DE940775C - Device for the production of fluoroscopic images of body sections - Google Patents

Description

ISSUED MARCH 29, 1956

N 5082 VIII c / 2ig

By applying a certain technique, x-rays can be obtained with particularly low levels Depth of field can be established. X-ray machines that are well suited for this purpose differ differs from devices for producing conventional X-ray images in that during the production of the Recording the radiation source is shifted, e.g. on a plane lying in one plane, to the image to be imaged Layer parallel orbit. At the same time, the image carrier parallel to the section to be depicted is displayed in moves in the opposite sense in such a way that the during a recording through any point The X-ray beam that travels the section to be imaged remains at the same point on the image carrier meets.

A device of this type is also used for fluoroscopy. The image carrier exists thereby from a fluorescent screen, and with the aid of one from a mirror or at least an appropriately moved optical system consisting of a lens can be accomplished be that the optical image is in the opposite sense as the image of the moving Image carrier moved so that this apparently remains at rest.

The device according to the invention is also used to produce fluoroscopic images thin sections using a moving x-ray source and die X-rays intercepting immovable image

carrier; it can be used for both medical examination as well as for material testing. According to the invention, the X-rays act collecting image carriers together with an electron-optical imaging device, which is provided with means through which the moving image is transformed into an immediately visible one - Image is converted which is at rest to the eye of the observer.

ίο When using an electron optical Reproduction device for amplifying X-ray fluoroscopic images it is known to use the photoelectric cathode generated by X-rays in a suitable image layer To activate luminescent light to emit electrons, the photocathode is attached in optical contact with this image layer.

To the means used according to the invention »ο for converting the moving to the Image carriers projected into a stationary image include electrostatic or magnetic Fields that are applied transversely to the direction of the electron beams from the photocathode. she should be the electron paths extending between the photoelectric cathode and the protective screen turn. The electrostatic deflection fields can with the help of at least a pair of parallel plates between which tension is maintained. The plates of each pair are arranged on either side of the electron trajectories. For the magnetic Fields magnetic coils can be used, two of which each jointly generate the field Coils arranged for deflection in a single direction on both sides of the electron path are. The deflection of the electron beam can be achieved by changing the voltage between the Plates or the excitation current of the coils changed according to the shift in the X-ray image will.

A particularly well-suited embodiment of the invention results from the use of a stationary X-ray tube with a moving focal point. A stationary X-ray tube whose focal spot is moved by deflection of the X-ray generating electron beam electrostatic or magnetic with the aid fields across the anode surface, is known and has also been used for ¹ Preparation of the body section images with a moving image carrier. By coupling the regulating organs that change the strength of these deflection fields with organs for regulating the strength of the deflection fields in the X-ray image intensifier, an exact correspondence is achieved between the displacement of the focal point in the X-ray tube and that of the intensified X-ray image. In addition, the displacement can take place at great speed, in that no inertia forces have to be overcome, as is the case when using a device with mechanically moved individual parts.

The invention is explained in more detail in the drawing, for example.

Fig. Ι represents the schematic arrangement of the most important individual parts of a device of the invention with a movable X-ray tube, and

Fig. 2 shows the same device with an X-ray tube with a movable focal point.

With the aid of the X-ray beam 2 supplied by the X-ray tube 1, a Silhouette of a part of the object 3 on the image layer 4. This lies on the flat floor 5, which closes one end of the cylindrical glass tube 6. The other end of the glass tube is closed by a wall 7, which is also flat. A fluorescent screen 8 is located on it.

The image layer 4 consists of a material that emits luminescent light when it is from the X-rays is taken. A photoelectric cathode 9 is attached to the image layer 4. It consists of a material which is produced in the image layer 4 under the effect of Light emits electrons. It is known that a corresponding mapping of the photocathode image can be generated on the fluorescent screen 8. An electric acceleration field ' and an electron optical lens 90 can be used. The lens field is controlled by the Magnet coil 10 is generated. The acceleration field is generated in that on the inner wall of the Tube 6 a conductive coating 11 is attached, which extends up in the vicinity of the photoelectric Cathode extends, and that an electrical voltage is applied to the photocathode. Preferably the fluorescent screen 8 is attached to a thin, transparent, conductive layer, which is electrically connected to the conductive covering 11.

An image of the sectional layer 12 of the object 3 is produced by moving the X-ray tube 1 between the two outermost layers α and b, indicated by dashed lines in FIG. The focal point of the tube 1 does not necessarily have to perform a rectilinear movement, but can, for. B. describe a circular or spiral path in a plane parallel to plane 12 of the body section.

When moving the X-ray tube 1 move the shadow images of parts of the body 3 that are within the cone of rays on the Since it is not shifted, the image layer 4 lies in the opposite direction. Move at the same time the electron images drawn on the photocathode 9 also change. As a result, would moving images can also be designed on the fluorescent screen 8. To cancel the movement the image of the parts lying in the considered section of the object become deflection fields used for the electron beams. If the tube is moved in a straight line, it becomes electrostatic or magnetic cross field is required. In the device of Fig. 1 is magnetic

Distraction used. One of the coils 13 of the required Coil pair is indicated by dashed lines. With the help of the X-ray beam When the X-ray tube 1 assumes the neutral position, an image 15 of the image layer 4 is produced Arrow 14 designed with the aid of the photocathode 9 by electron optical projection is transferred to the luminescent screen 8, and is indicated there by the arrow 16. Move in the process the electrons from the photocathode on paths that hit the screen in points, whose distance from the tube axis is proportional to that of the starting points.

When the X-ray tube 1 assumes the position α , the image of the arrow 14 is shifted upwards. So that the image on the luminescent screen can still be observed even with rapid movement, it must be ensured that it coincides with the image 16. This can be achieved in that the deflection coils 13 are excited in such a way that the electron paths are deflected by the correct angle under the effect of the generated magnetic field. The strength of the deflection field must now be changed continuously during the displacement of the X-ray tube. For this purpose, a regulating device for the coil current can be coupled to a movement device for the X-ray tube and, as a result, the change in current in the coils 13 can be derived from the movement of the X-ray tube.

When the X-ray tube 1 is moved into position b , the deflection coils 13 must be excited in the opposite direction. Parts of the object that lie in front of or behind the section indicated by the arrow 14 are not imaged in focus, but instead form a blurred background when the X-ray tube is moved sufficiently quickly, from which the image of the section to be imaged stands out sharply.

If a section closer to the X-ray tube or further away from it is to be sharply imaged, so only the strength of the field generated by the solenoids 13 has to be changed between other limits will. By regulating the field strength of the deflection field, it is possible to achieve the desired Cut the object 3 to focus on the luminescent screen 8 without a shift of the object opposite the X-ray tube is required.

The more the X-ray tube moves, the more blurred the background of the image becomes. It is therefore preferable to move the X-ray tube in a circular, closed path. For this purpose, a second set of deflection coils is arranged in the image intensifier at an angle of 90 ^° to the axis of the field generated by the first coils. By combining the deflection fields, when the coils are excited by ^{alternating currents phase-shifted by 90 0,} a composite deflection field is created whose field vector moves with the X-ray tube if the polarity of the excitation currents is appropriately selected. It brings about the desired deflection of the electron beams, which brings about that the fluorescent image of the section of the object remains at rest.

In another embodiment of the device according to the invention, which is shown in FIG is, there is an advantage that the image layer does not move and that when stopping the on electron-optical Paths generated fluorescent screen image no inertia forces occur, better exploited. It will an X-ray tube 17 with a movable focal point on the anode is used. The movement of the Focal spot results from the fact that the electron beam generating the X-rays is deflected will. In this case, the X-ray tube does not need to be moved.

According to Fig. 2, the X-ray tube 17 consists of a glass vessel 19 which is provided with a nozzle 20. This contains one from the cathode 21, the concentration electrode 22 and the acceleration electrode 23 existing electrode system to generate a directed electron beam. Between the acceleration electrode 23 and the A large potential difference is applied to the anode 18 arranged in the large part of the tube. A Holding member 24, which is connected to the tube wall, is used to fasten the anode 18 with the aid an electric field between the plates of the pair of deflection plates 25 can generate the electron beam deflected and the point of impact of the electron beam shifted over the anode surface will.

The X-ray tube is arranged in such a way that the surface hit by the electrons is parallel zürn is to be mapped section 26, which is indicated by a dashed line. On the from the side facing away from the X-ray tube, the image intensifier 27 is arranged, which corresponds to the above discussed device can be formed. Fig. 2 shows a device with electrostatic Focusing the electron beams. The one with the image layer to collect the X-rays combined photocathode electrons move through one in the Small opening 30 after the fluorescent screen 31. The anode tube contains the pair of baffles 32.

As a result of the application of an alternating potential difference between the plates 25 of the X-ray tube 17 the focal point moves in a straight line from top to bottom and vice versa over the surface of the anode 18. The movement of the image, which occurs through the combined image layer-photocathode 28 arise through electron-optical projection on the luminescent screen 31 would, by applying a suitable alternating potential difference to the plates 32 canceled.

The required deflection voltages are taken from a voltage divider 33 connected to a Voltage source 34 is connected. This is provided with terminals 35 for connection to the feed network. In the simplest case, the voltage source 34 consists of a transformer for conversion

the mains voltage into a desired deflection Value. However, it can also be designed as a frequency converter or as a pulse generator be.

To generate symmetrical deflection voltages, the center 36 of the voltage divider 33 is electrical connected to the cathode 22 of the X-ray tube 17 and to the anode 29 of the image intensifier 27. the Plates 32 are electrical with adjustment members 37 and deflector plates 25 with adjustment members 38 connected to the voltage divider, reducing the deflection fields in the X-ray tube and are coupled to the image intensifier and also enables precise setting of the two field strengths will.

Claims (4)

Patent claims: 1. Device for the production of fluoroscopic images Thin cuts through objects for medical examination and material testing with one in one plane lying path of movable X-ray source and an image carrier, which the X-rays catches and is immobile, characterized in that the image carrier with a cooperating electron-optical imaging device provided with facilities is through which the moving X-ray image on the image carrier in a direct visible image is converted, which is at rest to the eye of the observer. 2. Apparatus according to claim 1, wherein the electron optical imaging device with a photoelectric cathode attached to the image carrier and with a fluorescent screen is provided, which is arranged at a certain distance from the photocathode, thereby characterized in that at least one transverse field is effective over part of this distance, which deflects the electron orbits in such a way that the moving through the photocathode of a ' lent image emitted electron stream the luminescent screen as before in the same place meets. 3. Apparatus according to claim 2, characterized in that between the devices for moving the X-ray source and for regulating the field strength for the deflection fields there is such a coupling in the image intensifier that the effect of the deflection field on the Electron beam changes according to the movement of the radiation source. 4. Device according to one of the preceding claims, characterized in that it with an x-ray tube having a large surface area anode and with facilities is provided for deflecting the electron beam, the excitation of which is taken from a voltage source which also provides the excitation of the deflection means with which the image intensifier is provided. Referred publications :.
German Patent No. 726 595;
French Patent No. 876 016;
Austrian Patent No. 152 528;
U.S. Patent No. 2555545;
Röntgenblätter, 1949, pp. 163 to 167. 1 sheet of drawings 1 509 682 3.56