JP2017181221A - Space dose rate estimation method and space dose rate display method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for estimating a space dose rate and a method for displaying a space dose rate which can segmentalize and grasp the space dose rates of areas to be decontaminated and can increase the efficiency of the decontamination work.SOLUTION: The method for estimating a space dose rate typically includes the steps of: measuring a space dose rate in a specific measuring direction using a directivity radiation detector 100; imaging the same range using a thermal image measuring device 110 as when using the directivity radiation detector; and estimating a spot with a lower temperature of the thermal image taken by the thermal image measuring device to be a spot with a higher dose rate.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an air dose rate estimation method and an air dose rate display method using a directional radiation detector and a thermal image measurement device.

  When decontaminating radioactive contamination, there is a radiation dose rate as an index for judging the degree and distribution of contamination. In normal dose rate measurement, an air dose rate at a predetermined height (for example, 1 m on the ground surface) is measured. In order to perform decontamination efficiently, it is necessary to know the location (contamination source) where radioactive materials are deposited. However, since normal air dose rate measurement detects radiation from almost all directions, it is vaguely understood that the dose in the vicinity thereof is high, and the position of a specific contamination source is difficult to understand.

  Therefore, a radiation detector having directivity has been proposed as a radiation measuring instrument (Patent Document 1). If a radiation detector having such directivity is used, it is possible to measure a dose rate in an arbitrary direction. Therefore, the air dose rate from a specific direction can be evaluated by changing the measurement direction.

  However, when a radiation detector having directivity is used, it is natural that only a radiation dose within the detection angle range can be measured. Then, even if the radiation doses in a plurality of directions are measured, if the sparseness is measured, there is a possibility that measurement in a direction having a large influence on the air dose rate may be omitted. On the other hand, if the measurement directions are too dense, there are problems that the measurement ranges overlap and it takes time to work, and that the sum of the air dose rate components from each measurement direction does not match the on-site air dose rate.

  Therefore, Patent Document 2 discloses an air dose rate measurement method that measures air dose rates in a plurality of measurement directions by switching each detection angle using a directional radiation detector. According to this, since the measurement direction is switched for each detection angle, all directions from a certain measurement position can be measured as much as possible without overlapping. According to the technique of Patent Document 2, images in each measurement direction are taken from the position where the air dose rate is measured, and images having the same angle of view as the detection angle of the directional radiation detector are arranged according to the measurement direction. By displaying, it is possible to display at a glance how much radiation has been received from which location.

JP 2002-214353 A Japanese Patent Application No. 2014-001103

  According to the air dose rate measuring method of Patent Document 2, the air dose rate in each direction can be grasped by referring to the images in the respective measurement directions, and can be used as an index when examining the decontamination work. For example, an area corresponding to an image having a high air dose rate among images in each measurement direction can be specified as a decontamination target.

  However, with the method of Patent Document 2, although the area (measurement range of the directional radiation detector) shown in the image can be specified as the area to be decontaminated, the area of the area shown in the image Of these, it is not possible to identify which place had the highest air dose rate. For this reason, it is necessary to perform decontamination work on the entire area shown in the image. The area shown in the image is narrowed when the detection direction is directed directly below, but it is rapidly widened as it is raised toward the horizon. Therefore, although it is the technique of patent document 2, although the area | region of a decontamination object can be specified more efficiently than before, the improvement was calculated | required so that work efficiency could be raised more.

  In view of the above problems, the present invention is capable of further subdividing and grasping the air dose rate of the area to be decontaminated, and the air dose rate estimation method and the air dose capable of further improving the efficiency of the decontamination work An object is to provide a rate display method.

  In order to solve the above-described problems, a typical configuration of the air dose rate estimation method according to the present invention is to measure the air dose rate in a specific measurement direction using a directional radiation detector, and to use a thermal image measurement device. Then, the same range as that of the directional radiation detector is photographed, and the place where the temperature is low among the thermal images photographed by the thermal image measuring device is estimated as the place where the dose rate is high.

  The inventor first measured the air dose rate in various areas with different topography, and found that the air dose rate tends to be higher in places lower than the surroundings. From this, it was inferred that the radioactive dose in places higher than the surroundings would be swept away by rain, etc., so that the air dose rate would be higher in lower places. And it came to the present invention paying attention that the place where rainwater etc. stays is lower in temperature than the high place even if it is dry.

  That is, according to the said structure, while measuring the air dose rate of a specific measurement direction, the temperature distribution in the area which measured the air dose rate is acquired by measuring the thermal image of the same range. Thereby, the place where temperature was low in this area can be estimated as a place with a high air dose rate. Therefore, the air dose rate of the area to be decontaminated can be further subdivided and grasped, and the efficiency of the decontamination work can be further increased.

  In order to solve the above problems, a representative configuration of the air dose rate display method according to the present invention is to measure the air dose rate in a specific measurement direction using a directional radiation detector, and to use a thermal image measurement device. Then, the same range as that of the directional radiation detector is photographed, and the measured value by the directional radiation detector is added to the thermal image photographed by the thermal image measuring device.

  The component corresponding to the technical idea in the air dose rate estimation method mentioned above and its description are applicable also to the said air dose rate display method. Moreover, according to this structure, an air dose rate can be confirmed by visually observing a thermal image. As a result, it is possible to more accurately determine a place where decontamination is necessary in the area to be decontaminated.

  In view of the above problems, the present invention is capable of further subdividing and grasping the air dose rate of the area to be decontaminated, and the air dose rate estimation method and the air dose capable of further improving the efficiency of the decontamination work. An object is to provide a rate display method.

It is a figure explaining the air dose rate estimation method concerning this embodiment. It is a figure explaining the display of an air dose rate. It is a figure explaining the air dose rate display method concerning this embodiment.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The dimensions, materials, and other specific numerical values shown in the embodiments are merely examples for facilitating understanding of the invention, and do not limit the present invention unless otherwise specified. In the present specification and drawings, elements having substantially the same function and configuration are denoted by the same reference numerals, and redundant description is omitted, and elements not directly related to the present invention are not illustrated. To do.

  FIG. 1 is a diagram for explaining an air dose rate estimation method according to the present embodiment. FIG. 1A is a diagram illustrating an evaluation range of a directional radiation detector, and FIG. 1B is a diagram illustrating an evaluation surface of the ground surface. In the present embodiment, the air dose rate estimation method is described first, and then the air dose rate display method is described.

  In the air dose rate estimation method of the present embodiment, a directional radiation detector 100 shown in FIG. The directional radiation detector 100 is a radiation detector that can particularly detect radiation within a predetermined detection angle α with the measurement direction as the center. In order to efficiently and accurately evaluate radiation in all directions using the directional radiation detector 100, it is important how to measure all directions without overlapping.

  Therefore, in this embodiment, the directional radiation detector 100 is used to measure the air dose rate in a specific measurement direction. In FIG. 1B, the horizontal direction around the directional radiation detector 100 is measured by measuring the air dose rate in the areas 102 a to 102 h in the eight measurement directions while switching the detection angle of the directional radiation detector 100. The air dose rate is measured. Thereby, it is possible to eliminate the gap between the adjacent measurement ranges and perform measurement with the minimum number of times without duplication.

  Furthermore, in this embodiment, the thermal image measuring device 110 is used to capture a thermal image in the same range as the range in which the air dose rate is measured by the directional radiation detector 100. That is, thermal images of the areas 102a to 102h are taken in eight measurement directions. Thereby, the heat distribution in the areas 102a to 102h can be acquired.

  In particular, in this embodiment, as shown in FIG. 1B, the directional radiation detector 100 and the thermal image measurement device 110 are fixed at the same position using the same tripod 120 to perform measurement and photographing. Thereby, the air dose rate and the thermal image can be measured at the same angle. Therefore, there is no deviation in angle, and data reliability can be improved.

  Note that the thermal image measurement device 110 can also capture a visible light image in addition to the thermal image. Therefore, when taking a thermal image, it is preferable to take a visible light image at the same time. Further, the visible light image does not necessarily have to be taken by the thermal image measurement device, and a visible light camera may be added in addition to the directional radiation detector 100 and the thermal image measurement device 110.

  FIG. 2 is a diagram for explaining the display of the air dose rate. In FIG. 2, the air dose rate measured in the areas 102 a to 102 h shown in FIG. 1B is added to the visible light image of the areas 102 a to 102 h photographed together with the thermal image by the thermal image measuring device 110 and displayed. ing. As shown in FIG. 1B, the visible light images of the areas 102a to 102h are continuously displayed in the horizontal direction so that the visible light images of the areas 102a to 102h are displayed as one panoramic photograph. .

  Then, by confirming the value of the air dose rate added to the visible light image (0.04 μSv / h in the case of the area 102a), the area around the directional radiation detector 100 and the thermal image measurement device 110 is checked. It is possible to grasp which area has a high air dose rate. At this time, especially by adding the air dose rate to the visible light image as in the present embodiment, it is possible to intuitively understand which area is the area with the high air dose rate.

  That is, as described above, the space around the directional radiation detector 100 and the thermal image measurement device 110 is divided into a plurality of directions, and the air dose rate is measured in each direction. An area with a high dose rate can be roughly identified. However, at this stage, it is impossible to determine which of the areas with a high air dose rate has a particularly high air dose rate. For this reason, the object of decontamination work will be the entire area.

  Therefore, in the air dose rate estimation method of the present embodiment, the thermal distribution of the thermal image in the area where the air dose rate is high is referred. For example, in the example shown in FIG. 2, since the area 102d has the highest air dose rate, the thermal image is referred to. And it estimates that the place where temperature was low among the thermal images image | photographed with the thermal image measuring device 110 is a place where a dose rate is high.

  FIG. 3 is a diagram for explaining an air dose rate display method according to the present embodiment. FIG. 3A illustrates an example of a visible light image of grass, and is an image in which an air dose rate is added to the visible light image described in FIG. FIG. 3B illustrates a thermal image of the grass, and is a thermal image corresponding to the visible light image area of FIG. In addition, the numerical value shown outside the square of FIG. 3B is 1 cm of the point actually measured by the inventor using the radiation detector in order to verify the effect of the air dose rate measuring method of the present embodiment. Air dose rate at height.

  In the grass of FIG. 3 (a), as shown in FIG. 3 (b), a place where the color is dark (a place where the temperature is low) has a higher air dose rate than a place where the color is light (a place where the temperature is high) in the thermal image. high. This shows that there is a correlation between the air dose rate and temperature. Further, as shown in FIG. 3B, in the air dose rate display method of the present embodiment, the measured value by the directional radiation detector 100 is appended to the thermal image. Thereby, without reconfirming the air dose rate measured by the directional radiation detector, it is possible to simultaneously confirm the heat distribution and the air dose rate by referring only to the thermal image.

  FIG. 3C illustrates a visible image of a manhole. FIG. 3D is a thermal image obtained by enlarging a part of the visible light image area of FIG. 3C, and the air dose rate of 1 cm height of the point actually measured using the radiation detector is squared. Showing outside. In the manhole as shown in FIG. 3D as well as the grass as shown in FIGS. 3A and 3B, a place where the color is dark (a place where the temperature is low) is a place where the color is light in the thermal image. Air dose rate is higher than (high temperature place). From this, it can be understood that the air dose rate estimation method of the present embodiment is applicable regardless of the state of the ground surface.

  That is, the present invention pays attention to the fact that the place where the air dose rate is high is the place where water flows, and the place where the water flows is dry and the temperature is low. Of course, it has been known that the air dose rate is high in places where water flows, and typical examples of places where the air dose rate is high are those under rain gutters, road gutters, ground and mountainous areas. is there. However, in actual visual observation, the height is difficult to understand, and even if the partial height is known, it is often unclear where the water actually flows. However, when the temperature distribution is acquired from the thermal image, the place where water actually flows is recognized as a low temperature. This makes it possible to know where the water flows, that is, where the air dose rate is high, which cannot be understood from visual observation or empirical rules.

  As described above, according to the air dose rate estimation method of the present embodiment, an area to be decontaminated can be determined by referring to the air dose rate measured by the directional radiation detector 100 first. Then, by referring to the thermal image taken by the thermal image measuring device 110, it is possible to estimate a place having a particularly high air dose rate among the areas to be decontaminated. Thereby, the air dose rate in the area to be decontaminated can be further subdivided and grasped, and the efficiency of the decontamination work can be further increased.

  In FIG. 2 of the present embodiment, the configuration in which the air dose rate is added to the visible light image is illustrated. However, the present invention is not limited to this, and the air dose rate is added to the thermal image captured by the thermal image measurement device 110. It is also possible to display them continuously. It is also possible to adopt a configuration in which the air dose rate and the thermal image are associated with each other by an area identification number or the like without taking a visible light image.

  Further, as described above, the numerical values shown outside the frame in FIGS. 3B and 3D are the space of 1 cm height of the point actually measured using the radiation detector in order to confirm the effect of the present invention. It is a dose rate. On the other hand, since the numerical value shown in the center in the frame of FIGS. 3A to 3D is the air dose rate measured from a position away from the ground surface by the directional radiation detector 100, it is actually Causes distance attenuation. Therefore, in practice, the value is not the same as the air dose rate measured at a height of 1 cm.

  As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, it cannot be overemphasized that this invention is not limited to the example which concerns. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. Understood.

  The present invention can be used as an air dose rate estimation method and an air dose rate display method using a directional radiation detector and a thermal image measurement device.

DESCRIPTION OF SYMBOLS 100 ... Directional radiation detector, 102a-102h ... Area, 110 ... Thermal image measuring device, 120 ... Tripod

Claims (2)

Measure the air dose rate in a specific measurement direction with a directional radiation detector,
Photograph the same range as the directional radiation detector using a thermal image measurement device,
A method for estimating an air dose rate, wherein a place where a temperature is low among heat images taken by the heat image measurement device is estimated as a place where a dose rate is high. Measure the air dose rate in a specific measurement direction with a directional radiation detector,
Photograph the same range as the directional radiation detector using a thermal image measurement device,
A method for displaying an air dose rate, comprising adding a measurement value obtained by the directional radiation detector to a thermal image taken by the thermal image measurement device.