Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J47/00—Tubes for determining the presence, intensity, density or energy of radiation or particles
  • H01J47/02—Ionisation chambers
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J47/00—Tubes for determining the presence, intensity, density or energy of radiation or particles
  • H01J47/12—Neutron detector tubes, e.g. BF3 tubes
  • H01J47/1205—Neutron detector tubes, e.g. BF3 tubes using nuclear reactions of the type (n, alpha) in solid materials, e.g. Boron-10 (n,alpha) Lithium-7, Lithium-6 (n, alpha)Hydrogen-3
  • H01J47/1211—Ionisation chambers

Definitions

• the present invention relates in particular to a device for detecting and locating particles in a stream of neutral particles emitted by a source, comprising:
• the object of the present invention is, on the contrary, to allow the production of images of higher resolution and to allow, on a secondary basis, the obtaining of a high contrast, even in a priori unfavorable conditions of irradiation of the object to be examined, and more particularly in the event of poor conversion rates and / or in the presence of fluxes of incident particles of low intensity.
• the device of the invention is essentially characterized in that said conversion elements capable of also ensuring the collection of charges consist of cells distributed in a flat two-dimensional matrix arranged beyond the anode wires with respect to the source .
• the images obtained by the device of the invention have a higher resolution than that of the images obtained by the prior device described in patent EP 0 000 271, the two-dimensional matrix of which is formed by two parallel planes of elements. linear also parallel to each other, the elements of different planes being however crossed.
• the converter comprises an insulating plate one face of which carries said cells, this plate comprising, for each cell, a passage putting this cell in electrical contact with a conductor terminating on the other face this plate.
• the anode wires are placed in at least one plane substantially parallel to that of the converter, and are substantially parallel to each other.
• the cells comprise a conversion material chosen from the group comprising gadolinium, boron, and lithium, in the case where the particles neutrals used are neutrons and the cells comprise a conversion material chosen from the group comprising iron, and silver in the case where the neutral particles used are X-rays, in particular soft X-rays.
• the gas contains an extinguishing substance present in a proportion of at least 25 percent and that the ratio of the distance "S" between two neighboring anode wires, at the distance "G” between these wires and the converter, ie at least equal to 1.
• At least one of the charge collection elements is connected to a reference electrical potential by means of a capacity capable of accumulating the charges collected by this element.
• the device also comprises a source of voltage suitable for creating an electrical voltage between the cathode and the anode wires at least equal to 2000 volts, and the anode wires have a minimum diameter greater than 20 microns.
• the invention also relates to a method for detecting and locating particles in a stream of neutral particles emitted by a source, comprising the operations consisting in:
• the charge amplification operation preferably comprises the application of an electric field of sufficient value to allow the appearance of electronic avalanches of self-regulated size.
• the method can advantageously comprise another operation, consisting in accumulating for a certain time the collected electrical charges.
• the conversion of neutral particles into electrical charges is ensured with a conversion rate such that the number of particles detected is less than 10 5 particles per second and per square centimeter of surface of the converter.
• FIG. 1 is a schematic view showing, in perspective, the implementation of a device according to the invention.
• FIG. 2 is an exploded schematic view of a device according to the invention.
• FIG. 3 is a sectional view of a detection device usable in the system of Figure 1, taken along the plane III-III of Figure 2;
• FIG. 1 shows in 1 a source of neutral particles, for example a source of soft X-rays, but more typically a source of thermal neutrons in the main applications of the invention. At least part of the flow of particles emitted by this source passes through an object to be examined 2 and reaches the device 3 to which the present invention relates more particularly.
• a source of neutral particles for example a source of soft X-rays, but more typically a source of thermal neutrons in the main applications of the invention.
• this device firstly comprises an enclosure, intended to contain u gas and formed of a base 4a and a cover 4b made integral with each other in a sealed manner vis-à-vis the atmosphere, the cover 4b being, however, permeable neutral particles emitted by the source 1, for example by neutrons.
• the gas contained in the enclosure is a gaseous mixture allowing the appearance of a "streamer" operating mode, in other words the appearance of electron avalanches whose size is self-regulated by spontaneous suffocation.
• this gas comprises an effective quenching substance, consisting of carbonaceous and polyatomic molecules comprising many relaxation modes, such as isobutane or neopentane, in proportion at least percent.
• this gas can be * a mixture of 50 percent carbon dioxide and 50 percent isobutane, subjected to a pressure of the order of one to five bars.
• the converter 5 and the planar grid are connected to a reference electrical potential, and are for example brought to potentials close to the potential of the earth prevailing outside the enclosure, both playing the role. cathodes.
• the wires of the planar network 6 are on the other hand connected to an external source of electrical potential which delivers a positive potential + V with respect to the average potentials of the converter 5 and of the grid 7, for example of the order of 2000 to 7000 volts.
• the converter 5 comprises an insulating plate 8, better visible in FIG. 3, and a two-dimensional matrix of cells, such as 9a, 9b, 9c, arranged on one face of the plate ⁇ .
• Each of the cells such as 9a, is intended to supply a signal representing a point of a two-dimensional image of the object 2.
• Each of the cells therefore operates independently of its neighbors, and the image obtained consists of a matrix of points each of which corresponds to one of these cells.
• the light intensity associated with a point in the image depends on the quantity of particles received by the corresponding cell, this quantity being itself dependent on the thickness and the nature of the material from which the object is made. solid angle defined by the source on the one hand and by the cell in question on the other. The operation of the device is illustrated in Figure 3.
• the wavy path Tl represents that of a neutral particle, a neutron for example, which, after having been emitted by the source 1 and passed through the object 2, the cover 4b of the detector, the grid 7 and the plane of wires 6, reaches a cell 9c of the converter 5.
• cell 9c made of an adequate material, emits in a statistically observable and reproducible way a fast electron whose trajectory is represented in T2.
• this fast electron causes the ionization of the gas on its course, and the electrons thus produced drift towards the nearest wire, for example 6c of the network 6 under the effect of the electric field resulting from the difference between the potentials of the converter 5 and the wire pla 6.
• This movement is identified by the arrows such as T3 in FIG. 3.
• this amplification corresponds to a mode of operation in which avalanches of electrons appear whose size is self-regulated. This phenomenon, which results in a considerable increase in the electric charge, represented by the final number of electrons produced by each fast electron, continues until spontaneous suffocation of the avalanches.
• the corresponding positive ions representing a number of charges equal to that of the charges of all the electrons created, deviate from the wire 6c from which they are repelled in reason of their charge, and drift towards the nearest cathodes, constituted by the grid 7 on the one hand and by the converter 5 on the other hand.
• the converter 5 has a layered structure supported by an insulating plate 8, the latter being for example formed by a printed circuit board made of epoxy resin, with a thickness of 3.2 millimeters.
• This plate is covered with a layer of copper 10, a few microns thick.
• a layer of conductive adhesive 11 On the copper layer 10 is deposited a layer of conductive adhesive 11, with which the assembly can be covered with a layer of a conversion material 12, for example a sheet of gadolinium, with a thickness of tenth of a micron, previously golden to prevent oxidation.
• a conversion material 12 for example a sheet of gadolinium, with a thickness of tenth of a micron, previously golden to prevent oxidation.
• This stack of layers 10, 11, and 12, deposited on at least the largest part of the surface of the plate 8, is then cut, by saw cutter lines such as 13 attacking the upper face of this plate, into elements. electrically isolated from each other, which constitute the cells 9a, 9b, 9c, etc.
• the insulating plate 8 comprises, for each cell such as 9c, a passage such as 14c putting this cell in electrical contact with a conductor such as 15 terminating on the other face of the plate 8.
• each wire such as 6c is stretched exactly over a row of cells such as 9c, these advantageously having a rectangular or square shape.
• the cathode grid 7 can be made of stainless steel wires with a diameter of 50 microns each, intersecting at right angles, at a p of 500 microns, the role of this grid being to allow a symmetrization of the electric field on the wires such as 6c.
• the plane of wires 6 is produced in the form of a weaving on an insulating frame of golden tungsten wires with a minimum diameter of at least 20 microns, and preferably from 50 to 100 microns each, arranged parallel to each other. others following a pitch S of 2.54 millimeters for example. All of the wires are connected to a source of electrical potential outside the enclosure 3, delivering a voltage of 5000 vol for example.
• the distance G between the plane of wires 6 and the converter 5 on the one hand and the distance between the plane of wires 6 and the grid 7 on the other hand are preferably equal and on the order of 3 to 5 millimeters.
• the cells such as 9c for example have the shape of squares of 2 millimeters on a side, produced at the same pace as the wires, 2.54 millimeters in this case.
• the conversion material 12 used in cells such as 9c advantageously consists of gadolinium in the case where the neutral particles emitted by the source 1 are thermal neutrons, and of iron or silver in the case where these particles are rays X, in particular soft X.
• the conductors such as 15c are on the one hand connected to the earth potential via respective capacitors such as 16c, on the other hand connected, each at least for a given time interval, to an electronic device 17, of the type known per se, the function of which is to convert the signal present on each of these conductors to a point in a video image and / or to information capable of being stored in an optical, electronic or other memory.
• the wires such as 6c play the role of means for amplification and collection of negative charges, while the converter and its cells play both the role of conversion means, of cathode, and of means of collection of positive charges.
• the useful signal for each point of the image of the object, is constituted by the electrical signal present on the conductors such as 15c, the cells such as 9c constitute more precisely the useful elements of the means of charge collection.
• the invention develops all its advantages when the number of neutral particles detected is less than 10 5 particles per second and per square centimeter of surface area of the converter, and it is of particular interest when the particles detected are thermal neutrons.
• the charge amplification operation includes the application of an electric field of sufficient value to allow the appearance of electron avalanches of self-regulated size (streamer mode), and it is advantageous , for this purpose, that the ratio of the distance S (FIG. 3) between two neighboring anode wires 6b, 6c, to the distance G between these wires and the cathode 12, is at least equal to l.
• this mode allows the creation, for each fast electro emitted by the converter, of an extremely high number of charges, typically of the order of 10 7 to 10 9 , so that it is possible, even from a small number of particles received by the converter, or from a small number of particles converted by it, to obtain an image of an irradiated object such as 2 ( Figure 1).
• This property is also best exploited according to the embodiment of the invention which comprises an accumulation, for a certain time, of the electrical charges * collected, in a capacity such as 16c.
• this operating mode makes it possible to overcome an intrinsic defect which the solid converters exhibit under certain conditions of use, in particular for the detection of thermal neutrons.
• the fast electrons from the solid converter have a very high energy dispersion.
• the number of first ionization charges directly created per unit of distance by a fast electron passing through the gas is a rapidly variable function of the energy of this fast electron, so that the charge collecting elements, the cells such as 9c in this case, risk providing respective signals representative no longer of the number of neutral particles that these elements have received, but of the energy of the fast electrons to which these particles have led by conversion.
• the "streamer" mode which has the property of amplifying charges in a highly non-linear manner, makes it possible to re-establish this defect by giving rise, for each fast electron, to a number of charges collected which is substantially independent of the number of charges of first ionization directly created by fast electrons.
• the use of this operating mode thus makes it possible to reduce the fluctuations of the useful signal to a level close to the fish fluctuations of the source.

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• Physics & Mathematics (AREA)
• Chemical & Material Sciences (AREA)
• Engineering & Computer Science (AREA)
• Chemical Kinetics & Catalysis (AREA)
• High Energy & Nuclear Physics (AREA)
• Materials Engineering (AREA)
• Measurement Of Radiation (AREA)
• Analysing Materials By The Use Of Radiation (AREA)

Applications Claiming Priority (5)

Publications (2)

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• 1989
  • 1989-10-24 WO PCT/FR1989/000553 patent/WO1990004851A1/fr active IP Right Grant
  • 1989-10-24 EP EP89912456A patent/EP0441853B1/de not_active Expired - Lifetime
  • 1989-10-24 AT AT89912456T patent/ATE112891T1/de active
  • 1989-10-24 DE DE68918871T patent/DE68918871T2/de not_active Expired - Fee Related
  • 1989-10-24 US US07/678,279 patent/US5087821A/en not_active Expired - Fee Related

Non-Patent Citations (1)

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