DE2628438C3 - Process for producing multicolored x-ray images - Google Patents

Description

The invention relates to a method for producing multicolored x-ray images, in which one to be imaged Object one after the other, each with a pulse of X-rays of different types with regard to their spectral Composition on different pieces of the same black and white recording material, in particular a coherent film, is recorded, with possibly a luminescent screen and / or a Vei strengthening device is interposed, and the Recordings are processed into monochrome images of different colors and the images become one multicolored image can be combined.

Such a method is known from AT-PS 1 74 995. The earlier US-PS 20 40 685 describes a similar procedure. There are compared to other known methods in which the monochrome Images simultaneously on one behind the other arranged by different types of shielding foils from one another separate photographic layers are recorded (DE-PS 9 70 220, DE-AS 10 13 960) the advantages, that the division into the various spectral ranges is complete and that the radiation exposure of the

2c object is significantly lower different types of X-ray radiation can be selected and adjusted independently of one another, with very narrow-band wavelength ranges can also be used without mutual overlap. With these independent definitions of the types of radiation, much narrower ones can be made Depict areas of the absorption scale with high contrast as a color scale than in the case of processes with one after the other arranged photographic layers, and since the entire radiation can be used actinically, it is possible to get by with very small doses of radiation - an advantage that is particularly useful in diagnostic examinations living tissue is meaningful. The equipment and labor required for production multicolored x-ray images by the specified method is very considerable. This effort is just then portable if one uses the method in the manner of screening tests at a high working speed can perform. It must be obtained with a chosen set of operating parameters Work results correspond to an unchanged standard even over longer operating times. One for combination of high operating speed and high uniformity of the Work results have not yet been achievable, mainly because of the relatively complex color photographic Operations.

The invention is based on the object of a likewise working with low radiation exposure of the object Specify a method for producing multicolored x-ray images, which in serial examinations with little Effort and high working speed automatically and with high uniformity of the Results can be done.

According to the invention, this object is achieved with a method of the type specified above, which is characterized in that the black and white recordings with single-color recording material of each assigned color are further processed and that for further processing all types of single-color recording material be treated in a manner known per se with the same developer.

With the method according to the invention one can get by with very simple development devices, since monochrome recording material is commercially available, its processing and especially development is even easier than with normal black and white recording material, and there for all different types

of the monochrome recording material is the same developer is used. The effort is considerably less than for further processing with normal multicolor slm. The development process takes place more quickly and there are also numerous possibilities for errors are caused by the complicated working methods of the usual color film development. Besides, this is The resolution of the single-color recording material is better than that of conventional multicolor film.

In the method according to the invention, the number is ι ο the parameters influencing the photographic development process are stronger than conventional techniques reduced This offers considerable advantages for the standardization of the admission and development conditions, The prerequisite for this is that there is an improvement in the diagnostic possibilities at all is obtained. Also for the speed of processing and thus for the economic efficiency of the process Isv the method of operation according to the invention is crucially advantageous Automate procedures to a large extent. This also applies to the one-color illustrations necessary steps, i.e. the successive exposure with corresponding further transport of the black and white recording material, as well as the development of this black and white recording material and its further processing with monochrome recording material including its development in one common developer for all types of single-color recording material. There is one that goes even further Simplification and acceleration of the process flow possible in that the single-color recording material is developed by a single washing process; such processable single-color recording materials are commercially available.

A further improvement is possible in an embodiment of the invention in that the black and white recordings are made first processed to black and white enlargements and then through these enlargements Copying the monochrome images onto monochrome recording material of the respective assigned color manufactures. As a result, larger image formats are obtained, which are favorable for the evaluation, and the fact is borne out Bill that the commercially available monochrome recording material normally uses ultraviolet light must be exposed, so in enlargers, which for optical reasons with as possible small light sources have to work, cannot be processed.

When using single-color recording material with high contrast, it is advisable to preserve the Shades of gray to use a fine optical grid.

The method according to the invention is also suitable without further ado for lower degrees of automation. in the In general, however, it is recommended to use at least the ones required to produce the single-color images To bring steps to the process automatically, because then operating errors and evaluation errors are largely excluded. A compulsory assignment between the types of X-rays eo and the types of single-color recording material can be achieved very easily by the fact that for automatic selection of the types of single-color recording material depending on the type of material used X-ray type on the black and white recording attached coding is read.

For extensive automation of the method according to the invention, it is useful if the Inking recording materials in the form of a single Films are used on which the single-color recording materials the different colors are provided in sections. If the procurement or Manufacture of such a film material presents difficulties, or one less for other reasons If extensive automation is sufficient, the single-color recording materials of the various I use colors in the form of a film.

For diagnostic purposes in particular, it is often recommended that in addition to the black and white recordings a photograph of the surface of the object is produced and assigned to the multicolored image. From such a surface recording, which can of course also be used for identification purposes, often draw additional diagnostic conclusions. This is especially true when selected with photography Spectral ranges, in particular infrared, are preferably mapped.

The invention is described below with reference to exemplary embodiments in conjunction with the drawings described in more detail. It shows

IA and IB show a very schematic representation to explain the method according to the invention,

FIG. 2 is a schematic plan view of an intermediate film which, in the case of the according to FIGS. IA and IB ongoing procedure is used, and

F i g. 3 shows a schematic explanation of a modified embodiment.

According to Fig. IA and IB is a device for medical X-ray diagnosis built on a foundation 2 and contains an X-ray source 4, which is surrounded by a shielding housing 6. For the exit of the imaging X-ray beam 8 is a window 10 is provided in the housing 6. As is common with medical X-ray machines, the Window 10, a filter 12, for example in the form of an approximately 2 mm thick shielding plate, can be provided, to intercept physiologically harmful or undesirable soft radiation components. In the beam path of the beam 8 emerging from the window 10, an examination station 14 is provided at which the Object 16 to be examined, here the abdomen of a person 18, of which a colored x-ray image is to be made, is arranged. The object 16 is normally with the usual (in FIG. 1 not shown) aids fixed. Behind the examination station 14 there is one on an adjustable table 20 photographic recording device 22 is provided. This includes a camera 24, which is on a behind the Examination place 14 arranged fluorescent screen 26 is set with an amplifier device 28 and the shadow image of the object 16 generated by the beam 8 on the luminescent screen 26 on an image field 30 images of a photographic recording material processed in the camera 24. The table 20 is means a servomotor 32 in a horizontal guide 34 transversely to the object 16 and by means of a servomotor 36 in a vertical guide 38 adjustable in height. On the table 20, a bracket 40 is attached, which with an arm 42 in front of the examination station 16 and for displaying the object area to be imaged serves. In the illustrated embodiment, the arm 42 carries a mirror 44 via which one on the The projection light source 46 attached to the cantilever 40 creates a field on the object 16 that defines the image area illuminated. In addition to the light source 46 is an auxiliary camera 48 with its own lighting device,

preferably in the form of a ring lamp 52 placed around the lens 50 of the auxiliary camera 48.

The photographic recording device 22, in particular the camera 24, is set up for processing black-and-white recording material. This is unwound in the usual way as film 54 with the aid of a camera motor 56 from a supply reel 58 and pulled through deflection rollers through an encoder 60 and a film carrier 62. The film 54 is preferably perforated, and its transport length is detected with the aid of a sensor 64, preferably in the form of a wheel engaging the perforation. The exposed film passes through a bellows 66, which compensates for the vertical movement of the table 20, in a ^'5 Entwickiungsaulomaten 68, and is developed there, fixed and dried. The dry fused film is advanced through a black and white enlarger 72 by a drive 70. The drive is controlled by a code reader 74 which evaluates the code applied to the film 54 by the coding device 60 as a position signal.

In the magnifying means 72 that is, co- on the film 54, for example, 70 mm film, image on large-sized black and white photograph Material - piert "> This forms here an intermediate film 76, which is subtracted from a drive 78 from a supply reel 80th A second coding device 82 also belongs to the enlargement device 72. It provides the intermediate film 76 with a coding which designates the position and the origin of the enlarged copy produced in each case, that is to say takes over the information entered by the coding device 60 of the camera 24. The exposed intermediate film then passes through a second black ^{and white J5} and white automatic developing device 84 where it is developed, fused and dried. The intermediate located on the intermediate film 76 are therein positive is copied onto color recording material 92 of the same format, which is present here in the form of a film and is drawn off from a supply reel 96 by means of a drive 94.

As in Fig. 2, the color-receiving material% consists of a transparent carrier film 98 on which single-color emulsion layers for the basic colors used are applied in a repeating order, that is to say normally as in FIG. 2 shown for the three primary colors gelh. cyan and magenta. In the case of the FIG. In the example shown in FIG . 2, uncoated interspaces 100 are also present. The recording material also carries a Kodespur 102 with information about the location and type of coating The Kodespur 102 is read 104 (Fig. IA) of a code-reading device which controls inter alia the drive 94 is preferably additionally also a on the information in the Kodespur 102 precisely aligned perforation 106 ^{w is} provided in order to facilitate the mechanical handling of the recording material 92. An ultraviolet light source 108, which is controlled via a switching device 110 , is used to expose the recording material 92.

The information applied by the first encoder 60 of the camera ^b5 24 to the first film 54 is transferred in the enlarger 72 to the intermediate film 76 and in the color copier 90 to the color recording material 92 used therein and appears on this after development as legible information about the respective picture.

From the exit of the color copier 90, the intermediate film 76 is fed to a take-up spool 112 . The color receiving material 92, after passing through the color copier, is passed through a monochrome film developing device 114 and developed, fixed and dried there. As explained at the outset, this developing device 114 can be a very simple washing device, since the color recording material 92 in its spatially separated coatings represents a single color recording material. The developed recording material 92 is cut very precisely into pieces in a cutting device 116 under the control of a reading device 118 reading the code track 102 , each of which contains an inking image 120, 122, 124 etc. in register with one another. If a transparent recording material 92 is used, these single-color images can be placed one on top of the other in a holder 126 ensuring register accuracy and viewed as a multicolored overall image in transparency (light source 128) or processed further on conventional multicolor recording material. A registering holder is expediently supplied with each set of associated single-color images 120, 122, 124

It goes without saying that the films used between the individual parts of the device are, as usual, in Loops are made to compensate for differences in the individual transport processes. This is only indicated by dashed sections in FIG. 1A.

In order to obtain congruent images in the successive recordings in spite of the pulsating movement of the object 16, a blood pressure signal is picked up with a blood pressure cuff 131 and processed in a blood pressure signal transmitter 133 to a control signal that in a precisely predetermined phase the blood pressure. Curve occurs This ensures that the recordings made one after the other are made with the same blood pressure loads and thus the same dimensions as possible.

The X-ray source 4 is based on X-ray types of different spectral compositions switchable. For this purpose, an X-ray generator can be provided in the simplest case, which on different types of the X-ray radiation emitted by it can be switched in particular it is a common X-ray tube that can be switched to different acceleration voltages and / or has switchable filter attachments. However, it can be difficult for everyone One and the same beam geometry must be ensured. Difficulties of this kind are fundamental avoided if, as in the embodiment according to FIG. 1B for the different types of rays provides separate x-ray generators which alternate in relation to the examination station 14 geometrically-optically equivalent working positions can be moved. This also gives you spectral compositions and intensities greater possibilities for variation.

The embodiment according to FIG. 1B uses three X-ray flash tubes 130, 132, 134 as the X-ray generator. These are designed as a turntable

th indexing table 136 arranged in certain assembly positions so that they can be obtained by rotating the indexing table 136 can optionally be moved to the position shown in FIG. 1B just taken by tube 130 will. In the illustrated embodiment, a turntable is used, which is about a horizontal axis 138 is rotatable. In addition, the turntable 140 is a predetermined stereo distance in the direction thereof Rotation axis 138 displaceable, so that one and the same set of X-ray tubes 130, 132, 134 for both stereo positions can be used. A motor 140 is used to drive the indexing table 136 about the axis 138 provided, and is used for adjustment in the axial direction between the two stereo positions Drive 142.

Thus the working positions of the X-ray generator in relation to the geometry of the imaging process can be made completely the same, are adjustable correction means for the assembly positions the X-ray tubes are provided, namely here are the: <i Tubes can be displaced in brackets 144 and can be fixed by means of adjusting screws 146. The brackets 144 are in turn adjustable and fixable on the indexing table 136, for example by means of the in FIG. 1B indicated fastening screws 148 in elongated holes 150.

The switching positions of the indexing table 136 are provided by (preferably adjustable) cams 152, 154, 156 Are defined. These cams form stops for an armature 158 of a controllable locking device 160. In addition, a sensor 162 for codes 164, 166, 168 is located outside the path of movement of the cam the indexing table 136 is provided; these codes report the respective switch position.

From the required power supply lines to the tubes are shown in FIG. 1B only the leads 170, 172, 174 for the acceleration voltages are indicated schematically. They begin in contact pieces 176, 178, 180, which come into contact with a sliding contact 182 of a high-voltage generator 184 in the respective set working positions. In Fig. IB it is indicated schematically on the high-voltage generator that it can be switched to three different acceleration voltages, which are designated with g, c, m (corresponding to the colors yellow, cyan, magenta).

A programmer 186 is provided to control the entire system Selector switch 188 can be set to various useful workflows and this upon actuation a trigger 190 automatically runs. so

The X-ray tubes 130, 132, 134 have anticathodes made of various materials, for example molybdenum, chromium, iron, tungsten, and they are filters 192, 194, 196, which are made of the respective anti-cathode material or a material from adjacent Ordinal number exist. As a result, the bremsstrahlung can be strongly suppressed, so that the tubes emit predominantly the characteristic natural radiation of the respective anti-cathode material. One As far as possible monochromatization of the «> radiation is often useful in order to make it more meaningful and Increase the amount of detail in the multicolored images that are finally obtained. This is especially true when one closely spaced spectral ranges are used

A conventional shutter 198 is used to trigger the camera 24 Auxiliary camera 48 can be brought into the recording position, the projection light source 46 and the Auxiliary camera 48 can be moved back and forth in a guide 202 by means of a drive 200. To measure the Effective radiation intensity, a dose meter 204 is provided, which is used in particular to measure due to an attempt to set the correct aperture and / or exposure time of the camera 24. It is natural it is also possible to automatically control the exposure time and / or the aperture of the camera 24 in To be provided depending on the signal from the dosimeter 204, but generally only then required when very different types of objects are to be examined immediately one after the other. It may also be necessary to use the aperture and / or exposure time of the camera 24 together with the switching of the X-ray source 4 to change. The facilities required for this are not shown in the figures, since it is possible for any person skilled in the art to use such devices to create without further ado.

The device shown in Figs. IA and IB works as follows:

The table 20 is adjusted with the servomotors 32 and 36 so that the projection light source 46 the The area of the object 16 to be imaged is illuminated. The X-ray source 4 is located in the one shown in FIG. 1B shown state, so with the tube 130 in the working position. It is also assumed that the The tubes mainly emitted wavelengths of X-rays in the order of the tubes 130, 132 and 134, and that in that order the images produced by the tubes in the Colors should be displayed in yellow, cyan or magenta. The operator has at the selector switch 188 of the programmer 186 selected the corresponding program. The actuation of the trigger 190 then initiates the automatic control of the entire system according to this set program. In general, this automatic control will be a sequential control, i. H. that each sub-step of the entire procedure initiates the next sub-step upon completion triggers the design and execution of such controls are familiar to those skilled in the art, so that a closer look at Explanation is omitted here; instead, only the sequence of the individual sub-steps is shown here described, and it is understood that the various actuators such. B. the camera motor 56, the switching of the high voltage source 184, the indexing table motor 140, the stereo drive 142, the auxiliary camera drive 200 and the drives 70, 78, 86, 94 etc. as well as the corresponding electrical switching operations for the exposure control in the Enlarged & cirifichiüfig 72 and in the color copier 90 automatically take action at the right times.

As soon as the trigger 190 is actuated, the drive 200 pushes the auxiliary camera and the projection light source 46 to the right, so that the auxiliary camera 48 previously illuminated by the projection light source 46 Can record area of the object 16 photographically. The ring light 52 is switched on and the Auxiliary camera 48 is triggered. At this point in time at the latest, the indexing table 136 is activated by the motor 140 in the in F i g. 1B moves in the position shown the tube 130 is in the working position. The sensor 162 reports to the high-voltage generator 184 and the Encoding device 60 of camera 24 that the tube 130 is ready, so next that recording

which is to be processed into a yellow image. The high voltage generator 184 sets the acceleration voltage to be output by it to the value required by the tube 130 a. The coding device 60 prints corresponding information and a serial number on the Pieces of the film 54 belonging to the image field 30. As soon as this has happened, the camera shutter 198 is opened, and the high voltage generator 184 applies a high voltage pulse to the flash tube 130. The tube 130 then sends out a corresponding X-ray pulse. Immediately afterwards the camera shutter is activated 198 is closed and the camera motor 56 is turned on. The film 54 turns to one Image spacing advanced, controlled by feeler 64. At the same time, armature 158 becomes temporary withdrawn, and the motor 140 rotates the turntable 136 into the next switching position in which the Tube 132 is in the working position instead of tube 130; this new position is due to the stop of the Cam 154 on the anchor 158, which has meanwhile been extended again into the locking position. The tubes are set in their holders 144 so that their beam exit points 204 are exactly in the working position are the same. It goes without saying that for the diagnostic purposes mainly envisaged here the beam exit point must be as punctiform as possible, and the tubes are accordingly educated. Since this is part of the long-known state of the art, a more detailed description is given here waived.

The sensor 162 reports to the high-voltage generator 184 and the coding device 60 of the camera 24, that now the tube 132 is ready. The encoder 60 then prints a corresponding one Information and again a serial number on the film 54, and the recording with the tube 132 runs in the same manner as described above for tube 130. Finally follows in the same way Recording with the tube 134, and then the X-ray source 4 remains switched off and must for a new set of recordings is only started again by actuating the trigger 190 again will.

If the recordings are made at specific points in time during a periodic movement of the object 16 must be made, a corresponding control must be provided. In Fig. IA is an example of this indicated that a blood pressure signal generator 133 processes a blood pressure signal from a blood pressure cuff 131 is delivered on the arm of the person being examined. The blood pressure transducer 132 triggers the recording, for example, at the peak blood pressure values at which the Movement speed of the perfused organs passes through a minimum of course also can any intermediate values between maximum and minimum blood pressure triggering the admission be used.

When more than one of the processes described has been completed, the primary film is black and white 54 consecutive sets of three shots each, each in monochrome images of colors yellow or cyan or magenta should be processed in this order. The exposed film drifts through the black and white developing device 68 and thereafter fixed and dried in sequence Slide positives through the enlarging device 7Z. In this, the code reading device 74 controls the drive 70 of the film in such a way that the drive 70 is stopped as soon as one of the ones on the film 54 is located Black and white slide positives are in the correct position for enlargement. The enlargement process is then triggered, in particular by switching on a light source (not shown), and there will be a corresponding piece of the at that time in the Magnification device 72 exposed intermediate film 76. The second encoder 82 prints a corresponding information on the intermediate film 76, and by the drive 78 is then the intermediate film is advanced by a predetermined piece, so that a piece that has not yet been exposed to Enlargement is ready. In this way, the exposed intermediate film 76 travels through the second black and white developing device 84 and finally reaches the color copying device 90. The code reading device 88 provided there holds the associated Drive 86 on as soon as one of the slide negatives developed on the intermediate film 76 is in the copy position is located. At this point, the encoder 104, which is simultaneously on a Code track 102 (F i g. 2) of the color recording material 92 responds, the drive 94 stopped so that in the Color copier 90 exactly in one of the coated portions of the color receiving material 92 Copy position is located. The code reading device 88 of the developed intermediate film 76 reports to the drive

w 94 of the color recording material, to which color the enlarged slide positive located in the color copier is to be copied. If this desired color does not match the color that can be achieved with the coating of the color receiving material 92 lying in the copying position, the drive 94 continues to run until the correct coating is in the color copying device 90. As soon as the desired correspondence between the desired color and possible color has been achieved, the coding device 104 prints information on the color recording material 192; as a result, the primary information about the object is essentially passed on. In the further course of the process, the exposed color receiving material 92 passes through the color developing device 114 and leaves it in the form of a series of partial images developed into the corresponding colors. The code reading device 118 of the cutting device 116 then ensures that a related set of image sections

so exactly in congruent one-color pictures 120,122 and 124 is cut up. These single-color images are then placed in the holder 126 in Registration brought so that with the lighting device 128 a sharp, multicolored overall image can be viewed. It goes without saying that the Transfer of the single-color images 120, 122 and 124 to the holder 126 can be automated; in particular it is also easily possible to design this holder only in the manner of a slide frame, that is to say without a source of illumination 128, so that the user can adjust the bracket with the superimposed monochrome images in the same way can handle like a normal multi-colored slide positive. Of course, you can also use the one on top of the other Copy or enlarge single-color pictures onto normal multi-color film, yes this will generally not be necessary; It is particularly important to note that the consideration the individual single-color images are valuable in themselves

can provide diagnostic information.

The photographic processing steps described can of course also be carried out with a lesser degree of automation are executed. In the simplest case, all processes can also be triggered manually, i.e. do without the sequence control or program control described. A sufficient one for many purposes The degree of automation already exists if only the processes up to the development of the primary Black and white recording material or film 54 with the sequence control described automatically to / \ run out and the developed, fixed and dried film 54 is then cut into pieces, which are further processed by hand. It goes without saying that the black and white Auf- ι ϊ Use receiving material, shown in Figure 1A as intermediate film 76, in the form of individual sheets can. There is also a very significant simplification when you switch to the automatic execution of the Operations in and after the color copier 90 are dispensed with. It does not then need the above Special monochrome recording material 92 is used with successive different coatings to become; instead, the monochrome recording materials commercially available in sheet form can simply be used can be used, on the other hand it can easily be automated.

A further simplification is possible by focusing on the intermediate film 76, that is to say on the enlargement of the recording format, waived This means that the primary recording material 54 directly on the monochrome recording material is copied. In many cases, this way of working will deliver fully satisfactory results, especially if an enlarged view of the single-color Bikier obtained is planned anyway hen is such. B. in a slide projector.

F i g. 3 explains in a very schematic representation a modification in which instead of the color recording material shown in FIG different coatings three uniformly coated single-color recording materials 476a, 4766, and 476c can be used. These recording materials are in the form of films from Supply rolls 496d or 4966 or 496c unwound They each run through a partial hard copy device 490a and 4906 and 490c, respectively. These partial color copiers are successively removed from the fixed and pass through dried intermediate film 476. The coding located on the intermediate film 476 is from Read code reading devices 488a or 4886 or 488c. For the monochrome recording materials are Coding devices 504a and 504b and 504c are provided. JZine drive device 486 transports the Intermediate film 476 by the partial color copiers. As soon as an image in a set of related black and white images on the intermediate film 476 the partial color copying device intended for the assigned color has entered the copying position, the drive 486 is stopped and the black and white image is transferred to the underlying piece of the relevant single-color recording material is copied. At the same time, the associated coding device stamps a corresponding information on the monochrome recording material is then this recording material is transported further, and at the same time the intermediate film 476 is also transported further until the next one Black and white image from the same set in the copy position of the partial color copier intended for its color has arrived. Then the drive 486 is stopped again, the copying process in question executed, the relevant single-color recording material is encoded with the appropriate information and advanced, and the intermediate film 476 is transported on again until the last black and white image is registered with the associated partial color copier stepped. The copying process is then carried out there. The exposed single-color recording materials are activated, washed and in one and the same coloring developer 514 dried, and it is then cut from it by cutters 516a, 516b and 516c Control by code reading devices 518a or 5186 or 518c the single-color images 520 or 522 or 524, which are then viewed in the manner described or copied onto multicolor film or can be enlarged. It goes without saying that even in the device according to FIG. 4 without an intermediate film can be worked; in this case, instead of the intermediate film 476, that is directly from the camera to use upcoming black and white footage.

The mutual couplings between the switching processes in the X-ray source, the recording processes in the camera and the photographic processing processes are essential for a reliable and, if possible, automatic execution of the method according to the invention. This mutual coupling or control is not only useful with a view to the greatest possible degree of automation, but also increases operational reliability and eliminates the possibility of confusion. The association between the X-ray device and the photographic recording device is particularly important. This assignment not only ensures that the switching of the camera is coupled with the switching of the types of x-rays, but the message which type of x-ray is available (which x-ray generator is in the working position) to the camera's coding device ensures that that the exposed Aufhahmemateriai is clearly provided with information about the X-ray source used for exposure. This coding is then used in the subsequent photographic processing for the register-keeping device and for the assignment of the correct single-color recording material in the color copier. so that it is ensured that a certain type of x-ray is assigned a certain color of the color recording material. The coding device dtr the photographic recording device ⁰ 'K5mcr? 0 also has the task of impressing other important information on the primary recording material, in particular about the identity of the object or, in the case of stereo recordings, via the stereo position. For the subsequent photographic processing (developing, copying, etc.), the information on the primary recording material is read by code reading devices as described and used for control purposes can be useful for reliable automatic control of the entire process; such details have been mentioned in the foregoing description.

For this purpose 2 sheets of drawings

Claims (9)

Patent claims: 1. Method for producing multicolored x-ray images in which an object to be imaged one after the other, each with a pulse of X-rays of different types with regard to their spectral Composition on different pieces of the same black and white recording material, in particular a coherent film, is recorded, with possibly a luminescent screen and / or a Amplifier device is interposed, and the recordings to monochrome images of different The colors are further processed and the images are combined into a multi-colored image are, characterized in that the black and white recordings with monochrome recording material the color assigned in each case has been further processed and that all for further processing Treated types of monochrome recording material in a manner known per se with the same developer will. 2. The method according to claim 1, characterized in that the single-color recording materials in Form of a single film can be used on which the monochrome recording materials of the various Colors are provided in sections. 3. The method according to claim 1, characterized in that the single-color recording materials of the different colors can be used in the form of a film. 4. The method according to any one of the preceding claims, characterized in that the Black and white recordings are first processed to black and white enlargements and from these Then enlargements by copying onto the monochrome recording material of the respectively assigned Color the monochrome images can be produced. 5. The method according to any one of the preceding claims, characterized in that the single-color recording material is developed by a single wash. 6. The method according to any one of the preceding claims, characterized in that the for Creation of the monochrome illustrations automatically brought to the process will. 7. The method according to claim 6, characterized in that for the automatic selection of the varieties One-color recording material one according to the type of X-ray used at the Black and white recording attached coding is read. 8. The method according to any one of the preceding claims, characterized in that in addition a photograph of the surface of the object and the multicolored image is assigned. 9. The method according to claim 7, characterized in that selected with the photograph Spectral ranges, in particular infrared, are preferably mapped.