KR101380769B1 - The calibration method for interference correction of characterizing the key nuclide on tomographic gamma scanner - Google Patents

Abstract

The present invention relates to an interference removing method of interference nuclide for quantitative analysis of standard nuclide in radioactive waste drum TGS analysis and, more specifically, an interference removing method of interference nuclide for a quantitative analysis of standard nuclide in radioactive waste drum TGS analysis, capable of maximizing accuracy on the quantitative analysis of the standard nuclide in a radioactive waste drum. The present invention includes a first step of calculating the difference between gamma-ray energy (EK) of the standard nuclide and gamma-ray energy (EI) of the interference nuclide; a second step of calculating optimal energy range factor (F(EK)); and a third step of setting final energy (EKPE) of the standard nuclide as a value in which the gamma-ray energy (EK) of the standard nuclide is added to a value in which half amplitude (FWHM(EK)) of a detector on the standard nuclide and the optimal energy range factor are multiplied. [Reference numerals] (AA) Start; (BB) End; (S102) Form a primer layer; (S104) Arrange an insulation plate; (S106) Form an insulation waterproof mortar layer; (S108) Form a waterproof mortar layer; (S110) Form a protective mortar layer; (S112) Attach a pattern sheet; (S114) Apply a pigment; (S116) Remove the pattern sheet; (S118) Forming a coating layer

Description

The calibration method for interference correction of characterizing the Key Nuclide on Tomographic Gamma Scanner for radionuclide quantitative analysis of drum TGS analysis

The present invention relates to a method for eliminating interference of interference nuclei for quantitative analysis of reference nuclides in radioactive waste drum TGS analysis, and more particularly, even if an interference nucleus is present in a radioactive waste drum, The present invention relates to a method for removing interference phenomena of interfering nuclides for quantitative analysis of reference nuclei in radioactive drum TGS analysis, which enables accurate quantitative evaluation of reference nuclides without interference.

In general, radioactive waste is an unnecessary radioactive material generated in the process of using nuclear energy in a nuclear power plant and the like, and wastes, nuclear fission products, cooling water, cooling gas, etc., generated from a nuclear power plant or a workshop or laboratory dealing with radioactive materials. Leaks;

Since the radioactivity generated from these radioactive wastes is not destroyed by chemical changes, we have no choice but to wait for them to disappear naturally due to the collapse of the nuclear nucleus, which is why modern methods of treating and storing radioactive wastes are safe and permanent. It is a big challenge for society.

In order to solve this problem, most countries are currently adopting a method of storing and sealing radioactive waste in a predetermined processing container and burying it deep in the ground.

In other words, for safer management of radioactive waste, solid waste is compressed to ultra high pressure and placed in steel drums. Liquid wastes are evaporated to reduce volume, and then solidified with cement, sealed in drums, and stored in storage. After storage in a closed tank, if the radioactivity falls below the standard, it is filtered through a high performance filter (HEPA filter) and released into the atmosphere.

On the other hand, the radioactivity of the drum storing radioactive waste is classified into low and high level radioactive waste according to the amount of its inclusion, and the radioactivity of the radioactive waste present in the drum must be accurately evaluated in order to bring it into the disposal facility.

A drum nuclide analyzer is provided to evaluate the radioactivity of the radioactive waste. The drum nuclide analyzer is a non-destructive method for radioactive waste present in the drum to permanently dispose of radioactive waste generated at a nuclear power plant. It is the equipment to analyze.

The measurement results of the drum nuclide analysis device are the basic data to confirm that the total radioactivity of the drum to be permanently disposed does not exceed the storage limit of the disposal facility, and therefore high accuracy is required.

On the other hand, the method of measuring the radioactivity of the drum through the drum nuclide analysis device (hereinafter referred to as 'detector') is provided by SGS analysis and TGS analysis.

1 is a graph illustrating a general gamma ray spectroscopy, in which the radioactivity of a gamma nuclide is the total area (G) from the total area (G) for the range of the start and end of the peak energy of the nuclide. It is calculated through (S).

SGS analysis measures the average radiation density and average radiation concentration for each disc divided into eight equally divided 200 liter drums in the height direction, and compensates for the average radiation concentration by the attenuation of the measured average radiation density. TGS analysis divides the 200-liter drum into 16 equally in the height direction, while one disc is equally divided into 10 horizontally and 10 vertically, and measured in a total of 1,600 divisional units (VOxel). By measuring the radiation density and the radiation concentration for Voxel, respectively, the density compensation and the distance compensation for each location of the radiation source are performed, which is more accurate than the conventional SGS analysis.

The reason for equally dividing the drum as described above is that current detector production techniques cannot produce a large detector corresponding to the entire area of the radioactive waste drum (200 liters).

As a result, the radioactive waste drum is necessarily divided and measured, and then a technique of summing the respective measurement results is adopted.

In addition, TGS analysis is a radioactive waste tomography analysis technique using non-destructive high resolution gamma-ray spectroscopy installed on the radioactive waste detector.The density compensation for each position of the heterogeneous medium in the drum, which is the limitation of the existing SGS analysis, and the distance compensation according to the position of the radiation source The technology overcomes the limitations.

Accordingly, the TGS analysis is a technique that more than doubled the measurement range and accuracy of the radioactive density in the drum.

 However, since the TGS analysis measures one drum by 200 times more Voxel than the SGS analysis, the analysis time per division unit is reduced by 1/200 times.

Accordingly, in the statistical measurement method of evaluating the radioactivity of the radioactive waste drum by counting the radiation incident to the detector within the analysis time, a decrease in the analysis time causes a decrease in the radiation coefficient, and a decrease in the coefficient results in poor precision of the radioactivity measurement. At the same time, there is a disadvantage that the minimum detectable activity (Minimum Detectable Activity) that the detector can measure increases.

To overcome this drawback, TGS analysis uses three times the spectral energy range (FWHM; multiplier of Full Width at Half Maximum) to evaluate the nuclides in one to maximize the coefficient, as shown in FIG. The analysis has been set to a wider range, and the use thereof is limited, such as measuring only a target to be measured having a high radioactive concentration such as a radioactive waste drum.

On the other hand, Korea has recently completed the permanent disposal of radioactive waste drums, and in order to establish the suitability standards for disposal of radioactive waste drums, the results of the generator inspection on 1536 drums requested by the nuclear power plant in 2011 and the acceptance test results on the same drums ( Total inspection 1536 Drum sample inspection 97 Drum, Characteristic evaluation basic data 63 Drums).

In this process, when radioactive waste drums containing Ag-110m nuclides were analyzed by TGS analysis, the radioactivity concentration of Cs-137 (Cs-137, 661.57 keV half-life 30.17 years) as the reference for fissile nuclides was shown in FIG. As shown in Fig. 2, Ag-110m (Ag-110m 657.74 keV half-life 249.85 days) was interfered with the radionuclide to confirm that the radioactive concentration of the reference nucleus was incorrectly evaluated.

In other words, in the case of the generator test measured immediately after the production of the radioactive waste drum, the concentration of Ag-110m, which is an interfering nuclide, is high, so that the measured concentration of Ag-110m interferes with the measured concentration of Cs-137, which is a reference nucleus. While the measurement concentration was highly evaluated, the acceptance test conducted about three years later (the time when the concentration of Ag-110m was naturally reduced to 1 in 20 minutes) resulted in the natural attenuation of Ag-110m, which is the reference nucleus, and the reference nucleus Cs-. 137 Since the measured concentration was measured correctly, it was confirmed that there was a difference between the generator test and the acceptance test.

Therefore, a calibration technique is required to prevent interference of interfering nuclides with such reference nuclei, and an optimization calibration technique is required in which the reference nucleus concentration is accurately assessed and the minimum detection limit (MDA) of the reference nucleus is maintained in the generator test. It would have been.

Republic of Korea Patent Registration 10-0979559 Republic of Korea Patent Registration 10-1229562

The present invention has been made to solve the above problems, an object of the present invention is to cover the spectral range of the reference nuclide even if the interference nucleus (Ag-100m) is present in the radioactive waste drum during radioactivity analysis of the radioactive waste drum using TGS analysis Elimination of interfering nuclides for radionuclide quantitative analysis of radioactive waste drum TGS analysis to optimize quantitative evaluation of reference nucleus (Cs-137) without interference with interfering nuclei by optimizing and removing interfering nuclides. It was intended to provide a way.

In order to achieve the above object, the present invention measures the gamma-ray energy (E _K ) of a reference nucleus and the gamma-ray energy (E _I ) of an interfering nucleus to determine the gamma-ray energy (E _K ) of the reference nuclide and gamma-ray energy (E _K ) of the interfering nuclide. _I ) calculating a difference; the difference between the gamma-ray energy (E _K ) of the reference nuclide and the gamma-ray energy (E _I ) of the interfering nucleus (差) of the detector against the reference nucleus gamma-ray energy (E _K ). ) twice divided optimum energy range that is calculated by the half-width scale factor (F (E _K), a second step of calculating a) of; the optimal energy range factor (F (E _K)) If the calculated value is 1 or more than 3 standard The starting energy (E _KPS ) of a nuclide is set as the reference nucleus gamma-ray energy (E _K ) minus the product of the detector's full width at half maximum (FWHM (E _K )) and the optimal energy range factor (F (E _K )) for the reference nuclide. and, the end of energy (E _KPE) of the reference is a reference nuclide nuclides in the reference radionuclide gamma ray energy (E _K) Of the detector the full width at half maximum (FWHM (E _K)) and the optimal energy range factor (F (E _K)) product of a third step of setting a sum of the value of: including in for reference radionuclide quantification of radioactive waste drum TGS analysis consisting of the Provides a method of removing interference from interfering nuclides.

At this time, in the third step, if the calculated value of the optimal energy range factor (F (E _K )) is 1 or more and 3 or less, the starting energy (E _IPS ) of the interfering nuclide is changed from the interfering nucleus gamma-ray energy (E _I ) to the interfering nuclide. Is set by subtracting the product of the detector's half width (FWHM ((E _I )) and the optimal energy range factor (F (E _K )), and the end energy (E _IPE ) of the interfering nuclide gamma-ray energy (E _I ) Is preferably set to the sum of the product of the full width at half maximum (FWHM (E _I )) and the optimal energy range factor (F (E _K )) of the detector for the interfering nuclide.

Further, in the third step, when the calculated value of the optimal energy range factor (F (E _K )) is less than 1, and the gamma-ray energy (E _I ) of the interfering nuclide is emitted more than two,

는 간섭핵종의 방사선 계수가 제외된 기준핵종 감마선 에너지(

)의 순면적이며,

은 간섭핵종의 방사선 계수가 포함된 기준핵종 감마선 에너지(

)의 면적,

는 간섭핵종의 타 감마선 에너지에 의해 측정된 간섭핵종의 방사능,

는 단위붕괴 당 간섭핵종 감마선 에너지 (

) 방출확률,

는 간섭핵종 감마선 에너지(

)에 대한 검출기의 검출 효율)을 만족하는 것이 바람직하다.(

Is the reference nuclear gamma-ray energy excluding the radiation coefficient of the interfering nuclide (

) Net area,

Is the reference nuclear gamma-ray energy containing the radiation coefficient of the interfering nuclide (

),

Is the radioactivity of the interfering radionuclide measured by the other gamma ray energy of the interfering nuclide,

Is the internuclear gamma-ray energy per unit collapse (

) Emission probability,

Is interfering gamma-ray energy (

It is desirable to satisfy the detection efficiency of the detector with respect to the "

In addition, in the third step, when the calculated value of the optimal energy range factor (F (E _K )) is less than 1, the radioactivity measurement value in the radioactive waste drum is preferably calculated as the sum of the reference nuclide and the interfering nuclide.

The method of eliminating interference of interference nuclei for quantitative analysis of reference nuclei in radioactive drum TGS analysis according to the present invention has the following effects.

By providing a method of optimizing the spectral energy range (magnification of the full width at half maximum (FWHM)) of the reference nucleus gamma-ray energy such that the gamma-ray spectral energy of the reference nucleus and the gamma-ray spectral energy of the interfering nucleus do not overlap, the reference nuclide radioactivity concentration of the radioactive waste drum This has the effect of increasing the accuracy of the value.

Accordingly, it is possible to increase the reliability of the quantitative analysis on the reference nuclide of the radioactive waste drum, thereby maintaining a higher storage efficiency of the radioactive waste permanent repository and reducing the unnecessary management cost by safely evaluating the stock of the nuclide.

1 is a graph showing the characteristics of the radioactivity of gamma nuclide
2 is a graph showing that the range of spectral energy is uniformly three times the half width in applying the radioactivity measurement of the radioactive waste drum according to the prior art by TGS analysis.
Figure 3 is a graph showing the overlapping reference nuclide and interfering nuclide when the spectrum of the spectral energy is three times in applying the radioactivity measurement of the radioactive waste drum according to the prior art by TGS analysis
Figure 4 is a flow chart showing a method of removing interference phenomena of interference nuclei for the reference nuclide quantitative analysis of radioactive waste drum TGS analysis according to a preferred embodiment of the present invention
Figure 5 shows that the reference nuclide and the interference nucleus do not overlap by optimizing the range of spectral energy using the interference phenomena removal method for the reference nuclide quantitative analysis of the radioactive waste drum TGS analysis according to a preferred embodiment of the present invention graph
FIG. 6 shows other gamma-ray energy of interfering nuclides when the range of spectral energy cannot be avoided even when the interference phenomenon of the interfering nucleus for quantitative analysis of the reference nucleus of the radioactive waste drum TGS analysis according to the preferred embodiment of the present invention is not avoided. Graph for measuring the radioactivity concentration of the reference nuclide using
Figure 7 is a chart comparing the radioactivity analysis accuracy of the radioactive waste drum by the method of eliminating interference of the radionuclide for the reference nuclide quantitative analysis of the radioactive waste drum TGS analysis according to a preferred embodiment of the present invention.

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, with reference to the accompanying Figures 4 to 7 of the radionuclide interference removal method of the radionuclide for the reference nuclear quantitative analysis of the radioactive waste drum TGS analysis according to a preferred embodiment of the present invention (hereinafter, referred to as 'interference removal method' ).

In the method of eliminating interference, radio frequency analysis of radioactive waste drums prevents the overlapping of the count values for the internuclear gamma-ray energy detected by the detector due to interference with the multiplier for the reference-nuclear gamma-ray energy. There are technical features that increase the accuracy of quantitative analysis of nuclides.

To this end, by optimizing the range of spectral energy of the reference nucleus, the reference nucleus and the interfering nucleus are separated to increase the numerical accuracy of the reference radioactivity.

Hereinafter, a method of eliminating interference will be sequentially described with reference to FIG. 4.

First, the drums sealed with radioactive waste are virtually divided into 16 equal parts in the height direction to make 16 discs, and each disc is divided equally into 10 horizontally and 10 vertically.

Subsequently, the reference nucleus (Cs-137) gamma ray energy (E _K ) and the interfering nuclide (Ag-110m) gamma ray energy (E _I ) incident on the detector are measured using the detector (S100, S200).

Next, the value of the reference nucleus gamma ray energy E _K detected by the detector is compared with the value of the interfering nucleus gamma ray energy E _I (S300).

Subsequently, a step of calculating a difference (구) obtained by subtracting the gamma ray energy (E _I ) of the interfering nuclide from the value of the reference nucleus gamma ray energy (E _K ) is performed through the following equation. (E _{K -} E _I ) (S400)

In this case, when the value of the reference nucleus gamma ray energy (E _K ) is smaller than the value of the interference nucleus gamma ray energy (E _I ), the term of the reference nucleus gamma ray energy (E _K ) in the above formula and the interference nucleus gamma ray energy (E _I ) Calculate the terms of the values by exchanging them. (E _{I -} E _K ) (S500)

This is because the difference between the reference nucleus gamma-ray energy (E _K ) and the interfering nucleus gamma-ray energy (E _I ) must be provided as a positive number.

Next, as shown in the following equation, the half-width (FWHM) of the reference nucleus gamma-ray energy (E _K ) detected by the detector is used to determine the difference between the reference nucleus gamma-ray energy (E _K ) and the interfering nucleus gamma-ray energy (E _I ) calculated in the first step. ; Dividing by 2 times the Full Width at Half Maxium) yields the optimal energy range factor F (E _K ) (S600).

At this time, when the value of the reference nucleus gamma ray energy E _K is smaller than the value of the interference nucleus gamma ray energy E _I , it is preferable to divide it by twice the half width of the interference nucleus energy E _I.

This is because the half width increases in proportion to the half power of the energy, and as the energy increases, the half width increases, so by dividing the difference between the two gamma rays by the high half width, the start energy of the reference nucleus and the end energy of the interfering nuclide (or interference). This is to ensure that the starting energy of the nuclide and the end energy of the reference nucleus are not overlapped and the minimum interval is maintained.

The reason for dividing the difference between the reference nuclide and the interfering nuclide gamma ray energy by doubling the half width is that the nuclide energy generating the fouling width is the reference nucleus and the two interfering nuclides.

Next, when the value of the optimal energy range factor F (E _K ) is calculated through the above formula, it is determined whether the value is 1 or more and 3 or less.

This is because when the interference nucleus is Ag-110m, the interference nucleus of Ag-110m is most generated when the interference range with the reference nucleus gamma-ray energy is 3 or less or 1 or more.

Next, if the value of the optimal energy range factor F (E _K ) of the reference nucleus is 3 or less and 1 or more, in order to eliminate the interference between the reference nucleus and the interfering nuclide, the starting energy of each of the reference nucleus and the interfering nuclide is And the end energy is calculated. (S800)

Where E _KPS is the starting energy of the reference nuclide peak, E _KPE is the end energy of the reference nuclide peak, and E _IPS Is the starting energy of the internuclide peak, E _IPE Is the end energy of the interfering nuclide peak.

As described above, the start energy and end energy values of the reference nucleus and the interfering nucleus are calculated, so that the concentration values in the state where the reference nucleus does not interfere with the interfering nucleus can be calculated.

On the other hand, when the value of the optimal energy range factor F (E _K ) is less than 1, it is difficult to distinguish the interfering nucleus due to the half-width limit of the reference nucleus gamma-ray energy E _K by the detector.

At this time, if two or more radiation energy of the interfering radionuclide is emitted, the amount of radiation derived from the other gamma-ray energy of the interfering nuclide other than the interfering nucleus gamma-ray energy that causes the interference is used to evaluate by subtracting the effect that caused the interference in the reference nuclide evaluation. As a method, it is calculated using the following equation (S900).

는 간섭핵종의 방사선 계수가 제외된 기준핵종 감마선 에너지(

)의 순면적이며,

은 간섭핵종의 방사선 계수가 포함된 기준핵종 감마선 에너지(

)의 면적,

는 간섭핵종의 타 감마선 에너지에 의해 측정된 간섭핵종의 방사능,

는 단위붕괴 당 간섭핵종 감마선 에너지 (

) 방출확률,

는 간섭핵종 감마선 에너지(

)에 대한 검출기의 검출 효율을 의미한다.At this time,

Is the reference nuclear gamma-ray energy excluding the radiation coefficient of the interfering nuclide (

) Net area,

Is the reference nuclear gamma-ray energy containing the radiation coefficient of the interfering nuclide (

),

Is the radioactivity of the interfering radionuclide measured by the other gamma ray energy of the interfering nuclide,

Is the internuclear gamma-ray energy per unit collapse (

) Emission probability,

Is interfering gamma-ray energy (

Means the detection efficiency of the detector.

That is, as shown in FIG. 6, after calculating the net area S (E _K ) of the gamma ray energy of the reference nucleus and the interfering nucleus, the gamma ray energy (E) of the reference nucleus is subtracted by subtracting the net area of the interfering nucleus gamma ray energy E _I. Only the net area of _K ) is calculated, and the net area of the interfering nuclear gamma-ray energy E _I is used to calculate the radioactivity A _I (E _I2 ) of the interfering radionuclide other gamma-ray energy.

As described above, the method of eliminating interference of interference nuclides for quantitative analysis of reference nuclides in radioactive waste drum TGS analysis has technical features to remove interference with interfering nuclides so as to increase the accuracy of quantitative evaluation of reference nuclear gamma ray energy.

To this end, even if there are interfering nuclides in the radioactive waste drum, the spectral range (half-width; FWHM magnification) of the reference nucleus is optimized to eliminate the interference of the interfering nucleus, thus increasing the accuracy of the reference nucleus quantitative evaluation in the generator test. Increased efficiency for waste drum disposal.

As a result of evaluating the reference nuclide in the radioactive waste drum through this method, it can be seen that the accuracy of the reference nucleus calculation is increased as shown in FIG. 7.

In other words, by evaluating the reference nuclide of the radioactive waste drum using SGS analysis, which is a standard analysis method, and measuring the reference nuclide calculated value according to the present invention and the reference nuclide calculated value according to the present invention by measuring the reference nuclide concentration using the present invention The value confirms that the deviation range from the concentration measurement value by the reference analysis method is minimized.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Claims (4)

First measuring the gamma-ray energy (E _K) and gamma ray energy of the interfering radionuclides (E _I) of a reference nuclide to calculate the gamma-ray energy (E _K) and gamma ray energy of the interfering radionuclides (E _I) car (差) of a reference nuclide A half-width multiplier is obtained by dividing the difference between the gamma ray energy (E _K ) of the reference nucleus and the gamma ray energy (E _I ) of the interfering nucleus by twice the half width of the detector (FWHM) with respect to the reference nucleus gamma ray energy (E _K ). optimal energy range factor (F (E _K)) a second step of calculating a calculated as; optimal energy range factor (F (E _K)) If the calculated value is 1 or more than 3 standard start energy (E _KPS) of the nuclides Is set to the reference nucleus gamma-ray energy (E _K ) minus the product of the detector's half-width (FWHM (E _K )) and the optimal energy range factor (F (E _K )) for the reference nucleus, and the end energy ( E _KPE ) is the maximum half width (FWHM (E _K )) of the detector for the reference nucleus at the reference nucleus gamma-ray energy (E _K ). A third step of setting the product of the energy range factor (F (E _K )) plus the value: Method of eliminating interference of interference nuclei for reference species quantitative analysis of the radioactive waste drum TGS analysis. The method of claim 1,
In the third step,
Optimal energy range factor (F (E _K)) calculates a value of 1 or more 3 or less is the interference nuclides start energy (E _IPS) of the half-value width of the detector for the interfering radionuclides at the interface radionuclide gamma ray energy (E _I) (FWHM (( E _I )) minus the product of the optimal energy range factor (F (E _K )), and the end energy (E _IPE ) of the interfering nuclide is the half width of the detector for the interfering nucleus at the interfering gamma-ray energy (E _I ). (FWHM (E _I )) multiplied by the product of the optimal energy range factor (F (E _K )) to set the value of the interference cancellation method for interference nuclides for reference species quantitative analysis of radioactive waste drum TGS analysis. 3. The method according to claim 1 or 2,
In the third step,
When the calculated value of the optimal energy range factor (F (E _K )) is less than 1, and two or more gamma ray energy (E _I ) of the interfering nuclide is emitted,

(

Is the reference nuclear gamma-ray energy excluding the radiation coefficient of the interfering nuclide (

) Net area,

Is the reference nuclear gamma-ray energy containing the radiation coefficient of the interfering nuclide (

),

Is the radioactivity of the interfering radionuclide measured by the other gamma ray energy of the interfering nuclide,

Is the internuclear gamma-ray energy per unit collapse (

) Emission probability,

Is interfering gamma-ray energy (

Method for eliminating interference of interference nuclei for the reference nuclide quantitative analysis of the radioactive waste drum TGS analysis, 3. The method according to claim 1 or 2,
In the third step,
When the calculated value of the optimal energy range factor F (E _K ) is less than 1,
The radioactivity measurement in the radioactive waste drum is calculated as the sum of the reference nuclide and the interfering nuclide.

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