EP2363876A1 - Ionising radiation detector - Google Patents

Abstract

The detector has conductor tubes (10-1-10n) arranged in a parallel manner, and containing pressurized gas mixture containing boron fluoride. Conductor wires (14-1-14-n) are arranged at the center of the corresponding tubes and are polarized with respect to the corresponding tubes. Each tube is divided into electrically insulated longitudinal sections i.e. longitudinal cells (12-1-12-m) having same cross-section. The sections of the tube are formed of a grid of electrically connected strips. A connection unit connects the sections of the tube to a polarization and detection circuit (18).

Description

Field of the invention

The present invention relates to the field of detectors for particles or ionizing radiation, and in particular neutron, γ or X-ray detectors.

Presentation of the prior art

The figure 1 schematically represents a conventional structure of a detector sensitive to ionizing radiation. This detector comprises a conductive tube 1 filled with a gaseous mixture, sealed at its ends by insulating plugs 3. A conductive wire 5 whose ends pass tightly through the plugs 3 is held taut at the center of the tube 1 by a spring 7 located inside the tube. A positive electrical potential applied to the wire 5 by a measuring circuit 9 makes it possible to define inside the tube an electric field which is conducive to the drift and the amplification of electrons generated during the passage of the ionizing radiation.

The gaseous mixture contained in the tube is intended to be ionized by the particles that are to be detected, either directly or after conversion into ionizing particles. For example, a mixture of CF ₄ and ³ He in which the ³ He acts as a converter can be used for the detection of neutrons, and the CF _{4 as} the gas for stopping both particles. ionizing (proton and triton) emitted after neutron capture by a ³ He atom.

To measure the position of the impact along the tube is commonly used a process said division of charge. The wire is then resistive. The measurement circuit includes a read electronics for load signal amplitude measurement at each end of the wire. This detection mode is always complex. Another mode of operation, called "counting", uses electronics based on the comparison, with respect to a reference voltage, of the signal measured at one end of the wire. This detection mode is generally imprecise in its current implementations.

The uniformity of response of the detector is affected by the inaccuracy of centering of the wire inside the tube, and this centering is difficult to achieve. The difficulty of centering the wire 8 limits the maximum amplification gain with which the detector can operate, which has a direct impact on the performance of the detector (resolution in energy and in position).

An ionizing radiation detector is conventionally formed of several elementary detectors whose tubes are juxtaposed. The operation of a detector depends on the quality and pressure of the gas mixture it contains. In addition, when several detectors must be used together with a minimum of space between the tubes, typically 10 mm, it is difficult to ensure the continuity of the electromagnetic shielding between the tube casing and the measuring circuit 9 without exceeding the outer diameter of the tube, which has the effect of creating dead spaces between the detectors, resulting in a loss of sensitivity of the whole.

summary

An object of an embodiment of the present invention is to provide a simple and inexpensive assembly to make detectors sensitive to ionizing radiation.

An object of an embodiment of the present invention is to provide an ionizing radiation detector particularly suitable for using thin layers of converter material producing charged particles.

Another object of an embodiment of the present invention is to provide a detector adapted to detect the presence or absence of ionizing radiation, with or without locating the point of conversion of said radiation.

To achieve these objects, an embodiment of the present invention provides an ionizing radiation detector comprising a plurality of parallel conductor tubes containing a gaseous mixture, a conductive wire being tensioned in the center of each tube and adapted to be polarized relative to the latter, in which each tube is divided into electrically insulated longitudinal sections, all the sections of tubes of the same transverse slice being formed of a grid of electrically connected slats and each set of sections of the same slice comprising a means connecting to a detection circuit.

According to one embodiment of the present invention, the grid of blades of each slice is linked to a frame.

According to an embodiment of the present invention, each blade is coated with a layer containing a radiation converting product generating ions in response to an ionizing radiation.

According to one embodiment of the present invention, the converter product contains boron-10.

According to one embodiment of the present invention, the gas mixture is a mixture of pressurized gas containing BF ₃ .

According to one embodiment of the present invention, the blades are made of aluminum.

According to an embodiment of the present invention, a first group of grid blades comprises slits which cooperate with slots of a second group of blades of the grid orthogonal to the first group.

According to an embodiment of the present invention, the detection circuit comprises a plurality of resistors coupled in series between first and second amplifiers, the nodes between the resistors being coupled to the connection means of the respective slots.

According to one embodiment of the present invention, each of the tubes comprises means for connecting the conductive wire of the tube to another detection circuit.

According to one embodiment of the present invention, the conducting wires of a group of tubes are coupled to each other.

According to an embodiment of the present invention, the other detection circuit comprises a plurality of resistors coupled in series between third and fourth amplifiers, the nodes between the resistors being coupled to the connection means of the tubes or groups of tubes. respectively.

According to one embodiment of the present invention, the detector is provided for detecting neutrons.

An embodiment of the present invention provides a device for detecting ionizing radiation comprising a plurality of detectors as above arranged side by side.

According to an embodiment of the present invention, each of the plurality of detectors is disposed in a corresponding one of a succession of chambers forming a cylinder portion.

Brief description of the drawings

• la figure 1, décrite précédemment, représente le schéma d'un élément d'un détecteur de rayonnement classique ;
• la figure 2 représente de façon schématique une vue de face d'un détecteur de rayonnement ionisant selon un mode de réalisation de la présente invention ;
• la figure 3 est un schéma destiné à préciser les axes de coordonnées utilisés dans la présente description ;
• la figure 4 représente un mode de réalisation d'un élément d'un détecteur selon un mode de réalisation de la présente invention ;
• la figure 5 représente plus en détail un détecteur de rayonnement selon un mode de réalisation de la présente invention ;
• la figure 6 représente schématiquement et plus en détail une vue de dessus d'une tranche supérieure du détecteur de rayonnement de la figure 5 selon un mode de réalisation de la présente invention ; et
• la figure 7 représente un dispositif de détection de rayonnement selon un mode de réalisation de la présente invention.

These and other objects, features, and advantages will be set forth in detail in the following description of particular embodiments in a non-limitative manner with reference to the accompanying figures in which:

• the figure 1 , described above, represents the schematic diagram of an element of a conventional radiation detector;
• the figure 2 schematically shows a front view of an ionizing radiation detector according to an embodiment of the present invention;
• the figure 3 is a diagram for specifying the coordinate axes used in the present description;
• the figure 4 represents an embodiment of an element of a detector according to an embodiment of the present invention;
• the figure 5 shows in more detail a radiation detector according to an embodiment of the present invention;
• the figure 6 shows schematically and in more detail a top view of an upper edge of the radiation detector of the figure 5 according to an embodiment of the present invention; and
• the figure 7 represents a radiation detection device according to an embodiment of the present invention.

detailed description

As represented by figure 2 an ionizing radiation detector comprises a parallel assembly of tubes 10-1, 10-2, 10-3, 10-n, each tube consisting of a set of stacked sections 12-1, 12-2, 12- 3 ..., 12-m insulated electrically by insulators or intervals 11. Each tube is traversed by a conductive element 14-1, 14-2 ... 14-n, this conductive element having for example the shape of a wire, or as will be seen below, a thin band. The wires are connected to a polarization and detection circuit 16, and all the tube elements corresponding to the same wafer (a gate) are connected to a polarization and detection circuit 18. Thus, the structure can be considered as constituted a set of cells 12-ijk, i being between 1 and n, j being between 1 and m, and k being between 1 and 1, being the number of tubes in the direction perpendicular to the plane of the figure. When ionizing radiation interacts with one of the cells, an ionization of a gas contained in the cell occurs and this ionization provides an electrical signal on the one hand on the central conductor, on the other hand on the wall of the tube. There is thus an indication in x, y and z of the location at which the ionization has occurred.

For the orientations of the x, y and z axes, reference is made to the figure 3 which very schematically represents an assembly of detectors. This detector assembly comprises vertically stacked slices in the y direction, the x axis designates the horizontal direction and the z axis designates the direction in which the ionizing radiation is likely to arrive.

Thus, with the circuits 16 and 18, it will be possible to precisely determine the cell at which a conversion of a radiation, for example of a neutron, has taken place.

The entire structure is disposed in an enclosure filled with a clean gas to be ionized. The gas is for example under pressure. On the other hand, the converter product reacting to the ionizing radiation (for example neutrons), may be, as in the prior art described above, a gas such as helium-3 or BF ₃ . It may also be a reactive material deposited in a thin layer, alone or in combination with another material, on the walls of each tube, or else the combination of helium-3 or BF ₃ and layers thin reactive material. This reactive material may be boron-10, capable of interacting with a neutron to provide lithium-7 and an alpha-4 particle. Other products that may be used are known in the art. It may for example be isotopes of gadolinium or lithium, these materials being deposited in thin layers on the walls of the tube and / or on the central strip. It is interesting to use such converter materials because helium 3 is extremely expensive and hardly available. Advantageously, the use of BF ₃ gas and a boron coating on the walls of each tube leads to a double effect for the detection of neutrons. On the other hand, it is very difficult to coat the inner walls of a tube with a layer containing such a material.

The structure proposed here makes it possible, as will be seen below, to realize very simply the coating of the walls.

The figure 4 is an exploded view of an exemplary embodiment of a horizontal slice (disposed between two adjacent horizontal planes), which comprises a section of each tube of a detector according to an embodiment of the present invention. The wafer is formed from a frame 21 whose opposite edges are provided with grooves 22 for receiving first plates 23 oriented in the z direction. The plates 23 are provided with slots 24 in which are intended to fit orthogonal plates 25 provided with slots 26 cooperating with the slots 24. The ends of the plates 25 are received in opposite slots 27 of the edges of the frame oriented according to the direction z. The contact between the plates 23, 25 and the frame 21 and between the plates is conductive. This gives the set of cells or sections of a horizontal slice (a grid) of the detector.

Note that the plates, or blades, 23 and 25 can easily be coated with a converter product before assembly, which greatly simplifies this coating or deposit. Thus, when ionizing radiation interacts at one of the cells, an electrical signal results on the center conductor and the wafer. In addition, figure 4 an insulating joint 28 for separating two slices of a detector according to embodiments of the invention.

It will be understood that this is only an exemplary embodiment of the present invention. It will be possible to use any honeycomb structure, comprising, for example, cells of hexagonal shape or the like. In addition, it should be noted that the 21 including slots 22 and 27 is optional. Alternatively, a stack of plates 23 and 25 could be fixed in a chamber as described in more detail below.

It has been indicated previously that each section and each wire passing through a set of vertically aligned sections are connected to a polarization and detection system so that the wires constitute anodes and the walls of the cathode wafer sections to attract the ionized gases produced by the conversion of ionizing bombardment. It has also been indicated that each wire and cell slice is connected by a separate conductor to recognize the cell at which the ionizing radiation has been converted. In fact, this discrimination of the cells is not always necessary. In some cases, one simply wants, for example in airport security devices, to know if a piece of luggage or a container contains radioactive products emitting neutrons. It will be enough then to connect together all the wires and all the sections to have a very simple device to use, with few lines of exit.

As an example of dimensions, each section may have a side of the order of 2 cm and a height of the order of 2 cm and the entire structure may have a height of about 3 m. Those skilled in the art will be able to adapt these dimensions to their needs.

An advantage of using a grid structure is that the section of each tube can have small dimensions. For example, rather than being 2 cm as described above, the lateral length of each section of each rectangular tube is for example only 4 to 10 mm. This allows the electrons resulting from a reaction to have a short flight time and thus a relatively high gas pressure can be used in the tube, for example greater than 2.10 ⁵ Pa. This is particularly advantageous when the gas is from BF ₃ . In addition, such a grid structure can advantageously be consisting of plates or blades 23, 25 of aluminum having for example a thickness of 0.5 mm or less.

The figure 5 shows in more detail a radiation detector and in particular an example of a detection circuit of the polarization and detection device 18. The detection circuit comprises a resistor network 30 comprising a succession of resistors 30-1 to 30-7 in series. . Each resistor has for example a value between 100 and 200 ohms. In this example, there are eight slices and seven resistors, and one connection from the grid of each slice is coupled to the connection of a neighboring grid by a corresponding resistor. Both ends of the resistor network are coupled to amplifiers 32 and 34, respectively, which provide respective output voltages VA and V _B. Based on these voltages, the slice in which radiation is detected can be identified. In particular, the position is indicated by calculating V _A / (V _A + V _B ).

An advantage of the use of the resistance network 30 of the figure 5 is that it reduces the number of output lines to two rather than to a number equal to the number of slices.

The figure 6 is a top view of the upper edge of the radiation detector, and shows the polarization and detection circuit 16 according to an example in which groups of conductive wires 14 of each tube are coupled to each other. In the particular example of the figure 6 , the tube block son, 4 in depth and 2 in width, are coupled to each other, although other shapes and dimensions of blocks can be chosen. This further reduces the number of output lines for the radiation detector.

Additionally or alternatively, one or more resistive networks may be used to reduce the number of connections to the wires. The figure 6 illustrates the example of a resistor network 36 having three series resistors 36-1 to 36-3 and amplifiers 38 and 40 at each end. providing voltages V _C and V _D. The corresponding nodes of the resistor network 36 are coupled to four of the interconnected wire groups. The bias circuit for applying a bias voltage to these wires is also shown and includes, for example, a high voltage supply HV coupled by a resistor at the end of the resistor network, on the amplifier side 40. A capacitor 41 is coupled between the resistor network and the amplifier 40, while the input of the amplifier 40 is also coupled by a resistance to ground. Similarly, the figure 6 is an example of a resistor network 42 having three resistors connected in series 42-1 to 42-3 and amplifiers 44 and 46 at each end providing voltages V _E and V _F. Corresponding nodes of the resistor network 42 are coupled to four of the interconnected wire groups. The bias circuit for applying a bias voltage to these wires is also shown and includes, for example, a high voltage power supply coupled by a resistor at the end of the resistor network, on the amplifier side 46. A capacitor 47 is coupled between the resistor network and the amplifier 46 while the input of the amplifier 47 is also coupled by a resistance to ground.

The figure 7 is a top view illustrating a radiation detection device 50 having a curved wall 51 consisting of a succession of chambers 52 each of which contains the pressurized gas detectors. The wall 51 is for example made of metal sheets having a thickness of the order of 3 mm. Each chamber 52 comprises a radiation detector as described above, an example 56 of which is shown.

In one embodiment, the slices of the same level of neighboring detectors are coupled to each other, for example in pairs, to provide combined outputs, a level of these outputs being designated by references 58-1 to 58-6 in figure 7 . This further reduces the number of output lines.

Such a device can be used in a scientific application to detect the direction of radiation from a source 54 in the center of a partial cylinder consisting of the curved wall 51.

Particular embodiments of the present invention have been described. Various variations and modifications will be apparent to those skilled in the art. In particular, the superimposed slices can define various shapes of cells and be constituted in various ways.

Claims (14)

An ionizing radiation detector comprising a plurality of parallel-arranged conductive tubes containing a gaseous mixture, a conducting wire (14-1, ... 14-n) being stretched in the center of each tube and adapted to be polarized with respect thereto wherein each tube is divided into electrically insulated longitudinal sections (12-ijk), all tube sections of a same transverse slice being formed of a grid of electrically connected slats (23, 25) and each set of cross-sections. a same slot comprising means for connection to a detection circuit (18). The detector of claim 1, wherein the grid of blades of each wafer is bonded to a frame (21). The detector of claim 1 or 2, wherein each plate is coated with a layer containing an ion-generating radiation-converting product in response to an ionizing radiation. Detector according to claim 3, wherein the converter product contains boron-10. Detector according to any one of claims 1 to 4, wherein the gas mixture is a mixture of pressurized gas containing BF ₃ . Detector according to any one of claims 1 to 5, wherein the blades are aluminum. Detector according to any one of claims 1 to 6, wherein a first group of blades (23) of the grid comprises slots (24) which cooperate with slots (27) of a second group of blades of the grid orthogonal to the first group. A detector according to any one of claims 1 to 7, wherein the detection circuit (18) comprises a plurality of resistors (30-1 to 30-7) coupled in series between first and second amplifiers (32, 34), the nodes between the resistors being coupled to the connection means of the respective slots. A sensor as claimed in any one of claims 1 to 8, wherein each of the tubes comprises means for connecting the conductive wire of the tube to another detection circuit (16). The detector of claim 9, wherein the conductive wires of a group of tubes are coupled to one another. A detector according to claim 9 or 10, wherein the further detection circuit (16) comprises a plurality of resistors (36-1 to 36-3, 42-1 to 42-3) coupled in series between third and fourth amplifiers (44, 46), the nodes between the resistors being coupled to the connecting means of the respective tubes or groups of tubes. Detector according to any one of claims 1 to 11 for detecting neutrons. A device for detecting ionizing radiation comprising a plurality of detectors according to any one of claims 1 to 12 arranged side by side. Apparatus according to claim 13, wherein each of the plurality of detectors is disposed in a corresponding one of a succession of chambers forming a cylinder portion.

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