DE102008013781A1 - Scintillator-composite manufacturing method for computed tomography, involves forming light-conducting matrix, and connecting matrix with light generating scintillator material, where matrix has light conductor-fiber composite - Google Patents

Abstract

The method involves forming a light-conducting matrix, and connecting the matrix with a light generating powder scintillator material before a hardening of a scintillator-composite, where the matrix has a light conductor-fiber composite. The matrix is woven and is a fibrous, light-conducting plastic and/or glass matrix with a refractive index equal to that of the scintillator material. The scintillator-composite is cast into a mold, and the mold of the composite is fixed to a photosensor, where signals of the photosensor are supplied to an electronic device.

Description

The The present invention relates to a process for producing a Scintillator composites according to the preamble of the main claim. The present invention also relates to this scintillator composite prepared in this way and uses.

For X-ray detection in computed tomography, so-called scintillator arrays are used. These consist of single pixels of a scintillator material, such as Gd ₂ O ₂ S: Pr, Ce or CdWO ₄ . The optical separation of the light information generated by X-radiation is caused by so-called reflector materials, such as TiO 2, in an epoxy matrix. The following conventional disadvantages result:
On the one hand, the production of a scintillator array is complex and therefore expensive. The scintillator material is produced in ceramic or crystalline form and then further structured and filled by means of sawing processes.

Of Further is the spatial resolution the scintillator arrays limited. If the pixels run increasingly smaller, so takes the radiation insensitive surface the reflector more and more space. This results in a typical resolution limit from about 0.5 to one millimeter pixel margin.

The individual process steps for the preparation of the scintillator material and pixelation become stable optimized. However, there are limits to the fundamental Process.

It are different approaches, Scintillator material by insertion to create pourable in a plastic matrix, to make the scintillator material cheaper to form arrays. Unfortunately thereby deteriorate the optical properties of the scintillator material compared to the conventional ones monolithic sawing arrays. The reason for this is the raised one Scattering and thus the increased light path length in the casting material, which also has a negative effect on the afterglow and the drift.

It Object of the present invention is a scintillator composite, in particular for a computer tomograph, simple, inexpensive and to provide such that the spatial resolution is effective is improved.

The Task is by a method according to the main claim, a use according to the secondary claim and a scintillator composite according to the independent claim.

It novel photoconductive scintillator composites are proposed.

composite (lat. "Compositum", compound) generally refers to composite materials.

With Matrix is commonly referred to as the material in composites, in which other components are embedded.

One Scintillator material is a material that is charged during passage Particles and γ quanta is excited and the excitation energy in the form of light (usually in the UV or visible range) again. About the measurement of the amount of light (eg with a photomultiplier or a photodiode) can open the deposited energy will be closed. Indirectly, too free neutrons over Scattering processes or nuclear reactions in the material and the resulting be detected charged particles.

The proposed solutions cause the following advantages. It can powdery Scintillator materials are used. The occurring Scattering effects of the generated Lich tes lead to an increased spatial resolution, but also to a reduced light output. By built-in, according to the invention, evenly distributed light channels With an adapted refractive index, light output and spatial resolution can be matched to one another become. The resolution of a construction is determined by the area sizes and by the area fraction determined by matrix to scintillator material and can be applied to this Very easy, depending on the requirements, to be optimally adjusted. The proportion of area, which is inactive when impinging radiation is reduced. Positioning on a photosensor can be independent of whose pixelation is executed become. There are no further shaping components for the scintillator composite more necessary. The scintillator composite is cast in optimum plate size and fixed on the photosensor. In this way, none occur additional inactive areas. The scintillator material losses are minimized. Other advantages This arrangement is the reduced incidence of unabsorbed X-rays on photosensor and electronics as well as the mechanical stabilization through the fiber composite. The production and structuring of so-called UFC ceramics eliminated. With that you can the current manufacturing process greatly simplified and cheaper become.

Further advantageous embodiments are claimed in conjunction with the subclaims.

According to one advantageous embodiment, the matrix has fibrous light-conducting Plastic and / or glass fibers with a refractive index, similar or equal to the refractive index of the scintillator material. The deviation The refractive indices may be, for example, up to 10% of the refractive index of the scintillator material. As a plastic one calls one Solid, its basic component synthetically or semi-synthetically produced polymers with organic groups.

According to one Another advantageous embodiment, the matrix is woven and has thereby a preferred direction of the fiber flow.

According to one further advantageous embodiment, the fibers undergo the Matrix a cast form of the scintillator composite, in particular a plate, in full length and / or oblique in the air the form.

According to one Further advantageous embodiment, the bringing together the matrix and the scintillator material before curing the Scintillator composite.

According to one Another advantageous embodiment is the photoconductive matrix alternatively formed. It is dispensed with a woven matrix. There are fiber sections whose length, in particular about 10 to 40%, greater than a length a cast form of a scintillator composite, in particular one Plate, are, used.

According to one Further advantageous embodiment, the fibers extend due to their given length aslant through the molded mold, obliquely along the length of cast form.

According to one Another advantageous embodiment is a preferred direction of Fiber course by means of a flow while of bringing together.

According to one Another advantageous embodiment is the light-conducting matrix as follows educated. It will be powdery Proportions of the cured Polymer matrix or particulate base material / glass matrix added to the scintillator material. This intrinsically becomes a light guide through a coherent Chain formed of these particles. This can be the light output be further improved, since in principle every particle of a sufficiently sized light guide is surrounded and on this way, a network is generated, which in each case in a light guide particle ends at a photosensor.

According to one Another advantageous embodiment may be powdered scintillator material used become.

The The present invention will be described with reference to exemplary embodiments closer with the figures described. Show it:

1 an embodiment of a method according to the invention.

2 an embodiment of a use of a scintillator composite.

1 shows an embodiment of a method according to the invention. In a step S1, a light-conducting fiber composite having, light-transmitting matrix is formed. In a step S2, this matrix is brought together with a light-generating scintillator material.

2 shows an embodiment of a use of a scintillator composite according to the invention 1 , Here is the scintillator composite 1 poured into an optimal plate size and on a photosensor 2 been fixed. A cast mold 1a is the plate. This has a length 1b and a height 1c on. The signals of the photosensor 2 be an electronics device 3 fed. The signals of the electronic device 3 become a display device 4 fed. For example, the above-mentioned elements may be part of a computer tomograph.

Claims (12)

Method for producing a scintillator composite ( 1 ), comprising the steps of forming a photoconductive matrix; Contacting the matrix with a light-generating scintillator material; characterized in that the matrix has a fiber optic fiber composite. Method according to claim 1, characterized in that that the matrix is a fibrous, photoconductive plastic and / or glass matrix with a to that of Scintillator material similar or the same refractive index. Method according to claim 1 or 2, characterized that the matrix is woven and thereby a preferred direction of the Has fiber profile. Method according to one of the preceding claims 1 to 3, characterized in that the fibers of the matrix form a cast ( 1a ) of the scintillator composite ( 1 ), in particular plate, in full length ( 1b ) and / or obliquely in height ( 1c ) the form ( 1a ) run through. Method according to one of claims 1 to 4, characterized by contacting the matrix and the scintillator material prior to curing the scintillator composite ( 1 ). A method according to claim 1 or 2, characterized by using fiber sections whose lengths, in particular about 10-40%, greater than a length ( 1b ) of a cast mold ( 1a ) of the scintillator composite ( 1 ), in particular a plate, are. A method according to claim 6, characterized in that the fibers due to their predetermined length obliquely through the cast form ( 1a ). A method according to claim 6 or 7, characterized by means of a flow while bringing together a preferential direction of the fiber flow. A method according to claim 1 or 2, characterized by giving powdery Shares of a cured Polymer matrix or particulate plastic / glass matrix to the scintillator material. Method according to one of claims 1 to 9, characterized by using powdery Scintillator. Using a scintillator composite ( 1 ) according to one of the preceding claims, with the steps of casting the scintillator composite ( 1 ) into a form ( 1a ); Fixing the shape ( 1a ) of the scintillator composite ( 1 ) on a photosensor ( 2 ). Scintillator composite ( 1 ) prepared by a method according to any one of claims 1 to 10.