JP2012242369A - Radiation detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radiation detector capable of outputting an individual counting rate with high accuracy by discriminating the kinds of radiations with one radiation detector even at a spot where the kinds of radiations, such as an alpha ray, a beta ray and a gamma ray are unknown.SOLUTION: A first scintillator, the thickness of a first layer of which is 0.1 mm or below detects all alpha rays because an alpha ray has a short range. The first scintillator of the first layer loses only a small portion of energy in a beta ray, and a second scintillator, the thickness of a second layer of which is 0.1 to 1 mm loses almost all of the energy. The thickness of the second layer which loses almost all of the energy of a beta ray of targeted 2 to 3 MeV is selected. A third scintillator, the thickness of a third layer of which is 0.1 to 50 mm detects a gamma ray because the gamma ray has high penetrability. In the scintillator of each layer, an electronic circuit measures difference between light emission decay times by using different light emission decay times, and discriminates the kind of a radiation with high accuracy by performing waveform analysis.

Description

  The present invention relates to a radiation detector, and more particularly to a survey meter for detection of radioactive contamination associated with an accident at a nuclear power plant or the like.

Conventional survey meters are divided into alpha rays, beta rays, and gamma rays, and they are often used according to their respective purposes. However, in the detection of radioactive contamination due to accidents at nuclear power plants, many types of fission products are released into the environment, including alpha-emitting nuclides, beta-emitting nuclides, and gamma-emitting nuclides. To do.
A general survey meter uses a scintillation detector, but structurally, it often measures gamma dose in the environment. Therefore, it is necessary to use a dedicated survey meter for detecting alpha rays and beta rays. For example, as the alpha ray survey meter, a scintillation survey meter in which a ZnS (Ag) thin film and a photomultiplier tube are combined is used.

  Also, multiple layers of semiconductor radiation that are provided opposite to the incident direction of radiation and absorb radiation in different energy regions and output radiation detection signals according to the radiation dose as absorbing radiation in different energy regions A detector is known (Patent Document 1). However, in the case of the semiconductor radiation detector disclosed in Patent Document 1, it is necessary to correct the energy sensitivity characteristic such as multiplying the radiation detection signal in each layer by the weight, and the sensitivity greatly varies depending on the weight. There's a problem.

JP 2005-214869 A

In general, it is difficult to use three types of survey meters for alpha rays, beta rays, and gamma rays at an urgent contamination site. In addition, it is an economic burden to arrange a plurality of measuring instruments.
In view of the above situation, the present invention provides a single radiation detector even at a site where the type of radiation such as alpha rays, beta rays, and gamma rays is unknown, such as radioactive contamination associated with an accident at a nuclear power plant. Thus, it is an object to provide a radiation detector capable of discriminating these types of radiation and outputting individual count rates with high accuracy.

In order to achieve the above object, a radiation detector according to the first aspect of the present invention includes a first scintillator having a thickness of 0.1 mm or less and a second scintillator having a thickness of 0.1 to 1 mm, which have different emission decay times. These scintillators and a third scintillator having a thickness of 0.1 to 50 mm are laminated in order from the incident side, and are optically coupled to a photodetector that can detect light emitted from each scintillator.
According to this configuration, the first scintillator for alpha rays, the second scintillator for beta rays, and the third scintillator for gamma rays are stacked in this order from the incident side, and light emitted from each scintillator can be detected. By optically coupling with a photodetector, alpha rays, beta rays, and gamma rays can be discriminated and measured simultaneously.

Since alpha rays have a short range, they can all be detected by the first scintillator having a thickness of 0.1 mm or less in the first layer. The beta ray loses only a small amount of energy in the first scintillator of the first layer, and most of the energy is lost in the second scintillator having a thickness of 0.1 to 1 mm in the second layer. The thickness of the second layer is selected to lose almost all of the target 2-3 MeV beta ray energy. Since gamma rays have high penetrating power, they are detected by a third scintillator having a thickness of 0.1 to 50 mm in the third layer. As described above, when the scintillators of the respective layers have different emission decay times, the difference in the emission decay times is measured by an electronic circuit, and the waveform can be discriminated with high accuracy.
The purpose of optical coupling with the photodetector is to convert the optical signal electrically by grasping the path of the light emitted from the scintillator of each layer and guiding it to the light receiving surface without loss by an optimum method. is there.

The radiation detector according to the second aspect of the present invention has a thickness in which a first scintillator having a thickness of 0.1 mm or less and an alpha-ray absorber having the same thickness as the first scintillator are stacked on the incident side. 0.1 to 1 mm thickness of the second scintillator, and a beta ray absorber having a total thickness of the first scintillator thickness and the second scintillator thickness laminated on the incident side The third scintillators are arranged in parallel to each other, and are optically coupled to a photodetector that can detect light emitted from each scintillator.
According to such a configuration, the first scintillator for alpha rays, the second scintillator for beta rays, and the third scintillator for gamma rays are arranged in parallel, and light detection that can detect light emitted from each scintillator By providing a device, alpha rays, beta rays and gamma rays can be discriminated and measured simultaneously.
The purpose of optical coupling with the photodetector is to electrically convert the optical signal by grasping the path of the light emitted from each scintillator and guiding it to the light receiving surface without loss in an optimum manner. .

  In the case of the radiation detector according to the second aspect, the first scintillator for alpha rays, the second scintillator for beta rays, and the third scintillator for gamma rays are the radiation detector according to the first aspect. In contrast, the light emission decay times need not be different from each other, and the light emission decay times may be the same.

Here, the photodetector in the radiation detector according to the first aspect is a photomultiplier tube that detects light emitted from each scintillator and outputs it as an electrical signal. By using a photomultiplier tube, it is possible to obtain waveform analysis spectrum and energy spectrum information.
The photodetector in the radiation detector according to the first aspect or the second aspect is a position-sensitive photomultiplier tube that detects light emitted from each scintillator and outputs it as an electrical signal.
By using a position-sensitive photomultiplier tube as a photodetector, it becomes possible to obtain information on the position of radiation detected by the scintillator in addition to the waveform analysis spectrum and energy spectrum. The position information can be calculated, for example, by calculating the center of gravity of the output signal. For example, since plutonium that emits alpha rays exists in the form of particles, the position information is useful for detection of plutonium.

  According to the present invention, there is an effect that alpha rays, beta rays, and gamma rays can be simultaneously discriminated and measured with one radiation detector.

Schematic configuration schematic diagram of the radiation detector of Example 1 Photomultiplier tube output signal waveforms for alpha rays (A), beta rays (B), and gamma rays (C) observed with an oscilloscope Waveform analysis spectrum (left) and energy spectrum (right) when alpha, beta, and gamma rays are measured separately Counting rate of each layer when irradiated with alpha rays, beta rays, and gamma rays in order Schematic configuration schematic diagram of the radiation detector of Example 2 Schematic configuration schematic diagram of the radiation detector of Example 3

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The scope of the present invention is not limited to the following examples and illustrated examples, and many changes and modifications can be made.

FIG. 1 shows a schematic configuration diagram of a radiation detector according to the first embodiment of the present invention. The scintillator was optically coupled with a plastic scintillator with a thickness of 50 μm, a 0.5 mm thick Ce concentration of 1.5 mol% Gd ₂ SiO ₅ (GSO), and a 0.5 mm thick Ce concentration with 0.4 mol% GSO. The photomultiplier tube (PMT) which is a photodetector is optically coupled.
Since the range of alpha rays of about 6 MeV emitted from americium, which is a typical nuclide of nuclear reaction products, is about 50 μm in plastic, alpha rays lose all energy in the plastic scintillator, scintillation light Is generated. The emission decay time of this scintillation light is about 2.4 ns.

  The range of beta rays of about 2 MeV emitted from Sr-Y-90, which is a typical fission product, is about 2 mm on average in water. Accordingly, the range of beta rays is about 0.3 mm on average in GSO having a density of 6 times or more, and almost all energy is lost in the second layer GSO. Even in the first layer, the beta rays lose energy, but since the thickness of the plastic scintillator is 50 μm, the energy loss of the beta rays in this layer is negligible. The emission decay time of this scintillation light is about 35 ns.

The transmittance of 662 keV gamma rays emitted from Cs-137, which is a typical fission product, is extremely high, and is not detected in the first layer, but is detected in approximately the same ratio in the second and third layers. Therefore, the count of the third layer is only gamma rays because alpha rays and beta rays are absorbed in the first and second layers so far and do not reach the third layer. The emission decay time of this scintillation light is about 70 ns.
The light emitted from these three layers is guided to a photomultiplier tube and converted into an electric signal. Since the scintillation light signal of the electric signal is different in each of the first layer, the second layer, and the third layer, it is possible to discriminate which of the three layers emits the light by analyzing the waveform of this signal. It becomes possible.

FIG. 2 shows the signal waveform of the photomultiplier tube when the alpha ray from Am-241, the beta ray from Sr-Y-90, and the gamma ray from Cs-137 are individually measured in the radiation detector of the first embodiment. Indicates.
When alpha rays are incident on the detector, they are detected only by the first layer of plastic scintillator, so that a waveform with a fast emission decay time (slightly smoothed by the circuit and about 10 ns) is observed.
When beta rays enter the detector, they are detected only by the second-layer GSO, so that a waveform with a moderate light emission decay time (about 40 ns after being smoothed slightly by the circuit) is obtained.
When gamma rays are incident on the detector, they are detected in both the second and third layers, so they are moderate (slightly smoothed by the circuit and about 40 ns) and slow emission decay times (slightly smoothed by the circuit and about 80 ns) ) Waveform is obtained.
By performing waveform analysis of this signal, a waveform analysis spectrum can be obtained. As a signal processing method, the signal of the photomultiplier tube is converted from analog to digital, integrated with two types of integration times (for example, 50 ns and 320 ns), and a ratio between them is obtained.

FIG. 3 shows the waveform analysis spectrum and the energy spectrum when the alpha ray from Am-241, the beta ray from Sr-Y-90, and the gamma ray from Cs-137 are individually measured with the radiation detector of Example 1. Show. 3A to 3C, the left is the waveform analysis spectrum and the right is the energy spectrum.
When alpha rays are incident on the radiation detector, they are detected only by a plastic scintillator with a fast emission decay time, so that a peak is observed on the rightmost in the waveform analysis result (the left diagram in FIG. 3A). In the energy spectrum, a single peak with respect to alpha rays is observed (the right diagram in FIG. 3A).

When the beta ray is incident on the radiation detector, it is detected only in the second layer GSO having a medium emission decay time, so that a peak is observed in the middle in the waveform analysis result (left of FIG. 3B). Figure). In the energy spectrum, a broad distribution with respect to beta rays is observed (the right diagram in FIG. 3B).
When gamma rays are incident on the radiation detector, the light emission decay time is detected in both the second and slow third layers, so peaks are observed on the middle and left sides (see FIG. 3C). (Left figure). In the energy spectrum, a single peak with respect to gamma rays is observed (the right figure in FIG. 3C).
From these results, if the waveform analysis spectrum is divided into three, it is possible to obtain alpha, beta, and gamma ray counts from the right.

FIG. 4 shows changes in the count rate of each layer when alpha rays, beta rays, and gamma rays are irradiated in order. First, when alpha rays are irradiated, only the first layer count increases. Next, when beta rays are irradiated, only the second layer count increases. Finally, when gamma rays are irradiated, the counts of the second and third layers increase. Therefore, the first layer count represents alpha rays, the second layer represents beta rays, and the third layer represents gamma ray counts.
When beta rays and gamma rays are irradiated simultaneously, a corrected beta ray count rate can be obtained by subtracting a constant multiple of the third layer count from the second layer count.

  FIG. 5 shows a schematic configuration diagram of a radiation detector according to the second embodiment of the present invention. The scintillator is an optical detector by optically coupling a plastic scintillator with a thickness of 50 μm, a GSO with a Ce concentration of 1.5 mol% with a thickness of 0.5 mm, and a GSO with a Ce concentration of 0.5 mol with a thickness of 0.5 mm. It is configured to be optically coupled to a position sensitive photomultiplier tube (PSPMT). A light guide made of a transparent acrylic plate or the like can be inserted between the position-sensitive photomultiplier tube and the three types of scintillators.

  The radiation detected by the three types of scintillators is the same as in Example 1, but in this example, since it is optically coupled to the position-sensitive photomultiplier tube, in addition to the waveform analysis spectrum and energy spectrum, Information on the position of the radiation detected by the scintillator can be obtained. The position information can be calculated by, for example, calculating the center of gravity of the output signal. Since plutonium that emits alpha rays exists in the form of particles, position information is useful for detection of plutonium.

  FIG. 6 shows a schematic configuration diagram of a radiation detector according to the third embodiment of the present invention. For the scintillator, a plastic scintillator having a thickness of 50 μm is optically coupled to a part of the position-sensitive photomultiplier tube (PSPMT) (left side in FIG. 6), and GSO with a Ce concentration of 1.5 mol% with a thickness of 0.5 mm is added. As shown in FIG. 6, optical coupling is performed in the middle, and a plastic that does not emit light, for example, about 50 μm is attached to the incident surface. A GSO with a thickness of 0.5 mm and a Ce concentration of 0.4 mol% is optically coupled to the right side as shown in FIG. 6, and a beta ray absorbing material of about 1 mm is pasted before that. In Example 3, these scintillators are optically coupled to a position-sensitive photomultiplier tube that is a photodetector.

A light guide made of a transparent acrylic plate or the like can be inserted between the position-sensitive photomultiplier tube and the three types of scintillators to keep the height constant. Further, a light absorbing material can be placed between each scintillator so that the light emission does not spread to the position of another scintillator.
The radiation detected by the three types of scintillators is the same as that in Example 1, but in this Example 3, since it is optically coupled to the position-sensitive photomultiplier tube, the position of the radiation detected by the scintillator The information can represent the type detected by each scintillator. In this case, accuracy is improved by using waveform analysis together. In the case of Example 3, a scintillator having the same emission decay time may be selected.

The present invention is useful as a survey meter in a facility such as a nuclear power plant.

Claims (4)

  A first scintillator having a thickness of 0.1 mm or less, a second scintillator having a thickness of 0.1 to 1 mm, and a third scintillator having a thickness of 0.1 to 50 mm, which have different emission decay times, are sequentially provided. A radiation detector characterized in that it is laminated from the incident side and optically coupled to a photodetector capable of detecting light emitted from each scintillator.   A first scintillator having a thickness of 0.1 mm or less, a second scintillator having a thickness of 0.1 to 1 mm in which an alpha ray absorber having the same thickness as the first scintillator is laminated on the incident side, A third scintillator having a thickness of 0.1 to 50 mm in which a beta ray absorber having a total thickness of the scintillator and the second scintillator is stacked on the incident side is arranged in parallel, A radiation detector characterized by being optically coupled to a photodetector capable of detecting light emitted from a scintillator.   The radiation detector according to claim 1, wherein the photodetector is a photomultiplier tube that detects light emitted from each scintillator and outputs the detected light as an electric signal. The radiation detector according to claim 1 or 2, wherein the photodetector is a position-sensitive photomultiplier tube that detects light emitted from each scintillator and outputs it as an electrical signal.