KR101381579B1 - Electronic personal dosimeter using single channel analyzer - Google Patents

Abstract

Disclosed is a personal electronic dosimeter using multiple single channel analyzers. The personal electronic dosimeter, according to embodiments of the present invention, uses more than two single channel analyzers in order to form an energy window based on the radiation energy level of the radiation source, or form a reference level value greater than two. Through the reference level value, a radiation signal can be recognized, so as for a user to measure radiation of various sources, and calculate a reliable dose. [Reference numerals] (AA) Radiation energy; (BB) Time

Description

Electronic radiation personal dosimeter using multiple single channel analyzers {ELECTRONIC PERSONAL DOSIMETER USING SINGLE CHANNEL ANALYZER}

The present invention relates to an electronic radiation personal dosimeter, and more particularly to an electronic radiation personal dosimeter using a plurality of single channel analyzer.

The biggest problem in the operation of nuclear power plants is the damage of radiation from radioactive leakage. Since radiation is not visible to the human eye and its damage is fatal to humans, research on personal dosimeters to effectively prevent or minimize the damage caused by radiation by measuring and managing the exposure and contamination of individual workers The situation is actively going on.

In particular, the development of active dosimeters that can compensate for the disadvantages of the passive dosimeter (cumbersome reading process) in accordance with the development of integrated circuit and semiconductor technology in recent years.

Among the active dosimeters, the most widely used is an electronic radiation personal dosimeter using a silicon fin (PIN) diode, which has the advantage of being able to acquire data in real time and being easy to use.

The electronic radiation personal dosimeter using a silicon fin (PIN) diode uses a principle (solid ionization) that collects the charge generated by the radiation incident on the depletion region (solid ionization) and uses an intrinsic semiconductor between pn junctions of pn semiconductors. Intrinsic Semicondictor) is characterized by a large space charge region. Recently, in order to solve the problem that the dosimeter and tissues have different reaction characteristics according to the radiation energy, the energy response response of the dosimeter and the human tissue energy is provided by installing an energy compensation filter in front of the electronic radiation personal dosimeter. The characteristics are similar.

1 is a graph schematically showing the principle of calculating the exposure amount of the conventional electronic radiation personal dosimeter.

Referring to FIG. 1, the X axis of the graph shown represents time and the Y axis represents radiation energy. Conventional electronic radiation personal dosimeters detect radiation energy using a pin diode, and the signal according to the radiation energy is waveform signaled through a preamplifer, a shaping amplifier, a microprocessor, and the like. In this case, a single channel analyzer (SCA) is used to process the signal. The single channel analyzer forms one reference level value R and recognizes and outputs a radio signal only when the reference level value R is exceeded.

Specifically, it is assumed that there is a first source 1 having a relatively high energy level and a second source 2 having a lower energy level than the first source 1. In this case, it is assumed that the reference level value R formed in the single channel analyzer is located at a lower level than the energy level of the second source 2 as shown in FIG. 1.

In this case, since all of the radiation peaks exceed the reference level value R (seven peaks in FIG. 1), the single channel analyzer recognizes and outputs all seven radiation peaks as radiation signals. As a result, the exposure amount is determined to be 7 x (specific radiation energy level values). Herein, the specific radiation energy level value means a specific value that may be different for each individual dosimeter. The specific value can be determined by the manufacturer of the personal dosimeter.

However, in the conventional electronic radiation personal dosimeter which calculates the exposure amount in this way, there is a problem that reliability is very low because the dose is determined only by the number of radiation peaks exceeding the reference level value irrespective of the energy level of the radiation. . For example, the dose obtained by absorbing one radiation of 1 MeV and the dose obtained by absorbing one radiation of 1 keV may be treated in the same case in some cases.

In reality, since the exposure amount is determined according to the energy level of the source, an electronic radiation personal dosimeter capable of calculating the exposure amount to be more reliable is required.

Embodiments of the present invention seek to provide an electronic radiation personal dosimeter capable of measuring the radiation dose of various radiation sources and calculating a more reliable dose.

According to an aspect of the present invention, in the electronic radiation personal dosimeter for detecting the radiation energy to be exposed and calculate the radiation exposure amount, the upper level value and the lower level forming a predetermined energy width centered on the radiation energy level of the first source A first single channel analyzer forming a first energy window having a level value and recognizing and outputting a radiation signal only when a level of a signal input from a detector for detecting radiation energy is within the first energy window; And a second energy window having an upper level value and a lower level value having a predetermined energy width using the radiation energy level of the second source as a center value, wherein the level of the signal input from the detector is the second energy. And a second single channel analyzer for recognizing and outputting a radiation signal only when it is within a window, and calculating an exposure amount based on values output from the first single channel analyzer and the second single channel analyzer. Personal dosimeters may be provided.

At this time, the value output from the first single channel analyzer and the second single channel analyzer may be characterized by being processed by the following [Equation 1].

[Formula 1]

Signal processing value = ((number of signals located in the first energy window) × (radiation energy level value of the first source)) + ((number of signals located in the second energy window) × (radiation energy level of the second source value))

According to another aspect of the present invention, in the electronic radiation personal dosimeter for detecting the radiation energy to be exposed and calculate the radiation exposure amount, the level of the signal input from the detector for forming a first reference level value and detecting the radiation energy is A first single channel analyzer recognizing and outputting a radiation signal only when the first reference level value is exceeded; And forming a second reference level value lower than the first reference level value and recognizing and outputting the radiation signal only when the level of the signal input from the detector is between the first reference level value and the second reference level value. An electronic radiation personal dosimeter may be provided, comprising a second single channel analyzer, and calculating an exposure amount based on values output from the first single channel analyzer and the second single channel analyzer.

In this case, the value output from the first single channel analyzer and the second single channel analyzer may be processed by Equation 2 below.

[Formula 2]

Signal processing value = ((number of signals exceeding the first reference level value) × (first radiation energy level value exceeding the first reference level value)) + ((between the first reference level value and the second reference level value Number of signals located at) × (second radiation energy level value between the first reference level value and the second reference level value))

Embodiments of the present invention form an energy window or two or more reference level values centered on the radiation energy levels of various radiation sources using two or more single channel analyzers, thereby recognizing the radiation signal through The radiation dose can be measured and a more reliable dose can be calculated.

In addition, since two or more single channel analyzers are used, manufacturing costs can be significantly lowered compared to advanced dosimeters including multichannel analyzers.

1 is a graph schematically showing the principle of calculating the exposure amount of the conventional electronic radiation personal dosimeter.
2 is a graph schematically showing the principle of calculating the exposure amount of the electronic radiation personal dosimeter according to an embodiment of the present invention.
3 is a graph schematically showing the principle of calculating the exposure amount of the electronic radiation personal dosimeter according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The electronic radiation personal dosimeter according to the embodiments of the present invention is an active dosimeter, and the type of sensor of the dosimeter is not limited. However, for convenience of description, the electronic radiation personal dosimeter according to the embodiments of the present invention will be described with reference to a case where the electronic radiation personal dosimeter using a silicon pin (PIN) photodiode.

The electronic radiation personal dosimeter includes a silicon pin diode (PIN) diode, a detector for detecting radiation energy, a preamplifer and shaping amplifier for amplifying a signal according to the radiation energy, and a dose conversion factor. And a microprocessor for reading out the dose conversion factor and converting the dose conversion factor into a modulated waveform represented by a time-dependent function, a signal converter for converting the modulated waveform into a signal, a single channel analyzer processing the signal, and the like. Can be. In addition, an energy compensation filter may be installed in front of the personal dosimeter.

Each configuration of such an electronic radiation personal dosimeter is well-known, and a detailed description thereof will be omitted and hereinafter, the electronic radiation personal dosimeter according to the embodiments of the present invention will be mainly focused on a part different from the conventional electronic radiation personal dosimeter. Explain.

(1) First Embodiment

An electronic radiation personal dosimeter (hereinafter referred to as an individual dosimeter) according to an embodiment of the present invention corresponds to a personal dosimeter for detecting radiation energy to be exposed and calculating radiation exposure, and characterized by including two or more single channel analyzers. .

Conventionally, the same type of personal dosimeter includes only one single channel analyzer, but the personal dosimeter according to an embodiment of the present invention can improve the reliability of the radiation dose calculated by including two or more single channel analyzers. There is this.

The personal dosimeter may include two or more single channel analyzers, but for convenience of explanation, the following description will focus on the case where the personal dosimeter includes two single channel analyzers. In addition, the two single channel analyzers are classified and referred to as "first single channel analyzer" and "second single channel analyzer", respectively.

2 is a graph schematically illustrating a principle of calculating an exposure amount of an electronic radiation personal dosimeter according to an embodiment of the present invention.

Referring to FIG. 2, the personal dosimeter includes a first single channel analyzer and a second single channel analyzer.

The first single channel analyzer forms a first energy window 100 having an upper level value and a lower level value having a predetermined energy width with the radiation energy level 10 of the first source as a center value. Here, the first source means any radiation substance, and the radiation energy level of the first source means the radiation energy level of the radiation substance.

For example, in FIG. 2, when the radiation energy level 10 of the first source is 90 keV, the first energy window 100 is set to an energy width of 80 keV (lower level value) to 100 keV (higher level value). Can be. That is, a width of energy corresponding to a lower value to a higher value of the same magnitude may be set as the first energy window 100 based on the radiation energy level 10 of the first source. Of course, the radiation energy level may vary according to the radiation material, and the size of the width of the first energy window 100 may also be adjusted.

The first single channel analyzer is set to recognize and output a radiation signal only when the signal level input from the detector of the personal dosimeter is within the first energy window 100.

For example, a, b, d, and g of the radiation peaks of the waveform graph shown in FIG. 2 are located in the first energy window 100. In this case, the first single channel analyzer is set to recognize and output the four radiation peaks as a radiation signal.

The second single channel analyzer forms a second energy window 200 having an upper level value and a lower level value having a predetermined energy width with the radiation energy level 20 of the second source as a center value. Here, the second source means any radioactive material different from the first source, and the radiation energy level of the second source means the radiation energy level of the corresponding radioactive material.

For example, in FIG. 2, when the radiation energy level 20 of the second source is 60 keV, the second energy window 200 is set to an energy width of 50 keV (lower level value) to 70 keV (higher level value). Can be. That is, the width of energy corresponding to a lower value to a higher value of the same magnitude may be set as the second energy window 200 based on the radiation energy level 20 of the second source. Of course, the radiation energy level may vary according to the radiation material, and the size of the width of the second energy window 200 may be adjusted.

The second single channel analyzer is set to recognize and output a radiation signal only when the signal level input from the detector of the personal dosimeter is within the second energy window 200.

For example, c, e, and f of the radiation peaks of the waveform graph shown in FIG. 2 are located in the second energy window 200. In this case, the second single channel analyzer is set to recognize and output the three radiation peaks as a radiation signal.

The exposure amount may be calculated based on values output from the first single channel analyzer and the second single channel analyzer.

For example, the value output from the first single channel analyzer and the second single channel analyzer may be processed by the following [Formula 1].

[Formula 1]

Signal processing value = ((number of signals located in the first energy window) × (radiation energy level value of the first source)) + ((number of signals located in the second energy window) × (radiation energy level of the second source value))

Substituting the numerical values exemplified above into [Equation 1], the signal processing value corresponds to (4 x 90 keV) + (3 x 60 keV) = 540 keV. The signal processing value may be used as an exposure amount or may be calculated as an exposure amount after undergoing appropriate conversion. At this time, the method of converting the signal processing value may vary. For example, a method of weighting a specific radioactive material may be used.

As described above, when two single channel analyzers are used, the radiation energy level values of two or more radiation sources can be reflected in the exposure dose, so that not only the radiation dose of various radiation sources can be measured but also a more reliable exposure dose is calculated. The advantage is that it is possible.

(2) Second Embodiment

An electronic radiation personal dosimeter (hereinafter referred to as an individual dosimeter) according to another embodiment of the present invention is characterized by including two or more single channel analyzers as in the first embodiment described above. Hereinafter, a description will be given focusing on the parts that differ from the above-described first embodiment.

3 is a graph schematically showing the principle of calculating the exposure amount of the electronic radiation personal dosimeter according to another embodiment of the present invention.

Referring to FIG. 3, the personal dosimeter includes a first single channel analyzer and a second single channel analyzer.

The first single channel analyzer forms a first reference level value 110. The first reference level value 110 may be arbitrarily adjusted. The first single channel analyzer is set to recognize and output a radiation signal only when the signal level input from the detector of the personal dosimeter exceeds the first reference level value 110.

For example, among the radiation peaks of the waveform graph shown in FIG. 3, the cases of a, b, d, and g exceed the first reference level value 110. In this case, the first single channel analyzer is set to recognize and output the four radiation peaks as a radiation signal.

The second single channel analyzer forms a second reference level value 210. Here, the second reference level value 210 has a lower level than the first reference level value 110. This is to detect various sources by providing a level difference between the first reference level value 110 and the second reference level value 210. The second reference level value 210 may be arbitrarily adjusted.

The second single channel analyzer is set to recognize and output a radiation signal only when the signal level input from the detector of the personal dosimeter is between the first reference level value 110 and the second reference level value 210.

For example, the peaks exceeding the second reference level value 210 among the radiation peaks of the waveform graph shown in FIG. 3 are all peaks corresponding to a to g. However, the peaks between the first reference level value 110 and the second reference level value 210 are c, e, and f, and the second single channel analyzer recognizes and outputs the three radiation peaks as a radiation signal. Is set. This is because peaks exceeding the first reference level value 110 need not be signal-processed in conjunction with the second reference level value 210.

The exposure amount may be calculated based on values output from the first single channel analyzer and the second single channel analyzer.

For example, the value output from the first single channel analyzer and the second single channel analyzer may be processed by Equation 2 below.

[Formula 1]

Signal processing value = ((number of signals exceeding the first reference level value) × (first radiation energy level value exceeding the first reference level value)) + ((between the first reference level value and the second reference level value Number of signals located at) × (second radiation energy level value between the first reference level value and the second reference level value))

In Equation 2, the first radiation energy level value exceeding the first reference level value 110 refers to a radiation energy level value of the radioactive material estimated from energy levels of peaks exceeding the first reference level value 110. it means. In addition, the second radiation energy level value between the first reference level value 110 and the second reference level value 210 is a peak located between the first reference level value 110 and the second reference level value 210. It means the radiation energy level value of the radioactive material estimated from their energy level.

For example, assuming that the first radiation energy level value (reference numeral 11 in FIG. 3) is 90 keV and the second radiation energy level value (reference numeral 21 in FIG. 3) is 50 keV (first reference level value is 70 keV, 2 assumes that the reference level value is 40 keV), and substitutes this in [Equation 2], and the signal processing value corresponds to (4 x 90 keV) + (3 x 40 keV) = 480 keV. The signal processing value may be used as an exposure amount or may be calculated as an exposure amount after undergoing appropriate conversion. At this time, the method of converting the signal processing value may vary. For example, a method of weighting a specific radioactive material may be used.

As described above, when two single channel analyzers are used, the radiation energy level values of two or more radiation sources can be reflected in the exposure dose, so that not only the radiation dose of various radiation sources can be measured but also a more reliable exposure dose is calculated. The advantage is that it is possible.

As described above, embodiments of the present invention form an energy window or two or more reference level values centering on the radiation energy levels of various radiation sources using two or more single channel analyzers, thereby recognizing a radiation signal. Thus, the radiation dose of various radiation sources can be measured and a more reliable dose can be calculated.

In addition, since it is configured using two or more single channel analyzer, the manufacturing cost can be significantly reduced compared to the advanced dosimeter including a multichannel analyzer (Multichannel Analyzer), it is possible to supply a small personal dosimeter at a low price to the general public.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, many modifications and changes may be made by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

1: first sailor 2: second sailor
R: reference level value 10,11: radiation energy level of the first source
20,21: radiation energy level of the second source
100: first energy window 200: second energy window
110: first reference level value 210: second reference level value

Claims (4)

An electronic radiation personal dosimeter which detects radiation energy to be exposed and calculates radiation dose,
Forming a first energy window having an upper level value and a lower level value forming a predetermined energy width with the radiation energy level of the first source as the center value, the level of the signal input from the detector for detecting the radiation energy is A first single channel analyzer for recognizing and outputting a radiation signal only when within the first energy window; And
A second energy window having an upper level value and a lower level value having a predetermined energy width is formed using the radiation energy level of the second source as a center value, and the level of the signal input from the detector is the second energy window. A second single channel analyzer which recognizes and outputs a radiation signal only when it is within the
The value output from the first single channel analyzer and the second single channel analyzer is processed by the following [Equation 1], and based on the signal processing value of the following [Equation 1] electronic radiation, characterized in that for calculating the radiation exposure Personal dosimeter.
[Formula 1]
Signal processing value = ((number of signals located in the first energy window) × (radiation energy level value of the first source)) + ((number of signals located in the second energy window) × (radiation energy level of the second source value)) delete An electronic radiation personal dosimeter which detects radiation energy to be exposed and calculates radiation dose,
A first single channel analyzer forming a first reference level value and recognizing and outputting a radiation signal only when a level of a signal input from a detector for detecting radiation energy exceeds the first reference level value; And
Forming a second reference level value lower than the first reference level value, and recognizing and outputting the radiation signal only when the level of the signal input from the detector is between the first reference level value and the second reference level value A second single channel analyzer,
The value output from the first single channel analyzer and the second single channel analyzer is processed by the following [Equation 2], and based on the signal processing value of the following [Equation 2] electronic radiation, characterized in that for calculating the radiation exposure Personal dosimeter.
[Formula 2]
Signal processing value = ((number of signals exceeding the first reference level value) × (first radiation energy level value exceeding the first reference level value)) + ((between the first reference level value and the second reference level value Number of signals located at) × (second radiation energy level value between the first reference level value and the second reference level value)) delete

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