JP5032417B2 - Radiation detector - Google Patents

Description

  The present invention relates to a radiation detector that inspects for the presence or absence of radioactive contamination, and more particularly to a radiation detector that is thin, has a large detection area, and is highly sensitive.

  When leaving a radiation control area such as a nuclear power plant, the radioactive contamination density of the worker's body and clothing surface is inspected for the purpose of preventing exposure to workers and preventing contamination outside the control area. It is required by law to confirm that is below the control standard value.

  As a device for inspecting such radioactive contamination density, there are a hand foot cross monitor and a body surface contamination monitor. In particular, the body surface contamination monitor is installed at the exit of the radiation control area and inspects that the radioactive material is not attached to the whole body and clothes of the worker. At the same time, the body must be kept from moving in a predetermined pose, which is a burden. In order to reduce this burden, shortening the measurement time is one solution, but for that purpose, it is necessary to further improve the sensitivity of the radiation detector.

  In order to improve the sensitivity of the radiation detector, an attempt has been made to increase the area of the scintillator that emits fluorescence upon incidence of radiation. A basic configuration of such a radiation detector is shown in FIG. The radiation detector includes a scintillator unit 1 that emits fluorescence upon incidence of radiation, two light guide units 16 that collect the fluorescence, and a reflector 4 that is optically bonded to the light guide unit 16. A photoelectric converter 5 for converting the converted fluorescence into an electric signal, a pulse height discriminating section 6 for discriminating noise and a signal with a preset threshold with respect to the peak value of the electric signal, and a pulse only when the signal arrives at the same time. It is composed of a coincidence counting unit 7 that outputs, a contamination determination processing unit 8 that counts pulses to determine the presence or absence of contamination, and a display unit 10 that displays a signal count rate.

In addition, a radiation detector using a plastic scintillator that can be easily enlarged as a scintillator is also known (Patent Document 1). In this radiation detector, a wavelength shift fiber is arranged along the periphery of a flat plastic scintillator, scintillation light generated by the incidence of radiation is converted into fluorescence by the wavelength shift fiber, and the fluorescence is provided on the end face of the wavelength shift fiber. It is extracted as an electrical signal by a photoelectric converter.
Japanese Patent Laid-Open No. 10-232284

  In the radiation detector applied to the conventional body surface contamination monitor shown in Patent Document 1 above, the scintillator unit uses a plastic scintillator that can be easily increased in area, and shifts the wavelength along the side surface of the flat plastic scintillator. A light guide made of fiber is arranged, and a photoelectric converter is arranged at the end of the light guide, thereby opening up and down the detector and realizing a thin detector.

  However, in the detector having such a configuration, when the detection surface size is increased, transmission loss of light reaching from a region far from the photoelectric converter actually increases, and as a result, the overall detection sensitivity decreases. There is a problem such as. In other words, a light guide composed of a single wavelength-shifted fiber can be detected because, for example, as shown in FIG. 3, the amount of light reaching the photoelectric conversion unit is seen to decrease mainly depending on the distance due to self-absorption loss. There is a problem that the overall detection sensitivity decreases as the surface size increases.

  The present invention has been made to solve the above problems, and provides a radiation detector capable of realizing high detection sensitivity even when the detection area is increased while maintaining the thin structure of the conventional radiation detector. Objective.

In order to solve the above-described problems, a radiation detector according to the present invention includes a flat scintillator that emits fluorescence upon incidence of radiation, and a light guide that is provided on at least one side of the scintillator to collect the fluorescence. And a signal processing unit for detecting the presence or absence of contamination by detecting fluorescence condensed by the light guide group by a photoelectric converter , wherein the light guide group is made of a transparent member. a first light guide portion of the rod-shaped comprising a second light guide portion of the rod-shaped made of fluorescent conversion material, on the side surface of the first light guide portion of the rod-shaped made of fluorescent conversion material which is in close contact with an air layer first 3 and the light guide portion, Tona is, the one end face of the first light guide portion is optically joined to one end surface of the second light guide section, the first light guide portion of the other end surface及One end surface of the third light guide portion is optically bonded to the photoelectric converter, and a reflector is optically bonded to the other end surface of the third light guide portion and the other end surface of the second light guide portion. The three light guide portions are disposed on the opposite side of the scintillator portion with respect to the first light guide portion, and the side surfaces of the first light guide portion and the second light guide portion are one of the flat scintillator portions. It is characterized by being in close contact with the side .

The radiation detector according to the present invention includes a flat scintillator portion that emits fluorescence upon incidence of radiation, a light guide group that is provided on at least one side of the scintillator portion and collects the fluorescence, and the light guide. A signal processing unit for detecting the presence or absence of contamination by detecting fluorescence collected by the group by a photoelectric converter , wherein the light guide group is a rod-shaped first light made of a transparent member A guide portion and a fourth light guide portion; a rod-shaped second light guide portion made of a fluorescence conversion material disposed between the first light guide portion and the fourth light guide portion; the first light guide portion; a fourth third light guide section of the rod-like formed of the light guide portion fluorescent conversion materials each side are in close contact via the air layer and the fifth light guide portion, Ri Tona, the second Both end surfaces of the light guide portion are optically joined to one end surfaces of the first light guide portion and the fourth light guide portion, respectively, and the other end surface of the first light guide portion and one end surface of the third light guide portion, and The photoelectric converter is optically bonded to the other end surface of the fourth light guide portion and one end surface of the fifth light guide portion, respectively, and a reflector is applied to the other end surface of the third light guide portion and the fifth light guide portion. Are respectively optically joined, and the third light guide portion and the fifth light guide portion are disposed on the opposite side of the scintillator portion with respect to the first light guide portion and the fourth light guide portion, respectively, and and wherein the light guide unit, the third light guide unit and the fourth light guide portion side of which is adhered to one side of the plate-shaped scintillator unit That.

The radiation detector according to the present invention includes a flat scintillator that emits fluorescence upon incidence of radiation, a light guide group provided on each side of the scintillator to collect the fluorescence, and the light guide. A signal processing unit for detecting the presence or absence of contamination by detecting fluorescence collected by the group by a photoelectric converter , wherein the light guide group is a rod-shaped first light made of a transparent member a guide portion, and a third light guide portion of the second light guide portion of the rod-shaped made of fluorescent conversion materials, consisting of the fluorescent conversion material which is in close contact with an air layer on a side surface of the first light guide section bar- from it, the scintillator unit, the light shielding plate at the interface with being divided in a cross shape is optically joined, one end surface of the first light guide portion at one end of the second light guide portion The other end face of the first light guide part and one end face of the third light guide part are optically joined to the photoelectric converter, and the other end of the second light guide part and the third light guide part. Reflective materials are optically joined to the end surfaces of the first light guide portion, the third light guide portion is disposed on the opposite side of the scintillator portion with respect to the first light guide portion, and the first light guide portion and the second light guide portion are disposed. The side surface of the portion is in close contact with one side of the flat scintillator portion .

  According to the radiation detector according to the present invention, by using a light guide group that combines a light guide portion made of a transparent member and a light guide portion made of a fluorescence conversion material, it becomes possible to increase the light collection efficiency, As a result, a thin radiation detector with a large detection area and high sensitivity can be provided.

Hereinafter, embodiments of a radiation detector according to the present invention will be described with reference to the drawings.
(First embodiment)
The radiation detector which concerns on the 1st Embodiment of this invention is demonstrated using FIG.1 and FIG.2.
The radiation detector according to the first embodiment includes a scintillator unit 1 that emits fluorescence upon incidence of radiation, a first light guide unit 2 made of a rod-shaped transparent member, a second light guide unit 3 made of a fluorescence conversion material, A radiation detection unit 20 including a third light guide unit 11, a reflection unit 4, and a photoelectric conversion unit 5 that are in close contact with the side surface of the second light guide unit 3 via an air layer, and a signal processing unit 30. Is done.

  The end faces of the first light guide part 2 and the second light guide part 3 are optically bonded (bonding for suppressing reflection and transmission loss of light, and optical grease or optical adhesive is used as a bonding medium and is selected according to the situation. Can be).

As shown in FIG. 1 or FIG. 2, the scintillator unit 1 is disposed in close contact with the opposing side surfaces so that the positions of the first light guide unit 2 and the second light guide unit 3 are opposite to each other. A photoelectric conversion unit 5 that detects fluorescence and converts it into an electric pulse is optically joined to the end surfaces of the light guide unit 2 and the third light guide unit 11, and further, the other end surface of the third light guide unit 11 and the second end surface A reflective material 4 is optically bonded to the end surface of the light guide portion 3.
The radiation detection unit 20 (the scintillator unit 1, the first to third light guide units 2, 3, 11, the reflector 4 and the photoelectric conversion unit 5) is entirely covered with a light shielding film (not shown). .

The signal processor 30 outputs two pulse height discriminators 6 that output a pulse when the electrical signal of the photoelectric converter 5 exceeds a threshold value, and outputs one pulse only when two or more pulses arrive at the same time. To supply a high voltage to the counting unit 7, the contamination determination processing unit 8 that counts the number of pulses to determine the presence or absence of contamination, the display unit 9 that displays the count value and the contamination determination result, and the photoelectric conversion unit 5 The high-voltage power supply unit 10 is configured.
The scintillator unit 1 is optimally a flat plastic scintillator that is excellent in workability, easily available, and easy to handle.

Next, the function of the radiation detector having the above configuration will be described.
When radiation enters the scintillator unit 1, the fluorescence emitted inside the scintillator unit 1 spreads uniformly at an isotropic angle, and those satisfying the total reflection condition are emitted from the side edges of the entire periphery by internal capture.

As shown in FIG. 1 or FIG. 2, the fluorescence that collects on the side end face of the scintillator unit 1 is provided on two opposing sides of the scintillator unit and is provided with two light guide groups A (from the first to third light guide units). Are collected by a light guide group).
The arrangement of the first to third light guide portions constituting one light guide group A is 180 degrees rotationally symmetric with the arrangement of other light guide groups A provided on opposite sides.

  The side end surface of the scintillator unit 1 made of plastic scintillator and the side surfaces of the first to third light guide units are in close contact with each other through an air layer, optically bonded, or more practically used. The side surfaces of the first to third light guide portions are processed into a concave shape and are joined by a method in which the scintillator portion 1 is fitted therein.

  Further, in order to further improve the light collection efficiency, a diffused reflection material (not shown) made of, for example, titanium oxide is optically bonded to the side end surface of the scintillator portion 1 where the first to third light guide portions are not arranged. The fluorescence that collects on the side end surfaces in contact with the first to third light guide portions increases.

The light condensing characteristics of the light guide group A according to the present invention and a conventional light guide made of a single wavelength conversion material (hereinafter referred to as “light guide W”) will be described in comparison.
The conventional light guide W internally absorbs the fluorescence from the scintillator unit 1 and re-emits longer-wavelength fluorescence, and the fluorescent light mainly satisfies the total reflection condition. Compared with the acrylic material, an average higher light collection efficiency can be obtained.

  However, as described above, in the light guide W made of a single wavelength conversion material, for example, as shown in FIG. 3, the amount of light reaching the photoelectric conversion unit 5 is reduced mainly depending on the distance due to self-absorption loss. Since the situation can be seen, there is a problem that the overall detection sensitivity decreases as the detection surface size is increased.

  On the other hand, in the radiation detector according to the present embodiment, the second light guide portion 3 made of the wavelength conversion material is disposed in a region farther from the photoelectric conversion portion 5, and on the end face of the second light guide portion 3 from the middle. The first light guide portion 2 made of a transparent member is optically bonded to suppress self-absorption of the total reflection transmission component of the fluorescence from the second light guide portion 3 toward the first light guide portion 2.

  On the other hand, the fluorescent light incident on the side surface of the first light guide part 2 is emitted again to the outside because the total reflection condition is not satisfied inside the first light guide part 2 from the critical angle at the time of incidence. For this reason, as shown in FIG. 1, the third light guide portion 11 made of a fluorescent conversion material is arranged on the side surface of the first light guide, so that the total reflection transmission is performed in the condensing region on the side end surface of the first light guide portion 2. Can do.

  The third light guide portion 11 may be disposed on the scintillator portion 1 side of the first light guide portion 2 as shown in FIG. 1, or on the opposite side of the scintillator portion 1 as shown in FIG. You may arrange. In this case, since the fluorescence of the scintillator unit 1 passes through the first light guide unit 2 and is absorbed by the third light guide unit 11, the same effect as that of FIG. 1 is obtained.

  Moreover, it is desirable that the side surfaces of the first light guide portion 2 and the third light guide 11 are in close contact via an air layer. When the side surfaces are optically bonded, the total reflection component in the third light guide is also incident on the first light guide unit 2, and the total reflection component incident on the first light guide unit 2 reaches the photoelectric conversion unit 5. This requires an extra distance to increase transmission loss.

  The length of each of the first to third light guides 11 does not contribute to the improvement of detection efficiency when the number of photons reaching the photoelectric conversion unit 5 exceeds a certain amount. The lengths of the first to third light guides 11 are adjusted so as to be maximized.

Further, it is desirable that the surfaces of the first to third light guide portions be mirror-polished so as to eliminate small irregularities on the surface in order to suppress a reduction in the efficiency of total reflection transmission within the light guide portion.
Further, the side surfaces of the scintillator portions that are in close contact with the first to third light guide portions 2, 3, and 11 are also mirror-polished, so that the adhesion is enhanced and fluorescence scattering can be suppressed.

  The cross-sectional shapes of the rod-shaped first to third light guide portions can be various shapes, but considering the workability, a rectangular shape that is easy to process is good, and adhesiveness can be achieved by aligning the apertures of each other. This increases the propagation loss of fluorescence, facilitates fixing after placement, and reduces the cost.

Further, when the end faces of the first light guide 2 and the third light guide 11 are optically joined to the photoelectric conversion unit 5, if the diameters of both do not match, the light guide unit 15 shown in FIG. Can be received by the photoelectric conversion unit 5 efficiently.
Furthermore, since the surface of the light adapter part 15 can suppress the component which comes out by scattering if mirror polishing is given, condensing efficiency improves.

  Further, by excluding a portion where the first light guide 2, the third light guide 11, and the photoelectric conversion unit 5 of the light adapter unit 15 are optically joined, for example, titanium oxide is applied as a diffusely reflecting material to the surface, so that the light adapter unit 15 Since the fluorescence can be confined inside, the light collection efficiency is improved.

  The reflective material 4 that is optically bonded to the end faces of the second light guide portion 3 and the third light guide portion 11 is preferably a highly reflective material that provides a specular reflection effect. For example, a reflective coating by chemical treatment or the like is applied. Although most effective, for example, good reflective performance can be easily obtained by optically bonding an aluminum deposited film (such as an aluminum mylar film).

  The photoelectric conversion unit 5 is preferably a photomultiplier tube designed to obtain high quantum efficiency in the fluorescence wavelength band that is in the ultraviolet region. For example, a photomultiplier tube for photon measurement manufactured and sold by Hamamatsu Photonics Co., Ltd. may be used that has suitable wavelength sensitivity and size. The photomultiplier tube is used by supplying a high voltage of about 1000 V to the dedicated bleeder resistance circuit from the high-voltage power supply unit 10 in order to ensure quantum efficiency for converting light into electrons by the photoelectric effect.

Next, the function of the signal processing unit will be described.
The electrical signal output from the photoelectric conversion unit 5 includes a noise component generated by the photoelectric conversion unit 5 itself, a signal component due to radiation to be measured, or a signal component (interfering component) of unintended radiation. Since the electrical signal controls the material and thickness of the scintillator unit 2 so as to obtain high sensitivity to the radiation to be detected in advance, the signal wave height of the detected radiation is sufficiently higher than the wave heights of the other signal components. Is getting bigger. For this reason, the wave height discriminating unit 6 sets a wave height threshold value in advance in order to discriminate the radiation signal to be detected from other signal components, and outputs a single pulse when the signal wave height exceeds the threshold value. It becomes a pulse.

  Furthermore, since the pulses due to radiation are synchronous, the coincidence counting unit 7 discriminates noise components produced by the photoelectric conversion unit 5 itself by outputting one pulse only when two or more pulses come simultaneously. it can. The pulses output from the coincidence unit 7 are counted by the contamination determination processing unit 8, and the net count rate is obtained by subtracting the background count rate obtained in advance from the count rate obtained by dividing the count value by the measurement time. Is calculated, the contamination count rate set in advance is compared with the net count rate, and the presence or absence of contamination and the net count rate are output and displayed on the display unit 10.

  In the above-described embodiment, the example in which the light guide group A is arranged on the two opposite sides of the scintillator unit 1 has been described. However, the light guide group A may be arranged on only one side, and the same operation as described above. There is an effect.

  As described above, according to the radiation detector according to the first embodiment, a light guide group that combines a light guide portion made of a transparent member and a light guide portion made of a fluorescent conversion material is used to collect light. Efficiency can be increased, and as a result, a radiation detector that is thin, has a large detection area, and is highly sensitive can be provided.

(Second Embodiment)
A radiation detector according to a second embodiment of the present invention will be described with reference to FIGS.
In describing the second embodiment, the description of the same parts as those in the first embodiment is omitted.

  The radiation detector 20 of the radiation detector according to the second exemplary embodiment includes a scintillator 1 that emits fluorescence upon incidence of radiation, and a first light guide 2 and a fourth light guide 12 that are made of a rod-shaped transparent member. And a second light guide part 3, a third light guide part 11 and a fifth light guide part 13 made of a fluorescence conversion material, a reflection part 4, and a photoelectric conversion part 5.

  The end surfaces of the first light guide portion 2 and the fourth light guide portion 12 are optically joined to both end faces of the second light guide portion 3, respectively, and further, the third light guide is attached to the side surface of the first light guide portion 2. The part 11 is in close contact with the side surface of the fourth light guide part 12 in parallel with the fifth light guide part 13 through the air layer.

  These light guide groups B (light guide groups including first to fifth light guide portions) are arranged in close contact with opposing side surfaces of the scintillator portion 1 as shown in FIG. 4 or FIG. In addition, the photoelectric conversion unit 5 is optically joined to the end surfaces of the first light guide unit 2 and the third light guide unit 11 and the end surfaces of the fourth light guide unit 12 and the fifth light guide unit 13, and the third light guide unit 11. The reflective material 4 is optically bonded to the other end face of the fifth light guide portion 13.

  The radiation detection unit 20 (scintillator unit 1, light guide group B, reflector 4, photoelectric conversion unit 5) is entirely covered with a light-shielding film (not shown) as in the first embodiment. .

  The side end surface of the scintillator unit 1 made of plastic scintillator and the side surfaces of the first to fifth light guide units are in close contact with each other through an air layer, optically bonded, or more practically used. The side surfaces of the first to fifth light guide portions are processed into a concave shape and are joined by a method in which the scintillator portion 1 is fitted therein.

  While the light guide W having the light guide made of a single wavelength conversion material has the above-described problems, in the second embodiment, as shown in FIG. 4 or FIG. A second light guide portion 3 made of a wavelength conversion material is disposed in the center of the scintillator portion 1 which is farthest from the portion 5, and the first light guide portion 2 made of a transparent member and the second light guide portion 3 are arranged on both end faces of the second light guide portion 3. The four light guide parts 12 are optically joined to suppress self-absorption of the total reflection transmission component of the fluorescence from the second light guide part 3 toward the first light guide part 2 and the fourth light guide 12.

  On the other hand, the fluorescence that has entered the side surface of the first light guide part 2 is emitted to the outside again without satisfying the total reflection condition inside the first light guide part 2 from the critical angle at the time of incidence. For this reason, as shown in FIG. 1, the third light guide portion 11 made of a fluorescent conversion material is arranged on the side surface of the first light guide, so that the total reflection transmission is performed in the condensing region on the side end surface of the first light guide portion 2. Can do.

  In FIG. 4, the positions of the third light guide part 11 and the fifth light guide part 13 are arranged on the scintillator part 1 side. However, as shown in FIG. Even if the light guide part 13 is arranged on the opposite side of the scintillator part 1, the fluorescence of the scintillator part 1 is transmitted through the first light guide part 2 or the fourth light guide part 12, and the third light guide part 11 and the fifth light guide part 11 Since it is absorbed by the light guide part 13, the same effect is acquired.

  In addition, if the number of photons reaching the photoelectric conversion unit 5 exceeds a certain amount, it does not contribute to improvement in detection efficiency. Therefore, the first to fifth light guides are set so that the minimum amount of light reaching the photoelectric conversion unit 5 is maximized. Adjust the length of the section.

  Further, the surface of the light adapter portion 15 is a diffusely reflecting material except for the first light guide 2 and the third light guide 11 or the fourth light guide portion 12 and the fifth light guide portion 13 and the portion optically joined to the photoelectric conversion portion 5. For example, by applying titanium oxide, the fluorescence can be confined in the light adapter unit 15, so that the light collection efficiency is improved.

  In the above-described embodiment, the example in which the light guide group B is arranged on the two opposite sides of the scintillator unit 1 has been described. However, the light guide group B may be arranged on only one side, and the same operation as described above. There is an effect.

  According to the radiation detector according to the second embodiment, by using a light guide group in which two light guide portions made of a transparent member and three light guide portions made of a fluorescence conversion material are used, The light efficiency can be further increased. As a result, it is possible to provide a radiation detector that is thin, has a large detection area, and is highly sensitive.

(Third embodiment)
A radiation detector according to a third embodiment of the present invention will be described with reference to FIG.
In describing the third embodiment, the description of the same parts as those in the first and second embodiments is omitted.

  The radiation detector 20 of the radiation detector according to the third exemplary embodiment divides the scintillator 1 that emits fluorescence upon incidence of radiation into four crosses 1a to 1d in a cross shape and forms cross-shaped boundary surfaces that contact each other. A light shielding plate 14 that shields fluorescence is disposed. Around the scintillator portion 1, a first light guide portion 2 made of a rod-shaped transparent member, and a second light guide portion 3 and a third light guide portion 11 made of a fluorescent conversion material are arranged.

  The end surfaces of the first light guide part 2 and the second light guide part 3 are optically bonded to each other, and the third light guide part 11 is in close contact with the side surface of the second light guide part 3 in parallel via the air layer. .

  As shown in FIG. 6, the light guide group A (the light guide group including the first to third light guide parts) is divided into four parts on the outer sides of the scintillator parts 1a to 1d. (2) The light guide part 3 is arranged in close contact so that the end face position is in the same circumferential direction. That is, the light guide group A arranged on one side of the flat plate scintillator 1 is arranged so as to be 90 degrees rotationally symmetric with respect to the light guide group A arranged on the adjacent side.

  Photoelectric converters 5a to 5d that detect fluorescence and convert it into electric pulses are optically joined to the end faces of the first light guide part 2 and the third light guide part 11, and the other end face of the third light guide part 11 and the second light guide part 11 The reflecting material 4 is optically bonded to the end face of the two light guide portions 3.

  These radiation detection units 20 (scintillator units 1a to 1d, light guide group A, reflecting material 4, and photoelectric conversion unit 5) are entirely light-shielding films (not shown) as in the first and second embodiments. ).

  In general, when the size of the scintillator is increased, the incident probability of background radiation (cosmic rays or the like) increases in proportion to the area, and the background value increases. For this reason, in this 3rd Embodiment, the background value by a background radiation can be lowered | hung, maintaining the area of the whole scintillator part by dividing | segmenting a scintillator part surface into plurality.

  As the scintillator portions 1a to 1d, a plastic scintillator that is excellent in workability, easy to obtain, and easy to handle is optimal. A light shielding plate 14 capable of completely shielding the scintillator fluorescence is interposed on the boundary surface where the cross-divided portions of the scintillator portions 1a to 1d contact each other so as to be perpendicular to the surface of the scintillator. Prevents scintillator fluorescence from entering.

  For example, in order to suppress sagging of the light shielding film, a reinforcing material capable of shielding the cross-shaped fluorescent light provided at the same upper and lower positions as the cross portions of the scintillator portions 1a to 1d is connected to the light shielding plate 14. (Not shown) Since the space of the upper and lower surfaces of the scintillator portions 1a to 1d can be optically independent, it is possible to further prevent the fluorescence of other scintillators from being mixed.

  Fluorescence emitted inside the scintillator portions 1a to 1d by the incidence of radiation spreads uniformly at an isotropic angle, and those satisfying the total reflection condition are emitted from the side edges of the entire periphery by internal capture. As shown in FIG. 6, the four light guide groups A are arranged in the same direction with respect to the circumferential direction to collect the fluorescence collected on the side end surfaces of the scintillator portions 1a to 1d.

  The side end surface of the scintillator unit 1 made of plastic scintillator and the side surfaces of the first to third light guide units are in close contact with each other through an air layer, optically bonded, or more practically used. The side surfaces of the first to third light guide portions are processed into a concave shape, and the scintillator portions 1a to 1d are fitted therein by joining them.

  In addition, in order to further improve the light collection efficiency, the fluorescent light gathers on the side end surface in contact with the light guide A when an irregularly reflecting material made of, for example, titanium oxide is optically bonded to the cross-shaped boundary surfaces of the scintillators 1a to 1d. To increase.

Further, in the third embodiment, the noise component produced by the photoelectric conversion unit 5 itself can be discriminated by outputting one pulse only when two or more pulses come simultaneously in the coincidence counting unit 7. Therefore, the position of the radiation can be detected by taking the following coincidence count.
Photoelectric conversion unit 5a and photoelectric conversion unit 5b = scintillator 1a
Photoelectric converter 5b and photoelectric converter 5c = scintillator 1b
Photoelectric converter 5c and photoelectric converter 5d = scintillator 1c
Photoelectric converter 5d and photoelectric converter 5a = scintillator 1d

  The pulses output from the coincidence unit 7 are counted by the contamination determination processing unit 8, and the net count rate is obtained by subtracting the background count rate obtained in advance from the count rate obtained by dividing the count value by the measurement time. Is calculated, the contamination count rate set in advance is compared with the net count rate, and the presence or absence of contamination and the net count rate are output and displayed on the display unit 10.

  As described above, according to the third embodiment, while maintaining the thin structure of the conventional radiation detector, high detection sensitivity can be obtained even if the detection area is increased, and background radiation and the like can be obtained. The ground value can be lowered.

  According to the radiation detector according to the third exemplary embodiment, the scintillator includes a light guide group in which a scintillator portion divided into a cross shape is used and a light guide portion made of a transparent member and a light guide portion made of a fluorescent conversion material are combined. Because it is arranged on each side of the unit, it is possible to further increase the light collection efficiency and to detect the position of the radiation. As a result, the radiation detector is thin, has a large detection area, and can detect the position with high sensitivity. Can be provided.

1 is an overall configuration diagram showing a radiation detector according to a first embodiment of the present invention. The whole block diagram which shows the modification of the radiation detector which concerns on the 1st Embodiment of this invention. The characteristic view of the light guide group A which concerns on the 1st Embodiment of this invention. The whole block diagram which shows the radiation detector which concerns on the 2nd Embodiment of this invention. The whole block diagram which shows the radiation detector which concerns on the 2nd Embodiment of this invention. The whole block diagram which shows the radiation detector which concerns on the 3rd Embodiment of this invention. The figure which shows the light adapter part which concerns on the 1st thru | or 3rd embodiment of this invention. The whole block diagram of the conventional radiation detector.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Scintillator part, 2 ... 1st light guide part, 3 ... 2nd light guide part, 4 ... Reflection part, 5 ... Photoelectric conversion part, 6 ... Wave height discrimination part, 7 ... Simultaneous counting part, 8 ... Contamination determination processing part , 9: Display unit, 10: High voltage power supply unit, 11: Third light guide unit, 12: Fourth light guide unit, 13: Fifth light guide unit, 14: Light shielding plate, 15: Light adapter unit, 16: Light Guide, 20 ... radiation detector, 30 ... signal processor.

Claims (9)

A flat plate scintillator that emits fluorescence upon incidence of radiation, a light guide group that collects the fluorescence provided on at least one side of the scintillator unit, and a photoelectric converter that converts the light collected by the light guide group A radiation detector comprising: a signal processing unit that detects and determines the presence or absence of contamination,
The light guide unit is in close contact through the first light guide portion of the rod-like formed of a transparent member, a second light guide portion of the rod-shaped made of fluorescent conversion material, an air layer side surface of the first light guide portion a third light guide section of the rod-shaped made of fluorescent conversion material has, Ri Tona,
One end surface of the first light guide portion is optically bonded to one end surface of the second light guide portion,
The other end face of the first light guide part and one end face of the third light guide part are optically joined to the photoelectric converter,
A reflective material is optically bonded to the other end surface of the third light guide portion and the other end surface of the second light guide portion,
The third light guide portion is disposed on the opposite side of the scintillator portion with respect to the first light guide portion, and the side surfaces of the first light guide portion and the second light guide portion are the flat plate-like scintillator portions. A radiation detector characterized by being in close contact with one side . A flat plate scintillator that emits fluorescence upon incidence of radiation, a light guide group that collects the fluorescence provided on at least one side of the scintillator unit, and a photoelectric converter that converts the light collected by the light guide group A radiation detector comprising: a signal processing unit that detects and determines the presence or absence of contamination,
The light guide group includes a rod-shaped first light guide portion and a fourth light guide portion made of a transparent member, and a rod shape made of a fluorescent conversion material disposed between the first light guide portion and the fourth light guide portion. The second light guide part, and the rod-like third light guide part and the fifth light guide part made of a fluorescent conversion material that are in close contact with the side surfaces of the first light guide part and the fourth light guide part via an air layer, respectively. and, Ri Tona,
Both end surfaces of the second light guide portion are optically joined to one end surfaces of the first light guide portion and the fourth light guide portion, respectively.
The photoelectric converter is optically coupled to the other end surface of the first light guide portion and one end surface of the third light guide portion, and to the other end surface of the fourth light guide portion and one end surface of the fifth light guide portion. Joined and
Reflective materials are optically bonded to the other end surfaces of the third light guide portion and the fifth light guide portion, respectively.
The third light guide part and the fifth light guide part are disposed on the opposite side of the scintillator part with respect to the first light guide part and the fourth light guide part, respectively, and the second light guide part and the third light guide part A radiation detector, wherein the side surfaces of the light guide part and the fourth light guide part are in close contact with one side of the flat scintillator part . The light guide group disposed on one side of the scintillator is disposed so as to be 180 degrees rotationally symmetric with respect to the light guide group disposed on the opposite side. The radiation detector according to 1 or 2 . The radiation detector according to any one of claims 1 to 3 , wherein an irregularly reflecting material is optically connected to a side end surface of the side where the light guide group of the scintillator portion is not disposed. A plate-like scintillator that emits fluorescence upon incidence of radiation, a light guide group that is provided on each side of the scintillator unit to collect the fluorescence, and a photoelectric converter that converts the light collected by the light guide group A radiation detector comprising: a signal processing unit that detects and determines the presence or absence of contamination,
The light guide unit is in close contact through the first light guide portion of the rod-like formed of a transparent member, a second light guide portion of the rod-shaped made of fluorescent conversion material, an air layer side surface of the first light guide portion A rod-shaped third light guide portion made of a fluorescent conversion material,
The scintillator portion is divided into a cross shape and a light shielding plate is optically bonded to the boundary surface ,
One end surface of the first light guide portion is optically bonded to one end surface of the second light guide portion,
The other end face of the first light guide part and one end face of the third light guide part are optically joined to the photoelectric converter,
Reflectors are optically bonded to the other end surfaces of the second light guide part and the third light guide part, respectively.
The third light guide portion is disposed on the opposite side of the scintillator portion with respect to the first light guide portion, and the side surfaces of the first light guide portion and the second light guide portion are the flat plate-like scintillator portions. A radiation detector characterized by being in close contact with one side . The light guide group disposed on one side of the scintillator is disposed so as to be 90 degrees rotationally symmetric with respect to the light guide group disposed on an adjacent side. 5. The radiation detector according to 5 . The length of each of the first to fifth light guide portion, any one of claims 1 to 6 minimum light amount detected by the photoelectric conversion unit is characterized in that it is set to be maximum The radiation detector according to item 1. The signal processing unit performs simultaneous counting processing of a signal pulse from a photoelectric conversion unit for converting into an electric signal, a wave height discriminating unit for discriminating a signal and noise from the electric signal of the photoelectric conversion unit, and a previous wave height discriminating unit The contamination determination processing unit for determining presence / absence of contamination from a pulse rate from the coincidence counting unit, the coincidence counting unit, and a display unit for displaying a result of the contamination determination processing unit. the radiation detector according to any one of 1 to 7. The radiation detector according to any one of claims 1 to 8 , wherein a light adapter is provided between the photoelectric conversion unit and a light guide unit connected to the photoelectric conversion unit.

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