KR20200095237A - Materials screening apparatus and method thereof - Google Patents

Abstract

The present invention relates to a material screening apparatus and a method thereof. More specifically, according to one embodiment of the present invention, the material screening apparatus may be provided, which comprises a measurement unit measuring the mass of a radioactive nuclide contained in a material, and an external exposure evaluation unit which stores an allowable radioactivity value of the nuclide, derives a calculated radioactivity value of the nuclide from the mass of the nuclide measured by the measurement unit, and evaluates risk of external exposure of the material based on the allowable radioactivity value of the nuclide and the calculated radioactivity value of the nuclide.

Description

Materials screening apparatus and method {MATERIALS SCREENING APPARATUS AND METHOD THEREOF}

The present invention relates to an apparatus and method for screening materials such as building materials.

Naturally Occurring Radioactive Material (NORM) always exists in nature, and when manufactured using a material containing it, natural radionuclides also exist in processed products. Natural radionuclides produced from general industrial processes or process by-products of the natural radionuclides industry are partially recycled in building materials, which can increase radiation exposure to residents. In the case of building materials containing natural radionuclides, not only external exposure to occupants by gamma rays, but also internal exposure by radon from the uranium series may occur. Article 15 of the Peripheral Radiation Safety Management Act requires that the amount of human exposure by radiation emitted from processed products does not exceed the standards determined and notified by the Nuclear Safety Committee, and Article 4 of the notification stipulates the amount as 1 mSv per year. . In addition, the indoor air quality management law for multi-use facilities stipulates that the indoor radon concentration is 148 Bq/m ³ . However, if it is limited to annual dose, it is necessary to present the allowable activity concentration for natural radionuclides so that operators can meet the standards from the product manufacturing stage because of the difficulty in dose evaluation. In addition, in the case of building materials, internal exposure due to radon must be considered, so it is necessary to screen for radium concentration from the material stage before the building is built by predicting the indoor radon concentration by the radium content in the building material.

However, conventionally, as in Korean Patent Registration No. 10-1922208, after building construction is completed, only attention is paid to detecting radon concentration inside the building, and radionuclides such as radium, which are contained in building materials and generate radon, are detected. And external exposures such as gamma rays from other radionuclides have been overlooked. Since there is a limit to lowering radon concentration or reducing external exposure by radiation after the building is built, it is necessary to prevent the construction of buildings with high internal radon concentration or high risk of external exposure by radiation at the material level in advance. There is.

Korean Patent Registration No. 10-1922208

Embodiments of the present invention are intended to provide a material screening apparatus and a material screening method capable of pre-evaluating and predicting radioactive risk before construction material is constructed.

According to an aspect of the present invention, the measurement unit for measuring the mass of the radioactive nuclide included in the material; The allowable radioactivity value of the nuclide is stored, the calculated radioactivity value of the nuclide is derived from the mass of the nuclide measured by the measurement unit, and the material of the material is based on the allowable radioactivity value of the nuclide and the calculated radioactivity value A material screening apparatus may be provided, comprising an external exposure evaluation unit that evaluates the risk of external exposure to radiation.

According to embodiments of the present invention, there is an effect of predicting and evaluating the risk of radiation exposure even for materials before being constructed as a building.

1 is a conceptual diagram showing a material screening apparatus according to an embodiment of the present invention.
2 is a graph showing the limit of radium concentration according to the material thickness when the indoor radon concentration is 148 Bq/m ³ .
3 is a flow chart of a material screening method according to an embodiment of the present invention.

Hereinafter, a specific embodiment for implementing the spirit of the present invention will be described in detail with reference to the drawings.

In addition, in the description of the present invention, when it is determined that detailed descriptions of related well-known structures or functions may obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

In addition, when a component is referred to as being'transmitted' to another component, it is to be understood that although it is directly transmitted to the other component or pressure may be applied directly, another component may exist in the middle.

The terms used in this specification are only used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Hereinafter, components of the material screening apparatus 1 according to an embodiment of the present invention will be described with reference to FIG. 1.

Referring to FIG. 1, the material screening device 1 predicts the concentration of radioactivity that may be generated by natural radionuclides contained in the material, and determines the extent to which people in the building are exposed to radiation when such a material is constructed as a building. It is predictable. In other words, the material screening device 1 may calculate and evaluate the risk of radioactive exposure that may occur due to natural radionuclides contained in the material before the material is constructed into a building. Examples of such natural radionuclides include U-238 (uranium), Ra-226 (radium), Th-232 (thorium), and K-40 (potassium).

The material screening device 1 may include a measurement unit 10, an evaluation unit 20, and a display unit 30 to predict the risk of radioactive exposure that may occur due to nuclides contained in the material.

The measurement unit 10 may measure the mass of radioactive nuclides contained in the material. The measurement unit 10 may measure the mass of the radionuclide in the form of a concentration (ppm).

The measurement unit 10 may measure the mass of the radionuclide by a non-destructive analysis method. Since the measurement unit 10 is configured in a non-destructive analysis method, it is possible to measure the mass of the radionuclide regardless of the size of the sample, and to measure the mass of the radionuclide for a predetermined thickness. Therefore, it is possible to measure the mass of a nuclide contained in a solid sample such as a building material without chemical pretreatment, and has the advantage that the sample is not destroyed during the measurement process. The measurement unit 10 may be, for example, an X-Ray Fluorescence (XRF) device, ICP-MS, which measures the mass of a nuclide using X-ray fluorescence spectrometry, and may have a portable size.

The measurement unit 10 may measure the mass of at least one radionuclide. For example, the measurement unit 10 may measure the mass of one or more elements from sodium to uranium, and may measure the mass of at least any one of uranium, radium, thorium, and potassium.

The evaluation unit 20 may evaluate and predict the radioactive risk of the material based on the mass of the nuclide measured by the measurement unit 10. The evaluation unit 20 may include an external exposure evaluation unit 210 and an internal exposure evaluation unit 220.

The external exposure evaluation unit 210 may evaluate and predict the risk of external exposure due to radiation of the material based on the allowable radioactivity value and the calculated radioactivity value of the nuclide (external exposure evaluation step S210). These external exposures may be primarily due to gamma rays emitted from natural radionuclides. The external exposure evaluation unit 210 may store an allowable radioactivity value for at least one nuclide. The external exposure evaluation unit 210 may first calculate the radioactivity concentration (calculated radioactivity value) of the nuclide using Equation (1) below from the mass of the nuclide measured by the measurement unit 10.

Equation (1):

In Equation (1), A is the radioactivity concentration (decay rate, Bq), M is the molar mass (g), t1/2 is the half-life (s), and N _A is the Avogadro's number. m represents the mass of the nuclide to be analyzed. Since the mass of the nuclide measured in the measurement unit 10 includes the mass of the isotope, m (mass of the nuclide to be analyzed) in Equation (1) contains the natural isotope of the mass of the nuclide measured in the measurement unit 10. Apply what is multiplied by abundance. For example, in substituting m in Equation (1), the mass of U-238 is applied by multiplying the mass of uranium measured in the measurement unit 10 by 99.3% of the abundance of natural isotopes of U-238, and Th- 232 is applied by multiplying by 100% since no other isotope exists in nature, and the mass of K-40 is applied by multiplying the mass of potassium measured in the measurement unit 10 by 0.0117% of the abundance of the natural isotope of K-40. . In addition to the above example, when the masses of uranium, thorium, and potassium measured in the measurement unit 10 are 3.0 ppm, 10.0 ppm and 10000 ppm, respectively, the measured mass is multiplied by the isotope abundance and substituted into Equation (1). The calculated radioactivity values (radiation concentration) of each of the nuclides U-238, Th-232 and K-40 can be calculated as 37.1 Bq/kg, 40.7 Bq/kg and 309.6 Bq/kg.

The external exposure evaluation unit 210 may store an allowable radioactivity value (Activity concentration limits of nuclide x, Ax [Bq/kg]) for each radionuclide. The allowable radioactivity value for any radionuclide x can be calculated using Equation (2) below.

Equation (2): Annual radiation exposure limit = (SDRx × Ax-BKG) × AOT

Here, SDRx is the specific effective dose rate for the radionuclide x [Sv/h per Bq/kg]), and BKG is the natural emitted from cosmic rays and natural radioactive materials. As the dose rate of radiation emitted from the environment, it is the background dose rate [Sv/h], and the AOT is the average occupancy time [h/year] in the room.

In this equation (2), the SDRx for the radionuclide x can be calculated by a room model and a Monte Carlo code (algorithm), for example, a virtual room model having a rectangular shape of 5m in width, 4m in length, and 2.8m in height It can be set and calculated for each nuclide using a Monte Carlo code (algorithm) such as MCNP. Each SDRx for a plurality of radionuclides x in Equation (2) is calculated and set using the same room model and the same algorithm for the plurality of nuclides, but the SDRx of the plurality of nuclides have different values. By setting the allowable radioactivity value, it is used in the calculation of SDRx so that the allowable radioactivity value for each nuclide can be quickly and easily derived even without conducting a dose evaluation that reflects the exposure environment, type of building material, and residence time for each analysis. The room model is set conservatively, generally. Based on the room model and Monte Carlo code described above, the SDRs of U-238, Th-232, and K-40 are exemplarily derived, respectively. 5.75E-10, 8.09E-10, 5.49E-11 (Sv/h per Bq/kg). The allowable radioactivity value of each radionuclide may be previously stored in the external exposure evaluation unit 210, but may be input or changed by the user in the external exposure evaluation unit 210 arbitrarily.

The annual radiation exposure limit value is 1 mSv/year per year in accordance with the standards established and publicly announced by the Nuclear Safety Committee as prescribed by Article 15 of the Peripheral Radiation Safety Management Act and the same article. Therefore, 1 mSv/year can be substituted for the annual radiation exposure limit value in Equation (2) above, and a more conservative value can be set. In addition, since AOT is 7000 hours and BKG can be set to 5.53E-8 (Sv/h), these are substituted into Equation (2) to determine the allowable radioactivity concentrations for U-238, Th-232 and K-40. When calculated, the allowable concentrations of U-238, Th-232 and K-40 are 300 Bq/kg, 200 Bq/kg, and 3000 Bq/kg, respectively.

The external exposure evaluation unit 210 may evaluate the risk of external exposure of a person inside the building to radiation when a material is installed in a building based on the allowable radioactivity value of the nuclide and the calculated radioactivity value of the nuclide. The risk of external exposure of people inside a building to radiation can manifest itself in the amount of external exposure of people inside a building to radiation due to materials. In addition, the external exposure evaluation unit 210 may evaluate the risk of external exposure by comparing the ratio with a reference value based on the ratio of the calculated radioactivity value to the allowable radioactivity value of the nuclide. Specifically, by determining whether the sum of the ratio of the calculated radioactivity value to the allowable radioactivity value of the nuclide (which can be named as the calculation index (I _calculation )) is larger than the reference index (I _standard ), It can be determined whether the amount of external exposure exceeds the annual radiation exposure limit. In other words, when the external exposure evaluation unit 210 is greater than the calculation index (I _calculation ) reference index (I _standard ), which is a value obtained by adding the ratio of the calculated radioactivity values to the allowable radioactivity values of a plurality of nuclides, the external exposure of people inside the building Exceeding this annual radiation exposure limit, the material can be assessed as a high risk of external exposure to radiation to people in the building. Expressed by an equation, the external exposure evaluation unit 210 may evaluate that the risk of external exposure to radiation is high if the equation (3) below is not satisfied.

Equation (3):

To determine the risk of external exposure to radiation caused by U-238, Th-232 and K-40 contained in the material, the permissible radioactivity values of U-238, Th-232 and K-40 described above are 300 Bq/kg and 200 Bq. Substituting /kg and 3000 Bq/kg into Equation (3), it can be expressed as follows.

The external exposure evaluation unit 210 adds the ratio of the calculated radiation value to the allowable radiation values of U-238, Th-232 and K-40 (calculation index (I _calculation )) is less than the reference index (I _standard ). If so, it is evaluated as having low or no external exposure risk, and if the calculation index (I _calculation ) exceeds the reference index (I _standard ), the external exposure risk is evaluated as high.

The reference index (I _criterion ) used in Equation (3) may be conservatively set to a value less than 1 (for example, 0.7), but may be changed. Such a reference index (I _criterion ) may be previously stored in the external exposure evaluation unit 210, but may be input or changed by the user in the external exposure evaluation unit 210 arbitrarily.

The radiation risk evaluation result of the external exposure evaluation unit 210 may be displayed on the display unit 30. The radioactivity risk evaluation result of the external exposure evaluation unit 210 displayed on the display unit 30 is calculated based on the radioactivity value calculated for the allowable radioactivity value of the nuclide itself It may be expressed by indicating the calculation index (I _calculation ), which is a value obtained by adding the ratio of the calculated radioactivity value to each other, or by indicating whether the calculation index (I _calculation ) exceeds the reference index (I _standard ). .

The internal exposure evaluation unit 220 may evaluate the risk of internal exposure of people inside the building by radon when the material is constructed as a building based on the mass of Ra-226 (internal exposure evaluation step S220).

In nature, Ra-226 is in radial equilibrium with U-238, so the mass of Ra-226 can also be calculated from the mass of U-238. The mass of Ra-226 may be calculated by the measurement unit 10 or the evaluation unit 20.

Ra-226 is the parent nuclide of radon, and Ra-226 contained in the material affects the indoor radon concentration. The internal exposure evaluation unit 220 may store an allowable radioactivity value for Ra-226 in order to determine the risk of internal radiation exposure due to Ra-226 included in the material. The internal exposure evaluation unit 220 calculates the radioactivity concentration (calculated radioactivity value) of Ra-226 using the measured or calculated mass of Ra-226 and Equation (1), and the calculated radioactivity value of Ra-226 is Ra- By judging whether it is greater than the allowable radiation value for 226, it is possible to determine whether the internal exposure of people inside the building exceeds the annual radiation exposure limit.

The allowable radioactivity value for Ra-226 stored in the internal exposure evaluation unit 220 varies depending on the thickness of the building material and the target indoor radon concentration limit. The indoor air quality management method for multi-use facilities, etc., regulates the indoor radon concentration to 148 Bq/m ³ or less, so the Ra-226 concentration limit according to the material thickness when the indoor radon concentration is 148 Bq/m ³ is shown in the graph of FIG. same. When the material thickness of the building is conservatively set to 20 cm, referring to FIG. 3, the allowable radioactivity value for Ra-226 may be set to 130 Bq/kg. In other words, the allowable radiation value for Ra-226 stored in the internal exposure evaluation unit 220 may be 130 Bq/kg, and the internal exposure evaluation unit 220 has a calculated radiation value of Ra-226 than 130 Bq/kg. If it is large, it can be evaluated and predicted as having a high radioactive risk.

The radioactive risk evaluation result of the internal exposure evaluation unit 220 may be displayed on the display unit 30. The radioactive risk evaluation result of the internal exposure evaluation unit 220 displayed on the display unit 30 is whether the calculated radioactivity value of the measured Ra-226 exceeds the allowable radioactivity value for Ra-226, or Ra-226 included in the material. It can be expressed by indicating whether the mass of is exceeding the allowable content of radium derived from Equation (1).

The evaluation unit 20 is evaluated that the calculated index (I _calculation ) exceeds the reference index (I _standard ) by the external exposure evaluation unit 210, or the calculated radioactivity of Ra-226 measured by the internal exposure evaluation unit 220 If the value is evaluated as exceeding the allowable radioactivity value for Ra-226, it can be determined that the risk of radiation exposure is high, and the result can be expressed through the display unit 30.

The evaluation unit 20 may be implemented by a computing device including a microprocessor, and the implementation method is obvious to those skilled in the art, and thus a detailed description thereof will be omitted. In addition, the evaluation unit 20 may include a communication module for communicating with the outside of the material screening device (1).

The display unit 30 may be a display device capable of implementing text, numbers, and images.

Meanwhile, in the present embodiment, it has been described that the evaluation results of the external exposure evaluation unit 210 and the internal exposure evaluation unit 220 appear on the display unit 30, but the spirit of the present invention is not necessarily limited thereto, and the evaluation unit ( 20) may consist of transmitting the evaluation result to other computing devices, servers, etc. through communication means.

Meanwhile, FIG. 3 is a diagram showing a procedure of a material screening method according to an embodiment of the present invention. The method shown in FIG. 3 can be performed by the material screening device 1 shown in FIG. 1. In addition, since the procedure of the method shown in FIG. 3 is merely exemplary, the spirit of the present invention is not limited to FIG. 3.

Referring to FIG. 3, the measurement unit 10 of the material screening device 1 performs a measurement step S10 of measuring the mass of a radionuclide contained in the material. The evaluation unit 20 of the material screening apparatus 1 performs an evaluation step (S20) of evaluating the radioactive risk of the material based on the mass of the nuclide measured by the measurement unit 10. This evaluation step (S20) may include an external exposure evaluation step (S210) performed by the external exposure evaluation unit 210 and an internal exposure evaluation step (S220) performed by the internal exposure evaluation unit 220.

The external exposure evaluation step (S210) is performed based on Equations (1) to (3) described above. In the external exposure evaluation step (S210), the allowable radioactivity value of Equation (3) is derived for each of a plurality of nuclides based on the room model and the Monte Carlo code.

In the internal exposure evaluation step (S220), the radioactivity concentration (calculated radioactivity value) of Ra-226 is calculated using the measured or calculated mass of Ra-226 and Equation (1), and the calculated radioactivity value of Ra-226 is Ra- By judging whether it is greater than the allowable radiation value for 226, it is possible to determine whether the internal exposure of people inside the building exceeds the annual radiation exposure limit. This internal exposure evaluation step (S220) may be performed in the internal exposure evaluation unit 220.

On the other hand, since the material screen method according to an embodiment includes substantially the same technical idea as that for the material screen device 1 described above, it is decided to use the matters already described in the material screen device 1, and Duplicate description will be omitted.

On the other hand, the communication security method according to an embodiment is implemented in the form of a computer readable recording medium storing a computer program programmed to perform a procedure included in this method, or a computer program stored in a computer readable recording medium. It can be implemented in a form.

Although the embodiments of the present invention have been described above as specific embodiments, these are merely examples, and the present invention is not limited thereto, and should be interpreted as having the broadest scope according to the basic idea disclosed herein. Those skilled in the art may combine/replace the disclosed embodiments to implement patterns in an untimely manner, but this is also within the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, and it is obvious that such changes or modifications fall within the scope of the present invention.

1: material screening device 10: measuring unit
20: evaluation unit 210: external exposure evaluation unit
220: internal exposure evaluation unit 30: display unit

Claims (14)

Measurement unit for measuring the mass of the radioactive nuclide contained in the material;
The allowable radioactivity value of the nuclide is stored, the calculated radioactivity value of the nuclide is derived from the mass of the nuclide measured by the measurement unit, and the material of the material is based on the allowable radioactivity value of the nuclide and the calculated radioactivity value of the nuclide. Including an external exposure evaluation unit that evaluates the risk of external exposure to radiation,
Material screening device. The method of claim 1,
The external exposure evaluation unit,
By comparing the sum of the ratio of the calculated radioactivity value to the allowable radioactivity value of the nuclide and a preset reference index, the material evaluates the risk of external exposure to radiation,
Material screening device. According to claim 2,
The measurement unit measures the mass of at least one of uranium, thorium and potassium contained in the material, and the external exposure evaluation unit stores an allowable radioactivity value for at least one of uranium, thorium and potassium,
Material screening device. According to claim 2,
The allowable radioactivity value of a nuclide is set by reflecting the specific effective dose rate for the radionuclide x to be set to a different value for each nuclide,
Material screening device. The method of claim 4,
The non-effective dose rate is derived based on a virtually set room model and Monte Carlo code,
Material screening device. The method of claim 1,
It further includes an internal exposure evaluation unit,
The measuring unit measures the mass of radium contained in the material,
The internal exposure evaluation unit,
Evaluating the risk of internal radiation exposure of the material based on the mass of radium of the material measured by the measuring unit,
Material screening device. The method of claim 6,
To evaluate the risk of internal radiation exposure of the material by comparing the mass of radium measured by the measuring unit and the allowable radioactivity value for radium,
Material screening device. The method of claim 1,
The measurement unit measures the mass of the nuclide using X-ray fluorescence spectrometry,
Material screening device. A measurement step of measuring the mass of a radionuclide contained in the material;
External exposure evaluation that derives the calculated radioactivity value of the nuclide from the mass of the nuclide measured in the measuring step, and calculates the risk of external exposure to radiation of the material based on the allowable radioactivity value of the nuclide and the calculated radioactivity value of the nuclide Comprising steps,
Material screening method. The method of claim 9,
The external exposure evaluation step,
To evaluate the risk of external radiation exposure of the material by comparing the sum of the ratio of the calculated radioactivity value to the allowed radioactivity value of the nuclide and a preset reference index,
Material screening method. The method of claim 9,
Based on the mass of radium contained in the material, further comprising an internal exposure evaluation step of evaluating the radiation internal exposure risk of the material,
Material screening method. The method according to any one of claims 9 to 11,
The material is a building material, which is a material before construction as a building,
Material screening method. As a computer-readable recording medium storing a computer program that allows a processor to perform a material screening method,
The material screening method,
A measurement step of measuring the mass of a radionuclide contained in the material;
External exposure evaluation that derives the calculated radioactivity value of the nuclide from the mass of the nuclide measured in the measuring step, and calculates the risk of external exposure to radiation of the material based on the allowable radioactivity value of the nuclide and the calculated radioactivity value of the nuclide Comprising steps,
A computer-readable recording medium storing a computer program. As a computer program stored in a computer-readable recording medium that allows a processor to perform a material screening method,
The material screening method,
A measurement step of measuring the mass of a radionuclide contained in the material;
External exposure evaluation that derives the calculated radioactivity value of the nuclide from the mass of the nuclide measured in the measuring step, and calculates the risk of external exposure to radiation of the material based on the allowable radioactivity value of the nuclide and the calculated radioactivity value of the nuclide Comprising steps,
A computer program stored on a computer-readable recording medium.

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