JP6363498B2 - Radiation management system and radiation management method - Google Patents

Description

  FIELD Embodiments described herein relate generally to a radiation management system and a radiation management method having a radiation management work support function in a nuclear facility such as a nuclear power plant.

  At nuclear facilities such as nuclear power plants, a radiation management system has been introduced. This radiation management system is used to measure individual exposure, worker entry / exit, and worker contamination information in a radiation control area within a nuclear facility using individual exposure dosimeters, access control devices, contamination monitors, and other measuring devices. The measurement results are collected as digital information. Thereby, it is possible to tabulate and manage the exposure dose values of workers as accurately as possible and without omission.

  As described above, in order to collect and manage information on individual worker exposure, worker entry / exit, and worker contamination, the above-mentioned various types installed at the boundary between the radiation control area and the non-control area in the nuclear facility A measuring device is used. Information on these various measurement results is transmitted to the radiation management system. In this radiation management system, information of various measurement results is aggregated and displayed on the display unit, and output display such as a form print output is performed.

  In the radiation management system described above, when managing the individual exposure of workers, the safety manager or the system administrator who has received guidance from the safety manager shall check the exposure of individual workers, the entry and exit of workers, and contamination of workers. Implemented based on information. The daily radiation management information and the accumulated radiation management information are managed so as not to exceed a predetermined value.

  Such a radiation management system collects measurement information from various measuring devices installed at the boundary of each radiation management area of a nuclear facility. Further, the assumed operating state covers abnormal transient changes during normal operation, that is, periodic inspection, plant start-up or stop, and normal operation.

  On the other hand, even in emergency work where a large number of personnel work in a short time in a work area that has become a high-dose environment due to the occurrence of a serious accident, etc., reliable management of the exposure dose value and exposure of workers It is necessary to perform management to reduce this. In this case, there is a need for a means for grasping the exposure dose value of the worker and providing information necessary for developing a control plan.

JP 2001-281339 A JP-A-4-134287

  If the work area becomes a high-dose radiation control area due to the diffusion of radioactive materials at the occurrence of the serious accident mentioned above, all workers including the worker are monitored assuming that the dose limit is reached. Necessary.

  However, the conventional radiation management system that assumes normal operation is a system that checks and manages the exposure dose values of workers in a long-term, non-high-dose environment. Therefore, the conventional radiation management system does not assume that the dose limit value is reached by short-term high-dose environmental work.

  Therefore, in an emergency high-dose environment, the dose that is exposed in one operation is high, and personal dosimeters that can confirm the accumulated dose are not widely used. For this reason, it is found that the exposure dose limit value has been exceeded after work, or the work plan cannot be advanced due to a shortage of personnel due to the worker reaching the dose limit value in the middle of the work plan. Is expected to occur.

  To deal with such problems, it is necessary to predict the exposure dose value before the scheduled work starts and to formulate and implement a work plan that does not exceed the dose limit value and a dose control plan such as protection and decontamination. .

  As described above, there is a method for predicting an exposure dose value using an air dose value obtained by a survey meter (radiation measurement device). However, in the radiation control area in nuclear facilities, it is necessary to measure the air dose value at a large number of points, and the air dose depends on the environmental effects such as wind and rain, and the results of exposure reduction measures such as protection and decontamination. The value changes. Therefore, the above-described method has a problem that the air dose value needs to be reviewed and re-measured at a high frequency, and the labor involved in the measurement becomes large.

  The problem to be solved by the embodiments of the present invention is to provide a radiation management system and a radiation management method capable of predicting an exposure dose value before starting scheduled work.

  In order to solve the above problems, the radiation management system according to the present embodiment includes work schedule information in which work time, work area, and work type are set in the radiation control area, work time after work execution, work area, A work plan collection unit for inputting work result information of work types, a personal exposure dose value collection unit for inputting individual exposure dose value information for each worker, and inputting the individual exposure dose value information and the work result information. , Summing up the sum of individual exposure dose values for each work area and outputting as total exposure dose information for each area; input the total exposure dose information for each area and the actual work information; In addition, an exposure dose unitization unit for each area that calculates exposure dose values per unit time and number of persons for each work type and outputs the exposure dose value value information for each area, and based on the work schedule information. Predicted exposure dose calculation unit that calculates the exposure dose value for each work area and type of work scheduled to be performed from the exposure work time and the exposure dose value information of the exposure dose actual value information for each area, and outputs the exposure dose predicted value information for each area And.

  In the radiation management method according to the present embodiment, the work plan collection unit sets the work schedule information in which the work time, work area, and work type in the radiation control area are set, and the work time, work area, and work type after the work is performed. A work plan collection process for inputting work performance information, an individual exposure dose value collection unit for inputting individual exposure dose value information for each worker, and an exposure dose collection unit for the individual exposure dose collection unit. A dose summation process that inputs dose value information and the above-mentioned work performance information, sums up the sum of individual exposure dose values for each work area, and outputs it as total exposure dose value information for each area, and an exposure dose unitization unit for each area. Enter the total exposure dose value information by area and the work result information, calculate the exposure dose value per unit time and unit number for each work area and work type, and calculate the actual exposure dose value by area. The exposure dose unitization process to be output as a report, and the predicted exposure dose calculation unit, for each work area and work type scheduled for work based on the work time based on the work schedule information and the exposure dose value of the actual exposure dose value information for each area. And a predicted exposure dose calculation step for calculating a dose exposure value for each region and outputting it as predicted exposure dose value information for each area.

  According to the embodiment of the present invention, it is possible to predict an exposure dose value before starting scheduled work.

It is a block block diagram which shows the radiation management system of one Embodiment. It is explanatory drawing which shows the work performance information and personal exposure dose value information of FIG. It is explanatory drawing which shows the process of the exposure dose totalization part of FIG. It is explanatory drawing which shows the process of the exposure dose unitization part classified by area of FIG. It is explanatory drawing which shows the process of the estimated exposure dose setting part of FIG. 1, and work schedule information. It is explanatory drawing which shows the process of the predicted exposure dose calculating part of FIG. It is explanatory drawing which shows the process totaled in the work area in the prediction exposure dose calculating part of FIG. It is explanatory drawing which shows the process of the predicted exposure dose totalization part of FIG. It is explanatory drawing which shows the process of the high exposure area ordering part of FIG.

  Embodiments of a radiation management system and a radiation management method according to the present invention will be described below with reference to the drawings.

(One embodiment)
(Constitution)
FIG. 1 is a block diagram illustrating a radiation management system according to an embodiment.

  As shown in FIG. 1, the radiation management system S in the present embodiment inputs information output from the work plan formulation unit 1 and the personal dose measurement unit 3. The radiation management system S generally includes a work plan collection unit 2, an individual exposure dose value collection unit 4, an exposure dose result evaluation unit 7, an exposure dose prediction unit 10, a high exposure area prediction unit 13, and a display unit 14. . The exposure dose result evaluation unit 7, the exposure dose prediction unit 10, and the high exposure area prediction unit 13 are realized by a CPU (Central Information Processing Device) and software. The work plan collection unit 2 and the individual exposure dose collection unit 4 include a storage device such as a memory or an HDD (Hard disk drive).

  The exposure dose record evaluation unit 7 includes an exposure dose totaling unit 5 and an area-specific exposure dose unitization unit 6. The exposure dose prediction unit 10 includes a predicted exposure dose setting unit 8 and a predicted exposure dose calculation unit 9. The high exposure area prediction unit 13 includes a predicted exposure dose totalization unit 11 and a high exposure area ordering unit 12.

  The work plan formulation unit 1 formulates, records, stores, and outputs a work plan in the radiation control area. Specifically, the work plan formulation unit 1 performs the planned work time, the planned work area (radiation management area), the planned work number for each planned work type (work item) by a process determined by a human system process or a program. The work schedule information such as the actual work time after the work is performed, the actual work area such as the actual work area, the actual work number of persons, etc. are recorded, stored, and output.

  The work plan collection unit 2 inputs work schedule information such as scheduled work time, scheduled work area, and scheduled work type from the work plan formulation unit 1 and work result information such as actual work time, actual work area, and actual work type. . Specifically, the work plan collection unit 2 has an interface function, inputs the work schedule information and work result information output from the work plan formulation unit 1, and outputs the work schedule information to the exposure dose prediction unit 10. On the other hand, the operation result information is output to the exposure dose result evaluation unit 7.

  The personal dose measurement unit 3 enters the radiation control area, performs work, and measures the individual exposure dose value until leaving. Specifically, the individual dose measurement unit 3 is a dose monitor such as a radiation monitor that is carried by an individual worker and that measures the accumulated radiation dose, and a radiation gate monitor that measures the individual dose of the worker at the exit of the radiation control area. The individual exposure dose value until each worker enters, works, and leaves is measured by the vessel, and is output as individual exposure dose value information.

  The personal exposure dose value collection unit 4 has an interface function, inputs personal exposure dose value information, and outputs the personal exposure dose value information to the exposure dose totalization unit 5 of the exposure dose actual result evaluation unit 7.

  The exposure dose totalization unit 5 inputs personal exposure dose value information and work performance information, and calculates the sum of individual exposure dose values of all workers for each work area and each work type in a predetermined period. Aggregated as a total value, this total dose information for each area is output to the dose unit for exposure dose unit 6 for each area. Note that the predetermined period can be changed as appropriate by the administrator.

  The area-specific dose unitization unit 6 inputs the total exposure dose information for each area, calculates the exposure dose value per unit time and unit number for each work area and each work type as the actual exposure dose value for each area, The area-specific exposure dose actual value information is output to the predicted exposure dose setting unit 8 and the display unit 14 of the exposure dose prediction unit 10.

  The exposure dose record evaluation unit 7 controls the input / output information of the exposure dose totaling unit 5 and the area-specific exposure dose unitization unit 6.

  The predicted exposure dose setting unit 8 inputs the actual exposure dose value information for each area, sets the exposure dose per unit time for each work area as the predicted exposure dose for each area, and calculates the predicted exposure dose as the predicted exposure dose information for each area. To the unit 9.

  The predicted exposure dose calculation unit 9 inputs the work schedule information and the predicted exposure dose information for each area, and multiplies the work time based on the work schedule information by the predicted exposure dose for each area of the predicted exposure dose information for each area, The exposure dose value for each work area and work type in the scheduled work is output to the predicted exposure dose totalization unit 11 and the display unit 14 of the high exposure area prediction unit 13 as exposure dose prediction value information for each area.

  The exposure dose prediction unit 10 controls input / output information of the predicted exposure dose setting unit 8 and the predicted exposure dose calculation unit 9.

  The predicted exposure dose totalization unit 11 inputs the predicted dose exposure value information for each area, calculates the predicted exposure dose values of all workers for each work area in the work schedule, and calculates the higher exposure area order as the predicted exposure dose total value information. To the conversion unit 12.

  The high exposure area ordering unit 12 inputs the predicted exposure dose total value information, ranks the work areas in descending order of the predicted exposure dose total value, and outputs the order to the display unit 14 as the high exposure area order information.

  The high exposure area prediction unit 13 controls input / output information of the predicted exposure dose totalization unit 11 and the high exposure area ordering unit 12.

  The display unit 14 includes the actual exposure dose value information for each area output from the exposure dose unitization unit 6 for each area, the predicted exposure dose information for each area output from the predicted exposure calculation unit 9, and the high exposure area ordering unit. The high exposure area order information output from 12 is input and a message to that effect is displayed.

  Next, the exposure dose result evaluation method for each work area and work type of the exposure dose result evaluation unit 7 will be specifically described with reference to FIGS. FIG. 2 is an explanatory diagram showing the work performance information and personal exposure dose value information of FIG. FIG. 3 is an explanatory diagram showing the processing of the exposure dose totalization unit of FIG. FIG. 4 is an explanatory view showing the processing of the exposure dose unitization unit by area of FIG. In FIGS. 2 and 3 and FIGS. 5 to 8 to be described below, reference numerals in which A to E are shown in the circles indicate information flow correspondences.

  As shown in FIG. 2 and FIG. 3, the exposure dose totalization unit 5 performs the predetermined work area and work type in the radiation control area based on the work result information and the individual exposure dose value information during the period specified in advance. The individual exposure dose and work time of the target worker are summed for each work area and for each work type, and the total exposure dose value information for each area in the specified period is output to the exposure dose unitization section 6 for each area.

  Specifically, as shown in FIG. 2, on A month a, the worker a performs the work area 1-1, the work type is E work for 300 minutes, and the worker x is the work area on the A month c. 1-1, when the work type is E work for 350 minutes, the exposure dose totalization unit 5 sums up the exposure dose for each work area as shown in FIG.

  As shown in FIG. 4, the exposure dose unitization unit 6 by area performs the quotient calculation processing on the exposure dose total value information for each area during the specified period by the total work time, and the area per unit time and unit number of people in the specified period. The separate exposure dose actual value is output to the predicted exposure dose setting unit 8 and the display unit 14 of the exposure dose prediction unit 10 as the individual exposure dose actual value information.

  Specifically, as shown in FIG. 4, when the work area is designated and the work type is E work, the work time and the exposure dose per number of workers for the designated period ▲ month. The actual dose value information.

  Next, the exposure dose prediction method for each work area and work type of the exposure dose prediction unit 10 will be specifically described with reference to FIGS. 5 and 6. FIG. 5 is an explanatory diagram showing processing of the predicted exposure dose setting unit and work schedule information in FIG. FIG. 6 is an explanatory diagram showing processing of the predicted exposure dose calculation unit of FIG.

  As shown in FIG. 5, the predicted exposure dose setting unit 8 inputs the actual exposure dose value information for each area indicating the actual individual exposure dose value per unit time in each work area and work type in a predetermined period. The predicted exposure dose setting unit 8 sets, as the predicted exposure dose information for each area, the dose predicted to be exposed by the worker per unit time in each work area and work type. For example, when the work type is E work, the exposure dose for each work area 1-1 is 2 (mSv / h).

  The predicted exposure dose calculation unit 9 selects the predicted exposure dose for each area from the scheduled work area and scheduled work type of each worker based on the scheduled work information and the predicted exposure dose information for each area shown in FIG. Calculate the product of time. Thereby, the dose value predicted to be exposed when the scheduled work is executed is calculated for each worker, and is output as the exposure dose predicted value information for each area.

  Specifically, as shown in FIG. 6, the predicted exposure dose for each area when the worker a, the planned work area is 1-1, and the planned work type is E work is selected, and the predicted exposure dose for each area and the planned dose are selected. Work product is calculated. Thereby, since the scheduled work time of the worker a is 300 minutes (5 hours) on A month A day, the exposure dose for each area is 2 (mSv / h), and 2 × 5 = 10 mSv. This 10 mSv is the predicted individual exposure dose. Since the scheduled work time of worker a is 60 minutes (1 hour) on A month B, the exposure dose for each area is 2 (mSv / h) × 1 = 2 mSv. Since the scheduled work time for worker a is 120 minutes (2 hours) on A month C day, the exposure dose for each area is 2 (mSv / h) × 2 = 4 mSv.

  Next, the high-exposure zone order prediction method of the high-exposure zone prediction unit 13 will be specifically described with reference to FIGS.

  The predicted exposure dose totalization unit 11 sums up the predicted exposure dose values for all workers in a predetermined period, work area, and work schedule according to the work schedule based on the predicted exposure dose information for each area shown in FIG. (Total calculation), and this is output as predicted exposure dose total value information shown in FIG. In FIG. 8, the case where the work area is 1-1 and the radiation dose predicted value for each area is summed is shown.

  As shown in FIG. 9, the high-exposure area ordering unit 12 ranks and evaluates the areas according to the order of the predicted total exposure dose values for each area, and outputs the rank as high-exposure area order information. In FIG. 9, the value of the total predicted exposure dose value for each area is the largest in the work area 4-1, and decreases in the order of the work areas 3-2, 2-7, 2-6, 1-4, and 2-2. Yes.

(Function and effect)
Next, the operation of this embodiment will be described.

  As shown in FIG. 1, the work plan formulation unit 1 first sets work schedule information such as work time, work area, number of workers, etc. for each work type, and sets the work time, work area, work number, etc. after the work is performed. Record, store, and output work performance information.

  The work plan collection unit 2 inputs the work schedule information and work result information output from the work plan formulation unit 1 and outputs the work result information to the exposure result evaluation unit 7, while the work plan information is the exposure dose prediction unit. 10 is output.

  The personal dose measurement unit 3 measures and outputs an individual exposure dose value until each worker enters, works, and leaves.

  The personal exposure dose value collection unit 4 inputs the personal exposure dose value information output from the personal dose measurement unit 3 and outputs the personal exposure dose value information to the exposure dose totalization unit 5 of the exposure dose actual evaluation unit 7.

  The exposure dose totalization unit 5 inputs the work result information output from the work plan collection unit 2 and the individual exposure dose value information output from the individual exposure dose value collection unit 4, and the work area in a predetermined period. The total exposure dose value information for each area indicating the sum of the individual exposure dose values of all workers for each work type and each work type is output to the exposure dose unitization section 6 for each area. This area-specific exposure dose unitization unit 6 sets the exposure dose actual value information for each area indicating the exposure dose value per unit time and number of persons for each work area and each work type, and sets the predicted exposure dose of the exposure dose prediction unit 10. To the unit 8 and the display unit 14.

  The predicted exposure dose setting unit 8 inputs the actual exposure dose value information for each area output from the individual exposure dose unitization unit 6, and obtains the predicted exposure dose information for each area indicating the exposure dose per unit time for each work area. Output to the predicted exposure dose calculation unit 9. The predicted exposure dose calculation unit 9 also inputs the above-mentioned work schedule information together with the predicted exposure dose report for each area, and stores the predicted exposure dose information for each area indicating the exposure dose value for each work area and each work type in the scheduled work. Input to the predicted exposure dose totalization unit 11 and the display unit 14 of the exposure area prediction unit 13.

  The predicted exposure dose totalization unit 11 inputs the predicted dose exposure value information for each area, and sets the predicted exposure dose total value information indicating the predicted exposure dose total value of all workers for each work area scheduled for work as a high exposure area ordering unit. 12 is output. The high exposure area ordering unit 12 inputs the predicted exposure dose total value information, and inputs high exposure area order information indicating the rank of the predicted exposure dose total value of each work area to the display unit 14.

  The display unit 14 can display the exposure dose actual value information by area, the predicted exposure dose information by area, and the high exposure area sequence information, and the contents can be confirmed by display on a digital screen or print output by a printer or the like. It is.

  As described above, according to the present embodiment, by obtaining the exposure dose predicted value information for each area, the exposure dose value corresponding to the nearest work environment is predicted before the work is started, and the area where the exposure dose value is high is predicted. By doing so, it becomes possible to prevent the progress of the work plan from being hindered without exceeding the exposure dose limit value.

  In addition, according to the present embodiment, as a result of the operator performing work in the radiation control area, the actual exposure dose value per person per unit time for each work area and work type is estimated from the actual exposure dose value information for each area. It becomes possible to do. In addition, it is possible to predict how much exposure is to be performed when performing scheduled work from the exposure dose predicted value information for each area without performing enormous number of section dose measurements. Furthermore, based on the high exposure area sequence information, it is possible to grasp the work areas where the total exposure dose value of the worker is large in descending order of the values.

  In this embodiment, by providing the exposure dose totalization unit 5 and the area-specific exposure dose unitization unit 6, as a result of the operator performing work in the radiation control area, the individual exposure dose value per unit time as the actual value Can be grasped for each work area and each work type. In addition, for workers who do not carry exposure dose measuring instruments such as personal dosimeters, the corresponding actual exposure dose values for each area are selected from the work area and work type, and the actual exposure dose values for each area and the work time are selected. By performing the quotient calculation process, it is possible to estimate the exposure dose value in the actual work. That is, the user can estimate the exposed dose value by grasping the average value obtained by personal conversion of the dose that the worker has exposed in each work area and multiplying the actual work time by that value.

  In the present embodiment, by providing the predicted exposure dose setting unit 8 and the predicted exposure dose calculation unit 9, it is possible to obtain the above-mentioned exposure dose actual value information by area and work schedule information without performing an enormous number of air dose measurements. It is possible to calculate exposure dose value information for each area indicating how much exposure is possible, and to quantitatively predict how much the exposure will occur when the scheduled work is performed. That is, the user can confirm the quantitative exposure dose predicted value when the scheduled work is performed.

  In addition, when using the actual exposure dose value information for each area calculated from the personal exposure dose value information in the nearest work for the prediction calculation, it is possible to calculate the predicted exposure dose value according to the current environmental conditions. The exposure dose can be predicted without taking the trouble of re-measurement of the air dose in the environmental situation changed by the dyeing work.

  By adding the predicted exposure dose based on the work schedule information to the actual value of each worker, the administrator knows whether or not the exposure dose limit value will be exceeded and how long it will take to reach it. It is possible to formulate a work plan that does not exceed the dose limit and suppresses the influence on work such as schedule delay.

  Furthermore, in this embodiment, by providing the predicted exposure dose totalization unit 11 and the high exposure area ordering unit 12, when the work is performed based on the work schedule information, the total predicted exposure dose value of the worker is large. It becomes possible to grasp the following work areas in descending order of their values. Therefore, it becomes possible for the user to confirm by ranking the areas where the exposure dose value at the time of scheduled work is high.

  As a result, the manager should greatly reduce the exposure dose when carrying out work areas that cause workers to be exposed at a high rate relative to the total radiation dose in the entire radiation control area, that is, protection and decontamination plans. Can understand the work area that can be used, and formulate and implement measures to reduce the exposure of protection, decontamination, etc. with priority on this area, thereby effectively reducing the exposure and ensuring high safety. Can be obtained.

(Other embodiments)
Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, changes, and combinations can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

  In addition, although the radiation management system of the said embodiment demonstrated the example which installed the high exposure area prediction part 13 and the display part 14, even if these high exposure area prediction parts 13 and the display part 14 were abbreviate | omitted, an exposure dose limit It is possible to prevent the progress of the work plan from being hindered without exceeding the value.

  In the radiation management system of the above embodiment, the actual exposure dose value information for each area is input to the predicted exposure dose setting unit 8. However, the present invention is not limited to this, and the actual exposure dose value information for each area is set to the predicted exposure dose setting. You may make it input directly to the prediction exposure dose calculating part 9 not via the part 8. FIG. Even if comprised in this way, the same effect is acquired.

  DESCRIPTION OF SYMBOLS 1 ... Work plan formulation part, 2 ... Work plan collection part, 3 ... Individual dose measurement part, 4 ... Individual exposure dose value collection part, 5 ... Exposure dose totalization part, 6 ... Exposure dose unitization part according to area, 7 ... Exposure Dose performance evaluation unit, 8 ... predicted exposure dose setting unit, 9 ... predicted exposure dose calculation unit, 10 ... exposure dose prediction unit, 11 ... predicted exposure dose totaling unit, 12 ... high exposure area ordering unit, 13 ... high exposure area Prediction unit, 14 ... display unit

Claims (6)

A work plan collection unit for inputting work schedule information in which work time, work area, and work type are set in the radiation control area, and work result information of work time, work area, and work type after work is performed;
An individual exposure dose value collection unit for inputting individual exposure dose value information for each worker;
Input the personal exposure dose value information and the work performance information, total the individual exposure dose values for each work area and output as total exposure dose total value information by area,
Input the total exposure dose value information by area and the work performance information, calculate the exposure dose value per unit time and unit number for each work area and work type, and output it as the exposure dose actual value information by area A dose unitization unit;
Calculate exposure dose values for each work area and work type scheduled for work from the work time based on the work schedule information and the exposure dose value of the actual exposure dose value information for each area, and output the exposure dose predicted value information for each area. A predicted dose calculation unit;
A radiation management system comprising:   It further includes a predicted exposure dose setting unit that inputs the actual exposure dose value information for each area and outputs the exposure dose per unit time for each area as the predicted exposure dose information for each area to the predicted exposure dose calculation unit. The radiation management system according to claim 1. Input the predicted exposure dose information for each area, calculate the predicted exposure dose values of all workers for each work area in the work schedule, and output the predicted exposure dose total value information as predicted exposure dose total value information;
A high exposure area ordering unit that inputs the predicted exposure dose total value information, ranks each work area in descending order of the predicted exposure dose total value, and outputs it as high exposure area order information;
A display unit for displaying the exposure dose actual value information by the area, the predicted exposure dose information by the area, and the high exposure area sequence information;
The radiation management system according to claim 1, further comprising:   The area-specific exposure dose unitization unit calculates the exposure dose total value of the area-specific exposure dose total value information during the period specified in advance using the total work time, and calculates the exposure dose value per unit time and unit number of people. The radiation management system according to any one of claims 1 to 3, wherein the radiation dose actual value for each area is calculated as the actual radiation dose actual value for each work area and the work type, and the radiation dose actual value information for each area is used.   The predicted exposure dose value calculation unit selects an exposure dose increase factor for each corresponding area from the scheduled work area and the scheduled work type indicated by the work schedule information, and calculates a product of the scheduled work time and the exposure dose increase coefficient for each area. The radiation management according to any one of claims 1 to 4, wherein the radiation dose value in the scheduled operation is calculated as an exposure dose prediction value for each area, and used as the exposure dose prediction value information for each area. system. The work plan collection unit inputs the work schedule information in which the work time, work area, and work type in the radiation control area are set, and the work time information, work area, and work type information after the work is performed. Process,
The individual exposure dose value collection unit inputs the individual exposure dose value information for each worker, and the individual exposure dose value collection process,
An exposure dose summarizing step in which the exposure dose summarization unit inputs the personal exposure dose value information and the work performance information, sums up the sum of individual exposure dose values for each work area, and outputs the sum as individual exposure dose total value information; ,
The radiation dose unitization unit for each area inputs the total exposure dose value information for each area and the work performance information, calculates the exposure dose value per unit time and unit number for each work area and work type, and determines the exposure dose for each area. Radiation dose unitization process by area to be output as actual dose value information,
The predicted exposure dose calculation unit calculates the exposure dose value for each work area and work type scheduled for the work from the work time based on the work schedule information and the exposure dose value of the actual exposure dose value information for each area. Predicted exposure dose calculation process to output as predicted dose information,
A radiation management method comprising:

Images