1. Field of the Invention
The invention concerns a method to produce a scintillator-photosensor sandwich, a scintillator-photosensor sandwich, and a radiation detector with a photosensor sandwich, of the type wherein the scintillator-photosensor sandwich is produced by gluing a scintillator layer with a photosensor layer.
2. Description of the Prior Art
In the manufacture of detectors for graphical presentation of images generated by ionizing radiation for medical applications and for NDT (Non-Destructive Testing), scintillators, for example CsI:TI on Al substrates or GOS (Gadolinium oxysulfide=Gd2O2S) intensifier foils, are arranged over photosensors such as CMOS (Complementary Metal Oxide Semiconductor) arrays or CCD (Charge Coupled Device, i.e., a light-sensitive electronic component arrays), in particular with amorphous silicon (a-Si) technology. The scintillator layer is either only pressed on or is glued. The gluing has the advantage that more light is injected from the scintillator into the photosensor.
A production method for such a scintillator-photosensor sandwich and a radiation detector is known from the publication US 2008/0206917 A1. This publication discloses a production process for such a scintillator-photosensor sandwich for use in a radiation detector for ionizing radiation within the scope of a graphical presentation, in which process an adhesive layer is laminated onto a photosensor layer without vacuum with the use of a transfer adhesive tape. The remaining protective film of the transfer adhesive tape is removed from the adhesive layer in the procedure immediately following the lamination process, and the scintillator layer is thereupon placed on the photosensor layer provided with an adhesive layer and is glued to the photosensor layer with this adhesive layer.
This known production method is expensive, in particular due to the fact that is implemented in part under vacuum.
An object of the invention is to provide an alternative production method for an x-ray detector or an x-ray detector element in which the combination of scintillator layer and photosensor layer is produced more simply and securely.
The invention is based on the insight that a scintillator-photosensor sandwich can be produced more easily and securely by adhering the scintillator layer and the photosensor layer to each other in two lamination steps with the use of a transfer adhesive tape. Such an adhesive tape has at least one adhesive layer that is arranged on one protective film or between two protective films. For this purpose, in a first step, after removing a lower protective film of the adhesive tape the adhesive layer is laminated on the scintillator layer or photosensor sensor between two rollers. After the removal of the second protective film, this scintillator layer, or the photosensor layer occupied by an adhesive layer, is now laminated with the photosensor layer or scintillator layer. The same lamination device is advantageously used for this.
Air bubbles can be avoided by sufficiently high contact pressure, in particular in the second lamination step, even without vacuum. The method and the lamination device necessary for this are therefore much simpler and also allow multiple sensor sandwiches to be glued successively in the same lamination device, while in the aforementioned method in the prior art only a batch production is reasonable. Typical sufficient contact pressures in the first lamination process are 1-15 kg/cm2. Furthermore, in this method it is advantageous if the scintillator substrate is thinner than 0.6 mm, preferably approximately 0.3 mm, and is made from aluminum, and at least one anodized layer (also additional reflection layers) should be present on the luminophore side (thus the side of the scintillator layer). This design enables a uniform deflection, which is necessary during lamination in order to avoid air inclusions over large areas. In particular, this is advantageous when the scintillator layer with adhesive film is laminated onto the photosensor layer.
As used herein, a scintillator layer means a combination of a substrate with a scintillator material, CsI: TI, for example, deposited therein. As used herein, a photosensor layer encompasses any layer structure that generates electronic signals on a pixel-by-pixel basis from optical signals. In the description herein, both layers are designated with the term “function layers,” which (in use) includes the function of the conversion of ionization radiation into light pulses or the function of registering these light pulses.
A method in accordance with the invention to produce a scintillator-photosensor sandwich for use in a pixel-resolving radiation detector for ionizing radiation, in which either a scintillator layer or a photosensor layer can respectively be the first and second function layers (alternatively), includes the following method steps:
A transfer adhesive tape is provided that has at least one adhesive layer having a first side at which the adhesive layer is exposed and a second side covered by protective film.
The protective film-free side (first side) of the adhesive layer of the transfer adhesive tape is applied onto a first of the function layers.
A first lamination of the adhesive layer including the protective film onto the first function layer is implemented with the use of at least one roller.
The protective film is removed from the adhesive layer.
A second of the function layers is then placed in contact with the second side of the adhesive layer that is situated on the first of the function layers.
A second lamination of the two function layers with the adhesive layer situated between them is implemented, with the use of at least one roller.
A transfer adhesive tape with two protective films covering the adhesive layer on both sides can advantageously be used, wherein a protective film is removed from the adhesive layer before the placement of the transfer adhesive tape onto the photosensor layer, such that the adhesive layer directly contacts the surface of the function layer.
Furthermore, any adhesive layer that may be protruding can be separated from the scintillator-photosensor sandwich after the second and last lamination process of the function layers.
With regard to possible variants of the lamination method, a roller with a counter-roller or a roller with a counter-bar or a counter-surface can be used as a laminating device for the first and/or second lamination. For example, the counter-surface or the counter-bar can also be rotating with a resilient surface (for example a belt) forming to the opposite roller surface. Moreover, one of the rollers or the counter-bar or the counter-surface can be equipped to provide for a uniform pressure distribution across the entire roller width. Such measures are known on a larger scale from the fields of paper manufacturing and printing technology, for example.
Furthermore, the lamination process should advantageously be executed with a contact pressure from 1 to 15 kg/cm2, with the contact pressure preferably being higher in the second lamination than in the first lamination.
Moreover, it is advantageous when a scintillator material on a substrate made of aluminum is used as the scintillator layer. Here the aluminum on the side of the scintillator material can be coated with an anodized layer or additional reflection layers.
The invention also encompasses a scintillator-photosensor sandwich generated according to the production method described above, and a radiation detector for ionizing radiation for imaging examination methods that has at least one such scintillator-photosensor sandwich.
In the following the invention is described in detail with the use of
As is apparent in
The beginning of the second lamination process now follows as it is shown in different variants in
A second alternative of the second lamination step is shown in
In contrast to the methods shown in
Finally, in
The present invention thus shows a variant of the lamination of two function layers into a sensitive radiation detector for ionizing radiation that is easy and simple in practice, wherein the method shown here is also very well suited for a serial production since no vacuum generation is necessary in the individual method steps, and in spite of this air inclusions that are otherwise possible between the individual layers are avoided with certainty.
Although modifications and changes may be suggested by those skilled in the art, it is the intention of the inventors to embody within the patent warranted hereon all changes and modifications as reasonably and properly come within the scope of their contribution to the art.
Number | Date | Country | Kind |
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10 2010 062 040.8 | Nov 2010 | DE | national |