (G) and item data category (PC001). Extract product (G) data from 19.

[0105] The computer 11 extracts the binary relation between the product (G) and the assembly drawing (R) from the relational database 18 as manufacturing department data, and outputs the product number of the child data classification of the assembly drawing (R). Replace (PC002) with the product data category (PC002) in the product database 20, and based on the product number (R) and product data category (PC002), the assembly database (R) Extract data. The computer 11 extracts the binary relationship between the product (G) and the assembly process (U) from the relational database 18 and sets the process number (PC003) of the child data classification of the assembly process (U) in the process database 21. The data is read as the data classification (PC003), and the data of the assembly process (U) is extracted from the process database 21 based on the product number (U) and the process data classification (PC003).

[0106] The computer 11 extracts the binary relation between the assembly process (U) and the part) from the relational database 18, and uses the item number (PC001) of the child data classification of the part (7)) as the item database 19 The item data classification (PC001) is read, and the part (η) data is extracted from the item database 19 based on the part number (7)) and the item data classification (PC001). The computer 11 extracts the binary relation between the assembly process (U) and the line (ε) from the relational database 18, and also sets the resource number (PC004) of the child data classification of the line (ε) based on the resource data. The resource data classification (PC004) of the resource 22 is read, and the data of the line (ε) is extracted from the resource database 22 based on the product number (ε) and the resource data classification (PC004). The computer 1 1 extracts the binary relation between the assembly process (U) and the tool (λ) from the relational database 18 and sets the resource number (PC004) of the child data category of the tool (λ) to the resource in the resource database 22. Read the data category (PC004), and extract tool (λ) data from the resource database 22 based on the part number (λ) and the resource data category (PC004).

[0107] Extracting various binary relations between production factors from relational database 18 and extracting various multiple production elements forming binary relations from type database 17; computer 11 is binary relational Refer to the parent data category of the first production element and the child data category of the second production element that form the Integrate binary relationships. Specifically, the binary relationship between warehouse (C) and product (G), the binary relationship between product (G) and assembly drawing (R), and the relationship between product (G) and assembly process (U). Of the item relationships, the product (G) is judged to be the same and common production factor from the data classification (PC001) and the product number (G), and the product (G) is combined in these two item relationships, and the warehouse (C) The product (G) is connected to the lower part, and the assembly drawing (R) and assembly process (U) are connected in parallel to the lower part of the product (G).

[0108] Next, the binary relationship between the assembly process (U) and the part (η), the binary relationship between the assembly process (U) and the line (ε), the assembly process (U) and the tool (λ) Of the binary relationships, the assembly process (U) is judged as the same production element from the data classification (PC003) and the part number (U), and the assembly process (U) is combined in these binary relationships to assemble The part (η), the line (ε), and the tool (λ) are connected in parallel to the lower part of the process (U). In addition, the data of the warehouse (C), product (G), assembly drawing (R), assembly process (U) system and assembly process (U), parts), line), tool (λ) system Assume that the assembly process (U) is the same production element from (PC 003) and the part number (U), and the assembly process (U) is combined in these systems. As a result, the warehouse (C) is placed at the top, the product (G) is positioned immediately below it, and the assembly drawing (R) and assembly process (U) are positioned immediately below the product (G). Build a system (technical information system) in which parts (η), lines ( _ε ), and tools (λ) are located immediately below (U), and integrate these binary relationships (binary relationship integration means) .

[0109] Computer 1 1 integrates binary relations, and each production into a system based on the integrated binary relations. Incorporating elements, a production system is created in which various production elements are linked together from the superordinate concept to the subordinate concept (production system generation means). In the created production system, as shown in Fig. 11, the warehouse (C) is the highest, and the products (G), assembly drawings (R), assembly processes (U), parts (7)), Lines (ε) and tools (λ) are arranged. The computer 11 stores the production system of the article (1) generated after changing the production factors and binary relations in a storage device or hard disk (production system storage means), and outputs the production system of the generated article (1) as an output device. Output (production system output means).

[0110] Fig. 12 is a diagram showing the sectoral production system output to each sector 12, 13, 14, 15 after the production factors and binary relations are changed. In this system, only the production elements represented by the solid lines in Fig. 12 are output from the output devices installed in the respective departments 12, 13, 14, and 15, and the production elements represented by the dotted lines are not output in principle. The computer 11 transfers the entire production system created to the terminal equipment installed in each department 12, 13, 14, 15, and is necessary for each department based on the department number (1, 2, 3, 4). The production system for each department formed only from the production factors is displayed on the display installed in each department 12, 13, 14, 15 (production system for each department output means), and the production system for each department is displayed for each department 12, Print on printers installed at 13, 14 and 15 (Production system output by department).

[0111] As shown in Fig. 12, the display installed in the design department 12 has a product (G), assembly drawing (R), part (7)), line (ε ), The production system of the product (1) formed from the tool (λ) is displayed, the warehouse (C) with department number 4 is set, and the assembly process (U) with department number 2 is shown Not. The display installed in the manufacturing department 13 includes products (G), assembly drawings (R), assembly processes (U), parts "), lines (ε), and tools (λ) with department number 2. The production system of the formed article (1) is displayed, and the warehouse (C) with department number 4 is not displayed, and the department number 3 is set for the display installed in purchasing department 14. Warehouse (C), department by category, where the production system of goods (1) formed from the finished product (G), parts (7)), line) and tools (λ) is displayed. Assembly drawing (R) with numbers 1 and 2 and assembly process (U) with division number 2 are not displayed.Department number 4 is set on the display installed in logistics department 15. The production system of goods (1) formed from the warehouse (C) and product (G) is displayed. Assembly drawings (R), assembly processes (U), parts (7)), lines (ε), and tools (λ) with numbers 1, 2, and 3 are not displayed. However, each department 12, 13, 14, 15 can display the entire production system on the display by selecting the entire display.

FIG. 13 is a diagram showing a list of the start date and end date of each production factor after the production factor and binary relations are changed. In Fig. 13, as in Fig. 7, the period is from January 1 to September 30, 2005. When the production system generation instructions for March 15 and June 15 are instructed via the input device, the computer 11 refers to the start date and end date of the binary relationship, and starts the relationship database 18 to March. On the 15th and June 15th, we extracted a variety of binary relations that will form the production system, while referring to the start and end dates of the production elements, and each production that forms the extracted binary relations. Elements are extracted from the 1st to 5th type databases 19, 20, 21, 22 and 23. Next, the computer 11 integrates the extracted binary relations and, according to the integrated binary relations, connects the various extracted production factors from the superordinate concept to the subordinate concepts, and then connects them in series. Create a production system for goods (1) on those dates.

[0113] The generation of the production system on March 15 is explained as follows. When an instruction to generate a production system as of March 15, 2005 is given via the input device, the computer 1 1 refers to the start date and end date of the production factors and binary relations, and as of March 15, 2005. Then, the binary relations that form the production system are extracted from the relational database 18 and the production elements that form the extracted binary relations are extracted from the type database 17. The computer 11 extracts the binary relationship between the warehouse (Α) and the product (G) from the relational database 18 as the logistics department data. Computer 11 replaces the base number (Ρ C005) of the parent data category of warehouse (Α) with the base data category (PC005) of base database 23, and based on the product number (番) and the base data category (PC005)! / Then, the warehouse (Α) data is extracted from the base database 23. Computer 11 reads the item number (PC001) in the child data category of product (G) into the item data category (PC001) in item database 丄₉ , and the item based on the item number (G) and the item data category (PC001). Extract product (G) data from database 19

[0114] The computer 11 combines the product (G) from the relational database 18 as manufacturing department data. Extract the binary relationship with the drawing (Q), replace the product number (PC002) in the child data category of the assembly drawing (Q) with the product data category (PC002) in the product database 20, and replace the product number ( Based on Q) and the product data category (PC002), extract the data of the assembly chart (Q) from the product database 20. The computer 11 extracts the binary relation between the product (G) and the assembly process (S) from the relational database 18 and sets the process number (PC003) of the child data category of the assembly process (S) in the process database 21. Read the data classification (PC003), and extract the assembly process (S) data from the process database 21 based on the part number (S) and the process data classification (PC003).

[0115] The computer 11 extracts the binary relation between the assembly process (S) and the part (α) from the relational database 18, and also uses the item number (PC001) of the child data classification of the part (α) as the item database 19 The item data classification (PC001) is read, and the part (α) data is extracted from the item database 19 based on the part number) and the item data classification (Ρ C001). The computer 11 extracts the binary relationship between the assembly process (S) and the line (δ) from the relational database 18, and sets the resource number (PC004) of the child data classification of the line (δ) to the resource data in the resource database 22. The term (PC004) is read, and the data of the line (δ) is extracted from the resource database 22 based on the product number (δ) and the resource data category (PC004).

[0116] Computer 11 has a binary relationship between warehouse (倉庫) and product (G), a binary relationship between product (G) and assembly drawing (Q), and a relationship between product (G) and assembly process (S). Of the binary relationships, the product (G) is judged to be the same production factor from the data category (PC001) and the product number (G), and the product (G) is combined in the binary relationship, and the warehouse (Α) The product (G) is connected to the lower level of the product, and the assembly drawing (Q) and the assembly process (S) are connected in parallel to the lower level of the product (G). Next, of the binary relationship between the assembly process (S) and the part (α) and the binary relationship between the assembly process (U) and the line (δ), the assembly is based on the data classification (PC003) and the part number (S). The process (S) is judged as the same common production factor, the assembly process is combined in the binary relationship, and the part (α) and the line (δ) are connected in parallel below the assembly process (S). Geru. Furthermore, the data classification (PC003) among the system of warehouse (Α), product (G), assembly drawing (Q), assembly process (S) and assembly process (S), parts), line (δ) The assembly process (S) is determined as the same production factor from the product number (S) and the assembly number (S), and the assembly process (S) is combined in these systems. As a result, the warehouse (Α) is in the upper position, and the product (G) is positioned in the immediate lower position. In addition, the assembly (Q) and assembly process (S) are positioned immediately below the product (G), and the parts and line (δ) are positioned immediately below the assembly process (S) (technical information system) ) And integrate these binary relationships (binary relationship integration means).

[0117] When the binary relation is integrated, the computer 11 incorporates each production element into the system based on the integrated binary relation, and a production system in which a plurality of various production elements are connected from the superordinate concept to the subordinate concept. Generate (production system generation means). In the created production system, as shown in Fig. 13, the warehouse (Α) is the highest, and products (G), assembly drawings (Q), assembly processes (S), parts), lines (δ) ) Are lined up.

[0118] Next, the generation of the production system on June 15 is explained as follows. When the production system is instructed through the input device on June 15, 2005, the computer 11 refers to the production element and the start date and end date of the binary relation. The binary relations that currently form the production system are extracted from the relational database 18, and the production elements that form the extracted binary relations are extracted from the type database 17. The computer 11 extracts the binary relation between the warehouse (C) and the product (G) from the relational database 18 as logistics department data. Computer 11 replaces the base number (PC005) of the parent data classification of warehouse (C) with the base data classification (PC005) of base database 23, and based on product number (C) and base data classification (PC005)! /, The warehouse (C) data is extracted from the base database 23. Computer 11 reads the item number (PC001) in the child data category of product (G) into the item data category (PC001) in item database 19, and the item database based on the item number (G) and item data category (PC001). Extract product (G) data from 19

[0119] The computer 11 extracts the binary relation between the product (G) and the assembly drawing (Q) from the relational database 18 as the manufacturing department data, and outputs the product number of the child data classification of the assembly drawing (Q). Issue (PC002) is replaced with the product data category (PC002) in the product database 20, and based on the product number (Q) and product data category (PC002), the assembly database (Q) Extract the data. The computer 11 extracts the binary relationship between the product (G) and the assembly process (U) from the relational database 18, and sets the process number (PC003) of the child data category of the assembly process (U) to the process data in the process database 21. Replaced with category (PC003) The assembly process (U) data is extracted from the process database 21 based on the product number (U) and the process data classification (PC003).

[0120] The computer 1 1 extracts the binary relationship between the assembly process (U) and the part) from the relational database 18 and uses the item number (PC001) of the child data category of the part (7)) as the item database. 19 item data classification (PC001) is read, and part (η) data is extracted from the item database 19 based on the item number (7)) and the item data classification (PC001). The computer 1 1 extracts the binary relation between the assembly process (U) and the line (ε) from the relational database 18 and sets the resource number (PC004) of the child data classification of the line (ε) on the resource data basis. The resource data classification (PC004) of the resource 22 is read, and the data of the line (ε) is extracted from the resource database 22 based on the product number (ε) and the resource data classification (PC004). The computer 1 1 extracts the binary relation between the assembly process (U) and the tool (λ) from the relational database 18 and sets the resource number (PC004) of the child data category of the tool (λ) to the resource in the resource database 22. Read the data category (PC004), and extract tool (λ) data from the resource database 22 based on the part number (λ) and the resource data category (PC004).

[0121] Computer 1 1 has a binary relationship between warehouse (C) and product (G), a binary relationship between product (G) and assembly drawing (Q), and product (G) and assembly process (U). Of these two relations, the product (G) is judged to be the same production element from the data classification (PC001) and the part number (G), and the product (G) is combined in the two relations, and the warehouse (C The product (G) is connected to the lower part of), and the assembly drawing (Q) and assembly process (U) are connected in parallel to the lower part of the product (G). Next, the two-term relationship between the assembly process (U) and the part (η), the two-term relationship between the assembly process (U) and the line (ε), and the two terms between the assembly process (U) and the tool (λ) Among the relationships, the assembly process (U) is judged to be the same and common production element from the data classification (PC003) and the part number (U), and the assembly process (U) is combined in these two relations, and the assembly process (U The part (7)), the line (ε), and the tool (λ) are connected in parallel to the lower part of). Furthermore, the system of warehouse (C), product (G), assembly drawing (Q), assembly process (U) and assembly process (U), parts), line (ε), tool (λ) From the data classification (PC003) and the part number (U), the assembly process (U) is judged as the same common production factor, and the assembly process (U) is combined in those systems. As a result, the warehouse (C) is placed at the top, the product (G) is located immediately below it, and the assembly drawing (Q) and assembly process (U) are located immediately below the product (G). Part immediately below (U) A system (technical information system) where the product (]), line (ε) and tool (λ) are located is constructed, and these binary relationships are integrated (binary relationship integration means).

[0122] When the binary relationship is integrated, the computer 11 incorporates each production element into a system based on the integrated binary relationship, and a production system in which various production elements are connected in a series from the superordinate concept to the subordinate concept. Generate (production system generation means). In the created production system, as shown in Fig. 11, the warehouse (C) is the highest, and the products (G), assembly drawings (Q), assembly processes (U), parts (7)), Lines (ε) and tools (λ) are arranged.

[0123] The production system creation system 10 and the production system creation method can change the production factor and the first and second production factors at any point in time from the past to the changed production factor and the first production factor. 1, The second production factor can be used to create a new production system at any point in time from the past. The production system creation system 10 and the production system creation method are capable of centrally managing changes in production factors using the type database 17 and are related to changes in binary relationships due to changes in the first and second production factors. Since it can be centrally managed by database 18, it is not necessary to create and manage the production system by changing the production elements and the first and second production elements for each department 12, 13, 14, and 15. The ability to save labor and labor by changing each of the departments 12, 13, 14 and 15 individually and changing the first and second production factors.

[0124] In addition, the production system creation system 10 and the production system creation method can change the start date and the end date of the production factor at any time from the past to the present, The start date and end date of the binary relationship can be changed at the time, and a new production system from the past to the present time can be created using the changed start date and end date. Can do. In this production system creation system 10 and production system creation method, changes in the start and end dates of production factors can be managed centrally by the type database 17, and the start date and end date of the binary relations can be managed in the relational database. 18 can be centrally managed, and it is not necessary to create and manage the production system by changing the start date and end date for each department 12, 13, 14, and 15. Saves time and effort from being done individually by 12, 13, 14, 15 [0125] Fig. 14 is a diagram showing another example of various production factors stored in the type database 17, and Figs. 15 and 16 are binary relationships between the production factors stored in the relational database 18. It is a figure which shows another example of. FIG. 17 is a diagram for explaining another example of the integration of binary relationships performed by the computer 11. Figures 14 to 17 show the situation as of September 30, 2005. In the embodiment shown in FIGS. 14 to 17, some of the production elements stored in the main file of the type database 17 are deleted (modified) and added (modified) retroactively (first modifying means), Part of the first or second production factor stored in the main file of the database 18 has been deleted (modified) and added (modified) retroactively (second modifying means). An example of the deletion of production elements stored in the type database 17 is explained using the case of deleting assembly drawings (Q), assembly drawings (R), parts (γ), and lines (ε) from the state shown in FIG. Then, it is as follows.

[0126] When deletion is selected from the items displayed on the display, a production element deletion area and a relationship deletion area are displayed on the display. Enter assembly drawing (Q), assembly drawing (R), part (γ), line (ε) in the production element deletion area. After inputting these data in the production element deletion area, when an instruction to delete the production element is input from the input device, the computer 11 sends the assembly drawing (Q) and assembly drawing (R) data to the product database 20. And delete the part (Ί) data from the main file of the item database 19 and the line (ε) data from the main file of the resource database 22. The assembly drawing (Q) and assembly drawing (R) data is stored and saved in a subfile of the product database 20, and the part (Ί) data is stored and saved in a subfile of the item database 19. The data of the line (ε) is stored and saved in a subfile of the resource database 22.

[0127] An example of deleting the binary relation stored in the relational database 18 is as follows. Enter the product (G) and assembly drawing (Q) in the relationship deletion area (1) displayed on the display, enter the product (G) and assembly drawing (R) in the relationship deletion area (2), Enter the assembly process (Τ) and part (γ) in the related deletion area (3). Further, the assembly process (S) and the line (ε) are input to the relationship deletion area (4), and the assembly process (Τ) and the line (ε) are input to the relationship deletion area (5). When these data are entered in each relationship deletion area, the display shows the binary relationship between product (G) and assembly drawing (Q), the binary relationship between product (G) and assembly drawing (R), The binary relationship between the process (T) and the part (γ), the binary relationship between the assembly process (S) and the line (ε), and the binary relationship between the assembly process (Τ) and the line (ε) are displayed. . When an instruction to delete these binary relationships is input from the input device, the computer 1 1 is connected to the binary relationship between the product (G) and the assembly drawing (Q), and between the product (G) and the assembly drawing (R). Term relationship, two-term relationship between assembly process (Τ) and part (γ), two-term relationship between assembly process (S) and line (ε), two terms of assembly process (Τ) and line (ε) Delete the relationship from the main file in the relationship database 18 The binary relations deleted from the main file are stored and saved in a subfile of the relational database 18.

[0128] An example of adding production factors will be described below, taking as an example the case where the inspection process (V) and the inspection standard document (W) are added from the state shown in Fig. 2. When process addition is selected from the types displayed on the display, a process addition area, a department classification input area corresponding to the process addition area, a relation start date input area, and a relation end date input area are displayed on the display. Enter the inspection process (V) and its product number (V) (type identification number) in the process addition area via the input device, enter the division of inspection process (V) in the division input area, and start date Enter the start date and end date of the inspection process (V) in the input area and end date input area. When these data are input, the computer 11 refers to the item, production element, and type number stored in the storage device or hard disk, determines that the inspection process (V) belongs to the process, and enters the inspection process (V). The process data category (PC003) (third type number) is assigned, and based on the entered department category, the department number (1, 2) is assigned to the inspection process (V). The computer 11 includes the process data category (PC003) of the inspection process (V), the departmental number (1, 2), the part number (V) that identifies the inspection process (V), and the start date of the inspection process (V) ( The inspection process data such as the end date (1) of the inspection process (V) on January 1, 2005) is stored in the main file of the process database 21. The inspection process data includes the contents of the inspection process (V) (inspection procedure, inspection time, etc.).

[0129] When adding product is selected from the types displayed on the display, the product addition area, the department classification input area corresponding to the product addition area, the relationship start date input area, and the relationship end date input area are displayed. Is displayed. Enter the inspection standard (W) and its product number (W) (type identification number) in the additional area via the input device, and enter the division of the inspection standard (W) in the input area. , Start date input area Enter the start date and end date of the inspection standard document (W) in the or end date input area. When these data are input, the computer 11 refers to the type, production factor, and type number stored in the storage device or hard disk, and determines that the inspection standard document (W) belongs to the deliverable. The product data classification (PC002) (second type number) is attached to the certificate (W), and the department number (1, 2) is assigned to the inspection standard (W) based on the entered department classification. The computer 11 uses the product data category (PC002), department number (1, 2) of the inspection standard document (W), the part number (W) that specifies the inspection standard document (W), and the inspection standard document (W). The inspection standard data such as the start date (January 1, 2005) and the end date (1) of the inspection standard (W) is stored in the main file of the deliverable database 20. The inspection standard document data includes the contents of the inspection standard document (W) (details of the standard document, department for preparing the standard document, etc.).

[0130] As an example of adding the first and second production factors, the binary relationship between the product (G) and the inspection process (V) and the binary relationship between the inspection process (V) and the inspection standard document (W) The case of adding is described as an example as follows. When adding relation is selected from the types displayed on the display, a relation adding area, a relation start date input area, and a relation end date input area are displayed on the display. Enter the product (G) and inspection process (V) in the relationship addition area (1) of the relationship addition areas, and enter the division (2) in the division classification input area corresponding to the relationship addition area (1). input. Next, the product number (G) that identifies the product (G) as the parent product number (first production factor), the item number (PC001) (first type number) as the parent data category, and the child product number (second production factor) Enter the part number (V) (type identification number) that identifies the inspection process (V), and the process number (PC003) (third type number) as a child data category. In addition, enter the start date (January 1, 2005) and end date (one) of the binary relationship between the product (G) and the inspection process (V) in the relationship start date input area and relationship end date input area. To do. When these data are input, the computer 11 stores the data in the relational database 18. In the relational database 18, the product (G) and the inspection process (V) are linked, and the product (P) and the processing instruction (b) are linked based on the binary relation.

[0131] Enter the inspection process (V) and inspection criteria (W) in the relationship addition area (2), and enter the division (2) in the division input area corresponding to the relationship addition area (2) . Next, the part number (V) that identifies the inspection process (V) as the parent part number (first production factor) and the parent data classification Process number (PC003) (3rd type number), product number (W) (type identification number) that specifies the inspection standard (W) as the child product number (2nd production factor), and product number as the child data category ( PC0 02) (second type number) is entered. In addition, the start date (January 1, 2005) and end date (-) of the binary relationship between the inspection process (V) and the inspection standard document (W) are displayed in the relationship start date input area and the relationship end date input area. input. When these data are input, the computer 11 stores the data in the relational database 18. In the relational database 18, the inspection process (V) and the inspection standard document (W) are linked, and the inspection process (V) and the inspection standard document (W) are linked based on the binary relation. The two-term relationship between the product (G) and the inspection process (V) and the two-term relationship between the inspection process (V) and the inspection standard document (W) are the data of the manufacturing department 13 according to the division (2). Is called.

[0132] After the production elements and binary relations are deleted and added, when the production system is instructed via the input device, the computer 11 adds the remaining production elements and the new production elements added. And the binary relationship formed from the remaining first and second production factors and the binary relationship formed from the added first and second production factors, and in accordance with the integrated binary relationship. A production system corresponding to the article (1) is generated again. The production system generation on September 30 after the production factors and binary relations are deleted and added is explained as follows.

[0133] When a production system generation instruction on September 30, 2005 is issued via the input device, the computer 11 refers to the start date and end date of the production factors and binary relations. The binary relations that form the production system as of September 30, 2012 are extracted from the relational database 18, and the production elements that form the extracted binary relations are extracted from the type database 17. The computer 11 extracts the binary relation between the warehouse (B) and the product (G) from the relational data base 18 as logistics department data. Computer 11 replaces the base number (PC005) of the parent data classification of warehouse (B) with the base data classification (PC005) of base database 23, and the base data based on the part number (B) and the base data classification (PC005) Extract warehouse (B) data from base 23. The computer 11 reads the item number (PC001) of the child data category of the product (G) into the item data category (PC001) of the item database 19, and the item database based on the item number (G) and the item data category (PC001). 19 Extract data of product, product (G).

[0134] The computer 1 1 extracts the binary relation between the product (G) and the assembly drawing (P) from the relational database 18 as the manufacturing department data, and outputs the product of the child data classification of the assembly drawing (P). Replace the number (PC002) with the product data category (PC002) in the product database 20, and based on the product number (P) and product data category (PC002), the assembly drawing from the product database 20 (P) Extract the data. The computer 1 1 extracts the binary relationship between the product (G) and the inspection process (V) from the relational database 18 and assigns the process number (PC003) of the child data category of the inspection process (V) to the process in the process database 21. Read the data classification (PC003), and extract the data of the inspection process (V) from the process database 21 based on the product number (V) and the process data classification (PC003). The computer 11 extracts the binary relationship between the product (G) and the assembly process (T) from the relational database 18 and also stores the process number (PC003) of the child data category of the assembly process (T) in the process database 21. The process data category (PC003) is read, and the assembly process (T) data is extracted from the process database 21 based on the product number (T) and the process data category (PC003).

[0135] The computer 1 1 extracts the binary relationship between the inspection process (V) and the inspection standard document (W) from the relational database 18, and outputs the product number (PC002) of the child data category of the inspection standard document (W). ) Is replaced with the product data category (PC002) in the product database 20, and based on the product number (W) and product data category (PC002)! /, The inspection standard document (W) data from the product database 20 To extract. The computer 1 1 extracts the binary relation between the assembly process (T) and the part (13) from the relational database 18, and sets the item number (PC001) of the child data classification of the part (13) to the item data in the item database 19. The term (PC001) is read, and based on the part number (β) and the item data category (PC001), the part (/ 3) data is extracted from the item database 19. The computer 1 1 extracts the binary relation between the assembly process (Τ) and the line (δ) from the relational database 18, and the resource number (PCOO) of the child data classification of the line (δ).

4) is replaced with the resource data category (PC004) of the resource database 22, and the data of the line (δ) is extracted from the resource database 22 based on the product number (δ) and the resource data category (PC004).

[0136] Extracting various binary relations between production factors from the relational database 18 When the various production factors that form the binary relationship are extracted from the type database 17, the computer 11 refers to the parent data category of the first production element and the child data category of the second production element that forms the binary relationship. Then, the various binary relations extracted by combining the production elements of the same data category among those binary relations are integrated. Specifically, the binary relationship between warehouse (B) and product (G), the binary relationship between product (G) and assembly drawing (P), and the relationship between product (G) and inspection process (V). Among the two-term relationships between the item relationship and product (G) and assembly process (T), the product (G) is judged to be the same common production factor from the data classification (P C001) and the product number (G). Combine the product (G) with the relationship between the two items, connect the product (G) to the lower part of the warehouse (B), and the assembly drawing (P) and the inspection process (V) to the lower part of the product (G). Connect the assembly process (U) in parallel. The inspection standard document (W) is connected to the lower part of the inspection process (V) by the binary relation between the inspection process (V) and the inspection standard document (W).

[0137] Next, the binary relationship between the assembly process (T) and the part (/ 3), the binary relationship between the assembly process (T) and the line (δ), the assembly process (Τ) and the tool (Θ) Among the two relations, the assembly process (Τ) is determined as the same production element from the data classification (PC003) and the part number (Τ), and the assembly process (Τ) is combined in these two relations. The parts ((), line (δ), and tool (Θ) are connected in parallel to the lower part of the assembly process (Τ) .In addition, warehouse (Β), product (G), assembly drawing (Ρ), inspection process (V ), Assembly process (Τ), inspection standard (W) system and assembly process (工程), part (/ 3), line (δ), tool (Θ) system data classification (PC003) The assembly process (Τ) is determined to be the same common production factor from the product number (Τ) and the assembly process (Τ) is combined in those systems, so that the warehouse (Β) is in the higher order and the immediate lower order. Product (G) is located and assembled immediately below product (G) (Ρ), inspection process (V), and assembly process (Τ) are located, and inspection standard (W) is located immediately below inspection process (V), and immediately below assembly process (下位). A system (technical information system) in which parts ((), lines (δ), and tools (Θ) are located is constructed, and these binary relationships are integrated (binary relationship integration means).

[0138] When the binary relation is integrated, the computer 11 incorporates each production element into the system based on the integrated binary relation, and a production system in which various production elements are connected from the superordinate concept to the subordinate concept. Generate (production system generation means). In the created production system, as shown in Fig. 14, the warehouse (Β) is the highest and the products (G) and assembly drawings (Ρ) ), Inspection process (V), assembly process (Τ), inspection standard (W), parts (/ 3), line (δ), tool (Θ). The computer 11 stores the production system of the article (1) generated after deletion or addition of production factors and binary relations in a storage device or hard disk (production system storage means), and the production system of the generated article (1) is Output via output device (production system output means)

[0139] Fig. 18 is a diagram showing the sectoral production system output to each sector 12, 13, 14, 15 after the production factors and binary relations are deleted and added. In this system, only the production elements represented by solid lines in Fig. 18 are output from the output devices installed in each department 12, 13, 14, and 15, and the production elements represented by dotted lines are not output in principle. The computer 11 transfers the entire production system created to the terminal equipment installed in each department 12, 13, 14, 15, and based on the department number (1, 2, 3, 4), the department 12, 13, A production system for each department formed from only the necessary production elements for each of 14, 14 and 15 is displayed on the display installed in each department 12, 13, 14 and 15 (production system for each department production means). The production system is printed on a printer installed in each department 12, 13, 14, 1 5 (production system output means for each department).

[0140] As shown in Fig. 18, the display installed in the design department 12 has a product (G), assembly drawing (Ρ), inspection process (V), inspection standard document with department number 1 set. (W), parts (/ 3), line (δ), goods (1) formed from goods (Θ), production system (1) is displayed, warehouse (倉庫) with department number 4 set, department by The assembly process (Τ) with the number 2 is not displayed. The display installed in the manufacturing department 13 is a product (G), assembly drawing (Ρ), inspection process (V), assembly process (Τ), inspection standard (W), parts with department number 2. (/ 3), line (δ), production system of goods (1) formed from tools (Θ) is displayed, and warehouse (Β) with department number 4 is not displayed. In addition, the display installed in the purchasing department 14 includes an article (1) formed from a product (G), a part (/ 3), a line (δ), and a tool (Θ) with a department number 3. Warehouse (Β) with production system displayed and department number 4 set, assembly drawing with department numbers 1 and 2 (Ρ), inspection process (V), inspection standards (W), department The assembly process (Τ) with the number 2 is not displayed. The display installed in Logistics Department 15 displays the production system of goods (1) formed from warehouses (Β) and products (G) with department number 4 set. Assembly drawing (Ρ) with 3 set, inspection process (V), assembly process ( T), inspection standard (W), parts (/ 3), line (δ), tool (Θ) are not displayed. However, in each department 12, 13, 14, 15, the entire production system can be displayed on the display by selecting the entire display.

[0141] FIG. 19 is a diagram showing a list of the start date and end date of each production factor after the production factor and binary relations are deleted and added. In Fig. 19, as in Fig. 7, the period from January 1 to September 30, 2005 is shown. When an instruction to generate a production system on March 15 is given via the input device, the computer 11 refers to the start date and end date of the binary relation, and starts the production system from March 18 to March 15. Extracting the various binary relations that form the formation elements, and referring to the start and end dates of the production elements, the production elements that form the extracted binary relations are classified into the first to fifth type databases 19 , 20, 21, 22, 23. Next, the computer 11 integrates the extracted binary relations and, according to the integrated binary relations, connects a plurality of extracted production elements in a series from the superordinate concept to the subordinate concept, thereby obtaining those dates. Create a production system for goods (1). The production of the production system on March 15 is explained as follows.

[0142] When the production system generation instruction on March 15, 2005 is issued via the input device, the computer 11 refers to the production element and the start date and end date of the binary relation. The binary relations that form the production system as of today are extracted from the relational database 18, and the production elements that form the extracted binary relations are extracted from the type database 17. The computer 11 extracts the binary relation between the warehouse (Α) and the product (G) from the relational database 18 as logistics department data. Computer 11 replaces the base number (PC005) of the parent data category of the warehouse (Α) with the site data category (PC005) of the site database 23, and based on the product number (Α) and the site data category (PC005)! / Then, the warehouse (Α) data is extracted from the base database 23. Computer 11 replaces the item number (Ρ C001) in the child data category of product (G) with the item data category (PC001) in item database 19, and the item database based on the item number (G) and item data category (PC001). Extract product (G) data from 19.

[0143] The computer 11 extracts the binary relationship between the product (G) and the assembly drawing (Ρ) from the relational database 18 as the manufacturing department data, and outputs the product number of the child data classification of the assembly drawing (Ρ). Replace (PC002) with the product data category (PC002) in the product database 20, and based on the product number (P) and product data category (PC002), the assembly database (P) Extract data. The computer 11 extracts the binary relationship between the product (G) and the inspection process (V) from the relational database 18, and also assigns the process number (PC003) of the child data category of the inspection process (V) to the process data in the process database 21. The data is read as the category (PC003), and the data of the inspection process (V) is extracted from the process database 21 based on the product number (V) and the process data category (PC003). The computer 11 extracts the binary relation between the product (G) and the assembly process (S) from the relational database 18 and sets the process number (PC003) of the child data category of the assembly process (S) in the process database 21. The process data category (PC003) is read, and the assembly process (S) data is extracted from the process database 21 based on the product number (S) and the process data category (PC003).

The computer 11 extracts the binary relation between the inspection process (V) and the inspection standard document (W) from the relational database 18, and outputs the product number (PC002) of the child data category of the inspection standard document (W). The data is read as the product data category (PC002) in the database 20, and the inspection standard (W) data is extracted from the product database 20 based on the product number (W) and the product data category (PC002). The computer 11 extracts the binary relationship between the assembly process (S) and the part (<<) from the relational database 18 and sets the item number (PC001) of the child data classification of the part (α) to the item data classification of the item database 19. (PC001) is read, and the part (α) data is extracted from the item database 19 based on the part number (α) and the item data classification (PC001). The computer 11 extracts the binary relation between the assembly process (S) and the line (δ) from the relational database 18, and also identifies the resource number (PCOO) of the child data category of the line (δ).

4) is replaced with the resource data category (PC004) of the resource database 22, and the data of the line (δ) is extracted from the resource database 22 based on the product number (δ) and the resource data category (PC004). The computer 11 extracts the binary relation between the assembly process (S) and the tool (Θ) from the relational database 18, and uses the resource number (PC004) of the child data classification of the tool (Θ) as the resource data in the resource database 22. Replaced with category (PC004), and extracts tool (Θ) data from resource database 22 based on product number (Θ) and resource data category (PC004) [0145] Extracting various binary relations between production elements from relational database 18 and extracting various production elements forming binary relations from classification database 17 will cause computer 11 to form binary relations. Refer to the parent data category of the first production element and the child data category of the second production element, and combine the production data of the same data category in the two-term relationship. Integrate relationships. Specifically, the binary relationship between warehouse (A) and product (G), the binary relationship between product (G) and assembly drawing (P), and the relationship between product (G) and inspection process (V). Of the two-term relationship between the item relationship and product (G) and assembly process (S), the product (G) is judged to be the same common production factor from the data classification (P C001) and the product number (G). Combine the product (G) with the relationship between the two items, connect the product (G) below the warehouse (A), and the assembly drawing (P) and the inspection process (V) below the product (G). The assembly process (S) is connected in parallel. The inspection standard (W) is connected to the lower part of the inspection process (V) by the binary relationship between the inspection process (V) and the inspection standard (W).

[0146] Next, the binary relationship between the assembly process (S) and the part (α), the binary relationship between the assembly process (S) and the line (δ), the assembly process (S) and the tool (Θ) Among the two-term relationships, the assembly process (S) is judged as the same production element from the data classification (PC003) and the part number (S), and the assembly process () is combined in these two-term relationships, and the assembly process ( The part (α), line (δ) and tool (Θ) are connected in parallel under S). Furthermore, warehouse (Α), product (G), assembly drawing (Ρ), inspection process (V), assembly process (S), inspection standard (W) system and assembly process (S), parts), line ( δ) and tool (Θ) systems, the assembly process (S) is judged as the same production element from the data classification (PC003) and the part number (S), and the assembly process (S) is determined in those systems. Combine. As a result, the warehouse (Α) is placed at the top, the product (G) is located immediately below it, and the assembly drawing (Ρ), inspection process (V), and assembly process (S) are placed immediately below the product (G). In addition, the inspection standard (W) is positioned immediately below the inspection process (V), and the part (a), line (δ), and tool (Θ) are positioned immediately below the assembly process (S). System (technical information system) to be integrated, and these binary relationships are integrated (binary relationship integration means).

[0147] When the binary relation is integrated, the computer 11 incorporates each production element into the system based on the integrated binary relation, and a production system in which various production elements are connected from the superordinate concept to the subordinate concept. Generate (production system generation means). In the produced production system As shown in Fig. 19, warehouse (A) is at the top, products (G), assembly drawing (P), inspection process (V), assembly process (S), inspection standard document (W) in the lower order. , Parts (<<), lines (δ), and tools (Θ). The computer 11 stores the production system of the article (1) generated after deletion or addition of production factors and binary relations in a storage device or hard disk (production system storage means), and outputs the production system of the generated article (1) Output via the device (production system output means).

[0148] The production system creation system 10 and the production system creation method can delete and add production elements and the first and second production elements at any point in time from the past to the deleted and added production. A new production system from the past to the present time can be created using the elements and the first and second production elements. In the production system creation system 10 and the production system creation method, the deletion and addition of production elements can be managed centrally by the type database 17, and the deletion and addition of the first and second production elements can be managed based on the related data. It can be centrally managed by one. Therefore, it is not necessary to delete and add production elements and first and second production elements for each division 12, 13, 14, and 15 to create and manage production systems. By removing and adding production factors to each department 12, 13, 14, 15 power, it is possible to save the time and labor of the temples and labors.

[0149] In this system 10, the start date of the production element is set as the time when the production system of the production element is formed, and the end date of the production element is set as the time of departure from the production system of the production element. The ability to set the binary relationship start date as the time when the relationship production system was formed, and the binary relationship end date as the departure time from the binary relationship production system. (Hours, minutes, seconds) can also be set.

Claims

The scope of the claims

[1] In a production system creation system that creates an article production system from a combination of production elements that branch from a superordinate concept to a subordinate concept.

The power between the production elements is linked by an upper and lower binary relationship between an arbitrary first production element and a second production element that is immediately below it, and the system force S, a plurality of different production elements and their production elements Stores the type database that stores the time of production system formation and the time of departure from the production system, and the multiple binary relationships of different types and the time of production system formation and the time of departure from the production system of these binary relationships. A production system generation means for generating a production system at an arbitrary point in time from the past to the present corresponding to various articles using these production factors,

In the production system generation means, referring to the production system formation time and production system power of the binary relation, and the departure time of the production system, the plurality of binary relations necessary for creating the production system at the arbitrary time point are In addition to extracting from the relational database, various types of production elements corresponding to the first and second production elements that form the extracted binary relation are extracted from the type database, and those binary relations extracted from the relational database are extracted. In accordance with the integrated binary relationship, the production elements extracted from the type database are directed from the superordinate concept to the subordinate concept and connected in series to generate a production system for various goods at any given time. Production system creation system characterized by that.

[2] In the production system creation system, the type database is divided into a plurality of first to nth type databases, and the first to _nth type numbers for specifying the types of the production elements are individually assigned to the production elements. And the production factors are stored in the first to nth type database based on the first to nth type numbers, and the types of the first and second production factors forming the binary relation A number is stored in the relational database;

In the production system generation means, the first to n-th items are generated on the basis of the first to n-th type numbers of various production elements corresponding to the first and second production elements that form the extracted binary relationship. Of the production elements that form these two-term relationships, referring to the first to nth type numbers of the first and second production factors of the two-term relationship extracted from the type database and extracted from the relational database To combine production elements of the same type number 2. The production system creation system according to claim 1, which integrates a plurality of various binary relationships extracted in step (1).

[3] In the production system creation system, the 1st to nth department numbers for classifying the production elements by department are individually set to the production elements, and the production system generated by the production system generation means is used. In the system, execute the production system for each department that outputs the production system for each department formed only from the necessary production elements for each department.

The sector-specific production system output means refers to the same sector-specific numbers by referring to the sector-specific numbers of various production factors corresponding to the first and second production factors that form the binary relation extracted from the relational database. The production system creation system according to claim 1 or 2, wherein a production system created only from the production elements corresponding to the number is output.

[4] In the production system creation system, each production element stored in the type database can be modified retroactively to the present or the past, and the first production element and the second production element stored in the relational database can be changed. At least one of them can be modified retroactively to the present or the past, and the production system generation means modifies each production element stored in the type database and the first and second production elements stored in the relational database. Then, using the new production factor that was modified, the binary relationship was re-integrated using the new binary relationship that was formed from the first and second production factors after the modification, and integrated 2 The production system creation system according to any one of claims 1 to 3, wherein a production system corresponding to each kind of article is generated again according to the item relation.

[5] In the production system creation system, the time when the production system was formed and the time of departure from the production system can be changed retrospectively, and the time of formation of the binary system and the departure from the production system The production system creation system according to claim 1 to claim 4, wherein the time point can be changed retrospectively.

[6] A production system creation method that creates an article production system from a combination of production elements that branch from a superordinate concept to a subordinate concept!

The production system creation method stores a plurality of production elements of different types, a type database storing the production system formation time and the departure time from the production system, and an arbitrary first production element and its The two or more binary relationships of the production elements that are linked by the upper and lower binary relationships with the second production element that is immediately below. And a relational database that stores the time when the production system of these binary relations was formed and the time of departure from the production system.

In the production system creation method, referring to the production system formation time and production system power of the two-term relationship, and the departure time of the production system, the plurality of binary relations necessary for creating the production system at an arbitrary time point In addition to extracting from the relational database, various types of production elements corresponding to the first and second production elements that form the extracted binary relation are extracted from the type database, and those binary relations extracted from the relational database are extracted. In accordance with the integrated binary relationship, the production elements extracted from the type database are connected in series from the superordinate concept to the subordinate concept to generate and generate a production system for various articles at the arbitrary point in time. A production system creation method characterized by storing and outputting the produced production system.

[7] The type database is divided into a plurality of first to n-th type databases, and the first to n-th type numbers for specifying the types of the production elements are individually set for the production elements, and the production is performed. The elements are stored in the first to nth type databases based on the first to nth type numbers, and the type number powers of the first and second production elements forming the binary relation are stored in the relational database. Stored,

In the production system creation method, a plurality of various production elements corresponding to the first and second production elements that form the extracted binary relations are selected based on the first to nth type numbers. Of the production elements that form these two-term relationships, referring to the first to nth type numbers of the first and second production factors of the two-term relationship extracted from the type database and extracted from the relational database 7. The production system creation method according to claim 6, wherein a plurality of binary relationships extracted by combining production elements having the same type number are integrated.

[8] In the production system creation method, the 1st to nth department numbers for classifying the production elements by department are individually set in the production elements to form the binary relations extracted from the relational database. Referring to the first to nth department numbers of the various production elements corresponding to the first and second production elements to be created, the production system is created from only the production elements corresponding to the same department number. The production system creation method according to claim 6 or claim 7, wherein the output production system for each department is output.

[9] In the production system creation method, each production factor stored in the type database can be modified retroactively to the present or the past, and the first production factor and the second production factor stored in the relational database can be changed. At least one of the production factors stored in the type database and the first and second production factors stored in the relational database can be modified. Use new production factors, re-integrate the binary relationships using the new binary relationships formed from the first and second production factors after modification, and handle various articles according to the integrated binary relationships The production system creation method according to claim 6, wherein the production system to be generated is generated again.

[10] In the production system creation method, the production system production system formation time and the departure time from the production system can be retroactively changed, and the binary system production system formation time and the departure time from the production system can be changed. 10. The production system creation method according to any one of claims 6 to 9, which can be changed retrospectively.