DE10346681B4 - Screen-Film System - Google Patents

Abstract

Film-screen system for the Radiography comprising a scintillator layer (22) and a housing (21), being an X-ray film (24) during an x-ray by housing (21) is received and in contact with the scintillator layer (22) and the scintillator layer (22) impinges on them and because of the x-ray resulting X-ray intensity distribution converted into a visible light intensity distribution, so that the x-ray film (24) is exposed by means of the visible light intensity distribution, taking before the radiograph a shield (23a, 23b) in the housing (21) between the scintillator layer (22) and in the housing (21) recorded X-ray film (24) which is caused by the scintillator layer (22) Exposure of the X-ray film (24), characterized in that the shield (23a, 23b) for the X-ray in a lower part of the housing (21), such that the X-ray film (24) passes through the scintillator layer (22) is illuminable.

Description

The The invention relates to a film-film system.

In radiography so-called film-film systems are used to make X-rays (see, eg, EA Hoxter et al .: Röntgenaufnahmetechnik, 14th edition, Berlin: Siemens AG, 1991, pages 62-67). Such, formed in the prior art film-film system in the form of a film cassette is in the 1 shown schematically.

That in the 1 The film-film system shown comprises an opaque housing 1 in which a scintillator layer 2 , which is often referred to as a reinforcing sheet, is arranged. During an x-ray, that of a in the 1 X-ray source, not shown, emitting X-rays 3 whose marginal rays in the 1 shown in dashed lines, when passing through an examination subject, eg a patient 6 , weakened and hits as X-ray intensity distribution on the scintillator layer 2 on. The scintillator layer 2 converts the X-ray intensity distribution into a corresponding visible light intensity distribution. So that the X-ray intensity distribution is weakened as little as possible, the housing 1 in the area of the scintillator layer 2 made of a possible X-rays permeable material, such as aluminum or plastic.

For the radiograph is in the housing 1 an x-ray film 4 put that with a foam 5 as a pressure element against the scintillator 2 is pressed so that the X-ray film 4 in direct contact with the scintillator layer 2 stands and that of the scintillator layer 2 generated light intensity distribution the X-ray film 4 exposed. After the X-ray, the X-ray film becomes 4 taken and developed in a well-known manner and a new X-ray film in the housing 1 placed.

The for conventional Film-film systems used scintillator layers include powdery Scintillator material in a plastic binder. For radiation protection reasons should the scintillator as possible efficient X-ray radiation absorb and as much as possible for quality reasons good spatial resolution of the x-ray image allow. conventional However, scintillator materials used have a limited efficiency, the u.a. is due to the packing density of the powdery material. Film-film systems, however, are a well-tried and tested in practice relatively cheap solution, in particular compared with X-ray image intensifiers or Solid state detectors (see R. F. Schulz: Digital Detector Systems for Projection Radiography, in: RöFo 2001, Volume 173, pages 1137-1146).

A Increasing the efficiency of the scintillator layer can be achieved if instead of a powdery one Scintillator a needle-shaped scintillator layer is used, such as doped alkali halides. A acicular trained layer has opposite a powdery one Layer the advantage of having x-rays absorbent material can be packed more tightly, without being lateral Light propagation the spatial resolution to worsen.

adversely on a needle-shaped trained Scintillatorschicht is however its known afterglow after an x-ray. The afterglow has the consequence that one in the housing of the Film-film system newly inserted X-ray film at least partially through a so-called ghost image, that of the previous one X-ray photograph comes, is exposed, before ever the actual x-ray is made. Therefore, needle-shaped szin will become tatorschichtenschichten for conventional Film-foil systems not used.

From the US 4,303,327 a film cassette for radiography is known, which receives a film unit by means of releasable pressure closure and brings into exposure position. The protective cover which protects against daylight when the film unit is inserted is removed through a light-tight opening when the cassette is closed.

From the DE 43 28 782 A1 is a recording device for a dental X-ray diagnostic device with a handle part and a mouthpiece with storage luminescent screen located therein known. So that no light falls through two windows attached to the mouthpiece on the storage screen, a light aperture is provided. The light aperture can be pulled out of the region of the mouthpiece into that of the grip part in order to read the memory luminescent screen.

The The object of the invention is therefore to provide a film-film system of the initially to create said type, so that in particular in a scintillator with a notable afterglow a safer, easier and environmentally friendly protection of an X-ray film until the beginning of a X-ray photograph guaranteed is.

The object of the invention is achieved by a film-film system for radiography, comprising a scintillator layer and a housing, wherein an X-ray film is received in the housing during X-ray exposure and is in contact with the scintillator layer and the scintillator layer converts the incident X-ray intensity distribution resulting therefrom into a visible light intensity distribution such that the X-ray film is exposed using the visible light intensity distribution, before X-ray exposure, a shield is arranged in the housing between the scintillator layer and the X-ray film accommodated in the housing, which prevents an exposure of the X-ray film caused by the scintillator layer, characterized in that the shield for the X-ray image can be brought into a lower part of the housing, the X-ray film can be exposed by the scintillator layer.

basic idea of the film-film system according to the invention it is that a possible, emanating from the scintillator layer Afterglow should not expose the already inserted X-ray film, by placing the shield between scintillator layer and pickled X-ray film is arranged. The shield, which is e.g. around a dark and especially black plastic film is opaque. The Shield remains for the X-ray inside the case, as provided by the invention is. Thus, for example, the shield may be provided by deflectors, e.g. Roll, just before the x-ray laterally in the housing be rolled up.

Thus, with the film-sheet system of the present invention, it is possible to use, in particular, a scintillator layer having a needle-shaped structure. As already stated in the introduction, needle-shaped scintillator layers absorb X-rays more efficiently compared to powdered scintillator layers, whereby the radiation exposure in an X-ray image for a patient can be reduced. For example, in PJR Leblans et al .: New Needle-crystalline CR Detector, in: Proceedings of SPIE, Vol. 4320, 2001, pages 59-67, it is demonstrated that acicular phosphor layers have twice the DQE (detective quantum efficiency). have like powdered scintillator layers. This results in up to 50% dose savings. By contrast, the disadvantage of a needle-shaped scintillator layer in the form of afterglow is at least compensated by the shielding. With the film-film system according to the invention, it is therefore possible in particular to use needle-shaped scintillator layers, without the quality of the X-ray image being reduced by an afterglow. Needle-shaped phosphor materials are also described, inter alia, in JA Rowlands: The Physics Of Computed Radiography, Phys. Med. Biol. 47, 2002, R123-R166, and PR Gransford et al .: Performance of A 41X41 cm ² Amorphous Silicon Flat Panel X-Ray Detector For Radiographic Imaging Application, in: Med. Phys. 27 (6), 2000, pages 1324-1325.

embodiments are shown by way of example in the schematic drawings. Show it:

1 a film-film system according to the prior art and

2 to 3 an inventive film-film system.

The 1 was already described in the introduction.

In the 2 and 3 an inventive film-film system is shown, which is an opaque housing 21 in which a scintillator layer 22 is arranged comprises. In the case of the present embodiment, the scintillator layer 22 needle-shaped and includes doped alkali halides.

For an X-ray is in the housing 21 an x-ray film 24 inserted. So an x-ray film 24 not before the actual X-ray exposure by an afterglow of the scintillator layer 22 is exposed with a ghost image, the X-ray film becomes 24 by means of two shielding elements 23a and 23b which in the case of the present embodiment are elastic thin dark plastic plates, from the scintillator layer 22 shielded as it is in the 2 is illustrated.

For the actual radiograph, the two shielding elements 23a and 23b about roles 25 and 26 in the case 21 are rotatably disposed in the lower part of the housing 21 moves, as it is in the 3 is shown. The roles 25 and 26 be doing with a in the 2 and 3 Crank not shown set in motion.

After the two shielding elements 23a and 23b the x-ray film 24 no longer before exposure through the scintillator layer 21 Protect, can be made with the film-film system an X-ray. In addition, now pushes a foam 27 as pressure element the inserted X-ray film 24 against the scintillator layer 22 so that the x-ray film 24 in direct contact with the scintillator layer 22 stands.

After the X-ray, the Röntgen genfilm 24 again taken and developed in a well-known manner and a new X-ray film in the housing 21 placed. Before the new X-ray film in the case 21 is placed, the two shielding 23a and 23b again in the in the 2 Position shown so that they are the newly inserted X-ray film from the scintillator 22 shield.

The shielding elements 23a and 23b can also be rolled up laterally or only one shielding element can be used.

Claims (4)

Film-film system for radiography, comprising a scintillator layer ( 22 ) and a housing ( 21 ), where an X-ray film ( 24 ) during an x-ray in the housing ( 21 ) and with the scintillator layer ( 22 ) and the scintillator layer ( 22 ) converts the X-ray intensity distribution incident thereon and formed on the basis of the X-ray image into a visible light intensity distribution such that the X-ray film ( 24 ) is exposed by means of the visible light intensity distribution, wherein before the X-ray exposure a shield ( 23a . 23b ) in the housing ( 21 ) between the scintillator layer ( 22 ) and in the housing ( 21 ) recorded X-ray film ( 24 ), one through the scintillator layer ( 22 ) caused exposure of the X-ray film ( 24 ), characterized in that the shield ( 23a . 23b ) for the radiograph in a lower part of the housing ( 21 ), such that the X-ray film ( 24 ) through the scintillator layer ( 22 ) is illuminable. Film-film system according to Claim 1, in which the shielding ( 23a . 23b ) comprises a dark plastic film. Film-film system according to claim 2, wherein the plastic film is formed by a black plastic film. Film-film system according to one of Claims 1, 2 or 3, in which the scintillator layer ( 22 ) has a needle-shaped structure.