DE1956070A1 - Medical radiographic equipment - Google Patents

Abstract

A variable area stop is associated with the film holder, the screened areas being covered with plates of X ray absorbent material which define a window within the conical X ray beam and can be introduced before exposure starts and remain in position throughout the exposure. An image intensifier forms a part of the monitoring system used in an automatic exposure control loop.

Description

X-ray diagnostic apparatus with an X-ray image intensifier and a Automatic exposure machines The invention relates to an X-ray diagnostic apparatus with a X-ray image intensifier, an exposure machine and one near the X-ray image intensifier arranged Hai sion device for introducing an X-ray film into the X-ray path.

X-ray exposure machines are used to make the X-ray exposure when it is reached a certain X-ray dose sufficient for the desired film blackening to interrupt. For this purpose, a measuring device is placed in the X-ray path behind the patient arranged, the electrical reference variable corresponding to the measured dose rate generated. A specific section is used to determine this reference value within the cross-sectional area of the rays called the dominant. as Radiation measuring device either an ionization measuring chamber or a photomultiplier is used, which measures the light from a fluorescent X-ray screen located in the beam path. In In both cases the measuring current is extremely low, so that highly sensitive Ness amplifiers must be used, which are complex and prone to failure.

To eliminate this deficiency, it is already known to exist of an X-ray image intensifier to use its amplification properties and either to use the image intensifier current itself as the measurement or the brightness of the To measure the output screen with the help of a photomultiplier. It has found that due to various light conduction and scattering refracts inside of the image intensifier tube within the dominant brightness fluctuations of the inevitable Background brightness depending on the size of the hidden Radiation field occur on the input luminescent screen, which falsify the measured value.

The invention is based on the object of this dependency of the measured variable of the size of the primary radiation field to be eliminated with simple means. To this end, it is proposed according to the invention that an X-ray absorbing device be used before the start of the recording Plate in the beam path between the X-ray film cassette and the X-ray image intensifier to introduce whose area expansion is equal to or greater than the cross-sectional area of the cone of rays at the insertion point, and the one radiolucent opening in the size of the usual measuring field (dominant). It is the fact that the X-ray image intensifier is only used in the case of fluoroscopy has been exploited must be fully exploitable with regard to the size of the image field.

Although it is already known per se, the X-ray image intensifier is a adjustable beam diaphragm immediately in front to avoid that the not Areas of the image intensifier input screen located in the useful beam cone be hit by scattered radiation. In contrast, there is the inventive idea in it, when using the X-ray image intensifier as a radiation measuring device, the radiation filter at the same time as a means for generating dominants.

In an advantageous embodiment of the invention, the diaphragm coupled to the holder and insertion device of the cassette in such a way that Aperture and cassette can be introduced together into the beam path and out of the beam path are removable.

Further details of the invention are based on the following exemplary embodiment shown and described.

In Fig. 1 the principle of the arrangement is shown, while the figures 3 and 2 show design variants.

In Fig. 1, the X-ray radiation from an X-ray diagnostic apparatus generated with the generator 1, the X-ray tube 2 and the indexing table 9, which the Einteilmittel and control elements for the electrical values on the X-ray tube. In The X-ray image intensifier 5 is located behind the object 4 in the direction of the beam. In the beam path between the object 4 and the input luminescent screen 6 of the X-ray image intensifier an X-ray film cassette 7 is inserted into the beam path. Between the X-ray film cassette and the fluorescent screen of the X-ray amplifier is the lead screen 8 with the opening 9 in dominant size. The light of the exit phosphor screen 10 is in Durohleuchtungsbe operated via a tandem lens 11 of a not shown Insight opening 12 supplied to which a film camera, a television camera or the like. can be connected. In this case, i.e. with fluoroscopy, are Cassette and diaphragm outside the beam path. In the case of the one shown in FIG During exposure, the cassette and diaphragm are in the beam path as shown and the X-ray image intensifier becomes either directly or indirectly the formation one of the radiation dose rates occurring in the dominant area proportional electrical measured variable used.

For the direct generation of the measured variable, the line 13 is the The cathode 14 of the X-ray image intensifier is separated with the aid of the switch 15 and connected to an integration stage 16 which, among other things, contains a measuring capacitor, through which the cathode current flows and is charged. After reaching a certain Voltage level, which corresponds to a certain dose within the domain, is a stop process is triggered, which is controlled by the control part 17 of the X-ray exposure machine with the help of the switching elements arranged in the switching table 9, the X-ray tube circuit interrupts.

It is also possible to change the measurement variable at the output signal of the X-ray image intensifier take off, and the light of the output luminescent screen over an in the non-imaging Space between the two tandem lenses arranged deflection mirror to project onto the photo cathode of the photo multiplier 18 shown in dashed lines. Its measuring current then also serves in the form already described to the To interrupt the X-ray tube circuit after the required radiation dose has been reached, In Fig. 2 a practical Aus> Uhrungsform is shown according to the invention, in which the diaphragm consists of several in the rest position, as shown in dashed lines, Lamellas 19, 20, 21 lying one above the other. On the lamella 21 is a tab 22 arranged so that they of the cassette 7 when inserted into the beam path is taken so that the slats by means of a known, not shown Vorriohtung be drawn telescopically into the beam path. The middle Lamella contains the dominant opening 9.

In Fig. 3, a further embodiment is shown as a roller screen. It consists of a suf the role with the help of a spring balancer, not shown 23 windable lead rubber piece 24.

similar to the diaphragm arrangement shown in FIG also this diaphragm by means of a tab 25 through the cassette 7 into the beam path drawn into it. The dominant opening 9 is arranged in the center of the diaphragm.

It is of course also possible within the scope of the invention to use the diaphragm at the same time to use as a mounting device for the cassette or the cassette rear wall train yourself / so that it can serve as a screen.

Claims (9)

Claims X-ray diagnostic apparatus with an X-ray image intensifier, a Bellohtungsautomat and a holding device arranged near the X-ray image intensifier for Introducing an X-ray film into the X-ray path so that it is not possible nz e i c h n e t that when using the X-ray image intensifier (5) as a radiation measuring device or as part of the radiation measuring element of the X-ray exposure machine (16, 17), respectively before the start of recording an X-ray absorbing plate (8) for the duration the inclusion in the beam path between the X-ray film (7) and the X-ray image intensifier (5) can be introduced whose surface area is equal to or greater than the cross-sectional area of the cone of rays at the insertion point, and the one radiolucent opening (9) in the size of the desired measuring field (dominant). 2. X-ray diagnostic apparatus according to claim 1, characterized in that that the radiation-absorbing plate is divided into individual lamellae (19, 20, 21) which can be inserted telescopically into the beam path. 3. X-ray diagnostic apparatus according to claim 1, characterized in - characterized that the radiation-absorbing plate is made of flexible material, which according to Art a roller shutter can be introduced into the beam path. 4. X-ray diagnostic apparatus according to one of the preceding claims, characterized duroh means for moving the position of the measuring fields within the Cross-sectional area of the cone of rays. 5. X-ray diagnostic apparatus according to one of the preceding claims, characterized in that the radiation-absorbing plate has several mesa fields which can be optionally closed with a slider .s. 6. X-ray diagnostic apparatus according to claim 1, characterized in that that the radiation-absorbing plate is formed from overlapping lamellae, those from different directions from the outside to the center of the plate to be freely selectable Amounts are shiftable. 7. X-ray diagnostic apparatus according to one of the preceding claims, characterized in that the panel with the holding and insertion device is coupled in such a way that the diaphragm and cassette can be introduced together into the beam path and can be removed from the beam path. 8. X-ray diagnostic apparatus according to one of the preceding claims, characterized in that the radiation-absorbing plate itself as in the Beam path retractable cassette holder device is formed. 9. X-ray diagnostic apparatus according to one of the preceding claims, characterized in that the radiation-absorbing plate the X-ray radiation outside the dominant only weakens so far that a co-observation of the recording Over the entire recording area by means of those available for fluoroscopy Facilities possible.