JP2015206779A - Radiation visualization device, radioactive material monitoring method and radioactive material leakage detection method using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radiation visualization device which allows a user to easily, intuitively and visually grasp the dose-rate distribution.SOLUTION: In a radiation visualization device comprising: a scintillation fiber which detects a radiation of an object to be measured in an environment; photoelectric multipliers 30, 30' which convert and amplify an optical signal generated by the scintillation fiber into an electric signal; signal waveform pre-processing units 50, 50' which perform signal waveform pre-processing on the electric signal from the photoelectric multipliers 30, 30' for improving temporal resolution; a multiple peak analyzer 80 which performs classification in accordance with the intensity of the signal; and a display unit 100 which visualizes an output signal from the multiple peak analyzer 80, the display unit 100 consists of a plurality of light-emission parts arranged in a first direction in parallel to the longitudinal direction of the scintillation fiber.

Description

  The present invention relates to a radiation visualization apparatus capable of easily, intuitively and visually grasping a dose rate distribution. The present invention also relates to a radioactive substance monitoring method and a radioactive substance leakage detection method using such a radiation visualization apparatus.

  When measuring the air dose rate distribution at a decontamination site, radiation facility, radioactive waste storage facility, or the like, for example, a portable dosimeter is used.

As such a portable device, Patent Document 1 (Japanese Patent Laid-Open No. 2012-242192) discloses a GM tube survey meter.
JP 2012-242192 A

  When a conventional portable dosimeter is used to continuously investigate the dose rate distribution in a given area, the operator scans the measurement points using a portable dosimeter that is held by hand. There is a problem in that it takes time and effort to record and measure point by point, which requires time and labor.

  Thus, when a conventional portable dosimeter is used, there is a problem that it is difficult to intuitively and intuitively grasp the dose rate distribution.

  This invention solves the said subject, The invention which concerns on Claim 1 uses the scintillation fiber which detects the radiation of the to-be-measured object in an environment, and the optical signal generated with the said scintillation fiber as an electrical signal. A photomultiplier tube that converts and amplifies, a preamplifier that amplifies the signal from the photomultiplier tube into an electrical signal, and a signal waveform that preprocesses the electrical waveform amplified by the preamplifier to improve time resolution A pre-processing device, a signal from the signal waveform pre-processing device, a delay device for adjusting a time interval between a start signal and a stop signal, and a signal from the delay device, an input time difference for converting the time interval into an output magnitude A time wave height converter in which the wave height conversion is performed, and a multi-wave height analyzer that separates an output signal from the time wave height converter according to the intensity of the signal; A display unit for visualizing an output signal from the multi-wave height analyzer, wherein the display unit includes a plurality of light emitting units arranged in a first direction parallel to a longitudinal direction of the scintillation fiber. It is characterized by becoming.

  According to a second aspect of the present invention, in the radiation visualization apparatus according to the first aspect, the light emission intensity of the light emitting unit is controlled in accordance with the detected radiation dose rate.

The invention according to claim 3
The radiation visualization apparatus according to claim 1, wherein a color of the light emitting unit is controlled in accordance with a detected dose rate of radiation.

  According to a fourth aspect of the present invention, in the radiation visualization apparatus according to the first aspect, the display unit includes a first direction parallel to a longitudinal direction of the scintillation fiber and a second direction perpendicular to the longitudinal direction. It consists of a plurality of light emitting portions arranged in a matrix in the direction.

  In the invention according to claim 5, in the radiation visualization apparatus according to claim 4, it is controlled whether or not the light emitting unit arranged in the first direction is caused to emit light according to the position of the detected radiation. It is characterized by being.

  The invention according to claim 6 is the radiation visualization apparatus according to claim 4 or 5, wherein the light emitting unit arranged in the second direction is caused to emit light according to the dose rate of the detected radiation. Whether or not is controlled.

The invention according to claim 7 is characterized in that the radioactive material monitoring apparatus according to any one of claims 1 to 6 is disposed on a site boundary or a building boundary to monitor a radioactive substance. Further, the invention according to claim 8 is a building that uses or stores the radiation visualization device according to any one of claims 1 to 6. This is a radioactive substance leakage detection method using a radiation visualization device that detects the leakage of radioactive substances by being placed inside.

  The invention according to claim 9 is directed to monitoring radioactive substances by arranging the radiation visualization device according to any one of claims 1 to 6 along the transport direction of the radioactive waste transport means. It is a radioactive substance monitoring method by the radiation visualization apparatus characterized by performing.

  Since the radiation visualization apparatus according to the present invention includes a plurality of light emitting units arranged in a first direction parallel to the longitudinal direction of the scintillation fiber, according to such a radiation visualization apparatus according to the present invention, the dose rate The distribution can be easily grasped intuitively and visually.

  The radiation visualization apparatus according to the present invention includes a plurality of light emitting units arranged in a matrix in a first direction parallel to the longitudinal direction of the scintillation fiber and a second direction perpendicular to the longitudinal direction. Therefore, according to such a radiation visualization apparatus according to the present invention, the dose rate distribution can be easily and intuitively grasped visually.

  Moreover, according to the radioactive substance monitoring method according to the present invention, it is possible to constantly monitor the amount of space radiation in the facility without losing the position over a wide range. When this monitoring is performed not only remotely but also at the detection position using the LED unit of the radiation visualization device or the light emission of the LED (note that an alarm sound can be used instead of the light emission if necessary), a nearby worker Etc. can also be made known.

  Moreover, according to the radioactive substance monitoring method according to the present invention, the radiation dose can be continuously monitored over a wide range without taking up a place as compared with the conventional radioactive substance monitoring method using a spatial radiation dose monitoring device such as a monitoring post. It will be possible to reinforce the continuous monitoring system for leaked radiation from the facility and enable real-time communication with residents and local governments.

  Further, according to the radioactive substance leakage detection method according to the present invention, the amount of space radiation can be constantly monitored over a wide range and at continuous positions, and the leakage of the radioactive substance can be quickly detected. Further, since the radiation visualization device 1 is a long device, the radiation visualization device 1 can be installed in a narrow or curved space inside a building, and a radioactive substance leaks in a place where people cannot enter and exit. Can be detected quickly. When this leak detection is used not only remotely but also with the LED unit of the radiation visualization device or the light emission of the LED (note that an alarm sound can be used instead of the light emission if necessary) It is also possible to make it known.

Moreover, according to such a radioactive substance leakage detection method according to the present invention, it is possible to quickly detect a radioactive substance leaked from a facility or storage container that handles radioactive substances, and it is possible to take a prompt action. Become.

  According to such a radioactive substance monitoring method according to the present invention, it is possible to constantly monitor the amount of space radiation in the radioactive waste transporting means without being interrupted over a wide range. When this monitoring is performed not only remotely but also at the detection position using the LED unit of the radiation visualization device or the light emission of the LED (note that an alarm sound can be used instead of the light emission if necessary), a nearby worker Etc. can also be made known.

  Further, according to the radioactive substance monitoring method according to the present invention as described above, compared to the conventional radioactive substance monitoring method using a spatial radiation dose monitoring device such as a monitoring post, the radiation dose is continuously and widely spread over a wide area. Monitoring will be possible, and the continuous monitoring system around the equipment will be strengthened. Furthermore, it is possible for the worker to always know the radiation dose, and it is possible to quickly determine whether to evacuate or continue the work in an environment where the radiation dose changes every moment.

It is a figure explaining the outline | summary of the radiation visualization apparatus 1 which concerns on embodiment of this invention. It is a figure explaining the measurement principle of the radiation visualization apparatus 1 which concerns on embodiment of this invention. It is a figure which shows the relationship between the scintillation fiber bundle 20 and the display part 100 of the radiation visualization apparatus 1 which concerns on embodiment of this invention. It is a figure explaining the outline | summary of the radiation visualization apparatus 1 which concerns on other embodiment of this invention. It is a figure which shows the relationship between the scintillation fiber bundle 20 and the display part 100 of the radiation visualization apparatus 1 which concerns on other embodiment of this invention. It is a figure explaining the radioactive substance monitoring method by the radiation visualization apparatus 1 which concerns on embodiment of this invention. It is a figure explaining the radioactive substance leak detection method by the radiation visualization apparatus 1 which concerns on embodiment of this invention. It is a figure explaining the radioactive substance monitoring method by the radiation visualization apparatus 1 which concerns on embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic block diagram of a radiation visualization apparatus 1 according to an embodiment of the present invention.

  The radiation visualization apparatus 1 includes a scintillation fiber bundle 20 that is linear in the longitudinal direction, and a display unit 100 that is provided along the longitudinal direction of the scintillation fiber bundle 20. The longitudinal direction of the scintillation fiber bundle 20 is defined as the first direction. The x direction in FIG. 1 is the first direction.

  The scintillation fiber bundle 20 is formed by bundling a plurality of scintillation fibers 10. The light propagated through each scintillation fiber 10 enters the photomultiplier tubes 30 and 30 ′ provided at both ends of the scintillation fiber bundle 20.

  Here, the principle of radiation measurement using the scintillation fiber 10 will be described. FIG. 2 is a view for explaining the measurement principle of the radiation visualization apparatus 1 according to the embodiment of the present invention.

As shown in FIG. 2, the scintillation fiber 10 is similar to a normal optical fiber,
It consists of a core 11 located in the center and a clad 12 surrounding it, and a plastic scintillator that reacts with radiation is used for the core 11.

  The principle of light emission is the same as other scintillators, and scintillation light is generated by the excitation action of radiation. The light generated in the core 11 due to radiation propagates as a light pipe (light guide) by the total reflection at the boundary between the core 11 and the clad 12 as in the case of a normal optical fiber, and is located at the end. It reaches the photomultiplier tubes 30 and 30 ′ and is detected.

As shown in FIG. 2A, the refractive index n ₁ of the core 11 is set larger than the refractive index n _{2 of the} cladding (n ₁ > n ₂ ), and the critical angle θ _C.
θ _C = sin ⁻¹ (n ₂ / n ₁ )
On the other hand, if the incident angle θ _A from the core to the cladding is θ _A > θ _C , the light is reflected at the boundary surface,
If the incident angle θ _B from the core to the cladding is θ _B <θ _C , light leaks to the outside. Therefore, for example, the light emitted on the central axis propagates by repeating total reflection only of the light emitted in the cone of the critical angle by the core 11 and the clad 12 (indicated by reference numeral 14 in FIG. 6B). Will reach the photomultiplier tubes 30, 30 ′ provided at both ends.

  Details of the display unit 100 provided along the scintillation fiber bundle 20 which is a bundle of scintillation fibers 10 as described above will be described. FIG. 3 is a diagram showing a relationship between the scintillation fiber bundle 20 and the display unit 100 of the radiation visualization apparatus 1 according to the embodiment of the present invention.

  In FIG. 3, the scintillation fiber bundle 20 and a part of the display unit 100 are shown enlarged.

  The display unit 100 includes a plurality of LED units 115 arranged linearly with a first direction (x direction) parallel to the longitudinal direction of the scintillation fiber bundle 20. Such an LED unit 115 is provided on the base 110, and its light emission is controlled by the light emission control unit 90.

  As the LED unit 115, either (a) a single color whose emission intensity is variable or (b) a display capable of displaying a plurality of colors can be used. In addition, as such a display part 100, an LED tape can be used.

  In the present embodiment, it is assumed that m LED units 115 are arranged in the first direction (x direction). In FIG. 3, the n-th LED unit 115 in the first direction (x direction) It shows a state. In place of the LED unit 115, other light emitting means may be used. The number of LED units 115 arranged in the first direction (x direction) may be provided over the length of the scintillation fiber bundle 20, and is not particularly limited.

  When the scintillation fiber 10 detects radiation of the measurement object in the environment, it propagates through the scintillation fiber 10 and reaches the photomultiplier tubes 30 and 30 ′ provided at both ends of the scintillation fiber 10.

  Each photomultiplier tube 30, 30 ′ converts and amplifies the optical signal generated by the scintillation fiber 10 into an electrical signal. The preamplifiers 40 and 40 'amplify signals from the photomultiplier tubes 30 and 30' into electric signals.

  The CFD 50, 50 '(also referred to as "signal waveform pre-processing device") performs signal waveform pre-processing for improving the time resolution of the electrical signal amplified by the preamplifiers 40, 40'.

  The delay device 60 adjusts the time interval between the start signal and the stop signal for the signals from the CFDs 50 and 50 '.

  In the TAC 70 (also referred to as “time wave height converter”), input time difference wave height conversion for converting the signal from the delay device 60 into a magnitude of the output is performed.

  Further, the output signal from the TAC 70 (also referred to as “multiple wave height analyzer”) is classified according to the intensity of the signal.

  From the TAC 70, detection position information relating to which position of the scintillation fiber 10 the radiation has entered and radiation dose rate information relating to what the radiation dose is are output to the light emission control unit 90. The

  The light emission control unit 90 controls whether or not the LED units 115 arranged in the first direction (x direction) are caused to emit light according to the position of the detected radiation. That is, in the display unit 100, the LED unit 115 arranged in the first direction (x direction) serves as an indicator indicating at which position of the scintillation fiber 10 radiation has entered.

  In the case where a single color LED whose emission intensity is variable is used as the LED unit 115, the emission control unit 90 controls the emission intensity of the LED unit 115 according to the detected radiation dose rate. That is, the higher the dose rate of the detected radiation, the stronger the emission intensity of the LED unit 115.

  On the other hand, when the LED unit 115 is capable of displaying a plurality of colors, the light emission control unit 90 controls the color of the LED unit 115 according to the detected radiation dose rate. . For example, when the radiation dose rate is evaluated in three stages of low, medium and high, the LED unit 115 emits “blue” when it is at a low level, and the LED unit 115 emits “yellow” when it is at a medium level. When the level is high, control is performed so that the LED unit 115 emits light in “red”. The combination of dose rate and color is arbitrary.

The light emission control of the LED unit 115 by the light emission control unit 90 will be described with reference to FIG. As shown in FIG. 3, when radiation enters the x _n (n = _{1 to} m) section of the scintillation fiber 10 in the scintillation fiber bundle 20, in the radiation visualization apparatus 1 according to the present invention, the first direction ( In the x direction), the nth LED unit 115 is caused to emit light.

  If the LED unit 115 is a single color and the light emission intensity is variable, the nth LED unit 115 emits light with the lowest light emission intensity.

  In addition, when an LED unit 115 capable of displaying a plurality of colors is used, the LED unit 115 is caused to emit “blue” in the previous example.

  As described above, in the radiation visualization apparatus 1 according to the present invention, the display unit 100 provided along the scintillation fiber bundle 20 can indicate which position has what dose rate.

  As mentioned above, since the radiation visualization apparatus 1 which concerns on this invention is equipped with the several light emission part (LED unit 115) distribute | arranged to the 1st direction parallel to the longitudinal direction of the scintillation fiber 10, it concerns on such this invention. According to the radiation visualization apparatus 1, the dose rate distribution can be easily and intuitively grasped visually.

  Next, another embodiment of the present invention will be described. FIG. 4 is a schematic block diagram of a radiation visualization apparatus 1 according to another embodiment of the present invention.

  The radiation visualization apparatus 1 includes a scintillation fiber bundle 20 that is linear in the longitudinal direction, and a display unit 100 that is provided along the longitudinal direction of the scintillation fiber bundle 20. The longitudinal direction of the scintillation fiber bundle 20 is defined as the first direction, and the direction perpendicular to the hand direction is defined as the second direction. The x direction in FIG. 4 is the first direction, and the y direction is the second direction.

  The scintillation fiber bundle 20 is formed by bundling a plurality of scintillation fibers 10. The light propagated through each scintillation fiber 10 enters the photomultiplier tubes 30 and 30 ′ provided at both ends of the scintillation fiber bundle 20.

  Here, the principle of radiation measurement using the scintillation fiber 10 is the same as in the previous embodiment.

  Details of the display unit 100 provided along the scintillation fiber bundle 20 which is a bundle of scintillation fibers 10 as described above will be described. FIG. 5 is a diagram showing the relationship between the scintillation fiber bundle 20 and the display unit 100 of the radiation visualization apparatus 1 according to another embodiment of the present invention.

  In FIG. 5, the scintillation fiber bundle 20 and a part of the display unit 100 are shown in an enlarged manner.

  The display unit 100 is arranged in a matrix in a first direction (x direction) parallel to the longitudinal direction of the scintillation fiber bundle 20 and a second direction (y direction) perpendicular to the longitudinal direction (x direction). A plurality of LEDs 120 are provided. Such an LED 120 is provided on the base 110, and its light emission is controlled by the light emission control unit 90.

  In the present embodiment, it is assumed that m LEDs 120 are arranged in the first direction (x direction), and eight LEDs 120 are arranged in the second direction (y direction). The state of the n-th LED 120 in one direction (x direction) is shown. Note that other light emitting means may be used in place of the LED 120. The number of LEDs 120 arranged in the first direction (x direction) may be provided over the length of the scintillation fiber bundle 20, and is not particularly limited.

  In addition, since the LEDs 120 arranged in the second direction (y direction) exhibit high and low dose rates, the number of LEDs 120 arranged in the second direction (y direction) is preferably two or more.

  When the scintillation fiber 10 detects radiation of the measurement object in the environment, it propagates through the scintillation fiber 10 and reaches the photomultiplier tubes 30 and 30 ′ provided at both ends of the scintillation fiber 10.

  Each photomultiplier tube 30, 30 ′ converts and amplifies the optical signal generated by the scintillation fiber 10 into an electrical signal. The preamplifiers 40 and 40 'amplify signals from the photomultiplier tubes 30 and 30' into electric signals.

  The CFD 50, 50 '(also referred to as "signal waveform pre-processing device") performs signal waveform pre-processing for improving the time resolution of the electrical signal amplified by the preamplifiers 40, 40'.

  The delay device 60 adjusts the time interval between the start signal and the stop signal for the signals from the CFDs 50 and 50 '.

  In the TAC 70 (also referred to as “time wave height converter”), input time difference wave height conversion for converting the signal from the delay device 60 into a magnitude of the output is performed.

  Further, the output signal from the TAC 70 (also referred to as “multiple wave height analyzer”) is classified according to the intensity of the signal.

  From the TAC 70, detection position information relating to which position of the scintillation fiber 10 the radiation has entered and radiation dose rate information relating to what the radiation dose is are output to the light emission control unit 90. The

  The light emission control unit 90 controls whether or not the LEDs 120 arranged in the first direction (x direction) are caused to emit light according to the position of the detected radiation. That is, in the display unit 100, the LED 120 arranged in the first direction (x direction) serves as an indicator indicating at which position of the scintillation fiber 10 radiation has entered.

  Further, the light emission control unit 90 controls whether or not the LEDs 120 arranged in the second direction (y direction) are caused to emit light according to the detected radiation dose rate. That is, in the display unit 100, the LED 120 arranged in the second direction (y direction) serves as an indicator that indicates how much radiation has entered the scintillation fiber 10. In the present embodiment, since there are eight LEDs 120 arranged in the second direction (y direction), it is possible to notify the level of the eight-stage dose rate.

The light emission control of the LED 120 by the light emission control unit 90 will be described with reference to FIG. As shown in FIG. 5, when the radiation having the lowest dose rate among the eight dose rates is incident on the _xn (n = _{1 to} m) section of the scintillation fiber 10 in the scintillation fiber bundle 20, the present invention is applied. In the radiation visualization apparatus 1, light emission control is performed such that the first LED 120 is turned on in the nth direction in the first direction (x direction) and in the second direction (y direction).

  As described above, in the radiation visualization apparatus 1 according to the present invention, the display unit 100 provided along the scintillation fiber bundle 20 can indicate which position has what dose rate.

  The radiation visualization apparatus 1 according to another embodiment as described above is arranged in a matrix in a first direction parallel to the longitudinal direction of the scintillation fiber 10 and a second direction perpendicular to the longitudinal direction. Since a plurality of light emitting units (LEDs 120) are provided, according to the radiation visualization apparatus 1 according to such another embodiment, the dose rate distribution can be easily and intuitively grasped visually. .

Next, a method for monitoring radioactive substances and a method for detecting leakage of radioactive substances using the radiation visualization apparatus 1 configured as described above will be described. FIG. 6 is a diagram for explaining a radioactive substance monitoring method by the radiation visualization apparatus 1 according to the embodiment of the present invention.

  FIG. 6 shows a facility that handles radioactive waste 139. In such a facility, a site boundary wall 135 such as a wall or a fence is provided between the site interior 133 and the site exterior 137. In addition, in the site interior 133, a building 140 constituting a part of the facility is provided. The building 140 has a building boundary 145 such as an outer wall between the building interior 143 and the building exterior 147.

  In the radioactive substance monitoring method of the present invention, as shown in FIG. 6, the radiation visualization apparatus 1 is provided on the site boundary wall 135 or the building boundary 145, thereby monitoring the radioactive substance. Yes.

  According to such a radioactive substance monitoring method according to the present invention, it is possible to constantly monitor the amount of space radiation in a facility without discontinuing the position over a wide range. When this monitoring is performed not only remotely but also at the detection position using the light emission of the LED unit 115 or the LED 120 of the radiation visualization apparatus 1 (alternatively, an alarm sound can be used instead of the light emission) It is also possible to make known to workers and the like.

  Further, according to the radioactive substance monitoring method according to the present invention as described above, compared to the conventional radioactive substance monitoring method using a spatial radiation dose monitoring device such as a monitoring post, the radiation dose is continuously and widely spread over a wide area. It becomes possible to monitor, and the system for constantly monitoring the radiation leaked from the facility will be strengthened, enabling real-time communication with residents and local governments for safety and security.

  Next, the radioactive substance leakage detection method according to the present invention will be described. FIG. 7 is a diagram for explaining a radioactive substance leakage detection method by the radiation visualization apparatus 1 according to the embodiment of the present invention.

  FIG. 7 shows a building interior 143 of a facility that handles radioactive waste 139. For example, in such a building interior 143, it is assumed that a radioactive substance is used or stored. For example, it is assumed that a plurality of radioactive substance storage containers 150 are stored in the building interior 143 as illustrated. ing.

  In the radioactive substance leakage detection method of the present invention, as shown in FIG. 7, the radiation visualization apparatus 1 is provided on the wall part of the building interior 143 and the surrounding floor part where the plurality of radioactive substance storage containers 150 are arranged. In this way, leakage of radioactive material is detected.

  According to such a radioactive substance leakage detection method according to the present invention, it is possible to constantly monitor the amount of space radiation in a wide range and continuous positions, and to quickly detect the leakage of radioactive substances. Further, since the radiation visualization device 1 is a long device, the inside of the building 143 is narrow (for example, between the wall portion of the building 143 and the radioactive substance storage container 150, such as N in FIG. 7). It can also be installed in a space) or in a curved space, and it is possible to quickly detect a radioactive substance leak in a place where people cannot enter or leave. When this leakage detection monitoring is performed not only remotely but also using the light emission of the LED unit 115 or the LED 120 of the radiation visualization apparatus 1 (alternatively, an alarm sound can be used instead of the light emission if necessary). Etc. can also be made known.

  Moreover, according to such a radioactive substance leakage detection method according to the present invention, it is possible to quickly detect a radioactive substance leaked from a facility or storage container that handles radioactive substances, and it is possible to take a prompt action. Become.

  Next, another radioactive substance monitoring method according to the present invention will be described. FIG. 8 is a diagram for explaining a radioactive substance monitoring method by the radiation visualization apparatus 1 according to the embodiment of the present invention.

  FIG. 8 shows a building interior 143 of a facility that handles radioactive waste 139. For example, in such a building interior 143, the radioactive waste 139 is transported to the radioactive material deposition container 170 by a belt conveyor 160 which is a radioactive waste transport means.

  In the radioactive substance monitoring method of the present invention, as shown in FIG. 8, the longitudinal direction (first direction) of the radiation visualization apparatus 1 is arranged along the conveying direction of the belt conveyor 160 (radioactive substance conveying means). , Monitoring for radioactive materials. Furthermore, in the radioactive substance monitoring method of the present invention, the radiation visualization apparatus 1 is also disposed in the radioactive substance deposition container 170 to monitor the radioactive substance.

  According to such a radioactive substance monitoring method according to the present invention, it is possible to constantly monitor the amount of space radiation in the belt conveyor 160 which is a radioactive waste transport means without being interrupted over a wide range. . When this monitoring is performed not only remotely but also at the detection position using the light emission of the LED unit 115 or the LED 120 of the radiation visualization apparatus 1 (alternatively, an alarm sound can be used instead of the light emission) It is also possible to make known to workers and the like.

  Further, according to the radioactive substance monitoring method according to the present invention as described above, compared to the conventional radioactive substance monitoring method using a spatial radiation dose monitoring device such as a monitoring post, the radiation dose is continuously and widely spread over a wide area. Monitoring will be possible, and the continuous monitoring system around the equipment will be strengthened. Furthermore, it is possible for the worker to always know the radiation dose, and it is possible to quickly determine whether to evacuate or continue the work in an environment where the radiation dose changes every moment.

DESCRIPTION OF SYMBOLS 1 ... Radiation visualization apparatus 10 ... Scintillation fiber 11 ... Core 12 ... Cladding 14 ... Cone 20 ... Scintillation fiber bundle 30, 30 '... Photomultiplier tube 40, 40' ... Preamplifiers 50, 50 '... CFD (signal waveform pre-processing device)
60 ... delay device 70 ... TAC (time wave height converter)
80 ... MCA (Multiple Wave Height Analyzer)
90 ... light emission control unit 100 ... display unit 110 ... base 115 ... LED (light emitting diode) unit 120 ... LED (light emitting diode)
133 ... Inside the site 135 ... Site boundary wall 137 ... Outside the site 139 ... Radioactive waste 140 ... Building 143 ... Inside the building 145 ... Building boundary 147 ... Outside 150 ... Radioactive material storage container 160 ... Belt conveyor (radioactive waste transport means)
170 ... Radioactive material deposition container 180 ... Working / transporting machine

Claims (9)

A scintillation fiber that detects the radiation of the measurement object in the environment;
A photomultiplier tube that converts and amplifies the optical signal generated by the scintillation fiber into an electrical signal;
A preamplifier for amplifying a signal from the photomultiplier tube into an electrical signal;
A signal waveform pre-processing device that performs signal waveform pre-processing for improving the time resolution of the electrical signal amplified by the preamplifier;
A delay device for adjusting a time interval between a start signal and a stop signal, from the signal waveform pre-processing device;
A time wave height converter in which an input time difference wave height conversion is performed to convert the signal from the delay device into a time interval and an output magnitude; and
In a radiation visualization apparatus comprising: a multi-wave height analyzer that classifies an output signal from the time wave height converter according to signal intensity; and a display unit that visualizes the output signal from the multi-wave height analyzer.
The radiation visualization apparatus according to claim 1, wherein the display unit includes a plurality of light emitting units arranged in a first direction parallel to a longitudinal direction of the scintillation fiber. The radiation visualization apparatus according to claim 1, wherein the light emission intensity of the light emitting unit is controlled in accordance with a detected dose rate of radiation. The radiation visualization apparatus according to claim 1, wherein a color of the light emitting unit is controlled in accordance with a detected dose rate of radiation. The display unit includes a plurality of light emitting units arranged in a matrix in a first direction parallel to the longitudinal direction of the scintillation fiber and a second direction perpendicular to the longitudinal direction. Radiation visualization equipment. The radiation visualization apparatus according to claim 4, wherein whether or not the light emitting unit arranged in the first direction emits light is controlled according to the detected position of the radiation. 6. The radiation visualization apparatus according to claim 4, wherein whether or not to cause the light emitting unit arranged in the second direction to emit light is controlled according to the detected radiation dose rate. . A radioactive material monitoring method using a radiation visualization device, wherein the radiation visualization device according to any one of claims 1 to 6 is disposed on a site boundary or a building boundary to monitor the radioactive material. . Radioactive material leakage detection by a radiation visualizing device that detects leakage of radioactive material by arranging the radiation visualizing device according to any one of claims 1 to 6 inside a building that uses or stores the radioactive material. Method. The radiation visualization apparatus according to any one of claims 1 to 6, wherein the radiation visualization apparatus according to any one of claims 1 to 6 is disposed along a conveyance direction of the radioactive waste conveyance means to monitor a radioactive substance. Radioactive material monitoring method by

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