JP5920166B2 - Radioactivity inspection method and radioactivity inspection apparatus - Google Patents

Description

  The present invention relates to a radioactivity inspection method and a radioactivity inspection apparatus that detect radiation from cesium 134 and radiation from cesium 137 emitted from a subject with a radiation detector.

  Due to the accident at the Tokyo Electric Power Company Fukushima Daiichi Nuclear Power Station due to the Great East Japan Earthquake on March 11, 2011, a wide range of foods contained radioactive materials. To address this, there is a growing need for food radioactivity screening tests. For example, in a food radioactivity screening inspection apparatus that performs a radioactivity test on rice as food, a rice bag containing about 30 kilograms of rice is conveyed by a conveyor, and a radiation detector disposed above and below the conveyor. One having a configuration for detecting gamma rays emitted from a rice bag has been proposed.

  On March 1, 2012, the Ministry of Health, Labor and Welfare, Ministry of Health, Labor and Welfare, Food Safety Department, Food Safety Department, Monitoring and Safety Division, published “About Partial Revision of Radiocesium Screening Law in Foods”. Prior to this publication, radioactive substances in foods have been monitored by local governments based on guidelines established by the Ministry of Health, Labor and Welfare. From the perspective of ensuring efficient and effective monitoring, The method for screening radioactive cesium in foods has been established, and the introduction of screening tests by introducing simple measuring instruments has been promoted. And in the said revision, the technical performance requirements in "the radioactive cesium screening method in foodstuff" etc. are changed (refer nonpatent literature 1).

In this “method for screening radioactive cesium in foods”, a food radioactivity screening test apparatus capable of analyzing cesium 134 (Cs-134 / ¹³⁴ Cs) and cesium 137 (Cs-137 / ¹³⁷ Cs) is used. Samples that have been screened and whose screening results do not fall below a certain level and the radioactive cesium cannot be determined to be reliably lower than the reference value should be tested using a test method such as gamma spectrometry using germanium semiconductors. The test results are to be confirmed.

March 1, 2012 Ministry of Health, Labor and Welfare, Pharmaceutical and Food Bureau, Food Safety Department, Monitoring and Safety Division

  In such a screening inspection apparatus, a conversion coefficient for converting a count rate (Count per second / CPS), which is a detection value by a radiation detector, to a reference value (Bq / kg) is set in advance. By the way, although the target of the screening test in such a screening test apparatus is both cesium 134 and cesium 137, when setting the conversion coefficient described above, a single standard source of cesium 137 is usually used. .

  At this time, the half-life of cesium 134 is 2.7 years, and the half-life of cesium 137 is 30 years. For this reason, when a specimen containing cesium 134 and cesium 137 is measured using the above-described conversion coefficient, it is a safe but significant overestimation, and is determined to have a higher radioactivity concentration. It will be. In such a case, it is necessary to perform the inspection again using a test method such as gamma-ray spectrometry using a germanium semiconductor, and the inspection cost and inspection time increase more than necessary.

  The present invention has been made to solve the above problems, and a radioactivity test method and a radioactivity test apparatus capable of accurately performing a radioactivity test in consideration of the mixing ratio of cesium 134 and cesium 137. The purpose is to provide.

A value obtained by detecting radiation from cesium 134 and cesium 137 emitted from the subject by a radiation detector, and a conversion coefficient for converting the value detected by the radiation detector into radioactivity per unit weight of cesium In the radioactivity inspection method in which the multiplication result is compared with a reference value, a radiation detection value when a mixed standard radiation source of cesium 134 and cesium 137 is detected by the radiation detector, and a single value of cesium 134 Standard source measurement for measuring a radiation detection value when one standard radiation source is detected by the radiation detector and a radiation detection value when a single standard radiation source of cesium 137 is detected by the radiation detector An object measurement process for measuring a detected value of radiation when the object is detected by the radiation detector, and the standard radiation source measurement process. A mixture ratio calculating step for calculating a mixture ratio of cesium 134 and cesium 137 in the subject based on the detected value of the radiation measured in step and the detected value of the radiation measured in the subject measuring step; The detection value of the radiation detected by the radiation detector specified based on the mixing ratio of cesium 134 and cesium 137 in the subject with respect to the multiplication result of the detection value measured in the specimen measurement step and the conversion coefficient The first correction coefficient, which is a coefficient for correction corresponding to the mixing ratio, the radiation detection value when the mixed standard source of cesium 134 and cesium 137 is detected by the radiation detector, and the subject the detected value of radiation by the radiation detector calculated based on the detected value of radiation when detected by the radiation detector of the radiation detector It multiplies the second correction coefficient is a coefficient for correcting corresponding to time, characterized by comprising a comparison step of comparing the result of the multiplication with a reference value.

A value obtained by detecting radiation from cesium 134 and cesium 137 emitted from the subject by a radiation detector, and a conversion coefficient for converting the value detected by the radiation detector into radioactivity per unit weight of cesium In the radioactivity inspection method of comparing the multiplication result with a reference value, the radiation ratio of the cesium 134 and cesium 137 and the radiation by the radiation detector when the subject is detected by the radiation detector. A first correction coefficient storing step for storing a relationship with a first correction coefficient that is a coefficient for correcting the detected value of the first detection coefficient in accordance with the mixture ratio; and a mixed standard radiation source of cesium 134 and cesium 137 as the radiation. A first peak value including a first peak value of gamma rays from cesium 134 and a peak value of gamma rays from cesium 137 when detected by the detector. The detected value of the radiation in the second energy window EW2 including the second peak value of the gamma rays from the energy window EW1 and the cesium 134, and the first energy when the single standard source of the cesium 134 is detected by the radiation detector. A standard for measuring the detected value of radiation in the window EW1 and the second energy window EW2, and the detected value of radiation in the first energy window EW1 when a single standard source of cesium 137 is detected by the radiation detector. A radiation source measuring step, a subject measuring step of measuring a detected value of radiation in the first energy window EW1 and the second energy window EW2 when the subject is detected by the radiation detector, and the standard radiation source Cesium 134 and cesium 1 obtained in the measurement process 7 when the radiation detector detects the radiation detection value in the first energy window EW1 when the mixed radiation source is detected by the radiation detector and the subject obtained in the subject measurement step is detected by the radiation detector. Based on the detected value of radiation in the first energy window EW1, a second correction coefficient that is a coefficient for correcting the detected value of radiation by the radiation detector in accordance with the sensitivity of the radiation detector is calculated. Cesium 134 and cesium 137 in the subject based on the second correction coefficient calculating step, the radiation detection value measured in the standard source measurement step, and the radiation detection value measured in the subject measurement step. And a cesium 134 and cesium 13 in the subject obtained in the mixture ratio calculation step. 7 and a first correction coefficient specifying step for specifying a first correction coefficient from the relationship between the mixing ratio of cesium 134 and cesium 137 stored in the first correction coefficient storing step and the first correction coefficient. And a first correction coefficient obtained in the first correction coefficient specifying step with respect to a multiplication result of the detected value of radiation in the first energy window EW1 measured in the subject measurement step and the conversion coefficient, A comparison step of multiplying the second correction coefficient obtained in the second correction coefficient calculation step and comparing the multiplication result with a reference value is provided.

  The invention according to claim 3 is the invention according to claim 2, wherein the first energy window EW1 is a region including 605 keV and 662 keV as energy of gamma rays, and the second energy window EW2 is energy of gamma rays. As a region including 796 keV.

  The invention according to claim 4 is the invention according to claim 2 or claim 3, wherein the cesium 134 and cesium 137 are based on the time point when the first correction coefficient stored in the first correction coefficient storage step is specified. And the cesium 134 single standard source and the cesium 137 single standard source are corrected for attenuation.

A value obtained by detecting radiation from cesium 134 and cesium 137 emitted from the subject by a radiation detector, and a conversion coefficient for converting the value detected by the radiation detector into radioactivity per unit weight of cesium In the radioactivity test apparatus that compares the multiplication result with a reference value, and the radiation ratio of the cesium 134 and cesium 137 and the radiation detected by the radiation detector when the subject is detected by the radiation detector. A first correction coefficient storage unit that stores a relationship with a first correction coefficient that is a coefficient for correcting the detected value corresponding to the mixing ratio, and a single standard radiation source of cesium 134 by the radiation detector. The detected value of radiation when detected, the detected value of radiation when a single standard radiation source of cesium 137 is detected by the radiation detector, and the subject A mixing ratio calculation unit that calculates a mixing ratio of cesium 134 and cesium 137 in the subject based on a detected value of radiation when detected by a radiation detector, and a mixed standard radiation source of cesium 134 and cesium 137 Based on the detection value of the radiation when the radiation detector detects the radiation and the detection value of the radiation when the subject is detected by the radiation detector, the detection value of the radioactivity by the radiation detector is A second correction coefficient calculation unit that calculates a second correction coefficient that is a coefficient for correction corresponding to the sensitivity of the radiation detector; a mixing ratio of cesium 134 and cesium 137 calculated by the mixing ratio calculation unit; A first correction coefficient that identifies the first correction coefficient from the relationship between the mixing ratio of cesium 134 and cesium 137 stored in the first correction coefficient storage unit and the first correction coefficient. A coefficient specifying unit; a first correction coefficient obtained by the first correction coefficient specifying unit for a multiplication result of the detection value of the radiation when the subject is detected by the radiation detector and the conversion coefficient; A comparison unit that multiplies the second correction coefficient obtained by the second correction coefficient calculation unit and compares the multiplication result with a reference value is provided.

  According to the first to fifth aspects of the present invention, the radioactivity inspection can be accurately executed in consideration of the mixing ratio of cesium 134 and cesium 137. For this reason, it becomes possible to prevent effectively that the inspection cost and inspection time of radioactivity increase more than necessary.

  According to the fourth aspect of the present invention, the attenuation correction is performed in consideration of the difference in the half-life between cesium 134 and cesium 137, so that the radioactivity can be accurately measured regardless of the mixing ratio of cesium 134 and cesium 137. An inspection can be performed.

It is a perspective view of the radioactivity inspection apparatus concerning this invention. 1 is a schematic cross-sectional view of a radioactivity inspection apparatus according to the present invention. It is a block diagram which shows the main control systems of the radioactivity inspection apparatus based on this invention. It is a graph which shows the detected value of the radiation by the 1st radiation detector 7 and the 2nd radiation detector 8 in 1st energy window EW1 and 2nd energy window EW2. It is a flowchart of the radioactivity inspection method which concerns on this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. First, the basic configuration of the radioactivity inspection apparatus will be described. FIG. 1 is a perspective view of a radioactivity inspection apparatus according to the present invention. FIG. 2 is a schematic cross-sectional view of the radioactivity inspection apparatus according to the present invention.

  This radioactivity inspection apparatus is a food radioactivity screening inspection apparatus for carrying out a radioactivity inspection on a rice bag R in which, for example, 30 kilograms of rice is stored, and an entrance 2 for carrying the rice bag R therein. And the bag main body 1 in which the carry-out port 3 for carrying out the rice bag R is formed, and the rice bag R loaded into the device main body 1 from the carry-in port 2 and the inspection finished from the carry-out port 3 A pair of conveyors 4 for carrying out R (when these are generically referred to simply as “conveyor 4”) and a display unit 9 for displaying inspection results are provided.

  A first radiation detector 7 for detecting radiation radiated from the rice bag R is disposed at a position above the conveyor 4 in the apparatus main body 1. And around this 1st radiation detector 7, it is comprised from the lead which has the shielding effect of a radiation, and has the shape which surrounds areas other than the area | region of the lower side (conveyor 4 side) in the 1st radiation detector 7. 1 A radiation shielding member 5 is provided. The first radiation shielding member 5 has a flange 51 extending in the direction opposite to the conveying direction of the rice bag R by the conveyor 4 in the direction of the carry-in port 2 above the conveyor 4, and the direction of the carry-out port 3 above the conveyor 4. And a flange 52 extending in the conveying direction of the rice bag R by the conveyor 4. The first radiation shielding member 5 is supported by a support plate 12 in the apparatus main body 1. The support plate 12 is formed with an opening corresponding to the opening facing downward in the first radiation shielding member 5.

  On the other hand, a second radiation detector 8 for detecting radiation radiated from the rice bag R is disposed at a position below the conveyor 4 in the apparatus main body 1. Then, the second radiation detector 8 is formed of lead having a radiation shielding effect around the second radiation detector 8 and has a shape surrounding a region other than the upper region (conveyor 4 side) of the second radiation detector 8. A radiation shielding member 6 is provided. The second radiation shielding member 6 includes a hook 61 extending in the direction opposite to the conveying direction of the rice bag R by the conveyor 4 toward the carry-in port 2 below the conveyor 4, and the direction of the carry-out port 3 below the conveyor 4. And a flange 62 extending in the conveying direction of the rice bag R by the conveyor 4. The second radiation shielding member 6 is supported by a support plate 13 in the apparatus main body 1.

  A guide plate 41 is disposed between the conveyor 4 disposed on the carry-in port 2 side of the apparatus main body 1 and the conveyor 4 disposed on the carry-out port 3 side. The guide plate 41 is made of a material having a low radiation absorption rate, such as carbon. For this reason, the radiation from the rice bag R can be efficiently measured by the second radiation detector 8 without being blocked by the conveyor 4.

  The first radiation detector 7 and the second radiation detector 8 described above detect radiation from an opening in the first radiation shielding member 5 or the second radiation shielding member 6, for example, by combining a scintillator and a photomultiplier. It has the composition to do. The width in the direction orthogonal to the conveyance direction of the rice bag R in the radiation detection region of the first radiation detector 7 and the second radiation detector 8 is the width of the carry-in entrance 2 in the direction orthogonal to the conveyance direction of the rice bag R. It is almost the same. And the radiation detection surface in the 1st radiation detector 7 is arrange | positioned above the lower surface of the collar part 51 in the 1st radiation shielding member 5, and the collar part 52, The radiation detection surface in the 2nd radiation detector 8 Are disposed below the upper surfaces of the flange 61 and the flange 62 in the second radiation shielding member 6.

  FIG. 3 is a block diagram showing a main control system of the radioactivity inspection apparatus according to the present invention.

  This radioactivity inspection apparatus includes a control unit 100 that controls the entire apparatus. The control unit 100 includes a first correction coefficient storage unit 101, a mixture ratio calculation unit 102, a second correction coefficient calculation unit 103, a first correction coefficient specifying unit 104, a comparison unit 105, and a determination unit 106, which will be described later. The control unit 100 is connected to the first radiation detector 7, the second radiation detector 8, and the display unit 9 described above.

  In the radioactivity inspection apparatus having the above-described configuration, when the screening inspection of rice in the rice bag R is executed, the operator places a large number of rice bags R placed on the pallet on the conveyor 4 sequentially. The rice bag R placed on the conveyor 4 is carried into the apparatus main body 1 through the carry-in port 2. And when this rice bag R passes between the 1st radiation detector 7 and the 2nd radiation detector 8, from the rice put into the rice bag R by the 1st radiation detector 7 and the 2nd radiation detector 8 Radiation is detected.

  Thus, in the radioactivity inspection apparatus according to the present invention, the first radiation detector 7 and the second radiation detector 8 are conveyed by the conveyor 4 and detect radiation emitted from the moving rice bag R. The radioactivity inspection can be performed while the rice bags R are continuously conveyed, and a large amount of rice bags R can be efficiently inspected. For this reason, even when a screening test is performed on all rice bags R, the test can be completed in a short time.

  At this time, since the first radiation detector 7 is surrounded by the first radiation shielding member 5 and the second radiation detector 8 is surrounded by the second radiation shielding member 6, respectively, the influence of background radiation is reduced. Without receiving it, it becomes possible to detect radiation accurately.

  The detection value of the radiation by the first radiation detector 7 and the second radiation detector 8 is compared with a preset reference value. This reference value is, for example, a value of about 50 Bq per kilogram. When the radiation detection values by the first radiation detector 7 and the second radiation detector 8 are equal to or less than the reference value, a display to that effect (for example, “◯”) is displayed. On the other hand, when the detection value of the radiation by the first radiation detector 7 and the second radiation detector 8 exceeds the reference value, the display unit 9 displays that fact (for example, “x”), A warning sound is generated.

  Next, the structure of the characteristic part of this invention is demonstrated. When comparing the detection value of radiation by the first radiation detector 7 and the second radiation detector 8 with a preset reference value, a count which is a detection value by the first radiation detector 7 and the second radiation detector 8 is used. A conversion factor is used to convert the rate to a reference value. This conversion factor is usually set using a single standard source of cesium 137. However, as described above, due to the difference in half-life between cesium 134 and cesium 137, when a subject (rice bag R) containing cesium 134 and cesium 137 is measured, it is a safe but significant overestimation. It will be judged to have a higher radioactivity concentration.

  For this reason, in the radioactivity inspection apparatus according to the present invention, not only the detection value of radiation is multiplied by the conversion coefficient, but also the detection value of radiation by the first radiation detector 7 and the second radiation detector 8 is expressed as cesium 134. The first correction coefficient, which is a coefficient for correction corresponding to the mixing ratio of cesium 137, and the radiation detection values by the first radiation detector 7 and the second radiation detector 8 correspond to the sensitivity of these detectors. Thus, both the second correction coefficient, which is a coefficient for correction, is multiplied.

  Here, the first correction coefficient corresponds to the mixing ratio of cesium 134 and cesium 137 when the rice bag R as the subject is measured by the first radiation detector 7 and the second radiation detector 8. It is a coefficient for correcting. It is known that the detection values of radiation by the first radiation detector 7 and the second radiation detector 8 have different values depending on the mixing ratio of cesium 134 and cesium 137 even if the radiation dose is the same. For this reason, in this radioactivity inspection apparatus, the structure which correct | amends the detection value of the 1st radiation detector 7 and the 2nd radiation detector 8 according to the mixing ratio of cesium 134 and cesium 137 is employ | adopted.

  The mixing ratio of cesium 134 and cesium 137 and the detection values of the first radiation detector 7 and the second radiation detector 8 when the rice bag R is detected by the first radiation detector 7 and the second radiation detector 8 The relationship can be obtained experimentally in advance. For this reason, there is a relationship between the mixing ratio and the first correction coefficient that corresponds to the mixing ratio of cesium 134 and cesium 137 and what value should be used as the first correction coefficient for the mixing ratio. , Which is determined in advance corresponding to the mixing ratio. The relationship between the mixture ratio and the first correction coefficient is stored as a table in the first correction coefficient storage unit 101 shown in FIG. At the time of the radioactivity test described later, the first correction coefficient is specified by the first correction coefficient specifying unit 104 shown in FIG. 3 based on the mixing ratio of cesium 134 and cesium 137, and the detected value of radiation and the conversion coefficient are multiplied. The result is multiplied by this first correction factor.

  As will be described later, the mixing ratio of cesium 134 and cesium 137 is the detection value of radiation when a single standard radiation source of cesium 134 is measured by the first radiation detector 7 and the second radiation detector 8. , A single standard radiation source of cesium 137 measured by the first radiation detector 7 and the second radiation detector 8, and a detected value of the rice bag R as the first radiation detector 7 and the second radiation detector 8. It is calculated based on the detected value of radiation when measured by the above.

  The second correction coefficient is obtained by measuring the detected value of the rice bag R as the subject with the first radiation detector 7 and the second radiation detector 8, and using the first radiation detector 7 and the second radiation detector. 8 is a coefficient for correction corresponding to the sensitivity of 8. The second correction coefficient is obtained by detecting the radiation detection value when the mixed standard radiation source of cesium 134 and cesium 137 is detected by the first radiation detector 7 and the second radiation detector 8, and the rice bag R by the first radiation detector. 7 and the detection value of the radiation when measured by the second radiation detector 8. Then, the multiplication result of the radiation detection value and the conversion coefficient is multiplied by the second correction coefficient.

  Next, a calculation method of the mixing ratio of cesium 134 and cesium 137 and a calculation method of the second correction coefficient will be described. FIG. 4 is a graph showing radiation detection values by the first radiation detector 7 and the second radiation detector 8 in the first energy window EW1 and the second energy window EW2.

  Here, the vertical axis of the graph shown in FIG. 4 indicates the radiation counting rate (CPS), and the horizontal axis of the graph shown in FIG. 4 indicates the energy of gamma rays of radiation (kiloelectron volts / keV). Also, (1) in FIG. 4 shows a mixed standard radiation source (200 Bq) of cesium 134 and cesium 137 composed of cesium 134 of 100 Bq (becquerel) and cesium 137 of 100 Bq, the first radiation detector 7 and the second radiation. The detection result when measured by the detector 8 is shown. Further, (2) in FIG. 4 shows a detected value of radiation when a single standard radiation source of 100 Bq cesium 134 is measured by the first radiation detector 7 and the second radiation detector 8. Further, (3) in FIG. 4 shows the detected value of radiation when a 100 Bq cesium 137 single standard radiation source is measured by the first radiation detector 7 and the second radiation detector 8. Further, (4) in FIG. 4 shows the detected value of radiation when the rice bag R is measured by the first radiation detector 7 and the second radiation detector 8.

  The first energy window EW1 is an energy window including 605 keV which is a first peak value of gamma rays from cesium 134 and 662 keV which is a peak value of gamma rays from cesium 137. The second energy window EW2 is an energy window including 796 keV, which is the second peak value of gamma rays from cesium 134.

  When the first radiation detector 7 and the second radiation detector 8 are generally those using a scintillator and a photomultiplier, the energy resolution is lower than that of a radiation detector using a germanium semiconductor, This causes a problem that the peak value of gamma rays becomes dull. For this reason, the occurrence of such a problem is effectively prevented by setting the first and second energy windows EW1 and EW2 focused only near the peak value of the gamma ray.

  As shown in FIG. 4 (2), when a single standard radiation source of 100 Bq cesium 134 is measured by the first radiation detector 7 and the second radiation detector 8, the detected value of the radiation is obtained in the second energy window EW2. It is assumed that the count number corresponds to 80 Bq. Under this condition, as shown in FIG. 4 (4), when the rice bag R is measured by the first radiation detector 7 and the second radiation detector 8, the detected value of radiation corresponds to 100 Bq in the second energy window EW2. In the case of the count number to be used, the cesium 134 in the rice bag R can be recognized as the count number corresponding to 125 Bq. Then, as shown in FIG. 4 (2), when a single standard radiation source of 100Bq cesium 134 is measured by the first radiation detector 7 and the second radiation detector 8, the detected value of the radiation is the first energy window. Since the count number corresponds to 140 Bq in EW1, if the cesium 134 in the rice bag R is a count number corresponding to 125 Bq, 125 × (140/100) in the first energy window EW1 in FIG. = 175Bq can be determined to be the count number by cesium 134.

  In this case, among the count numbers corresponding to 250 Bq in the first energy window EW1 in FIG. 4 (4), the count number corresponding to 175Bq is cesium 134, so the count number by cesium 137 is the remaining 75Bq. The corresponding count number. At this time, as shown in FIG. 4 (3), when a single standard radiation source of 100Bq cesium 137 is measured by the first radiation detector 7 and the second radiation detector 8, the detected value of the radiation is the first energy. Since it is the count number corresponding to 120 Bq in the window EW1, it can be seen that the cesium 137 in the rice bag R is a count number corresponding to 75 × (120/100) = 90 Bq. Therefore, the mixing ratio of cesium 134 and cesium 137 in the rice bag R is 125: 90. Based on the mixing ratio of cesium 134 and cesium 137, the first correction coefficient stored in the first correction coefficient storage unit 101 is specified.

  As shown in FIG. 4 (1), a mixed standard radiation source (200Bq) of cesium 134 and cesium 137 composed of cesium 134 of 100Bq (becquerel) and cesium 137 of 100Bq is used as the first radiation detector 7 and the second radiation. The detection result in the first energy window EW1 when measured by the detector 8 is a count corresponding to 240Bq. For this reason, when the rice bag R is measured by the first radiation detector 7 and the second radiation detector 8, the detected value is corrected in accordance with the sensitivity of the first radiation detector 7 and the second radiation detector 8. Therefore, the second correction coefficient is (240/200). Here, the reason why only the first energy window EW1 is focused is that the second energy window EW2 has a lower S / N than the first energy window EW1.

  And the final measurement result about the rice bag R is a detection value by the first radiation detector 7 and the second radiation detector 8 with respect to the count number corresponding to 250 Bq in the first energy window EW1 of FIG. Is multiplied by a conversion coefficient for converting the counting rate (CPS) to a reference value (Bq / kg) and multiplied by the specified first correction coefficient and the calculated second correction coefficient. It is determined. The multiplication result is compared with a preset reference value to determine whether or not the reference value is exceeded.

  Note that the mixed standard source of cesium 134 and cesium 137, the single standard source of cesium 134, and the single standard source of cesium 137 decay with time corresponding to their half-life. For this reason, it is necessary to execute attenuation correction in order to accurately perform the radioactivity measurement.

  For example, as of January 2012, for a mixed standard source with cesium 134 cesium (half life 2.7 years) is 100 Bq / kg and cesium 137 (half life 30 years) is 100 Bq / kg. When the sensitivity of the first radiation detector 7 and the second radiation detector 8 in the first energy window EW1 is assumed to be 10%, that is, cesium 134 and cesium 137 are each 10 CPS (total 20 CPS). The conversion coefficient of cesium 134 is 10 (Bq / kg / CPS), the conversion coefficient of cesium 137 is 10 (Bq / ko / CPS), and the total conversion coefficient is 20 (Bq / kg / CPS). .

  About 2.7 years have passed since then, around July 2014, the mixed standard radiation source is attenuated, cesium 134 is 50 Bq / kg, and cesium 137 is 94 Bq / kg. If attenuation correction is not performed in this case, cesium 134 is handled as 100 Bq / kg, and only 5 CPS is counted, so the conversion coefficient of cesium 134 is 20 (Bq / kg / CPS). In this case, by performing attenuation correction, cesium 134 is handled as 50 Bq / kg, and the conversion coefficient of cesium 134 is corrected to a correct value of 10 (Bq / kg / CPS). Such a condition is the same as in the case of cesium 137.

  Parameters necessary for correctly performing this attenuation correction are nuclides (cesium 134 and cesium 137 in the above-described embodiment), mixing ratio, half-life for each nuclide (2.7 years and 30 years), and sensitivity for each nuclide. (10% in the above example). These are stored in advance in the storage area of the control unit 100.

  Next, an operation when the radioactivity test is executed by the radioactivity test apparatus based on the above-described premise will be described. FIG. 5 is a flowchart of the radioactivity inspection method according to the present invention.

  Before performing the radioactivity inspection, as a preparation process, a first correction coefficient storage process (step S1), a standard radiation source measurement process (step S2), and an attenuation correction process (step S3) are executed.

  In the first correction coefficient storage step (step S1), as described above, the mixing ratio of cesium 134 and cesium 137 and the rice bag R are detected by the first radiation detector 7 and the second radiation detector 8. The relationship between the detection values of the first radiation detector 7 and the second radiation detector 8 is experimentally obtained in advance. Then, the first correction coefficient storage unit 101 shown in FIG. 3 corresponds to the mixing ratio of cesium 134 and cesium 137, and at that time, what value should be used as the first correction coefficient and the first The relationship with one correction coefficient is stored as a table.

  In the standard source measurement process (step S2), a mixed standard source of cesium 134 and cesium 137, a single standard source of cesium 134, and a single standard source of cesium 137 The detection value of the radiation when measured by the radiation detector 7 and the second radiation detector 8 is measured.

  Further, in the attenuation correction step (step S3), attenuation correction is performed for the mixed standard radiation source of cesium 134 and cesium 137, the single standard radiation source of cesium 134, and the single standard radiation source of cesium 137. In this case, the correction is executed in consideration of the date and time serving as the reference for each standard radiation source and the above-described parameters.

  If the above preparation process is completed, it will wait for the start of a radioactivity test | inspection (step S4). When the radioactivity inspection is started, the operator places the rice bag R on the conveyor 4 and conveys the rice bag R by the conveyor 4, so that the rice bag R is transferred to the first radiation detector 7 and the second radiation. Measurement is performed by the detector 8 (step S5). And based on the measurement result in a standard radiation source measurement process, and the measurement result of the rice bag R, the 2nd correction coefficient calculation part 103 shown in FIG. 3 calculates a 2nd correction coefficient (step S6), and mixing ratio The mixture ratio is calculated by the calculation unit 102 (step S7). Thereafter, the first correction coefficient specifying unit 104 specifies the first correction coefficient corresponding to the mixture ratio from the data stored as a table in the first correction coefficient storage unit 101 based on the calculated mixture ratio (step). S8).

  Next, the first radiation detector 7 and the second radiation detection are performed on the measurement result in the first energy window EW1 in which the rice bag R is measured by the first radiation detector 7 and the second radiation detector 8 by the comparison unit 105. Multiplying the count rate (CPS), which is a detected value by the detector 8, by a conversion coefficient for converting to a reference value (Bq / kg), multiplying this by a first correction coefficient and a second correction coefficient, and comparing The multiplication result is compared with the reference value by the unit 105 (step S9). Then, the relationship between the calculation result and the reference value is determined by the determination unit 106 (step S10). If the detected value of radiation is equal to or less than the reference value, a message to that effect is displayed on the display unit 9 to detect the radiation. When the value exceeds the reference value, a warning sound and the like are generated along with a display to that effect on the display unit 9.

DESCRIPTION OF SYMBOLS 1 Apparatus main body 2 Carry-in port 3 Carry-out port 4 Conveyor 5 1st radiation shielding member 6 2nd radiation shielding member 7 1st radiation detector 8 2nd radiation detector 9 Display part 11 Frame 100 Control part 101 1st correction coefficient memory | storage part DESCRIPTION OF SYMBOLS 102 Mixing ratio calculating part 103 2nd correction coefficient calculating part 104 1st correction coefficient specific | specification part 105 Comparison part 106 Judgment part EW1 1st energy window EW2 2nd energy window R Rice bag

Claims (5)

A value obtained by detecting radiation from cesium 134 and cesium 137 emitted from the subject by a radiation detector, and a conversion coefficient for converting the value detected by the radiation detector into radioactivity per unit weight of cesium In the radioactivity test method of multiplying
Radiation detection value when a mixed standard source of cesium 134 and cesium 137 is detected by the radiation detector, and radiation detection value when a single standard source of cesium 134 is detected by the radiation detector A standard source measurement step of measuring a detected value of radiation when a single standard source of cesium 137 is detected by the radiation detector;
An object measurement step of measuring a detected value of radiation when the object is detected by the radiation detector;
A mixing ratio for calculating a mixing ratio of cesium 134 and cesium 137 in the subject based on the detected value of radiation measured in the standard radiation source measuring step and the detected value of radiation measured in the subject measuring step A calculation process;
The detection value of the radiation by the radiation detector specified based on the mixture ratio of cesium 134 and cesium 137 in the subject with respect to the multiplication result of the detection value measured in the subject measurement step and the conversion coefficient The first correction coefficient, which is a coefficient for correcting the mixing ratio according to the mixing ratio, the detected value of the radiation when the mixed standard radiation source of cesium 134 and cesium 137 is detected by the radiation detector, and the subject Is a coefficient for correcting the radiation detection value by the radiation detector calculated based on the radiation detection value when the radiation detector is detected by the radiation detector according to the sensitivity of the radiation detector. A comparison step of multiplying a coefficient and comparing the multiplication result with a reference value;
A radioactivity inspection method characterized by comprising: A value obtained by detecting radiation from cesium 134 and cesium 137 emitted from the subject by a radiation detector, and a conversion coefficient for converting the value detected by the radiation detector into radioactivity per unit weight of cesium In the radioactivity test method of multiplying
A mixing ratio of cesium 134 and cesium 137 and a coefficient for correcting a radiation detection value by the radiation detector in accordance with the mixing ratio when the subject is detected by the radiation detector. A first correction coefficient storing step for storing a relationship with one correction coefficient;
A first energy window EW1 including a first peak value of gamma rays from cesium 134 and a peak value of gamma rays from cesium 137 when a mixed standard source of cesium 134 and cesium 137 is detected by the radiation detector; The detected value of the radiation in the second energy window EW2 including the second peak value of the gamma ray from the cesium 134, the first energy window EW1 when the single standard source of the cesium 134 is detected by the radiation detector, and the Standard radiation source measurement step of measuring a detected value of radiation in the second energy window EW2 and a detected value of radiation in the first energy window EW1 when a single standard radiation source of cesium 137 is detected by the radiation detector. When,
An object measurement step of measuring a detected value of radiation in the first energy window EW1 and the second energy window EW2 when the object is detected by the radiation detector;
The detected value of the radiation in the first energy window EW1 when the mixed standard radiation source of cesium 134 and cesium 137 obtained in the standard radiation source measurement step is detected by the radiation detector, and obtained in the subject measurement step. Based on the detected value of the radiation in the first energy window EW1 when the subject is detected by the radiation detector, the detected value of the radiation by the radiation detector corresponds to the sensitivity of the radiation detector. A second correction coefficient calculation step of calculating a second correction coefficient that is a coefficient for correction;
A mixing ratio for calculating a mixing ratio of cesium 134 and cesium 137 in the subject based on the detected value of radiation measured in the standard radiation source measuring step and the detected value of radiation measured in the subject measuring step A calculation process;
Relationship between the mixing ratio of cesium 134 and cesium 137 in the subject obtained in the mixing ratio calculation step, the mixing ratio of cesium 134 and cesium 137 stored in the first correction coefficient storage step, and the first correction coefficient A first correction coefficient specifying step for specifying a first correction coefficient;
A first correction coefficient obtained in the first correction coefficient specifying step with respect to a multiplication result of the detected value of radiation in the first energy window EW1 measured in the subject measurement step and the conversion coefficient, and the first correction coefficient A comparison step of multiplying the second correction coefficient obtained in the two correction coefficient calculation step and comparing the multiplication result with a reference value;
A radioactivity inspection method characterized by comprising: In the radioactivity inspection method according to claim 2,
The radioactivity inspection method, wherein the first energy window EW1 is a region including 605 keV and 662 keV as gamma-ray energy, and the second energy window EW2 is a region including 796 keV as gamma-ray energy. In the radioactivity inspection method according to claim 2 or claim 3,
Based on the time point when the first correction coefficient stored in the first correction coefficient storage step is specified, the mixed standard source of cesium 134 and cesium 137, the single standard source of cesium 134, and the single standard source of cesium 137 Radioactivity inspection method to compensate for attenuation of one standard source. A value obtained by detecting radiation from cesium 134 and cesium 137 emitted from the subject by a radiation detector, and a conversion coefficient for converting the value detected by the radiation detector into radioactivity per unit weight of cesium In a radioactivity test apparatus that multiplies and compares the multiplication result with a reference value,
A mixing ratio of cesium 134 and cesium 137 and a coefficient for correcting a radiation detection value by the radiation detector in accordance with the mixing ratio when the subject is detected by the radiation detector. A first correction coefficient storage unit that stores a relationship with one correction coefficient;
The radiation detection value when a single standard radiation source of cesium 134 is detected by the radiation detector, the radiation detection value when a single standard radiation source of cesium 137 is detected by the radiation detector, A mixing ratio calculation unit that calculates a mixing ratio of cesium 134 and cesium 137 in the subject based on a detection value of radiation when the specimen is detected by the radiation detector;
Based on the detection value of the radiation when the mixed standard radiation source of cesium 134 and cesium 137 is detected by the radiation detector and the detection value of the radiation when the subject is detected by the radiation detector, A second correction coefficient calculation unit that calculates a second correction coefficient that is a coefficient for correcting the detection value of the radioactivity by the radiation detector in accordance with the sensitivity of the radiation detector;
From the mixing ratio of cesium 134 and cesium 137 calculated by the mixing ratio calculation unit, and the relationship between the mixing ratio of cesium 134 and cesium 137 stored in the first correction coefficient storage unit and the first correction coefficient, A first correction coefficient specifying unit for specifying one correction coefficient;
The first correction coefficient obtained by the first correction coefficient specifying unit and the second correction coefficient for the multiplication result of the detection value of the radiation when the subject is detected by the radiation detector and the conversion coefficient A comparison unit that multiplies the second correction coefficient obtained by the calculation unit and compares the multiplication result with a reference value;
A radioactivity inspection apparatus comprising:

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