JP5047341B2 - Radiation measurement system - Google Patents

Description

  The present invention relates to a radiation measurement system, particularly a radiation monitor such as a radiation monitor or a radioactive contamination inspection apparatus that can be used for radiation measurement and radiation management in a nuclear facility, a nuclear fuel facility, an accelerator utilization facility, a decommissioning reactor, etc. that handles radioactive substances. It is about the system.

In order to measure the radiation to be measured with high sensitivity, it is necessary to select a radiation detector that has high detection sensitivity for the radiation quality and energy, and low detection sensitivity for interfering radiation. is there.
When the radiation to be measured is β rays, a plastic scintillator that is inexpensive and easily available is often used as the radiation sensor. In general, interfering radiation is environmental gamma rays, and plastic scintillators are composed of elements having a low atomic number and can be made thin, which is preferable in terms of suppressing the detection sensitivity of environmental gamma rays. In order to use a plastic scintillator for the radiation detector and provide a highly sensitive radiation monitor or radioactive contamination inspection device, the plastic scintillator is made as thin as possible and the method of shielding the radiation detector with lead has been adopted for a long time. However, in recent years, a radiation detector having a plurality of scintillator layers and a simultaneous count of pulse signals output as a result of each scintillator layer reacting to radiation have been measured as β-rays, resulting in a small reaction cross section. A method of eliminating environmental γ rays with a low probability of coincidence has been proposed (see, for example, Patent Document 1).

JP 2001-13250 A

  Conventionally, the β-rays to be measured are measured by simultaneously counting the pulse signals resulting from the simultaneous reaction of the two scintillator layers to the β-rays. The probability of simultaneous counting is lower as the β-ray energy is lower, and improvement of the detection sensitivity of low-energy β-rays has been a problem. Further, since the energy absorbed by the scintillator layer is divided into two, the lower limit of β-ray energy measurement is inevitably pushed up, and there is a problem that low-energy β-rays cannot be measured.

  The present invention seeks to obtain a radiation measurement system capable of stably measuring β-rays to be measured with high sensitivity and high accuracy without being affected by environmental β-rays.

The radiation measurement system according to the present invention includes a first reactant that reacts with radiation and environmental γ-rays emitted from the measurement object, a first β-ray shield that blocks β-rays emitted from the measurement object, A second reactant that receives radiation radiated from the measurement object through the first β-ray shield and reacts with environmental γ-rays, and a second reactant that blocks environmental β-rays to the second reactant. A β-ray shield, a conversion unit that converts the results of the reaction of the first reactant and the second reactant with radiation into a counting signal, and a counting signal converted by the conversion unit are input and operated. A measurement unit that converts the output signal into an output signal and outputs the output signal, and the measurement unit γ radiated from the measured object without being affected by β rays based on the measurement result of the radiation detected by the second reactant; Effects of γ-rays to derive the degree of influence of γ-rays in proportion to the results of reaction with radiation and environmental γ-rays Based on the measurement result of the radiation detected by the deriving means and the first reactant, this measurement result compensates the γ-ray influence degree derived by the γ-ray influence degree deriving means and β emitted from the measured object Provided with a β-ray measuring means for measuring a line , comprising a container made of a β-ray shielding material through which a sample gas as a measurement object is passed, and the container being the first β-ray shielding The first reactant is provided on the inner surface of the container, and the second reactant is provided on the outer surface of the container .

According to the present invention, β-rays to be measured can be stably measured with high sensitivity, high accuracy and without being affected by environmental β-rays , and the detection unit is small and simple, and can be carried at a low cost. You can get a system.

It is a block diagram which shows the structure of the radiation monitor or radioactivity contamination inspection apparatus concerning Embodiment 1 by this invention. It is a block diagram which shows the structure of the detection part concerning Embodiment 1 by this invention. It is a block diagram which shows the structure of the strip scintillation fiber concerning Embodiment 1 by this invention. It is a block diagram which shows the structure of the detection part concerning Embodiment 2 by this invention. It is a block diagram which shows the structure of the radiation monitor concerning Embodiment 3 by this invention. It is a block diagram which shows the structure of the detection part concerning Embodiment 4 by this invention. It is the upper side figure and side view which show the structure of the radioactive contamination inspection apparatus concerning Embodiment 5 by this invention. It is a side view which shows the structure of the radioactive contamination inspection apparatus concerning Embodiment 6 by this invention. It is a block diagram which shows the radiation monitor concerning Embodiment 7 by this invention. It is a block diagram which shows the radiation monitor concerning Embodiment 8 by this invention. It is a side view which shows the radiation monitor concerning Embodiment 9 by this invention.

Embodiment 1 FIG.
A first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a block diagram showing a configuration of a radiation monitor or a radioactive contamination inspection apparatus according to the first embodiment. FIG. 2 is a block diagram illustrating a configuration of the detection unit according to the first embodiment. FIG. 3 is a block diagram showing the configuration of the strip scintillation fiber according to the first embodiment.

  FIG. 1 shows a configuration of a radiation monitor or a radioactive contamination inspection apparatus according to the present invention. A detection unit 2 detects radiation emitted from a measurement object 1 and outputs a voltage pulse signal. The measuring unit 3 inputs the voltage pulse signal, converts it into an engineering value, and outputs it. The output of one or more detection units 2 is input to the measurement unit 3. Here, the DUT 1 is sample gas, filter paper that collects dust in the sample gas, radioactive solid waste, and the like.

FIG. 2 shows the configuration and structure of the detection unit 2. The β-ray shield 22 is a metal plate or a plastic material in which metal powder having a large atomic number such as Ti is kneaded when flexibility is required. A formed plastic member such as a plate member, the first belt-like scintillation fiber 21a is fixed on the measured object 1 side, and the second belt-like scintillation fiber 21b is fixed on the opposite side. It is optically joined to the photomultiplier tube 23a and the second photomultiplier tube 23b. Further, the outputs of the first photomultiplier tube 23a and the second photomultiplier tube 23b are input to the first preamplifier 24a and the second preamplifier 24b, respectively.
The number of combinations of the first belt-like scintillation fiber 21 a and the second belt-like scintillation fiber 21 b fixed to the β-ray shield 22 is determined according to the required detection sensitivity or the area of the measured object 1.
If a radiation monitor or a radioactive contamination inspection device is permanently installed and the environment γ rays have directionality, the number of second strip scintillation fibers 21b is reduced relative to the number of first strip scintillation fibers 21a. Also good.

  FIG. 3 shows the configuration and structure of a strip scintillation fiber. The strip scintillation fiber 21 is formed by sequentially bending plastic scintillation fibers 211a, 211b, 211c... 211n on a flexible substrate 212 in a U shape. Straight portions sp other than the part cp bent in a semicircle are bonded in parallel to each other, end portions ep are bundled, and end surfaces thereof are processed into a plane for optical joining, The whole is covered with a light shielding film 213 except for the end face. The plastic scintillation fibers 211a, 211b, 211c,... 211n can be automatically wired on the substrate 212 without breaking when using ones having an outer diameter of 0.3 mm or less. 0.25 mm can be used.

Next, the operation will be described. Fluorescence emitted as a result of radiation entering the scintillation fiber 211 constituting the first belt-like scintillation fiber 21a is transmitted to the end face while being refracted inside, and is incident on the first photomultiplier tube 23a. When fluorescence enters the first photomultiplier tube 23a, electrons are emitted and the electrons are multiplied and converted into current pulses. The first preamplifier 24a converts the current pulse into a voltage pulse and outputs the voltage pulse.
Similarly, the fluorescence emitted as a result of radiation incident on the scintillation fiber 211 constituting the second strip scintillation fiber 21b is transmitted to the end face while being refracted inside, and is incident on the second photomultiplier tube 23b. The second preamplifier 24b converts the current pulse into a voltage pulse and outputs the voltage pulse.

  The first belt-like scintillation fiber 21a detects β-rays and γ-rays emitted from the measurement object 1, and further detects γ-rays incident from the environment. At this time, the probability of detecting γ rays is as low as 1/100 or less than the probability of detecting β rays. The second belt-like scintillation fiber 21b detects γ rays emitted from the measurement object 1 and further γ rays incident from the environment. Β rays emitted from the measurement object 1 are blocked by a β ray shield 22. Further, a part of β rays incident on the valleys between the scintillation fibers 211 of the first strip scintillation fiber 21a are back-scattered by the shield 22 and incident on the first strip scintillation fiber 21a again, thereby contributing to counting. To do.

The voltage signal pulse output from the first preamplifier 24 a and the voltage pulse output from the second preamplifier 24 b are respectively input to the measurement unit 3, counted at a fixed period, and provided in the measurement unit 3. computed by the arithmetic unit first strip scintillation fiber 21a is counting rate n _b of the counting index n _a and a second strip-shaped scintillation fiber 21b corresponding to radiation detected corresponds to the radiation detected is determined.
Counting index n _a of the first strip-shaped scintillation fiber 21a corresponds to the radiation detected is by counting index n _{a (beta)} and γ-rays emitted from the object to be measured 1 by beta rays emitted from the object to be measured 1 This is the sum of the count rate n _a (γ _s ) and the count rate n _a (γ _e ) due to gamma rays incident from the environment.
The count rate n _b of the second strip-shaped scintillation fiber 21b corresponds to the radiation detected, count rate n by counting rate n _{b (gamma s)} and gamma-rays entering from the environment by gamma-rays emitted from the object to be measured 1 It is the sum of _b (γ _e ).
Therefore, the net count rate n _N = n _a (β) is expressed by the following equation (1).
_{n a (β) = n a} -n a (γ s) -n a (γ e) = n a - {k s × n b (γ s) + k e × n b (γ e)} ......... ( Here, the counting rate n _a (γ _s ) by the γ-rays radiated from the measured object 1 detected by the first strip scintillation fiber 21a is the measured object detected by the second strip scintillation fiber 21b. 1 is proportional to the count rate n _b (γ _s ) due to the γ rays radiated from 1, and the proportional count is k _s , which is expressed by the following equation (3).
n _a (γ _s ) = k _s × n _b (γ _s ) (2) Equation (2) Also, the counting rate n _a (γ _e ) due to γ rays incident from the environment detected by the first strip scintillation fiber 21a. is proportional to the count rate of the second strip-shaped scintillation fiber 21b is gamma rays incident from the detected environmental n _{b (gamma e),} when the proportional coefficient a k _e, those represented by the following formula (3) is there.
n _a (γ _e ) = k _e × n _b (γ _e ) (3) When k _s = k _e = k, the counting rate n _a (β (β) emitted from the measurement object 1 ) Is expressed by the following equation (4).
_{n a (β) = n a} -k × n b ......... (4) equation Thus, calculated or if it experimentally determined coefficient k, calculating the k × _{n b} in (4) can be, and can be calculated count rate n _{a (β)} is subtracted the k × n _b from the counting rate n _a, it is possible to measure the beta rays emitted from the object to be measured 1.

Here, k × n _b in the expression (4), the second strip-shaped scintillation fiber 21b indicates a gamma ray impact derived by counting rate n _b corresponding to radiation detected, gamma rays impact k × arithmetic unit measuring portion 3 for deriving the n _b constitutes the γ-ray influence deriving means.
Then, the γ-ray influence k × n _b of the first band-shaped scintillation fiber 21a is compensated for counting index n _a which corresponds to the radiation detected count rate n _a by emitted β-rays from the object to be measured 1 The arithmetic unit of the measurement unit 3 that calculates (β) constitutes β-ray measurement means.

  As described above, the detection unit 2 of the radiation monitor or the radioactive contamination inspection apparatus is arranged in the order of the first strip scintillation fiber 21a, the β-ray shield 22 and the second strip scintillation fiber 21b in order from the measured object 1. The influence of γ rays is estimated based on the measurement result of the radiation detected by the second strip scintillation fiber 21b, and the influence of the γ rays is compensated from the measurement result of the radiation detected by the first strip scintillation fiber 21a. As a result, even if the environmental γ-ray changes by moving the radiation monitor or the radioactive contamination inspection device, the β-ray emitted from the surface of the measurement object 1 and the γ-ray emitted from the inside Even if the ratio changes, the β ray to be measured can be measured with high sensitivity and high accuracy.

  Further, utilizing β-rays that enter a substance with a large atomic number, the backscattering increases, and a metal plate or a metal powder such as Ti is kneaded as the β-ray shield 22 if flexibility is required. By using a plastic plate or the like, a part of β rays incident on the valleys between the scintillation fibers 211a, 211b, 211c,. Since it is incident on the single band scintillation fiber 21a and contributes to counting, the detection sensitivity of the measurement object is increased.

  Further, with respect to the first belt-like scintillation fiber 21a and the second belt-like scintillation fiber 21b, plastic scintillation fibers 211a, 211b, 211c,. The plastic scintillation fibers 211a, 211b, 211c,... 211n can be automatically wired without breakage by bending and sequentially shifting and sticking, and the manufacturing cost can be reduced to 1/3 or less of the conventional one. When it is desired to manually wire, thin plastic scintillation fibers 211a, 211b, 211c... 211n generally have a minimum diameter of 1 mm, avoiding small diameters, due to an increase in work amount and a decrease in workability. However, since it becomes possible to use a small diameter by automation, and the γ sensitivity can be suppressed, β rays can be measured with high sensitivity.

(1A) According to Embodiment 1 of the present invention, the first reactant comprising the strip scintillation fiber layer 21a that reacts with the radiation radiated from the measurement object 1 and the environmental γ-rays, is emitted from the measurement object. a β-ray shield that blocks β-rays, a second reactant comprising a scintillation fiber layer 21b that receives radiation emitted from the object to be measured via the β-ray shields and reacts with environmental γ-rays, the first reactant A conversion unit comprising a detection unit 2 for converting the results of the reaction of the reactant and the second reactant to radiation into a counting signal comprising a pulse signal, respectively, and inputting the counting signal converted by the conversion unit A measurement unit 3 that converts and outputs an engineering value is provided, and the measurement unit 3 derives an influence degree of γ rays based on a measurement result of radiation detected by the second reactant. Means, Based on the measurement result of the radiation detected by the first reactant, the measurement result is compensated for the γ-ray influence degree derived by the γ-ray influence degree deriving means, and the β ray emitted from the measurement object is measured. Since the radiation measurement system is configured as a radiation monitor or radioactive contamination inspection device characterized by providing a β-ray measurement means, the environmental γ-rays change when the radiation monitor or radioactive contamination inspection device is moved. In addition, even if the ratio of β rays emitted from the surface of the measurement object 1 and γ rays emitted from the inside changes, a radiation monitor that can measure β rays to be measured with high sensitivity and high accuracy, or A radiation measurement system as a radioactive contamination inspection apparatus can be obtained.

(1B) According to the first embodiment of the present invention, the first and second reactants composed of the scintillation fiber layers 21a and 21b are made of plastic on the flexible light-shielding substrate 212 in the configuration in the section (1A). The scintillation fibers 211a, 211b, 211c,... 211n are bent into a U-shape, sequentially shifted, adhered and adhered, and the plastic scintillation fibers 211a, 211b, 211c,. Since the radiation measurement system as the radiation monitor or the radioactive contamination inspection apparatus is configured, even if the environmental γ-rays are changed by moving the radiation monitor or the radioactive contamination inspection apparatus, the radiation is emitted from the surface of the measurement object 1. Even if the ratio of β-rays emitted and γ-rays emitted from inside changes, It is possible to obtain a radiation measurement system the β line of the target as a radiation monitor or radioactive contamination inspection system for a small and simple structure can be measured with high sensitivity and high accuracy.

(1C) According to the first embodiment of the present invention, the plastic scintillation fibers 211a, 211b, and 211c constituting the first and second reactants composed of the scintillation fiber layers 21a and 21b in the configuration in the above (1B) section. Since the outer diameter of 211n is set to 0.3 mm or less, wiring work of scintillation fibers 211a, 211b, 211c,... 211n can be performed by automation, and a small diameter can be used by automation, and γ sensitivity can be suppressed. It is possible to obtain a radiation measurement system as a radiation monitor or a radioactive contamination inspection device that can measure the sensitivity of the radiation.

(1D) According to the first embodiment of the present invention, in any of the configurations from (1A) to (1C), a metal or a plastic member kneaded with metal is used as the β-ray shield. Therefore, it is possible to obtain a radiation measurement system as a radiation monitor or a radioactive contamination inspection apparatus capable of improving the detection sensitivity of β rays and measuring β rays with higher sensitivity.

Embodiment 2. FIG.
A second embodiment of the present invention will be described with reference to FIG. FIG. 4 is a block diagram illustrating a configuration of a detection unit according to the second embodiment.
In the second embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in the first embodiment described above, and exhibits the same operation. In the drawings, the same reference numerals indicate the same or corresponding parts.

  In the first embodiment, the detection unit 2 of the radiation monitor or the radioactive contamination inspection apparatus includes the first strip scintillation fiber 21a, the β-ray shield 22 and the second strip scintillation fiber 21b in order from the measured object 1 side. Although arranged in this order, in the second embodiment, as shown in FIG. 4, the first strip scintillation fiber 21a, the first β-ray shield 22a, the second strip scintillation fiber 21b, Since the second β-ray shields 22b are arranged in this order, natural radon / tron gas is released from the concrete in the room where the detection unit 2 is installed, and dust containing its progeny nuclides adheres to the detection unit 2. Since the second β-ray shield 22b blocks the β-rays emitted from the dust, the second belt-like shield is formed by the β-rays emitted from the dust. There is no conventional event that switch configuration fiber 21b malfunctions, the β rays to be measured can be measured with stable accuracy.

(2A) According to the second embodiment of the present invention, the first reactant comprising the strip scintillation fiber layer 21a that reacts with the radiation radiated from the measured object 1 and the environmental γ-rays is emitted from the measured object. a first β-ray shield 22a for blocking β-rays, a second reactant comprising a scintillation fiber layer 21b that receives radiation emitted from the measurement object through the β-ray shields and reacts with environmental γ-rays, The second β-ray shield 22b that blocks the environmental β-rays to the second reactant composed of the scintillation fiber layer 21b, and the results of the reaction of the first reactant and the second reactant with radiation are respectively pulsed. A conversion unit including a detection unit 2 that converts a signal into a counting signal, and a measurement unit 3 that inputs the calculation signal converted by the conversion unit, calculates the engineering signal, and outputs the engineering value. The measurement unit 3 includes γ-ray influence degree deriving means for deriving the degree of influence of γ-rays based on the measurement result of the radiation detected by the second reactant, and the radiation detected by the first reactant. And a β-ray measuring means for measuring the β-ray emitted from the measured object by compensating the γ-ray influence degree derived by the γ-ray influence degree deriving means based on the measurement result of Since the radiation measurement system as the characteristic radiation monitor or radioactive contamination inspection apparatus is configured, even if the environmental γ-ray changes by moving the radiation monitor or radioactive contamination inspection apparatus, the measurement object 1 Even if the ratio of β-rays emitted from the surface and γ-rays emitted from the inside changes, the β-rays to be measured can be measured with high sensitivity and high accuracy, and the β-rays to be measured can be measured with stable accuracy. Radiation monitor or radioactive contamination inspection equipment It is possible to obtain a radiation measurement system as.

Embodiment 3 FIG.
A third embodiment of the present invention will be described with reference to FIG. FIG. 5 is a block diagram showing the configuration of the radiation monitor according to the third embodiment.
In the third embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in the first embodiment or the second embodiment described above, and exhibits the same operation. It is. In the drawings, the same reference numerals indicate the same or corresponding parts.

In the second embodiment, for the detection unit 2 of the radiation monitor, the strip scintillation fiber 21a, the first β-ray shield 22a, the second strip scintillation fiber 21b, and the second β-ray shield are sequentially provided from the measured object 1 side. Although the body 22a is arranged in this order, the third embodiment includes the sampling unit 4 as shown in FIG. 5, and the measured object 1 is a sample gas containing radioactivity, and the first β-ray shield 22a (FIG. 4), the sample gas is introduced into a cylindrical sample container 25 that blocks β rays, and a plate scintillator 26 disposed in the sample container 25 instead of the first strip scintillation fiber 21a A pulse signal is output as a result of the reaction with β-rays, γ-rays, and environmental γ-rays emitted from the radioactivity. A second strip scintillation fiber 21b covered with an equivalent cover 27 is arranged so as to be parallel to the plate scintillator 26. If the second strip scintillation fiber 21b is arranged so as to be parallel to the plate scintillator 26, the influence of the environmental γ rays can be accurately compensated even when the environmental γ rays have directionality.
The sampling unit 4 includes a filter 41 and a pump 42, and the sample gas as the measured object 1 sampled from the measurement point s by the pump 42 is removed from the dust by the filter 41 and introduced into the sample container 25. Is exhausted.
Based on the measurement result of the radiation detected by the second strip scintillation fiber 21b covered with the cover 27, the influence of the environmental γ ray is estimated, and the influence of the γ ray is determined from the measurement result of the radiation detected by the plate scintillator 26. Is compensated to measure β rays and γ rays emitted from the sample gas.
In this case, γ-rays radiated from the sample gas are measured as β-rays, but this does not hinder measurement. Rather, sensitivity is improved by measuring β-rays and γ-rays emitted from the sample gas.

  By configuring as described above, background compensation can be easily added to a radiation monitor using the plate scintillator 26 using an inexpensive plastic plate material, and a highly sensitive and accurate radiation monitor can be manufactured at low cost. Can be realized.

(3A) According to the third embodiment of the present invention, the β-ray blocking that blocks the β-ray emitted from the radioactivity of the DUT 1 while passing the DUT 1 made of a gas containing radioactivity through the inside. A container 25 formed of a material, and a plastic plate that is disposed in the container 25 and has a plane that receives radiation and environmental γ-rays emitted from the DUT 1 and reacts with the radiation and environmental γ-rays. A first reactant comprising a plate-like scintillator 26, which is disposed outside the container 25 and is covered with an enveloping member comprising a cover 27 having the same degree of attenuation of environmental γ rays as the container 25. The second reactant comprising the second strip scintillation fiber 21b that receives environmental γ rays and reacts with the environmental γ rays on a plane parallel to the plane of the part, the first reactant and the second reactant are exposed to radiation. Reacted Each of which is converted into a counting signal, and a measuring unit 3 that inputs the calculation signal converted by the converting unit, calculates it, converts it into an engineering value, and outputs it. Γ-ray influence degree deriving means for deriving the degree of influence of γ-rays based on the measurement result of the radiation detected by the reactant, and derivation of the γ-ray influence degree based on the measurement result of the radiation detected by the first reactant And a β-ray measuring means for measuring the β-rays emitted from the measured object by compensating the degree of γ-ray influence derived by the means, so that the environment γ can be moved by moving the radiation monitor or the radioactive contamination inspection device. Even if the line changes or the ratio of the β ray emitted from the surface of the DUT 1 and the γ ray emitted from the inside changes, the β ray to be measured is measured with high sensitivity and high accuracy. And an inexpensive radiation monitor with added background compensation. It can be obtained in the radiation measurement system.

Embodiment 4 FIG.
A fourth embodiment of the present invention will be described with reference to FIG. FIG. 6 is a block diagram illustrating a configuration of a detection unit according to the fourth embodiment.
In the fourth embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in the first embodiment or the second embodiment described above, and exhibits the same operation. It is. In the drawings, the same reference numerals indicate the same or corresponding parts.

In the first and second embodiments, the end portions of the first strip scintillation fiber 21a and the second strip scintillation fiber 21b in the radiation monitor or the detection unit 2 of the radioactive contamination inspection apparatus are respectively the first photomultiplier tubes. 23a and the second photomultiplier tube 23b are optically joined. In the fourth embodiment, as shown in FIG. 6, the first band-like scintillation fiber 21a has a first photomultiplier at both ends of the scintillation fiber 211, respectively. Optically joined to the double tube 23a and the third photomultiplier tube 23c and connected to the corresponding first preamplifier 24a and third preamplifier 24c. Output a digital pulse when
Similarly, the second strip scintillation fiber 21b is optically joined to the second photomultiplier tube 23b and the fourth photomultiplier tube 23d at both ends of the scintillation fiber 211, respectively, and the corresponding second preamplifier 24b, A digital pulse is output when each of the outputs connected to the fourth preamplifier 24 d is simultaneously input with a pulse signal by the coincidence counting circuit 28. Each digital pulse is input to the measurement unit 3 and counted at a fixed period, and the β ray to be measured is measured in the same manner as in the first embodiment.

  As described above, by configuring the detection unit of the radiation monitor or the radioactive contamination inspection apparatus, the fluorescence generated by the reaction of radiation with the scintillation fiber 211 is simultaneously incident on the two photomultiplier tubes, and as a result. The digital pulse signal of the coincidence circuit 28 is counted, and the probability of coincidence of the noise pulse of the photomultiplier tube is rare, and the pulse signal is counted by entering the noise region of the photomultiplier tube. Therefore, even low energy β rays can be measured with high sensitivity.

(4A) According to the fourth embodiment of the present invention, the items (1A) to (1D) in the first embodiment, the (2A) term in the second embodiment, and the (3A) term in the third embodiment. In either of the configurations, the first and second reactants formed in a strip shape composed of the strip scintillation fibers 21a and 21b, and both ends of each strip reactant constituting the first and second reactants, respectively. Since the coincidence counting means comprising the coincidence counting circuit 28 for simultaneously counting the counting signals received and output and the measurement unit 3 (see FIG. 1) for measuring radiation according to the output of the coincidence counting means are provided. Even if the environmental γ-rays are changed by moving the radiation monitor or the radioactive contamination inspection device, the ratio of the β-rays emitted from the surface of the measurement object 1 to the γ-rays emitted from the inside is also increased. It is possible to obtain an inexpensive radiation monitor or a radiation measurement system as a radioactive contamination inspection apparatus that can measure β-rays to be measured with high sensitivity and high accuracy, and can measure β-rays with low energy with high sensitivity. it can.

Embodiment 5 FIG.
A fifth embodiment of the present invention will be described with reference to FIG. FIG. 7A is a top view showing the configuration of the radioactive contamination inspection apparatus according to the fifth embodiment. FIG.7 (b) is a side view which shows the structure of the radioactive contamination inspection apparatus concerning Embodiment 5. FIG.
In the fifth embodiment, the configuration other than the specific configuration described here has the same configuration content as the configuration in the first embodiment or the second embodiment described above, and exhibits the same operation. It is. In the drawings, the same reference numerals indicate the same or corresponding parts.

  In the first and second embodiments, the case where the detection unit 2 of the radioactive contamination inspection apparatus is fixed has been described. In the fifth embodiment, the detection unit moving device 6 is provided as shown in FIG. An upper moving mechanism 61 that horizontally moves the flat plate-like detection unit 2A so as to cover the upper end surface of the drum can 11 that is a measurement object placed on the gantry 5 and a lower end surface of the drum can 11 so as to cover the upper end surface. A lower moving mechanism 62 that horizontally moves another flat detection unit 2B, and a left moving mechanism 63 that moves the half-cylindrical detection unit 2C so as to cover the left side surface of the peripheral surface of the drum 11. A right-side moving mechanism 64 that moves another half-cylindrical detection unit 2D so as to cover the right side surface of the peripheral surface of the drum can 11 is provided.

The illustrated state in FIG. 7A shows a measurement preparation state. The drum 11 that is the object to be measured is placed on the gantry 5.
In order to shift to the measurement state, first, the illustrated right-side detection unit 2C and the left-side detection unit 2D in the shape of a half cylinder facing the peripheral surface of the drum 11 with the drum 11 interposed therebetween are the left-side moving mechanism 63 and the right-side unit. The moving mechanism 64 is moved in the direction approaching the peripheral surface of the drum can 11 and is stopped at a predetermined measurement position with a predetermined distance from the peripheral surface of the drum can 11.
Next, the flat plate-like detection units 2A and 2B respectively facing the upper and lower end surfaces of the drum can 11 are stopped by the upper moving mechanism 61 and the lower moving mechanism 62 at a predetermined measurement position maintaining a predetermined distance from the upper and lower end surfaces of the drum can 11. .
In this measurement state, the peripheral surface of the drum can 11 is covered with the detection units 2C and 2D that maintain a predetermined distance from the peripheral surface of the drum can 11, and the upper and lower end surfaces of the drum can 11 maintain a predetermined distance from the upper and lower ends of the drum can 11. Measurement is performed by the detection units 2A, 2B, 2C, and 2D that are covered with the detection units 2A and 2B and cover the entire drum 11.

  By comprising as mentioned above, the influence of the gamma ray radiated | emitted from the radioactive substance in a drum can can be excluded, and the radioactive contamination of the drum can surface can be measured with high sensitivity and accuracy. In addition, exposure can be reduced by measuring remotely.

(5A) According to Embodiment 5 of the present invention, any one of the configurations from (1A) to (1D) in Embodiment 1 and (2A) in Embodiment 2 In FIG. 2, the first and second belt-like scintillation fibers 21a and 21b (see FIG. 2) are disposed on both sides of the measured object so as to surround the circumferential surface of the measured object having a cylindrical shape composed of the drum can 11. The first and second detectors 2C and 2D composed of the first and second reactants and the β-ray shield 22 (see FIG. 2) are arranged on a peripheral surface of the measured object including the drum 11. First and second strip scintillation frames disposed on both sides of the end face of the object to be measured comprising the first and second moving mechanisms 63 and 64 for moving to the measurement position and the drum 11 respectively. The third and fourth detectors 2A and 2B composed of the first and second reactants and β-ray shields 22 (see FIG. 2) made of Iber 21a and 21b (see FIG. 2) are measured. Third and fourth moving mechanisms 61 and 62 for moving to a predetermined measurement position facing the end face of the body 1, the first and second detectors 2C and 2D, and the third and fourth detectors 2A , 2B to the predetermined measurement position so as to cover the measurement object, the measurement unit 3 uses the counting signals output from the first and second detection units and the third and fourth detection units. (See FIG. 1) Radiation was measured to inspect the radioactive surface contamination of the object to be measured, so that γ-rays radiated from the radioactive substance in the cylindrical object to be measured such as the drum 11 can be obtained. The surface of the object to be measured has a cylindrical shape with the influence removed It is possible to obtain a radiation measurement system as radioactive contamination inspection apparatus capable of measuring accurately the Ino contaminated with high sensitivity.

Embodiment 6 FIG.
A sixth embodiment of the present invention will be described with reference to FIG. FIG. 8 is a side view showing the configuration of the radioactive contamination inspection apparatus according to the sixth embodiment.
In the sixth embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in the first embodiment described above, and has the same function. In the drawings, the same reference numerals indicate the same or corresponding parts.

  In the first and second embodiments, the case where the detection unit 2 of the radioactive contamination inspection apparatus is fixed has been described. In the sixth embodiment, as shown in FIG. 8, an automatic traveling robot that travels on the floor surface. 7 includes a detection unit 2, a measurement unit 3, and a self-position measuring device 8. The self-position measuring device 8 measures the position of the automatic traveling robot 7, and the first and second belt-like scintillation fibers 21a, 21b and β-rays are measured. The detection unit 2 having the shield 22 (see FIG. 2) detects β-rays radiated from the radioactivity on the floor surface, and the measurement unit 3 emits γ-rays from K-40 emitted from the concrete and the descendants of Radon Tron. Radioactivity contamination on the floor surface is automatically measured by compensating for γ-rays caused by nuclides, recorded in the recording device 3A, and the recorded measurement results are processed and displayed on a map. Quick and accurate execution , It is possible to reduce the exposure by the measurement work.

(6A) According to the sixth embodiment of the present invention, the detection unit 2 and the measurement unit 3 having the first and second strip scintillation fibers 21a and 21b and the β-ray shield 22 (see FIG. 2) are mounted. From automatic traveling means consisting of an automatic traveling robot 7 that automatically travels on the floor, position identification means consisting of a self-position measuring device 8 that identifies the position of the automatic traveling means, and a recording device 3A that records measurement positions and measurement results And the recording position is recorded by the recording means while the position identification means identifies the position of the automatic traveling means and the surface contamination of the floor surface is automatically inspected. It is possible to obtain a radiation measurement system as a radioactive contamination inspection apparatus that can automatically measure and record radioactive contamination and perform measurement work quickly and accurately without being affected by the exposure. Kill.

Embodiment 7 FIG.
A seventh embodiment of the present invention will be described with reference to FIG. FIG. 9 is a block diagram showing a radiation monitor according to the seventh embodiment.
In the seventh embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configuration in any of the first to third embodiments described above, and is similar. It has an effect. In the drawings, the same reference numerals indicate the same or corresponding parts.

  The detection unit 2 of the radiation monitor according to the third exemplary embodiment detects the radiation of the sample gas with the plate scintillator 26 disposed in the sample container 25, and the second belt-like shape covered with the cover 27 outside the sample container 25. Although the scintillation fiber 21b is arranged so as to be parallel to the plate scintillator, in the seventh embodiment, β-ray shielding is used instead of the plate scintillator 26 (see FIG. 5) as shown in FIG. A first strip scintillation fiber 21a is formed on the inner surface of the sample container 25 made of a body, and a second strip scintillation fiber 21b (see FIG. 5) covered with a cover 27 outside the sample container 25 is placed on the outer surface of the sample container 25. Since the two strip scintillation fibers 21b are installed, the detection unit 2 is small and simple, and a low-priced portable radiation monitor can be realized. .

Here, the sample gas as the DUT 1 sampled from the measurement point s by the pump 42 is dust removed by the filter 41, introduced into the sample container 25, and exhausted by the pump 42.
The radiation measurement of the sample gas as the measurement target 1 introduced into the sample container 25 is performed based on the measurement result of the radiation detected by the second strip scintillation fiber 21b provided on the outer surface of the sample container 25. The effect of γ rays is compensated from the measurement result of the radiation detected by the first strip scintillation fiber 21a provided on the inner surface of the sample container 25, and the β rays and γ emitted from the sample gas are estimated. Measure the line.

(7A) According to the seventh embodiment of the present invention, the items (1A) to (1D) in the first embodiment, the item (2A) in the second embodiment, and the item (4A) in the fourth embodiment. In any of the configurations, a container 25 made of a β-ray shielding material through which a sample gas as the measurement object 1 is passed is provided, and the container 25 is the β-ray shielding layer or the first β-ray shielding body. The second reactant is formed as a layer, and the first reactant comprising the first strip scintillation fiber 21a is provided on the inner surface of the container 25, and the second reactant comprising the second strip scintillation fiber 21b on the outer surface of the container. Is provided in parallel with each other at the position facing the first reactant, so that the detection unit 2 is small and simple, and a radiation measurement system as a portable radiation monitor with low cost is realized. Kill.

Embodiment 8 FIG.
An eighth embodiment of the present invention will be described with reference to FIG. FIG. 10 is a block diagram showing a radiation monitor according to the eighth embodiment.
In the eighth embodiment, the configuration other than the specific configuration described here has the same configuration contents as those in the first to third embodiments and the seventh embodiment described above, It has the same effect. In the drawings, the same reference numerals indicate the same or corresponding parts.

  In the radiation monitor of the seventh embodiment, the sample gas is introduced into the sample container 25 by the pump 42. However, in the eighth embodiment, as shown in FIG. Is introduced into the sample container 25, the configuration of the radiation monitor is simplified, and in the application of measuring the radioactivity in the air in the chamber (not shown), the glove box (not shown) In the application for measuring the radioactivity of the air inside, the detection unit 2 is small and simple, and a radiation monitor with high sensitivity and low cost can be realized.

(8A) According to the eighth embodiment of the present invention, in the configuration according to the item (7A) in the seventh embodiment, the container 25 is provided with the blower fan 9 for blowing the sample gas as the measured object 1, Since the radioactivity concentration in the sample gas blown into the container 25 by the blower fan 9 is measured, the detection unit 2 becomes small and simple, and radiation measurement as a radiation monitor with high sensitivity and low cost. A system can be realized.

Embodiment 9 FIG.
A ninth embodiment of the present invention will be described with reference to FIG. FIG. 11 is a side view showing a radiation monitor according to the ninth embodiment.
In the ninth embodiment, the configuration other than the specific configuration described here has the same configuration contents as the configurations in the first to third embodiments and the seventh embodiment described above, It has the same effect. In the drawings, the same reference numerals indicate the same or corresponding parts.

In the radiation monitor of the eighth embodiment, the sample gas is introduced into the sample container 25 by the blower fan 9. In this ninth embodiment, the blower fan 9 is connected to one side of the sample container 25 as shown in FIG. The bellows duct 10 is connected to the opposite side, and since the blower fan 9 functions as ventilation and sample gas introduction, a highly sensitive and low cost radiation monitor can be realized.
The bellows duct 10 constitutes an exhaust duct that can be bent and expands and contracts in the axial direction. The bellows duct 10 communicates the internal space of the sample container 25 with the external space outside and is introduced into the sample container 25 by the blower fan 9. The sample gas whose radiation has been measured is discharged to the external space, and the room in which the sample container 25 is provided is also ventilated.
Needless to say, when the existing equipment has a bellows duct and a blower fan, the blower fan of the existing equipment can be used as the blower fan 9 or the bellows duct of the existing equipment can be used as the bellows duct 10.

(9A) According to the ninth embodiment of the present invention, in the configuration according to the item (7A) in the seventh embodiment, the sample gas as the measurement object 1 passed through the container 25 is discharged and ventilated. Since the exhaust duct that can be bent and can be expanded and contracted in the axial direction is provided, the bellows duct 10 can be used for both ventilation and sample gas introduction, and a radiation measurement system as a radiation monitor with high sensitivity and low cost can be realized. .

  DESCRIPTION OF SYMBOLS 1 Measured object, 11 drum can, 2 detector, 21 strip scintillation fiber, 21a first strip scintillation fiber, 21b second strip scintillation fiber, 211 scintillation fiber, 212 flexible substrate, 213 light shielding film, 22 β Ray shield, 22a first beta ray shield, 22b, 23 photomultiplier tube, 23a first photomultiplier tube, 23b second photomultiplier tube, 23c third photomultiplier tube, 23d first 4 photomultiplier tube, 24 preamplifier, 24a first preamplifier, 24b second preamplifier, 24c third preamplifier, 24d fourth preamplifier, 25 sample container, 26 plate Scintillator, 27 cover, 28 coincidence counting circuit, 3 measuring section, 4 sampling section, 41 filter, 42 pump 5 gantry, 6 detector moving mechanism, 61 an upper moving mechanism, 62 lower moving mechanism, 63 a left portion moving mechanism, 64 the right portion moving mechanism, 7 automatic mobile robot, 8 self-position measuring device, 9 blowing fan, 10 a bellows duct.

Claims (8)

A first reactant that reacts with radiation and environmental γ rays emitted from the measurement object, a first β-ray shield that blocks β rays emitted from the measurement object, and radiation emitted from the measurement object A second reactant that reacts with the receiving environment γ-rays through the first β-ray shield, a second β-ray shield that blocks environmental β-rays to the second reactant, the first A conversion unit that converts the result of the reaction of the reactant and the second reactant to radiation into a counting signal, and a measurement signal that is input from the counting signal converted by the converting unit, calculated, converted into an output signal, and output The measurement unit includes a reaction result of γ-rays and environmental γ-rays radiated from the measurement object without being affected by β-rays based on the measurement result of the radiation detected by the second reactant. Γ-ray influence degree deriving means for deriving the degree of influence of γ-rays proportional to Things and β ray measuring means to measure based on the result of γ-ray influence which is derived by the γ-ray influence deriving means on the measurement result of the radiation to compensate for measuring the β rays emitted from the object to be measured digits set And a container made of a β-ray shielding material through which a sample gas as an object to be measured is passed. The container is configured as the first β-ray shielding body, and the first β-ray shielding body is formed on the inner surface of the container. A radiation measurement system characterized in that the second reactant is provided on the outer surface of the container . The radiation measurement system according to claim 1 , wherein the container is provided with a blower fan that blows a sample gas as a measurement object, and the radioactivity concentration in the sample gas blown by the blower fan is measured. The radiation measurement system according to claim 1 , further comprising an exhaust duct that exhausts and ventilates a sample gas as an object to be measured that is passed through the container. An automatic traveling means for automatically traveling on a floor surface by mounting a detection unit and a measurement unit composed of the first and second reactants and the first and second β-ray shields; and A position identifying means for specifying the position; and a recording means for recording the measurement position and the measurement result. The recording means records the measurement position and the measurement result while specifying the position of the automatic traveling means by the position identification means. The radiation measurement system according to any one of claims 1 to 3 , wherein surface contamination of the floor surface is automatically inspected. The scintillation fiber layers constituting the first and second reactants are formed by bending plastic scintillation fibers in a U-shape on a flexible light-shielding substrate, sequentially shifting them, and attaching them in close contact, and attaching the plastic scintillation fibers to the light-shielding film. The radiation measurement system according to any one of claims 1 to 4 , wherein the radiation measurement system is covered with. 6. The radiation monitor or radioactive contamination inspection apparatus according to claim 5 , wherein an outer diameter of the plastic scintillation fiber is 0.3 mm or less. The radiation measuring system according to any one of claims 1 to 6, wherein a metal or a plastic member kneaded with metal is used as the first and second β-ray shields. Simultaneous counting means for simultaneously counting the first and second reactants formed in a strip shape and the counting signals received and outputted at both ends of each of the strip reactants constituting the first and second reactants radiation measurement system according to any of claims 1 to 7, wherein further provided things when the.

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