JPH11153673A - Collimator and gamma-ray detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To ensure γ-ray incidence number and lower scattering introduced in a detector, by providing a conical hole enlarging from source side toward a γ-ray detector side in a γ-ray path hole, and providing annular step surface projecting inward and facing to the source side. SOLUTION: A γ-ray detector is provided with a collimator 4 made of lead and the like in γ-ray incidence part of a γ-ray detector. A γ-ray path hole 5 consists of a conical hole part 6 in volume source 1 side, a tip hole part 7 in a γ-ray detector 3 side and a middle hole part 8 between them. Between the middle hold part 8 and the tip hole part 7, an annular step surface 9 facing to the volume source 1 side is formed due to the hole diameter difference. With this configuration, an eliminating γ-ray coming in the γ-ray path hole 5 of the collimator 4 from the volume source 1 is reduced in scattering on the inner wall of the collimator 4 in the process passing the conical hole 6 due to the slope of the conical surface surrounding the conical hole 6. Most of scattering ray scattered on the conical surface is shielded at the annular step surface 9.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a collimator and a gamma ray detecting device.

[0002]

2. Description of the Related Art In gamma ray measurement, gamma rays from a radiation source are made incident on a detector, for example, a Ge semiconductor detector, whereby electric pulses of various energy levels are output from the detector. Is used to measure an energy spectrum with a multi-channel analyzer. However, in the spectrum measured as described above, a background due to Compton scattered radiation was observed, which sometimes caused inconvenience in spectrum analysis and the like.

For example, in radiation measurement using iodine 131 ( ¹³¹ I) (364 keV) in a primary coolant in a nuclear power plant as a measurement target, as shown in FIG. 7, a CVCS pipe through which the primary coolant flows is used. 51 is a radiation source, and a Ge semiconductor detector 52 is arranged outside the radiation source.
In some cases, the energy spectrum is measured by a multi-channel analyzer using the output electric pulses from the second and the spectrum analysis of ¹³¹ I is performed from the spectrum. However, as shown in FIG. 6, ¹³¹ I (36
4 keV) is located on the high energy side of the Compton end (341 keV) of the annihilation gamma ray (511 keV),
Therefore, much of the background of ¹³¹ I is occupied by Compton scattered radiation of annihilation gamma rays, which may cause inconvenience in the spectrum analysis of ¹³¹ I.

[0004] Therefore, as a result of repeated studies for the purpose of reducing the background due to the γ-ray scattered radiation as described above, one of the reasons for increasing the ¹³¹ I background is that the γ-ray incidence of the detector 52 is increased. It has been found that the collimator 53 is provided in the shape of the collimator. That is, as shown in FIG. 7, the conventional collimator 53 has
4 is formed to have a straight and constant size from one end to the other end. For this reason, annihilation γ-rays cause small-angle scattering on the inner wall surface of the collimator 53, and the small-angle scattered rays are easily incident on the detector 52. ^The background of ¹³¹ I was increased.

The present invention has been made based on the above-described elucidation and
An object of the present invention is to provide a collimator and a γ-ray detection device capable of effectively reducing the number of γ-rays incident on a ray detector while effectively reducing the number of scattered rays incident on the detector. .

[0006]

The object of the present invention is to provide, in a γ-ray passing hole, a conical hole extending from a source side to a γ-ray detector side, and The problem is solved by a collimator characterized in that an annular step is provided adjacent to the line detector side, protruding inward and facing the source side.

That is, γ-rays that enter the γ-ray passage hole of the collimator from a radiation source first scatter on the inner wall surface of the passage hole in the process of passing through the conical hole. The object is shielded at the annular cross section without being scattered by the inclination of the conical surface of the conical hole. In addition, most of the scattered radiation caused by scattering at the conical surface of the conical hole is
It is shielded by the annular step surface in the γ-ray passage hole. In particular, the direction of travel of the scattered radiation is directed to the annular step by the action of the inclination of the conical surface of the conical hole, whereby the scattered radiation is more effectively shielded by the annular step. As a result, the incidence of scattered gamma rays on the detector is reduced. In addition, the number of γ-rays incident on the γ-ray detector is increased by the structure including the inclination of the conical surface surrounding the conical hole and the annular stepped surface.

[0008]

Next, embodiments of the present invention will be described with reference to the drawings.

In this embodiment, ¹³¹ I (364 keV) in the primary coolant in the nuclear power plant is used as the nuclide to be measured. In FIGS. 1A and 1B, reference numeral 1 denotes a CV.
The primary coolant 2 is circulated inside the volume line source by the CS pipe. The diameter of the volume radiation source 1 is, for example, 90 mm. Reference numeral 3 denotes a Ge semiconductor detector as a γ-ray detector, and a γ-ray incident portion of the detector 3 is provided with a collimator 4 made of lead or the like to constitute a γ-ray detector.

The collimator 4 has an overall length L of, for example, 1
It is designed to be 00 mm. The γ-ray passing hole 5 includes a conical hole 6 on the source 1 side, a tip hole 7 on the detector 3 side, and an intermediate hole 8 therebetween.

The conical hole 6 is provided with the γ-ray detector 3 from the source 1 side.
The length a is, for example, 50 mm, the diameter d ₁ at the end on the source 1 side is, for example, 40 mm, and the diameter d ₂ at the end on the detector 3 side is, for example, 60 mm. Designed.

The tip hole 7 is a straight circular hole having a constant cross-sectional size in the length direction. The length c is, for example, 30 mm, and the diameter d ₃ is the diameter of the end of the conical hole 6 on the larger diameter side. It is designed to be smaller than the hole diameter, for example, 40 mm. The intermediate hole 8 is a straight circular hole having a constant cross-sectional size in the length direction similarly to the tip hole 7, and has a length b
Is designed to be, for example, 20 mm, and the diameter d ₂ is set to 60 mm, which is the same as the diameter of the large-diameter end of the conical hole 6. An annular step surface 9 is formed between the intermediate hole portion 8 and the distal end hole portion 7 so as to face the radiation source 1 due to the difference in the hole diameter.

In the collimator 4 described above, the annihilation γ that has entered the γ-ray passage hole 5 of the collimator 4 from the volume radiation source 1
In the process of passing the line (511 keV) through the inside of the conical hole 6, the inclination of the conical surface surrounding the conical hole 6 reduces scattering on the inner wall surface of the collimator. Fig. 1 (b)
As shown in (1), most of the scattered radiation caused by the conical surface of the conical hole 6 is shielded by the annular step surface 9. As a result, the incidence of scattered gamma rays on the detector 3 is reduced.

The collimator 4 shown in FIGS.
Has the above-mentioned intermediate hole 8 omitted, and its total length L is designed to be, for example, 60 mm, and the length c of the tip hole 7 is designed to be, for example, 10 mm. Others are the same as the collimator 4 described above.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First and second embodiments are described below using a volume source.
Was performed in two stages.

The first test uses a volume-ray source with a diameter of 90 mm, using ray source, ²² Na of 7684Bq / cm ^3, 8
10 Bq / cm ³ of ⁵⁸ Co was used. As collimators, four types of collimators C1, C2, C3 each having a total length L of 100 mm as shown in FIGS.
, C4 were prepared. The dimensions of γ rays passing hole of the collimator C1, as shown in FIG. 3 (b), d ₁ is 40 mm. Further, the dimensions of the γ-ray passage hole of the collimator C2, as shown in FIG. 3 (b), d ₁ is 80 mm, d ₂ is 60m
m and d ₃ are 40 mm, and a and b are each 50 mm. Further, the dimensions of the γ-ray passage hole collimator C3, as shown in FIG. 3 (c), d ₁ is 40 mm, d ₂ is 60m
m and d ₃ are 40 mm, a is 50 mm, b is 20 mm, c
Is 30 mm. Further, the dimensions of the γ-ray passage hole collimator C4, as shown in FIG. 3 (d), d ₁ is 30m
m and d ₂ are 20 mm, and a and b are each 50 mm. Then, the collimator was separated from the radiation source by a predetermined distance, and the annihilation gamma ray in the volume radiation source was measured.
The P / C ratio when the Compton region of 360 to 370 keV was C was calculated, and the total count rate was measured.

As a result, assuming that the P / C ratio of the collimator C4 having the best P / C ratio is 1.00 and the total count rate ratio is 1.00, the P / C ratio of the collimator C1 is P / C.
The C ratio was 0.86 and the total count ratio was 3.69. The collimator C2 has a P / C ratio of 0.8.
2. The total count rate ratio was 5.70. The collimator C3 had a P / C ratio of 0.88 and a total count rate ratio of 4.36. From this result, the collimator C1,
Among C2, C3 and C4, the collimator C3 having a large value of the total count rate while exhibiting a large value of the P / C ratio was evaluated as the optimal collimator (corresponding to the collimator of FIG. 1).

FIG. 4 is a spectrum graph obtained by measurement using collimators C1, C2 and C3. From this graph, it can be seen that the use of the collimator C3 of the present invention makes it possible to use the collimator C1 of 360 to 370 k in comparison with the case of using the conventional collimator C1 and the case of using the collimator C2.
It was confirmed that the count value of the eV Compton region could be reduced. 5A to 5B show various shapes of the collimator considered in the execution of the first test.

In the second test, the P / C ratio and the total count rate when the length of the collimator C3 was determined to be optimum in the first test as shown in FIG. As shown in Table 1, as collimators No.
No. 1 to No. Prepare 19 types of 19 collimators,
Under the same conditions, the annihilation gamma rays in the volume radiation source 1 were measured. Dimensions L, a, b, and c in the table are L, a, b, and c of the collimator C3 shown in FIG. D ₁ is 40 m
m, d ₂ is 60 mm, d ₃ was fixed with 40 mm. The results are shown in the same table. The P / C ratio and the total count rate are as shown in FIG. The data of No. 1 is used as a reference and shown as a relative value. In addition, an evaluation value based on the relative value P / C ratio × the total count rate is shown. According to the table, when the length of the collimator is increased, the P / C ratio shows a large value, but the total count rate is small. Conversely, when the collimator length is shortened, the P / C ratio decreases,
The total count rate is increasing. Then, No. 1 to N
o. 19, the No. 19 having a large evaluation value based on the P / C ratio × the total count rate. Nineteen collimators were evaluated as optimal collimators (corresponding to the collimators in FIG. 2).

Although the embodiments, examples and optimum collimators of the present invention have been described above, the present invention is not limited to these, and various design changes can be made without departing from the spirit of the invention. It goes without saying that it is a thing. For example, the size and specific shape of the collimator are determined on a case-by-case basis according to the energy and size of the radiation source, and are not limited to the above embodiments and examples. Further, in addition to a Ge semiconductor detector, a NaI (Tl) scintillator or another detector may be used as the γ-ray detector.

[0021]

[Table 1]

[0022]

As described above, according to the collimator of the present invention, a conical hole extending from the source side to the γ-ray detector side is provided in the γ-ray passage hole, Hole and γ
An annular step surface that is adjacent on the line detector side, protrudes inward and opposes the source side is provided, and the γ-ray detection device of the present invention provides such a collimator with γ Because it is provided in the γ-ray incident part of the X-ray detector, while ensuring a large number of γ-rays incident on the γ-ray detector,
The incidence of the scattered radiation on the detector can be effectively reduced.

Therefore, using the above-described collimator, for example, the primary coolant in a nuclear power plant can be used.
^{When 131} I (364 keV) was measured, 364 keV due to small-angle scattering of annihilation gamma rays (511 keV) was obtained.
Can be reduced, and the inconvenience in the spectrum analysis of ¹³¹ I can be reduced or eliminated.

[Brief description of the drawings]

FIGS. 1 (a) and 1 (b) are plan sectional views showing a γ-ray detector provided with a collimator according to one embodiment.

FIGS. 2A and 2B are plan cross-sectional views showing a γ-ray detection device provided with a collimator according to another embodiment.

FIGS. 3A to 3D are plan sectional views of a collimator used in the test.

FIG. 4 is an energy spectrum diagram measured using three specific collimators used in the test.

FIGS. 5A to 5C are cross-sectional views showing various types of collimators considered in the test.

FIG. 6 is an energy spectrum diagram showing an annihilation γ-ray peak and Compton scattered radiation.

FIG. 7 is a plan sectional view showing a γ-ray detection device provided with a conventional collimator.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Volume radiation source 3 ... Ge semiconductor detector (gamma ray detector) 4 ... Collimator 5 ... Gamma ray passage hole 6 ... Conical hole part (conical hole part) 9 ... Annular step surface

 ──────────────────────────────────────────────────続 き Continuation of the front page (71) Applicant 000230940 Japan Atomic Power Co., Inc. 1-6-1, Otemachi, Chiyoda-ku, Tokyo (71) Applicant 591212349 Nuclear Engineering Co., Ltd. 1-3-3 Tosabori, Nishi-ku, Osaka-shi, Osaka No. 7 (72) Inventor Toshitaka Nakamura 3-3-22 Nakanoshima, Kita-ku, Osaka City, Osaka Prefecture Inside Kansai Electric Power Company (72) Inventor Muneo Tanaka 61-2, Minatomachi, Matsuyama-shi, Ehime Prefecture Shikoku Electric Power Company Inside the company (72) Koichi Tazaki 2-82, Watanabe-dori, Chuo-ku, Fukuoka City, Fukuoka Prefecture Inside Kyushu Electric Power Company (72) Inventor Taku Ohira 1-6-1, Otemachi, Chiyoda-ku, Tokyo Nippon Atomic Energy (72) Inventor Masataka Yamada 1-3-7 Tosabori, Nishi-ku, Osaka-shi, Osaka Within Nuclear Engineering Co., Ltd.

Claims (2)

[Claims] 1. A conical hole extending from a radiation source side to a γ-ray detector is provided in a γ-ray passage hole, and the conical hole is adjacent to the γ-ray detector on a γ-ray detector side; A collimator characterized by having an annular step surface projecting inward and facing the source side. 2. A collimator provided in a γ-ray incident part of a γ-ray detector, a conical hole part expanding from a source side to a γ-ray detector side in a γ-ray passage hole, A gamma ray detecting device comprising: a conical hole adjacent to the gamma ray detector side, an inwardly protruding annular step surface facing the source side.