EP0033894A1 - Plural-stage vacuum X-ray image amplifier - Google Patents

Abstract

The invention relates to multi-stage vacuum image intensifiers, in which the X-ray image converted into an electron image is amplified by acceleration in the electrical field at least in two stages, which are coupled to one another via a screen. This screen contains as essential elements a luminescent layer and a photocathode layer optically in contact with it. One of them is located on one side and the other on the opposite side on a sufficiently stable support plate that allows the light from the light layer to pass through. With this intermediate screen, it is difficult to keep the area for applying the photocathode layer sufficiently clean. To this end, the invention provides for the surface of the carrier plate (7) to be provided with one of the photocathode layers (9) that are resistant to coating (8), which for a photocathode layer made of cesium-antimony consist of cesium iodide and can be 5 to 10 μm thick. This ensures that the underlay is covered tightly and that the surface is clean. An x-ray image intensifier improved according to the invention is particularly suitable for use in medical x-ray diagnostics.

Description

The invention relates to multi-stage X-ray image intensifier (RBV) according to the preamble of claim 1. Such image intensifiers are known, for example, from US Pat. No. 2,555,423.

In multi-stage image intensifiers, in which the x-ray image is first converted into an electron image, the individual stages, which amplify the electron image by acceleration in the electric field, are coupled to one another via screens, the essential elements of which are a luminescent layer and an optical one with it Have contact standing photocathode layer. These two reactive layers usually have little strength in themselves. They are therefore attached to both sides of a sufficiently stable support plate which allows the light released in the luminescent layer to pass through to the photocathode layer on the other side.

The support must be designed so that there is a good "contact copy" of the fluorescent screen image on the photocathode, i.e. that the support does not reduce the sharpness of the image. This is e.g. achievable through the use of fiber optic plates as supports for the layers. But they have the main disadvantage that they are very expensive.

A reduction in costs would be the use of transparent plates or foils, something made of glass, mica or a vacuum-proof organic material (e.g. polyimide) or the like. However, the thickness of the carrier layer must not cause any significant scattering of the light passing through. For the image sharpness that can generally be used in RBV, for example, up to 50 _/ um would still be permissible. In known methods, the phosphor layer is first applied to the carrier. This is followed by installation in the image intensifier arrangement and finally the application of the photocathode layer to the still free surface of the support opposite the luminous layer.

Most intermediate screens manufactured in a known manner have uneven brightness transmission over the surface. This can be explained, for example, by the fact that even an originally sufficiently clean surface during sedimentation of the phosphor on one side of the support "dirty" the opposite side, which was later to be covered with the photocathode, by the means used in the manufacture of the fluorescent screen, because of the sensitivity of the thin film is insufficient protection. The low stability of the film also means that the "dirty" surface cannot be cleaned sufficiently afterwards. In this way, the local disturbances of the photocathode and thus a blotchy image are obtained.

The invention has for its object to provide a coupling screen in image intensifiers according to the preamble of claim 1, which results in flawless images and is still inexpensive and easy to manufacture. This object is achieved by the measures specified in the characterizing part of claim 1. The subjects of the subclaims relate to advantageous developments of the invention.

The invention is based on the fact that a clean base for the photocathode can also be obtained by applying a clean assignment before the photocathode is applied. In addition, it has proven to be expedient to provide base areas on both the input screen and the intermediate screen, which are of the same type and at the same time form a barrier against influences from the base. Care should be taken, however, that the application on the base of the coupling screen should be thin in order to keep the loss of light and sharpness low, i.e. so that the light passing from the screen into the photocathode is not unduly absorbed and scattered.

• a) Kathodenverträgliche Diffusionssperre gegen Verunreinigungen der Trägeroberfläche, die sonst zur partiellen "Vergiftung" der Fotokathode führen können.
• b) Sowohl auf dem Eingangsschirm als auch auf dem Träger des bzw. der Zwischenschirme wird gleiches Substrat für die Fotokathode erhalten, so daß gleichmäßigere Kathoden erzielt werden können.
• c) Bei fehlerhafter Herstellung der Fotokathode und Verwendung einer zusätzlichen Schicht aus einem Mittel, das in einer Flüssigkeit löslich ist, die den Träger nicht angreift, kann die Fotokathodenschicht zusammen mit der zusätzlichen Schicht abgewaschen und der Schirm erneut verwendet werden.

The additional layer has the following advantages:

• a) Cathode compatible diffusion barrier against contamination of the carrier surface, which can otherwise lead to partial "poisoning" of the photocathode.
• b) The same substrate for the photocathode is obtained both on the input screen and on the support of the intermediate screen or screens so that more uniform cathodes can be achieved.
• c) If the photocathode is manufactured incorrectly and an additional layer of an agent which is soluble in a liquid which does not attack the carrier is used, the photocathode layer can be washed off together with the additional layer and the screen can be used again.

In the current X-ray image intensifiers in which cesium iodide is doped with sodium (CsJ: Na) as a light vaporization of the coupling screen with CsJ: Na has proven to be favorable. The thickness of the evaporation of the surfaces to be covered later with the photocathode layer should be at least so strong that a dense covering of the base is obtained. When this is reached, the evaporation can be stopped with cesium iodide. An upper limit is given by the still acceptable image blur.

A method which has proved to be advantageous is that the "contaminated" surface before the coating with the photo-cathode with a layer of CsI. Na is occupied, the 5 to 10 _/ is to thick, it is a very clean Get a pad for the photo cathode. In addition, both the entrance screen and the intermediate screen (s) are given surfaces of the same material, ie the same substrate is produced. This makes it possible to manufacture the photocathodes in the same or a similar process. In this way, cathodes of the same cesium saturation can be obtained. In earlier methods, cathode oversaturation could occur due to different formation rates occurring on different substrates. In the invention, one can get by with an antimony (Sb) source, whereas in the known production a special Sb source was required for each photo-cathode because of the necessary adaptation to the substrate. If water-soluble cesium iodide is used as the material of the additional layer, the cathode material can simply be rinsed off with water together with the background vapor deposition.

The technology according to the invention can also be used with advantage where subsequent cleaning of the base of the photocathode itself would be possible. Through the Intermediate layer according to the invention can generally be achieved in addition to the advantages specified above, because the cleaning step can be dispensed with (cleaning, polishing, etc.).

Details and advantages of the invention are explained in more detail below with reference to the embodiment shown in cross-section in the figure as a flat RBV.

In the figure, 1 denotes a vacuum-tight bulb, which carries on its one end wall 2 in the interior of the bulb a luminous layer 3, on which a photocathode layer 4 follows. At a distance of about 12 mm, an electron-sensitive fluorescent screen, which consists of an electron permeable, light reflecting cover 5 made of aluminum and a light-emitting layer 6. This rests on a support 7 which consists of mica and 50 _/ is thick. Follows On its free surface, the carrier 7 is provided with a coating 8 made of cesium iodide, which is 8 _/ um thick. Finally, a photocathode layer 9 which corresponds to layer 4 is applied to layer 8. The luminescent screen combination lying on the output side 10 opposite the input side 2, like that designated in the intermediate screen with 5 and 6, consists of a cover 11 made of aluminum and a luminescent layer 12.

To operate the image intensifier, a voltage of 15 kV is applied between the photocathode 4 and the aluminum layer 5 for close focusing and acceleration from a direct current source 13. For the same purpose, a voltage of 20 kV from a source 14 is applied between the photocathode layer 9 and the aluminum cover 11.

In order to generate an X-ray image, a beam of rays 17 coming from an X-ray tube 16 is directed onto a body 18 from a device 15 for generating X-rays. After penetrating the body 18, the rays from the bundle 17 come through the input window 2 onto the fluorescent screen 3, where they generate light which acts on the photocathode 4 and triggers electrons there. These are then accelerated as indicated by dotted lines 19 onto the fluorescent screen consisting of 5 and 6. There, the electrons trigger light again in the sense of the desired imaging and amplification 19, which acts on the photocathode 9 through the support 7 and the coating 8 and there again triggers an electron beam 20, which then emits light in the fluorescent screen consisting of 11 and 12 triggers that, as indicated by arrows 21, can be observed from the outside.

Claims (6)

1. Multi-stage X-ray image intensifier, in which the X-ray image in an input screen is converted into an electron image, which is amplified in an electrical acceleration field and then made visible on an output screen, with at least one additional one with an intermediate screen between the end of the acceleration field and the output screen beginning of the electric acceleration field and the intermediate screen carries on a translucent support on the side facing the input screen an electron-sensitive luminescent layer and opposite a photocathode layer, characterized in that the intermediate screen has the photocathode layer (9) attached to it on the carrier (7) which is resistant to it Occupancy (8). 2. Image intensifier according to claim 1, characterized in that the input screen also has such an assignment (3). 3. Image intensifier according to claim 1 or 2, characterized in that the assignment (3, 8) is a vapor deposition layer, which covers the base (entrance window (2) and / or support (7)) tightly. 4. Image intensifier according to claim 1, characterized in that the assignment (3, 8) consists of cesium iodide (CsJ). 5. Image intensifier according to claim 3, characterized in that the assignment (3, 8) consists of sodium-activated cesium iodide phosphor (CsJ: Na). 6. Image intensifier according to claim 5, characterized in that the resistant assignment (8) of the intermediate screen is 5 to 10 _/ um thick.

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