JP2001042040A - Radioactive gas monitor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accurately detect the γ rays of a nuclide of interest in an off gas being emitted from a reactor. SOLUTION: A detection part 12 is provided at a specific part of piping 10 where an off gas flows. A main detector 16 is buried into scintillator blocks 14A and 14B. A sub detector is composed of the scintillator blocks 14A and 14B, and photomultipliers 18A and 18B. Interference γ rays with 511 keV are transmitted through the main detector 16, and are detected by both of the main detector 16 and the sub detector, thus excluding the interference γ rays from a measurement result by utilizing the simultaneous count. The γ rays from a nuclide of interest with a peak at a low-energy region can be accurately detected.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a radioactive gas monitor used in a nuclear power plant or the like.

[0002]

2. Description of the Related Art As the demand for energy increases year by year, a nuclear power plant that extracts energy by nuclear fission has become indispensable. There is a need for safer equipment to promote the peaceful use of nuclear energy.

[0003] A large number of fuel rods are inserted into a nuclear reactor, and nuclear fission in the fuel rods transfers heat to cooling water surrounding the fuel rods to form a thermal cycle. The fuel rods are the primary key to containment of fission products and are well designed to prevent them from breaking. Double and triple safety systems are in place to prevent any possible damage to the fuel rods from affecting the outside world.

[0004] As described above, the fuel rods perform important functions, and it is desirable to constantly monitor the health of the fuel rods.
For this reason, monitoring of the gas exhausted from inside the reactor (hereinafter referred to as off-gas) is being performed. A conventional gas monitor is provided near a pipe into which a gas is introduced, and a gamma ray emitted from the gas is detected as a current output of the ionization chamber.

[0005] However, neutrons in a nuclear reactor, the oxygen atom is radiated by the action of a proton, ¹³ N gas having radioactive are mass produced. The annihilation of the positron emitted from the ¹³ N generates a 511-keV gamma ray, but the detection by the gas monitor becomes dominant. Further, the γ
Compton scattering of the line makes observation more difficult. Even if a fuel rod leaks and noble gas as a fission product is generated, it is difficult to detect the γ-ray if the amount is small, so it is difficult to detect the leak with the current gas monitor alone. difficult.

The noble gas as a fission product includes, for example, Xe-138, Kr-87, Kr-85,
Kr-88, Kr-85m, Xe-135, Xe-13
3, Xe-135m, Xe-137, Kr-89, Ar
-41 and the like. In the off-gas, those rare gas components are small, and N-13 accounts for the majority.

The present invention has been made in view of the above-mentioned conventional problems, and an object of the present invention is to provide a rare gas generated by fission (particularly, a rare gas emitting γ-rays lower than 511 keV).
Is to be measured with high accuracy in the presence of ¹³ N gas.

[0008]

(1) In order to achieve the above object, the present invention relates to a radioactive gas monitor provided near a pipe into which a radioactive gas is introduced. A main detector, a sub-detector provided surrounding the pipe and the main detector, and when the main detector and the sub-detector simultaneously detect γ-rays, And a signal processing unit that is excluded from the detection result.

According to the above configuration, since the main detector is surrounded by the sub-detectors, the γ-rays which have not completely been blocked by the main detector and passed therethrough are also detected by the sub-detectors. Therefore, if coincidence counting is performed between the main detector and the sub-detector, only relatively high-energy γ-rays that have passed through such a main detector and have come out can be specified, and the γ-rays can be identified from the detection results. It is possible to exclude the γ-ray component. Therefore, as a result, the nuclide of interest that emits low-energy gamma rays can be detected with high sensitivity.

According to the present invention, even if a large amount of ¹³ N is generated by activation of oxygen atoms inside a nuclear reactor (particularly a light water reactor), the detection of off-gas as a radioactive gas causes the positrons emitted from ¹³ N to be detected. 51 caused by annihilation
1 keV γ-rays can be discriminated and detected and excluded from the detection results. That is, when the positron is annihilated, the two annihilation gamma rays (511 keV) fly out in opposite directions. This is detected by the main detector and the sub-detector, and 511-keV γ-rays are specified and removed using anti-coincidence. No such annihilation gamma ray is basically observed for the rare gas.

Preferably, the main detector comprises 511
It has a low blocking effect on keV interfering γ-rays and has 511
It is composed of a thin detector having a predetermined detection depth with a high blocking action for attention γ-rays having an energy lower than keV, and disturbing γ-rays transmitted through the main detector are detected by the sub-detector. By detecting, interference γ-rays are excluded by coincidence counting.

That is, the sensitivity of the main detector is low for 511 keV γ-rays, and the main detector basically does not observe the photoelectric peak of the disturbing γ-rays but only the Compton continuum. Become. However, Compton-scattered interfering gamma rays are also detected by the sub-detector. On the other hand, attention γ of energy lower than 511 keV
The line is basically absorbed by the main detector, and the main detector can observe the photoelectric peak of the target γ-ray. Therefore, if simultaneous counting is performed between the main detector and the sub-detector, the interference γ
Lines can be removed.

Preferably, the main detector is a semiconductor detector having the predetermined detection depth. Here, the detection depth correlates with the thickness of the depletion layer. Further, the main detector may be a scintillation detector.

Preferably, the sub-detector includes a scintillator block having a housing chamber for housing the main detector, and a photomultiplier tube joined to the scintillator block.

Preferably, the rear side of the storage chamber as viewed from the piping forms a part of the scintillator block, and the main detector is embedded in the scintillator block.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a configuration of a detecting section of a radioactive gas monitor according to the present invention. Here, FIG. 1 is a schematic perspective view of the detection unit. The pipe 10 allows off-gas discharged from the nuclear reactor to flow. A detection unit 12 shown in FIG. 1 is provided at a predetermined location. The detecting section 12 has a cylindrical scintillator block 14 in the present embodiment, and the pipe 10 is inserted into a through hole 15 at the center thereof. The insertion part is positioned as a gas chamber. Incidentally, the off-gas flows in the pipe 10 at a constant flow rate.

An accommodation chamber for accommodating the main detector 16 is formed in the scintillator block 14. Here, the accommodation chamber is formed so as to communicate with the internal space of the scintillator block 14, that is, the main detector 16 disposed therein is in close proximity to the side surface of the pipe 10.

FIG. 2 is a cross-sectional view showing a more specific configuration of the detection unit 12. As shown in FIG. Here, the scintillator block is divided into, for example, left and right, and two scintillator blocks 14A and 14B are formed. Two photomultiplier tubes (PMT) 18A, 18B are provided corresponding to the scintillator blocks 14A, 14B.
When radiation enters the scintillator blocks 14A, 14B, light emission occurs therein, and the emitted photons are detected by the corresponding photomultiplier tubes 18A, 18B.

Incidentally, the scintillator block 14 does not necessarily have to be divided, and even in this case, it is desirable to provide two or more photomultiplier tubes so that light generated over the entire area can be observed. For example, it is possible to receive light generated in the entire scintillator block 14 with one photomultiplier tube using a light guide or the like.
Further, the scintillator block 14 may be divided into three or more parts, and a photomultiplier tube may be provided for each divided element. According to this configuration, there is an advantage that the problem of counting down due to pile-up or the like can be dealt with. In any case, in the present embodiment, the scintillator block 14 constituting the sub-detector is provided so as to surround the entire periphery of the pipe 10 in consideration of the scattered reflection of γ-rays on the pipe 10. Incidentally, the sub-detector is composed of the scintillator block 14 and one or a plurality of photomultiplier tubes.

The main detector 16 comprises a semiconductor radiation detector in this embodiment. The semiconductor type detector has low sensitivity to 511 keV γ-rays, that is, interfering γ-rays, and has high sensitivity γ-ray absorption (rejection) characteristics to γ-rays of lower energy (attention γ-rays). ing. Here, in other words, the detection depth of the semiconductor detector, that is, the thickness of the depletion layer and its structure are determined so as to have such selective characteristics.

In the present embodiment, since the scintillator block 14 is provided not only around the main detector 16 as viewed from the pipe 10 but also behind it, the light is transmitted after being scattered by the main detector 16. Γ-rays can be simultaneously detected by the sub-detector.

In FIG. 2, for example, ¹³ N
Out of the pair of 511 keV γ-rays 102 and 104 generated by the annihilation of positrons (see reference numeral 100) from the positrons, when one of the γ-rays 102 enters the main detector 16, the function of the main detector 16 as described above is performed. From the γ-ray 102
Is the main detector 1 while performing Compton scattering
6 and enters the sub-detector, and is also observed at that sub-detector at the same time. On the other hand, the attention γ-ray has lower energy, and basically, when the attention γ-ray enters the main detector 16, the absorption is blocked on the main detector 16. . Therefore, the two different behaviors of the disturbing γ-ray and the attention γ-ray are used to discriminate the two, and specifically, the counting of the disturbing γ-ray is excluded by the simultaneous counting between the main detector and the sub-detector. It is possible to do.

FIG. 3 shows the entire configuration of the radioactive gas monitor according to the present embodiment. This radioactive gas monitor is roughly composed of a detection unit 12 and a signal processing unit 14. Here, the signal processing unit 14 will be described in detail.

As described above, the detecting section 12 includes one or a plurality of sub-detectors and one main detector 16.
An amplifier 34 and a high voltage source 36 are provided for each sub-detector. Here, the amplifier 34 is a photomultiplier tube 18
A high-voltage source 36 is a circuit for supplying a high voltage to the photomultiplier tube. A peak discriminator 38 provided for each sub-detector is a circuit that passes a pulse having a predetermined peak value or more from among the detection pulses output from each amplifier 34, and these pulses are sent to an OR circuit 40. After that, it is output to the subtractor 32 as an anti-signal G.

On the other hand, the output pulse of the main detector 16 is amplified by the amplifier 30 and then output to the subtractor 32 as the main signal M.

In the subtracter 32, signal processing for excluding the anti-signal G from the main signal M is executed. Specifically, processing for sampling the main signal M during periods other than the period in which the anti-signal G is output is performed. It is running.
That is, the elimination of the coincidence component and the conversion to the digital signal are executed.

The signal that has passed through the subtractor 32 is counted for each channel in a multi-channel analyzer (MCA) 42, and the analysis result is sent to a calculation unit 44, where a predetermined calculation is executed. Here, the predetermined calculation includes calculation of the radioactivity of the nuclide of interest, determination of an abnormality in the fuel rod, and the like.

FIG. 4 shows that the main detector is NaI (Tl).
The detection characteristics of the radioactive gas monitor when a scintillation detector is used are shown. By the way, the code 200
Indicates the detection characteristic of the conventional radioactive gas monitor, and reference numeral 202 indicates the detection characteristic of the radioactive gas monitor according to the present embodiment.

As shown in the drawing, in the present embodiment, since the exclusion of interference γ-rays is performed by coincidence counting, the photoelectric peak of 511 keV, which has been seen in the related art, has disappeared, and the Compton continuous portion due to the elimination has been reduced. As a result, the peak of the γ-ray of interest of 511 keV or less can be clearly represented on the spectrum. Here, the nuclides of interest are, for example, Xe-133, Kr-85m, Xe-138, Xe
-135 m.

Incidentally, in FIG. 2, a certain effect can be obtained even if the sub-detector is formed only around the main detector 16 when viewed from the pipe 10 side. However, many interfering γ-rays pass straight through the main detector 16, and in order to effectively detect such γ-rays and eliminate them by coincidence counting, the rear side of the main detector 16 is also part of the sub-detector. Should be.

The main detector and the sub-detector are not limited to those described above, and other detectors can be used.

According to the above embodiment, ¹³ N which is an interfering nuclide
Γ-rays emitted from the noble gas (nuclide of interest) in the off-gas without being affected by neutrons can be measured with high accuracy, and for example, the ratio of the short half-life nuclide and the long half-life nuclide can be accurately obtained. Further, it becomes important data when judging and analyzing whether the damage state of the fuel rod in the reactor is a pinhole or a crack state.

[0034]

As described above, according to the present invention,
There is an advantage that γ-rays of a nuclide of interest in off-gas can be measured with high accuracy.

[Brief description of the drawings]

FIG. 1 is a schematic perspective view showing a configuration of a detection unit of a radioactive gas monitor according to the present invention.

FIG. 2 is a cross-sectional view illustrating a specific configuration of a detection unit illustrated in FIG.

FIG. 3 is a block diagram illustrating an overall configuration of a radioactive gas monitor according to the present embodiment.

FIG. 4 is a characteristic diagram showing characteristics of a radioactive gas monitor.

[Explanation of symbols]

10 piping, 12 detector, 14 scintillator block, 16 main detector, 30, 34 amplifier, 32
Subtractor, 38 wave height discriminator, 40 OR circuit, 42 multi-channel analyzer (MCA), 44 operation unit.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Shohei Matsubara Inventor 6-22-1, Mure, Mitaka City, Tokyo Aloka Co., Ltd. (72) Inventor Hiroshi Nakaoka 6-22-1, Mure, Mitaka City, Tokyo Aloka Co., Ltd. (72) Inventor Yoshihiro Nishida 16-46 Aoyama-cho, Kashiwazaki-shi, Niigata Prefecture Inside the Tokyo Electric Power Company Kashiwazaki-Kariwa Nuclear Power Station (72) Inventor Yozo Sasaki 16-46 Aoyama-cho, Kashiwazaki-shi, Niigata Prefecture Tokyo Electric Power Company Kashiwazaki Corporation Inside the Kariwa Nuclear Power Station (72) Inventor Koichi Nakabayashi 16-46 Aoyama-cho, Kashiwazaki-shi, Niigata Prefecture Tokyo Electric Power Co. Inside the Kashiwazaki-Kariwa Nuclear Power Station (72) Inventor Junji Ueda 16-46, Aoyama-cho, Kashiwazaki-shi, Niigata F-term in Kashiwazaki-Kariwa Nuclear Power Station (reference) 2G088 EE12 EE22 FF04 FF07 FF15 GG09 GG21 HH09 JJ01 KK01 KK15 KK29 LL02

Claims (6)

[Claims] 1. A radioactive gas monitor provided in the vicinity of a pipe into which a radioactive gas is introduced, a main detector provided in close proximity to the pipe, and a sub-detector provided surrounding the pipe and the main detector. A detector, and a signal processing unit that excludes γ-rays from the detection result of the main detector when simultaneous detection of γ-rays is performed by the main detector and the sub-detector. Gas monitor. 2. The radioactive gas monitor according to claim 1, wherein the main detector has a low rejection effect on 511 keV interfering γ-rays and has a high rejection on target γ-rays having an energy lower than 511 keV. It is constituted by a thin detector having a predetermined detection depth having an action, and by detecting the disturbing γ-rays transmitted through the main detector with the sub-detector, the exclusion of the disturbing γ-rays by coincidence counting is eliminated. Radioactive gas monitor characterized by performing. 3. The radioactive gas monitor according to claim 2, wherein the main detector is a semiconductor detector having the predetermined detection depth. 4. The radioactive gas monitor according to claim 2, wherein the main detector is a scintillation detector having the predetermined detection depth. 5. The radioactive gas monitor according to claim 1, wherein the sub-detector includes a scintillator block having a storage chamber for storing the main detector, a photomultiplier tube joined to the scintillator block, A radioactive gas monitor characterized by comprising: 6. The radioactive gas monitor according to claim 4, wherein the rear side of the storage chamber as viewed from the pipe forms a part of the scintillator block, and the main detector is embedded in the scintillator block. Radioactive gas monitor featured.