JP5693908B2 - Demolition management system - Google Patents

Description

  The present invention relates to a dismantled object management system that manages a plurality of dismantled objects after dismantling various components constituting a building.

  There is a dismantling method for dismantling a building without damaging a reusable internal member that is covered with a surface layer member that forms a room of the building and is disposed inside the surface layer member (see Patent Document 1). In this dismantling method, the RFID storing the information of the internal member is attached to the internal member in advance, and the surface of the surface layer member is scanned using a detection device before disassembling to acquire the information stored in the RFID, The type and position of the internal member are specified based on the stored information.

  A step of removing the radioactive material and the coating film on the inner wall surface of the nuclear facility by the removing means; a step of demolishing the nuclear facility from which the radioactive substance and the coating film have been removed into a dismantled product of a predetermined size by the disassembling means; The dismantled material to be disassembled is stored in a transport container and transported from the nuclear facility to the turbine building adjacent to it, and the dismantled material stored in the transport container in the turbine building is shredded to a predetermined size by shredding means. There is a nuclear facility dismantling method that includes a cutting step and a step of decontaminating the shredded material by a decontamination means and then storing it in a container (see Patent Document 2).

JP 2008-255680 A JP 2010-8091 A

  The building dismantling method disclosed in Patent Document 1 uses an RFID having an IC chip to store information on internal members in the RFID, attaches the RFID to the internal member, and uses a detector before dismantling. By determining the type and position of the reusable internal member, the reusable internal member hidden in the surface layer member can be confirmed. However, it is not possible to identify the buildings to which they belong after dismantling the buildings after dismantling the buildings, and it is not possible to track the buildings to which they belong after dismantling the buildings .

  In addition, the building demolition method disclosed in Patent Document 2 specifies the attributes such as the contamination level, risk, material, specific information, demolition date and time of the radioactive material of the multiple demolitions of the dismantled nuclear facilities after demolition In addition to being able to identify the nuclear facilities to which they belonged in multiple demolitions after dismantling nuclear facilities, it is possible to grasp the attributes of those demolitions for each demolition Cannot be managed based on the attribute. In particular, in the dismantling work at nuclear facilities, in order to strictly prevent radioactive contamination, it is required to be able to track and grasp the structure before dismantling to which the dismantling belongs, and the attributes of the dismantling are dismantling. It is required that it can be traced and grasped later, and management for each attribute of the demolished product is required. However, the dismantling method disclosed in Patent Document 2 cannot satisfy such conditions required for dismantling nuclear facilities.

  It is an object of the present invention to specify a structure to which a dismantled material after dismantling belongs after dismantling, and to manage the dismantled material that can track and grasp the constituents to which the dismantled objects belong after dismantling the components. To provide a system. Another object of the present invention is to be able to track and grasp the attributes of the structure to which the dismantled material that dismantled the nuclear facility belongs, and to manage the dismantled material that dismantled the nuclear facility for each attribute. It is to provide a demolition management system.

  The premise of the present invention for solving the above-mentioned problems is a dismantled object management system that manages a plurality of dismantled objects after dismantling various components constituting the building.

The feature of the present invention based on the premise is that the building is a nuclear facility, and the dismantled management system displays a serial number tape on which a plurality of printable identification codes representing consecutive numbers are displayed, and a serial number tape Using an identification code reader that reads the identification code displayed on the computer, and a computer to which the identification code number is transferred from the identification code reader, and before dismantling management before disassembling the components constituting the nuclear facility In the pre-disassembly management, serial number tapes with multiple identification codes are affixed to the pre-disassembly components that make up the nuclear facilities, and the pre-disassembly configuration is performed. the first number and the last number among the affixed to serial numbers tape consecutive number identification code represents a is read by the identification code reader at the object, to identify the computer each construct Run the composition storage means for storing the composition specified identifier and the top number in association with consecutive numbers until the last number, the demolition after administration, at least one component comprises serial number tape constituting the nuclear facilities One of the identification code is dismantled into a plurality of demolition which remained to be read, after dismantling the composition into a plurality of demolition material, serial number tape identification code affixed to their dismantling thereof is read by the identification code reader The computer executes the component specifying means for specifying the component to which the dismantled object belongs from the component specifying identifier corresponding to the number represented by the identification code of the serial number tape affixed to the dismantled material.

  As another example of the present invention, the computer stores various attributes of the components in a state associated with the component identification identifier, and the post-demolition management outputs the attributes of the components to which the demolition belongs. .

  As another example of the present invention, in the dismantled object management system, a plurality of types of serial number tapes distinguished by a plurality of various colors are used, and attributes of components can be recognized by the color of the serial number tapes.

  As another example of the present invention, in the dismantled object management system, a plurality of types of serial number tapes distinguished by various types are used, and the attributes of the components can be recognized by the form of the serial number tape.

  As another example of the present invention, in the dismantled object management system, a plurality of types of serial number tapes distinguished by various types of symbols are used, and the attributes of the components can be recognized by the symbols displayed on the serial number tapes. .

  As another example of the present invention, the attribute of the component is the level of contamination of the component by radioactive material in a nuclear facility.

  As another example of the present invention, the attribute of the component is the risk of the component in a nuclear facility.

  As another example of this invention, the attribute of a structure is the material of those structures in a nuclear power related facility.

  As another example of this invention, the attribute of a structure is the specific information and dismantling date of those structures in a nuclear related facility.

As another example of the present invention, the identification code is a bar code, and on the connecting tape, the bar code is continuously arranged in a line in a state of being spaced apart at equal intervals in the length direction of the connecting tape .

According to dismantling thereof management system according to the present invention, in disassembled before administration, serial number tape affixed to construct, consecutive numbers affixed to serial numbers tape identification code of the construct is expressed constituting the nuclear facilities The first number and the last number are read by the identification code reader, the computer stores the component identification identifier for identifying each component in association with the consecutive numbers from the first number to the last number, and dismantling in post-administration, be dismantled into a plurality of demolition product structure composing the nuclear facilities remains readably at least one identification code of the serial number tape, the plurality of demolition material after disassembling the construct identification code of the serial number tape remaining is read by the identification code reader, turn the computer represented affixed to serial numbers tape identification code of their dismantling thereof Because they demolition material from construct specific identifier corresponding to identify the composition that belong to, by using the identification code displayed on the serial number tape, construct multiple pieces of demolition material constitutes the nuclear facilities belonging Can be specified for each dismantled object, and after the dismantling of the constituents, the constituents of the nuclear related facility to which the dismantled objects belonged can be tracked and grasped. Dismantling product management system, even more pieces of demolition material is composition is finely dismantling constituting the nuclear facilities occurs, their dismantling thereof via the identification code affixed to the serial numbers tape them dismantling thereof since the dismantling previous construct can be reliably identified, or stray demolition prepared by dismantling the structure of certain nuclear facilities from dismantled product group configuration of its nuclear facilities, construction of some nuclear facilities Even if a dismantled product that has been dismantled is included as a dismantled product of another nuclear facility , the dismantled product can be identified before dismantling it. . In dismantling work at nuclear facilities, for the purpose of strictly preventing radioactive contamination, it is required that the attributes of the components to which multiple dismantles belong can be traced and grasped after dismantling. Although management for each attribute is required, this demolition management system can satisfy such conditions required for the dismantling of nuclear facilities.

The dismantled management system is configured such that at least one identification code remains readable on a serial number tape affixed to the dismantled material, and at least one readable identification code remains on the dismantled material. Therefore, it is possible to identify the constituent to which the dismantled object belongs, and to reliably track and grasp the constituent to which each dismantled object belongs after the dismantling of the constituent.

  The property management system in which the attribute of the component is stored in the computer in a state associated with the component identification identifier, and the attribute of the component to which the demolished object belongs is output in post-disassembly management. In addition to being able to track and grasp later, even after the dismantling of the structure, since the attributes of the structure to which the dismantle belongs can be grasped for each dismantled object, Therefore, it can be managed separately for each attribute.

  A dismantlement management system that uses multiple types of serial tapes that are classified by various colors and can recognize the attributes of the constituents by the color of the tape, tracks and grasps the constituents to which the dismantles belong after dismantling In addition, even after the disassembly of the component, since the attributes of the component to which the dismantle belongs can be grasped for each dismantle by the color of the serial number tape, the dismantle by using the tape Can be managed separately for each component and for each attribute.

  A dismantled management system that uses multiple types of serial number tapes that are distinguished by color shading and that recognizes the attributes of the constituents based on the shading of the color of the tape tracks and grasps the constituents to which the dismantles belong after dismantling In addition, even after the dismantling of the structure, the attributes of the structure to which the dismantle belongs can be grasped for each dismantled object by the shade of color of the serial number tape. The dismantled object can be managed for each component and for each attribute.

  The dismantlement management system that uses multiple types of serial numbered tapes that are distinguished by various forms and that can recognize the attributes of the constituents by the shape of the tape, tracks and grasps the constituents to which the dismantles belong after dismantling. In addition, even after the dismantling of the components, the attributes of the constituents to which the dismantling belongs can be ascertained for each dismantling by the form of serial number tape. Can be managed separately for each component and for each attribute.

  Using a plurality of types of serial number tapes that are distinguished by various symbols, the dismantlement management system that can recognize the attributes of the constituents by the symbols displayed on the tape tracks the constituents to which the dismantles belong, In addition to being able to grasp, even after the disassembly of the structure, the attribute of the structure to which the dismantle belongs can be grasped for each dismantle by the symbol displayed on the serial number tape. By doing so, the dismantled object can be managed for each component and for each attribute.

  The dismantlement management system, whose attribute is the level of contamination of radioactive materials in facilities related to nuclear power, uses the identification code displayed on the serial number tape to disassemble the component to which the dismantle belongs. In addition to being able to track and grasp, it is possible to manage the contamination level of the radioactive material of each dismantled object for each dismantled object and prevent radioactive contamination through the dismantled object beforehand. The dismantlement management system uses the color, shading, shape, and symbols of the serial number tapes to determine the level of contamination of the components due to radioactive materials for each dismantlement. Can be managed based on level.

  The dismantlement management system, whose attributes are the dangers of those constituents in nuclear facilities, uses the identification code displayed on the serial number tape to track and grasp the constituents to which the dismantles belong after dismantling. In addition, it is possible to manage the risk of the composition to which each demolition belongs, and to prevent the unknown risk of the composition to which the demolition belongs. The dismantlement management system uses the color, shading, shape, and symbol of the serial number tape to identify the risk of the composition to which each dismantle belongs, and each dismantlement Can be managed based on the level of risk of the component to which it belongs.

  The dismantlement management system, whose attributes are the material of those constituents in nuclear facilities, uses the identification code displayed on the serial number tape to track and grasp the constituents to which the dismantles belong after dismantling. In addition, it is possible to manage the material of the constituent to which each dismantle belongs for each dismantle, and to prevent the unknown of the material of the constituent to which the dismantle belongs. The dismantlement management system uses the color, shading, shape, and symbol of the serial number tape to identify the material of the structure to which each dismantle belongs, and each dismantlement It can be managed based on the material of the component to which it belongs.

  The dismantlement management system, whose attributes are the specific information and dismantling date and time of those constituents in nuclear facilities, uses the identification code displayed on the serial number tape to In addition to being able to track and grasp, it is possible to manage the specific information and dismantling date of the structure to which each dismantle belongs for each dismantled object, and to identify the specific information of the constituent to which the dismantle belongs and the date of dismantling Can be prevented.

The schematic block diagram of the dismantlement management system shown as an example. The figure which shows an example of a serial number tape. The perspective view of the wall of the reinforced steel concrete building where the serial number tape was stuck. The perspective view of the pillar of the reinforced steel concrete building where the serial number tape was stuck. The figure which shows an example of the demolition work of a wall. The figure which shows an example of the dismantling operation | work of a pillar. The figure which shows the demolition thing after demolition of a wall. The figure which shows the demolition thing after dismantling a pillar. The figure which shows an example of a nuclear power plant. The figure which shows an example of the serial number tape utilized for the dismantling of a nuclear power plant. The figure which shows another example of a serial number tape. The figure which shows another example of a serial number tape. The perspective view of the wall where the serial number tape shown in FIG. 10 was affixed. The figure which shows an example of the demolition work of each wall. The figure which shows the demolition thing after demolishing each wall. The perspective view of the column where the serial number tape shown in FIG. 11 was affixed. The figure which shows an example of the dismantling operation | work of each pillar. The figure which shows the demolition thing after dismantling each pillar. The perspective view of the floor slab with which the serial number tape shown in FIG. 12 was affixed. The figure which shows an example of the dismantling operation | work of each floor slab. The figure which shows the dismantled thing after dismantling each floor slab.

  The details of the demolition management system according to the present invention will be described with reference to the accompanying drawings such as FIG. 1 which is a schematic configuration diagram of the demolition management system shown as an example. FIG. 2 is a diagram showing an example of the serial number tape 11. The dismantled object management system 10 includes a serial number tape 11, a barcode reader 12 (identification code reader), and a computer 13. The dismantlement management system 10 uses the serial number tape 11, the barcode reader 12, and the computer 13 to perform management before dismantling of various constituents constituting the building, and after dismantling after dismantling the constituents Perform management.

  As shown in FIG. 1, the dismantling serial number tape 11 is an elongated band in a planar shape, and is processed into a wound shape obtained by winding the band. On the surface of the serial number tape 11, there are continuous unlimited numbers (for example, 1, 2, 3,..., N continuous numbers, but even numbers 2, 4, 6. A plurality of bar codes 14 (identification codes) representing 3, 5... N may be displayed (printed). The bar codes 14 are continuously arranged in a line in a state of being spaced apart at equal intervals in the length direction (one direction) of the connecting tape 11. The serial number tape 11 is made of a synthetic resin sheet or a paper sheet or a composite sheet of a synthetic resin sheet and a paper sheet, and an adhesive (not shown) is applied to the back surface thereof. In addition, the adhesive material may be coat | covered and protected with release paper (not shown).

FIG. 2 shows a one-dimensional barcode 14 as a barcode. In addition to the one-dimensional barcode 14, a matrix-type two-dimensional barcode such as a QR code (registered trademark) , a Veri code, or a maxi code is used. It is also possible to use a stack type two-dimensional barcode such as Code 49, Code 16K, Codable, and SuperCode. Chameleon codes can also be used. In addition to the barcode, a digital mark (identification code) or a color mark (identification code) can be used. When a digital mark is used, a digital mark reader that reads a digital mark is used instead of the barcode reader 12, and when a color mark is used, a color mark reader that reads a color mark instead of the barcode reader 12. Is used.

  The barcode reader 12 is connected to the computer 13 via an interface (wired or wireless). Although three bar code readers 12 are illustrated in FIG. 1, the number of bar code readers 12 is not particularly limited, and there may be one or four or more bar code readers 12. Each barcode reader 12 is set with a private IP address and a MAC address, and each barcode reader 12 can be individually specified based on the address information.

  The barcode reader 12 reads the barcode 14 displayed on the serial number tape 11 and transfers the data represented by the read barcode 14 to the computer 13 as a digital signal. Although not shown, each bar code reader 12 is accompanied by a numeric keypad unit and a display. Using the numeric keypad unit, necessary data can be transmitted from the barcode reader 12 to the computer 13, and using the display, data transmitted from the barcode reader 12 to the computer 13 can be displayed and confirmed. A message from the computer 13 can be displayed and confirmed.

  The computer 13 has a central processing unit (CPU or MPU) and a memory (storage unit), and incorporates a large-capacity hard disk. Although three computers 13 (portable notebook computers) are shown in FIG. 1, the number of computers 13 is not particularly limited, and the number of computers 13 may be one or four or more. In the pre-disassembly management, one or more of the barcode readers 12 are connected to one of the computers 13, and the barcode 14 reading operation and data storage operation are performed. Note that a private IP address and a MAC address are set in the computer 13, and each computer 13 can be individually specified based on the address information. The computer 13 has a built-in communication port, and input devices such as a keyboard 15 and a mouse 16 and output devices such as a display 17 and a printer (not shown) are connected via an interface.

  The computer 13 receives a request from a DNS server function for setting a correspondence between a host name and an IP address assigned to the host name, a Web server function necessary for publishing a home page, and another computer or another server. A database server function that provides functions for reading and writing various information, a mail server function for sending and receiving e-mails, a document server function that saves all data such as texts and images created, and makes it possible to search for such data Have. Each computer 13 can be connected to the Internet, and can transmit and receive various data between networks. Within the network, various data can be transmitted and received between the computers 13.

  The computer 13 receives address information of the barcode reader 12 and data represented by the barcode 14 read by the barcode reader 12 as digital data. A dismantlement management application is stored in the memory of the computer 13. Based on the control by the operating system, the central processing unit of the computer 13 activates the dismantlement management application stored in the memory, and executes each means described later according to the application.

  FIG. 3 is a perspective view of the wall 18 constituting the reinforced steel concrete building to which the serial number tape 11 is attached, and FIG. 4 is a column 19 constituting the reinforced steel concrete building to which the serial number tape 11 is attached. FIG. FIG. 5 is a diagram illustrating an example of the dismantling operation of the wall 18, and FIG. 6 is a diagram illustrating an example of the dismantling operation of the column 19. In FIG. 3, the serial number tape 11 is attached to the wall 18, and the barcode 14 of the tape 11 is read by the barcode reader 12. In FIG. 4, the serial number tape 11 is attached to the pillar 19, and the barcode 14 of the tape 11 is read by the barcode reader 12. The buildings to be demolished include all artificially made objects such as buildings and vehicles. In FIGS. 3 and 4, the wall 18 and the pillar 19 are illustrated as the structure of the building, but the structure is not limited thereto, and includes any other structure constituting the building.

  The procedure for dismantling the walls 18 (components) and pillars 19 (components) of a reinforced steel concrete building (building) (not shown) using this dismantling management system 10 is as follows. is there. First, the building to be demolished (reinforced steel concrete building) is divided for each component (wall 18, column 19). After dividing the building into components, the serial number tape 11 is affixed to the component. Specifically, as shown in FIG. 3, the serial number tape 11 is randomly applied to one surface of the wall 18, and as shown in FIG. 4, the serial number tape 11 is randomly applied to the peripheral surface of the pillar 19.

  There are no particular restrictions on the location and length of the serial number tape 11 attached to the wall 18 or column 19, and it can be applied to any location on the wall 18 or column 19 in consideration of the size and number of disassembled components and dismantled items. In addition, an arbitrary length can be attached to the wall 18 or the pillar 19. Moreover, there is no particular limitation on the number of barcodes 14 displayed on the serial number tape 11 to be attached to the wall 18 or the pillar 19, and any number of barcodes 14 can be attached.

  After affixing the serial number tape 11 to the wall 18, as shown in FIG. 3, among the barcodes 14 displayed on the tape 11, the barcode 14 located at the head is read by the barcode reader 12, and at the end. The barcode 14 positioned is read by the barcode reader 12. Note that the intermediate barcode 14 arranged between the barcode 14 located at the head and the barcode 14 located at the tail is not read.

  Further, a reinforced steel concrete building (name) is input by using the numeric keypad unit of the bar code reader 12 or the keyboard 15 and the mouse 16 of the computer 13 (from the pull-down list of the building display displayed on the display 17). A concrete building can be selected), and a wall (name) is input (a wall can also be selected from a pull-down list of the component display displayed on the display 17).

  Using the numeric keypad unit of the barcode reader 12 or the keyboard 15 and mouse 16 of the computer 13, specific information (name, address, map, photograph, telephone number, URL, etc.) of the reinforced steel concrete building, dismantling date (year, month, day) , Time), usage, building volume, etc. (input of building attributes), wall 18 specific information (1st floor showroom, 2nd floor office, etc.), dismantling date (date, time), material Input attributes such as strength (wood, concrete, mortar, metal, etc.) (component attribute input). In addition, there is no limitation in particular in the attribute of the building which can be input, It is not restricted to an example attribute, All other attributes, such as a physical property and property of a building, can be input. Moreover, there is no limitation in particular in the attribute of the structure which can be input, It is not restricted to an example attribute, All other attributes, such as a physical property and property of a structure, can be input.

  The bar code reader 12 stores data (first number data, last number data) represented by the read bar code 14, building data representing a reinforced steel concrete building, building attribute data of a reinforced steel concrete building, and a wall 18. The constituent data to be represented and the constituent attribute data of the wall 18 are converted into digital data, and the data is transferred to the computer 13. When receiving the data from the barcode reader 12, the central processing unit of the computer 13 generates a building identification number (building identification identifier) that identifies the reinforced steel concrete building (building), and the wall. A component specifying identification number (component specifying identifier) for specifying 18 (component) is generated.

  After generating these identification numbers, the central processing unit of the computer 13 associates the structure specific identification numbers with the building specific identification numbers, and the number data from the first number to the last number transferred from the barcode reader 12 ( For example, when the first number is 0001 and the last number is 0020, the numbers from 0001 to 0020) are associated with the building specific identification number and the component specific identification number. Further, the transferred building attribute data is associated with the building specifying identification number and the building specifying identification number, and the transferred building attribute data is associated with the building specifying identification number. After completing the association, the central processing unit stores the building identification number, the building identification number, the number data, the building attribute data of the building, and the component attribute data of the wall 18 on the hard disk (configuration). Storage means). On the bar code reader 12 and the display 17 of the computer 13, a data storage completion message of the building → wall 18 is displayed.

  After confirming the data storage completion message of the building → the wall 18, the wall 18 is disassembled. In the dismantling operation, as shown in FIG. 5, the wall 18 is finely disassembled, and the wall 18 is disassembled into a plurality of dismantling objects 20. The serial number tape 11 remains in the dismantled object 20 of the dismantled wall 18, and there are cases where the barcode 14 displayed on the tape 11 is one, two, three, and the like. It should be noted that at least one barcode 14 needs to remain readable on the serial number tape 11 affixed to the dismantling material 20 on the wall 18.

  After affixing the serial number tape 11 to the pillar 19, as shown in FIG. 4, among the barcodes 14 displayed on the tape 11, the barcode 14 located at the head is read by the barcode reader 12, and at the end. The barcode 14 positioned is read by the barcode reader 12. Further, using the numeric keypad unit of the bar code reader 12 or the keyboard 15 and the mouse 16 of the computer 13, a reinforced steel concrete building (name) is input and a column (name) is input (configuration displayed on the display 17. You can also select a column from the pull-down list of the object display).

  Using the numeric keypad unit of the bar code reader 12 or the keyboard 15 or mouse 16 of the computer 13, specific information (name, address, map, telephone number, URL, etc.) of the reinforced steel concrete building, date of dismantling (year, month, day, time) ), Input attributes such as usage and building volume (building attribute input), pillar 19 specific information (3rd floor work room, 4th floor conference room, etc.), dismantling date (date, time), material ( (Wood, concrete, mortar, metal, etc.) and strength (component attribute input).

  The bar code reader 12 stores data (first number data, last number data) represented by the read bar code 14, building data representing a reinforced steel concrete building, building attribute data of a reinforced steel concrete building, and a column 19. The constituent data to be represented and the constituent attribute data of the pillar 19 are converted into digital data, and the data is transferred to the computer 13. When receiving the data from the barcode reader 12, the central processing unit of the computer 13 generates a component identification number (component identification identifier) that identifies the column 19 (component).

  After generating the component identification number, the central processing unit of the computer 13 associates the component identification number with the building identification number generated in the dismantling of the wall 18 and transfers the leading number transferred from the barcode reader 12. To the last number (for example, when the first number is 0050 and the last number is 0080, the numbers from 0050 to 0080) are associated with the building specific identification number and the structure specific identification number. Further, the transferred building attribute data is associated with the building specifying identification number and the building specifying identification number, and the transferred building attribute data is associated with the building specifying identification number. After completing the association, the central processing unit stores the building identification number, the building identification number, the number data, the building attribute data of the building, and the component attribute data of the pillar 19 on the hard disk (configuration Storage means). On the bar code reader 12 and the display 17 of the computer 13, a data storage completion message of building → pillar 19 is displayed.

  After confirming the data storage completion message of the building → pillar 19, the dismantling work of the pillar 19 is performed. In the dismantling operation, as shown in FIG. 6, the pillar 19 is disassembled finely, and the pillar 19 is disassembled into a plurality of dismantling objects 21. The serial number tape 11 remains in the dismantled product 21 of the dismantled column 19, and there are cases where the barcode 14 displayed on the tape 11 is one, two, three, and the like. It should be noted that at least one barcode 14 needs to remain readable on the serial number tape 11 affixed to the disassembled material 21 of the pillars 19.

  FIG. 7 is a diagram showing the demolished product 20 after the wall 18 is demolished, and FIG. 8 is a diagram showing the demolished product 21 after the wall 19 is demolished. In FIG. 7, only one dismantlement 20 of the wall 18 is shown, and illustration of other dismantles is omitted. In FIG. 8, only one dismantlement 21 of the pillar 19 is shown, and illustration of other dismantles is omitted. 7 and 8, the barcode 14 of the serial number tape 11 affixed to the dismantled materials 20 and 21 is read by the barcode reader 12.

  The dismantled material 20 dismantled from the wall 18 is disposed of, but is attached to the dismantled material 20 (the dismantled material 20 of the wall 18) using the bar code reader 12 before or during disposal or after disposal. By reading the bar code 14 of the serial number tape 11, the structure (reinforced steel concrete building) and the structure (wall 18) before the dismantled object 20 is dismantled, the reinforced steel concrete building and the pillar thereof Each of the 18 attributes can be confirmed.

  When the barcode 14 of the serial number tape 11 of the dismantled product 20 is read, the number data represented by the barcode 14 is transferred from the barcode reader 12 to the computer 13. The computer 13 compares the number data (for example, 0005) transferred from the barcode reader 12 with the number data (0001 to 0020) stored in the hard disk, and the disassembled object 20 is the disassembled object 20 of the wall 18. Judgment (component identification means).

  The computer 13 specifies a building specific identification number corresponding to the component specific identification number of the wall 18 and specifies a reinforced steel concrete building corresponding to the building specific identification number. Furthermore, the building attribute data corresponding to the building specifying identification number and the building specifying identification number is specified, and the component attribute data corresponding to the building specifying identification number is specified. Attribute data (specific information, dismantling date, usage, building capacity, etc.) of the reinforced steel concrete building where the wall 18 was installed, attribute data (specific information, dismantling date, material, volume, strength, etc.) of the wall 18 ) Is taken out from the hard disk, and the reinforced steel concrete building / wall 18 is displayed on the display 17 and the attribute data and number data are displayed on the display 17. Each data displayed on the display 17 can be output from the printer.

  The dismantled material 21 dismantled from the pillar 19 is disposed of, but is attached to the dismantled material 21 (the dismantled material 21 of the column 19) using the barcode reader 12 before or during disposal, or after disposal. By reading the bar code 14 of the serial number tape 11, the structure (reinforced steel concrete building) and the structure (column 19) before the demolished product 21 is demolished, the reinforced steel concrete building and the column 19 attributes and the like can be confirmed.

  When the barcode 14 of the serial number tape 11 of the dismantled product 21 is read, the number data represented by the barcode 14 is transferred from the barcode reader 12 to the computer 13. The computer 13 compares the number data (for example, 0065) transferred from the barcode reader 12 with the number data (0050 to 0080) stored in the hard disk, and the dismantled object 21 is the dismantled object 21 of the pillar 19. Judgment (component identification means).

  The computer 13 specifies a building specific identification number corresponding to the component specific identification number of the pillar 19 and specifies a reinforced steel concrete building corresponding to the building specific identification number. Furthermore, the building attribute data corresponding to the building specifying identification number and the building specifying identification number is specified, and the component attribute data corresponding to the building specifying identification number is specified. Attribute data (specific information, date of dismantling, usage, building volume, etc.) of the reinforced steel concrete building where the column 19 was installed, and attribute data (specific information, date of dismantling, material, strength, etc.) of the column 19 on the hard disk The reinforced steel concrete building / column 19 is displayed on the display 17 and the attribute data and number data are displayed on the display 17. Each data displayed on the display 17 can be output from the printer.

  Among the numbers represented by the barcode 14 of the tape 11 affixed to the wall 18 or the pillar 19, the serial number tape 11 is affixed to the wall 18 or the pillar 19 (component) in the dismantling management system 10. Are read by the bar code reader 12, and the computer 13 stores the component specifying identification number for identifying the wall 18 and the pillar 19 in association with the numbers from the first number to the last number, In post-disassembly management, the barcode 14 of the serial number tape 11 affixed to the plurality of dismantlements 20 and 21 after dismantling the walls 18 and pillars 19 is read by the bar code reader 12, and the computer 13 detects these disassembly objects 20. , 21, the wall 18 and the column 19 to which the dismantled objects 20, 21 belong are determined from the component identification numbers corresponding to the numbers represented by the barcode 14 of the tape 11. In addition to specifying the reinforced steel concrete building to which the wall 18 and the column 19 belong, by using the barcode 14 displayed on the serial number tape 11, The structure can be specified for each dismantled object 20, 21, and after the dismantling of the wall 18 and the pillar 19, the building and the structure (the wall 18 and the pillar 19) to which the dismantled parts 20, 21 belonged are tracked and I can grasp it.

  Even if the wall 18 and the pillar 19 which comprise a reinforced steel concrete building are disassembled finely and the several dismantlements 20 and 21 generate | occur | produce, the dismantlement management system 10 is the serial number stuck on these dismantlements 20 and 21. Through the barcode 14 of the tape 11, the components (walls 18 and pillars 19) before the dismantling of the dismantling materials 20 and 21 can be reliably identified for each dismantling material 20 and 21. Since the dismantled material management system 10 can specify the structure before dismantling of the dismantled materials 20 and 21 using the barcode 14 of the serial number tape 11, the dismantled material 20 in which the wall 18 and the pillar 19 are dismantled. , 21 may be separated from the group of dismantled components, or the dismantled materials 20, 21 dismantled from the wall 18 and the pillar 19 may be mixed in as dismantled materials of other components. The structure of (2) can be clarified, and the unidentification of the dismantlements 20 and 21 can be prevented.

  The demolished object management system 10 is stored in the computer 13 in a state where the attributes of the reinforced steel concrete building are associated with the building identification number, and the attributes of the wall 18 and the pillar 19 are associated with the component identification number. Therefore, even after the wall 18 and the pillar 19 are disassembled, the bar code 14 of the serial number tape 11 is used to specify the attributes of the buildings and structures to which the dismantled objects 20 and 21 belong. It is possible to grasp each demolished product 20, 21 and manage the demolished products 20, 21 for each building and for each attribute, and to manage the demolished products 20, 21 for each component. Therefore, it can be managed separately for each attribute.

  FIG. 9 is a diagram illustrating an example of a nuclear power plant 22 that is demolished using the demolished material management system 10. The demolition management system 10 shown in FIG. 1 formed by the serial number tape 11, the barcode reader 12, and the computer 13 can be effectively used for the demolition of the nuclear power plant 22 (building). The system 10 can be used effectively not only for the nuclear power plant 22 but also for dismantling other nuclear facilities (buildings). Other nuclear facilities include intermediate storage facilities, reprocessing plants, MOX fuel plants, fast breeder reactors, fast breeder reactor fuel factories, fast breeder reactor reprocessing plants, and high-level radioactive waste final disposal facilities. .

  The nuclear power plant 22 is formed of a central control room 23, a turbine building 24, and a reactor building 25. In the dismantling of the nuclear power plant 22, the dismantlement is strictly managed for the purpose of strictly preventing radioactive leaks and radioactive contamination, and the dismantled components can be tracked and grasped after dismantling. Is required. Furthermore, it is required that the attribute of the constituent to which the demolished object belongs can be tracked and grasped after dismantling, and management for each attribute of the demolished object is required.

  FIG. 10 is a diagram illustrating an example of the serial number tapes 11 (a) to 11 (b) used for dismantling the nuclear power plant 22, and FIG. 11 illustrates the serial number tapes 11 (d) to 11 (f). It is a figure which shows another example of. FIG. 12 is a diagram illustrating another example of the serial number tapes 11 (g) to 11 (i). The serial number tapes 11 (a) to 11 (i) shown in these drawings are classified by various colors, various shades of colors (chromatic and achromatic colors), various shapes, and various symbols. Yes. The tapes 11 (a) to 11 (i) correspond to various attributes of the components of the nuclear power plant 22, and the shades of the colors correspond to the various attributes of the components. The symbol corresponds to various attributes of the component, and the symbol corresponds to the various attributes of the component.

  Although the serial number tapes 11 (a) to 11 (i) are not shown in the drawing, the planar shape is formed into a long and narrow band, and is processed into a wound form by winding the band. . On the surfaces of these tapes 11 (a) to 11 (i), a plurality of barcodes 14 representing continuous unlimited numbers are displayed (printed). The tapes 11 (a) to 11 (i) are made of a synthetic resin sheet or a paper sheet or a composite sheet of a synthetic resin sheet and a paper sheet, and an adhesive is applied to the back surface thereof.

  The attribute of the composition of the nuclear power plant 22 corresponding to the color of the serial number tapes 11 (a) to 11 (i) includes the contamination level of the composition due to radioactive substances, the name of the composition, the material of the composition, and the composition. However, there is no particular limitation on the attribute of the component corresponding to the color of the serial number tapes 11 (a) to 11 (i), and the attribute can be set freely. The colors of the tapes 11 (a) to 11 (i) are not particularly limited, and include all colors that are visible and distinguishable.

  The attributes of the components corresponding to the color shades of the tapes 11 (a) to 11 (i) include the level of contamination of the components by radioactive substances, the name of the components, the material of the components, the danger of the components, and the like. However, there is no particular limitation on the attributes of the constituents corresponding to the shades of color of the serial number tapes 11 (a) to 11 (i), and the attributes can be set freely. There is no particular limitation on the shades of the colors of the tapes 11 (a) to 11 (i), and the shades of the colors of the tapes 11 (a) to 11 (i) can be freely set.

  The attributes of the component corresponding to the shapes of the tapes 11 (a) to 11 (i) include the contamination level of the component due to radioactive substances, the name of the component, the material of the component, and the danger of the component. The attributes of the constituents corresponding to the shapes of the serial number tapes 11 (a) to 11 (i) are not particularly limited, and the attributes can be set freely. There is no particular limitation on the shape of the tapes 11 (a) to 11 (i), and the shapes of the tapes 11 (a) to 11 (i) can be freely set.

  The attributes of the component corresponding to the symbols on the tapes 11 (a) to 11 (i) include the contamination level of the component due to radioactive material, the name of the component, the material of the component, the danger of the component, and the like. The attributes of the constituents corresponding to the shapes of the serial number tapes 11 (a) to 11 (i) are not particularly limited, and the attributes can be set freely. There is no particular limitation on the symbols of the tapes 11 (a) to 11 (i), and the symbols of the tapes 11 (a) to 11 (i) can be set freely.

  The tape 11 (a) of (a) among the serial number tapes 11 (a) to 11 (c) shown in FIG. 10 has a shape that undulates so as to draw an arc in the length direction, and is the lightest blue color. It is colored and the symbol (A) is displayed. As an example, the tape 11 (a) is used for dismantling the wall 26 that is a component of the central control room 23. As an example of the attribute of the wall 26, a name (wall) (for example, the shape of the tape represents the name). ), Material (shielding concrete) (for example, the color of the tape represents the material), radioactive material contamination level (low) (for example, the shade of the tape color represents the contamination level of the radioactive material), danger (Small) (for example, a tape symbol indicates danger).

  The bar code 14 displayed on the tape 11 (a) in FIG. 10 (a) includes not only the code representing the number data but also the code representing the color of the tape 11 (a) and the color of the tape 11 (a). A code representing shading, a code representing the shape of the tape 11 (a), and a code representing a symbol of the tape 11 (a) are included (however, the barcode 14 may not include these codes). ). The hard disk of the computer 13 stores nuclear power plant codes of a plurality of nuclear power plants and a plurality of building identification numbers (building identification identifiers) corresponding to these codes, and a central control room code, a turbine building code, A reactor building code and the like and a plurality of building identification numbers (building identification identifiers) corresponding to these codes are stored.

  On the hard disk of the computer 13, code data representing the color of the tape 11 (a), code data representing the color shade of the tape 11 (a), code data representing the shape of the tape 11 (a), tape 11 (a) And the attribute data (name (wall), material (shielded concrete), radioactive substance contamination level (low), risk (small)) of the wall 26 of the central control room 23 are associated with each other. Stored in state.

  Of the serial number tapes 11 (a) to 11 (c) shown in FIG. 10, the tape 11 (b) of (b) undulates so as to draw an arc in the length direction, and is the second darkest blue color. The symbol (B) is displayed. As an example, the tape 11 (b) is used for dismantling the wall 27 which is a component of the turbine building 24. As an example of the attributes of the wall 27, the name (wall), the material (shielding concrete), and radioactive material contamination Indicates level (medium) and danger (medium).

  The barcode 14 displayed on the tape 11 (b) in FIG. 10 (b) includes not only the code representing the number data but also the code representing the color of the tape 11 (b) and the color of the tape 11 (b). A code representing shading, a code representing the shape of the tape 11 (b), and a code representing the symbol of the tape 11 (b) are included (however, the barcode 14 may not include these codes). ). On the hard disk of the computer 13, code data representing the color of the tape 11 (b), code representing the color shade of the tape 11 (b), code data representing the shape of the tape 11 (b), and the code data representing the tape 11 (b) Code data representing a symbol, the attribute data of the wall 27 of the turbine building 24 (name (wall), material (shielding concrete), radioactive substance contamination level (medium), dismantling risk (medium)) are associated with each other Is stored in.

  The tape 11 (c) of (c) among the serial number tapes 11 (a) to 11 (c) shown in FIG. 10 has a shape that undulates so as to draw an arc in the length direction, and has the darkest blue color. It is colored and the symbol (C) is displayed. As an example, the tape 11 (c) is used for dismantling the wall 28 that is a component of the reactor building 25. As an example of the attributes of the wall 28, the name (wall), material (shielding concrete), radioactive substance Indicates pollution level (high) and danger (high).

  The bar code 14 displayed on the tape 11 (c) in FIG. 10 (c) includes not only the code representing the number data but also the code representing the color of the tape 11 (c) and the color of the tape 11 (c). A code representing shading, a code representing the shape of the tape 11 (c), and a code representing a symbol of the tape 11 (c) are included (however, the barcode 14 may not include these codes). ). On the hard disk of the computer 13, code data representing the color of the tape 11 (c), code data representing the color shade of the tape 11 (c), code data representing the shape of the tape 11 (c), tape 11 (c) And the attribute data (name (wall), material (shielding concrete), radioactive material contamination level (high), demolition risk (high)) of the wall 28 of the reactor building 25 are associated with each other. It is stored in the state.

  Of the serial number tapes 11 (d) to 11 (f) shown in FIG. 11, the tape 11 (d) of (a) is a shape that draws a plurality of triangles in the length direction, and is colored the lightest yellow. Symbol (A) is displayed. The tape 11 (d) in FIG. 17A is used for disassembling the pillar 29 which is a component of the central control room 23 as an example. As an example of the attribute of the pillar 29, a name (pillar) (for example, The shape of the tape represents the name), the material (metal) (for example, the color of the tape represents the material), the contamination level of the radioactive material (low) (for example, the shade of the color of the tape represents the contamination level of the radioactive material) ), Danger (small) (for example, a tape symbol represents danger).

  The bar code 14 displayed on the tape 11 (d) in FIG. 11 (a) includes not only the code representing the number data but also the code representing the color of the tape 11 (d) and the color of the tape 11 (d). A code representing shading, a code representing the shape of the tape 11 (d), and a code representing a symbol of the tape 11 (d) are included (however, the barcode 14 may not include these codes). ). On the hard disk of the computer 13, code data representing the color of the tape 11 (d), code data representing the color shade of the tape 11 (d), code data representing the shape of the tape 11 (d), tape 11 (d) Code data representing the symbol, and the attribute data (name (pillar), material (metal), radioactive substance contamination level (low), risk (small)) of the pillar 29 of the central control room 23 are associated with each other Is stored in.

  Of the serial number tapes 11 (d) to 11 (f) shown in FIG. 11, the tape 11 (e) of (b) is a shape that draws a plurality of triangles in the length direction and is colored second dark yellow. The symbol (B) is displayed. As an example, the tape 11 (e) is used for dismantling the pillar 30 that is a component of the turbine building 24. As an example of attributes of the pillar 30, the name (pillar), the material (metal), and the contamination level of radioactive substances. (Medium), indicates danger (Medium).

  The bar code 14 displayed on the tape 11 (e) in FIG. 11B includes not only the code representing the number data but also the code representing the color of the tape 11 (e) and the color of the tape 11 (e). A code representing shading, a code representing the shape of the tape 11 (e), and a code representing a symbol of the tape 11 (e) are included (however, the barcode 14 may not include these codes). ). On the hard disk of the computer 13, code data representing the color of the tape 11 (e), code data representing the color shade of the tape 11 (e), code data representing the shape of the tape 11 (e), tape 11 (e) In the state where the code data representing the symbol of the above and the attribute data (name (column), material (metal), radioactive substance contamination level (medium), danger (medium)) of the column 30 of the turbine building 24 are associated with each other. Stored.

  Of the serial number tapes 11 (d) to 11 (f) shown in FIG. 11, the tape 11 (f) of (c) is a shape that draws a plurality of triangles in the length direction, and is colored the darkest yellow. Symbol (C) is displayed. As an example, the tape 11 (f) is used for dismantling the pillar 31 that is a component of the reactor building 25. As an example of the attributes of the pillar 31, contamination of the name (pillar), material (metal), and radioactive material is possible. Indicates level (high) and danger (high).

  The bar code 14 displayed on the tape 11 (f) in FIG. 11C includes not only the code representing the number data but also the code representing the color of the tape 11 (f) and the color of the tape 11 (f). A code representing shading, a code representing the shape of the tape 11 (f), and a code representing a symbol of the tape 11 (f) are included (however, the barcode 14 may not include these codes). ). On the hard disk of the computer 13, code data representing the color of the tape 11 (f), code data representing the color shade of the tape 11 (f), code data representing the shape of the tape 11 (f), tape 11 (f) Code data representing the symbol of the above, the attribute data (name (column), material (metal), radioactive contamination level (high), risk (high)) of the column 31 of the reactor building 25 are associated with each other Is stored in.

  Of the serial number tapes 11 (g) to 11 (i) shown in FIG. 12, the tape 11 (g) of (a) has a shape of drawing a plurality of squares in the length direction, and is colored the lightest red. Symbol (A) is displayed. The tape 11 (g) in FIG. 12A is used as an example for dismantling the floor slab 32 that is a component of the central control room 23, and the name (floor slab) is an example of the attribute of the floor slab 32. (For example, the shape of the tape represents the name), the material (high-strength reinforced concrete) (for example, the color of the tape represents the material), the contamination level of the radioactive material (low) (for example, the shade of the tape color) Represents a contamination level of radioactive material), and represents a danger (small) (for example, a tape symbol represents a danger).

  The bar code 14 displayed on the tape 11 (g) in FIG. 12A includes not only the code representing the number data but also the code representing the color of the tape 11 (g) and the color of the tape 11 (g). A code representing shading, a code representing the shape of the tape 11 (g), and a code representing a symbol of the tape 11 (g) are included (however, the bar code 14 may not include those codes). ). On the hard disk of the computer 13, code data representing the color of the tape 11 (g), code data representing the color shade of the tape 11 (g), code data representing the shape of the tape 11 (g), tape 11 (g) And the attribute data (name, material (high-strength reinforced steel concrete), radioactive material contamination level (low), risk (small)) of the floor slab 32 of the central control room 23 are associated with each other. It is stored in the state.

  Of the serial number tapes 11 (g) to 11 (i) shown in FIG. 12, the tape 11 (h) of (b) has a shape that draws a plurality of squares in the length direction, and is colored the second darkest red. The symbol (B) is displayed. As an example, the tape 11 (h) is used for dismantling the floor slab 33 that is a component of the turbine building 24. As an example of the attributes of the floor slab 33, a name (floor slab) and a material (high-strength reinforced steel concrete) are used. ), Radioactive material contamination level (medium), and danger (medium).

  The bar code 14 displayed on the tape 11 (h) in FIG. 12B includes not only a code representing number data but also a code representing the color of the tape 11 (h) and the color of the tape 11 (h). A code representing shading, a code representing the shape of the tape 11 (h), and a code representing a symbol of the tape 11 (h) are included (however, the bar code 14 may not include those codes. ). On the hard disk of the computer 13, code data representing the color of the tape 11 (h), code data representing the color shade of the tape 11 (h), code data representing the shape of the tape 11 (h), tape 11 (h) Code data representing the symbol of the above, the attribute data of the floor slab 33 of the turbine building 24 (name, material (high-strength reinforced steel concrete), radioactive substance contamination level (medium), risk (medium)) are associated with each other Stored in state.

  Of the serial number tapes 11 (g) to 11 (i) shown in FIG. 12, the tape 11 (i) of (c) is a shape that draws a plurality of squares in the length direction and is colored the darkest red. Symbol (C) is displayed. As an example, the tape 11 (i) is used for dismantling the floor slab 34 that is a component of the reactor building 25. As an example of the attributes of the floor slab 34, a name (floor slab) and a material (high-strength reinforced steel frame) are used. Concrete), radioactive substance contamination level (high), danger (high).

  The barcode 14 displayed on the tape 11 (i) in FIG. 12C includes not only the code representing the number data but also the code representing the color of the tape 11 (i) and the color of the tape 11 (i). A code representing shading, a code representing the shape of the tape 11 (i), and a code representing a symbol of the tape 11 (i) are included (however, the barcode 14 may not include these codes. ). On the hard disk of the computer 13, code data representing the color of the tape 11 (i), code data representing the color shade of the tape 11 (i), code data representing the shape of the tape 11 (h), tape 11 (h) Code data representing the symbol of the above, the attribute data of the floor slab 34 of the reactor building 25 (name (floor slab), material (high-strength reinforced steel concrete), radioactive substance contamination level (high), danger (high)) Are stored in association with each other.

  FIG. 13 is a perspective view of the walls 26 to 28 to which the serial number tapes 11 (a) to 11 (c) shown in FIG. 10 are affixed, and FIG. 14 shows an example of the dismantling work of the walls 26 to 28. FIG. FIG. 15 is a diagram illustrating the dismantled items 35 to 37 after the respective walls 26 to 28 are disassembled. In FIG. 13, tapes 11 (a) to 11 (c) are attached to the walls 26 to 28 of the central control room 23, the turbine building 24, and the reactor building 25, and these serial number tapes 11 (a) to 11 (c). ) Is read by the barcode reader 12. In FIG. 15, only one demolished product 35-37 of the walls 26-28 is shown, and the barcode 14 of the serial number tapes 11 (a) -11 (c) affixed to the demolished products 35-37 is the barcode. It is read by the reader 12. The disassembly of the walls 26 to 28 will be described with reference to FIGS. 13 to 15 as follows.

  After dividing the central control room 23, turbine building 24, and reactor building 25 (building) of the nuclear power plant 22 (building) to be demolished into components (walls, columns, floor slabs), the walls 26 to The serial number tapes 11 (a) to 11 (c) are affixed to 28. Specifically, as shown in FIG. 13 (a), the tape 11 (a) of FIG. 10 (a) is randomly applied to one surface of the wall 26 of the central control chamber 23, and shown in FIG. 13 (b). As shown in FIG. 13B, the tape 11 (b) in FIG. 10B is randomly attached to one surface of the wall 27 of the turbine building 24, and as shown in FIG. 13C, the tape 11 in FIG. (C) is affixed to one surface of the wall 28 of the reactor building 25 at random.

  After affixing the serial number tapes 11 (a) to 11 (c) to the walls 26 to 28, the barcode located at the head of the barcodes 14 displayed on the tapes 11 (a) to 11 (c) 14 is read by the barcode reader 12, and the barcode 14 located at the end is read by the barcode reader 12. Note that the intermediate barcode 14 arranged between the barcode 14 located at the head and the barcode 14 located at the tail is not read.

  Further, the name of the nuclear power plant 22 is input using the numeric keypad unit of the barcode reader 12 or the keyboard 15 or mouse 16 of the computer 13 (the power plant name from the pull-down list of the plurality of nuclear power plants displayed on the display 17). Enter any of the main control room, turbine building, or reactor building (name) (select them from the pull-down list of the nuclear power plant building displayed on the display 17) The wall (name) is input (the wall can also be selected from the pull-down list of the component display displayed on the display 17).

  Using the numeric keypad unit of the bar code reader 12 or the keyboard 15 and mouse 16 of the computer 13, specific information (name, address, map, photograph, phone number, URL, etc.) of the nuclear power plant 22, the central control room 23 and the turbine building 24, Reactor building 25 specific information (name, address, map, photo, etc.), dismantling date (date, time), usage, building volume, etc. (building attribute input) and wall specific information (The first floor of the central control room 23, the entrance of the turbine building 24, etc.), dismantling date (date, time), strength, etc. are input (component attribute input). The attributes of the nuclear power plant 22, the central control room 23, the turbine building 24, and the reactor building 25 that can be input are not particularly limited, and are not limited to the illustrated attributes, and any other attribute can be input. Moreover, there is no limitation in particular in the attribute of the walls 26-28 which can be input, Not only the example attribute but all the other attributes can be input.

  The bar code reader 12 converts the data represented by the read bar code 14 or the input data into digital data and transfers the data to the computer 13 (when data is input from the keyboard 15 or the mouse 16, the bar code reader 12 12 transfers only the data represented by the read barcode 14 to the computer 13).

  When the central processing unit of the computer 13 receives the data from the barcode reader 12, the number represented by the barcode, the color of the tapes 11 (a) to 11 (c), and the color of the tapes 11 (a) to 11 (c). , Density of tape 11 (a) -11 (c), symbol of tape 11 (a) -11 (c), each attribute represented by barcode (name, material, contamination level of radioactive material, danger), The input nuclear power plant 22, central control room 23, turbine building 24, reactor building 25 building attributes and walls 26 to 28 are displayed on the display 17.

  After each data is displayed on the display 17 and the data is confirmed, the central processing unit of the computer 13 displays the nuclear power plant 22, the central control room 23, the turbine building 24, and the reactor building 25 (building). A specific building identification number (building specific identifier) to be specified is generated, and a specific building identification number (structural identification identifier) that specifies the walls 26 to 28 (components) is generated.

  After generating the building specific identification number and the component specific identification number, the central processing unit of the computer 13 associates the building specific identification number with the building specific identification number that specifies the nuclear power plant 22, and the central control room 23. In addition to associating the component identification number with the building identification number identifying either the turbine building 24 or the reactor building 25, the number data from the first number to the last number transferred from the barcode reader 12 (for example, When the leading number of the tape 11 (a) in FIG. 10 (a) is 0001 and the last number is 0020, the numbers from 0001 to 0020, the leading number of the tape 11 (b) in FIG. When the last number is 0040, the numbers from 0021 to 0040, the first number of the tape 11 (c) in FIG. 10C is 0041, and the last number is 0060. If, associated with the construct specific identification numbers and building specific identification number number) to 0041-0060.

  Further, the transferred building attribute data is associated with the building identification number and the building identification number, the transferred component attribute data is associated with the component identification number, and the attribute data represented by the barcode 14 is Associate with a component identification number. After these associations are completed, the central processing unit of the computer 13 includes the building identification number, the building identification number, the number data, the building attribute data, the building attribute data of the walls 26 to 28, and the barcode 14. The attribute data to be represented is stored in the hard disk (component storage means). On the bar code reader 12 and the display 17 of the computer 13, a data storage completion message for the central control room 23 → wall 26, turbine building 24 → wall 27, reactor building 25 → wall 28 is displayed.

  After each data is stored in the hard disk of the computer 13, the walls 26 to 28 are disassembled. In the dismantling work, as shown in FIGS. 14A to 14C, the walls 26 to 28 are finely disassembled, and the walls 26 to 28 are disassembled into a plurality of dismantled objects 35 to 37. The serialized tapes 11 (a) to 11 (c) remain on the dismantled objects 35 to 37 of the dismantled walls 26 to 28, and the bar codes displayed on the tapes 11 (a) to 11 (c). There are two cases, two cases, three cases, and the like. It should be noted that at least one barcode 14 remains readable on the serial number tapes 11 (a) to 11 (c) affixed to the dismantling materials 35 to 37 of the walls 26 to 28.

  As shown in FIGS. 15 (a) to 15 (c), the demolished product 35 using the bar code reader 12 as shown in FIGS. Before the dismantled items 35-37 are disassembled by reading the barcode 14 of the serial number tapes 11 (a) -11 (c) affixed to -37 (disassembled items 35-37 of the walls 26-28) Of the building (the nuclear power plant 22, the central control room 23, the turbine building 24, the reactor building 25) and the components (walls 26 to 28), and the attributes and the like of the building and the components Can be confirmed.

  When the barcode 14 of the serial number tapes 11 (a) to 11 (c) of the disassembled items 35 to 37 is read, the number data represented by the barcode 14 is transferred from the barcode reader 12 to the computer 13. The central processing unit of the computer 13 compares the number data transferred from the barcode reader 12 with the number data stored in the hard disk, and the disassembled items 35 to 37 are disassembled items 35 to 37 of the walls 26 to 28. Judgment (component identification means).

  For example, when the number data transferred from the bar code reader 12 is 0007, the dismantled object 36 is the dismantled object 36 of the wall 26 that constitutes the central control room 23 as compared with the number data stored in the hard disk. Judge that there is. When the number data transferred from the bar code reader 12 is 0035, it is determined that the dismantled object 37 is the dismantled object 37 of the wall 27 constituting the turbine building 24 by comparing with the number data stored in the hard disk. To do. Further, when the number data transferred from the bar code reader 12 is 0053, compared with the number data stored in the hard disk, the disassembled material 38 is a dismantled material 38 of the wall 28 constituting the reactor building 25. Judge that there is.

  The central processing unit of the computer 13 specifies the building identification number corresponding to the component identification number of the walls 26 to 28 (components), and the nuclear power plant 22 (building) corresponding to the building identification number. ), Any one of the central control room 23, the turbine building 24, and the reactor building 25 is specified. Furthermore, the building attribute data corresponding to the building specifying identification number and the building specifying identification number is specified, and the component attribute data corresponding to the building specifying identification number is specified.

  The central processing unit of the computer 13 includes a central control room 23 → the wall 26, the turbine building 24 → the wall 27, and the reactor building 25 → the wall 28, as well as the number indicated by the bar code, tapes 11 (a) to 11 (c). The color of the tape 11 (a) to 11 (c), the shape of the tape 11 (a) to 11 (c), the symbol of the tape 11 (a) to 11 (c), and the wall represented by the barcode 14 26-28 attributes (name, material, radioactive substance contamination level, risk), the inputted nuclear power plant 22, central control room 23, turbine building 24, reactor building 25 building attributes and walls 26- 28 component attributes are displayed on the display 17. Each data displayed on the display 17 can be output from the printer.

  16 is a perspective view of the pillars 29 to 31 to which the serial number tapes 11 (d) to 11 (f) shown in FIG. 11 are attached, and FIG. 17 shows an example of the dismantling work of the pillars 29 to 31. FIG. FIG. 18 is a diagram illustrating the dismantled items 38 to 40 after the respective columns 29 to 31 are disassembled. In FIG. 16, tapes 11 (d) to 11 (f) are affixed to the pillars 29 to 31 of the central control room 23, the turbine building 24, and the reactor building 25, and these serial number tapes 11 (d) to 11 (f). ) Is read by the barcode reader 12. In FIG. 18, only one disassembled product 38 to 40 of the pillars 29 to 31 is shown, and the barcode 14 of the serial number tapes 11 (d) to 11 (f) attached to the disassembled products 38 to 40 is a barcode. It is read by the reader 12. The disassembly of the pillars 29 to 31 will be described with reference to FIGS. 16 to 18 as follows.

  The serial number tapes 11 (d) to 11 (f) are attached to the pillars 29 to 31 of the central control room 23, the turbine building 24, and the reactor building 25 (building) of the nuclear power plant 22 (building) to be dismantled. To do. Specifically, as shown in FIGS. 16A to 16C, the tape 11 (d) of FIG. 11A is randomly attached to the peripheral surface of the column 29 of the central control chamber 23, and FIG. The tape 11 (e) of (b) is affixed randomly to the peripheral surface of the column 30 of the turbine building 24, and the tape 11 (f) of FIG. 11 (c) is attached to the peripheral surface of the column 31 of the reactor building 25. Affixed randomly.

  After affixing the serial number tapes 11 (d) to 11 (f) to the pillars 29 to 31, the barcode located at the head of the barcodes 14 displayed on the tapes 11 (d) to 11 (f) 14 is read by the barcode reader 12, and the barcode 14 located at the end is read by the barcode reader 12. Furthermore, using the numeric keypad unit of the barcode reader 12 or the keyboard 15 and mouse 16 of the computer 13, the name of the nuclear power plant 22 is input, and any of the central control room, turbine building, and reactor building (name) is input. At the same time, a column (name) is input (a column can also be selected from a pull-down list of component display displayed on the display 17).

  Using the numeric keypad unit of the barcode reader 12 or the keyboard 15 and mouse 16 of the computer 13, the specific information of the nuclear power plant 22, the specific information of the central control room 23, the turbine building 24, and the reactor building 25, the dismantling date and time, the usage, While entering the building volume and the like (input of building attributes), input the specific information of the pillars 29 to 31 (center of the central control room 23, the left end of the reactor building 25, etc.), dismantling date and time, strength, etc. (component attributes) input). In addition, there is no limitation in particular in the attribute of the pillars 29-31 which can be input, Not only the example attribute but all the other attributes can be input.

  The bar code reader 12 transfers the data represented by the read bar code 14 and the input data to the computer 13. When the central processing unit of the computer 13 receives the data from the barcode reader 12, the number represented by the barcode, the color of the tapes 11 (d) to 11 (f), and the color of the tapes 11 (d) to 11 (f). , The shape of the tapes 11 (d) to 11 (f), the symbols of the tapes 11 (d) to 11 (f), and the attributes of the columns 29 to 31 represented by the barcode (name, material, contamination level of radioactive material) , Risk), the inputted nuclear power plant 22, central control room 23, turbine building 24, reactor building 25 building attributes and pillar 29-31 component attributes are displayed on the display 17.

  After each data is displayed on the display 17 and the data is confirmed, the central processing unit of the computer 13 provides a component identification number (component identification identifier) that identifies the pillars 29 to 31 (components). Generate. In addition, the building specific identification number which specifies the nuclear power plant 22, the central control room 23, the turbine building 24, and the reactor building 25 (building) uses those generated in the storage of the data of the walls 26-28. .

  After generating the component identification numbers that identify the pillars 29 to 31, the central processing unit associates the component identification numbers with the building identification numbers that identify the nuclear power plant 22, the central control room 23, the turbine building 24, the building specific identification number is associated with the building specific identification number that identifies one of the reactor buildings 25, and the number data from the first number to the last number transferred from the barcode reader 12 (for example, FIG. 11). When the first number of the tape 11 (d) in (a) is 0100 and the last number is 0120, the numbers from 0100 to 0120, the first number of the tape 11 (e) in FIG. Is 0140, 011 to 0140, the leading number of tape 11 (f) in FIG. 11C is 0141, and the last number is 00140. The number) of up to 0160 associated with the construct specific identification numbers and building specific identification number.

  Further, the transferred building attribute data is associated with the building identification number and the building identification number, the transferred component attribute data is associated with the component identification number, and the attribute data represented by the barcode 14 is Associate with a component identification number. After completing the association, the central processing unit of the computer 13 has the building identification number, the building identification number, the number data, the building attribute data, the component attribute data of the pillars 29 to 31 and the barcode 14. The attribute data to be represented is stored in the hard disk (component storage means). On the bar code reader 12 or the display 17 of the computer 13, a data storage completion message for the central control room 23 → column 29, the turbine building 24 → column 30, and the reactor building 25 → column 31 is displayed.

  After each data is stored in the hard disk of the computer 13, the disassembly work of these pillars 29 to 31 is performed. In the dismantling work, as shown in FIGS. 17A to 17C, the pillars 29 to 31 are finely disassembled, and the pillars 29 to 31 are disassembled into a plurality of dismantled objects 38 to 40. The serial number tapes 11 (d) to 11 (f) remain in the dismantled articles 38 to 40 of the disassembled pillars 29 to 31, and the bar codes displayed on the tapes 11 (d) to 11 (f) There are two cases, two cases, three cases, and the like. It should be noted that at least one barcode 14 remains readable on the serial number tapes 11 (d) to 11 (f) affixed to the dismantled items 38 to 40 of the pillars 29 to 31.

  As shown in FIGS. 18 (a) to 18 (c), the dismantled article 38 is used by using the barcode reader 12 as shown in FIGS. Before the disassembled articles 38 to 40 are disassembled by reading the barcode 14 of the serial number tapes 11 (d) to 11 (f) attached to -40 (disassembled articles 38 to 40 of the pillars 29 to 31) Of the building (the nuclear power plant 22, the central control room 23, the turbine building 24, the reactor building 25) and the components (pillars 29 to 31) can be confirmed, and the attributes and the like of these buildings and components Can be confirmed.

  When the barcode 14 of the serial number tapes 11 (d) to 11 (f) of the dismantled items 38 to 40 is read, the number data represented by the barcode 14 is transferred from the barcode reader 12 to the computer 13. The central processing unit of the computer 13 compares the number data transferred from the barcode reader 12 with the number data stored in the hard disk, and the dismantled items 38 to 40 are disassembled items 38 to 40 of the pillars 29 to 31. Judgment (component identification means).

  For example, when the number data transferred from the barcode reader 12 is 0109, the dismantled product 39 is compared with the number data stored in the hard disk, and the dismantled product 39 is the dismantled product 39 of the pillar 29 constituting the central control room 23. Judge that there is. When the number data transferred from the bar code reader 12 is 0129, it is compared with the number data stored in the hard disk and it is determined that the dismantled object 40 is the dismantled object 40 of the pillar 30 constituting the turbine building 24. To do. Further, when the number data transferred from the barcode reader 12 is 0145, the dismantled object 41 is a dismantled object 41 of the pillar 31 that constitutes the reactor building 25 in comparison with the number data stored in the hard disk. Judge that there is.

  The central processing unit of the computer 13 specifies the building identification number corresponding to the component identification number of the pillars 29 to 31 (components), and the nuclear power plant 22 (building) corresponding to the building identification number. ), The central control room 23, the turbine building 24, and the reactor building 25 (building) are specified. Furthermore, the building attribute data corresponding to the building specifying identification number and the building specifying identification number is specified, and the component attribute data corresponding to the building specifying identification number is specified.

  The central processing unit of the computer 13 includes the central control room 23 → the pillar 29 and the turbine building 24 → the pillar 30 and the reactor building 25 → the pillar 31 as well as the number indicated by the barcode, the tapes 11 (d) to 11 (f). , Color density of tapes 11 (d) to 11 (f), shape of tapes 11 (d) to 11 (f), symbols of tapes 11 (d) to 11 (f), column 29 represented by bar code 31 attributes (name, material, radioactive material contamination level, risk), the nuclear power plant 22 and the central control room 23, the turbine building 24, the reactor building 25 building attributes and the columns 29 to 31 Are displayed on the display 17. Each data displayed on the display 17 can be output from the printer.

  FIG. 19 is a perspective view of the floor slabs 32 to 34 to which the serial number tapes 11 (g) to 11 (i) shown in FIG. 12 are affixed, and FIG. 20 is an example of a dismantling operation of the floor slabs 32 to 34. FIG. FIG. 21 is a diagram illustrating the dismantled articles 41 to 43 after the floor slabs 32 to 34 are dismantled. In FIG. 19, tapes 11 (g) to 11 (i) are attached to the floor slabs 32 to 34 of the central control room 23, the turbine building 24, and the reactor building 25, and these serial number tapes 11 (g) to 11 ( The barcode 14 displayed in i) is read by the barcode reader 12. In FIG. 21, only one demolished product 41 to 43 of the floor slabs 32 to 34 is shown, and the bar code 14 of the serial number tapes 11 (g) to 11 (i) attached to the demolished products 41 to 43 is a bar code. It is read by the code reader 12. The disassembly of the floor slabs 32 to 34 will be described with reference to FIGS. 19 to 21 as follows.

  Serial number tapes 11 (g) to 11 (i) are placed on the floor slabs 32 to 34 of the central control room 23, the turbine building 24, and the reactor building 25 (building) of the nuclear power plant 22 (building) to be dismantled. Affix it. Specifically, as shown in FIGS. 19 (a) to 19 (c), the tape 11 (g) of FIG. 12 (a) is randomly attached to one surface of the floor slab 32 of the central control chamber 23, and FIG. The tape 11 (h) of (b) is affixed to one surface of the floor slab 33 of the turbine building 24 at random, and the tape 11 (i) of FIG. Affixed randomly.

  After affixing the serial number tapes 11 (g) to 11 (i) to the floor slabs 32 to 34, the bar 14 located at the head of the bar codes 14 displayed on the tapes 11 (g) to 11 (i) The barcode 14 is read by the barcode reader 12, and the barcode 14 positioned at the tail is read by the barcode reader 12. Furthermore, using the numeric keypad unit of the barcode reader 12 or the keyboard 15 and mouse 16 of the computer 13, the name of the nuclear power plant 22 is input, and any of the central control room, turbine building, and reactor building (name) is input. At the same time, the floor slab (name) is input (the floor slab can be selected from the pull-down list of the component display displayed on the display 17).

  Using the numeric keypad unit of the barcode reader 12 or the keyboard 15 and mouse 16 of the computer 13, the specific information of the nuclear power plant 22, the specific information of the central control room 23, the turbine building 24, and the reactor building 25, the dismantling date and time, the usage, While inputting the building volume and the like (building attribute input), input the specific information of the floor slabs 32 to 34 (the corridor of the central control room 23, the passage of the reactor building 25, etc.), the dismantling date and time, the strength, etc. Attribute input). In addition, there is no limitation in particular in the attribute of the floor slabs 32-34 which can be input, Not only the attribute of illustration but all the other attributes can be input.

  The bar code reader 12 transfers the data represented by the read bar code 14 and the input data to the computer 13. When the central processing unit of the computer 13 receives the data from the barcode reader 12, the number represented by the barcode, the color of the tapes 11 (g) to 11 (i), and the color of the tapes 11 (g) to 11 (i). , The shape of the tapes 11 (g) to 11 (i), the symbols of the tapes 11 (g) to 11 (i), and the attributes of the floor slabs 32 to 34 represented by the barcode (name, material, contamination of radioactive substances) Level, risk), the inputted nuclear power plant 22, central control room 23, turbine building 24, reactor building 25 building attributes and floor slabs 32-34 component attributes are displayed on the display 17.

  After each data is displayed on the display 17 and confirmation of the data is performed, the central processing unit of the computer 13 specifies a component identification number (component identification identifier) that identifies the floor slabs 32 to 34 (components). Is generated. In addition, the building specific identification number which specifies the nuclear power plant 22, the central control room 23, the turbine building 24, and the reactor building 25 (building) uses those generated in the storage of the data of the walls 26-28. .

  After generating the component identification numbers that identify the floor slabs 32-34, the central processing unit associates the component identification numbers with the building identification numbers that identify the nuclear power plant 22, and the central control room 23, turbine The component identification number is associated with the building identification number that identifies either the building 24 or the reactor building 25, and the number data from the first number to the last number transferred from the barcode reader 12 (for example, FIG. When the first number of the tape 11 (g) of 12 (a) is 0200 and the last number is 0230, the numbers from 0200 to 0230, the first number of the tape 11 (h) of FIG. When the number is 0260, the numbers from 0231 to 0260, the leading number of the tape 11 (i) in FIG. 12C is 0261, and the last number is 0290. The number) of up to 1 to 0290 associated with the construct specific identification numbers and building specific identification number.

  Further, the transferred building attribute data is associated with the building identification number and the building identification number, the transferred component attribute data is associated with the component identification number, and the attribute data represented by the barcode 14 is Associate with a component identification number. After completing the association, the central processing unit of the computer 13 executes the building identification number, the building identification number, the number data, the building attribute data, the building attribute data of the floor slabs 32-34, and the barcode 14. Is stored in the hard disk (component storage means). On the bar code reader 12 and the display 17 of the computer 13, a data storage completion message for the central control room 23 → floor slab 32, turbine building 24 → floor slab 33, reactor building 25 → floor slab 34 is displayed.

  After each data is stored in the hard disk of the computer 13, the floor slabs 32-34 are dismantled. In the dismantling work, as shown in FIGS. 20A to 20C, the floor slabs 32 to 34 are finely disassembled, and the floor slabs 32 to 34 are disassembled into a plurality of dismantled articles 41 to 43. The serialized tapes 11 (g) to 11 (i) remain in the demolished articles 41 to 43 of the demolished floor slabs 32 to 34, and the bars displayed on the tapes 11 (g) to 11 (i). There are one case, two cases, three cases, and the like. Note that at least one barcode 14 remains readable on the serial number tapes 11 (g) to 11 (i) affixed to the disassembled materials 41 to 43 of the floor slabs 32 to 34.

  21. As shown in FIGS. 21 (a) to 21 (c), the demolished material 41-43 dismantled from the floor slabs 32-34 is disassembled using the barcode reader 12, as shown in FIGS. 21 (a) to 21 (c). By reading the barcode 14 of the serial number tapes 11 (g) to 11 (i) affixed to 41 to 43 (disassembled articles 41 to 43 of the floor slabs 32 to 34), the disassembled articles 41 to 43 are disassembled. Can confirm the previous buildings (the nuclear power plant 22, the central control room 23, the turbine building 24, the reactor building 25) and the components (floor slabs 32 to 34), and the building and its components Can be confirmed.

  When the barcode 14 of the serial number tapes 11 (g) to 11 (i) of the dismantled items 41 to 43 is read, the number data represented by the barcode 14 is transferred from the barcode reader 12 to the computer 13. The central processing unit of the computer 13 compares the number data transferred from the barcode reader 12 with the number data stored in the hard disk, and the dismantled articles 41 to 43 are dismantled objects 41 to 43 of the floor slabs 32 to 34. (Constituent specifying means).

  For example, when the number data transferred from the bar code reader 12 is 0227, it is compared with the number data stored in the hard disk, and the disassembled material 42 of the floor slab 32 that constitutes the central control room 23. It is judged that. When the number data transferred from the barcode reader 12 is 0251, it is compared with the number data stored in the hard disk, and the dismantled product 43 is the dismantled product 43 of the floor slab 33 constituting the turbine building 24. to decide. Further, when the number data transferred from the bar code reader 12 is 0278, it is compared with the number data stored in the hard disk, and the dismantled product 44 of the floor slab 34 in which the dismantled product 44 constitutes the reactor building 25. It is judged that.

  The central processing unit of the computer 13 identifies the building identification number corresponding to the component identification number of the floor slabs 32 to 34 (components), and the nuclear power plant 22 (construction) corresponding to the building identification number. The central control room 23, the turbine building 24, and the reactor building 25 (building) are specified from the component specifying identification number. Furthermore, the building attribute data corresponding to the building specifying identification number and the building specifying identification number is specified, and the component attribute data corresponding to the building specifying identification number is specified.

  The central processing unit of the computer 13 includes a central control room 23 → floor slab 32 and a turbine building 24 → floor slab 33, a reactor building 25 → floor slab 34, and numbers represented by barcodes, tapes 11 (g) to 11 (11). The color of (i), the shade of the color of the tapes 11 (g) to 11 (i), the shape of the tapes 11 (g) to 11 (i), the symbols of the tapes 11 (g) to 11 (i), and the barcode Each attribute (name, material, radioactive substance contamination level, risk) of the floor slabs 32 to 34 to be represented, the inputted nuclear power plant 22 and central control room 23, turbine building 24, reactor building 25 building attributes and The component attributes of the floor slabs 32 to 34 are displayed on the display 17. Each data displayed on the display 17 can be output from the printer.

  The demolition management system 10 uses the bar code 14 displayed on the serial number tapes 11 (a) to 11 (i), so that the central control room 23 and the turbine of the nuclear power plant 22 to which the demolitions 35 to 43 belong. Components such as the walls 26 to 28, the columns 29 to 31 and the floor slabs 32 to 34 constituting the building 24 and the reactor building 25 can be specified for each demolition 35 to 43, and the walls 26 to 28 and the columns Track and grasp the components (walls 26-28, columns 29-31, floor slabs 32-34) of the nuclear power plant 22 to which the respective demolitions 35-43 belonged after the dismantling of 29-31 and floor slabs 32-34 can do.

  The demolition management system 10 includes a central control room 23 of the nuclear power plant 22, a turbine building 24, and walls 26 to 28, columns 29 to 31, and floor slabs 32 to 34 that constitute the reactor building 25. Even if the demolition products 35 to 43 are generated, the demolition products 35 to 43 are not disassembled through the barcode 14 of the serial number tapes 11 (a) to 11 (i) attached to the disassembly products 35 to 43. A structure (walls 26-28, pillars 29-31, floor slabs 32-34) can be specified reliably. The dismantlement management system 10 uses the barcodes 14 of the serial number tapes 11 (a) to 11 (i) to construct the dismantling materials 35 to 43 before dismantling them (walls 26 to 28, pillars 29 to 31, Since the floor slabs 32 to 34) can be reliably identified, the central control room 23 of the certain nuclear power plant 22, the turbine building 24, the walls 26 to 28 of the reactor building 25, the columns 29 to 31, and the floor slabs 32 to 32 34 is dismantled from the group of dismantled components of the nuclear power plant 22, or the central control room 23 of a certain nuclear power plant 22, the turbine building 24, and the walls 26 to 28 of the reactor building 25. Even if the dismantlements 35 to 43 obtained by dismantling the pillars 29 to 31 and the floor slabs 32 to 34 are mixed in as dismantling materials of other nuclear facilities, the walls 26 to 28, the pillars 29 to 31 and the floor slab 32 ~ 34 before dismantling The composition of the nuclear power plant 22 (wall 26 to 28, column 29 to 31, the floor slab 32 to 34) can reveal, it is possible to prevent the attribution unknown of demolition material 35 to 43.

  The demolition management system 10 is connected to the computer 13 in a state where various attributes of the nuclear power plant 22, the central control room 23, the turbine building 24, and the reactor building 25 are associated with the building identification number and the component identification number. Since the various attributes of the walls 26 to 28 and the pillars 29 to 31 and the floor slabs 32 to 34 are stored in the computer 13 in association with the component identification numbers, the walls 26 to 28 and the pillars 29 to 29 are stored. 31, even after the dismantling of the floor slabs 32 to 34, the attributes of the buildings and structures to which the dismantling materials 35 to 43 belong can be grasped for each dismantling materials 35 to 43, and the dismantling materials 35 to 43 are Each building can be managed separately for each attribute, and the demolition objects 35 to 43 can be managed for each component and for each attribute.

  In the dismantling work in the central control room 23, the turbine building 24, and the reactor building 25 of the nuclear power plant 22, the walls 26 to 28, the columns 29 to 31, the floor slabs 32 to 34, etc. It is required that the attributes of the constituents can be traced and grasped after dismantling, and the attributes of the constituents to which the dismantling objects 35 to 43 after dismantling belong are required to be traceable and comprehensible. Although management for each attribute of these demolitions 35 to 43 is required later, this demolition management system 10 is required for dismantling the central control room 23 of the nuclear power plant 22, the turbine building 24, and the reactor building 25. Such conditions can be satisfied.

DESCRIPTION OF SYMBOLS 10 Demolition management system 11 Serial number tape 11 (a) -11 (i) Serial number tape 12 Bar code reader (identification code reader)
13 Computer 14 Bar code (identification code)
18 walls (components)
19 Pillars (components)
20 Demolition 21 Demolition 22 Nuclear power plant (building)
23 Central control room (building)
24 Turbine building (building)
25 Nuclear Building (Building)
26 Wall (component)
27 Wall (component)
28 Wall (component)
29 pillars (components)
30 pillars (components)
31 pillars (components)
32 Floor slab (component)
33 Floor slabs
34 Floor slabs
35-37 Demolition (wall)
38-40 Demolition (pillar)
41-43 Demolition (floor slab)

Claims (11)

In a dismantlement management system for managing a plurality of dismantled objects after dismantling various components constituting the building,
The building is a nuclear facility, and the demolition management system includes a serial number tape on which a plurality of printable identification codes representing consecutive numbers are displayed, and an identification code displayed on the serial number tape. Utilizing an identification code reader to be read and a computer to which the identification code number is transferred from the identification code reader, management prior to disassembly before disassembling the components constituting the nuclear facility, and disassembling the components And after dismantling management
In the management before dismantling, the serial number tapes on which the plurality of identification codes are displayed are affixed to the composition before dismantling constituting the nuclear facility, and the serial number tapes affixed to the constituent before dismantling Of the consecutive numbers represented by the identification code, the first number and the last number are read by the identification code reader, and the computer specifies a component identification identifier for identifying each component and the first number to the last number. Executing a component storage means for storing the numbers in association with consecutive numbers;
In the post-disassembly management, the constituents constituting the nuclear facility are disassembled into a plurality of dismantled objects that remain so that at least one identification code of the serial number tape can be read, and the constituents are disassembled into a plurality of dismantled objects. after dismantling, the serial number tape identification code affixed to their dismantling was read by said identification code reader, corresponds to the number of the computer represents the identification code of the serial number tape affixed to their dismantling thereof A dismantlement management system for executing a constituent identifying unit that identifies a constituent to which the dismantlement belongs from a constituent identification identifier to be performed. 2. The computer stores various attributes of the components in a state associated with the component identification identifier, and outputs attributes of the component to which the demolition belongs in the post-disassembly management. Demolition management system described. 3. The dismantled product management system uses a plurality of types of the serial number tapes distinguished by various types of colors, and the attribute of the component can be recognized by the color of the serial number tapes. Demolition management system described in 1. 2. The dismantlement management system uses a plurality of types of serial tapes distinguished by color shades, and the attribute of the component can be recognized by the color shades of the serial tapes. 3. Demolition management system in any one of 3. 5. The dismantlement management system uses a plurality of types of the serial number tapes distinguished by various types, and the attributes of the components can be recognized by the form of the serial number tapes. The dismantlement management system according to any one of the above. 2. The dismantlement management system uses a plurality of types of serial number tapes distinguished by various types of symbols, and the attributes of the components can be recognized by symbols displayed on the serial number tapes. The dismantlement management system according to claim 5. The dismantlement management system according to any one of claims 1 to 6 , wherein the attribute of the component is a contamination level of the component in the nuclear facility with radioactive materials . The demolished matter management system according to any one of claims 1 to 7 , wherein the attribute of the component is a risk of the component in the nuclear facility . The dismantlement management system according to any one of claims 1 to 8 , wherein the attribute of the component is a material of the component in the nuclear facility . The dismantlement management system according to any one of claims 1 to 9 , wherein the attributes of the constituents are specific information and dismantling date and time of the constituents in the nuclear facility . The identification code is a bar code, in the connection tape, the bar code is either equidistant spaced claim sequentially arranged in a line in the state 1 to claim 10 to the length direction of the connecting tape Demolition management system described in 1.

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