Classifications

• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01T—MEASUREMENT OF NUCLEAR OR X-RADIATION
  • G01T1/00—Measuring X-radiation, gamma radiation, corpuscular radiation, or cosmic radiation
  • G01T1/16—Measuring radiation intensity
  • G01T1/20—Measuring radiation intensity with scintillation detectors
  • G01T1/2006—Measuring radiation intensity with scintillation detectors using a combination of a scintillator and photodetector which measures the means radiation intensity
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
  • Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
  • Y10T156/00—Adhesive bonding and miscellaneous chemical manufacture
  • Y10T156/10—Methods of surface bonding and/or assembly therefor

Definitions

• the present invention relates to a solid-state X-ray detector comprising a photosensitive sensor associated with a radiation converter.
• the fields of application of this type of detector include radiology: radiography, fluoroscopy, mammography, but also non-destructive testing.
• Such radiation detectors are for example described in French patent FR 2 803 081 in which a sensor formed of amorphous silicon photodiodes is associated with a radiation converter.
• the photosensitive sensor is generally made from photosensitive elements in the solid state arranged in a matrix.
• the photosensitive elements are made from semiconductor materials, most commonly mono-crystalline silicon for CCD or CMOS type sensors, polycrystalline silicon or amorphous silicon.
• a photosensitive element comprises at least one photodiode, a phototransistor or a photo resistance. These elements are deposited on a substrate, usually a glass slab. These elements are generally not directly sensitive to very short wavelength radiation, as are X or gamma rays. This is why the photosensitive sensor is associated with a radiation converter which comprises a layer of a scintillating substance. This substance has the property, when excited by such radiation, to emit radiation of longer wavelength, for example visible or near-visible light, to which the sensor is sensitive. The light emitted by the radiation converter illuminates the photosensitive elements of the sensor which perform a photoelectric conversion and deliver electrical signals exploitable by appropriate circuits.
• the radiation converter will be called a scintillator in the following description.
• Certain scintillating substances of the alkaline halide or rare earth oxysulfide family are frequently used for their good performance.
• sodium or thallium doped cesium iodide depending on whether emission is desired at about 400 nanometers or about 550 nanometers respectively, is known for its high X-ray absorption and for its excellent fluorescence efficiency.
• It is in the form of thin needles that are grown on a support. These needles are substantially perpendicular to this support and they partially confine the light emitted towards the sensor. Their fineness conditions the resolution of the detector.
• Lanthanum and gadolinium oxysulfides are also widely used for the same reasons.
• cesium iodide its decomposition gives cesium hydroxide Cs + OH "and free iodine I 2 which can then be combined with iodide ions to give the complex I 3".
• the ambient air as well as the glue used for assembling the detector always contain it.
• the presence of moisture in the adhesive is due either to the ambient air or as a by-product of the polymerization if it results from the condensation of two chemical species, which is common.
• One of the important aspects when making these detectors will be to minimize the amount of moisture present initially inside the detector, and in contact with the scintillator, and to avoid the diffusion of this moisture inside. of the sensor during its operation.
• the radiation detectors comprise an input window traversed by the X-radiation upstream of the scintillator. Moreover, the scintillating substance is generally deposited on a metal support. The support and the scintillating substance then form the scintillator. It is possible, but not required, to use the media as an input window.
• the inlet window When the scintillating substance is thus deposited on the inlet window to form the scintillator which is then attached by gluing on the sensor, the inlet window must withstand without damage the thermal stresses of the deposition and treatment of the scintillator and preferably have a coefficient of thermal expansion of the same order of magnitude as that of the scintillator and that of the sensor, more particularly that of its substrate. It can also be provided that the window has a low modulus of elasticity, which makes it possible to eliminate differential stresses between, on the one hand, the window and the scintillator and, on the other hand, the window and the sensor, or more particularly the substrate of the sensor. This eliminates the risk of cracking of the scintillator and breakage of the sensor substrate.
• the surface state of the inlet window must also allow, in particular for cesium iodide, a growth of the finest possible needles, in the most uniform manner possible. The fineness of the needles is a quality factor for the resolution of the detector.
• the supports are aluminum.
• the transparency of aluminum to the radiation to be detected is excellent, its optical properties are good. It is possible to obtain, after treatment of aluminum, a satisfactory surface state for depositing the scintillator.
• its coefficient of expansion is very different from that of the sensor.
• This seal is necessarily flexible to accommodate the differences in expansion between the scintillator support and the sensor during thermal cycling, and minimize the constraints and risks of breakage.
• soft materials are generally permeable to moisture. This results in insufficient protection of the scintillator against this moisture, which reduces the life of the detector.
• the input window is an additional element placed on the scintillator, without being attached to the scintillator, and a seal sealing moisture assembles the input window and the sensor.
• the input window is reported on the assembly formed by the sensor and the scintillator. Sealing is done between the input window and the sensor.
• the stresses to which the support of the scintillator is subjected are distributed between the support and the new input window itself.
• the scintillator support remains subject to the same reflectivity and surface state constraints for scintillating substance deposition as in the previous structure.
• it is no longer subject to the sealing and support constraints of the sealing joint. These constraints are reported on the new additional input window.
• This embodiment makes it possible to define an input window material which is compatible with the material of which the sensor is made, especially in terms of the compatibility of their respective expansion coefficients, which should make it possible to use a sealing gasket more hard, and therefore more impervious to moisture.
• This embodiment can be implemented in two configuration configurations of the scintillator and the sensor.
• the scintillator substance is deposited on a support that the radiation to be detected must pass before reaching the sensor.
• the assembly formed of the scintillating substance and its support is then glued to the sensor.
• An optical glue is used for this purpose, the object of which is to ensure good mechanical contact between the scintillator and the sensor, but also a good transfer of light from the scintillator to the photosensitive sensor.
• the senor serves as a support for the scintillating substance which is then in direct and intimate contact with the sensor.
• the two configurations each have advantages and disadvantages which are described, for example, in French Patent FR 2,831,671.
• the invention aims to overcome all or part of the problems mentioned above by proposing the implementation of a reported entry window without using a thick seal.
• the subject of the invention is a detector of a first radiation in the solid state comprising a photosensitive sensor, a scintillator transforming the first radiation into a second radiation to which the sensor is sensitive, and a rigid input window. traversed by the first radiation upstream of the scintillator, the scintillator being disposed between the sensor and the input window, the sensor comprising a substrate and photosensitive elements arranged on the substrate, characterized in that the input window is set shaped to match the shape of the scintillator and that the inlet window is moisture-tightly attached to the sensor substrate.
• the subject of the invention is also a method for producing a radiation detector according to the invention, characterized in that it consists in following the following operations: • sticking the scintillator on the sensor; • place the entrance window on the assembly formed by the sensor and the scintillator;
• FIG. 1 represents an exemplary embodiment of a radiation detector according to the invention.
• the scales are not respected.
• the radiation detector 10 shown in FIG. 1 makes it possible to detect X-radiation, the direction of which is indicated by the arrows 11.
• the detector 10 comprises a sensor 12, a scintillator 13 transforming the X-ray radiation into a radiation to which the sensor 12 is sensitive, and a rigid input window 14 traversed by the X-ray upstream of the scintillator 13.
• the invention is described in relation to an X-ray detector. It should be understood that the invention may be implemented for other wavelengths of radiation requiring a scintillator.
• the scintillator 13 is disposed between the sensor 12 and the input window 14.
• the sensor 12 comprises a substrate 15 and photosensitive elements 16 disposed on the substrate 15.
• Each photosensitive element 16 is mounted between a line conductor and a conductor column so that it can be addressed. Line and column conductors are not shown in the figure to avoid overloading it.
• the photosensitive elements 16 and the conductors are generally covered with a passivation layer intended to protect them from moisture.
• the scintillator 13 comprises a support 17 and a scintillator substance 18 deposited on the support 17.
• the scintillator substance 18 belongs, for example, to the family of alkaline halides, such as cesium iodide, which is particularly sensitive to wet oxidation, but it could also belong to the rare earth oxysulfide family, some of whose members are also unstable, such as lanthanum oxysulfide.
• the support 17 is traversed by the X-ray upstream of the scintillating substance 18 and the scintillator 13 is fixed to the sensor 12 on the side of the scintillating substance 18.
• the input window 14 is placed on the scintillator 13 without being fixed thereto.
• the inlet window 14 is rigid and is moisture-tightly attached to the substrate 15 of the sensor 13.
• a waterproof seal 19 fixes the inlet window 14 to the substrate 15.
• the choice of a material for the seal 19 is made according to the materials of the inlet window 14 and the substrate 15.
• the seal sealing 19 may be made based on mineral material. This type of seal has a very good impermeability but it requires a high operating temperature, of the order of 400 ° C.
• the seal 19 may be made of organic material. These materials have a poorer seal than mineral materials. But on the other hand their operating temperature is lower, lower than 200 ° C. Among organic materials the best seal is provided by epoxy adhesives
• the inlet window 14, for its part, may consist of any material whose thermal expansion coefficient is close to that of the material of which the substrate 15 is formed.
• the expansion coefficient of the inlet window is less than to that of aluminum.
• the proximity of the expansion coefficients of the two materials to be assembled, namely that of the inlet window 14 and that of the substrate 15 makes it possible to use a hard seal 19.
• Several materials may be suitable for making the entrance window 14. The materials containing few heavy elements are generally suitable because of their good X-ray transparency.
• the input window 14 may comprise glass.
• the glass is mono component and therefore easy to implement.
• the substrate 15 may also include glass. More generally, the inlet window 14 and the substrate 15 may be made of the same material or at least comprise the same majority material, which limits the difference in coefficient of thermal expansion between the input window 14 and the substrate 15.
• Carbon fibers can also be used to make the entrance window 14. The carbon fibers have a better transparency X-ray than glass and are also less fragile. In contrast, carbon fibers, often held with epoxy resin, are more difficult to seal because of their rough surface condition.
• the inlet window 14 may comprise a ceramic material whose X-ray transparency is close to that of the glass.
• the input window 14 may also include an organic material such as polyester.
• This material has better X-ray transparency than glass. Its fragility is also less than that of glass. It is a homogeneous material having a smooth surface state when it is obtained by rolling or molding. Nevertheless, the sealing of polyester is more difficult to achieve than that of glass.
• the input window 14 is shaped so as to cover the scintillator 13 and come as close as possible to the substrate 15.
• the inlet window 14 is shaped so as to match the shape of the scintillator 13 and thus reduce the thickness of the seal 19 to minimize the passage of moisture in the seal 19.
• the scintillator 13 may be schematically represented as a parallelepiped of which a first end face 20 is disposed against the photosensitive elements 16. A second end face 21 opposite the face 20 is traversed by the X-ray.
• the scintillator 13 also comprises side faces substantially perpendicular to the two end faces 20 and 21. In Figure 1, two side faces 22 and 23 appear.
• the input window 14 is shaped so as to cover the front face 21 and the side faces.
• the entrance window 14 may be made of a glass sheet which can easily be deformed to conform to the shape of the scintillator.
• the glass sheet may be hot formed. Hot forming involves softening the glass temperature and let it sag on a mold.
• the glass sheet can be hollowed out by mechanical sanding.
• Mechanical sanding involves projecting a jet of particles of a hard material, usually alumina or other material, onto the glass sheets. by preserving certain zones by masking, in particular the zones to be fixed on the substrate 15.
• the scintillator 13 is fixed on the sensor 12 by means of a glue 25 transparent to the radiation to which the sensor 12 is sensitive.
• the input window 14 is fixed on the substrate 15 of the sensor 12 also by means of the adhesive 25.
• the adhesive 25 extends over the entire surface of the scintillator 13 opposite the sensor 12. In other words, the same adhesive is used. in order to ensure an optical glue function between the scintillator 13 and the sensor 12 as well as a sealing joint function between the inlet window 14 and the substrate 15.
• the sealing joint 19 and the glue 25 form only one element.
• the glue 25 is chosen for its transparency and its absence of defects, which contributes directly to the quality of the final image delivered by the detector 10.
• the glue 25 must also ensure the mechanical integrity of the optical interface between the elements. photosensitive 1 6 and the scintillating substance 18.
• the adhesive 25 must ensure a good mechanical connection between the substrate 15 and the inlet window 14. This connection must also be moisture-tight, either by the intrinsic properties of the adhesive material 25, or by its small thickness due to the important degree of confinement of the passage of the moisture, brought by the input window 14 shaped closer to the scintillator 13.
• the adhesive 25 may be either a liquid adhesive, deposited on the substrate
• the adhesive 25 may require annealing or any processing before optical coupling of the scintillating substance 18 and removal of the input window 14.
• the adhesive 25 may also be deposited on the substrate 15 and implemented in the form of a film from a roll, before optical coupling of the scintillating substance 18 and removal of the input window 14.
• the glue 25 may comprise an element belonging to one of the adhesive families: silicone, acrylic or epoxy.
• a method of producing a detector according to the invention consists in following the following operations:
• the method comprises:

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• Spectroscopy & Molecular Physics (AREA)
• Measurement Of Radiation (AREA)

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• 2008
  • 2008-11-14 FR FR0806377A patent/FR2938705B1/fr active Active
• 2009
  • 2009-11-12 CA CA2743993A patent/CA2743993A1/en not_active Abandoned
  • 2009-11-12 CN CN2009801503908A patent/CN102246059A/zh active Pending
  • 2009-11-12 WO PCT/EP2009/065066 patent/WO2010055101A1/fr active Application Filing
  • 2009-11-12 JP JP2011536014A patent/JP2012508873A/ja active Pending
  • 2009-11-12 EP EP09759921A patent/EP2347283A1/fr not_active Withdrawn
  • 2009-11-12 US US13/129,310 patent/US20110260066A1/en not_active Abandoned

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