DE19962774A1 - Read-out apparatus for reading information stored in storage layer of X-ray cassette, has erasing device which outputs radiation at two different intensities - Google Patents

Abstract

The invention relates to a device and a method for reading out information stored in a storage layer (15) and to an X-ray cartridge. Said device and method use a deleting means (11, 12, 14) that produces a deleting ray (17) for deleting information that is stored in the storage layer (15). This deleting ray (17) can have a first and a second intensity, the first intensity being greater than the second intensity.

Description

The present invention relates to an apparatus and a method for Ausle information stored in a storage layer in accordance with the Preambles of claims 1 and 17 and an X-ray cassette.

In particular for medical purposes, an object, for example a patient, by means of X-ray radiation, generates an image that is in a Storage layer is stored as a latent image. As a storage layer mostly a phosphor layer is used. For reading the in the Spei X-ray image stored in the layer becomes the storage layer excited by a radiation source. It then emits on the basis of this Excitation light that has an intensity corresponding to the stored x-ray has radiation pattern. The light emitted by the storage layer becomes received by a receiving means and then in electrical signals converted so that the x-ray stored in the storage layer can then be made visible. The X-ray For example, picture can be displayed directly on a monitor or on a monitor Written photographic X-ray film specially used for X-ray images  become. After reading out the X-ray image from the memory layer is deleted by a deleting device to a subsequent one To be able to save an X-ray image.

Such storage layers can be arranged in an X-ray cassette. European Patent EP 0 288 014 B1 describes the deletion of a memory Cherschicht known, which is located in an X-ray cassette. The X-ray cassette contains an opening mechanism so that the x-ray cassette can be opened Deletion of information stored in the storage layer opened can be. There is an extinguishing agent outside the X-ray cassette emits an extinguishing radiation. This extinguishing radiation is in the open X-ray gene cassette irradiated and thrown onto the storage layer. By the Be Radiation of the storage layer by means of the extinguishing radiation are those in the memory information stored in the layer is deleted. The well-known X-ray box Sette contains a reflector or diffusion agent to get into the cassette to reflect incident radiation and across the width of the memory to spread layer.

A device for reading out stored in a storage layer Information is known from US Pat. No. 5,038,037. In it is a X-ray table for X-raying patients described. The x-ray table contains two layers of phosphor attached to the top and bottom of a tape are brought in and serve to store X-ray information. As well as those on the top as well as those on the bottom of the band brought phosphor layer, the well-known X-ray table has its own device device for reading out information from these phosphor layers. Of the x-ray table also contains two extinguishing agents that are used to extinguish the phos phosphor layers are used. There is one for each of the phosphor layers Extinguishing agent provided. An extinguishing lamp serves as an extinguishing agent Direction of transport of the belt viewed - is arranged in front of that point  at which the x-ray image is taken by the patient. There is an "old" X-ray stored in the phosphor layer tion image deleted before a "new" X-ray image is taken. Several extinguishing devices arranged side by side are also used as extinguishing agents lamps used in the X-ray table below that position are arranged on which the X-ray image on the standing band with the Phosphor layers is projected. Before taking the "new" x-ray Radiation picture is therefore with this extinguishing agent when the belt is stationary next the "old" X-ray image is deleted. With this type of extinguishing agent the phosphor layer cannot be used directly for the "new" picture. The Deletion of the phosphor layers takes place only immediately before the following one took a "new" X-ray image. This means a time loss and a coordination between delete and subsequent storage process. The deletion has to be finished before the next X-ray can begin.

An X-ray cassette is known from patent application WO 99/28 765, in of both a device for reading out in the storage layer stored information as well as an extinguishing agent for deleting in the memory Layer stored information is available. The extinguishing lamp he stretches across the entire width of the storage layer in which the Informatio can be saved. The extinguishing agent is activated by a drive along a transport direction that is perpendicular to the line direction over led the storage layer. In this way, the storage layer can line up wisely deleted.

The present invention has for its object to simple and effek tive way of deleting information stored in a storage layer tion and a good quality reproduction of stored information to enable.  

This task is carried out according to the technical teachings of claim 1, of the An claim 16 or claim 17 solved.

Because of the configuration according to the invention, it is possible to avoid or at least to reduce ghosting in the storage layer. Such ghosting can arise if the device according to the invention or the X-ray cassette is exposed to scattered radiation from other X-ray recording devices; that can be nearby, for example. Such scattered radiation can be very low in detail, but by adding scattered radiation from several X-ray images of other X-ray recording devices, visible ghost images can accumulate in the storage layer. In addition, conventional storage layers can contain small amounts of radioactive isotopes, e.g. B. ²²⁶ Ra, which also emit low levels of radiation: These are supplemented by natural, cosmic rays. Particularly when the storage layer is not used for a long time, these radiations can contribute to the formation of the ghost images. Ghost images have a detrimental effect on the quality of the reproduction of the information read out. When reading out stored information, ghost images can become noticeable as noise. On the basis of the invention, it can furthermore advantageously be ensured that "new" information can be stored without having to delete it immediately prior to the storage. It is not necessary to match the deletion process to the saving process.

The extinguishing agent advantageously gives immediately after reading In formations of an image from the storage layer an erasure radiation with the greater, first intensity. This ensures that the memory layer quite quickly after saving an image for taking a new picture is ready.  

In a further advantageous embodiment of the invention, after the end give the extinguishing radiation with the first intensity the extinguishing radiation with the second, weaker intensity output. This will make an undesirable Preventing stray radiation striking the storage layer from being stored, since this scattered radiation is continuously extinguished by the extinguishing radiation.

In a particularly advantageous embodiment, between reading the Information of a first picture and the subsequent storage of In formations of a second image the extinguishing radiation on the storage layer spent. This saves stray radiation and creates ghosting the entire time between reading the first and the storage of the information of the second image avoided. This further improves the quality of the reproduction of the information. Furthermore, the quenching radiation with the second intensity can be independent of the saving of information of a new image are output. A reconciliation between saving and deleting with the second Intensity is not required for the sake of simplicity.

A detection means for detecting that radiation is advantageous with which information is stored in the storage layer. This enables the extinguishing agent to be switched off automatically if storage of information of a new image begins. Simplicity neck The detection means can contain a photodiode in front of a wall Treatment layer for converting the stored radiation into radiation is brought, which has a wavelength that can be detected by the photodiode is.

Further advantageous embodiments of the invention can the dependent An sayings are taken.

In the following the invention and its advantages with reference to execution described examples. Show it:

Fig. 1 shows a first embodiment of an inventive Röntgenkas sette having a sheet-like extinguishing source,

Fig. 2 is a sectional view of the first embodiment of the Röntgenkas sette shown in FIG. 1,

Fig. 3 shows a second embodiment of an inventive Röntgenkas sette with a laterally attached to the X-ray cassettes edge erase source,

Fig. 4 is a sectional view of the second embodiment of the X-ray cassette according to FIG. 3,

Fig. 5 shows an example of an X-table, in which a third embodiment of an X-ray cassette according to the invention is arranged and

Fig. 6 is a detailed schematic representation of the third embodiment of the X-ray cassette with an embodiment of a read head according to the invention.

In the following, the same reference will be made for the same elements with the same effect characters used.

Fig. 1 shows the first embodiment of the present invention Rönt Cassette 1. This x-ray cassette contains a storage layer 15 . The storage layer 15 is a phosphor plate here. X-ray radiation images can be stored in the phosphor plate 15 . The X-ray cassette 1 contains a reading head 10 for reading out the X-ray radiation images stored in the phosphor plate 15 . Along the long sides of the phosphor plate 15 , two guide rods 16 and 17 are attached, which are used for porting and for guiding the reading head 10 . The reading head 10 can be transported along the guide rods 16 and 17 in a feed direction A over the surface of the phosphor plate 15 by means of a drive, not shown. An erasing lamp 11 is attached to the left behind the reading head 10 . The extinguishing lamp 11 is connected to the reading head 10 and, like the reading head 10 , can be transported along the guide rods 16 and 17 over the surface of the phosphor plate 15 in the feed direction A by means of the drive, not shown. The erase lamp 11 is used to erase phorplatte in Phos stored information genstrahlungsbildes after reading a Rönt are stored by means of the read head 10 in the phosphor plate 15 °. During operation, the extinguishing lamp 11 emits extinguishing radiation with a first intensity. This first intensity is advantageously so great that residual information of the X-ray image remaining in the phosphor plate 15 is deleted with a single back and forth movement of the erasing lamp 11 via the phosphor plate 15 along the direction A. After erasing the phosphor plate 15 by means of the erase lamp 11 , the X-ray cassette is ready for receiving a subsequent, second X-ray image. The erasing lamp 11 and the reading head 10 extend in a row direction B over the entire width of the phosphor plate 15 . The line direction B is perpendicular to the feed direction A.

A second erase lamp 12 is arranged under the phosphor plate 15 within the X-ray cassette 1 . This second extinguishing lamp 12 is flat. The area of the second extinguishing lamp 12 runs parallel to that of the phosphor plate 15 . The extent of the area of the second extinguishing lamp 12 essentially corresponds to that of the phosphor plate 15 in which the X-ray images are stored. The quenching radiation emitted by the second quenching lamp 12 has a wavelength which is within the wavelength range in which the phosphor plate 15 can be stimulated. The flat radiator "PLANON" sold by Osram, for example, can be used as such a flat second extinguishing lamp 12 .

The x-ray cassette 1 also contains a control means 13 with which the components contained in the x-ray cassette 1 are controlled. The control means 13 is used in particular to control the first extinguishing lamp 11 and the second extinguishing lamp 12 . By means of the control means 13 , the two extinguishing lamps 11 and 12 are in an on state; in which they emit extinguishing radiation, and can be switched to an off state in which they emit no extinguishing radiation. The second extinguishing lamp 12 is advantageously switched on by the control means 13 immediately after the phosphor plate 15 has been extinguished by the first extinguishing lamp 11 . It then continuously emits the quenching radiation with the weak, second intensity. The second intensity is advantageously so weak that its contribution to the overall noise can be neglected. For storing a new X-ray image in the phosphor plate 15 , the second erase lamp 12 is switched by the control means 13 to the off state. The new x-ray image can therefore be stored completely continuously in the phosphor plate 15 without the slightest part of information being deleted by the second erase lamp 12 . As already described above, the X-ray radiation image is then read out with the reading head 10 and the residual information of the X-ray radiation image stored further in the phosphor plate 15 after the reading is deleted by means of the first erase lamp 11 .

It is also possible to leave the second erasing lamp 12 in the on state even while the new x-ray image is being saved. In this case, there is advantageously no need to coordinate between the second extinguishing lamp and the radiation source, which outputs the exposure radiation with the information to be stored in the direction of the phosphor plate 15 . The extinguishing radiation that can be output by the second extinguishing lamp 12 can be designed in such a way that it is no longer necessary to switch off the second extinguishing lamp 12 . An integration and coordination of the function of the second erase lamp 12 in the recording, reading and erasing process is therefore simply not necessary for reasons of safety.

FIG. 2 shows a schematic sectional illustration of the phosphor plate 15 and the second extinguishing agent 12 according to FIG. 1. The second extinguishing lamp 12 is arranged parallel to the phosphor plate 15 within the X-ray cassette 1 . The second extinguishing lamp 12 emits an extinguishing radiation 17 in the direction of the phosphor plate 15 , which has the weak, second intensity.

Fig. 3 shows a second embodiment of the X-ray cassette 1 of the invention. Instead of the second erase lamp 12 ( FIG. 1) attached below the phosphor plate 15, a third erase lamp 14 is arranged here on the rear longitudinal side wall of the X-ray cassette 1 . This third extinguishing lamp 14 is located laterally next to the phosphor plate 15 and extends along the long side thereof. On the inside of the upper cover of the Röntgenkas set 1 , a flat reflector 16 is parallel to the phosphor plate 15 angeord net. The reflector 16 can be a mirror, for example.

The third extinguishing lamp 14 has the same function as the second extinguishing lamp 12 of the first exemplary embodiment according to FIG. 1. It emits extinguishing radiation with the weak, second intensity. This weak quenching radiation can partially radiate directly from the third quenching lamp 14 onto the phosphor plate 15 , or it can be directed from the third quenching lamp 14 onto the reflector 16 and in turn reflected by the latter in the direction of the phosphor plate 15 . In this way, the extinguishing radiation emitted by the third extinguishing lamp 14 is distributed over the entire surface of the phosphor plate 15 . The entire surface of the phosphor plate 15 is reached due to the arrangements of the extinguishing lamp 14 and the reflector 16 from the second extinguishing radiation 17 .

Fig. 4 shows a schematic sectional view of the X-ray cassette 1 ge according to the second embodiment of Fig. 3. The X-ray cassette 1 is shown here cut in the row direction B. The third extinguishing lamp 14 is arranged on the left side of FIG. 4. It is located laterally to the gate Reflectors 16 and the phosphor plate 15 are added, in about the same distance from the reflector 16 and the phosphor plate 15, within the x-ray cassette. 1

FIG. 5 shows an application example of a third embodiment of the X-ray cassette 1 of the invention. In this application example, the X-ray cassette 1 is used in an X-ray table 20 . This X-ray table 20 contains an X-ray base 23 , in which the X-ray cassette 1 is located, and a support surface 24 arranged on this X-ray base 23 . Patients are placed on this bearing surface 24 for X-ray exposure. Above the support surface 24 and the X-ray foot 23 with the X-ray cassette 1 located therein, an X-ray source 21 is attached to the X-ray table 20 . The x-ray source 21 emits an x-ray radiation 25 in the direction of the support surface 24 for taking the x-ray image. The X-ray cassette 1 present in the X-ray foot 23 here contains a detection means 22 which serves as a sensor for the X-ray radiation 25 . The sensor 22 can be used to determine whether the x-ray source 21 emits x-ray radiation 25 . The functional activity of the extinguishing agent contained within the X-ray cassette 1 can be controlled with the aid of the sensor 22 .

FIG. 6 serves to further clarify the function of the sensor 22 and to describe the reading head 10. FIG. 6 shows the reading head 10 and further components present in this reading head 10 for reading out the x-ray information stored in the phosphor plate 15 . The reading head 10 contains a laser diode line 34 which extends along the line direction B. The laser diode line 34 serves to excite a phosphor material 32 , which is applied to a transparent carrier material 33 and forms the phosphor plate 15 together with this carrier material 33 . An excitation radiation 38 output by the laser diode line 34 crosses the carrier material 33 and penetrates into the phosphor material 32 . Due to this excitation of the phosphor material 32 Phos phormaterials 32 emits an emission radiation. This emission radiation is imaged on an CCD line 36 by an optical imaging means 35 , which for example contains a large number of optical waveguides. The CCD line 36 contains a multiplicity of rows of light-sensitive surfaces 37 arranged next to one another.

FIG. 6 shows further the sensor 22 for detecting X-ray radiation 25. The sensor 22 contains a photodiode 30 , over which a scintillation layer 31 is arranged. The X-ray source 25 emitted by the X-ray source 21 strikes it. Scintillation layer 31 . The scintillation layer 31 performs a wavelength conversion. The x-ray radiation 25 is converted into radiation with a wavelength that can be detected by the photo diode 30 . The sensor 22 is connected to the control means 13 . The information determined by the sensor 22 about the output of X-ray radiation 25 by the X-ray source 21 can be used by the control means 13 to control the second extinguishing lamp 12 . This second extinguishing lamp 12 is in the embodiment according to FIG. 6 under the phosphor plate 15 , as already described in connection with FIG. 1, is arranged.

The second extinguishing lamp 12 is in its on state, so that it emits weak extinguishing radiation 17 in the direction of the phosphor plate 15 , the second extinguishing lamp 12 can then be switched to the off state by the control means 13 if by the sensor 22 it is established that the x-ray source 25 for the renewed storage of an x-ray image in the phosphor plate 15 emits x-ray radiation 25 . In this way, the second extinguishing lamp 12 can be switched off automatically, so that deletion with the second extinguishing radiation 17 does not take place during the taking of a new X-ray image.

Instead of the photodiode 30 and the scintillation layer 31 , the sensor 22 can also be configured differently. The configuration by means of the photodiode 30 and the scintillation layer 31 represents a particularly easy to implement variant of the sensor 22 .

In the previously described exemplary embodiments, two extinguishing lamps 11 and 12 and 14 are used to extinguish the phosphor plate 15 by means of the strong and the weak extinguishing radiation. It is also possible to use a single extinguishing lamp instead of two extinguishing lamps or else more than two extinguishing lamps. In the case of a single extinguishing lamp, it is designed in such a way that it emits both the weak and the strong extinguishing radiation.

Claims (17)

1. Device for reading out information stored in a storage layer ( 15 ) with an extinguishing agent ( 11 , 12 , 14 ) for deleting information stored in the storage layer ( 15 ) by means of an extinguishing radiation ( 17 ), characterized in that the extinguishing agent ( 11 , 12 , 14 ) is configured such that the extinguishing radiation ( 17 ) that can be output can assume a first and a second intensity, and the first intensity is greater than the second intensity. 2. Device according to claim 1, characterized in that the extinguishing means ( 11 , 12 , 14 ) is designed such that it outputs the extinguishing radiation ( 17 ) with the first intensity substantially immediately after reading out information from a first image. 3. Device according to claim 1 or 2, characterized in that the extinguishing agent ( 11 , 12 , 14 ) is designed such that it outputs the extinguishing radiation ( 17 ) with the second intensity after outputting the extinguishing radiation ( 17 ) with the first intensity . 4. Device according to one of claims 1 to 3, characterized in that the extinguishing agent ( 11 , 12 , 14 ) is designed such that it is at least between the reading of the information of a layer ( 15 ) stored in the memory first image and the subsequent one storing information from a second image in the storage layer (15), the erasure radiation (17) outputs to the storage layer (15). 5. Device according to one of claims 1 to 4, characterized in that it has a control means ( 13 ) for controlling the extinguishing agent ( 11 , 12 , 14 ), so that this in an on state in which the extinguishing radiation ( 17th is) output onto the storage layer (15), and in an OFF state is switched, in which no erasure radiation (17) on the SpeI cherschicht (15) is output. 6. Device according to one of the preceding claims, characterized in that the extinguishing agent ( 11 , 12 , 14 ) is designed such that in operation during the storage of information in the storage layer ( 15 ) extinguishing radiation ( 17 ) with the second intensity on the storage layer ( 15 ) can be output. 7. Device according to one of the preceding claims, characterized in that the extinguishing agent ( 11 , 12 , 14 ) has a first extinguishing source ( 11 ) for outputting the extinguishing radiation with the first intensity and a second extinguishing source ( 12 , 14 ) for outputting the extinguishing radiation ( 17 ) with the second intensity. 8. Device according to one of the preceding claims, characterized in that the extinguishing agent ( 11 , 12 , 14 ) has a flat-shaped extinguishing source ( 12 ), the surface of which is arranged parallel to the storage layer ( 15 ). 9. The device according to claim 7 and claim 8, characterized in that the second extinguishing source ( 12 ) is the flat-shaped extinguishing source ( 12 ). 10. The device according to claim 8 or claim 9, characterized in that the area for outputting the quenching radiation ( 17 ) has at least the size of the storage layer ( 15 ). 11. The device according to one of claims 1 to 7, characterized in that the extinguishing agent ( 11 , 12 , 14 ) has an extinguishing source ( 14 ) which is arranged since Lich next to the storage layer ( 15 ). 12. Apparatus according to claim 11, characterized in that it comprises a reflector (16) for reflecting the source of the laterally arranged erasing erasure radiation produced (17) and the reflector (16) is arranged so that light reflected by it erasure radiation (17 ) is directed towards the storage layer ( 15 ) during operation. 13. Device according to one of the preceding claims, characterized in that it has a detection means ( 22 ) for detecting a Abspei cherungs radiation ( 25 ), which serves to store the information in the storage layer ( 15 ). 14. The apparatus according to claim 5 and claim 13, characterized in that the detection means ( 22 ) is connected to the control means ( 13 ). 15. The apparatus according to claim 13 or claim 14, characterized in that the detection means ( 22 ) has a photodiode ( 30 ) and a conversion layer ( 31 ) for converting the storage radiation ( 25 ) into radiation which is emitted by the photodiode ( 30 ) is detectable. 16. X-ray cassette with a storage layer ( 15 ) for storing information and a device according to one of the preceding claims. 17. A method for reading out abgespeicher in a storage layer (15) th information, wherein in the storage layer (15) stored infor mation be erased by means of an erasure radiation (17), characterized in that the erasure radiation a first and a second Inten intensity takes , and the first intensity is greater than the second intensity.