JP7121648B2 - Radioactive waste level estimation method - Google Patents

Description

The present invention relates to a radioactive waste level estimation method.

Conventionally, in nuclear power plants and accelerator facilities, neutrons generated during operation undergo nuclear reactions with various elements in the surroundings, so that various parts within the facilities are activated. Concrete used as a radiation shield is discharged as radioactive waste when the facility is dismantled. Radioactive waste is divided into clearance levels, L3, L2, and L1, in descending order of radioactivity level. Radioactive waste from demolition of the facility will be disposed of separately by level. For example, clearance level radioactive waste can be reused as general material.

Radioactive waste levels are analyzed by core-boring concrete in several places in the facility, slicing and crushing each core, measuring the amount of activation by radioactivity measurement, and obtaining the depth distribution of radioactivity. (See Patent Document 1, for example). Since concrete contains various elements, various radionuclides are generated. Radioactive waste is divided into each level by multiplying the value obtained by dividing the radioactivity concentration of each nuclide obtained by the measurement by the coefficient. However, since this measurement method only knows the distribution around the core boring, it is necessary to comprehensively judge the radioactive waste level (clearance ~ L1) by comparing the distribution of activation by computer simulation and the distribution by actual measurement. become.

JP 2018-141669 A

However, the above-mentioned conventional analysis method requires time for preparation and measurement of the measurement sample, and requires complicated analysis for determining the level of radioactive waste. In addition, there was a problem that the level of radioactive waste could not be grasped on site. For this reason, there has been a demand for a technique that can easily estimate the level of radioactive waste.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method for estimating the level of radioactive waste, which is capable of easily estimating the level of radioactive waste.

In order to solve the above problems and achieve the object, a method for estimating the level of radioactive waste according to the present invention is a method for estimating the level of radioactivity in radioactive waste, comprising: A step of detecting radiation emitted from a radiation detector with a radiation detector, a step of measuring the radioactivity concentration of each radionuclide in the sample at the reference position with a radioactivity measuring instrument, and A step of obtaining an integrated value of the radioactivity concentration and the ratio of the radioactivity concentration for each radionuclide measured from the sample at the reference position, and counting radiation when the integrated value obtained for each radioactivity level reaches a predetermined value. calculating the radiation rate based on the counting rate of radiation emitted from a reference position; A step of detecting with a detector, comparing the count rate of radiation detected from the arbitrary position and the count rate of radiation when the integrated value obtained for each radioactivity level becomes a predetermined value. and estimating the radioactivity level of the radioactive waste.

Further, another method for estimating the level of radioactive waste according to the present invention is characterized by using a Geiger-Muller radiation detector as the radiation detector in the above invention.

Further, another method for estimating the level of radioactive waste according to the present invention is characterized in that the radioactive waste is activated concrete in the invention described above.

According to the method for estimating the level of radioactive waste according to the present invention, the method for estimating the radioactivity level of radioactive waste includes detecting radiation emitted from a reference position set in the radioactive waste with a radiation detector. a step of measuring the radioactivity concentration of each radionuclide in the sample at the reference position with a radioactivity measuring instrument; the radioactivity concentration of each radionuclide set for each radioactivity level; a step of obtaining an integrated value of ratios of radioactivity concentrations for each radionuclide; Detecting radiation emitted from an arbitrary position in the radioactive waste or an arbitrary position around the place where the radioactive waste was collected with a radiation detector; A step of estimating the radioactivity level of the radioactive waste by comparing the radiation count rate detected from the radioactivity level with the radiation count rate when the integrated value obtained for each radioactivity level becomes a predetermined value , it is possible to roughly classify the level of radioactive waste using a simple radiation detector simply by measuring the radiation and radioactivity concentration at one reference position. Therefore, there is an effect that the level of radioactive waste can be easily estimated.

Further, according to another method for estimating the level of radioactive waste according to the present invention, a Geiger-Muller radiation detector is used as the radiation detector, so the level of radioactive waste is estimated using a simple radiation detector. It has the effect of being able to

In addition, according to another method for estimating the level of radioactive waste according to the present invention, since the radioactive waste is activated concrete, it is possible to easily and quickly classify the activated concrete discharged at the time of demolition of radiation utilization facilities. There is an effect that it can be performed in

FIG. 1 is a schematic flow chart showing an embodiment of a radioactive waste level estimation method according to the present invention. FIG. 2 is a diagram showing an example of calculated values of depth distribution of nuclides generated in biological shielding concrete of a light water reactor. FIG. 3 is a diagram showing an example of depth distribution calculation values of radioactivity ratios with ⁶⁰ Co of nuclides generated in living body shielding concrete of a light water reactor.

An embodiment of the method for estimating the level of radioactive waste according to the present invention will be described in detail below with reference to the drawings. In addition, this invention is not limited by this embodiment.

In the present embodiment, the radioactivity level of activated concrete walls discharged as radioactive waste at the time of demolition of radiation utilization facilities such as nuclear power plants and accelerator facilities and boring cores collected from them can be quickly and easily measured. is a method of estimating This embodiment can immediately estimate the level of radioactive waste by simple measurement. A GM survey meter (radiation detector) is mainly used for the measurement, and the level of radioactive waste is classified based on a certain counting rate.

The sensitivity of GM survey meters varies depending on the nuclide. In addition, the coefficients used for calculating the radioactive waste level also have various values depending on the nuclide. Therefore, it is difficult to apply the present invention when the ratios of multiple nuclides present in the activation material are greatly different. Figures 2 and 3 show an example of calculated values of the depth distribution of the radioactivity of nuclides generated in the bioshielding concrete of a light water reactor and the depth distribution of the radioactivity ratio of ⁶⁰ Co. As shown in these figures, the radioactivity ratio to ⁶⁰ Co varies somewhat depending on the depth, but it is understood that it does not greatly affect the level estimation of the present invention.

As described above, it has been shown that nuclides are generated at a certain rate in the concrete shield of a nuclear reactor facility. Estimate the level.

(Step S1)
First, non-activated concrete is measured with a GM survey meter to obtain a background.

(Step S2)
Next, in the concrete core sampled by boring, radiation emitted from one location (reference position) where the radiation is relatively strong is measured (detected) by a GM survey meter (radiation detector). The reason for selecting a location with strong radiation is that the larger the measured value, the smaller the counting error.

(Step S3)
After the measurement, slice and pulverize the measured place to prepare a sample, and measure the radioactivity concentration of this sample with a radioactivity measuring instrument. A well-known radioactivity measuring instrument can be used. The relationship between the radioactivity concentration value of each radionuclide obtained by this radioactivity measurement and the count rate of the GM survey meter serves as a reference for estimating the activation (radioactivity) level.

(Step S4)
Next, a GM survey meter is used to measure the radiation of concrete at an arbitrary location on the concrete core or at an arbitrary location within the facility where the concrete core was collected.

Based on the above measurement data, the level of radioactive waste is estimated by the following method. The count rate and radioactivity concentration used here are represented by the following symbols.

Background count rate of GM survey meter measured in step S1 above: _CBKG
GM survey meter count rate measured in step S2 above: C _STD
Radioactivity concentration (Bq/g) of each nuclide (nuclide name: ₁ , ₂ , ₃ ...) measured in step S3 above: A1, A2, A3...
GM survey meter count rates of arbitrary locations (location names: a, b, c, . . . ) measured in step S4 above: C _a , C _b , C _c .
Radioactivity concentration (Bq/g) of each nuclide (nuclide name: 1, 2, 3...) at each radioactive waste level: A1 _-level , A2 _-level , A3 _-level ...

The ^{radioactivity concentrations} corresponding to A _1-level , ^A _2-level , A _3-level . .1 Bq/g, ¹⁵² Eu is defined as 0.1 Bq/g.

Next, a method for estimating the radioactive waste level will be described.

(Step S5)
First, the radioactivity concentration (Bq/g) of each nuclide (nuclide name: 1, 2, 3 ...) at each radioactive waste level, and each nuclide measured in step S3 above (nuclide name: 1, 2 , 3...), the integrated value M of the radioactivity concentration (Bq/g) ratio is calculated by the following equation (1).

M = A1 _/ A1 _-level + _A2 /A2 _-level + A3/A3 _{- level} + (1)

If M≤1.0, the level is radioactive waste. For example, if ⁴¹ Ca is 10 Bq/g, ⁶⁰ Co is 0.01 Bq/g, ¹³⁴ Cs is 0.01 Bq/g, and ¹⁵² Eu is 0.01 Bq/g, the clearance level is M=0.4, Although it can be discarded as a clearance product, if it is contained 10 times this amount, M=4 and cannot be discarded as a clearance product.

(Step S6)
Next, the counting rate CM of the GM survey meter when the integrated value _M obtained at each level becomes a predetermined value is calculated as shown in the following equation (2) using the counting rate C _STD measured in step S2 above. Define.

C _M = (C _STD - C _BKG )/M (2)

Assuming that _M =1 in the above equation (2), the counting rate CM=1 of the GM survey meter is calculated by the following equation (3). As for the value of M, instead of setting M=1, a value other than this value may be employed in calculation in consideration of the safety factor.

C _{M = 1} = (C _STD - C _BKG )/M (3)

(Step S7)
Next, a count rate is obtained by subtracting the background count rate _CBKG from the count rate (C _a , C _b , C _c . . . ) at an arbitrary location. The calculated count rate is compared with CM ₌₁ at each level. As a result, if the calculated count rate is less than CM ₌₁ at each level, then the radioactive waste is discardable at that level. Also, this level is estimated as the radioactivity level of concrete at any location.

In this way, it is possible to roughly classify the levels of radioactive waste using a simple radiation detector by simply measuring the radiation and radioactivity concentration at one reference position. Therefore, it is possible to easily estimate the level of radioactive waste. It also allows estimation of the level of radioactive waste at the site.

As described above, according to the method for estimating the level of radioactive waste according to the present invention, the method for estimating the level of radioactivity in radioactive waste comprises: A step of detecting with a radiation detector, a step of measuring the radioactivity concentration of each radionuclide in a sample at a reference position with a radioactivity measuring device, a radioactivity concentration of each radionuclide set for each radioactivity level, and a reference A step of obtaining an integrated value of the radioactivity concentration ratio for each radionuclide measured from the sample at the position; A step of determining based on the counting rate of emitted radiation, and a step of detecting radiation emitted from an arbitrary position in the radioactive waste or an arbitrary position around the place where the radioactive waste was collected with a radiation detector. Then, by comparing the radiation count rate detected from the arbitrary position and the radiation count rate when the integrated value obtained for each radioactivity level becomes a predetermined value, the radiation of radioactive waste Since the step of estimating the activity level is provided, it is possible to roughly classify the level of radioactive waste using a simple radiation detector just by measuring the radiation and radioactivity concentration at one place of the reference position. . Therefore, it is possible to easily estimate the level of radioactive waste.

Further, according to another method for estimating the level of radioactive waste according to the present invention, a Geiger-Muller radiation detector is used as the radiation detector, so the level of radioactive waste is estimated using a simple radiation detector. can do.

In addition, according to another method for estimating the level of radioactive waste according to the present invention, since the radioactive waste is activated concrete, it is possible to easily and quickly classify the activated concrete discharged at the time of demolition of radiation utilization facilities. can be done.

As described above, the method for estimating the level of radioactive waste according to the present invention estimates the level of radioactive waste such as activated concrete discharged when dismantling a radiation utilization facility such as a nuclear power plant or an accelerator facility. and is particularly suitable for easily estimating levels.

Claims (3)

A method for estimating the radioactivity level of radioactive waste, comprising:
A step of detecting radiation emitted from a reference position set in the radioactive waste with a radiation detector;
measuring the radioactivity concentration of each radionuclide in the sample at the reference position with a radioactivity meter;
obtaining an integrated value of the ratio of the radioactivity concentration for each radionuclide set for each radioactivity level and the radioactivity concentration for each radionuclide measured from the sample at the reference position;
determining the radiation count rate when the integrated value determined for each radioactivity level becomes a predetermined value based on the radiation count rate emitted from the reference position;
Detecting with a radiation detector radiation emitted from any position in the radioactive waste or from any position around the place where the radioactive waste was collected;
Radioactivity level of radioactive waste by comparing the radiation count rate detected from the arbitrary position and the radiation count rate when the integrated value obtained for each radioactivity level reaches a predetermined value A method for estimating the level of radioactive waste, comprising the step of estimating 2. The method for estimating the level of radioactive waste according to claim 1, wherein a Geiger-Muller type radiation detector is used as the radiation detector. 3. The method for estimating the level of radioactive waste according to claim 1, wherein the radioactive waste is activated concrete.

Images