JP2014202717A - Radioactive waste inspection device, and radioactive waste inspection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radioactive waste inspection device and a radioactive waste inspection method, having high inspection processing performance to waste.SOLUTION: A radioactive waste inspection device of an embodiment includes first to third inspection sections and a conveyor. The conveyor moves radioactive waste being an object to be inspected from the first inspection section to the second inspection section, and moves the radioactive waste from the second inspection section to the third inspection section. The first inspection section includes a first inspection device group which executes side-surface dose equivalent rate inspection of the radioactive waste and inspection other than measurement of a radioactivity amount. The second inspection section includes a second inspection device group which executes side-surface dose equivalent rate inspection of the radioactive waste and measurement of a radioactivity amount of the radioactive waste. The third inspection section includes a labeling device which adheres a label on the radioactive waste and prints on it.

Description

  Embodiments described herein relate generally to a radioactive waste inspection apparatus and a radioactive waste inspection method.

  Conventionally, a general radioactive waste inspection device consists of a weight measurement device, surface contamination density measurement inspection device, appearance inspection device, surface dose equivalent rate measurement inspection device, radioactivity amount measurement inspection device, labeling device, and transport crane. Has been. In the appearance inspection, the appearance of the top, side, and bottom surfaces of the waste is inspected, and in the surface dose equivalent rate measurement inspection, the surface dose at a position away from the top, side, bottom, and side of the waste by a predetermined distance. The equivalence rate is measured and inspected.

  In such a conventional radioactive waste inspection apparatus, a transport crane is used to move the radioactive waste until it is carried into the radioactive waste inspection apparatus, moved between the inspection apparatuses, and carried out from the radioactive waste inspection apparatus. Was used.

  However, in such an inspection flow, it takes a lot of inspection and measurement time, and the processing capacity for the number of wastes in a day is reduced, so that it is not possible to meet the needs when a larger number of processes are required. was there.

JP 2009-162704 A JP 2011-247828 A

  The problem to be solved by the present invention is to provide a radioactive waste inspection apparatus and a radioactive waste inspection method having a high inspection processing capability for waste.

  The radioactive waste inspection apparatus of the embodiment has first to third inspection units and a conveyor. The conveyor conveys the radioactive waste as an object to be inspected from the first inspection unit to the second inspection unit, and transfers the radioactive waste from the second inspection unit to the third inspection unit. Move. The first inspection unit includes a first inspection device group that performs inspections other than the side dose equivalent rate inspection and the radioactivity measurement of the radioactive waste. The second inspection unit includes a second inspection device group that performs a side surface dose equivalent rate inspection of the radioactive waste and a radioactivity amount measurement of the radioactive waste. The third inspection unit includes a labeling device that labels and prints the radioactive waste.

1 is a perspective view of a radioactive waste inspection apparatus according to Embodiment 1. FIG. The top view of the apparatus shown in FIG. The time chart of the measurement by the apparatus shown in FIG. 1, inspection, and radioactive waste movement. The top view of the radioactive waste inspection apparatus by Embodiment 2. FIG. FIG. 5 is a time chart of measurement, inspection, and radioactive waste movement by the apparatus shown in FIG. 4. 2 is a flowchart of a radioactive waste inspection method according to Embodiment 1. 9 is a flowchart of a radioactive waste inspection method according to Embodiment 2.

  Hereinafter, some embodiments will be described with reference to the drawings. In the drawings, the same portions are denoted by the same reference numerals, and redundant description thereof is omitted as appropriate.

(A) Radioactive waste inspection device (1) Embodiment 1
(Device configuration)
FIG. 1 is a perspective view showing a schematic structure of a radioactive waste inspection apparatus according to Embodiment 1, and FIG. 2 is a plan view of the apparatus shown in FIG. The radioactive waste inspection apparatus shown in FIGS. 1 and 2 includes a carry-in crane CL1, first to third inspection units UT1 to UT3 provided in first to third inspection regions RT1 to RT3, and a drum transport conveyor 3, respectively. And an unloading crane CL2.

  The carry-in crane CL1 is a container for storing radioactive waste that is an object to be inspected, such as a drum can (hereinafter referred to as “waste body” as appropriate) D, and a movable loading table outside the apparatus, for example, a pallet 2 shown in FIG. To the drum conveyor 3. The carry-out crane CL2 moves the waste body D that has passed all the inspections to a movable storage facility outside the apparatus, for example, the container 8 shown in FIG. The drum conveyor 3 moves the waste body D in parallel from the first inspection region RT1 to the third inspection region RT3. The carry-in crane CL1, the drum conveyor 3 and the carry-out crane CL2 are configured independently of each other.

  In addition, after the waste body D which failed in the 1st thru | or 3rd test | inspection part UT1-UT3 was moved by the drum conveyance conveyor 3 to the stand for unacceptable drum cans and the rejection pallet which are not shown in figure, it fails. The waste body D for the drum can stand is collected by the carry-in crane CL1, and the waste body D for the unacceptable pallet is collected by a special vehicle, for example, a forklift.

  The first inspection unit UT1 includes a weight measurement device 13, a surface contamination density measurement inspection device 12, and an appearance inspection device 9. The weight measuring device 13 measures the weight of each waste body D. The surface contamination density measurement and inspection device 12 wipes the surface of the waste body D with a filter cloth, measures the filter cloth after wiping, and confirms the radioactive substance contamination density on the entire surface of the waste body D, and determines the collimator density during Ge measurement. decide. The surface contamination density measurement / inspection apparatus 12 according to the present embodiment is configured such that the pressing force to the waste body D is constant, and can be wiped off with an indefinite curved surface.

  The appearance inspection apparatus 9 is an apparatus for confirming the presence or absence of scratches or dents in the waste body D and the waste body manufacturing number. The appearance inspection apparatus 9 according to this embodiment is a predetermined separation position in a second inspection section UT2 described later. Before the side dose equivalent rate measurement and the upper and lower side surface dose equivalent rate measurements are performed, the appearance of the entire surface of the waste D is continuously recorded. For this reason, the second inspection unit UT has a functional configuration capable of confirming the appearance of the recorded video at any time while the predetermined separation position side surface dose equivalent rate measurement and the upper and lower side surface dose equivalent rate measurement are being performed.

  In the present embodiment, the weight measurement device 13, the surface contamination density measurement inspection device 12, and the appearance inspection device 9 correspond to, for example, a first inspection device group.

  The second inspection unit UT2 includes an upper and lower side surface dose equivalent rate measurement / inspection apparatus 10, a predetermined separation position side dose equivalent rate measurement / inspection apparatus 11, and a radioactivity amount measurement apparatus 15.

  The upper and lower side surface dose equivalent rate measurement / inspection apparatus 10 measures the maximum radiation dose equivalent rate from the upper and lower side surfaces of the waste D and confirms whether or not it passes the embedment standard. The predetermined separation position side surface dose equivalent rate measurement / inspection apparatus 11 measures the maximum radiation equivalent rate from the side surface at a position away from the waste body D by a predetermined distance. This predetermined distance is about 1 m in this embodiment. The radioactive quantity measuring device 15 identifies the amount and concentration of the radioactive substance contained in the waste.

  In the present embodiment, the upper and lower side surface dose equivalent rate measurement / inspection apparatus 10, the predetermined separation position side dose equivalent rate measurement / inspection apparatus 11, and the radioactivity amount measurement apparatus 15 correspond to, for example, the second inspection apparatus group.

  The third inspection unit UT3 includes a labeling device 16.

(Operation)
The operation of the radioactive waste inspection apparatus shown in FIGS. 1 and 2 will be described with reference to the time chart of FIG.
First, the waste body D is taken out from the pallet 2 by the carry-in crane CL <b> 1 and moved to the drum conveyor 3. After the movement, the waste body D is moved to the inspection place of the first inspection unit UT1 by the drum conveyor 3.

  In the first inspection unit UT1, first, the weight measurement device 13 performs weight measurement, and then the surface contamination density measurement inspection device 12 performs surface contamination density measurement. In the surface contamination density measurement, the waste cloth surface is wiped with a filter cloth, and then the contamination density of the filter cloth is measured. In a general surface contamination density measuring and inspecting apparatus, there is a possibility that the filter cloth may be separated from the arm portion for wiping the surface of the waste D with the filter cloth. Therefore, the surface contamination density is measured after the appearance inspection is performed. . However, since the surface contamination density measurement / inspection apparatus 12 installed in the radioactive waste inspection apparatus of the present embodiment has improved reliability, an appearance inspection can be performed after the surface contamination density measurement. For this reason, the first inspection is performed. Arrangement to the part UT1 became possible.

Subsequent to the surface contamination density measurement, the appearance inspection device 9 performs an appearance inspection of the waste. In the appearance inspection, the drum can containing the waste is inspected for scratches, and when the result of the appearance inspection is input, the drum moves to the next inspection section. Even if the result of the appearance inspection is input even before the surface contamination density measurement result is obtained, it is possible to proceed to the next inspection / measurement.
The result of the appearance inspection can be recorded on a monitor screen (not shown) so that the form can be recorded, and the drum number, drum manufacturer (including date of manufacture) number, etc. can be output on the form. It has become. In addition, it is possible to perform marking with a touch pen or add a comment on an arbitrary screen on a monitor (not shown) and print the screen on a form.

  When the appearance inspection is passed, the waste body D moves to the second inspection unit UT2 which is the next inspection unit by the drum transport conveyor 3.

  In the second inspection unit UT2, first, the upper and lower side surface dose equivalent rate measurement / inspection apparatus 10 measures the maximum radiation dose equivalent rate from each surface of the upper and lower side surfaces of the waste body D and confirms whether it passes the embedment standard. When it is confirmed that the radiation dose equivalent rate of the upper and lower side surfaces passes the standard, the maximum radiation from the side surface at a position away from the waste D by a predetermined distance by the predetermined separation position side dose equivalent rate measurement / inspection apparatus 11. The equivalence rate is measured. This predetermined distance is about 1 m in this embodiment.

  Next, the amount and concentration of the radioactive substance contained in the waste is identified by the radioactive quantity measuring device 15.

  The waste D that has passed the surface dose equivalent rate measurement inspection, the predetermined separation position side dose equivalent rate measurement inspection, and the radioactivity measurement is moved to the third inspection unit UT3 by the drum transport conveyor 3.

  In the third inspection unit UT3, the labeling device 16 attaches a required labeling to the side surface of the waste body D, and prints a reference number after the application. After labeling and printing, the entire waste body D is visually confirmed with a camera, and the serial number and the like are automatically recognized, and then conveyed to the carry-out crane CL2 by the drum conveyer 3. The transported waste D is stored in a reject pallet (not shown), a sampling waste pallet (not shown), or a container by the carry-out crane CL2 according to the inspection result.

  In the third inspection unit UT3, the labeling of the waste body D and the visual confirmation of the printing are performed by a real-time video image inspection using an imaging device (not shown). This imaging apparatus (not shown) is configured to be able to freely perform a zoom function, rotation speed change / reverse rotation / temporary stop, and thus it is possible to respond quickly when an abnormality is confirmed. Yes.

  Thus, according to the radioactive waste inspection apparatus of the present embodiment, once the waste body D is carried into the inspection area, it is paralleled by the drum conveyor 3 from the first inspection unit UT1 to the third inspection unit UT3. Since the inspection is performed while moving, the time required for the movement is shortened, and the entire processing time is shortened accordingly.

  For example, the time required to move the waste D is about 3 minutes. For example, the weight measuring device 13 → the surface contamination density measuring / inspecting device 12 → the appearance inspecting device 9 → the upper and lower side surface dose equivalence rate measuring / inspecting device 10 → the predetermined separation position side surface If the dose equivalent rate measurement / inspection device 11 → the radioactivity measurement device 15 → the labeling device 16 is moved between the inspection / measurement devices in this order, the movement of the waste body D within the inspection region only takes about 3 minutes × 6 times. = It takes about 18 minutes.

  On the other hand, according to the present embodiment, the movement of the waste body D is limited to two times from the first inspection unit UT1 to the second inspection unit UT2 and from the second inspection unit UT2 to the third inspection unit UT3. The movement of the waste body D within the inspection area is about 3 minutes × 2 times = about 6 minutes, and the throughput can be improved three times.

(2) Embodiment 2
(Device configuration)
FIG. 4 is a plan view showing a schematic configuration of the radioactive waste inspection apparatus according to the second embodiment. As is clear from comparison with FIG. 2, one of the features of this embodiment is that the upper and lower surface dose equivalent rate measurement and inspection device 102 and the side surface dose equivalent rate are replaced with the upper and lower surface dose equivalent rate measurement and inspection device 10. Among the above-described inspection devices and measurement devices other than the labeling device including the measurement inspection device 104, only the radioactivity measurement device 15 and the side surface dose equivalent rate measurement inspection device 104 are arranged in the second inspection unit UT2, and other inspection devices In addition, all the measuring devices are arranged in the first inspection unit UT1.

  That is, the first inspection unit UT1 includes a weight measurement device 13, an appearance inspection device 9, a predetermined remote position side dose equivalent rate measurement inspection device 11, a surface contamination density measurement inspection device 12, and an upper and lower surface dose equivalent rate measurement inspection device 102. Is placed. In the present embodiment, these inspection apparatuses correspond to, for example, a first inspection apparatus group.

  In the second inspection unit UT2, a radioactivity measuring device 15 and a side surface dose equivalent rate measuring / inspecting device 104 are arranged. In the present embodiment, these inspection apparatuses correspond to, for example, the second inspection apparatus group.

(Operation)
The operation of the radioactive waste inspection apparatus shown in FIG. 4 will be described with reference to the time chart of FIG. As is clear from comparison with FIG. 3, one of the features of the operation of the radioactive waste inspection apparatus of the present embodiment is that the waste body D is in each region of the first inspection unit UT1 and the second inspection unit UT2. Is inspected and measured without being moved by the drum conveyor 3.

First, the carry-in crane CL1 takes out the waste body D from the pallet 2 and moves it onto the drum transport conveyor 3 in the first inspection unit UT1.
In the first inspection unit UT1, first, the weight measuring device 13 performs weight measurement. Subsequently, the appearance inspection apparatus 9 performs an appearance inspection over the upper surface, the lower surface, and the side surface of the waste body D. Next, the maximum radiation equivalent rate from the side surface at a position away from the waste body D by a predetermined distance, for example, a position about 1 m away, is measured by the predetermined separation position side surface dose equivalent rate measurement / inspection apparatus 11. Since the appearance of the entire surface of the waste body D has already been recorded by the appearance inspection, it is possible to confirm the appearance on the recorded video at the same time during the measurement of the predetermined separation position side dose equivalent rate.

  Subsequently, the surface contamination density measurement / inspection apparatus 12 performs a contamination density measurement / inspection on the upper surface of the waste body D, and then performs a contamination density measurement / inspection on the lower surface of the waste body D.

  The surface contamination density measurement / inspection apparatus 12 further performs a contamination density measurement / inspection on the side surface of the waste D. Simultaneously with the surface contamination density measurement / inspection device 12 by the surface contamination density measurement / inspection device 12, the upper / lower surface dose equivalent rate measurement / inspection device 102 measures the maximum radiation dose equivalent rate from the upper and lower surfaces of the waste body D and embeds it. Check if the standards are passed.

  During the contamination density measurement inspection on the upper surface of the waste body, the contamination density measurement inspection on the lower surface of the waste body, and the upper and lower surface dose equivalent rate measurement inspection apparatus 102 by the surface contamination density measurement inspection apparatus 12, the waste is discarded. The body D moves vertically and rotates by a lifting mechanism and a rotating mechanism (not shown). Since the appearance of the entire surface of the waste body D has already been recorded by the appearance inspection, it is possible to confirm the appearance on the recorded video simultaneously during the measurement of the upper and lower dose equivalent ratios.

  When it is confirmed that the radiation dose equivalent ratios of the upper and lower surfaces pass the standard, the drum transport conveyor 3 moves the passed waste D to the second inspection unit UT2.

  In the second inspection unit UT2, the radioactivity measuring device 15 identifies the amount and concentration of the radioactive substance contained in the waste. In parallel with the measurement of the radioactivity measuring device 15, the side surface dose equivalent rate measurement / inspection device 104 measures the maximum radiation dose equivalent rate from the side surface of the waste D and confirms whether it passes the embedment standard. Thereby, in 2nd test | inspection part UT2, a measurement test | inspection can be complete | finished within the range of the test | inspection time by the radioactivity measuring apparatus 15. FIG.

  In the second inspection unit UT2, the measurement of the side surface dose equivalent rate and the measurement of the amount of radioactivity are simultaneously performed on the waste D that has passed the first inspection unit UT1 and has been transported by the drum conveyor 3. Although simultaneous measurement is possible in this way, in order to confirm the burial standards, first measure the side surface dose equivalent rate, and then identify the amount and concentration of radioactive material contained in the waste by radioactivity measurement. It is good.

  The waste D that has passed the side surface dose equivalent rate measurement inspection and the radioactivity measurement in the second inspection unit UT2 is moved to the third inspection unit UT3 by the drum transport conveyor 3.

  In the third inspection unit UT3, the labeling device 16 performs labeling and printing on the waste body D as in the first embodiment.

  According to the present embodiment, in the second inspection unit UT2 in which the radioactivity measuring device 15 that requires the most processing time for inspection / measurement is arranged, in addition to the radioactivity measuring device 15, the operation and parallel processing of the radioactivity measuring device 15 are performed. Since only the possible side surface dose equivalent rate measurement / inspection apparatus 104 is arranged, the processing time of the second inspection unit UT2 can be shortened as much as possible, thereby improving the processing capacity of the entire radioactive waste inspection apparatus. Can be made.

  In addition, since each inspection unit is arranged so that all inspections / measurements can be performed without moving the waste body D, the movement of the waste body D by the drum transport conveyor 3 is also performed from the first inspection unit UT1 to the second. The movement is limited to the inspection unit UT2 and the movement from the second inspection unit UT2 to the third inspection unit UT3. As a result, the time required for moving the waste D can be further shortened, which contributes to the improvement of the processing capacity of the entire radioactive waste inspection apparatus, and the possibility of damaging the drum can by reducing the number of times the waste D is moved. Therefore, the safety of radioactive waste inspection is further improved.

  Moreover, since the measurement of the predetermined separation position side surface dose equivalent rate and the measurement of the upper and lower surface dose equivalent rate are completed in the first inspection unit UT1, the inspection measurement time in the second inspection unit UT2 is shortened accordingly, Waste disposal can be carried out rationally.

  According to the radioactive waste inspection apparatus of at least one embodiment described above, once it is carried into the apparatus by the carry-in crane CL1, the waste body D is a drum from the first inspection unit UT1 to the third inspection unit UT3. Since the inspection is performed by parallel movement by the conveyor 3, the time required for the movement is shortened, and the entire processing time is shortened accordingly. In addition, since the first inspection unit UT1 to the third inspection unit UT3 are not subjected to the holding / suspension operation against the weight of the waste by the crane arm or the like, there is no risk of damaging the drum or risk of falling. The inspection can be carried out with high safety.

(B) Radioactive waste inspection method (1) Embodiment 1
Hereinafter, the radioactive waste inspection method according to Embodiment 1 will be described with reference to the flowchart of FIG. In the flowchart of FIG. 6, steps S11 to S16 are the first inspection region RT1 (see FIG. 1), steps S21 to S25 are the second inspection region RT2 (see FIG. 1), and steps S31 to S33. The process is inspection / measurement in the third inspection region RT3 (see FIG. 1).

  The movement of the waste body D from the first inspection area RT1 to the second inspection area RT2 and the movement of the waste body D from the second inspection area RT2 to the third inspection area RT3 are, for example, the drum transport conveyor 3 shown in FIG. This is done by parallel movement using.

  First, the waste body D, which is an object to be inspected, is moved to the first inspection area RT1 (step S1). For the movement at this time, it is desirable to use a carry-in crane independent of the drum conveyor 3, for example, a carry-in crane 1 shown in FIG. 1.

  Next, weight measurement is performed on each of the waste bodies D (step S11). Next, a measurement inspection of the surface contamination density is performed on the waste D. For example, the surface contamination density is performed on the upper and lower surfaces (step S12) and then on the side surfaces (step S13). At this time, the waste body D is vertically moved and rotated using a lifting mechanism and a rotating mechanism (not shown).

  Subsequently, an appearance inspection of the waste body D is performed (step S14). More specifically, the drums that contain the waste are inspected for scratches.

  Here, it is determined for each waste body D whether or not the inspection / measurement in the first inspection region RT1 is passed (step S15). The passed waste body D moves to the second inspection region RT2 by the drum transport conveyor 3 or the like. If there is a rejected waste body D, it is similarly carried out by the drum conveyor 3 or the like to a reject drum stand (not shown) (step S16).

Next, the surface dose equivalent rate is measured across the upper and lower surfaces and the side surface of the waste D that has passed the inspection / measurement in the first inspection region RT1 (step S21).
Next, the maximum radiation equivalent ratio from the side surface at a position away from the waste body D by a predetermined distance is measured (step S22). This predetermined distance is about 1 m in this embodiment.

  Furthermore, the amount and concentration of radioactive material contained in the waste are identified by measuring the amount of radioactivity (step S23).

  A pass / fail determination is performed on the waste D that has been inspected and measured in the second inspection region RT2 (step S24). The rejected waste D moves to the third inspection region RT3 by the drum transport conveyor 3 or the like. If there is a rejected waste body D, it is carried out to a reject waste body pallet (not shown) by the drum conveyor 3 or the like (step S25).

  Next, in the third inspection region RT3, the waste body D that has passed the inspection / measurement in the second inspection region RT2 is labeled (step S31). More specifically, a required labeling is affixed to the side surface of the waste body D, and a serial number or the like is printed after the affixing.

  A final pass / fail determination is performed on the waste D that has finished the labeling process (step S32). The passed waste body D is moved to a movable storage facility, for example, the container 8 shown in FIG. 1 by, for example, the carry-out crane CL2 shown in FIG. 1 (step S41). If there is a rejected waste body D, it is carried out to a reject waste body pallet (not shown) by the drum conveyor 3 or the like (step S33).

  In the above description, the mode in which the pass / fail determination is performed every time inspection / measurement in each inspection region is completed is described. However, the timing of the pass / fail determination is not limited to this, and for example, as in Embodiment 2 described later. In addition, it is possible to appropriately carry out in each inspection area.

  According to the radioactive waste inspection method of the present embodiment, once it is carried into the inspection area, the waste body D is transferred from the first inspection area RT1 to the third inspection area RT3, such as the drum conveyor 3 (see FIG. 1). Therefore, the time required for the movement is shortened, and the entire processing time is shortened accordingly.

  For example, it takes about 3 minutes to move the waste D, for example, weight measurement → surface contamination density (upper and lower, side) measurement → appearance inspection → surface (upper and lower, side) dose equivalent rate measurement → predetermined separation position side dose equivalent If it is moved between inspections / measurements in the order of rate measurement → radioactivity measurement → labeling, it takes about 3 minutes × 6 times = about 18 minutes just by moving waste D in the inspection area. Become.

  On the other hand, according to the present embodiment, the movement of the waste body D is limited to two times from the first inspection region RT1 to the second inspection region RT2 and from the second inspection region RT2 to the third inspection region RT3. The movement of the waste body D within the inspection area is about 3 minutes × 2 times = about 6 minutes, and the throughput can be improved three times.

(2) Embodiment 2
Next, the radioactive waste inspection method according to Embodiment 2 will be described with reference to the flowchart of FIG. In the flowchart of FIG. 7, steps S61 to S67 are in the first inspection region RT1, steps S71 to S73 are in the second inspection region RT2, and steps S81 to S83 are in the third inspection region RT3. It is a measurement. The movement of the waste body D from the first inspection area RT1 to the second inspection area RT2 and the movement of the waste body D from the second inspection area RT2 to the third inspection area RT3 are, for example, the drum transport conveyor 3 shown in FIG. This is done by parallel movement using. However, in this embodiment, inspection / measurement is performed without the waste body D moving in parallel in each inspection region.

  First, similarly to the first embodiment described above, the waste body D, which is an object to be inspected, is moved to the first inspection region RT1 (step S51). For the movement at this time, it is desirable to use a carry-in crane independent of the drum conveyer 3, for example, a carry-in crane CL1 shown in FIG.

  Next, weight measurement is performed on each of the waste bodies D (step S61). Next, an appearance inspection is performed on the upper surface, the lower surface, and the side surface of the waste body D, and the maximum radiation equivalent ratio from the side surface at a position away from the waste body D by a predetermined distance, for example, about 1 m is measured (step) S62). In the appearance inspection, the drums containing the waste are inspected for scratches. At this time, the waste body D is vertically moved and rotated using a lifting mechanism and a rotating mechanism (not shown). Since the appearance of the entire surface of the waste body D has already been recorded by the appearance inspection, it is possible to confirm the appearance on the recorded video simultaneously during the measurement of the predetermined separation position side dose equivalent rate.

  Here, it is determined for each waste body D whether it has passed the appearance inspection and the predetermined separation position side surface dose equivalent rate measurement inspection (step S63). The passed waste D undergoes the following inspection / measurement. If there is a rejected waste body D, it is similarly carried out by the drum conveyor 3 or the like to a reject drum stand (not shown) (step S64).

  Next, a measurement inspection of the surface contamination density is performed on the waste body D that has passed the appearance inspection and the predetermined separation position side surface dose equivalent rate measurement inspection. For example, the surface contamination density is performed on the upper surface (step S65) and then on the lower surface (step S66).

  Subsequently, the surface contamination density is measured and inspected on the side surface of the waste body D, and at the same time, the maximum radiation dose equivalent rate from each surface of the upper and lower surfaces of the waste body D is measured and passed the embedment standard. Is confirmed (step S67).

  During the contamination density measurement and inspection of the upper and lower surfaces and the dose equivalent rate measurement of the upper and lower surfaces, the waste body D is vertically moved and rotated by a lifting mechanism and a rotating mechanism (not shown). Since the appearance of the entire surface of the waste body D has already been recorded by the appearance inspection, it is possible to confirm the appearance on the recorded video simultaneously during the measurement of the upper and lower dose equivalent ratios.

  When the contamination density measurement inspection and the upper and lower dose equivalent rate measurement are completed, the waste body D is translated to the second inspection region RT2 by, for example, the drum transport conveyor 3 (see FIG. 1).

  In the second inspection region RT2, the maximum radiation dose equivalent rate from the side surface of the waste body D is measured to confirm whether it passes the embedment standard, and the amount and concentration of the radioactive substance contained in the waste is identified ( Step S71). Thereby, in 2nd test | inspection part UT2, a measurement test | inspection can be complete | finished within the range of the test | inspection time by the radioactivity measuring apparatus 15. FIG.

  A pass / fail determination is performed on the waste D that has been inspected and measured in the second inspection region RT2 (step S72). The rejected waste D moves to the third inspection region RT3 by the drum transport conveyor 3 or the like. If there is a rejected waste body D, it is carried out to a reject waste body pallet (not shown) by the drum conveyor 3 or the like (step S73).

  Next, in the third inspection region RT3, labeling is performed on the waste D that has passed the inspection / measurement in the second inspection region RT2 (step S81). More specifically, a required labeling is affixed to the side surface of the waste body D, and a serial number or the like is printed after the affixing.

  A final pass / fail determination is performed on the waste D after the labeling process (step S82). The passed waste body D is moved to a movable storage facility, for example, the container 8 shown in FIG. 1 by, for example, the carry-out crane CL2 shown in FIG. 1 (step S91). If there is a rejected waste body D, it is carried out by the drum transport conveyor 3 or the like to a reject waste body pallet (not shown) (step S83).

  According to the present embodiment, in the second inspection region RT2 in which the radioactivity measurement that requires the most processing time for inspection / measurement is performed, the side surface dose equivalent rate measurement that can be performed in parallel with the radioactivity measurement other than the radioactivity measurement. Therefore, the processing time in the second inspection region RT2 can be shortened as much as possible, thereby improving the throughput of the entire radioactive waste inspection. In addition, since all inspection / measurement is performed without moving the waste body D in each inspection area, the parallel movement of the waste body D by the drum transport conveyor 3 (see FIG. 1) can also be performed in the first inspection area RT1. To the second inspection region RT2 and the movement from the second region to the third inspection region RT3. As a result, the time required for moving the waste D can be further shortened, which contributes to the improvement of the throughput of the entire radioactive waste inspection, and the possibility of damaging the drum can by reducing the number of times the waste D is moved. The safety of radioactive waste inspection is further improved.

  In addition, since the measurement of the predetermined separation position side surface dose equivalent rate and the measurement of the upper and lower surface dose equivalent rate are completed in the first inspection region RT1, the inspection measurement time in the second inspection region RT2 is shortened accordingly, Waste disposal can be carried out rationally.

  According to the radioactive waste inspection method of at least one embodiment described above, the waste body D is translated by the drum conveyor 3 (see FIG. 1) from the first inspection region RT1 to the third inspection region RT3. Therefore, it is not subject to holding / suspension operations against the weight of the waste itself, such as by crane arms. Therefore, there is no risk of damaging the drum and no risk of dropping, so the inspection can be performed with high safety.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 3 ... Drum conveyance conveyor, 9 ... Appearance inspection apparatus, 10 ... Upper and lower surface dose equivalent rate measurement inspection apparatus, 11 ... Predetermined separation position side dose equivalent rate measurement inspection apparatus, 12 ... Surface contamination density measurement inspection apparatus, 13 ... Weight measurement Device: 15 ... Radioactivity measuring device, 16 ... Labeling device, 102 ... Upper / lower surface dose equivalent rate measurement / inspection device, 104 ... Side surface dose equivalent rate measurement / inspection device, CL1 ... Carrying crane, CL2 ... Carrying crane, D ... Disposal Body (waste), RT1 to RT3 ... inspection area, UT1 to UT3 ... (first to third) inspection sections.

Claims (8)

First to third inspection units;
A transport conveyor that moves the radioactive waste that is the object to be inspected from the first inspection section to the second inspection section, and moves the radioactive waste from the second inspection section to the third inspection section; ,
With
The first inspection unit includes a first inspection device group that performs an inspection other than a side dose equivalent rate inspection and a radioactivity measurement of the radioactive waste,
The second inspection unit includes a second inspection device group that performs a side surface dose equivalent rate inspection of the radioactive waste and a radioactivity measurement of the radioactive waste,
The third inspection unit includes a labeling device that labels and prints the radioactive waste.
Radioactive waste inspection equipment.   2. The radioactive waste inspection apparatus according to claim 1, wherein the second inspection group includes a radioactive quantity measuring apparatus that identifies the amount and concentration of the radioactive substance contained in the waste.   The second inspection group further includes a side surface radiation dose equivalent rate measuring device that measures the maximum radiation equivalent rate from the side surface of the waste body and confirms whether it passes the embedding standard. The radioactive waste inspection device described in 1. The first inspection unit includes:
A weight measuring device for measuring the weight of each of the waste bodies;
A surface contamination density measuring and inspecting device for measuring the radioactive material contamination density of the entire surface of the waste body
Appearance inspection device that reads whether the waste body is damaged or deformed, and the serial number;
An upper and lower surface dose equivalent rate measurement and inspection device for measuring whether or not the maximum radiation equivalent rate from the upper and lower surfaces of the waste body is passed and confirming whether or not the embedment standard is passed,
The radioactive waste inspection apparatus according to any one of claims 1 to 3, further comprising:   The radioactive waste inspection apparatus according to claim 4, wherein the surface contamination density measurement and inspection apparatus determines a collimator density at the time of Ge measurement from the measured radioactive substance contamination density. The first inspection unit includes:
The radioactive waste inspection apparatus according to claim 4, further comprising a side dose equivalent ratio measurement / inspection apparatus that measures a maximum radiation equivalent ratio from a side surface at a position away from the waste by a predetermined distance. A carry-in crane for carrying the radioactive waste onto the conveyor;
An unloading crane for unloading the radioactive waste from the conveyor;
The radioactive waste inspection apparatus according to claim 1, further comprising: Moving the radioactive waste that is the object to be inspected sequentially in parallel from the first inspection region to the third inspection region;
Performing side dose equivalent rate inspection and radioactivity measurement of the radioactive waste in the second inspection region;
In the first inspection area, performing a test other than the side dose equivalent rate test and the radioactivity measurement of the radioactive waste;
Labeling and printing the radioactive waste in the third inspection area;
A radioactive waste inspection method comprising:

Images