WO2011131339A2 - Radiation detector device - Google Patents

Abstract

The invention relates to a radiation detector device for identifying radioactive contaminants in a measurement volume (1) comprising an arrangement of radiation detectors (3), an evaluation unit and a display unit, wherein the radiation detectors (3) each have a scintillator crystal (4) and a converter for providing the radiation detector signals, wherein the measurement volume (1) and the radiation detector device pass one another during a first coarse measurement, wherein the evaluation unit, during the coarse measurement, determines the individual spectra of the radiation detectors (3) (counters per energy channel) and/or the aggregate spectra of individual radiation detectors (3) (accumulated counts of individual radiation detectors per energy cannel) and, from the individual spectra and/or the aggregate spectra, determines, if appropriate, the total counts of the radiation detectors (3) (counts over entire energy range), and/or the aggregate total counts of individual radiation detectors (3) (accumulated total counts of individual radiation detectors). It is proposed that the evaluation unit, during the coarse measurement, with low channel resolution, generates the individual spectra of the radiation detectors (3) and/or the aggregate spectra of individual radiation detectors (3) and, upon identifying an alarm condition, generates an alarm for the relevant measurement location at the measurement volume (1), and that the evaluation unit, in the case of an alarm, in a fine measurement at the measurement location (1) to be assigned to the alarm, with high channel resolution, generates the individual spectrum of a radiation detector (3) and/or the aggregate spectrum of individual radiation detectors (3) and performs a nuclide analysis on the basis thereof.

Description

 Radiation detector device

The present invention relates to a radiation detector device according to the preamble of claim 1 and to a radiation detector according to the preamble of claim 14.

The radiation detector device in question is becoming increasingly important today, since radiating materials are increasingly entering the material cycle. Radiation sources here are, for example, steel and iron from nuclear power plants, control radiation sources of medical activity measuring devices or the like or products with luminous paint application.

In the present case, the identification of radioactive contaminants in a measuring volume of scrap, semi-finished products or the like is in the foreground. This is not to be understood as limiting.

The known radiation detector device (WO 2006/095188 A1), from which the present invention is based, comprises a frame to which an arrangement of radiation detectors, there gamma- radiation detectors, is attached. Lorries loaded with metal scrap can pass through this frame and be checked for radioactive contamination.

In the known radiation detector device is checked in a first step, if there is any kind, increased radiation exposure. In a second step, a nuclide analysis is performed on the presence of certain nuclides in the measuring volume. In both measuring steps, it is provided in a variant to interconnect a plurality of radiation detectors to increase the sensitivity.

Radiation detectors with scintillator crystals are used in the known radiation detector device. If radiation quanta of the radiative material present in the measuring volume hit the scintillator crystal of a radiation detector, light flashes are produced in the scintillator crystal, which are converted by means of a converter with a photocathode into radiation detector signals.

CONFIRMATION COPY Each radiation quantum incident in the scintillator crystal generates a voltage pulse in the radiation detector signal, the magnitude of which is proportional to the energy of the incident radiation quantum.

Usually, the entire relevant energy range of the radiation quanta is subdivided into a plurality of equally wide energy bands, which are referred to as energy channels. In a measurement process, the incidence of a radiation quantum triggers a voltage pulse, as explained above, which is assigned to one of the energy channels via its height. The measured number of radiation quanta is referred to herein as "counts".

The indication of the counts per energy channel for a single radiation detector corresponds to the single spectrum of the respective radiation detector. Alternatively, the counts of individual radiation detectors per energy channel are summed up. This is then the sum spectrum of these radiation detectors.

The above spectra, in particular the local distributions of spectral peaks, allow a simple nuclide analysis. The reason for this is that each nuclide can be assigned a characteristic spectral "fingerprint".

From the individual spectra or the sum spectra, it is also possible to determine the total counts of the radiation detectors, ie the counts over the entire energy range, and the total totals of individual radiation detectors, ie the summed total counts of individual radiation detectors.

A challenge in the implementation of the known radiation detector device is that during the measurement process the truck having the measuring volume passes through the radiation detector device, so that only little time remains for the determination of the above spectra. However, this also means that comparatively few counts per energy channel can arise during the measurement process. This has an unfavorable effect on the quality of the measurement results. The invention is based on the problem of designing and further developing the known radiation detector device in such a way that a high measurement quality is ensured even with a fast relative movement between the measuring volume and the radiation detector device.

The above problem is solved in a radiation detecting device according to the preamble of claim 1 by the features of the characterizing part of claim 1.

The proposed solution is based first of all on the idea of making a coarse measurement for the triggering of an alarm after detection of increased radioactive radiation, and, after alarm triggering, a fine measurement for nuclide analysis. This takes into account the fact that a coarse measurement for mere alarm generation, ie without nuclide analysis, in a manner yet to be explained with little time is possible, which takes into account the relative movement between the measuring volume and the radiation detector device.

It is essential that the evaluation unit generates the individual spectra of the radiation detectors and / or the sum spectra of individual radiation detectors with a low channel resolution during the coarse measurement. A low channel resolution means that the total counts of a measurement process are divided into only a few energy channels. With high channel resolution, the total counts split accordingly to a high number of energy channels. In order to be able to make statistically reliable statements, it can be expected that a measurement process with a high channel resolution takes longer than a measurement process with a low channel resolution.

As a result, with the low channel resolution in the coarse measurement it is achieved that the coarse measurement requires only a short time and thus the relative movement between the measuring volume and the radiation detector device is unproblematic.

With the low channel resolution, it is accepted that a nuclide analysis is hardly or not at all possible, since the spectral "fingerprint" of the nuclides is barely or not at all resolvable. In order nevertheless to enable a nuclide analysis, it is proposed that the evaluation unit in a fine measurement at the measuring point to be assigned to the alarm generate the individual spectrum of a radiation detector and / or the sum spectrum of individual radiation detectors with high channel resolution and then carry out a nuclide analysis.

With a suitable design of the proposed radiation detector device, it is therefore possible to achieve an optimum compromise between speed on the one hand and measuring accuracy on the other hand.

The proposed solution makes it possible according to claim 3 that the coarse measurement is repeated during the passage of the measuring volume and the radiation detecting device in short periodic intervals, wherein the relative position of the alarm point to be assigned to the measuring volume for performing the subsequent fine measurement is stored. This relative position can be calculated, for example, by determining the relative speed between the measuring volume and the radiation detector device.

During the fine measurement, preferably no relative movement is provided between the measuring volume and the radiation detector device according to claim 4. This can be achieved, for example, by positioning the truck or the like carrying the measuring volume, for example with the aid of the display unit, at the corresponding location in front of the respective radiation detector or in front of the respective radiation detectors.

Scintillator crystals have the great advantage that high signal resolution in the energy range can be achieved, which is associated with a particularly high quality in nuclide analysis. Furthermore, the formation of sum spectra of individual radiation detectors allows spatial detection ranges to be achieved to an almost unlimited extent.

In the preferred embodiment according to claim 5, it is therefore provided that radiation detectors are interconnected to form the above sum spectra and arranged substantially in a plane to to increase the effective radiation detector area and thus the spatial detection area.

With the formation of a sum spectrum of several radiation detectors, the sensitivity with regard to alarm generation and nuclide detection can indeed be increased. However, the resulting result in the formation of the sum spectrum always refers to the correspondingly enlarged detection range, which impairs the spatial resolution of the measurement. Therefore, it is proposed according to claim 6 to first perform the fine measurement based on the single spectrum of a single radiation detector and only if the resulting nuclide analysis due to insufficient expression of spectral peaks does not allow the identification of a nuclide to produce the sum spectrum of this radiation detector and at least one other radiation detector and based on it to carry out the nuclide analysis.

The particularly preferred embodiment according to claim 9 shows a particularly effective solution for the consideration of the background radiation in the alarm generation. The problem is not the existence of the background radiation as such, but the shielding effect of the container of the measuring volume, the truck o. The like., Which can lead to an unknown in the coarse and fine measurement reduction of the background spectrum.

According to claim 9, it is proposed to compare the relative count distribution of an energy spectrum determined without measurement volume with the relative count distribution of the energy spectrum determined with measurement volume in order to be independent of the above reduction of the background spectrum. In principle, this principle is known (DE 695 18 504 T2). In the present case, however, it has been recognized that the channel resolution for this principle is completely irrelevant, so that an application to the proposed coarse measurement (with low channel resolution) with simple means leads to a particularly fast and at the same time fault-tolerant overall system.

According to another teaching according to claim 14, which is also of independent significance, a radiation detector device is claimed in which it depends on a relative movement between the measuring volume and the radiation detector. direction does not arrive. For the rest, with regard to the basic structure, however, reference may be made to the comments on the first teaching.

Essential according to the further teaching is the fact that the radiation detector is preferably arranged in a completely substantially closed, shielding housing having an array of windows, preferably made of plastic or ceramic, for the passage of radioactive radiation and thus for setting the detection area.

The further teaching shows a solution to increase the quality of measurement by a special construction of the radiation detector device, and not necessarily by the control measures mentioned above.

It has been recognized that although a housing with windows has a lower permeability to radioactive radiation than a housing completely open to the detection area, the design and arrangement of the windows opens up new degrees of freedom in the design of the spatial detection area. In addition, such a closed housing provides a particularly robust protection against external influences.

In the following the invention will be explained in more detail with reference to a drawing illustrating only embodiments. In the drawing shows:

1 shows a proposed radiation detector device with retracted truck from the front,

FIG. 2 shows the radiation detector device according to FIG. 1 from the side, FIG.

3 shows a partial section of the radiation detector device according to FIG. 2 in a sectional view according to the section line III-III, FIG.

4 shows a proposed radiation detector,

5 shows a single spectrum in the coarse measurement with and without alarm, and

Fig. 6 is a single spectrum in the fine measurement. The radiation detector device illustrated in FIGS. 1 and 2 serves to identify radioactive contaminants in a measuring volume 1 which is accommodated here and preferably in a truck 2. The transport of the measuring volume 1 in a truck is of course only an example, and not restrictive to understand. It is also conceivable that the measuring volume 1 is transported on a conveyor belt or the like or is arranged stationary.

The measuring volume 1 may be any supposedly radioactively contaminated material, in particular metal scrap, semi-finished products or the like.

The radiation detector device has an arrangement of radiation detectors 3, an evaluation unit, not shown, and a display unit, not shown. In the illustrated embodiment, a total of four radiation detectors 3 are provided. Depending on the application, a higher or lower number of radiation detectors 3 may be provided.

The radiation detectors 3 are each crystal detectors. Accordingly, the radiation detectors 3 are each equipped with a scintillator crystal 4 and a converter, not shown, for providing the radiation detector signals. The scintillator crystal 4 is here and preferably oblong and round in cross-section configured. There are also conceivable in cross-section rectangular or square configurations.

During a first coarse measurement, it is provided that the measuring volume 1 and the radiation detector device pass each other. Here, this means that the truck 2 passes through a toroidal structure on which the radiation detectors 3 are mounted.

During the coarse measurement, the evaluation unit determines the individual spectra of the radiation detectors 3 and / or the sum spectra of individual radiation detectors 3. The total counts of the radiation detectors 3 and / or the sum total counts of individual radiation detectors 3 are optionally also determined from the individual spectra or the sum spectra. It is essential that the evaluation unit generates the individual spectra of the radiation detectors 3 and / or the sum spectra of individual radiation detectors during the coarse measurement with a low channel resolution. Fig. 5 shows a single spectrum with alarm (hatched filling) and no alarm (black filling).

Upon detection of an alarm condition, here at the exceeding of a limit to be explained (Fig. 5, white filling), an alarm for the relevant measuring point on the measuring volume 1 is generated. This is the case in the spectrum shown in Fig. 5 in the channels 10, 1 1 and 12 of the case. The measuring point is here any point on the truck 2 at which the alarm was triggered during the coarse measurement.

In the event of an alarm, the evaluation unit generates the individual spectrum of a radiation detector 3 and / or the sum spectrum of individual radiation detectors 3 in a fine measurement at the measuring point to be assigned to the alarm. Based on this, the evaluation unit then performs a nuclear analysis to check which one Nuclide or which nuclide composition the radioactive contaminant decreases. The advantages of coarse measurement with low channel resolution and fine measurement with high channel resolution have been explained in the general part of the description.

FIG. 6 shows a single spectrum generated in the context of fine measurement with a channel resolution of 1024 channels in the event of an alarm. The alarm case shown in Fig. 6 corresponds to the alarm case shown in Fig. 5. A comparison of FIGS. 5 and 6 shows that spectral "fingerprints" can always be detected automatically with the high channel resolution.

It has been shown in tests that the limit between low channel resolution and high channel resolution in the above sense optimally lies with 256 energy channels. Preferably, it is therefore provided that the low channel resolution corresponds to a division of the relevant energy spectrum into a maximum of 256 energy channels. Further preferably, the high channel resolution corresponds to a division of the relevant energy spectrum into a number of more than 256 energy channels. In a preferred embodiment, the low channel resolution is a 32-channel resolution and the high channel resolution is a 1024-channel resolution. This has been proven in the application of the above truck measurement with measuring volume of scrap metal and semifinished products.

Because the coarse measurement can be carried out particularly quickly as explained, it is preferably provided that the evaluation unit repeats the coarse measurement during the passage of the measurement volume 1 and the radiation detector device at periodic intervals. The measuring volume 1, in this case the measuring volume 1 arranged in the truck 2, is to a certain extent scanned "slice by slice." If an alarm occurs during the scanning, it is further preferably provided that the evaluation unit determines the relative position of the measuring point to be associated with the alarm for the subsequent measurement The fine measurement is associated with a greater expenditure of time than the coarse measurement, so that no relative movement is provided during the fine measurement between the measurement volume 1 and the radiation detector device.

The truck 2 passes through the radiation detector device at walking speed during the coarse measurement. If an alarm has been generated at any measuring point, the truck 2 is positioned a second time in the radiation detector device, specifically so that the measuring point to be assigned to the alarm is positioned in front of at least one of the radiation detectors 3, in particular in front of the radiation detector 3 triggering the alarm is.

For the second entry or the resetting of the truck 3, the driver of the truck can be given a position via the display unit, so that the respective measuring point comes to stand on the corresponding radiation detector 3. Fully automatic systems are also conceivable here, for example by a motorized longitudinal adjustment of the radiation detectors 3. FIG. 1 shows that the radiation detectors 3 are pairwise substantially in one plane, in such a manner that the effective radiation detector area is increased. It is quite generally proposed that the radiation detectors involved in the coarse measurement and / or in the fine measurement on the formation of the sum spectrum lie substantially in one plane, precisely in order to increase the effective radiation detector area.

It has already been pointed out that the fine measurement may also be carried out in two stages. In a first stage, it is provided that in the event of an alarm, the evaluation unit generates the individual spectrum of a radiation detector 3 at the measuring point to be assigned to the alarm and, based on this, carries out the nuclear analysis. In the event that the expression of spectral peaks in the single spectrum is not sufficient to carry out the identification of a nuclide, it is proposed to generate the sum spectrum of this radiation detector 3 and at least one further, in particular adjacent, radiation detector 3. Based on this, the nuclide analysis can then be carried out with better chances of success.

The best results have been shown in experiments, when the fine measurement is based on the individual spectrum or the sum spectrum of the radiation detector 3 or the radiation detectors 3, which or was the cause of the alarm triggering was or were. Of course, this is only possible if the truck 2 retracts or resets into the radiation detector device.

In application cases in which there is a high throughput of to be tested measuring volume 1, it is preferably provided that the fine measurement with an additional, separate radiation detector 6 or with additional, separate radiation detectors 6 takes place in the respective direction of movement, here the Movement direction of the truck 3, seen behind the radiation detector 3 and the radiation detectors 3 is or are, the or was the cause of the alarm was or were. Such additional, separate radiation detectors 3 are shown in FIG. 2 in dashed line. It is conceivable here that an alarm is generated at a measuring point by the first radiation detectors 3 and that the truck 2 is stopped when the measuring point reaches the further radiation detectors 6 Has. Then, the fine measurement can be done without the truck has to be retracted or reset a second time in the radiation detector device.

It has been pointed out in the general part of the description that the background radiation always present has to be taken into account in one way or another. Here and preferably, it is provided that the evaluation unit initially determines the energy spectra without measurement volume 1, which is referred to herein as "background spectrum." This can be done in a calibration process, which is preferably repeated periodically at specific intervals During the coarse and fine measurement, the energy spectra are then determined with measuring volume 1. In the present case, these energy spectra are referred to as "measuring spectrum" in each case.

During the coarse measurement, the relative count of the background spectrum relative to the respective total counts (over the entire relevant energy range) is compared with the corresponding relative count value of the measurement spectrum, an alarm being triggered with a predetermined deviation of the two relative count distributions from one another. This alarm generation to be carried out by the evaluation unit is based on the comparison of the relative, ie on the total counts, courses of the energy spectra. A lowering of the energy spectrum as a whole, as caused for example by the shielding effect of the truck, has accordingly only a statistical influence on the measurement result.

FIG. 5 shows, in addition to the relative count distributions with and without alarm, a limit value which is calculated from the background spectrum. It should be noted that the values in FIG. 5 are just relative values in the above sense, namely the counts attributable to an energy channel in relation to the respective total counts.

In the simplest case, the limit values result by adding a constant to the relative count distribution of the background spectrum. This constant can be the standard deviation associated with the energy spectrum and / or a user-defined parameter value. Numerous possibilities for the design of the scintillator crystal 4 are conceivable. In a particularly preferred embodiment, however, the scintillator crystal 4 is a sodium iodide crystal (Nal crystal) or a cesium iodide crystal (Csl crystal) having a volume of at least 0.5 l (liter), preferably at least 1 1 (liters).

Another interesting scintillator crystal alternative to a sodium iodide crystal or a cesium iodide crystal is a bismuth (BGO) crystal that has much better photopeak efficiency over a sodium iodide or cesium iodide crystal.

It can be seen from the synopsis of FIGS. 1 to 3 that the radiation detectors 3 are of elongated design and have a shield 7 on the rear side and laterally relative to the detection region. In Fig. 3, the detection area are located at the top, the back area corresponding to the bottom and the side areas corresponding to the left and right.

In cross-section, the shields 7 each have a plate-like portion 7a on the rear side, from the two ends of which two wing-like portions 7b project funnel-shaped towards the detection area. With this funnel-shaped configuration, collision of radiation quanta into the scintillator crystal 4 is also possible at a certain angle.

It is also conceivable, however, for the shield 7 to be at least partially, preferably completely, substantially closed and for the detection area to have an arrangement of windows 8, preferably of plastic or ceramic, for the passage of radioactive radiation. Such a shield 7 with windows 8 is shown in Fig. 4. It has already been explained that with such windows, the detection range of the respective radiation detector can be adjusted within a wide range.

An above radiation detector 3 with an at least partially, preferably completely, substantially closed, shielding housing 9, which has an arrangement of windows 8, preferably made of plastic or ceramic, for the passage of radioactive radiation and thus for setting the detection mode. empire is the subject of another doctrine of independent significance. The measuring method proposed after the first teaching does not matter here. Incidentally, reference may be made to all the above explanations regarding the radiation detectors 3.

Finally, it should be pointed out that the above windows 8 can be made of any materials that allow the passage of radioactive radiation. In principle, the windows 8 in the above sense can also be pure openings in the shield 7 or in the housing 9.

Claims

claims

A radiation detector device for identifying radioactive contaminants in a measuring volume (1) comprising an array of radiation detectors (3), an evaluation unit and a display unit, the radiation detectors (3) each having a scintillator crystal (4) and a converter for providing the radiation detector signals, wherein during a first coarse measurement, the measuring volume (1) and the radiation detector device pass each other, the evaluation unit during the coarse measurement the individual spectra of the radiation detectors (3) (counts per energy channel) and / or the sum spectra of individual radiation detectors (3) (summed counts of individual Radiation detectors per energy channel) and from the individual spectra or the sum spectra if necessary the total counts of the radiation detectors (3) (counts over the entire energy range) and / or the total totals of individual radiation detectors (3) (summed total counts of individual radiation detectors oren),

characterized,

during the coarse measurement with low channel resolution, the evaluation unit generates the individual spectra of the radiation detectors (3) and / or the sum spectra of individual radiation detectors (3) and generates an alarm for the relevant measuring point on the measuring volume (1) when an alarm condition is detected and that the evaluation unit in the event of an alarm, the individual spectrum of a radiation detector (3) and / or the sum spectra of individual radiation detectors (3) is generated in a fine measurement on the measuring point (1) with high channel resolution which is to be assigned to the alarm and a nuclide analysis is carried out based thereon.

2. Radiation detector device according to claim 1, characterized in that the low channel resolution of a division of the relevant Energiesper- rum in a number of a maximum of 256 energy channels, preferably 32 energy channels, and the high channel resolution of a division of the relevant energy spectrum in a number of more than 256 Energy channels, preferably of 1024 energy channels corresponds.

3. Radiation detector device according to claim 1 or 2, characterized in that the evaluation unit, the coarse measurement during the passage of the Measuring volume (1) and the radiation detector device at periodic intervals repeated, preferably, that the evaluation unit stores the relative position of the alarm to be assigned measuring point for carrying out the subsequent fine measurement.

4. Radiation detector device according to one of the preceding claims, characterized in that during the fine measurement between the measuring volume (1) and the radiation detecting device no relative movement is provided.

Radiation detector device according to one of the preceding claims, characterized in that the radiation detectors (3) involved in the coarse measurement and / or in the fine measurement of the formation of the sum spectrum lie substantially in one plane in order to increase the effective radiation detector area.

6. Radiation detector device according to one of the preceding claims, characterized in that the evaluation unit in case of alarm, the individual spectrum of a radiation detector (3) generated at the alarm to be assigned measuring point and based on the nuclide performs and that the evaluation unit in the event that the individual spectrum due to insufficient Expression of spectral peaks, the identification of a nuclide not allowed, the sum spectrum of this radiation detector (3) and at least one other, in particular adjacent radiation detector (3) generated and based on the nuclide analysis performs.

7. Radiation detector device according to one of the preceding claims, characterized in that the fine measurement is based on the individual spectrum or the sum spectrum of the radiation detector (3) or the radiation detectors (3), which was or were the cause of the alarm.

8. Radiation detector device according to one of the preceding claims, characterized in that the fine measurement with an additional, separate radiation detector (3) or with additional, separate radiation detectors (6) takes place, or seen in the respective direction of movement behind the radiation detector (3) or the radiation detectors (3) lies or lie, which was or were the cause of the alarm triggering.

9. Radiation detector device according to one of the preceding claims, characterized in that the evaluation unit the energy spectra respectively without measurement volume - background spectrum - and with measurement volume - measurement spectrum - determined and compares the relative, related to the respective total counts count distribution of the background spectrum with the corresponding relative count distribution of the measurement spectrum and at a predetermined limit deviation of the two relative Countverteilungen an alarm triggers each other.

10. Radiation detector device according to one of the preceding claims, characterized in that the Szintillatorkristall (4) has a Nal crystal or a Csl crystal and that the Nal crystal or the Csl crystal has a volume of at least 0.5 1, on preferably at least 1 1.

1 radiation detector device according to any one of the preceding claims, characterized in that it is the scintillator crystal (4) is a BGO crystal.

12. Radiation detector device according to one of the preceding claims, characterized in that the radiation detectors (3) are elongated and each having a shield (7) based on the detection area on the back and side, preferably, that in cross section, the shields (7) each back one plate-like portion (7a), project from the two ends of two wing-like portions (7b) funnel-shaped to the detection area.

13. Radiation detector device according to claim 12, characterized in that the shield (7) at least partially, preferably completely, is designed substantially closed and the detection area towards an arrangement of windows (8), preferably made of plastic or ceramic, for the passage of radioactive radiation having.

14. Radiation detector for identifying radioactive contaminants in a measuring volume (1) with at least one scintillator crystal (4),

characterized,

in that the scintillator crystal (4) is arranged in an at least partially, preferably completely, essentially closed, shielding housing (9), which faces the detection area an arrangement of windows (8), preferably of plastic or ceramic, for the passage of radioactive Having radiation.