JP6208554B2 - Method and system for measuring removal contamination level - Google Patents

Description

The present invention relates to a method and a system for measuring a contamination level of a removed material when transporting a removed material such as removed soil generated by decontamination (soil removed by decontamination or waste contaminated with radioactive substances). About.

As a related prior art, there is a technique described in Patent Document 1.
This is related to a method for isolating incineration ash, sludge or soil containing radioactive substances as waste, and the work is performed in the following procedure.

1) Collect incinerated ash, sludge or soil waste containing radioactive materials and store in a flexible container (flexible pack).
2) Radiation dose is measured for each flexible container.
3) Select and distinguish flexible containers whose radiation dose exceeds a predetermined value, and preferentially store only the selected and distinguished flexible containers in a corrosion-resistant container.
4) A corrosion-resistant container is loaded on a truck and transported to a predetermined storage location.

JP2013-160754A

The removed matter generated by decontamination is transported by vehicle from a temporary storage location such as a temporary storage site installed in each decontamination area to an intermediate storage facility.
As for the removed matter, the treatment method and the storage method differ depending on the contamination level, so it is required to measure the contamination level in advance.

In order to grasp the contamination level of the removed product, the following methods are conceivable.
a) When removing a removed material from a temporary storage place such as a temporary storage place, the flexible containers are measured one by one. The method described in Patent Document 1 also corresponds to this.
b) Measure the flexible containers one by one when carrying them from a temporary storage location such as a temporary storage site to a receiving facility of an intermediate storage facility with a dump truck or the like.
c) While transporting the removed object, measurement is performed by passing a gate monitor (a gate-type measuring device) for each transport vehicle.
d) In the separation facility of the intermediate storage facility, after the flexible container is broken, it is measured and sorted in the state of soil.
However, any of the above methods has the following problems.

Ideally, the radiation dose for measuring the contamination level should be measured over a certain time for each flexible container in a shielded building.
However, in the method a), it is necessary to secure such a place in a temporary storage place such as a temporary storage place, but this is difficult.
In the method b), it is necessary to secure such a place in the receiving facility of the intermediate storage facility, but a large amount of containers are carried into the intermediate storage facility from many temporary storage locations. It is difficult to secure such a place for other containers.
For this reason, when measuring at a carrying-out place or a carrying-in place like the method a) or b), it is necessary to employ a belt conveyor type measurement. However, the belt-conveyor-type measurement is a measurement in a short time and in a moving state, and the stabilization time of the sensor output cannot be secured, so that accurate measurement is difficult.

In addition, in the method of measuring the entire transport vehicle as in c), accurate measurement cannot be performed because there is a distance between the sensor and the removed object. Since the transport vehicle has a shielding function by a part related to shielding / scattering prevention of removed objects, accurate measurement cannot be performed. In addition, there is a problem that measurement cannot be performed for each container.
Moreover, in the method of measuring after the bag breakage as in the above d), the separation after the measurement is not easy and is not efficient.

The present invention has been made in view of such a situation, and provides a removal contamination level measuring method and system capable of measuring a contamination level efficiently and accurately in advance with respect to a removal to be conveyed. Let it be an issue.

In order to solve the above problems, removing contamination level measuring method according to the present invention, the vehicle carrying the container for collection and transportation with the generated removal was due to decontamination accommodated by the predetermined capacity by more loading A measuring unit that includes a sensor unit disposed at a place where the container on the vehicle is placed, and that can measure the contamination level of the removed object for each container; and the contamination level for each container measured by the measuring unit And measuring the contamination level of the removed matter for each of the containers on the vehicle during transportation from the temporary storage location including the loading process to the intermediate storage facility. And recording using the recording means .

According to the present invention, measurement can be performed on a vehicle during transportation including a loading process, and there is no place restriction or time restriction. Therefore, it is possible to measure efficiently and to measure accurately over a necessary and sufficient time.
Moreover, the contamination level can be measured for each container for collection and transportation, and separation after the measurement is easy.
Moreover, the measurement can be performed under the same conditions on the transport vehicle, and the influence of external factors can be eliminated as much as possible.

Schematic which shows one Embodiment of the removal thing contamination level measurement system which concerns on this invention System configuration diagram using normal sensors System configuration diagram when using an optical fiber sensor Illustration of radiation dose rate-activity concentration conversion table The figure which shows the example of sensor arrangement in the case of 1 stacking The figure which shows the example of sensor arrangement in the case of two-stage stacking The figure which shows the example of sensor arrangement in the case of 3 stacking The figure which shows another example of sensor arrangement in the case of 3 stacking

Hereinafter, embodiments of the present invention will be described in detail.
Here, a case will be described in which removed matter (removed soil, etc.) generated in connection with decontamination is transported from a temporary storage site, which is a typical example of a temporary storage place, to an intermediate storage facility by a vehicle. The temporary storage place is a temporary storage place that is set up in a municipality or community unit in a case where the removed materials are collected and stored in another place from the decontamination place. However, there is also an on-site storage form for storing decontaminated soil etc. at the decontamination site, and this is also applicable when transported from the site for temporary storage in this case to an intermediate storage facility by vehicle. Is possible. The intermediate storage facility is a facility for safely and intensively managing and storing the removed material until final disposal.

First, the storage state of the removed material in the temporary storage place will be described.
The removed soil generated by decontamination is stored in a fixed volume (for example, 1 m ³ ) packed in a collection / transport container, such as polypropylene, in a cylindrical or rectangular parallelepiped flexible container. Below, the case where a flexible container is used as a container for collection and conveyance is demonstrated.

  An information medium such as an IC tag and / or a code label (a label attached with a barcode or a two-dimensional code represented by QR code (registered trademark)) is attached to the flexible container. This information medium includes the number of the flexible container, the type of removed material (soil, undergrowth, fallen leaves, chips, etc.), the location of the removed material (district name, removal area such as forest / farmland / residential land, road, etc., removal Information such as location), date (stuffing date), weight (kg), etc. are recorded.

From the temporary storage site to the intermediate storage facility, a plurality of flexible containers each storing a certain amount of the removed material are loaded and transported on a transport vehicle.
FIG. 1 is a schematic view of a removed contamination level measuring system showing an embodiment of the present invention, in which a transport vehicle 1 is shown.
In the removed matter contamination level measurement system according to the present invention, the removal contamination level is measured for each flexible container FC on the transport vehicle 1.

For this reason, in the transport vehicle 1, the sensor unit 2 of the measuring means is disposed at a place where the flexible container FC is placed.
The sensor unit 2 is a device for detecting a radiation dose rate (μSv / h), and outputs a signal related to the radiation dose rate.

The transport vehicle 1 is also equipped with a signal processing / recording unit 3 into which signals from the sensor unit 2 are input by wire or wirelessly.
The signal processing / recording unit 3 includes a signal processing unit 4 constituting a measuring unit together with the sensor unit 2, and a recording unit 5 as a recording unit.
In FIG. 1, the signal processing / recording unit 3 (the signal processing unit 4 and the recording unit 5) is drawn on the driver's seat roof of the transport vehicle 1. Needless to say, it may be installed indoors.

The signal processing unit 4 detects the radiation dose rate (μSv / h) for each flexible container FC based on the signal from the sensor unit 2. At this time, the signal processing unit 4 detects the radiation dose rate based on a signal after a predetermined stabilization time has elapsed from the start of signal output of the sensor unit 2. As a result, detection with high accuracy becomes possible. The stabilization time here is about three times the time constant specific to the sensor, and is, for example, 60 to 90 seconds.
The signal processing unit 4 further estimates the radioactivity concentration (Bq / kg) as the contamination level for each flexible container FC based on the detected radiation dose rate. For this estimation, as shown in FIG. 4, a conversion table in which the relationship between the radiation dose rate and the radioactivity concentration is determined in advance is used. This conversion table is created using a conversion coefficient, and the conversion coefficient is determined according to the volume of the flexible container FC, the properties of the removed soil (element composition, specific gravity, particle size distribution characteristics, etc.), the type of radioactive substance, and the like.

  The recording unit 5 records the radioactivity concentration for each flexible container FC calculated by the signal processing unit 4. Such recording is performed on a built-in hard disk so that it can be read from the outside, or on a removable memory card. Further, the recording data may be transferred by communication at a place where the removed object is carried.

The sensor unit 2 of the measuring means will be described in more detail with reference to FIGS.
FIG. 2 is a system configuration diagram when a normal sensor (radiation dose detector) is used. In this case, the sensor unit (radiation dose detector) 2 is provided for each flexible container, and each signal is input to the signal processing unit 4. In this case, each of the sensor units 2 includes a photomultiplier tube (PMT) that receives light from a scintillation unit that emits light when irradiated with radiation, and an A / D converter that performs A / D conversion on the output thereof. (Not shown).

  FIG. 3 is a system configuration diagram when an optical fiber type sensor (radiation dose detector) is used. The sensor unit (radiation dose detector) 2 in this case is configured by one scintillation optical fiber cable 20 for all of the flexible containers on the vehicle or for each predetermined group.

The scintillation optical fiber cable 20 is an optical fiber cable that contains a scintillator so that a portion irradiated with radiation emits light and transmits the emitted light.
More specifically, the scintillation optical fiber cable 20 includes a core having optical waveguide properties and a clad layer surrounding the core, and a scintillator that emits light by radiation is dispersed in the clad layer. Therefore, a part of the light generated when the scintillator is irradiated with radiation is transmitted through the core.

The scintillation optical fiber cable 20 is routed through a plurality of measurement positions where a plurality of flexible containers FC are placed. In other words, a plurality of measuring units 21 set in the extending direction of the scintillation optical fiber cable 20 are routed so as to be arranged at a place where the flexible container FC to be measured is placed.
In addition, it is good to give the coating | cover which has a shielding function except the measurement part 21 so that radiation may not inject from other than the measurement part 21. FIG.

A reflector 22 is attached to one end of the scintillation optical fiber cable 20. The other end of the scintillation optical fiber cable 20 is connected to the signal processing / recording unit 3.
In this case, a photomultiplier tube (PMT) 23 and an A / D converter 24 are built in the signal processing / recording unit 3, and the other end of the scintillation optical fiber cable 20 is connected to the photomultiplier tube 23 and A The signal processing unit 4 is connected via the / D converter 24.

  The signal processing unit 4 detects the radiation dose while specifying the measurement position (measured flexible container FC) from the phase and peak of the signal waveform corresponding to the radiation dose from the scintillation optical fiber cable 20. According to this method, multipoint measurement can be performed with a single optical fiber sensor.

Next, exemplary arrangements of the sensor units 2 according to the loading state of the flexible container FC will be described with reference to FIGS.
FIG. 5 shows an example of the arrangement of the sensor units when the flexible containers are stacked one stage.
The sensor unit 2 of the measuring means is disposed on the loading platform of the vehicle 1 and faces the bottom of the flexible container FC.

FIG. 6 shows an example of the arrangement of sensor units when two layers of flexible containers are stacked.
For the lower flexible container FC-L, the sensor unit 2-L of the measuring means is disposed so as to face the bottom of the flexible container FC-L, as in FIG.
For the upper flexible container FC-U, the sensor unit 2-U of the measuring means is arranged so as to face the upper part of the flexible container FC-U. In this case, the sensor unit 2-U is attached to an upper cover that covers the flexible container loaded on the vehicle.

FIG. 7 shows an example of the arrangement of the sensor units when the flexible containers are stacked in three stages.
For the lower flexible container FC-L, as in FIGS. 5 and 6, the sensor unit 2-L of the measuring means is disposed so as to face the bottom of the flexible container FC-L.
For the upper flexible container FC-U, as in FIG. 6, the sensor unit 2-U of the measuring means is disposed so as to face the upper part of the flexible container FC-U.
For the middle flexible container FC-M, the sensor unit 2-M of the measuring means is sandwiched between the flexible container FC-M and another flexible container FC-U (or FC-L). Is done. And between this sensor part 2-M and said other flexible container FC-U (or FC-L), in order to exclude the influence from said other flexible container, the shielding board 31 is arrange | positioned.

FIG. 8 shows another arrangement example of the sensor units when the flexible containers are stacked in three stages.
For the lower flexible container FC-L, the sensor unit 2-L of the measuring means is disposed so as to face the bottom of the flexible container FC-L, as in FIGS.
For the upper flexible container FC-U, as in FIGS. 6 and 7, the sensor unit 2-U of the measuring means is disposed so as to face the upper part of the flexible container FC-U.
For the middle flexible container FC-M, the sensor unit 2-M of the measuring means is arranged to face the side of the flexible container FC-M. In this example, the shielding plate 32 is disposed outside the sensor unit 2-M that is opposed to the side of the flexible container FC-M to eliminate the influence from the other flexible containers FC-U and FC-L. doing.

  Here, in order to eliminate the influence from the flexible container FC other than the measurement target on the sensor unit 2, a shielding plate that covers the sensor unit 2 is provided on the side opposite to the measurement target flexible container FC with respect to the arbitrary sensor unit 2. It may be provided.

  As described above, according to the present embodiment, the contamination level of the removed object can be measured on the transport vehicle, so that it can be measured on the vehicle during transport including the loading process, and there are no place restrictions or time restrictions. I do not receive it. Therefore, it is possible to measure efficiently and to measure accurately over a necessary and sufficient time. In addition, the contamination level can be measured for each collection / transport container such as a flexible container on the transport vehicle, and separation after the measurement is easy. Moreover, the measurement can be performed under the same conditions on the transport vehicle, and the influence of external factors can be eliminated as much as possible.

  In addition, when measuring and recording the level of contamination of a removed object for each collection / transport container such as a flexible container, the measurement data is written on an IC tag or a code label attached in advance for each container. It is desirable to record in association with the container number.

  The illustrated embodiments are merely examples of the present invention, and the present invention is not limited to those directly described by the described embodiments, and various improvements and modifications made by those skilled in the art within the scope of the claims. Needless to say, it encompasses changes.

1 Transport vehicle 2 Sensor part (sensor part of measuring means)
3 Signal processing / recording unit 4 Signal processing unit (signal processing unit of measuring means)
5 Recording section (recording means)
20 Scintillation optical fiber cable 21 Measuring unit 22 Reflector 23 Photomultiplier tube 24 A / D converter 31, 32 Shield plate FC Flexible container

Claims (11)

For vehicles that carry multiple collection and transport containers that store a certain volume of the decontaminated materials generated by decontamination and transport them from temporary storage locations to intermediate storage facilities .
A measuring unit that includes a sensor unit disposed at a place where the container on the vehicle is stationary, and is capable of measuring a contamination level of a removed object for each container;
Recording means for recording the contamination level of each container measured by the measuring means;
Comprising
During transportation from the temporary storage location including the loading process to the intermediate storage facility, on the vehicle, the measurement means is used to measure the contamination level of the removed matter for each container,
The removal contamination level measuring method , wherein recording is performed using the recording means . The measurement unit includes the sensor unit and an arithmetic processing unit, the sensor unit outputs a signal related to a radiation dose rate, and the arithmetic processing unit is based on a signal from the sensor unit. 2. The removal contamination level measurement method according to claim 1, wherein a radiation dose rate is detected, and a radioactivity concentration is estimated as the contamination level based on the detected radiation dose rate. 3. The removed contamination level according to claim 1, wherein the measurement unit measures the contamination level based on a signal after a predetermined stabilization time has elapsed from the start of signal output of the sensor unit. Measurement method . The sensor unit of the measuring means includes a scintillator so that a portion irradiated with radiation emits light, and is configured by an optical fiber cable that transmits the emitted light, and the optical fiber cable passes through a plurality of measurement positions. The removal contamination level measurement method according to any one of claims 1 to 3, wherein the removal contamination level measurement method is performed . The removed object contamination according to any one of claims 1 to 4, wherein the sensor unit of the measuring unit is disposed on a loading platform of the vehicle and faces the bottom of the container. Level measurement method . The containers are stacked in at least two stages;
The removal according to any one of claims 1 to 5, wherein the sensor unit of the measuring unit is arranged so as to face the upper part of the upper container. Contamination level measurement method . The containers are stacked in at least three stages,
The sensor unit of the measuring means is arranged between the container and another container with respect to the middle container, and a shielding plate is arranged between the sensor unit and the other container. The removal contamination level measuring method according to any one of claims 1 to 6. The sensor part of the measuring means is arranged so as to be opposed to a side part of the container for at least a part of the container. Method for measuring the level of contamination of removed substances. The removal according to any one of claims 1 to 8, wherein a shielding plate that covers the sensor unit is provided on a side opposite to the measurement target container with respect to the sensor unit of the measuring unit. Contamination level measurement method . A plurality of collection and transportation containers that store a certain volume of the debris generated during decontamination are loaded on a transportation vehicle,
During transport from the temporary storage location including the loading process to the intermediate storage facility, the level of contamination of the removed material is measured for each container using a sensor unit disposed on the vehicle where the container is placed. ,
A method for measuring a contamination level of a removed object, wherein the measured contamination level for each container is recorded. A vehicle that loads and transports multiple collection / transport containers that store a certain volume of the debris generated during decontamination;
A measuring unit that includes a sensor unit disposed at a place where the container on the vehicle is stationary, and is capable of measuring a contamination level of a removed object for each container;
Recording means for recording the contamination level of each container measured by the measuring means;
Comprising
The containers are stacked in at least three stages,
The sensor part of the measuring means is arranged between the container and the other container for the middle container, and a shielding plate is arranged between the sensor part and the other container ,
A removal contamination level measuring system characterized in that the contamination level of the removal object can be measured on a transport vehicle.