JP2008157846A - Radiation detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve detection sensitivity, and to easily specify the detection position of radiation. <P>SOLUTION: A radiation detector comprises: a scintillator 2 in a disk shape or nearly in a disk shape; and a plurality of light detection sections 3 arranged equally at the side peripheral surface of the scintillator 2. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a radiation detector using a scintillator, and more particularly to a radiation detector capable of specifying the incident position of radiation on the scintillator.

The radiation detector of this kind, for example as shown in Patent Document 1, a rectangular photomultiplier tube to the side of the scintillator directly, or in with intervening ride guide such as an optical fiber disposed scintillation Some devices detect light and specify the incident position of radiation.

  However, in the conventional radiation detector, since a photodetector such as a photomultiplier tube is not provided symmetrically with respect to the scintillator, in order to specify the incident position of the radiation, the radiation detector is provided for each photodetector. There is a problem that a calibration curve between the incident position and its light intensity needs to be obtained in advance.

Also, if the scintillator is rectangular, the generated scintillation light is reflected at the corners a plurality of times on the side surface, and the vicinity of the incident area is uniformly emitted and blurred to identify the incident position. There is a problem that it is difficult. Furthermore, this causes a problem that the sensitivity at the corners is lowered and sensitivity correction is required.
JP 2005-91035 A

The present invention has been made to solve at a stroke the above problems, to improve the detection sensitivity as unnecessary sensitivity correction due to the shape of the scintillator, and easily identify the detected position of the radiation The main intended task is to be able to do so.

  That is, the radiation detector according to the present invention includes a disc-shaped or substantially disc-shaped scintillator, and a plurality of light detection units arranged uniformly on a side peripheral surface of the scintillator.

In such a case, a disc-shaped or substantially disc-shaped scintillator is used, and the photodetection portion is evenly arranged on the side peripheral surface thereof, so that the conventionally required corner correction processing is not required. However, the detection sensitivity can be improved and the position resolution can be improved. Further, the above-described configuration, it is possible to identify from a comparison of the plurality of average values of the optical detection unit and the output signals of the light detector, an incident position of easy radiation.

  As a specific embodiment of the light detection unit, the light detection unit is a light detector provided with a light incident surface in contact with a side peripheral surface of the scintillator, and the plurality of light detectors, It is desirable that the scintillators are evenly disposed on the side peripheral surface. In addition, the light detection unit includes a waveguide provided with a tip surface in contact with a side peripheral surface of the scintillator, and a photodetector connected to the other end of the waveguide, It is desirable that the waveguides of the plurality of light detection units are evenly arranged on the side peripheral surface of the scintillator.

  In order to make the effect of the present invention more remarkable, it is desirable that the distal end surface of the waveguide is disposed on the side peripheral surface of the scintillator without a gap.

  As a specific embodiment for specifying the incident position of radiation, the angular direction of the incident position of the radiation is specified from the light detection unit whose detection signal indicates the maximum light intensity, and the maximum light intensity and the plurality of light detection units It is desirable that an incident position specifying unit for specifying the radial position of the incident position of the radiation is provided on the basis of the value relating to the average light intensity indicated by the detection signal from Here, the “value relating to the average” means an average value of the light intensity or a value related to the average value, for example, a sum of the light intensity.

According to thus constituted present invention, it can be identified to improve the detection sensitivity as unnecessary sensitivity correction due to the shape of the scintillator, and the detection position of easy radiation.

  An embodiment of the present invention will be described below with reference to the drawings. 1 is a schematic configuration diagram of the radiation detector 1 according to the present embodiment, FIG. 2 is a schematic cross-sectional view of the radiation detector 1, and FIG. 3 is an information processing apparatus of the radiation detector 1. FIG. 4 is a functional configuration diagram of the information processing apparatus 4.

<Device configuration>
As shown in FIGS. 1 and 2, the radiation detector 1 according to the present embodiment includes a disc-shaped scintillator 2 and a plurality of light detection units 3 that are evenly arranged on the side peripheral surface of the scintillator 2. A calculation device 4 that receives an electrical signal from the photodetector 32 and performs a predetermined calculation, and an image display device 5 that displays a two-dimensional image of radiation based on the calculation result of the calculation device 4 are provided. ing. The scintillator 2 and the light detection unit 3 are covered with a light shielding film (not shown) so that light from the outside does not enter.

  Each part will be described below.

  The scintillator 2 emits scintillation light (fluorescence) when radiation enters. In this embodiment, the scintillator 2 is a NaI (Tl) scintillator or CsI (Tl) scintillator that emits scintillation light when γ rays are incident. The scintillator 2 has a radiation incident surface 21 on which radiation such as γ rays is incident on one surface, and the side peripheral surface is a light emitting surface 22 that emits the scintillation light. The scintillator 21 is a thin one having a thickness of about 0.5 mm. A reinforcing plate (not shown) that reinforces the mechanical strength of the scintillator 2 is provided on the opposite side of the radiation incident surface 21 of the scintillator 2 as necessary.

  Each light detection unit 3 includes a wavelength conversion fiber 31 serving as a waveguide, and a photodetector 32 provided continuously to the wavelength conversion fiber 31.

  The wavelength conversion fiber 31 generates fluorescence having different wavelengths when the scintillation light generated by the scintillator 2 is incident, and transmits the scintillation light in the axial direction. The front end surface is provided in contact with the side peripheral surface of the scintillator 2, and the photodetector 32 is provided at the rear end portion. As shown in FIG. 2, the diameter of the wavelength conversion fiber 31 is approximately the same as or slightly smaller than the thickness of the scintillator 2.

  The wavelength conversion fibers 31 of the plurality of light detection units 3 are evenly disposed on the side peripheral surface of the scintillator 2. More specifically, the distal end surface of the wavelength conversion fiber 31 is disposed on the side peripheral surface of the scintillator 2 without a gap in the circumferential direction.

  The photodetector 32 detects light from the wavelength conversion fiber 31 and converts it into an electrical signal, and is, for example, a photomultiplier tube. In the present embodiment, the electrical signal output from the photodetector 32 is further amplified by an amplifier (amplifier) 7 such as a preamplifier or a main amplifier.

  The information processing apparatus 4 receives an electrical signal from the light detector 32 and calculates the incident position of the radiation, etc. The equipment configuration is as shown in FIG. A general-purpose or dedicated computer including an output interface 403, an AD converter 404, and the like. When the CPU 401 and its peripheral devices operate based on a program stored in a predetermined area of the internal memory 402, FIG. As shown, it functions as a detection signal receiving unit 41, an incident position specifying unit 42, and the like.

  The detection signal receiving unit 41 receives the detection signal from the photodetector 32 and outputs the detection signal to the incident position specifying unit 42.

  The incident position specifying unit 42 specifies the incident position of the radiation to the scintillator 2 based on the detection signal from the photodetector 32 and outputs the position specifying signal to the image display device 5. The image display device 5 displays a two-dimensional image of radiation on the display based on the position specifying signal.

  Specifically, the incident position specifying unit 42 specifies the angular direction of the incident position of the radiation from the light detecting unit whose detection signal indicates the maximum light intensity, and the maximum light intensity and the light intensity indicated by the detection signals from the plurality of light detecting units. And the radial position of the incident position of the radiation is specified.

  First, the identification of the angular direction (azimuth) of the radiation incident position will be described. As shown in FIG. 5, when radiation is incident on the region P of the scintillator 2, as shown in FIG. 6, the photodetector B is the shortest distance from the region P, and all the photodetectors In 32, a detection signal indicating the maximum light intensity is output. From this, the incident position specifying unit 42 specifies the photodetector 32 (photodetector B) exhibiting the maximum intensity, and determines that the photodetector 32 is the photodetector 32 closest to the incident position. The angle direction in which the photodetector 32 (photodetector B) is disposed is determined from the reference photodetector 32 (photodetector A).

  Next, identification of the radial position (distance from the center of the scintillator 2) of the radiation incident position will be described. The incident position specifying unit 42 specifies the radial position of the radiation incident position based on the ratio between the maximum light intensity indicated by the light detector B and the average value of the light intensity indicated by the all light detectors.

  Specifically, the radial position of the incident position is specified as follows.

When the light intensity of the scintillation light generated when radiation is incident on the central portion (center O) of the scintillator 2 is I 2 _O , the light intensity detected by the light detector A and the light detector B is the same. When the light intensity is I _C , the following equation is established from the relationship of light attenuation. However, the radius of the scintillator 2 is r.

I _C = I _O × exp (−λ × r) (Formula 1)

Then, scintillation light radiation occurs when incident on the portion (a region P) with a scintillator 2, if the radiation is the same energy as in the above (Formula 1), an I _O. Then, when the light intensity detected by the photodetector B and I _B, the following equation holds from the relationship of the light attenuation. However, the shortest distance between the incident position and the light detector B of radiation and x.

I _B = I _O × exp (−λ × x) (Formula 2)

By transforming (Equation 2),
I _O = I _B / exp (−λ × x) (Formula 3)

And if (Equation 3) is substituted into (Equation 1),
I _C = I _B × exp (−λ × x) / exp (−λ × r)
I _C = I _B × exp {λ (r−x)}
ln (I _C / I _B ) = λr−λx
λx = λr−ln (I _C / I _B )
x = r−ln (I _C / I _B ) / λ

Therefore, the position in the radial direction of the radiation (the shortest distance x from the photodetector B) is obtained from I _C , I _B , λ, r.

By the way, in the state of (Equation 1) and the state of (Equation 2), since the output I _all of _{all the} photodetectors 32 is the same, when the number of the photodetectors 32 is n,

I _C = I _all / n
You can. From this, without obtaining (Equation 1), from (Equation 2),

_{x = r-ln {I all} / (n × I B)} / λ
Thus, the radial position of the radiation (the shortest distance x from the light detector B) is obtained.

<Effect of this embodiment>
According to the radiation detector 1 according to the present embodiment configured as described above, the disc-shaped scintillator 2 is used, and the light detection unit 3 is disposed without gaps on the side circumferential surface thereof. Thus, it is possible to improve the detection sensitivity while eliminating the corner correction process required in the above.

Moreover, the incident position of the radiation can be specified by comparing the output of the photodetector 32 indicating the maximum light intensity with the average output of the all-light detector 32. Therefore, in the photodetector 32, and the incident position of the radiation, it is possible that it is not necessary to obtain the calibration curve of the light intensity, identifying the detected position of easy radiation.

<Other modified embodiments>
The present invention is not limited to the above embodiment. In the following description, the same reference numerals are given to members corresponding to the above-described embodiment.

  For example, in the embodiment, the scintillator 2 has a disk shape. However, the scintillator 2 may have a substantially disk shape having the effect of the embodiment.

  Moreover, although the radiation detector 1 of the said embodiment was a thing which detects a gamma ray, it may detect a beta ray, an X-ray, etc. in addition. At this time, various scintillators can be used in addition to the NaI (Tl) scintillator and the CsI (Tl) scintillator.

  Furthermore, the wavelength conversion fiber 31 of the above embodiment is disposed without a gap in the circumferential direction of the side circumferential surface of the scintillator 2, but may be disposed with a gap in addition. In this case, the wavelength conversion fibers 31 are arranged uniformly. That is, the distal end surface of the wavelength conversion fiber 31 is provided so as to contact the side peripheral surface of the scintillator 2 at regular intervals in the circumferential direction.

  Further, instead of the wavelength conversion fiber 31, an optical fiber may be used as a waveguide.

  Alternatively, the light detection unit 3 may be composed only of the light detector 32 without using a waveguide. In this case, the light incident surface of the photodetector 32 is provided in contact with the side peripheral surface of the scintillator 2. The photodetectors 32 are evenly arranged on the side peripheral surface of the scintillator 2.

  In addition, in the above-described embodiment, the radiation detector 1 is composed of a single-layer scintillator 2, but a plurality of scintillators 2 may be used to form a multilayer structure. In this case, the plurality of light detection units 3 are equally arranged on the side peripheral surface of the scintillator 2 of each layer. With such a configuration, it becomes possible to detect the irradiation direction of radiation, the amount of radiation energy, and the like.

  In addition, a coincidence counting circuit may be connected to the photodetector 32 so that radiation counting can be performed.

  In addition, some or all of the above-described embodiments and modified embodiments may be combined as appropriate, and the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention. .

The side view of the radiation detector concerning one embodiment of the present invention. The schematic end elevation of the radiation detector in the same embodiment. The equipment block diagram of the information processing apparatus in the embodiment. The function block diagram of the information processing apparatus in the embodiment. The figure regarding specification of the radiation incident position in the embodiment. The figure which shows the light intensity | strength of each photodetector in the embodiment.

Explanation of symbols

1 ..... radiation detector 2 ----- scintillator 21 ... radiation entrance surface 3 ----- light detecting unit 31 ... waveguide 32 .... photomultiplier Tube (light detector)
4. Information processing device 41 ... Incident position specifying unit

Claims (5)

  A radioactivity detector comprising: a disc-like or substantially disc-like scintillator; and a plurality of photodetecting portions arranged uniformly on a side peripheral surface of the scintillator. The light detector is a light detector provided such that a light incident surface is in contact with a side peripheral surface of the scintillator,
The radioactivity detector according to claim 1, wherein the plurality of photodetectors are evenly arranged on a side peripheral surface of the scintillator. The light detection unit is
A waveguide provided with a tip surface in contact with a side peripheral surface of the scintillator;
A photodetector connected to the other end of the waveguide,
The radioactivity detector according to claim 1, wherein the waveguides of the plurality of light detection units are evenly arranged on a side peripheral surface of the scintillator.   The radioactivity detector according to claim 3, wherein a front end surface of the waveguide is disposed on a side peripheral surface of the scintillator without a gap.   The angle direction of the incident position of the radiation is specified from the light detection unit where the detection signal indicates the maximum light intensity, and based on the maximum light intensity and the value regarding the average of the light intensity indicated by the detection signals from the plurality of light detection units The radioactivity detector according to claim 1, further comprising an incident position identifying unit that identifies a radial position of the radiation incident position.