JP2004069352A - Radiation detection element integrated card, dosage reading write-in system, in/out management system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radiation detection element integrated card as a back up dosimeter and an in/out management system using the card, by including OSL in an ID card which a user always carries. <P>SOLUTION: The in/out management system 130 comprises the radiation detection element integrated card 1 provided with a fluorescent material coupling part 3 which attaches fluorescent material 2 used in order to detect radiation, and a chip 4 having a memory region in which user's identification information and exposure information are written; a measuring instrument 100 which writes the exposure information in the memory region, by contact with the card 1 or by reading the user's identification information and exposure information at nonconatact; and an in/out system 110 which can control in/out of a user by reading the dose information from the card 1. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a radiation detecting element integrated card for measuring a radiation exposure dose of a user working in a controlled area such as a nuclear power plant, and a radiation dose reading / writing for reading and writing the radiation detecting element integrated card. The present invention relates to a system and an exposure management system using the radiation detecting element integrated card.
[0002]
[Prior art]
A user working in a controlled area such as a nuclear power plant (hereinafter referred to as “user”) is required to control the radiation exposure dose value and the working time in the controlled area.
[0003]
An access control system of a nuclear power plant will be described as an example. FIG. 10 shows a configuration diagram of a conventional entry / exit management system. FIG. 11 shows an embodiment of the memory configuration of the memory area of the IC card 201. FIG. 12 shows an embodiment of the record definition of the database of the radiation management computer.
[0004]
The conventional entry / exit management system 230 of FIG. 10 includes an IC card 201, an entry / exit device 210, and a radiation management computer 40. The IC card 201 has a chip 204 having a memory area in which identification information of the user 30 is written. The measuring device 200 reads the identification information of the user 30 by making contact with the IC card 201 or in a non-contact manner, and writes the exposure information in the memory area. The entry / exit device 210 reads dose information from the electronic personal dosimeter 20 and controls entry / exit of the user 30. In the online processing in which the entry / exit device 210 and the radiation management computer 40 are connected via a dedicated line, the radiation management computer 40 performs all the actual data storage and entry / exit control of the entry / exit processing. For example, due to the maintenance work of the radiation management computer 40, in the off-line processing that is not connected via the dedicated line of the radiation management computer 40 and the radiation management computer 40, the actual data storage and the entrance / exit control of the entrance / exit processing are all performed by the entrance / exit apparatus 210 Do it alone. Then, after the maintenance work of the radiation management computer 40 is completed, the actual data of the entry / exit processing is transmitted to the radiation management computer 40.
[0005]
The memory configuration of the memory area of the IC card 201 in FIG. 11 will be described. The user ID is a code for uniquely identifying the user 30. The expiration date indicates a time period during which the user 30 can enter and leave the management area. The user category indicates a qualification when the user 30 enters or leaves the management area. The affiliation code is a code for uniquely identifying the affiliation company of the user 30. The IC card 201 stores fixed data and does not operate to rewrite the data each time entry / exit is performed.
[0006]
The record definition of the database of the radiation management computer in FIG. 12 will be described. FIG. 12A shows a user DB. The user ID is a code for uniquely identifying the user 30. The expiration date indicates a time period during which the user 30 can enter and leave the management area. The user category indicates a qualification when the user 30 enters or leaves the management area. The affiliation code is a code for uniquely identifying the affiliation company of the user 30. FIG. 12B shows the user's performance data DB. The user ID is a code for uniquely identifying the user 30. The exposure information of the user indicates the past exposure record of the user 30. The one-year dose value indicates a dose value for the past one year. The three-month dose value indicates a dose value in the past three months. The monthly dose value indicates the dose value of the previous month. This month's dose value indicates the dose value of this month. The weekly dose value indicates the dose value for the current week. The dose value on the day indicates the dose value already exposed on the day. The work time on the day indicates the time of work already performed on the day. The user's work number is a work number permitted to the user 30. The planned dose value is a dose value planned for the work content of the day. The planned work time is the work time planned for the work content of the day.
[0007]
When the user enters the management area, the electronic personal dosimeter sets the dose value obtained by subtracting the dose value on the day from the planned dose value and the time obtained by subtracting the work time on the day from the planned work time. The electronic personal dosimeter verifies the actually measured dose value (hereinafter referred to as actual dose value) and the working time (hereinafter referred to as actual working time) in real time, and the actual dose value exceeds the planned dose value during work. If an alarm occurs or the actual work time exceeds the planned dose value, an audible alarm will sound and the user will be notified. The user recognizes the alarm condition based on the alarm sound and the display value of the electronic personal dosimeter, and leaves the control area.
[0008]
When the user leaves the controlled area, read the actual dose value and actual working time of the electronic personal dosimeter and update the user's exposure information.
[0009]
Conventionally, a user carries an electronic personal dosimeter and a backup dosimeter such as a film badge to carry out work in a controlled area. The backup dosimeter is to ensure reading of the actual dose value if the electronic personal dosimeter fails and cannot read the actual dose value or the actual working time. Film badges are often used as a medium for backup dosimeters.
[0010]
Film badges are usually changed on a monthly basis, and development and radiation dose measurement are performed by a specialized measurement company. The radiation manager compares the integrated value of the actual dose value of the electronic personal dosimeter with the radiation dose of the backup dosimeter on a monthly basis, and confirms that the integrated value of the actual dose value for the month is correct.
[0011]
The film badge was sent to a specialized measurement company for development and radiation dose measurement, and it took at least a few days for the results to be known. There is no problem during normal operation, but there is a problem with the measurement method that takes several days as described above when the electronic personal dosimeter breaks down and it is urgent to determine the actual dose value. The radiation manager has an obligation to determine the actual dose value and the actual working time of the user on a daily basis. The radiation manager cannot permit the work on the next day if the actual dose value and the actual work time for that day have not been determined.
[0012]
As a result, the user has no work permission and cannot work in the controlled area. If the user is an inspector or site manager, it may affect the process progress at the work site.
[0013]
The inability of the user to work in the controlled area due to the failure of the electronic personal dosimeter, rather than a factor attributable to the user, is severe for the user. In order to avoid such a situation, it has been desired to use a backup dosimeter capable of real-time measurement.
[0014]
Next, OSL (Optical Stimulated Luminescence) will be described. OSL was developed as a next-generation dosimeter. As an OSL measurement method, for example, JP-T-2000-503396 and JP-T-2000-503759 are disclosed. These documents describe OSL components, laser irradiation methods, and light reception measurement methods.
[0015]
Further, Japanese Patent Application Laid-Open No. 11-237479 discloses a method in which an OSL is provided at the tip of an irradiation optical path fiber and a light receiving fiber, and a laser beam is applied to the irradiation optical path fiber to receive and measure the OSL light emitted from the OSL. Have been.
[0016]
In conventional thermofluorescence dosimeter readers, the size of the device housing was sometimes large in order to eliminate the effects of heat due to continuous use. However, OSL uses laser light, so there is no need to worry about heat and compact reading is possible. A part can be formed.
[0017]
[Problems to be solved by the invention]
The present invention has been made in consideration of the above points, and uses an OSL (Optical Stimulated Luminescence) as a fluorescent material used for detecting radiation of a backup dosimeter.
[0018]
The present invention provides a radiation detecting element integrated card that measures a radiation exposure dose by incorporating an OSL into an ID card that is always carried by a user. Further, a radiation dose reading and writing system for reading and writing the radiation detecting element integrated card by reading the OSL reading section into the inside of the measuring instrument and the access device, and an exposure management system using the radiation detecting element integrated card I will provide a.
[0019]
[Means for Solving the Problems]
In order to solve the above problem, a radiation detecting element integrated card according to claim 1 of the present invention includes a fluorescent material mounting portion for mounting a fluorescent material used for detecting radiation, and a chip having a memory area. I do.
[0020]
With the above configuration, the radiation detecting element integrated card can output the actual dose value of the fluorescent material and store the user management information therein. As a result, even when the electronic personal dosimeter fails and the actual dose value cannot be read, the actual dose value for the user's work in the work concerned must be determined by adopting the actual dose value of the radiation detecting element integrated card. Can be.
[0021]
A radiation detecting element integrated card according to a second aspect of the present invention includes a fluorescent material mounting portion for mounting a fluorescent material used for detecting radiation, and a chip having a memory area.
[0022]
With the above configuration, the radiation detecting element-integrated card can be replaced with a fluorescent material. As a result, the fluorescent material can be automatically replaced during the reading process in the access device.
[0023]
In the card with integrated radiation detecting element according to claim 3 of the present invention, the fluorescent material is OSL.
[0024]
With the above configuration, the radiation detecting element integrated card can use OSL as the fluorescent material.
[0025]
In the radiation detecting element integrated card according to the fourth aspect of the present invention, the user's exposure information is stored in the memory area of the chip.
[0026]
With the above configuration, the radiation detecting element integrated card can store the exposure information of the user.
[0027]
A radiation dose reading / writing system according to claim 5, wherein a chip having a fluorescent material mounting portion for mounting a fluorescent material used for detecting radiation, and a memory area in which user identification information and exposure information are written. By contacting the radiation detecting element-integrated card with the radiation detecting element-integrated card, or in a non-contact manner, the identification information and the exposure information of the user are read, and the exposure information is stored in the memory area. And a measuring instrument for writing.
[0028]
With the configuration described above, the radiation dose reading / writing system can read and write the user identification information and the exposure information stored in the radiation detecting element integrated card in a contact process or a non-contact manner in the reading process in the measuring instrument.
[0029]
The radiation dose reading and writing system according to claim 6 of the present invention has a configuration in which an exposure dose for a plurality of predetermined periods can be written in a memory area.
[0030]
With the above configuration, the radiation dose reading / writing system receives the radiation exposure for a predetermined period from the radiation management computer in the online operation in which the radiation management computer and the measurement device are connected in the reading process of the measurement device, You can write on the body card Further, the radiation dose reading / writing system can refer to the user's exposure amount during the predetermined period by reading out the exposure amount during the predetermined period stored in the radiation detecting element integrated card.
[0031]
According to a seventh aspect of the present invention, there is provided an entry / exit management system comprising: a fluorescent material mounting unit for mounting a fluorescent material used for detecting radiation; and a chip having a memory area in which user identification information and exposure information are written. By contacting the radiation detecting element integrated card with the radiation detecting element integrated card or the non-contact type, reads out the user identification information and the exposure information, and writes the exposure information in the memory area. It comprises a measuring device and an entrance / exit device capable of reading dose information from the radiation detecting element integrated card and controlling entrance / exit of the user.
[0032]
With the above configuration, even when the electronic personal dosimeter fails and the actual dose value cannot be read, the entrance / exit management system adopts the actual dose value of the radiation detecting element integrated card to enable the user to perform the work in the work. The actual dose value can be determined.
[0033]
Further, even in an off-line operation in which the radiation management computer and the entrance / exit device are not connected, the entrance / exit management system can read out user identification information and exposure information from the radiation detecting element integrated card and control entrance / exit. Further, the exit / entry management system can write the exposure information reflecting the results of the entrance / exit processing in the radiation detection element integrated card in the exit processing.
[0034]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0035]
(Embodiment 1)
Embodiment 1 of the present invention will be described with reference to FIGS.
[0036]
FIG. 1 is a configuration diagram of a radiation detecting element integrated card. FIG. 2 shows an embodiment of the memory configuration of the memory area.
[0037]
FIG. 1 is a configuration diagram of a radiation detecting element integrated card. The radiation detecting element integrated card 1 includes a fluorescent material mounting portion 3 for mounting a fluorescent material 2 used for detecting radiation, and a chip 4 having a memory area.
[0038]
FIG. 2 shows an embodiment of the memory configuration of the memory area. The user ID is a code for uniquely identifying the user 30. The expiration date indicates a time period during which the user 30 can enter and leave the management area. The user category indicates a qualification when the user 30 enters or leaves the management area. The affiliation code is a code for uniquely identifying the affiliation company of the user 30.
[0039]
The radiation detecting element integrated card 1 can output the actual dose value of the fluorescent material 2 and store user management information therein. As a result, even when the electronic personal dosimeter 20 fails and the actual dose value cannot be read, the actual dose value of the user 30 in the work can be obtained by adopting the actual dose value of the radiation detecting element integrated card 1. Can be fixed. Note that by using OSL as the fluorescent material, the size of the housing of the reading device can be reduced.
[0040]
(Embodiment 2)
Embodiment 2 of the present invention will be described with reference to FIG.
[0041]
FIG. 3 is a configuration diagram of the radiation detection element integrated card.
[0042]
The radiation detecting element integrated card 1 includes a fluorescent material mounting portion 3 for mounting a fluorescent material 2 used for detecting radiation, and a chip 4 having a memory area, and the fluorescent material 2 is replaceably mounted. FIG. 3A shows a state in which the fluorescent material 2 is attached to the radiation detecting element integrated card 1. FIG. 3B shows a state in which the fluorescent material 2 has been removed from the radiation detecting element integrated card 1. The fluorescent material 2 has a structure that can be easily removed and attached to the radiation detecting element integrated card 1.
[0043]
As a result, the radiation detecting element integrated card 1 can automatically exchange the fluorescent material 2 during the manual operation and the reading process in the reading device. Note that by using OSL as the fluorescent material, the size of the housing of the reading device can be reduced.
[0044]
(Embodiment 3)
Third Embodiment A third embodiment of the present invention will be described with reference to FIGS.
[0045]
FIG. 4 is a configuration diagram of the radiation detecting element integrated card. FIG. 5 shows an embodiment of the memory configuration of the memory area.
[0046]
FIG. 4 is a configuration diagram of the radiation detecting element integrated card. The radiation detecting element integrated card 1 includes a fluorescent material mounting portion 3 for mounting a fluorescent material 2 used for detecting radiation, and a chip 4 having a memory area.
[0047]
FIG. 5 shows an embodiment of the memory configuration of the memory area. The user ID is a code for uniquely identifying the user 30. The expiration date indicates a time period during which the user 30 can enter and leave the management area. The user category indicates a qualification when the user 30 enters or leaves the management area. The affiliation code is a code for uniquely identifying the affiliation company of the user 30. The exposure information of the user 30 indicates the past exposure record of the user 30. The one-year dose value indicates a dose value for the past one year. The three-month dose value indicates a dose value in the past three months. The monthly dose value indicates the dose value of the previous month. This month's dose value indicates the dose value of this month. The weekly dose value indicates the dose value for the current week. The dose value on the day indicates the dose value already exposed on the day. The work time on the day indicates the time of work already performed on the day.
[0048]
The radiation detecting element-integrated card can store the exposure information of the user 30 stored in only the radiation management computer 40 in the conventional radiation management system.
[0049]
(Embodiment 4)
Embodiment 4 of the present invention will be described with reference to FIGS.
[0050]
FIG. 6 is a configuration diagram of the radiation dose reading / writing system. FIG. 7 shows an embodiment of identification information and exposure information of the user 30 in the memory area.
[0051]
A configuration diagram of the radiation dose reading / writing system in FIG. 6 will be described. The radiation dose reading / writing system 120 includes the radiation detecting element integrated card 1 and the measuring instrument 100. The radiation detecting element integrated card 1 has a fluorescent material mounting portion 3 for mounting a fluorescent material 2 used for detecting radiation, and a chip 4 having a memory area. The measuring device 100 reads the identification information and the exposure information of the user 30 by making contact with the radiation detecting element integrated card 1 or in a non-contact manner, and writes the exposure information in the memory area.
[0052]
An embodiment of the identification information and the exposure information of the user in the memory area in FIG. 7 will be described. The user ID is a code for uniquely identifying the user 30. The expiration date indicates a time period during which the user 30 can enter and leave the management area. The user category indicates a qualification when the user 30 enters or leaves the management area. The affiliation code is a code for uniquely identifying the affiliation company of the user 30. The exposure information of the user 30 indicates the past exposure record of the user 30. The one-year dose value indicates a dose value for the past one year. The three-month dose value indicates a dose value in the past three months. The monthly dose value indicates the dose value of the previous month. This month's dose value indicates the dose value of this month. The weekly dose value indicates the dose value for the current week. The dose value on the day indicates the dose value already exposed on the day. The work time on the day indicates the time of work already performed on the day.
[0053]
The measuring device 100 reads identification information and exposure information of the user 30 of the radiation detecting element integrated card 1 by contact or non-contact. The measuring device 100 reads the dose value of the fluorescent material 2 and measures the present time at the one-year dose value, three-month dose value, one-month dose value, this-month dose value, weekly dose value, same-day dose value, and same-day work time of the exposure information. Add the result of Further, the measuring device 100 writes the updated exposure information on the radiation detecting element integrated card 1 in a contact or non-contact manner.
[0054]
With the above-described configuration, the radiation dose reading / writing system 120 reads out the identification information and the exposure information of the user 30 stored in the radiation detecting element integrated card in a reading process in the measuring device 100 in a contact or non-contact manner, and performs the current measurement. Exposure information reflecting the result of the above can be written.
[0055]
(Embodiment 5)
Embodiment 5 of the present invention will be described with reference to FIGS.
[0056]
FIG. 8 is a configuration diagram of the entry / exit management system. FIG. 9 shows an embodiment of identification information and exposure information of the user 30 in the memory area.
[0057]
A configuration diagram of the entry / exit management system in FIG. 8 will be described. The entrance / exit management system 130 includes the radiation detecting element integrated card 1 and the entrance / exit device 110. The radiation detection element integrated card 1 has a fluorescent material mounting portion 3 for mounting a fluorescent material 2 used for detecting radiation, and a chip 4 having a memory area in which identification information of the user 30 and exposure information are written. . The measuring device 100 reads the identification information and the exposure information of the user 30 by making contact with the radiation detecting element integrated card 1 or in a non-contact manner, and writes the exposure information in the memory area. The entry / exit device 110 reads dose information from the radiation detecting element integrated card 1 and controls entry / exit of the user 30.
[0058]
An embodiment of the identification information and the exposure information of the user in the memory area in FIG. 9 will be described. The user ID is a code for uniquely identifying the user 30. The expiration date indicates a time period during which the user 30 can enter and leave the management area. The user category indicates a qualification when the user 30 enters or leaves the management area. The affiliation code is a code for uniquely identifying the affiliation company of the user 30. The exposure information of the user 30 indicates the past exposure record of the user 30. The one-year dose value indicates a dose value for the past one year. The three-month dose value indicates a dose value in the past three months. The monthly dose value indicates the dose value of the previous month. This month's dose value indicates the dose value of this month. The weekly dose value indicates the dose value for the current week. The dose value on the day indicates the dose value already exposed on the day. The work time on the day indicates the time of work already performed on the day.
[0059]
The measuring device 100 reads identification information and exposure information of the user 30 of the radiation detecting element integrated card 1 by contact or non-contact. The measuring device 100 reads the dose value of the fluorescent material 2 and measures the present time at the one-year dose value, three-month dose value, one-month dose value, this-month dose value, weekly dose value, same-day dose value, and same-day work time of the exposure information. Add the result of Further, the measuring device 100 writes the updated exposure information on the radiation detecting element integrated card 1 in a contact or non-contact manner.
[0060]
With the above configuration, even when the electronic personal dosimeter 20 fails and the actual dose value cannot be read due to the failure of the electronic personal dosimeter 20, the entrance / exit management system 130 adopts the actual dose value of the radiation detecting element integrated card 1 so that the user 30 The actual dose value in this operation can be determined.
[0061]
In addition, the entry / exit management system 130 reads the identification information and the exposure information of the user 30 from the radiation detecting element integrated card 1 even in an off-line operation in which the radiation management computer 40 and the entry / exit device 110 are not connected, and performs the entry processing. In this case, the planned dose value is calculated by confirming that the dose value on the day does not exceed the maximum dose value of the day, permitting entry, and subtracting the dose value of the day from the daily maximum dose value. In the case of the departure processing, the departure is permitted after adding the dose value of the day and the dose value of the entrance / exit processing, and confirming that the addition result does not exceed the maximum dose value of one day. Further, in the exit processing, the entry / exit management system 130 writes exposure information reflecting the results of the entrance / exit processing on the radiation detecting element integrated card 1.
[0062]
【The invention's effect】
As described above, according to the present invention, a radiation detecting element integrated card as a backup dosimeter can be provided by incorporating an OSL into an ID card that is always carried by a user.
[0063]
A radiation dose reading / writing system that reads and writes a radiation detecting element integrated card by combining a radiation detecting element integrated card and a measuring device, and an entrance / exit device further including a radiation detecting element integrated card and a measuring device inside An exposure management system can be provided by combining the above.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a radiation detecting element integrated card according to a first embodiment; FIG. 2 is a diagram illustrating an example of a memory configuration of a memory area according to the first embodiment; FIG. FIG. 4 is a diagram showing a configuration of a radiation detecting element integrated card according to a third embodiment. FIG. 5 is a diagram showing an example of a memory configuration of a memory area according to the third embodiment. FIG. 7 is a diagram illustrating an example of identification information and exposure information of a user in a memory area according to a fourth embodiment. FIG. 8 is a diagram illustrating an entry / exit management system. FIG. 10 is a diagram showing an example of user identification information and exposure information in a memory area according to a fifth embodiment. FIG. 10 is a configuration diagram of a conventional entry / exit management system. FIG. 11 is a memory in a memory area of a conventional IC card 201. FIG. 12 shows an embodiment of the configuration. FIG. 12 shows a conventional radiation tube. It illustrates an embodiment of a record definition database computer EXPLANATION OF REFERENCE NUMERALS
REFERENCE SIGNS LIST 1 radiation detecting element integrated card 2 fluorescent material 3 fluorescent material mounting portion 4 radiation detecting element integrated card chip 20 electronic personal dosimeter 30 user 40 radiation management computer 100 measuring instrument 110 entry / exit device 120 radiation dose reading / writing system 130 entry / exit management system 200 conventional measuring device 201 IC card 204 IC card chip 210 conventional entry / exit device 230 conventional entry / exit management system

Claims (7)

A card integrated with a radiation detecting element, comprising a fluorescent material mounting portion for mounting a fluorescent material used for detecting radiation, and a chip having a memory area. A radiation detection element integrated card comprising: a fluorescent material mounting portion for mounting a fluorescent material used for detecting radiation; and a chip having a memory area, wherein the fluorescent material is replaceably mounted. 3. The card according to claim 1, wherein the fluorescent material is OSL. 3. The card according to claim 1, wherein the user's exposure information is stored in a memory area of the chip. A radiation detecting element-integrated card having a fluorescent material mounting portion for mounting a fluorescent material used for detecting radiation, a chip having a memory area in which user identification information and exposure information are written; A radiation dose reading and writing system comprising: a measuring device that reads the identification information of the user and the exposure information by making contact with a body card or in a non-contact manner, and writes the exposure information in the memory area. 6. The radiation dose reading / writing system according to claim 5, wherein an exposure dose for a plurality of predetermined periods can be written in the memory area. A radiation detecting element-integrated card having a fluorescent material mounting portion for mounting a fluorescent material used for detecting radiation, a chip having a memory area in which user identification information and exposure information are written; By contacting with a body card or reading out the user's identification information and exposure information in a non-contact manner, a measuring instrument that writes the exposure information in the memory area, and dose information from the radiation detecting element integrated card. An entry / exit management system comprising an entry / exit device capable of controlling reading and entering / exiting of a user.

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