JPH10319122A - Radiation image pick-up device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect even radiation such as low-energy gamma rays as a radiation image with improved sensitivity by applying radiation from a specific direction using a cylindrical collimator being provided at the incidence surface side of a detection part. SOLUTION: A gamma ray detector consists of a body 21 that accommodates a detection part and a cylindrical collimator that is formed in one piece with the body 21 and is extended toward the front of a detection part 20, namely the incidence surface side of gamma rays. The detection part 20 is preferably made of a material with a larger atomic number for improving sensitivity such as a semiconductor material including CdTe and CdTeZn or a scintillator, thus improving the photoelectric effect and obtaining a miniature detector with improved sensitivity. A drive mechanism can be miniaturized for scanning XY directions by the compact detector and a drive force can also be reduced. The body 21 and a collimator 22 are made of lead and the collimator 22 is set slightly thicker to avoid the detection of transmission gamma rays.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a radiation imaging apparatus for forming an image of radiation such as gamma rays.

[0002]

2. Description of the Related Art Conventionally, various types of gamma ray detectors have been developed. For example, a device using scintillation such as a NaI crystal or a plastic is well known as a highly sensitive detector. However, these detectors were all developed to measure the intensity of gamma rays, and could not be detected as gamma ray images. For this reason, it has not been possible to recognize in advance where the gamma ray is emitted, and the location of the gamma ray was examined by bringing the detector close to the gamma ray source. This is a very inconvenient system when, for example, finding the position of a gamma ray source in a nuclear facility such as a nuclear reactor.

For this reason, particularly in the field of nuclear reactors, it has been desired to develop a detector for obtaining a gamma ray image.
Many researchers have been studying for many years. However, a few practical examples of low-energy gamma rays have been developed in the medical field, but there are no such remote measuring devices in nuclear facilities as described above. .

[0004] Based on such a background, the present inventor:
We checked the principle of gamma ray image detection, and we thought about using a pinhole camera because there is no optical element for making an image such as a lens like gamma rays like visible light. I thought about detecting the gamma-ray source position as an image by superimposing a CCD image for visible light at the same time as taking an image using it, so I repeated my research with other researchers.

[0005]

However, ultimately,
We concluded that it would not be feasible for the following reasons:

1) In an X-ray CCD, the sensitivity is greatly reduced in a gamma ray region.

2) Even if a pinhole as an image element is made of lead, gamma rays having high energy have a strong penetrating power.
Does not work as a pinhole. (If the energy is 200 keV or less, it works as a pinhole).

3) When a pinhole is used, the solid angle desired by the detector from the position of the radiation source becomes smaller (a visible light lens is used to avoid it), so that the image becomes darker and the detection sensitivity becomes lower. Lower.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a radiation imaging apparatus capable of detecting a radiation image such as a low-energy gamma ray with high sensitivity as a radiation image.

[0010]

SUMMARY OF THE INVENTION A radiation imaging apparatus according to the present invention includes an imaging apparatus for imaging an optical image, a radiation detector for obtaining an energy intensity distribution image of radiation rays in an imaging range of the imaging apparatus, and a detection apparatus for detecting the radiation intensity. An output signal from the device, a processor that combines the signal from the imaging device to form a radiation image, the radiation ray detector, the detection unit,
And a cylindrical collimator provided on the incident surface side of the detection unit and for causing radiation from a predetermined direction to enter the detection unit.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A radiation imaging apparatus according to an embodiment of the present invention will be described below with reference to the accompanying drawings in the case of a gamma ray imaging apparatus.

In FIG. 1, reference numeral 10 denotes a gamma ray detector (radiation detector). The output side of the gamma ray detector is a pulse height analyzer (PHA) 12 via a preamplifier 11 for amplifying an output pulse signal. Is connected to the input side. In the PHA 12, the input signals are classified according to the magnitude of the pulse height of each pulse, and the signals are totaled to obtain a pulse height distribution and output. That is, the energy intensity distribution of the incident gamma ray is output. This PHA 12 is, as known,
It is also possible to select a pulse having a specific pulse height and output it. The output side of the PHA 12 is connected to a processor 13 for image processing.

An output side of a known CCD camera 14 is also connected to the processor 13. As a result, the processor 13 outputs an output signal indicating an energy distribution from the PHA 12 and a visible light image from the CCD camera 14. Are combined to form a gamma ray image.

The processor 13 includes a driving device 15 for scanning the incident surface of the gamma detector 10 in the X and Y directions.
As a result, the gamma ray detector 10 is scanned by the driving device in the X direction and the Y direction over the entire operation range of the CCD camera 14. As a result, the gamma ray image becomes an image in which the visible light image captured by the CCD camera 14 and the image of the energy distribution of the gamma ray obtained by the gamma ray detector 10 overlap, and the gamma ray intensity corresponding to the visible light image portion Can be measured.

The output side of the processor 13 includes:
CR for measuring the gamma ray image in real time
T16 is connected. The CRT screen 16 also displays the energy spectrum of the gamma rays formed by the PHA 12.

As shown in FIG. 2, the gamma ray detector 10 is formed integrally with a main body 21 containing a detection unit 20, and is provided in front of the detection unit 20, that is, on the gamma ray incident surface side. And a cylindrical collimator 22 extending to the end. The detector 20 is not particularly limited, but is preferably made of a material having a large atomic number (Z) in order to improve sensitivity, for example, CdTe, CdTeZn.
Etc. or a scintillator. For example, at around 1 MeV, the photoelectric effect is
Since the cross-sectional area of Compton scattering is improved by 500 times or more with respect to Si constituting the CD by 3 times or more with respect to Si, a highly sensitive detector can be obtained even if it is small. Thus, by using a small detector, this can be
The driving mechanism for scanning in the Y direction can be reduced in size, and the driving force can be reduced. It should be noted that NaI, which is generally known as a scintillator material, may be used, but in this case, there is a disadvantage that the size must be increased in order to obtain a predetermined sensitivity.

As described above, the gamma ray detector 10 of the apparatus of the present invention is provided with a cylindrical collimator on the gamma ray incident side. The inner diameter of the collimator 22 may be arbitrary, but is preferably about 5 to 15 mm. For example, in a device using a pinhole described as a conventional example, assuming that the diameter of the pinhole is 1 mm, gamma rays passing through the pinhole at a rate of about 20 / sec even at a distance of 10 m from a large energy source such as ICi. And the detection efficiency is 10
Even assuming 0%, detection of gamma rays is quite difficult. However, in the present invention, if a collimator having an inner diameter of 10 mm is used, the sensitivity is improved about 100 times. In addition, high energy gamma rays generate high-energy electrons both in the photoelectric effect and Compton scattering due to the elementary processes that occur inside the detector, and the range becomes longer. There is no problem even if the angle is about 5 to 10 °, so the collimator 22 does not need to be so long, and may be about 100 to 200 mm. The body 2
1 and the collimator are made of lead, and the collimator is set slightly thicker to avoid detection of transmitted gamma rays.

Next, the shape of the collimator 22 will be described in detail.

1. Length of collimator The angle of view of the collimator must be smaller than the angle of view of the CCD camera.
Since it is 0 °, when the angle of view of the collimator is calculated as 10 °, when the angle of view is θ, the length is 1 and the inner diameter is a, sin 10 ｄd / l = 1 from sin θ∞d / l. When the inner diameter a of .745 × 10 ^-1 is 16 mm, 1 = 91.6 mm, and the length may be about 10 cm.

1. Thickness of collimator When the angle of view is 10 °, it may be about 1 cm.

A consideration of the sensitivity of the gamma-ray imaging device of the present invention having an upper air configuration will be described below.

1Ci (3.7 (10) Bg) as a radiation source
If the distance between this source and the pinhole (1 mm ² ) in the conventional device is 10 m, 4πr ² = 4π × (10 ⁴ ) ² = 1.25
From 7 (9) mm ² , the gamma ray incident on the 1 mm ² pinhole is 3.
7 (10) /1.257 (9) = 2.94 (1) / sec.

Therefore, if the efficiency of the detector is about 10%, the actual detection amount is 2 to 3 detectors / second, which is very poor in sensitivity and practically not practical.

In the apparatus of the present invention, CdTe (diameter: 16 mm, thickness: 2 mm, A116 / P4 or B116 / P4 manufactured by Kansai Electronics Co., Ltd.) is used as a scintillator, and measurement is performed under the same conditions as above. The light receiving area is about 2.01 (2) mm ² , and about 200 times the sensitivity can be obtained as compared with the case where the pinhole is used.

A comparison of sensitivity between the case where CdTe is used as the scintillator and the case where Si of the CCD is used will be described below.

Since the photoelectric effect is proportional to Z ⁵ (Z is the atomic number), Zeff of CdTe = 50, Ze of Si =
Assuming that the sensitivity ratio is 14, the sensitivity ratio A is A = (50/14) ⁵
= 5.81 (2) times.

On the other hand, in the Compton scattering, if the cross-sectional area ratio is represented by ρ, density by A, and atomic number by Z, the following equation is established.

Σ ₁ / σ ₂ = ρ ₁ / ρ ₂ × A ₂ /
A ₁ × Z ₁ / Z ₂ Therefore, comparing CdTe with Si, Si has a ρ of 2.34, an A of 28, a Z of 14, and a CdTe
If ρ is 6.2, A is 119, and Z is 50, then σ _CdTe / σ _Si = 3.15, which is about 3.15 times C
dTe has higher sensitivity.

Accordingly, the sensitivity is increased by the following Table 1. Table 1 Photoelectric effect 50 × 5.81 (2) = 2.5 (4) times Compton scattering 50 × 2.2 (1) = 3.15 In this table, the thickness of the depletion layer of the detector is assumed to be the same. However, since CdTe can be 50 times longer than Si, the substantial ratio can be ~ 150 times greater for Compton scattering than in this table.

As described above, the gamma ray imaging device having the upper air configuration can provide a gamma ray image with high sensitivity. Although a scintillator is used as the gamma detector, another type of gamma ray detector such as a semiconductor detector may be used. Further, according to the technical idea of the present invention, a radiation image can be obtained by utilizing not only gamma rays but also other radiations such as neutron rays.

In the above embodiment, one cylindrical collimator is used to make the radiation incident on the detecting section.
The gamma ray detector was scanned so as to coincide with the scanning area of the CCD camera, but a plurality of cylindrical collimators facing each other like compound eyes of an insect were placed on different parts (they may partially overlap). With the use of a radiation detector, the operating range of the detector can be reduced, or the scanning itself can be reduced or eliminated. In this case, the processor combines the energy intensity distribution signals from the plurality of detectors,
The setting is made so as to be combined with the image signal from the CCD camera. The collimators of these detectors may have the same dimensions or different lengths and apertures so that several solid angles are visible. Although a CCD camera is used as the visible light imaging device, the present invention is not limited to this, and an imaging device that does not use a CCD can be used. Further, it is possible to mount the imaging device and the radiation detector or only the radiation detector on a robot, and perform remote operation and measurement to approach the imaging range.

[Brief description of the drawings]

FIG. 1 is a circuit diagram for explaining a gamma ray imaging device according to an embodiment of the present invention.

FIG. 2 is an enlarged sectional view showing a gamma ray detector used in the gamma ray imaging device shown in FIG.

[Explanation of symbols]

10: Gamma ray detector (radiation detector), 13: Processor, 14: CCD camera, 20: Detector, 22: Collimator.

Claims (5)

[Claims] An imaging device for capturing an optical image, a radiation detector for obtaining an energy intensity distribution image of radiation rays in an imaging range of the imaging device, an output signal from the detector, and a signal from the imaging device And a processor that forms a radiation image by combining the radiation beam detector and the radiation ray detector, wherein the radiation ray detector is provided on a light incident surface side of the detection unit, and a tube that makes radiation from a predetermined direction incident on the detection unit. A radiation imaging apparatus comprising: a collimator in a shape of a circle. 2. The radiation imaging apparatus according to claim 1, wherein the radiation detector scans over an imaging range of the imaging apparatus. 3. The radiation detector according to claim 1, wherein the radiation detector includes a plurality of cylindrical collimators arranged so that radiation from respective regions of an imaging range of the imaging device is incident on the detection unit. Radiation imaging device. 4. The radiation imaging apparatus according to claim 1, wherein said radiation detector is a gamma ray detector. 5. The detection unit of the gamma detector, wherein the detection unit is a CdT
5. The radiation imaging apparatus according to claim 4, wherein the radiation imaging apparatus is made of e, CdTeZn, or a scintillator.