JPH07225280A - Radiation measuring apparatus - Google Patents

Abstract

PURPOSE:To provide a radiation measuring apparatus which prevent a background level by Cherenkov radiation from being increased. CONSTITUTION:In a simultaneous counting type radiation measuring apparatus, one pair of photomultiplier tubes 8a, 8b which simultaneously count photons converted by a scintillator 2 are provided with reference to the scintillator 2 which converts a radiation into photons. In the simultaneous counting type radiation measuring apparatus, transparent shielding members 4a 4b, which correspond to the individual photomultiplier tubes 8a, 8b are arranged between the scintillator 2 and the photomultiplier tubes 8a, 8b so as to be separated optically. Consequently, since Cherenkov radiation which is generated in the transparent shielding member 4a (or 4b) on one side does not reach the transparent shielding member 4b (or 4a) on the other side, it can be removed as a noise, and the radiation can be measured at a low background.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiation measuring apparatus, and more particularly to a simultaneous counting type radiation measuring apparatus utilizing a scintillation effect and having a low noise level.

[0002]

2. Description of the Related Art Conventionally, a coincidence counting type radiation measuring apparatus utilizing a scintillation effect of emitting light by irradiating radiation has been known. This radiation measuring apparatus will be described with reference to FIG.

In the figure, the scintillator 2 is a flat plate made of plastic or the like, and when irradiated with radiation, it generates photons proportional to the absorbed energy of the radiation, and the photomultiplier tube 8
Reference numerals a and 8b respectively convert and amplify the photons generated in the scintillator 2 into predetermined voltage pulses.

The light guide 20 is made of a transparent material such as plastic or glass having a predetermined thickness, and guides the photons generated in the scintillator 2 to the photomultiplier tubes 8a and 8b. A light reflecting member 6 is provided around the side surface of the light guide 20 so that photons generated in the scintillator 2 do not leak to the outside.

[0005] Incidentally, photomultiplier tubes 8a, includes a ⁴⁰ K or the like to the glass window 8b the light guide 20 side, the
Β rays are generated due to ⁴⁰ K and so on. Light guide 20
Is a photomultiplier tube 8a, 8 for photons from the scintillator 2.
In addition to leading to b, it has a function of blocking unnecessary β rays caused by the photomultiplier tubes 8a and 8b. Due to this β-ray shielding function of the light guide 20, the photomultiplier tube 8
The β rays emitted from a and 8b are prevented from reaching the scintillator 2 and detected as radiation to be measured, and noise caused by ⁴⁰ K or the like is reduced.

In the photomultiplier tubes 8a and 8b to which a high voltage is applied, noise due to heat is generated and the radiation measurement accuracy is lowered. However, paying attention to the extremely low probability that this thermal noise is simultaneously generated in the pair of photomultiplier tubes 8a and 8b, the scintillator 2 is provided with the pair of photomultiplier tubes 8a and 8b to measure the radiation to be measured. Simultaneous counting reduces thermal noise.

Specifically, when photons generated in the scintillator 2 reach both of the photomultiplier tubes 8a and 8b and are output as a predetermined voltage pulse from both, the output voltage pulse is temporally changed. Since they match, a counting circuit (not shown) counts this output voltage pulse. Even if a voltage pulse is output from one of the photomultiplier tubes 8a, (8b) due to thermal noise or the like, the other photomultiplier tube 8b, (8b)
Since the output voltage pulse from a) does not match in time,
The counting circuit removes this as noise and counting is not performed.

As described above, by performing the coincidence counting, it is possible to measure radiation in a low noise level, that is, in a low background state.

[0009]

However, in the conventional radiation measuring apparatus, the light guide 20 made of plastic or the like having a certain thickness is used to shield the β rays caused by the photomultiplier tubes 8a and 8b. Since it is used, there is a problem that the Cherenkov effect is generated in the light guide 20 and noise is generated due to the Cherenkov effect.

Here, the Cherenkov effect means that when charged particles such as high-energy γ-rays and cosmic rays move in a substance, the movement speed is the speed of light in the substance (light velocity in vacuum /
It is to generate radiant energy (Cherenkov light) when it becomes larger than the refractive index of a substance.

The Cherenkov effect generated in the light guide 20 is as follows. Specifically, as shown in FIG. 3, high-energy γ-rays and cosmic rays coming from outside pass through the scintillator 2 and enter the light guide 20. To reach and generate Cherenkov light in this light guide 20.

The Cerenkov light generated in the light guide 20 reaches the pair of photomultiplier tubes 8a and 8b at the same time, and is simultaneously counted, and becomes noise with respect to the radiation to be measured. As a result, there is a problem that the background level increases.

The present invention has been made in order to solve the above problems, and it is possible to increase the background level due to Cherenkov light while maintaining the function of reducing the noise due to β rays caused by the conventional photomultiplier tube. It is an object to provide a preventable low background radiation measuring device.

[0014]

In order to achieve the above object, the radiation measuring apparatus according to the present invention has the following features.

That is, a scintillator for converting radiation into photons, a pair of photomultiplier tubes for simultaneously counting the photons converted by the scintillator, and arranged between the scintillator and the photomultiplier tube, While guiding the photons from the scintillator to each of the photomultiplier tubes, a transparent shielding member having a predetermined thickness to shield the radiation emitted from each photomultiplier tube to the scintillator side,
And a transparent shielding member that is optically separated corresponding to each photomultiplier tube.

Further, the transparent shield member is arranged at a predetermined distance from the scintillator.

[0017]

According to the radiation measuring apparatus of the present invention, since the transparent shield member is optically separated corresponding to each photomultiplier tube, the inside of one transparent shield member is affected by cosmic rays from the outside. Although Cherenkov light is generated and reaches the photomultiplier tube corresponding to this transparent shield member, it does not reach the photomultiplier tube on the other side as in the conventional case.

Further, the probability that Cherenkov light is simultaneously generated in both the pair of photomultiplier tubes is extremely low.

As described above, most of the Cherenkov light is detected by only one of the photomultiplier tubes. Therefore, the outputs from the pair of photomultiplier tubes are compared by performing coincidence counting, and the outputs are temporally different. In this case, if this is removed as noise, it is possible to perform low-background radiation measurement with a low noise level.

[0020]

An embodiment of the present invention will be described below with reference to the drawings.

(Embodiment 1) FIG. 1 is a conceptual diagram showing a main part of a radiation measuring apparatus according to an embodiment of the present invention.

In the figure, the scintillator 2 is a flat plate or a cylinder made of plastic or the like, and when irradiated with radiation, it produces photons proportional to the radiation absorption energy. And
The thickness of the scintillator 2 is generally about 0.5 mm when measuring the amount of radiation, and about 20 to 30 mm when measuring not only the amount but also the spectrum of the radiation.

The photomultiplier tubes 8a and 8b are provided for converting the photons generated by the scintillator 2 into predetermined voltage pulses when the photons arrive and amplifying the photons. . This is because thermal noise is randomly generated in the photomultiplier tubes 8a and 8b as described above, and it is extremely low that the thermal noises are simultaneously detected by a plurality of photomultiplier tubes 8. And a predetermined voltage pulse is applied to the photomultiplier tube 8
Except when it is obtained from both a and 8b at the same time, the voltage pulse is removed as noise to reduce the noise level.

Next, the transparent shielding members 4a and 4b are made of plastic or glass having a predetermined thickness, and the photomultiplier tubes 8a and 8b are provided between the scintillator 2 and the photomultiplier tubes 8a and 8b. Corresponding to the scintillator 2
The photons generated in 1 are guided to the corresponding photomultiplier tubes 8. The photomultiplier tube 8a, but contains ⁴⁰ K, etc. The scintillator 2 side glass window of 8b, transparent shielding member 4a, the 4b have the function of blocking the β-rays caused by the ⁴⁰ K, etc. However, β rays emitted from the photomultiplier tubes 8a and 8b are prevented from reaching the scintillator 2 to generate photons and become noise.

Here, the thickness of the transparent shielding members 4a and 4b is, for example, 5 mm to 10 mm, and if the material is plastic or glass, the photomultiplier tube 8 starts from about 5 mm.
It has the effect of blocking β rays emitted from a and 8b.

The light reflecting member 6 efficiently guides the photons generated in the scintillator 2 to the corresponding photomultiplier tubes 8a and 8b, and prevents light from leaking between the adjacent photomultiplier tubes 8a and 8b. In order to prevent it, the transparent shielding member 4
It is provided around the side surfaces of a and 4b.

Further, by the air layer 10, the transparent shield members 4a, 4b and the scintillator 2 are provided with a predetermined interval (eg, photon generated in the scintillator 2) to both of the pair of photomultiplier tubes 8a, 8b. 10 mm).

In the radiation measuring apparatus having the above-described structure, when radiation to be measured (eg, β-rays) enters the scintillator 2 from the outside, photons corresponding to this radiation are generated in the scintillator 2. This photon is the air layer 10
To reach both photomultiplier tubes 8a and 8b through transparent shielding members 4a and 4b provided corresponding to the respective photomultiplier tubes 8a and 8b. The photomultiplier tubes 8a and 8b convert the photons into predetermined voltage pulses according to the number of photons that have reached them, and output them to a counting circuit (not shown). In the counting circuit, the voltage pulses output from the pair of photomultiplier tubes 8a and 8b are compared with each other. If the voltage pulses are generated at the same time, the voltage pulses are counted, and if they are not generated at the same time, they are removed as noise and counted. do not do.

On the other hand, high-energy γ-rays and cosmic rays from the outside penetrate the scintillator 2 and reach the transparent shielding members 4a, 4b through the air layer 10. Then, Cherenkov light is generated in the transparent shielding members 4a and 4b as described above. The generated Cherenkov light reaches the photomultiplier tubes 8a and 8b corresponding to the transparent shielding members 4a and 4b, and is converted into a predetermined voltage pulse.

However, since the transparent shielding members 4a and 4b are optically separated for each photomultiplier tube 8a and 8b,
For example, even if Cherenkov light is generated in the transparent shield member 4a, the Cherenkov light is shielded by the light reflecting member 6 provided around the side surface of the transparent shield member 4a and does not leak to the outside, and the other transparent shield member. 4b and the corresponding photomultiplier tube 8b cannot be reached. The reverse is also true. Note that the probability that the Cherenkov light is simultaneously generated in both the transparent shielding members 4a and 4b corresponding to the pair of photomultiplier tubes 8a and 8b is extremely low.

Therefore, even if Cherenkov light is generated on one of the transparent shielding members 4a and 4b due to cosmic rays or the like, this Cherenkov light does not reach the other transparent shielding member 4b and 4a, so that simultaneous counting is performed. However, noise due to Cherenkov light can be removed.

As described above, according to the radiation measuring apparatus of the present embodiment, the function of reducing / eliminating the noise and the like due to the β rays caused by the photomultiplier tubes 8a and 8b is maintained, and the Cherenkov light is used. It is possible to reduce and remove noise, and it is possible to perform measurement with an extremely low noise level, and it is possible to perform the measurement even if the radiation to be measured is weak.

The thickness and shape of each member are geometrically defined, and are not limited to the values and shapes already described.

(Second Embodiment) Next, a radiation measuring apparatus having a configuration different from that of the first embodiment will be described with reference to FIG. In the figure, the same parts as those in FIG.

The characteristics of the radiation measuring apparatus according to this embodiment are as follows.
When the pair of photomultiplier tubes 8a, 8b are arranged adjacent to each other at an extremely short distance, the transparent shielding members 12a, 12b corresponding to the photomultiplier tubes 8a, 8b are integrally configured and the photomultiplier tube is formed. That is, the light reflecting member 6 is provided in a corresponding portion between 8a and 8b. Transparent shield members 12a and 12b integrally formed by the light reflecting member 6
Are optically separated for each photomultiplier tube 8a, 8b.

With this structure, as in the first embodiment,
It is possible to reduce and remove noise due to Cherenkov light while retaining the function of reducing and eliminating noise due to β-rays caused by the photomultiplier tubes 8a and 8b. Even if the radiation to be measured is weak, It has an effect that measurement can be performed.

Furthermore, since the arrangement distance between the pair of photomultiplier tubes 8a and 8b can be reduced, the position dependence of the photomultiplier tubes 8a and 8b on the radiation can be reduced, and the noise level can be further increased. It has the effect of contributing to reduction and removal.

[0038]

As described above, according to the radiation measuring apparatus of the present invention, the function of reducing / removing the thermal noise generated in the photomultiplier tube and the noise due to the β rays caused by the photomultiplier tube. Not only that, but also noise due to Cherenkov light can be reduced / removed, and the noise level can be made extremely low. Therefore, it is possible to provide a low background radiation measuring apparatus capable of measuring even weak radiation.

[Brief description of drawings]

FIG. 1 is a conceptual diagram showing a main part of a radiation measuring apparatus according to a first embodiment of the present invention.

FIG. 2 is a conceptual diagram showing a main part of a radiation measuring apparatus according to a second embodiment of the present invention.

FIG. 3 is a conceptual diagram showing a main part of a conventional radiation measuring apparatus.

[Explanation of symbols]

 2 scintillator 4a, 4b, 12a, 12b transparent shielding member 6 light reflecting member 8a, 8b photomultiplier tube 10 air layer 20 light guide

Claims (2)

[Claims] 1. A scintillator for converting radiation into photons, a pair of photomultiplier tubes for simultaneously counting photons converted by the scintillator, and arranged between the scintillator and the photomultiplier tube, A transparent shielding member having a predetermined thickness that guides photons from the scintillator to each of the photomultiplier tubes and shields radiation emitted from the photomultiplier tubes to the scintillator side, wherein the photomultiplier tubes A radiation measuring apparatus, comprising: a transparent shielding member which is optically separated correspondingly to each. 2. The radiation measuring apparatus according to claim 1, wherein the transparent shield member is arranged at a predetermined distance from the scintillator.