JP7079666B2 - Radioactivity concentration display device, radioactivity concentration calculation device, radioactivity concentration display method and radioactivity concentration calculation method - Google Patents

Description

The present invention relates to a radioactivity concentration display device, a radioactivity concentration calculation device, a radioactivity concentration display method, and a radioactivity concentration calculation method.

In a nuclear power plant, there is a technique to generate a map showing the radioactivity concentration distribution in order to know the radioactivity concentration distribution due to radioactive contamination. For example, Non-Patent Document 1 describes that a treatment disposal classification map showing a radioactivity concentration distribution is generated. The treatment disposal classification map in Non-Patent Document 1 shows the radioactivity concentration distribution for a structure of a single material.

Innovative Practical Nuclear Technology Development Expense Subsidy Project 2006 Achievement Report Summary Version Technology Development on Low Radiation Design Method to Lower Clearance Level

However, some structures installed in actual nuclear plants are not composed of a single material. Therefore, in such a case, it may not be possible to properly confirm the state of the radioactivity concentration distribution for the structure even by looking at the map of a single material. Therefore, there is a demand for a technique that can appropriately confirm the state of the radioactivity concentration distribution.

The present invention solves the above-mentioned problems, and provides a radioactivity concentration display device, a radioactivity concentration calculation device, a radioactivity concentration display method, and a radioactivity concentration calculation method that can appropriately confirm the state of the radioactivity concentration distribution. The purpose is.

In order to achieve the above object, the radioactivity concentration display device according to the present disclosure determines the radioactivity concentration for each activated nuclei species based on the material information of the site for a structure having a plurality of sites whose materials are different from each other. , A calculation unit that calculates for each of the parts, and a display unit that displays the information on the radioactivity concentration of each of the parts calculated by the calculation unit and the image of the structure on the screen. Have.

Since this radioactivity concentration display device can display the radioactivity concentration distribution of the parts where the materials are different from each other, according to this radioactivity concentration display device, the state of the radioactivity concentration distribution for the structure can be appropriately confirmed. can do.

The calculation unit calculated the radioactivity concentration for all of the plurality of activated nuclides contained in the site, totaled the radioactivity concentration for each activated nuclide, and the display unit totaled the radioactivity concentration. It is preferable to display information on the radioactivity concentration. According to this radioactivity concentration display device, the radioactivity concentration of all nuclides can be confirmed on the screen, so that the state of the radioactivity concentration distribution can be appropriately confirmed.

The calculation unit calculates a neutron flux for each site, and obtains the nuclide information for each site and the activated cross section for each site calculated based on the material information of the site for the neutron flux for each site. It is preferable to calculate the radioactivity concentration by multiplying by. This radioactivity concentration display device can appropriately confirm the state of the radioactivity concentration distribution while making the calculation of the radioactivity concentration highly accurate.

The calculation unit includes a region division unit that divides the region into a plurality of regions, a neutron bundle distribution calculation unit that calculates a neutron bundle for each region, and nuclear species information of the region acquired based on material information of the region. And the activation cross-sectional area of the region are multiplied by the neutron bundle to calculate the radioactivity concentration of the region, and the radioactivity concentration of the region is calculated for a plurality of the regions. It is preferable to have a radioactivity concentration calculation unit for calculating the radioactivity concentration for the site. This radioactivity concentration display device can appropriately confirm the state of the radioactivity concentration distribution while making the calculation of the radioactivity concentration highly accurate.

It is preferable that the display unit superimposes the information on the radioactivity concentration on the image of the structure and displays it. According to this radioactivity concentration display device, by superimposing the radioactivity concentration information on the image of the structure, the radioactivity concentration distribution for each position of the structure can be appropriately visually recognized.

It is preferable that the display unit displays the information on the radioactivity concentration separately for each numerical range of the radioactivity concentration. According to this radioactivity concentration display device, the radioactivity concentration is displayed in a state where it is classified by level, so it is possible to appropriately visually check which area has a high radioactivity concentration and effectively confirm the disposal classification. Can be done.

It is preferable that the display unit displays the information on the radioactivity concentration of each of the parts calculated by the calculation unit and the image of the structure on one screen. According to this radioactivity concentration display device, even if there are parts with different materials, the radioactivity concentration distribution of the different parts can be displayed on one screen, so that the status of the radioactivity concentration distribution for the structure can be displayed. It can be confirmed more appropriately.

In order to achieve the above object, the radioactivity concentration calculation device according to the present disclosure is a radioactivity concentration calculation device for calculating the radioactivity concentration of a structure having a plurality of parts having different materials from each other, and the above-mentioned parts are used. A region division unit that divides into a plurality of regions, a neutron bundle distribution calculation unit that calculates neutron flux for each region, and nuclear species information of the region and activation cross-sectional area of the region acquired based on material information of the region. By multiplying the neutron flux with the radioactivity concentration in the region, and by calculating the radioactivity concentration in the region for all the regions, the radiation for each of the regions. It has a radioactivity concentration calculation unit for calculating the radioactivity concentration. According to this radioactivity concentration calculation device, the state of the radioactivity concentration distribution for the structure can be appropriately confirmed.

In order to achieve the above object, the radioactivity concentration display method according to the present disclosure determines the radioactivity concentration for each activated nuclei species based on the material information of the site for a structure having a plurality of sites whose materials are different from each other. , A calculation step calculated for each of the parts, and a display step of displaying the information of the radioactivity concentration of each of the parts calculated in the calculation step and the image of the structure on the screen. Have. According to this radioactivity concentration display method, the state of the radioactivity concentration distribution for the structure can be appropriately confirmed.

In order to achieve the above object, the radioactivity concentration calculation method according to the present disclosure is a radioactivity concentration calculation method for calculating the radioactivity concentration of a structure having a plurality of parts having different materials from each other. The region division part that divides into a plurality of regions, the neutron bundle calculation step that calculates the neutron flux for each region, the nuclear species information for each region and the activation interruption for each region acquired based on the material information of the site. By multiplying the area by the neutron flux, the radioactivity concentration for each region is calculated, and by calculating the radioactivity concentration for each region for a plurality of regions, the radioactivity concentration for each region is calculated. It has a radioactivity concentration calculation step for calculating the radioactivity concentration. According to this radioactivity concentration calculation method, the state of the radioactivity concentration distribution for the structure can be appropriately confirmed.

According to the present invention, the state of the radioactivity concentration distribution can be appropriately confirmed.

FIG. 1 is a schematic diagram of a nuclear power plant according to the present embodiment. FIG. 2 is a schematic block diagram of the radioactivity concentration display device according to the present embodiment. FIG. 3 is a schematic view showing the structure of the reactor containment vessel. FIG. 4 is a schematic diagram illustrating the area division of the structure. FIG. 5 is a diagram showing an example of a radioactivity concentration map. FIG. 6 is a diagram showing another example of the radioactivity concentration map. FIG. 7 is a flowchart illustrating the processing contents of the control unit according to the present embodiment. FIG. 8 is a diagram showing the calculation result of the radioactivity concentration in each Z direction.

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The present invention is not limited to this embodiment. In addition, the components in the following embodiments include those that can be easily replaced by those skilled in the art, or those that are substantially the same.

FIG. 1 is a schematic diagram of a nuclear power plant according to the present embodiment. In the reactor applied to the nuclear power plant 1 of the present embodiment, light water is used as a reactor cooling material and a neutron reducing material, and high temperature and high pressure water that does not boil over the entire primary system is used, and this high temperature and high pressure water is used as a steam generator. It is a pressurized water reactor (PWR) that sends and generates steam by heat exchange and sends this steam to a turbine generator to generate power.

In the nuclear power plant 1 having this pressurized water reactor, as shown in FIG. 1, a reactor containment vessel 11 is provided in the nuclear building 10. The reactor containment vessel 11 has external shielded concrete 11A, a reactor containment vessel 11B, a secondary shielded concrete 11C, and a primary shielded concrete 11D, which will be described later, as portions thereof. Then, the reactor containment vessel 11 has a reactor vessel 12, a steam generator 13, cooling water pipes 14, 15, a pressurizer 16, and a next cooling material as parts inside the reactor containment vessel 11B. It has a circulation pump 17. The reactor vessel 12 and the steam generator 13 are connected to each other via cooling water pipes 14 and 15. The cooling water pipe 14 is provided with a pressurizer 16. The cooling water pipe 15 is provided with a primary cooling material circulation pump 17. Therefore, in the reactor vessel 12, light water is heated as a primary coolant by the fuel constituting the core, and the high-temperature light water is maintained at a predetermined high pressure by the pressurizer 16 and passed through the cooling water pipe 14 to the steam generator 13. Sent. In the steam generator 13, heat is exchanged between the high-temperature and high-pressure light water (primary coolant) and the secondary coolant, and the cooled light water is passed through the cooling water pipe 15 by the primary coolant circulation pump 17 to the reactor. Returned to container 12.

The steam generator 13 is connected to the steam turbine 18 and the condenser 19 provided outside the reactor containment vessel 11 via cooling water pipes 20 and 21. The cooling water pipe 21 is provided with a water supply pump 22. Further, the steam turbine 18 is connected to the generator 23. The condenser 19 is connected to an intake pipe 24 and a drain pipe 25 for supplying and discharging cooling water (for example, seawater). Therefore, the steam generated by heat exchange with the high-pressure and high-temperature primary cooling water in the steam generator 13 is sent to the steam turbine 18 through the cooling water pipe 20, and the steam drives the steam turbine 18 to generate power. Power is generated by the machine 23. The steam that drives the steam turbine 18 is cooled by the condenser 19 and then returned to the steam generator 13 through the cooling water pipe 21.

FIG. 2 is a schematic block diagram of the radioactivity concentration display device according to the present embodiment. The radioactivity concentration display device 40 according to the present embodiment is a radioactivity concentration calculation device for calculating the radioactivity concentration in the nuclear power plant 1, and further, it shows a radioactivity concentration distribution based on the calculated radioactivity concentration. It is a device that displays a radioactivity concentration map. The radioactivity concentration display device 40 displays a radioactivity concentration map for the structures inside the nuclear power plant 1, but displays a radioactivity concentration map for the structures outside the nuclear power plant 1. May be.

As shown in FIG. 2, the radioactivity concentration display device 40 is a computer having an input unit 42, an output unit 44, a storage unit 46, and a control unit 48. The input unit 42 is a device capable of inputting information from a user, and is, for example, a mouse, a keyboard, a touch panel, or the like. The output unit 44 as a display unit is a device that displays a radioactivity concentration map or the like generated by the control unit 48, and is a display or a touch panel in the present embodiment. The storage unit 46 is a memory that stores the calculation contents of the control unit 48, program information, and the like. The storage unit 46 includes, for example, at least one external storage device such as a RAM (Random Access Memory), a ROM (Read Only Memory), and a flash memory (Flash Memory).

The control unit 48 is an arithmetic unit, that is, a CPU (Central Processing Unit). It can also be said that the control unit 48 is a calculation unit. The control unit 48 calculates the radioactivity concentration of the structure, here, the structure provided in the nuclear power plant 1, and based on the calculated radioactivity concentration, the radioactivity concentration map showing the radioactivity concentration distribution of the structure. To create. Here, the structure provided in the nuclear power plant 1 or the like may have a plurality of parts whose materials are different from each other. The control unit 48 makes it possible to display the radioactivity concentration of each part of the structure having different parts of the material in one radioactivity concentration map. In the following description, the control unit 48 uses the structure as the reactor containment vessel 11 as an example to create a radioactivity concentration map of the reactor containment vessel 11. However, the control unit 48 can create a radioactivity concentration map of any structure other than the reactor containment vessel 11. Further, the control unit 48 may display the radioactivity concentration distributions of different structures (for example, the reactor containment vessel 11 and the steam generator 13) on one radioactivity concentration map.

FIG. 3 is a schematic view showing the structure of the reactor containment vessel. As shown in FIG. 3, the reactor containment vessel 11 has an external shielding concrete 11A, a reactor containment vessel 11B, a secondary shielding concrete 11C, and a primary shielding concrete 11D as portions. The external shielding concrete 11A is a portion forming the outermost wall of the reactor containment vessel 11. The external shielding concrete 11A is an external shielding, for example, made of reinforced concrete (combination of concrete and carbon steel). The reactor containment vessel (carbon steel) 11B is a portion that forms a wall provided inside the external shielding concrete 11A. The reactor containment vessel 11B is a reactor containment vessel, for example, made of carbon steel. The secondary shielded concrete 11C is a portion provided inside the reactor containment vessel 11B, and holds the steam generator 13 between the secondary shielded concrete 11C and the primary shielded concrete 11D. The secondary shielding concrete 11C is reinforced concrete, and more specifically, it is a combination of concrete and carbon steel. The primary shielding concrete 11D is a portion that holds the reactor vessel 12 inside. The primary shielding concrete 11D is reinforced concrete, and more specifically, it is a combination of concrete and carbon steel. As described above, it can be said that the reactor containment vessel 11 has a plurality of parts (for example, the external shielded concrete 11A and the secondary shielded concrete 11C) whose materials are different from each other. Further, the reactor vessel body 11 has the reactor vessel 12, the steam generator 13, the cooling water pipes 14 and 15, the pressurizer 16, and the secondary coolant circulation pump 17 as parts thereof. The materials of the parts may also be different from each other. In this description, the control unit 48 exemplifies the generation of a radioactivity concentration map for these parts of the reactor containment vessel 11. Furthermore, in the following description, it is necessary to generate a radioactivity concentration map for the part included in the cross section of the arrow A in FIG. 3, that is, the primary shielding concrete 11D and the reactor vessel 12 of the reactor containment vessel 11. Is taken as an example. Hereinafter, one direction along the horizontal direction is referred to as a direction X, and a direction that is one direction along the horizontal direction and orthogonal to the direction X is referred to as a direction Y. Then, the direction orthogonal to the directions X and Y, that is, the vertical direction is defined as the direction Z.

Returning to FIG. 2, the control unit 48 includes a structure information acquisition unit 50, a region division unit 52, a neutron flux distribution calculation unit 54, a radioactivity concentration calculation unit 56, and a radioactivity concentration map generation unit 58. .. The structure information acquisition unit 50, the region division unit 52, the neutron flux distribution calculation unit 54, the radioactivity concentration calculation unit 56, and the radioactivity concentration map generation unit 58 are software (programs) stored in the storage unit 46. ) Is read to execute the process described later.

The structure information acquisition unit 50 acquires information on the structure for which the radioactivity concentration is to be calculated. Therefore, the structure information acquisition unit 50 in the present embodiment acquires the information of the reactor containment vessel 11. The structure information acquisition unit 50 acquires material information of each part as information of the reactor containment vessel 11. The material information refers to a parameter determined based on the material of the site, and in the present embodiment, includes information on the type of nuclide (activated nuclide) for each site. Then, the structure information acquisition unit 50 acquires the number of parent nuclides of the nuclide, the activation cross-sectional area of the nuclide, and the decay constant of the nuclide as material information for each nuclide (activated nuclide). do. That is, the structure information acquisition unit 50 acquires information on nuclides (radionuclides) contained in the primary shielding concrete 11D, that is, information on what kind of nuclides are contained in the primary shielding concrete 11D. In the present embodiment, the structure information acquisition unit 50 determines the number of nuclide parent nuclides, the activation cross-sectional area of the nuclide, and the decay constant of the nuclide for each of the nuclides contained in the primary shielding concrete 11D. And get. The structure information acquisition unit 50 acquires the same information for other parts. That is, in the present embodiment, the structure information acquisition unit 50 also has information on the types of nuclides (radionuclides) contained in the reactor vessel 12, the number of parent nuclides of each nuclide, and the radiation of each nuclide. Obtain the chemical cross section and the decay constant of each nuclide.

The number of parent nuclides of a nuclide (activated nuclide), the activation cross-sectional area of the nuclide, and the decay constant of the nuclide are values determined for each nuclide. The structure information acquisition unit 50 extracts the type of nuclide from the composition of each part of the reactor containment vessel 11, for example, the number of parent nuclides with respect to the extracted nuclide from the database stored in the storage unit 46. And the activation cross section and the decay constant are read out. However, the structure information acquisition unit 50 may acquire such information from a database of an external server (not shown). That is, the structure information acquisition unit 50 is arbitrary regarding the acquisition method of these information.

FIG. 4 is a schematic diagram illustrating the area division of the structure. The model of the reactor containment vessel 11 shown in FIG. 4 is a cross-sectional view of the reactor containment vessel 11 as viewed from the arrow A in FIG. FIG. 4 includes, as the reactor vessel 12, a reactor vessel main body 12A, a core tank 12B provided inside the reactor vessel main body 12A, and a core baffle 12C provided inside the core tank 12B. However, the reactor vessel 12 may include parts other than these. The reactor vessel body 12A is made of carbon steel, the core tank 12B is made of stainless steel, and the baffle 12C is made of stainless steel.

As shown in FIG. 4, the region division portion 52 divides the structure, that is, the reactor containment vessel body 11 into a plurality of regions R. Furthermore, the region division portion 52 divides each part of the reactor containment vessel 11, that is, the primary shielding concrete 11D, the reactor vessel body 12A, the core tank 12B, the baffle 12C, and the like into a plurality of regions R. ing. Therefore, it can be said that one region R is smaller than the surface area of each part, that is, the primary shielding concrete 11D, the reactor vessel body 12A, the core tank 12B, the baffle 12C, and the like. The region division unit 52 does not divide the actual reactor containment vessel 11 into regions R, and virtually a plurality of models of the reactor containment vessel 11 are used for calculating the neutron flux described later. It is divided into a region R, that is, a mesh. In FIG. 4, the region R is provided two-dimensionally in the cross section of the reactor containment vessel 11, but in reality, all the parts of the reactor containment vessel 11 are three-dimensionally region R. It is divided into.

The neutron flux distribution calculation unit 54 calculates the neutron flux for each region R. The neutron flux distribution calculation unit 54 calculates the neutron flux for all the regions R to generate a neutron flux distribution showing the distribution of the neutron flux in the entire reactor storage container 11. The neutron flux distribution calculation unit 54, for example, executes resonance calculation to calculate an effective cross-sectional area that is an input value of the neutron transport equation. In this resonance calculation, for example, the cross-sectional area based on the ultra-detailed energy group of 100,000 groups is reduced by the neutron flux obtained by the neutron transport calculation based on the ultra-detailed energy group, for example, 172 groups. Calculate the effective cross-sectional area. Then, the neutron flux distribution calculation unit 54 creates a plurality of neutron flight paths on the region R, solves the neutron transport equation for each neutron flight path using the calculated execution cross section, and obtains the neutron flux in the region R. calculate.

The method for calculating the neutron flux is not limited to this, and any method may be used as long as the neutron flux can be calculated for each region R. Further, in the present embodiment, the neutron flux is calculated for each region R, but the calculation is not limited to each region R. For example, the neutron flux distribution calculation unit 54 may calculate the neutron flux for each site, that is, for each of the primary shield concrete 11D, the reactor vessel body 12A, the core tank 12B, the baffle 12C, and the like.

The radioactivity concentration calculation unit 56 calculates the radioactivity concentration for each region R, that is, the radioactivity concentration for each region R. Specifically, the radioactivity concentration calculation unit 56 calculates the radioactivity concentration in the region R by the following equation (1).

Here, j refers to the position of the region R, and Φ _(j) is the neutron flux (n / cm ² · s) of the region R at the position j. Further, i refers to the type of nuclide (activated nuclide). Then, K _{(i, j)} is calculated by the following equation (2).

K _{(i, j)} = N _(i) , σ _{(i, j)} , (1-e- ^{λ (i) t1} ), (e- ^{λ (i) t2} ) ... (2)

Here, N _(i) is the number of parent nuclides of the nuclide i, and can be said to be nuclide information. Further, σ _{(i, j)} is the activation cross section of the nuclide i in the region R at the position j, and λ _(i) is the decay constant of the nuclide i. Further, t1 is the irradiation time of neutrons, and t2 is the cooling time, that is, the time when the neutrons are stopped.

That is, the radioactivity concentration calculation unit 56 uses the equation (2) to multiply the nuclide i in the region R at the position j by the number of nuclides of the nuclide i and the activation cross-sectional area of the nuclide i. The radioactivity concentration when receiving neutrons is calculated as K _{(i, j)} . Then, as shown in the equation (1), the radioactivity concentration calculation unit 56 multiplies K _{(i, j)} by Φ _(j) to receive the calculated neutron flux, and the region at the position j. The radioactivity concentration of nuclide i in R is calculated. Then, the radioactivity concentration calculation unit 56 calculates the radioactivity concentration when receiving one neutron for each nuclide contained in the region R by the equation (2), and Φ (position j of the nuclide). By multiplying the neutron bundle in the region R), the radioactivity concentration of each nuclide in the region R at the position j is calculated. Then, as shown in the equation (1), the radioactivity concentration calculation unit 56 calculates the total radioactivity concentration of all the nuclides in the region R at the position j by summing up the radioactivity concentrations of each nuclide. do. In this way, the radioactivity concentration calculation unit 56 calculates the radioactivity concentration for all of the plurality of activated nuclei species contained in the site (here, the region R), and totals the radioactivity concentration for each activated nuclei species. Therefore, it can be said that the radioactivity concentration of the site (region R) is calculated.

In this way, the radioactivity concentration calculation unit 56 calculated the radioactivity concentration in the region R at the position j, but for the other regions R, by calculating the radioactivity concentration in the same manner, all the regions R Calculate the radioactivity concentration in. As a result, the radioactivity concentration calculation unit 56 calculates the radioactivity concentration in the entire area of the reactor containment vessel 11, that is, in each portion.

The radioactivity concentration map generation unit 58 shown in FIG. 2 generates concentration information for generating a radioactivity concentration map based on the radioactivity concentration of each region R calculated by the radioactivity concentration calculation unit 56. The concentration information is information generated for each region R, and indicates the radioactivity concentration information which is the information on the radioactivity concentration of the region R and the position (coordinates) of the region R in the reactor containment vessel 11. It has location information. That is, the radioactivity concentration map generation unit 58 generates information on the radioactivity concentration of the region R for each position as concentration information. Furthermore, the radioactivity concentration map generation unit 58 associates the position (coordinates) of the region R in the reactor containment vessel 11 with the position (coordinates) on the display screen of the output unit 44, and position information. To generate. As a result, the position information becomes information indicating which position on the display screen the radioactivity concentration of the region R is the information of the radioactivity concentration.

Further, in the present embodiment, the radioactivity concentration map generation unit 58 divides the possible numerical range of the radioactivity concentration into a plurality of numerical ranges. Then, the radioactivity concentration map generation unit 58 assigns the value of the radioactivity concentration calculated by the radioactivity concentration calculation unit 56 to any of a plurality of numerical values, and the information of the assigned result is used as the radioactivity concentration. Use as information. For example, a numerical range with a small numerical value is defined as the 0th level, a numerical range larger than the 0th level is defined as the first level, and a numerical range larger than the first level is defined as the second level. In this case, the radioactivity concentration map generation unit 58 uses the radioactivity concentration information of the region R in which the radioactivity concentration is within the numerical range of the 0th level as the information to the effect that the radioactivity concentration is the 0th level, and the radioactivity concentration is the first. The radioactivity concentration information of the region R within the numerical range of the level is used as the information indicating that the level is the first level, and the radioactivity concentration information of the region R whose radioactivity concentration is within the numerical range of the second level is used as the second level. Information to the effect that it is a level. That is, the radioactivity concentration map generation unit 58 sets the radioactivity concentration information of the regions R assigned to different numerical ranges, that is, different levels, as information divided from each other (information different from each other). For example, the radioactivity concentration map generation unit 58 may use the radioactivity concentration information of the regions R assigned to different levels as information having different colors. For example, in the example of this embodiment, the 0th level is white, the 1st level is yellow, and the 2nd level is red. However, the method of classifying the radioactivity concentration information of the regions R assigned to different levels is not limited to the color and is arbitrary. Further, the number of levels to be divided is not limited to three and is arbitrary.

The radioactivity concentration map generation unit 58 generates concentration information for all regions R. Then, the radioactivity concentration map generation unit 58 reads out the image data of the equipment (here, the reactor containment vessel 11) stored in the storage unit 46, for example. The image data here refers to image data that the structure of the reactor storage container 11 is displayed on the output unit 44 by outputting to the output unit 44, for example, two-dimensional of the reactor storage container 11. Drawing data and three-dimensional 3D model data.

The radioactivity concentration map generation unit 58 outputs the density information and image data thus generated to the output unit 44, so that the radioactivity concentration map is displayed on one screen 44A of the output unit 44. .. In other words, it can be said that the density information and the image data are the information constituting the radioactivity density map. The output unit 44 uses the radioactivity concentration information, that is, the radioactivity concentration information of each part, and the image data, that is, the image of the reactor containment vessel 11, as a radioactivity concentration map on one screen 44A. Display. However, the radioactivity concentration map generation unit 58 may display the radioactivity concentration map on a plurality of screens separately. That is, the radioactivity concentration map generation unit 58 may display the radioactivity concentration map on the screen. However, it is preferable that the radioactivity concentration map generation unit 58 simultaneously displays information on the radioactivity concentration including a plurality of parts and an image of the reactor containment vessel 11.

Here, the concentration information includes the position information and the radioactivity concentration information. Therefore, the radioactivity concentration information indicating the level of the radioactivity concentration is associated with the position information indicating the level of the radioactivity concentration at which position (coordinates) on the screen 44A. Further, in the image data, the image of the reactor containment vessel 11 and the position (coordinates) on the screen 44A are associated with each other. Therefore, the output unit 44 can associate the position of the radioactivity concentration information with the image of the reactor containment vessel 11 by the concentration information and the image data. In other words, the output unit 44 can associate the radioactivity concentration information indicating the level of the radioactivity concentration with the information on the position of the image of the reactor containment vessel 11.

FIG. 5 is a diagram showing an example of a radioactivity concentration map. FIG. 5 is a radioactivity concentration map of the reactor containment vessel 11 as viewed from the arrow A shown in FIG. 3, and the image of the reactor containment vessel 11 divides the reactor containment vessel 11 into 1/8. It is a cross-sectional view. The output unit 44 outputs the radioactivity concentration information to the reactor storage container so that the radioactivity concentration information indicating the level of the radioactivity concentration corresponds to the position on the image of the reactor storage container 11 in the radioactivity concentration map. It is superimposed on the image of the body 11 and displayed. Therefore, as shown in FIG. 5, in the present embodiment, the output unit 44 radiates an image of the reactor containment vessel 11 color-coded with the color specified in the radioactivity concentration information for each position. Display as a function density map.

In the example of FIG. 5, the image PD is an image showing the primary shielding concrete 11D, the image PA is an image showing the reactor vessel body 12A, and the image PB is an image showing the core tank 12B, and the image PC. Is an image showing the baffle 12C. That is, the output unit 44 displays an image of the primary shielding concrete 11D, the reactor vessel main body 12A, the core tank 12B, and the baffle 12C in a state of being assembled to each other. Further, the radioactivity concentration image SD is an image showing the radioactivity concentration information in the primary shielding concrete 11D, and is superimposed on the image PD. Further, the radioactivity concentration image SA is an image showing the radioactivity concentration information in the reactor vessel main body 12A, and is superimposed on the image PA. Further, the radioactivity concentration image SB is an image showing the radioactivity concentration information in the core tank 12B, and is superimposed on the image PB. Further, the radioactivity concentration image SC is an image showing the radioactivity concentration information in the baffle 12C, and is superimposed on the image PC. In the example of FIG. 5, the radioactivity concentration information of the primary shielding concrete 11D is, for example, the first level. In addition, the reactor vessel body 12A contains different levels of radioactivity concentration information, which is the first level in most of the outer regions and the second level in some of the inner regions. It is divided into two parts. The core tank 12B and the baffle 12C are at the second level.

The radioactivity concentration information does not necessarily have to be the information divided into levels for each numerical range. For example, the radioactivity concentration information may be classified for each value and displayed differently for each value. In this case, in the example of FIG. 5, the radioactivity concentration information is classified only at three levels, but by classifying by value, the difference in radioactivity concentration for each position can be grasped in more detail. be able to. Further, the output unit 44 displays the total value of the radioactivity concentrations of a plurality of nuclides (activated nuclides) as radioactivity concentration information, but displays the radioactivity concentration of one nuclide as radioactivity concentration information. You may. Further, the output unit 44 may switch and display the radioactivity concentration information based on the radioactivity concentration of one nuclide and the radioactivity concentration information based on the total value of the radioactivity concentrations of a plurality of nuclides. In this case, the output unit 44 keeps the same image of the reactor storage container 11 and uses only the radioactivity concentration information, the radioactivity concentration information based on the radioactivity concentration of one nuclei, and the radioactivity concentration of a plurality of nuclei. It may be switched with the radioactivity concentration information based on the total value of.

For example, in the radioactivity concentration map, if the radioactivity concentration distributions of different parts cannot be displayed at the same time, only the radioactivity concentration distribution of one part can be displayed, and the radioactivity concentration distribution in the entire structure can be recognized. It can be difficult. On the other hand, the output unit 44 according to the present embodiment displays the radioactivity concentration information of each part and the image of the structure as a radioactivity concentration map on the screen. That is, when displaying the radioactivity concentration of the reactor containment vessel 11, the output unit 44 can simultaneously display the radioactivity concentration distribution of different parts even if there are parts having different materials. Therefore, according to the radioactivity concentration map displayed by the output unit 44, the state of the radioactivity concentration distribution for the structure can be appropriately confirmed. Furthermore, since the output unit 44 displays the radioactivity concentration information of each part and the image of the structure on one screen 44A as a radioactivity concentration map, the state of the radioactivity concentration distribution for the structure. Can be confirmed more appropriately.

FIG. 6 is a diagram showing another example of the radioactivity concentration map. The radioactivity concentration map in FIG. 5 is a radioactivity concentration map of the reactor containment vessel 11 viewed from the arrow A shown in FIG. 3, and was an image divided into 1/8. However, the method of displaying the radioactivity concentration map is not limited to FIG. 5 and is arbitrary as long as images of different parts can be displayed. For example, as shown in FIG. 6, the radioactivity concentration map may be displayed as a cross-sectional view seen from the direction Y. Further, it may not be displayed as a cross-sectional view, or may be displayed as a three-dimensional image.

The control unit 48 calculates the radioactivity concentration as described above, and displays it as a radioactivity concentration map on the output unit 44. The flow of processing for displaying the radioactivity concentration map by the control unit 48 will be described below. FIG. 7 is a flowchart illustrating the processing contents of the control unit according to the present embodiment. As shown in FIG. 7, the control unit 48 uses the structure information acquisition unit 50 to obtain material information, that is, the type of nuclide contained in the site, the number of nuclide parent nuclides, the activation cross-sectional area, and the decay constant. Acquire (step S10). Then, the control unit 48 divides the reactor storage container 11 into each region R by the region division unit 52 (step S12), and calculates the neutron flux of each region R by the neutron flux distribution calculation unit 54. (Step S14), the radioactivity concentration calculation unit 56 calculates the radioactivity concentration of each region R based on the neutron flux and the material information (step S16). After calculating the radioactivity concentration, the control unit 48 outputs the image data and the radioactivity concentration information (concentration information) to the output unit 44 by the radioactivity concentration map generation unit 58, and the radioactivity concentration to the output unit 44. Display the map (step S18). In this radioactivity concentration map, the radioactivity concentration for a plurality of parts having different materials is displayed on one screen 44A.

The control unit 48 generated the radioactivity concentration map from the calculation result of the radioactivity concentration, but since the value of the radioactivity concentration itself is also calculated, it is necessary to create data other than the radioactivity concentration map. Can be done. FIG. 8 is a diagram showing the calculation result of the radioactivity concentration in each Z direction. The radioactivity concentration calculation unit 56 calculates the radioactivity concentration for each region R. Therefore, the radioactivity concentration display device 40 according to the present embodiment can notify the user of the value of the radioactivity concentration for each region R, that is, for each position. Further, as shown by the line segment L in FIG. 8, the radioactivity in the Z direction is displayed in a graph by displaying the value of the radioactivity concentration in each Z direction for the region R in which the X direction and the Y direction are at the same position. The change in concentration can be confirmed. Of course, the value of the radioactivity concentration in each direction in the Z direction may be graphed.

As described above, the radioactivity concentration display device 40 according to the present embodiment has a control unit 48 (calculation unit) and an output unit 44. The control unit 48 calculates the radioactivity concentration for each activated nuclide for each site of the structure having a plurality of sites whose materials are different from each other, based on the material information of the sites. Further, the output unit 44 displays on the screen the information on the radioactivity concentration of each portion calculated by the control unit 48 and the image of the structure. The radioactivity concentration display device 40 displays information on the radioactivity concentration of parts having different materials and an image of the structure. Therefore, the radioactivity concentration display device 40 can simultaneously display the radioactivity concentration distributions of different parts even if there are parts whose materials are different from each other. Therefore, according to the radioactivity concentration display device 40, the state of the radioactivity concentration distribution for the structure can be appropriately confirmed.

Further, the control unit 48 calculates the radioactivity concentration for all of the plurality of activated nuclides contained in the site, totals the radioactivity concentration for each activated nuclide, and the output unit 44 performs the total radioactivity concentration. Display information about. In this radioactivity concentration display device 40, even if there are a plurality of activated nuclides, the radioactivity concentration for each activated nuclide is totaled and displayed on the output unit 44. Therefore, according to this radioactivity concentration display device 40, even if there are a plurality of activated nuclides, the radioactivity concentrations of all the nuclides can be confirmed on the screen, so that the state of the radioactivity concentration distribution can be appropriately checked. You can check.

Further, the control unit 48 calculates a neutron flux for each site, and multiplies the nuclide information for each site calculated based on the material information of the site and the activated cross section for each site with respect to the neutron flux for each site. Then, calculate the radioactivity concentration. Since the radioactivity concentration display device 40 calculates the radioactivity concentration for each part and displays it on the screen, it is possible to appropriately confirm the state of the radioactivity concentration distribution while making the calculation of the radioactivity concentration highly accurate. can.

Further, the control unit 48 has a region division unit 52, a neutron flux distribution calculation unit 54, and a radioactivity concentration calculation unit 56. The area division portion 52 divides the portion into a plurality of areas R. The neutron flux distribution calculation unit 54 calculates the neutron flux for each region R. The radioactivity concentration calculation unit 56 calculates the radioactivity concentration of the region R by multiplying the neutron bundle by the nuclear species information of the region R and the activation cross-sectional area of the region R acquired based on the material information of the region. Then, by calculating the radioactivity concentration of the region R for a plurality of regions R (all regions R in this embodiment), the radioactivity concentration for each region is calculated. Since the radioactivity concentration display device 40 calculates the radioactivity concentration for each region R and displays it on the screen, the state of the radioactivity concentration distribution can be appropriately confirmed while making the calculation of the radioactivity concentration highly accurate. Can be done.

Further, the output unit 44 superimposes and displays the information on the radioactivity concentration on the image of the structure. According to the radioactivity concentration display device 40, by superimposing the information on the radioactivity concentration on the image of the structure, the radioactivity concentration distribution for each position of the structure can be appropriately visually recognized.

Further, the output unit 44 displays the information on the radioactivity concentration separately for each numerical range of the radioactivity concentration. According to this radioactivity concentration display device 40, since the radioactivity concentration is displayed in a state of being classified by level, it is possible to appropriately visually recognize which region has a high radioactivity concentration and the like, and effectively dispose of the radioactivity. You can confirm.

Further, the output unit 44 displays the information on the radioactivity concentration of each portion calculated by the control unit 48 and the image of the structure on one screen 44A. According to this radioactivity concentration display device 40, even if there are parts having different materials from each other, the radioactivity concentration distribution of the different parts can be displayed on one screen 44A, so that the state of the radioactivity concentration distribution for the structure Can be confirmed more appropriately.

Further, the radioactivity concentration display device 40 (radioactivity concentration calculation device) according to the present embodiment calculates the radioactivity concentration of a structure having a plurality of parts whose materials are different from each other, and includes the region division unit 52 and the region division unit 52. It has a neutron bundle distribution calculation unit 54 and a radioactivity concentration calculation unit 56. The area division portion 52 divides the portion into a plurality of areas R. The neutron flux distribution calculation unit 54 calculates the neutron flux for each region R. The radioactivity concentration calculation unit 56 calculates the radioactivity concentration of the region R by multiplying the neutron bundle by the nuclear species information of the region R and the activation cross-sectional area of the region R acquired based on the material information of the region. Then, by calculating the radioactivity concentration of the region R for a plurality of regions R (all regions R in this embodiment), the radioactivity concentration for each region is calculated. Since the radioactivity concentration display device 40 calculates the radioactivity concentration for each region R and displays it on the screen, the state of the radioactivity concentration distribution can be appropriately confirmed while making the calculation of the radioactivity concentration highly accurate. Can be done.

Although the embodiments of the present invention have been described above, the embodiments are not limited by the contents of the embodiments. Further, the above-mentioned components include those that can be easily assumed by those skilled in the art, those that are substantially the same, that is, those in a so-called equal range. Further, the above-mentioned components can be combined as appropriate. Further, various omissions, replacements or changes of the components can be made without departing from the gist of the above-described embodiment.

1 Nuclear power plant 11 Reactor containment vessel 11A Externally shielded concrete 11B Reactor containment vessel (carbon steel)
11C Secondary shielded concrete 11D Primary shielded concrete 40 Radioactivity concentration display device (Radiation concentration calculation device)
44 Output section (display section)
48 Control unit (calculation unit)
50 Structure information acquisition unit 52 Region division unit 54 Neutron flux distribution calculation unit 56 Radioactivity concentration calculation unit 58 Radioactivity concentration map generation unit

Claims (9)

For a structure having a plurality of parts whose materials are different from each other, a calculation unit for calculating the radioactivity concentration for each activated nuclide based on the material information of the parts, and a calculation unit for each part.
It has a display unit that links the information on the radioactivity concentration of each of the parts calculated by the calculation unit and the image of the structure to the position of the structure and displays it on the screen .
The calculation unit
A region division part that divides the model of the part into multiple regions with a three-dimensional mesh, and
A neutron flux distribution calculation unit that calculates neutron flux for each region,
By multiplying the neutron bundle by the nuclear species information of the region and the activation cross-sectional area of the region acquired based on the material information of the region, the radioactivity concentration of the region is calculated and the radiation of the region is emitted. It is provided with a radioactivity concentration calculation unit for calculating the radioactivity concentration for each of the sites by calculating the radioactivity concentration for each of the plurality of the regions in association with the three-dimensional position coordinates of the regions.
Radioactivity concentration display device. The calculation unit calculates the radioactivity concentration for all of the plurality of activated nuclides contained in the site, and totals the radioactivity concentration for each activated nuclide.
The radioactivity concentration display device according to claim 1, wherein the display unit displays information on the total radioactivity concentration. The calculation unit calculates a neutron flux for each site, and obtains the nuclide information for each site calculated based on the material information of the site and the activated cross-sectional area for each site with respect to the neutron flux for each site. The radioactivity concentration display device according to claim 1 or 2, wherein the radioactivity concentration is calculated by multiplying by. The radioactivity concentration display device according to any one of claims 1 to 3 , wherein the display unit superimposes and displays information on the radioactivity concentration on an image of the structure. The radioactivity concentration display device according to claim 4 , wherein the display unit displays information on the radioactivity concentration separately for each numerical range of the radioactivity concentration. Any of claims 1 to 5 , wherein the display unit displays information on the radioactivity concentration of each of the parts calculated by the calculation unit and an image of the structure on one screen. The radioactivity concentration display device according to item 1. It is a radioactivity concentration calculation device that calculates the radioactivity concentration of a structure having multiple parts whose materials are different from each other.
A region division part that divides the model of the part into multiple regions with a three-dimensional mesh , and
A neutron flux distribution calculation unit that calculates neutron flux for each region,
By multiplying the neutron bundle by the nuclear species information of the region and the activation cross-sectional area of the region acquired based on the material information of the region, the radioactivity concentration of the region is calculated, and the radioactivity concentration of the region is calculated. A radioactivity concentration calculation unit that calculates the radioactivity concentration for each of the parts by calculating the radioactivity concentration for each of the regions in association with the three-dimensional position coordinates of the regions .
Radioactivity concentration calculation device. For a structure having a plurality of parts whose materials are different from each other, a calculation step for calculating the radioactivity concentration for each activated nuclide based on the material information of the parts, and a calculation step for each part.
A display step in which information on the radioactivity concentration of each of the parts calculated in the calculation step and an image of the structure are linked to the position of the structure and displayed on the screen.
The calculation step is
A region division step that divides the model of the site into multiple regions with a three-dimensional mesh, and
The neutron flux distribution calculation step for calculating the neutron flux for each region,
By multiplying the neutron bundle by the nuclear species information of the region and the activation cross-sectional area of the region acquired based on the material information of the region, the radioactivity concentration of the region is calculated and the radiation of the region is emitted. A radioactivity concentration calculation step for calculating the radioactivity concentration for each of the sites by calculating the radioactivity concentration for each of the plurality of the regions in association with the three-dimensional position coordinates of the regions.
A method for displaying the radioactivity concentration. It is a radioactivity concentration calculation method for calculating the radioactivity concentration of a structure having a plurality of parts having different materials from each other.
A region division part that divides the model of the part into multiple regions with a three-dimensional mesh , and
A neutron flux calculation step for calculating a neutron flux for each region,
By multiplying the neutron bundle by the nuclear species information for each region and the activation cross-sectional area for each region, which were acquired based on the material information of the region, the radioactivity concentration for each region was calculated. A radioactivity concentration calculation step for calculating the radioactivity concentration for each of the regions by calculating the radioactivity concentration for each region in association with the three-dimensional position coordinates of the region for each of a plurality of regions. When,
A method for calculating the radioactivity concentration.

Images