DE4411729A1 - Computer controlled X-ray appts. for dental radiography - Google Patents

Abstract

The X-ray appts. includes an emitter (1) which generates a beam (2) directed towards a receiver (3). An area is pre-defined on the receiver surface to collect the incident beam. A sensor (5) generates a signal when the beam hits the receiver outside the pre-defined area. The signal is transmitted to a control circuit (6) which can switch off the emitter power supply.

Description

DE-OS 24 19 640 is a dental X-ray diagnosis Stikeinrichtung known in which a controllable blasting transmitter for emitting a beam and generating it a radiation field is provided on a radiation receiver is. The radiation receiver can be in a pocket Film holder and placed in the mouth of a patient. At the bag has a detector transmission circuit, which is one of the Film blackening corresponding electrical signal wirelessly sends out. This signal is received by an antenna and a control circuit for determining the exposure time and to switch off the radiation transmitter when the ge desired dose of film blackening supplied.

In an X-ray diagnosis known from DE-OS 33 10 971 Stikgerät is a controllable X-ray tube for emitting X-rays provided. The limited x-rays bundle can be faded in by a primary diaphragm, the two pairs of diaphragm plates adjustable perpendicular to each other having. The X-ray beam passes through an ionization chamber with three measuring fields and meets an X-ray film cassette containing an X-ray film. Each one of the measuring fields is connected to a switching device X-ray exposure machine can be switched on, the shutdown the x-ray tube causes when a predetermined dose is applied the measuring field has acted. A microcomputer is installed hen, a signal corresponding to the film-focus distance like signals corresponding to the respective position of the diaphragm plates are fed to the primary beam aperture. From these The microcomputer calculates the size of the signals on the Ionization chamber impinging radiation field. The Mi crocomputers will also generate signals according to the above Switching device each manually selected measuring field  leads. A comparison is used to determine whether this is the case selected measuring field lies in the radiation field. If so, so the measuring field selection is not changed. However, it is not the case, the selected measuring field is switched off and from Microcomputer selected a measuring field, which is shown in the Radiation field lies. Exposure errors are thus avoided the.

An X-ray is from German patent application 42 39 825 Diagnostic device known that an X-ray tube with a Radiation diaphragm and a radiation receiver, which a opposite ge on an adjustable bracket are wearing. Means are provided for adjustment the X-ray emitter and / or the radiation receiver and / or the aperture and / or an adjustment of its aperture Mellen cause such that the center of the beam of the X-ray emitter always on the central area of the Radiation receiver strikes.

Esp. in dental X-ray diagnostic equipment, where there is no direct coupling between the radiation transmitter and the radiation receiver, it is possible that a radiation field emitted by the radiation transmitter either not or only in part to a predetermined one, provided for image generation hit that area of the radiation receiver, so that at for example, a patient as an examination object of a beam exposure that does not contribute to image generation.

The object of the invention is therefore a dental X-ray genetic diagnostic device of the type mentioned above cause radiation exposure of the object under examination avoided by radiation not contributing to imaging becomes.

The object is achieved according to a variant of the invention through a dental X-ray diagnostic device  a controllable radiation transmitter for emitting a beam lenbündels and to generate a radiation field on one Radiation receiver, wherein the radiation receiver passes agreed area to receive the radiation field and little least has a radiation detector that he a signal testifies when the radiation field outside the predetermined loading rich meets the radiation receiver and with a tax circuit that supplied the signal of the radiation detector is and due to the signal a shutdown of the Radiation transmitter causes.

The advantage of the invention is that the radiation is switched off transmitter occurs when the radiation field is outside the matched area meets the radiation receiver. The Un test object is therefore not exposed to radiation, that does not contribute to imaging.

According to a second variant of the invention, the object solved by a dental X-ray diagnostic device with a controllable radiation transmitter for emitting a Beam bundle, with controllable aperture lamellae for insertion that of the ray bundle and to limit a ray field of on a radiation receiver, the radiation receiver a predetermined area for receiving the radiation field and has at least one radiation detector, which is a Si gnal generated when the radiation field outside the predetermined area meets the radiation receiver and with a Control circuit based on the signal of the radiation detector tors actuation of the diaphragm blades such that the radiation field is limited to the predetermined range.

The advantage of the invention is that the radiation field through the Si gnal of the radiation detector and the controllable aperture lamella len is always limited to the predetermined range, so that the object under examination is not exposed to radiation that does not contribute to imaging.  

The object is achieved according to a further variant of the invention also solved by dental X-ray diagnostics device with a controllable radiation transmitter for emit animals of a ray bundle and to generate a ray field on a radiation receiver, the radiation receiver ger adjustable carried by a controllable bracket and wherein the radiation receiver has a predetermined loading rich for receiving the radiation field and at least one Has radiation detector that generates a signal when that Radiation field outside the predetermined range on the Radiation receiver hits and with a control circuit that based on the signal from the radiation detector the holder so that the radiation receiver so is aligned that the radiation field to the predetermined Area meets.

Advantage of the invention is that the radiation receiver through Control of the bracket is aligned so that the Radiation field strikes the predetermined area so that here, too, the object under examination does not emit radiation that does not contribute to imaging.

Further advantages and details of the invention emerge from the following description of exemplary embodiments a dental X-ray diagnostic device based on the Figures in connection with the dependent claims.

It shows:

Fig. 1 shows a dental X-ray diagnostic device according to the invention and the

Fig. 2 to 5 radiation receiver and associated Strahlendetek factors of dental Röntgendiagnostikeinrich processing of FIG. 1.

The dental X-ray diagnostic device shown in FIG. 1 has a controllable radiation transmitter 1 for emitting a radiation beam 2 . The radiation beam 2 is directed at a radiation receiver 3 , on which it strikes as a radiation field. The radiation receiver 3 has a predetermined area 4 ( FIGS. 2 to 5) for receiving the radiation field. Furthermore, at least one radiation detector 5 is provided which generates a signal when the radiation field outside the predetermined range 4 hits the radiation receiver 3 . The signal of the radiation detector 5 is fed to a control circuit 6 , which causes the radiation transmitter 1 to be switched off due to the signal.

According to an alternative or in a further embodiment of the dental X-ray diagnostic device described above, the radiation transmitter 1 is designed with controllable diaphragm blades 7 . These diaphragm blades 7 are used to superimpose the beam 2 and are adjustable for this purpose, for example, by means of an electromechanical drive 8 . In the game Ausführungsbei only two aperture blades 7 are shown. In the framework of the invention, of course, further aperture blades can also be provided, which are arranged offset in a plane parallel to the first aperture blades 7 by 90 °. The diaphragm blades 7 thus limit, for example, a rectangular radiation field on the radiation receiver 3 . If the radiation field hits the radiation receiver 3 outside the predetermined range 4 , the radiation detector 5 generates a signal which is fed to the control circuit 6 . On the basis of this signal, the drive (s) 8 are actuated to adjust the diaphragm blades 7 in such a way that the radiation field is limited to the predetermined region 4 .

According to a further alternative or in addition to the dental X-ray diagnostic device already described, the radiation receiver 3 is carried in an adjustable manner by a controllable holder 9 . If the beam emitter 1 emitted by the beam transmitter 1 generates the beam field 2 outside the predetermined area 4 on the beam receiver 3 , a signal is generated by the beam detector 5 , which is fed to the control circuit 6 . By the control circuit is based on the signal to control the holder 9 such that the radiation receiver 3 is aligned so that the radiation field strikes the pre-determined area 4 . The bracket 9 can be designed so that the radiation receiver 2 is adjustable along two perpendicular axes and pivotable about them.

In the context of the invention, the radiation transmitter 1 and the radiation receiver 3 can be mechanically decoupled, but alternatively also be coupled, so that panorama or ceph recordings can be made.

In the radiation receiver 3 shown in FIG. 2, four radiation detectors 5 are provided, which are provided outside of the predetermined area 4 and on the edge thereof. If the radiation field outside the predetermined area 4 , in which, for example, an X-ray film is arranged, strikes the radiation detectors 5 (dashed line), the signal for controlling the radiation transmitter and / or the lens plates and / or the holder 9 is generated.

In the radiation receiver 10 shown in FIG. 3, which is designed, for example, as a CCD converter, a region of the individual detectors is designed as a predetermined region 4 for receiving the radiation field for imaging and a region of further individual detectors as a radiation detector 5 . If the radiation field strikes the further area, the signal for controlling the radiation transmitter 1 and / or the aperture blades 7 and / or the holder 9 is generated.

In the embodiment of a radiation receiver 1 shown in FIG. 4, two radiation detectors 5 are arranged in the predetermined area 4 . If the radiation field no longer strikes the predetermined area 4 and thus on one of the radiation detectors 5 (dashed line), the signal for controlling the radiation transmitter 1 and / or the aperture blades 7 and / or the holder 9 is generated.

In a further embodiment of a radiation receiver 12 , radiation detectors 5 are arranged on the edge of opposite corners of the predetermined area 4 .

Claims (8)

1. Dental X-ray diagnostic facility
with a controllable radiation transmitter ( 1 ) for emitting a radiation beam ( 2 ) and for generating a radiation field on a radiation receiver ( 3 , 10 , 11 , 12 )
wherein the radiation receiver ( 3 , 10 , 11 , 12 ) has a predetermined area ( 4 ) for receiving the radiation field and
has at least one radiation detector ( 5 ) which generates a signal when the radiation field hits the radiation receiver ( 3 , 10 , 11 , 12 ) outside the predetermined range ( 4 ) and
with a control circuit ( 6 ), to which the signal from the beam end detector ( 5 ) is fed and which, due to the signal, causes the beam transmitter ( 1 ) to be switched off. 2. Dental x-ray diagnostic device with a controllable radiation transmitter ( 1 ) for emitting a beam ( 2 ),
with controllable diaphragm blades ( 7 ) for fading in the beam ( 2 ) and for limiting a radiation field on a radiation receiver ( 3 , 10 , 11 , 12 ),
wherein the radiation receiver ( 3 , 10 , 11 , 12 ) has a predetermined area ( 4 ) for receiving the radiation field and at least one radiation detector ( 5 ) which generates a signal when the radiation field is outside the predetermined area ( 4 ) on the radiation receiver ( 3 , 10 , 11 , 12 ) and with a control circuit ( 6 ) which, based on the signal from the radiation detector ( 5 ), controls the diaphragm blades ( 7 ) in such a way that the radiation field is limited to the predetermined region ( 4 ). 3. Dental X-ray diagnostic device
with a controllable radiation transmitter ( 1 ) for emitting a radiation beam ( 2 ) and for generating a radiation field on a radiation receiver ( 3 , 10 , 11 , 12 ),
wherein the radiation receiver ( 3 , 10 , 11 , 12 ) is adjustably carried by a controllable holder ( 9 ) and
wherein the radiation receiver ( 3 , 10 , 11 , 12 ) has a predetermined area ( 4 ) for receiving the radiation field and at least one radiation detector ( 5 ) which generates a signal when the radiation field is outside the predetermined area ( 4 ) on the radiation receiver ( 3 , 10 , 11 , 12 ) and with a control circuit ( 6 ) which, based on the signal from the radiation detector ( 5 ), triggers the holder ( 9 ) in such a way that the radiation receiver ( 3 , 10 , 11 , 12 ) does so is directed from that the radiation field strikes the predetermined area ( 4 ). 4. Dental X-ray diagnostic device according to one of claims 1 to 3, wherein the radiation receiver ( 11 , 12 ) has at least radiation detectors ( 5 ) which are provided at opposite corners of the predetermined area. 5. Dental X-ray diagnostic device according to one of claims 1 to 4, wherein the radiation receiver ( 3 ) has four radiation detectors ( 5 ) which are arranged in the edge region of the predetermined area ( 4 ). 6. Dental X-ray diagnostic device according to claim 5, wherein the radiation detectors ( 5 ) are arranged outside the predetermined area ( 4 ). 7. Dental X-ray diagnostic device according to claim 5, wherein the radiation detectors ( 5 ) are arranged in predetermined areas ( 4 ). 8. Dental X-ray diagnostic device according to one of claims 1 to 7, wherein the radiation receiver ( 3 , 10 , 11 , 12 ) is performed as a CCD converter.