WO2010061081A2 - Self-contained device and method for monitoring the radioactive contamination of a user - Google Patents

Abstract

The invention relates to a device (1) and a method for monitoring the contamination of a user with a radioactive element emitting beta radiation, provided with at least two vertically arranged proportional counter panels (12) with gas circulation, connected in series and suitable for detecting beta radiation. Each panel (12) comprises a frame (21) shaped like a parallelepiped vessel for retaining the gas and forming a cathode, a sheet (26) of conductive polymer attached to the top rim (27) of said vessel, a conductive metal grating (29) for protecting said panel, attached and electrically connected to said frame, sandwiching said sheet, and a rigid edge (B) for uniformly clamping the perimeter of the grating against the top rim of the frame. The device includes a means for sealing the vessel made up of a means for sticking the polymer sheet to the entire perimeter of the top rim (27) of said vessel, the gas supply circuit for the two panels comprising a built-in gas tank (R).

Description

AUTONOMOUS DEVICE AND METHOD FOR CONTROLLING RADIOACTIVE CONTAMINATION OF A USER

The present invention relates to an autonomous device for controlling the contamination of a user by a radioactive element emitting beta radiation, comprising a gantry of passage of the user between a zone subject to contamination called hot zone, and a zone less subject to contamination and / or directly accessible to the public, called cold zone.

It also relates to a contamination control method implementing such a device. It finds a particularly important application although not exclusive in the field of the detection of the contamination of individuals working in a controlled zone, inside a nuclear installation, detection allowing a control of the presence of radioactive elements emitting radiation beta and / or gamma, all over their body.

Apparatus or devices are already known for subjecting an individual to controls for detecting the contamination of his body and / or his clothing with radioactive products emitting beta radiation, comprising a casing substantially in the form of a cupboard or portico , on the inner side of which are arranged a plurality of proportional flow gas meter panels adapted to detect the radiation emitted substantially over the height of the individual placed vis-à-vis. Those exposed to the risk of contamination are then successively controlled on the anterior and posterior side, an order being given to the person to turn 180 ° once the control of a face performed.

Such devices, however, have several disadvantages.

A first disadvantage comes from the very use of gas proportional meters, which require a permanent gas flow in the meters to ensure good reliability of measurements. A continuous flow is indeed necessary to minimize the risk, either not to allow the detection, or on the contrary to generate false alarms, generating considerable nuisance in the day-to-day work of users.

A second disadvantage of known portals is related to the complexity of the maintenance operations concerning them. The maintenance operator must indeed, by design devices continuously fed, to intervene on meters located on the internal face of the gantry, from inside the latter located in a potentially contaminated hot zone. In case of contamination of the interior of the gantry, such an operation can be particularly complex, long and make the control means unavailable for a time requiring the provision of dubbing facilities. To limit the risks of breakdowns and poor detection, in the event of partial deterioration, the gantries of the prior art then sought to provide sufficient number of flat detectors. to compensate for the malfunction of one of them, while allowing a more precise detection of the location of the contamination, each proportional counter detector being associated with a specific anode corresponding to a determined geographical detection area.

Such an arrangement, however, has the disadvantage of increasing the shadow areas, which are the junction areas between meter panels and which are structurally obviously unable to detect a radiation emission.

Finally, the devices of the prior art all require to be connected to a fixed gas supply system, which generates specific civil engineering installations, with rigid piping circuit and imposes the immobility of the gantry to a station irremovable.

The present invention aims to overcome these disadvantages. It aims to propose a solution that better than those previously known to the requirements of the practice, particularly in that it proposes a device and a method considerably limiting the gas consumption of the beta radiation detectors, which will allow to provide a reservoir integrated gas and thus make the gantry autonomous and mobile, if necessary, in that it allows easy maintenance, especially only from the cold zone, while allowing a fine control of the location contamination and by significantly limiting the shadows, for improved cost and reliability. For this purpose, the present invention proposes in particular a device for controlling the contamination of a subject with a radioactive element emitting beta radiation, said device being provided with at least one proportional gas flow counter panel capable of detecting the beta-ray, said panel comprising a parallelepipedic cathode-gas-holding tank-shaped frame, a conductive polymer sheet attached to the upper edge of said tank, a conductive metal protective grid of said fixed panel and electrically connected to said frame; taking said sandwich sheet and a border (B) of uniform plating of the perimeter of the grid on the upper edge of the frame, characterized in that the subject being a user, the device comprises a passage gantry of the user provided with at least two of said proportional counter panels, arranged vertically, connected in series, in that tank sealing means formed by gluing means of the polymer sheet over the entire periphery of the upper edge of said tank and in that the gas supply circuit of the two panels comprises a tank (R ) of integrated gas.

The low gas consumption is obtained thanks to the glue sealing of panels supplied in series as described above, a discontinuous feed rate from an on-board tank being provided, whether or not it is controlled automatically. . With the invention it is thus possible to have a range of six to twelve months with only a reservoir bottle 5 1 inflated to 200 bar.

The risks of leakage are further minimized thanks to the limited number of panels.

In advantageous embodiments, one and / or the other of the following provisions is also used: the integrated gas tank is a removable bottle of pressurized gas with a capacity of less than or equal to 10 l, by Example 5 1;

the device comprises means for moving the gantry making it mobile; the gas supply circuit of the two panels comprises a gas supply valve and opening / closing control means of said valve arranged to supply the gas panels at a fixed rate;

the device comprises a gas supply valve, means for controlling the opening and closing of said valve suitable for feeding the panels discontinuously, electronic means for compensating for the loss of efficiency of the device; due to the pollution of the air gas in the panels over a given range, said compensation means comprising means for measuring said pollution, means for calculating and controlling said compensation from a higher threshold value called good operation in clean gas, and means for controlling the control means of the valve to said measurement, for gas supply from a lower threshold value of said range, until re-obtaining of said upper threshold value and reclosing the power supply; the electronic compensation means comprise means arranged to increase the gain of the acquisition chain of the device; the electronic compensation means comprise means arranged to adapt the threshold of discrimination of the pulses emitted by the detected beta radiation. More precisely, the principle here is to compensate for the loss of efficiency over time of the beta detector associated with the panels (non-continuous gas supply), and this because of the progressive pollution of the gas in the air, in particular because of micro -fits, by a dynamic adaptation of the electronics either by increasing the gain of the acquisition chain (by increasing the high voltage supply of the detector and / or by increasing the gain of the Beta radiation detection amplifier or) by adjusting the discrimination threshold of the pulses generated by the passage of Beta radiation in the panel gas. This compensation is made only over a specific range, ie between an upper threshold value (known as a good operating value) and a lower threshold value.

It makes it possible to further minimize the periodicity and / or the duration of the gas tank feeding times.

When the compensation arrives at the range limit, the circulation of the gas becomes effective again.

This re-circulation of the gas has the effect of repurifying the gas and thus progressively increase the efficiency of the detector. Advantageously, the dynamic compensation of the electronics also works in the sense of raising the efficiency of the detector to maintain a homogeneous detection sensitivity. When the optimal efficiency of the detector is found, the flow of gas is interrupted.

Thus, the gas supply cycle is slaved to both the sealing level of the detector (gas exchange with the outside, due to micro-leakage for example, resulting in a loss of efficiency of the detector) and the possibilities compensating for this loss of efficiency by electronics;

the reservoir comprises means for remote management of the gas reservoir, suitable for measuring the consumption and the level of gas reserve of said reservoir;

the conductive polymer is a material known under the trademark Mylar, the sheet being of grammage less than or equal to 2 mg / cm ² , the device being designed to detect emitters with energy of less than or equal to 6.5 Kev. Such an arrangement allows the detection of activation products such as ⁵⁵ Fe or ¹⁴ C;

- Each panel has at least five parallel anodes arranged regularly through its frame, each panel being rectangular, surface greater than or equal to 0.5 m ² .

Nothing suggested such a number of anodes per panel in the prior art, for such applications, especially in view of sealing concerns with proportional meters with traditional gas circulation; - The bonding means are formed of a film of adhesive spread throughout and on the upper face of the upper edge of the tank.

The simplicity of such a bonding and its ease of implementation, did not presume the sealing obtained, conventionally achieved by O-ring and all the more so that one could fear a bad behavior in the time of a adhesive bonding; the gantry comprises two series of two vertical panels, extending substantially over the height of the user placed opposite each other, the two series extending each in a plane forming with the plane of the other series, an angle of between 120 and 170 °, advantageously 140 °;

each panel comprises at least eight anodes respectively connected to an electronic collection and processing circuit specific to each anode suitable for attacking a central control and control unit of an alarm;

- The panels are fixed in a support frame and are arranged laterally in a plane substantially parallel to the direction of passage of the user, said support being mounted on a horizontal sliding rack integral with the rest of the frame and being arranged to be extracted from a single block of the rest of the gantry from only one of the side faces of said gantry by simple sliding.

Thanks to the simplicity of the sealed assembly according to the invention such an arrangement on a sliding rail, for extraction in a single block, could be developed; - The gas circuits of the panels are connected and isolatable from each other by sealed self-sealing quick connectors;

the device furthermore comprises at least one scintillating plastic block for detecting gamma radiation; it has four gamma detection blocks arranged in parallel and behind the beta detection panels; it furthermore comprises correlation means between measurement of the gamma detector (s) and measurement of the beta detector (s), and alarm in case of incoherence between signals;

- It comprises anomaly signal means in case of increase of the background noise.

This control means appeared extremely effective due to the discontinuous operation according to the invention.

The invention also provides a method implementing the device as described above.

It also provides a method for controlling the contamination of a subject with a beta radiation emitting radioactive element, comprising at least one gas flow proportional counter panel capable of detecting beta rays, said panel comprising a beta-shaped frame. parallelepipedic cathode gas retention tank, and a conductive polymer sheet fixed thereto, characterized in that, the subject being a user, the control is carried out by a passage gantry of the user provided with at least two panels of proportional counter capable of detecting the beta rays emitted substantially over the height of the user placed opposite, in that the panels connected in series by a removable reservoir (R) integrated in the frame of the gantry are supplied with gas, the fixing and the sealing of each panel, being carried out by means bonding and clamping means on the entire periphery of the upper edge of said vessel.

In an advantageous embodiment the gas supply is automatically discontinuous.

Also advantageously, the gas / air pollution is measured and a dynamic adaptation of the electronics of the panels compensates for the loss of efficiency of the detection due to said pollution over a range determined from an upper threshold value for good operation in clean gas of said decreasing range to the lower threshold value of said range, before refeeding gas from said lower threshold value to obtain said upper threshold value.

In an advantageous embodiment, the loss of efficiency is compensated by increasing the gain of the acquisition chain and / or by adjusting the discrimination threshold of the Beta radiation pulses. Advantageously the control is carried out in a traveling manner by moving the gantry to bring it to the location of said control.

Also advantageously the panels being fixed in a support frame and arranged laterally in a plane substantially parallel, in the direction of passage of the user, said support being mounted on a horizontal sliding rack integral with the rest of the frame, the maintenance of the panels is carried out by extracting a single block from the rest of the gantry from only one of the lateral faces of said gantry by simple sliding.

In an advantageous embodiment, the device further comprising at least one gamma radiation detection scintillator plastic block, correlates between measurement of the gamma detector (s) and measurement of the beta detector (s), and an alarm is triggered in case of inconsistency between signals.

Advantageously, an anomaly signal is triggered in case of increase of the background noise.

The invention will be better understood on reading the following description of embodiments given as non-limiting examples. The description refers to the accompanying drawings in which:

Figure 1 is a perspective view of a gantry according to a first embodiment of the invention of the hot zone side. Figure 2 is a rear perspective view of the gantry of Figure 1, partly open, the cold zone side showing the internal gas tank.

Figure 3 is a rear perspective view from another angle, the gantry of Figure 2, showing the proportional counters panels in the extracted position for maintenance access.

FIG. 4 is a front view, in principle, of four counter panels according to the embodiment of the invention more particularly described here.

Figure 5 is an exploded perspective view showing the mounting of the meter panel according to one embodiment of the invention. FIG. 6 gives a schematic diagram of the beta and gamma detector means according to one embodiment of the device of the invention.

FIG. 7 gives a schematic diagram of the device according to one embodiment of the invention with electronic compensation means.

FIGS. 1, 2 and 3 show a gantry 1 formed of a metallic parallelepipedal box 2, comprising a hot zone side access face 3, provided with an inlet opening 4 closed by a pivoting barrier 5, for access by a user.

The gantry comprises an opposite exit face 6 of the user, closed by a transparent sliding door 7, on the cold zone side, which opens once the control operations are performed in a positive manner.

The gantry comprises, in a manner known per se, other control devices than those which will be described more precisely below in connection with the invention.

In particular, it includes for example a reader

8 electronic dosimeters, allowing the user to know the equivalent of dose he has undergone when he was in hot zone, disposed outside the box 2.

It also comprises a horizontal plate 9, formed by a gas flow proportional counter arranged to detect beta contamination of the feet, a device for detecting the presence of the user (not shown) of the positioning sensors of the hands, feet and upper body, and safety detectors (no shown) for the exit door 7. A computer screen 10 makes it possible to display the detection information on the cabin.

The gantry further comprises a sliding side face 11, formed by four panels 12 of proportional counters. These panels each form two series of two panels superimposed vertically, each located in a different plane, to form a V whose two sides or planes have between them an angle CX of 140 °.

According to the invention (see FIG. 2), the gantry comprises a bottle R for storing the feed gas for the panels, connected to the latter by means of a circuit which will be described below. The bottle R, which will for example allow autonomy for six months, is easily removable and manually replaceable from the cold zone.

The gantry also comprises means 46 (for example two sets of two lockable castors) for easy movement of the gantry.

Figure 3 shows the four panels 12, integral with a metal frame 12 'V-shaped angle, mounted on sliding rails 11' in the extraction position by the rear side cold side of the gantry.

The counter 9 for the feet is also extractable on this side, as are the gamma counters which will be detailed below. All the parts and electronic cards and motorization is also accessible by this rear face when the shutter and protection panel is removed, as shown in Figure 2. With reference to FIG. 4, the panels 12 are identical, rectangular and interconnected in series by a gas supply network (Argon + CO ₂ ). The network 13 comprises, upstream, the gas storage bottle R, for example composed of 90% Argon and 10% CO ₂ under pressure, for example a five-liter bottle at 200 bar with integrated expansion valve.

The bottle R is connected to the panel by a circuit 14 and comprises a pressure sensor 15 connected to remote management means 47 for remote maintenance of the consumption and gas reserve of the gantry.

Advantageously, the means A1 manage several devices including gantries 2 ', 2 "similar or identical to the gantry 2.

The circuit 14 comprises a regulator 16 connected to the internal gas circuit of the panels 12, which allows remote control by a central control unit 17 programmed to inject gas, the valve 18 supply.

In order to make them separable, the panels are interconnected to the network by snap-in quick couplings 20, for example of the type manufactured by the company STAUBLI.

Referring to Figure 5, each panel 12, for example 1 m by 40 cm, is formed of a metal frame 21 forming a parallelepiped cathode, forming a vessel whose walls are 13 mm in height and for example provided with new stiffeners 22 delimiting ten elements of identical surface 23 on the bottom of the frame.

The gas is introduced at 24. In the embodiment more particularly described here, each side proportional beta counter panel has ten 25 parallel-shaped anodes extending across the width of the frame.

The anodes are for example brought to a voltage of 1500 V relative to the cathode which is grounded. They are arranged regularly and transversely to the panel. This further comprises a sheet 26 of conductive polymer, for example material known under the trademark MYLAR, for example metallised MYLAR® with a density of less than 1.5 mg / cm ² , for example 0.85 mg / cm ² which completely covers the surface of the frame with the upper edge 27 to which it is fixed by gluing.

More specifically, in the embodiment of the invention more particularly described here, the sheet is fixed by means of an adhesive film 28, for example of the same width e_ as the edge of the frame, for example an adhesive said to "Transfer", formed of a layer of fine glue, for example 50 to 100 microns, deposited on the support by means of a roller 28 'for example manufactured by the company 3M.

The small thickness of polymer, less than 1.5 mg / cm ² of MYLAR®, which becomes possible with the excellent seal obtained with the invention, allows the detection of low energy emitter β, (= 6.5 Kev ) as that emitted by activation products ⁵⁵ Fe or ¹⁴ C.

This detection has always been problematic. In particular, it makes it possible to avoid more effectively risk of skin cancer caused by undetected contamination of this type of product.

The panel, for example, 1 m by 0.5 m furthermore comprises a protective grid 29 made of stainless steel formed, in a known manner, of honeycombs and of the same surface as the frame.

In the embodiment of the invention described here, the grid is plated on the MYLAR® sheet by a rigid border or stainless steel frame, for example 2.5 mm thick all around the detector.

It is fixed by metal screws 30 through the MYLAR ®, on the upper edge 27 of said frame, to ensure electrical continuity and allows to cancel the wave effect created by tightening the screws by distributing the crushing forces on the glue film.

In addition to the four β radiation counters for detecting the contamination of the body of the user in a lateral manner, there are provided so-called plastic scintillation counters of gamma radiation, known in themselves, for example two or four detectors directly. placed on the back of β radiation detectors. A spare side panel 12 'and a spare foot panel 9', both full of gas, as in series with the gantry gas circuit, are provided so as to allow the rapid exchange of a panel no need for gas circulation for several hours to purge air.

They are placed parallel to the panels 12 and behind lead plates (not shown). We will now describe with reference to the figure

6, the electrical and electronic diagram of the detection device according to the embodiment of the invention more particularly described here (see also Figure 2).

The circuit 31 comprises a circuit 32 of detectors β 33 and 34, namely four identical β 33 detectors, corresponding to the four panels 12, each provided with ten anodes 35 and a small counter β for the feet 34, provided for its part with four parallel anodes only.

These detectors are connected via a circuit 36 to a microprocessor processing card 37 of the signals detected to be connected, via a data bus 38, to a central control unit 39, or a microcomputer, and to implement a alarm, in case of detection beyond a determined threshold, by loudspeaker 40, also used to give instructions to the user. In the embodiment more particularly described here (cf FIG. 4), the central control unit 39 is also connected to the management means 47 (for example formed by a server computer programmed accordingly in a manner known per se), and directly or indirectly through these means 47 to the sensor 15 of the bottle or tank R.

The circuit 31 further comprises a detection circuit γ 41, provided with four scintillation blocks 42, each block being connected to a central unit 43, itself connected to the CPU 39, for correlation between β measurements and γ measurements. In a manner known per se, an inverter 44 and a rail 45 for supporting the relays, the 24V supply, etc., are provided on the rear face, on the cold zone side, to allow maintenance access, after opening the panel ( not shown) of rear protection.

FIG. 7 shows a device 50 according to one embodiment of the invention, comprising electronic means 51 for compensating for the loss of efficiency of the device due to the pollution of the gas in air.

The device 50 comprises four vertical panels 51 for detecting beta radiation 52, as described with reference to FIGS. 3, 4, 5 and 6. The panels are supplied with gas from the compact tank R by a circuit 53 which comprises the valve 54 gas supply, the purge valve 55 for gas filling / circulation and the means 56 for controlling the opening and closing of said valves, similar to the elements 17 and 18 described with reference to FIG. 4.

The device comprises, from the Beta detector 57 known in itself, electronic compensation means 58 connected to or integrated with a computer 59 for managing, calculating and restoring the detection data.

More precisely, the electronic compensation means 58 comprise means 60 for measuring the pollution of the gas in air in the panels or tanks of the panels, means 61 (microcontroller) for calculating and controlling said compensation from a threshold value. superior, said clean gas operation, and means 62 controlling the control means 56 of the valve 54 (and the valve 55) to the measurement of the pollution, for supplying gas from a lower threshold value of the range until the said upper threshold value is obtained again and closing the valves.

Recall that there are three ways to compensate for the loss of efficiency of the detector, either by increasing the high polarization voltage of the detector, or by increasing the gain of the amplifier, or by adjusting the discrimination threshold.

Of these three possibilities, there is one particularly advantageous. This is the one where it is necessary to adjust the high polarization voltage of the detector.

In this case, the lower threshold value corresponds to the maximum high voltage of the detector before it changes its operating mode (changeover from operating mode to counter proportional to a GM tube type regime). The maximum threshold value corresponds to the optimum value of high voltage. In other cases the threshold values are determined empirically, in a manner known in itself and within the scope of the skilled person.

In the embodiments more particularly described, the electronic servo-control means comprise means 63 for increasing the gain of the overall acquisition chain 64 of the device 50 by acting on the high-voltage supply 65 of the electrodes and / or means 66. arranged to adapt the discrimination threshold of the pulses emitted by the detected beta radiation. The operation of the detector 57 has been described in greater detail below. In order to operate, it is polarized at a voltage of the order of 1500 V to 2000 V via the high voltage supply 65.

The pulses from the detector 57 are amplified by the amplifier 67. The output 68 of the amplifier is connected to two comparators 69, 70, each comparator having a low threshold adjustable by the microcontroller 61. The outputs of FIG. each comparator (respectively 71, 72) is in fact connected to a pulse counting input of said microcontroller 61.

The microcontroller thus counts the pulses from each comparator.

The pulses at the output of the amplifier 67 are distributed as follows: - very small amplitude pulses: pulses due to the noise of the electronics, pulses of low amplitude at medium amplitude: pulses due to gamma radiation, pulses of average amplitude with high amplitude: pulses due to beta radiation.

The threshold of the comparator 69 is set to 73 so as to eliminate the noise of the electronics.

The threshold of the comparator 70 is set at 74 according to a compromise, in order to be able to eliminate as much as possible of pulses due to gamma radiation without reducing the efficiency of the beta radiation detector too much. By differentiating between the counts of the two channels or outputs 71 and 72, counting of pulses essentially from gamma radiation is obtained. The principle of operation of the entire compensation electronics will now be described below.

The pollution of the gas by air induces a loss of efficiency of the detector. The loss of efficiency of the detector results in a decrease in the amplitude of the pulses at the output of the amplifier.

In order to detect this loss of efficiency, and in the embodiment more particularly described, the following ratio is periodically calculated: [channel 1 pulses (71) - channel 2 pulses (72)] / channel 2 pulses.

This calculation is done only during the phases of measurement of background noise, so when there is no beta radiation. As long as there is no gas pollution, this ratio remains constant.

The pollution of the gas will reduce this ratio. The principle of servo control is to keep this ratio constant either by increasing the gain of the chain (increase of the value of the high voltage or increase of the gain of the electronics) or by decreasing the thresholds 1 and 2.

We will now describe the implementation of the device according to the embodiment of the invention more particularly envisaged here with reference to Figures 1 to 3.

The user who has intervened in a controlled zone (hot zone) may have been contaminated with particles radioactive radiation emitting beta radiation and / or gamma radiation.

In general these types of contamination go hand in hand. The entire body and clothing of the user must be controlled, including feet, hands and hair.

To do this, the user is in front of the gate 5 of the gantry which opens for example automatically. It then enters the interior of the cabin 2, and is placed in front of the panels 12, the sliding door 7 overlooking the cold zone being closed.

The V arrangement of the panels makes it possible to better adapt to the oblong configuration of the human body, the angle α having been optimized.

A presence detector for example integrated in the ceiling of the cabin, signals to the computer (Unit

Central) the presence of the user, who is given instructions to be pressed against the panels and that he places his feet and hands in the right places.

Optical detectors control the correct positioning of the hands (axis at 25 mm from the outer surface of the support plate of the panels 12), the feet (axis at 20 mm from the outer surface of the support plate of the panels 12) and the positioning of the back or face (25 mm axis of the outer surface of the support plate panels 12). Barrier 5 closes and control begins first from the front then from the back. At the end of the control, the screen of the computer 10 possibly allows the user to visualize the zones of panels corresponding to a detection of contamination due to the production of additional ions in the panel at the level of a specific anode, by avalanche effect, according to the principle of amplification of the ionization chambers of a proportional gas meter .

Each panel is supplied with gas (Argon + CO ₂ ) by the bottle R independently of the entry or not of a user in the cabin. The excellent tightness achieved with the invention makes it possible to have a large autonomy allowing a sufficient supply of gas for several months, with a reservoir of reduced capacity, for example from 1 to 200 bars. To do this, and in order to maintain the sufficient amount of gas in the panels, they are fed intermittently, for example for fifteen minutes, then closed the circuit 14 for 3:45 and so on, and automatically. By interrupting the flow and it will be possible to detect a leak.

Another embodiment is to measure continuously through a sensor (not shown) the pressure in the system formed by said panels connected in series.

When the pressure falls below a determined value, the solenoid valve 18 is opened and then the sufficient quantity of gas is injected to compensate for the (minimal) leaks that caused the pressure drop from the bottle R. .

For example a flow rate of 51 / h is injected for ten minutes, by opening and then closing the valve 18, the panels 12 connected in series then remaining without power until a new trigger by the next measurement.

With the configuration of the invention, it is therefore possible to have a very low consumption, allowing operation with the removable tank. The beta detection of the feet can also be mounted in series or apart from the beta detector panels of the body contamination. In the event of gas leakage, ^• the central unit is designed to detect an abnormal variation in the number of ionization in panels that react to natural irradiation, which triggers an alarm to involve maintenance. Furthermore, in the case of an empty tank or about to be, an alarm is transmitted to the means 47 which can initiate a response action and organize the replacement of the tank.

Advantageously, the means 47 manage several devices.

Simultaneously with the detection of a beta contamination, detection of gamma radiation is performed by four plastic scintillation detectors of known type. Their detection surface covers the entire body and goes down to 95 mm below the surface of the floor. Finally, note that lead plates are arranged on the back of the panels 12 to reduce the background noise and thereby improve performance.

The combination of the measurements made by the cards 37 and 42 of the detectors β and γ makes it possible to correlate them in the central unit 39 and triggers a alarm 40, in case of inconsistency between these measurements, automatically. In case of detection of contamination, the user comes out of the hot zone and decontaminates the part identified by the computer is indicated on the screen and through the speaker.

In case of non-contamination, the Central Unit asks the user to exit the gantry.

Then the door 7 opens automatically to let the user found uncontaminated. Otherwise the door does not open.

There is shown in Figures 2 and 3 the rear face of the cabin.

This allows direct and complete access to the various meters and their control units from the cold zone.

The foot 9 and side panels 12 are extracted simply by sliding them on rails 11 'before disassembly by means of quick couplers allowing the replacement of a panel by an advantageous replacement panel and located behind the lead screen, while in state already filled with gas, which allows an extremely fast replacement. •

The tank R is also removable and recoverable from the rear in the cold zone.

It is very easy handling due to its low weight.

As is obvious and as also follows from the above, the present invention is not limited to the embodiments more particularly described. On the contrary, it embraces all the variants and in particular those where the gantry has other additional detectors.

Claims

1. Device (1) for controlling the contamination of a subject by a beta radiation-emitting radioactive element, provided with at least one panel (12) of a proportional gas-flow-detecting counter (beta), said panel (12) comprising a frame (21) in the form of a parallelepipedal cathode gas retention tank, a sheet (26) of conductive polymer fixed on the upper edge (27) of said tank, a metal protection grid (29) conductor of said panel fixed and electrically connected to said frame by taking said sandwich sheet and a border (B) of uniform plating of the perimeter of the grid on the upper edge of the frame, characterized in that the subject being a user, the device comprises a gantry (2) for the passage of the user provided with at least two of said proportional counter panels, arranged vertically, connected in series, in that it comprises means for sealing the cuv e formed by bonding means of the polymer sheet over the entire periphery of the upper edge (27) of said tank and in that the gas supply circuit of the two panels comprises a reservoir (R) of integrated gas.

2. Device according to claim 1, characterized in that the tank (R) of integrated gas is a removable bottle of gas pressure of capacity less than or equal to 10 1.

3. Device according to any one of the preceding claims, characterized in that comprises means (46) for moving the gantry making it movable.

4. Device according to any one of the preceding claims, characterized in that the gas supply circuit of the two panels comprises a supply valve (18) and means (17) for controlling and closing said valve arranged to supply the gas panels according to a determined rhythm.

5. Device according to any one of the preceding claims, characterized in that the device comprises a gas supply valve, control means for opening and closing said valve to allow the gas supply of the panels of intermittently, electronic means for compensating for the loss of efficiency of the device due to the pollution of the air gas in the panels over a given range, said compensation means comprising means for measuring said pollution, means of calculation and controlling said compensation, from an upper threshold value of good functioning in clean gas, and means for controlling the control means of the valve to said measurement, for supply of gas from a threshold value. lower of said range, until re-obtaining of said upper threshold value and resetting of the power supply.

6. Device according to claim 5, characterized in that the electronic compensation means comprise means arranged to increase the gain of the acquisition chain of the device.

7. Device according to any one of claims 5 and 6, characterized in that the electronic compensation means comprise means arranged to adapt the threshold of

5 discrimination of the pulses emitted by the beta radiation detected.

8. Device according to any one of the preceding claims, characterized in that it comprises means (47) for remote management of the consumption and the level of the gas tank.

9. Device according to any one of the preceding claims, characterized in that the conductive polymer is a material known under the trademark Mylar, the sheet being of lower weight

Or equal to 2 mg / cm ² , the device being arranged to detect emitters of energy less than or equal to 6.5 Kev.

10. Device according to any one of the preceding claims, characterized in that

Each panel (12) has at least five anodes

(25) arranged regularly through its frame (21) and in that each panel is rectangular in area greater than or equal to 0.5 m ² . 11. Device according to any one of the preceding claims, characterized in that the means (28) of bonding are formed of a film of adhesive spread throughout and on the upper face of the upper edge of the tank. 12. Device according to any one of the preceding claims, characterized in that the gantry comprises two series of two vertical panels (12), extending substantially over the height of the user placed in opposite, the two series each extending and respectively in a plane forming with the plane of the other series, an angle between 120 and 170 °.

13. Device according to any one of the preceding claims, characterized in that each panel comprises at least eight anodes (25) respectively connected to an electronic collection and processing circuit specific to each anode suitable for attacking a central unit (39) control and control of an alarm.

14. Device according to any one of the preceding claims, characterized in that the panels (12) are fixed in a support frame and are arranged laterally in a plane substantially parallel to the direction of passage of the user, said support being mounted on a rack (H ') sliding horizontal integral with the rest of the frame and being arranged to be extracted from a single block of the rest of the frame from a single side faces of said frame by simple sliding.

15. Device according to any one of the preceding claims, characterized in that the gas circuits of the panels are connected and isolatable from each other by tight self-sealing quick connectors (20).

16. Device according to any one of the preceding claims, characterized in that it further comprises at least one block (42) plastic scintillator gamma radiation detection.

17. Device according to claim 16, characterized in that it comprises four blocks (42) of gamma detection arranged in parallel and behind the beta detection panels.

18. Device according to any one of claims 16 and 17, characterized in that it further comprises correlation means between measurement of the gamma detector (s) and measurement of the beta detector (s), and alarm in case of inconsistency. between signals.

19. Device according to any one of the preceding claims characterized in that it comprises means (39, 40) anomaly signal in case of increase in background noise.

20. Method for controlling the contamination of a subject with a radioactive element emitting beta radiation, comprising at least one panel

(12) counter proportional gas flow meter capable of detecting the beta rays, said panel comprising a rectangular parallelepipedic tank-shaped cathode gas retention frame, and a conductive polymer sheet attached thereto, characterized in that, the subject being a user, the control is carried out by a user passage gantry (2) provided with at least two proportional counter panels capable of detecting the beta rays emitted substantially over the height of the user placed facing each other. , in that the panels (12) connected in series by a removable tank (R) integrated in the frame of the gantry are supplied with gas, the fixing and sealing of each panel, being carried out by means (27) of bonding and clamping means (30, 13) on the entire circumference of the upper edge (27) of said tank.

21. Process according to claim 20, characterized in that the panels are supplied with gas in a discontinuous manner.

22. A method according to claim 21, characterized in that the gas / air pollution is measured and compensated by a dynamic adaptation of the panel electronics the loss of efficiency of the detection due to said pollution over a given range, to from an upper threshold value for clean gas operation of said decreasing range to the lower threshold value of said range, before refilling with gas from said lower threshold value to obtain said upper threshold value.

23. Method according to claim 22, characterized in that the loss of efficiency is compensated by increasing the gain of the acquisition chain and / or by adjusting the discrimination threshold of the Beta radiation pulses.

24. Control method according to any one of claims 20 to 23, characterized in that the control is performed in a traveling manner by moving the gantry to bring it to the location of said control.

25. A method according to any one of claims 20 to 24, characterized in that the panels (12) being fixed in a support frame and arranged laterally in a plane substantially parallel to the direction of passage of the user, said support being mounted on a horizontal sliding rack (H ') integral with the rest of the gantry, the panels are maintained by extracting the remainder of the gantry from a single block from a single side faces of said frame by simple sliding.

26. A method according to any one of claims 20 to 25, characterized in that, the device (1) further comprising at least one block (42) plastic scintillator gamma radiation detection, correlates between measurement or detectors gamma and measurement of the beta detector (s), and an alarm is triggered in case of inconsistency between signals.

27. Method according to any one of claims 20 to 26, characterized in that an anomaly signal is triggered in case of increase of the background noise.