JP2007248408A - Radiation detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the number of installed photodetectors while having a large area of thin detecting face. <P>SOLUTION: A band-like body comprising a plurality of scintillator fibers arrayed in parallel is provided with sheet-like bodies formed foldedly once or plurality of times not to be overlapped in at least one part, the photodetectors connected to a terminal end of the band-like body, and a sheet-like light reflecting material provided overlappedly on the sheet-like body. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a radiation detector capable of reducing the number of installed photodetectors while being a thin radiation detector having a large-area detection surface.

  As shown in FIG. 5, a conventional radiation detector 1 having a thin and large-area detection surface made of a scintillator fiber has a strip-like body made of a scintillator fiber 2 coated with a sheet made of a fluororesin or barium sulfate. A plurality of light reflecting members 3 are arranged side by side (Patent Document 1).

  Similarly, the radiation detector 1 made of a sheet-like plastic scintillator or NaI (Tl) scintillator having a detection surface with a large area as shown in FIG. A plurality of sheets are arranged side by side on the opposite surface to the detection surface of the sheet-like scintillator 3 ′ (Patent Document 2).

In these radiation detectors 1, a pair of photodetectors 4 are provided at both ends of a bundle of scintillator fibers 2 or wavelength conversion fibers 2 ′ in order to remove electrical noise.
JP-A-7-35867 JP2003-4886

  However, in such a configuration, one pair of photodetectors 4 is required for each bundle of scintillator fiber 2 and wavelength conversion fiber 2 ', so that the detection system becomes complicated and there is a problem in terms of cost and maintenance.

  Therefore, the present invention is intended to provide a simple radiation detector by reducing the number of installed photodetectors while having a thin and large-area detection surface.

  That is, the radiation detector according to the present invention comprises a sheet-like body formed by folding one or more times so that at least one part of a strip-like body composed of a plurality of scintillator fibers arranged in parallel does not overlap, It is provided with the photodetector connected to the terminal of a strip | belt-shaped body, and the sheet-like light reflection material provided in piles on the said sheet-like body.

  If this is the case, it is possible to use the photodetector by reducing the number of scintillator fibers without changing the number of scintillator fibers constituting the radiation detection surface (that is, the area of the detection surface). In addition to simplifying the detection system by reducing the number, the inspection surface can be covered with fibers of the same quality, improving performance and maintainability. Also, the longer the length of the scintillator fiber, the lower the transmission efficiency of fluorescence derived from radiation, but by providing a light reflecting material over the scintillator fiber and returning the fluorescence leaked from the scintillator fiber back into the scintillator fiber , Fluorescence transmission loss can be minimized.

  In addition, the surface of the scintillator fiber and the associated light reflecting material is appropriately folded to form a three-dimensional shape and surround the periphery of the object to be inspected, so that radiation can be detected in all directions on the peripheral side surface. Increase can be achieved.

  When the length of the scintillator fiber is long, in order to suppress the transmission loss of fluorescence, an integrating sphere is provided in addition to the light reflecting material, and the end of the strip is connected to the photodetector through the integrating sphere. There may be.

  With this configuration, the fluorescence transmitted through the scintillator fiber is once condensed by an integrating sphere and then introduced into the photodetector, thereby further suppressing the fluorescence transmission loss.

When the number of scintillator fibers constituting the radiation detection surface is the same, increasing the number of turns using a long scintillator fiber can reduce the number of photodetectors. It is preferably folded.

  In the radiation detector according to the present invention, a wavelength conversion fiber may be used instead of the scintillator fiber, and a sheet-like scintillator may be used instead of the light reflecting material. That is, a strip-like body composed of a plurality of wavelength conversion fibers arrayed in parallel is connected to the end of the strip-like body, and a sheet-like body formed by folding one or more times so that at least one part does not overlap. The present invention also includes a radiation detector provided with a photodetector and a sheet-like scintillator provided on the sheet-like body.

  Since the wavelength conversion fiber is made of a material having a higher light transmission efficiency than the scintillator, the fluorescence generated by the scintillator is further transmitted to the wavelength conversion fiber to change the wavelength of the fluorescence to reach the photodetector. Can be transmitted to the photodetector with high transmission efficiency. Even in such a radiation detector, the number of photodetectors can be reduced by folding the wavelength conversion fiber. Can do.

  As the sheet-like scintillator, for example, a plastic scintillator or a NaI (Tl) scintillator can be used.

  Plastic scintillators can be molded thinly, so they are suitable for transmitting only γ rays with strong penetrating power and selectively detecting only β rays. NaI (Tl) scintillators efficiently receive the energy of γ rays. be able to.

  As described above, according to the present invention, in a thin radiation detector having a large detection area using a light transmission fiber such as a scintillator fiber or a wavelength conversion fiber, the number of photodetectors can be reduced while maintaining the function of removing electrical noise. it can.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the radiation detector 1 according to the first exemplary embodiment includes a sheet-like body formed by folding the strip-like body composed of a plurality of scintillator fibers 2 arranged in parallel so as not to overlap each other. And a light reflecting material 3 arranged so as to overlap the sheet-like body, and a photodetector 4 is connected to the end of the belt-like body.

  Each part will be described below. As the scintillator fiber 2, a fiber-shaped plastic scintillator is used. A plurality of parallel scintillators are arranged in parallel to form a belt-like body having a certain width. The sheet is combined to form a radiation detection surface.

  The scintillator fiber 2 has a diameter of about 0.1 to 3 mm, and transmits γ-rays with strong transmission power, so that only β-rays are selectively detected. When β rays are incident on the scintillator fiber 2, the encapsulated scintillation substance receives energy from the β rays and emits fluorescence.

  The light reflecting material 3 is made of a sheet made of a fluororesin or a plastic sheet coated with barium sulfate, and is placed on a sheet-like body made of the scintillator fiber 2, and outside the fluorescence emitted by the scintillator fiber 2. The leaked one is reflected and returned to the inside of the scintillator fiber 2 again.

  The light reflecting material 3 and the sheet-like body made of the scintillator fiber 2 are fixed to each other with an installation agent or the like, and the light reflecting material 3 also functions as a support for the scintillator fiber 2.

  A photo detector 4 made of a photomultiplier tube (PMT) is connected to the end of the strip made of the scintillator fiber 2, and the photo detector 4 converts the fluorescence transmitted from the scintillator fiber 2 into an electric signal. . In this embodiment, two sets of strips made of scintillator fibers 2 are used, and therefore four photodetectors 4 are used.

  As shown in FIG. 2, by incorporating the radiation detector 1 according to the present embodiment into a radioactivity measuring apparatus 10 including a coincidence counting circuit 11 and an arithmetic circuit 12, a β-ray measuring apparatus can be configured.

  At this time, the radiation detector 1 is covered with a light shielding film (not shown) so that light from the outside does not enter.

  As shown in FIG. 2, when the radiation detector 1 of this embodiment is used as a radiation detector of a radioactivity measuring apparatus 10 including a coincidence counting circuit 11 and an arithmetic circuit 12, fluorescence is converted by the photodetector 4. The generated electric signal is output to the coincidence counting circuit 11. The electrical signal output from the photodetector 4 includes not only the electrical signal converted from the β-ray fluorescence but also electrical noise, but it is connected to the end of the strip made of the same scintillator fiber 2. Although the timings of the electrical signals derived from the β rays output from the pair of photodetectors 4 match, the timings of the electrical noises output from the photodetectors 4 do not match. Using this, the coincidence circuit 11 discriminates between electrical noise and electrical signal, removes electrical noise and extracts only the electrical signal derived from β-rays detected by the radiation detector 1 to obtain β A line detection signal is output. In FIG. 2, a bundle of a plurality of scintillator fibers 2 is omitted as one.

  The arithmetic circuit 12 calculates the measured value of radioactivity from the total number of β-ray detection signals counted by the coincidence circuit 11. The arithmetic circuit 12 may be further connected to a display device or a recording device, and may be configured to display or record the measured radioactivity value.

  According to this embodiment, even if the number of scintillator fibers 2 constituting the radiation detection surface (the area of the detection surface) is the same as in the conventional example shown in FIG. Can be reduced from eight to four. Further, although the transmission efficiency of the fluorescence derived from β rays decreases as the length of the scintillator fiber 2 increases, it is sufficient that at least it can be identified that the fluorescence is derived from β rays. By providing the reflective material 3, fluorescence transmission loss can be minimized.

  In the radiation detector 1 according to the second embodiment, as shown in FIG. 3, the strip-shaped body composed of a plurality of scintillator fibers 2 arranged in parallel is folded three times so as not to overlap, and the sheet-shaped body is formed. It is formed.

  In this embodiment, the number per bundle is the same as in the first embodiment, but a scintillator that forms a radiation detection surface by using a longer scintillator fiber 2 and increasing the number of turns. While the number of fibers 2 (the area of the detection surface) is made equal, the number of photodetectors 4 is reduced from four to two. In addition, it is preferable that the length of the scintillator fiber 2 is 3 m or less from light transmission efficiency.

  As the scintillator fiber 2 becomes longer, the light transmission efficiency decreases. However, in addition to the light reflector 3, an integrating sphere 5 is provided between the end of the scintillator fiber 2 and the photodetector 4, so that the scintillator fiber 2 By condensing the fluorescence transmitted through the inside and then transmitting it to the photodetector 4, the transmission loss of the fluorescence is suppressed.

  According to the present embodiment, the number of photodetectors 4 can be further reduced while maintaining the area of the radiation detection surface. Then, the transmission loss of the fluorescence accompanying the increase in the length of the scintillator fiber 2 is added to the light reflecting material 3, and the fluorescence is condensed using the integrating sphere 5 and then transmitted to the photodetector 4. Can be minimized.

  Both the first embodiment and the second embodiment described above relate to the β-ray detector provided with the scintillator fiber 2, but the configurations are the same as those embodiments, but FIG. 1 and FIG. As shown, by using the wavelength conversion fiber 2 ′ instead of the scintillator fiber 2, using the sheet-like scintillator 3 ′ instead of the light reflecting material 3, and configuring the radiation detection surface with the sheet-like scintillator 3 ′, If the sheet-like scintillator 3 ′ is a plastic scintillator, a β-ray detector can be constructed. If the sheet-like scintillator 3 ′ is a NaI (Tl) scintillator, a γ-ray detector can be constructed.

  At this time, a thin plastic scintillator of about 0.1 to 0.3 mm is used. As a result, γ-rays with strong penetrating power are transmitted and only β rays are selectively detected.

  On the other hand, as the NaI (Tl) scintillator, a thick type having a thickness of about 1 cm is used.

  The wavelength conversion fiber 2 ′ is disposed in close contact with the surface opposite to the detection surface of the sheet-like scintillator 3 ′, and generates fluorescence having a wavelength different from that when the fluorescence generated by the sheet-like scintillator 3 ′ enters. Then, the fluorescence is transmitted in the fiber axial direction. The wavelength conversion fiber 2 'is made of a material having a higher light transmission efficiency than the sheet-like scintillator 3'.

  Both ends of the band-shaped body made of the wavelength conversion fiber 2 'are connected to the photodetector 4, and the photodetector 4 converts the fluorescence transmitted from the wavelength conversion fiber 2' into an electrical signal. In the embodiment shown in FIG. 3, the fluorescence transmitted from the wavelength conversion fiber 2 ′ is once condensed by the integrating sphere 5 and then introduced into the photodetector 4.

  When β-rays or γ-rays are incident on the sheet-like scintillator 3 ′, the scintillation substance that receives energy from the radiation emits fluorescence, and the wavelength conversion fiber 2 ′ disposed in the vicinity of the light emission site receives the fluorescence. Fluoresce with different wavelengths. Since light is emitted isotropically in the wavelength conversion fiber 2 ′ where the fluorescence is generated, the generated fluorescence is transmitted through the wavelength conversion fiber 2 ′, reaches the photodetector 4, and is converted into an electrical signal. As shown in FIG. 2, the radiation detector 1 according to these embodiments can also be configured as a β-ray measuring device or a γ-ray measuring device by being incorporated in the radioactivity measuring device 10.

  Also in these embodiments, the number of installed photodetectors 4 can be reduced without changing the number of wavelength conversion fibers 2 ′ that transmit fluorescence derived from radiation.

  The present invention is not limited to the above embodiment. For example, the number of turns of the scintillator fiber 2 and the wavelength conversion fiber 2 'can be set as appropriate within the range allowed by the curvature of each fiber. Also, the number of scintillator fibers 2 can be selected as appropriate.

  Further, the β-ray detector and the γ-ray detector according to the present invention may be used in an overlapping manner. In this case, the β-ray detector is arranged on the measurement object side, and the γ-ray detector is arranged outside thereof.

  The radiation detector according to the embodiment may be bent so as to have a three-dimensional structure as shown in FIG. FIG. 4A shows the scintillator fiber 2 bent so that the bundle of a plurality of scintillator fibers 2 is omitted as one, and the light reflecting material 3 is on the outside (inspected object side). FIG. 4 (b) shows a mode, in which the sheet-like scintillator 3 ′ is inside, and the wavelength conversion fiber 2 ′ (a bundle of a plurality of wavelength conversion fibers 2 ′ is omitted as one) is shown. The aspect bent so that it might become the outer side is shown. In such a case, radiation can be detected not only from one surface but also from the surrounding side surface, and the maximum signal can be obtained. FIG. 4 shows the three-dimensional structure formed by bending the radiation detector according to the second embodiment, but the radiation detector according to the first embodiment is also configured three-dimensionally in the same manner. can do.

  In addition, it goes without saying that the present invention can be variously modified without departing from the spirit of the present invention.

1 is a schematic plan view of a radiation detector according to an embodiment of the present invention. The schematic schematic diagram of the radioactivity measuring apparatus incorporating the radiation detector which concerns on the same embodiment. The typical top view of the radiation detector concerning other embodiments of the present invention. The typical perspective view of what constituted the radiation detector concerning the embodiment three-dimensionally (example of a rectangular parallelepiped). The typical top view which shows one Embodiment of the conventional radiation detector.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Radiation detector 2 ... Scintillator fiber 3 ... Light reflecting material 4 ... Photo detector

Claims (8)

A sheet-like body formed by folding once or a plurality of times so that at least a part of a strip-like body composed of a plurality of scintillator fibers arranged in parallel does not overlap;
A photodetector connected to the end of the strip;
A radiation detector comprising: a sheet-like light reflecting material provided to overlap the sheet-like body.   The radiation detector according to claim 1, wherein an end of the strip is connected to a photodetector through an integrating sphere.   The radiation detector according to claim 1, wherein the belt-like body is folded twice or more. A sheet-like body formed by folding once or a plurality of times so that at least a part of a band-shaped body composed of a plurality of wavelength conversion fibers arranged in parallel does not overlap;
A photodetector connected to the end of the strip;
A radiation detector, comprising: a sheet-like scintillator provided to overlap the sheet-like body.   The radiation detector according to claim 4, wherein the sheet-like scintillator is a plastic scintillator or a NaI (Tl) scintillator.   The radiation detector according to claim 4 or 5, wherein an end of the strip is connected to a photodetector through an integrating sphere.   The radiation detector according to claim 4, 5 or 6, wherein the strip is folded twice or more. The radiation detector according to claim 1, 2, 3, 4, 5, 6 or 7, wherein the sheet-like body and the accompanying surface of the sheet-like light reflecting material or the sheet-like scintillator form a three-dimensional structure. .