DE2116668A1 - Improving readability of x-ray electro-photograph - by multicolour production - Google Patents

Abstract

Improving readability of X-ray electrophotograph by multicolour production. Image differentiation is achieved by developing the image in two or more stages with differently coloured toners, an accordance with the various potential differences which are present. Different voltages are applied to a counter electrode, the voltage applied forming the lower limit for the potentials of the photoconductor layer which attract toner powder.

Description

Method of Producing X-ray Electrophotography Die The invention relates to x-ray electrophotography and, more particularly, to a method for making X-ray electrophotographs in which the image reproduction or readability of the images is greatly improved by using the X-ray radiation Reproduces electrophotography in two or more colors.

In the known electrophotographic production of images with the help of X-rays create a photosensitive or photoconductive layer, by placing amorphous selenium on an aluminum base plate under vacuum vapor-deposited and the plate produced in this way then in a counter-visible Light shielded dark room with the help of a corona discharge device electrically charges, with the object to be photographed lying on the plate, whereupon this plate is "exposed" to X-rays. Those passing through the object X-rays irradiate the selenium surface with the appropriate dosage, which with increasing Absorption of the object on top decreases. Da-dias - electrical potential located on the surface of the selenium layer depending on the size of the dosage on the corresponding parts of the Selenium layer decreases or disappears completely when the X-rays hit it in this way an electrostatic latent image - of the inner structure of ee'S 'Gegenstanies can be generated on the selenium surface.

Now the latent image can be made visible by a polarity opposite to the electrostatic latent image electrically charged developer powder is scattered on the selenium layer, whereby the developer powder is attracted to the selenium surface with a distribution of the size of the surface potential at the corresponding parts of the selenium layer.

After you have made the latent image visible on a transfer sheet Od. The like. Electrostatically transferred, it is with the help of heat or a Steam solvent fixed, creating a permanent X-ray image of the recorded Object receives. So far, monochromatic powders have been used as developer powder with a powder grain size in the range of 5 to 20 / u in the colors black, blue or white is used, which is why the reading or evaluation of the image is due the density differences in the various image sections took place.

In X-ray electrophotography, the Eonotraste are des final image is much weaker than when taking pictures with the help of films made that have a coating of silver salsemulsion. on the other hand become the wanten or outlines of the objects taken because of the electrophotography own edge effect clearly developed, so that one can easily see or capturable image.

In other words, this means that when evaluating an image mainly monitored the contours of the captured object instead of that To evaluate the image of the object on the basis of the differences in density.

So although so far it has been possible to create the contours or outlines of a to determine the object to be recorded with the help of a monochrome developer the object of the invention is to create the possibility of these contours or To make outlines better and easier to see by adding color differences used.

To solve this problem it is proposed according to the invention, the visibility and readability of an X-ray electrophotography image by dividing the image into a variety of sections-accordingly the difference in produced by the dose of absorbed X-rays Electric surface potential divides, wherein one image portion developer powder with two or more colors while applying to a portion of the image with a another surface potential applies developer powder with any other color, whereby the internal structure of an object due to color differences that can be achieved by the color mixing principle or different coloring principle, is made clearly visible.

These and other objectives, features and advantages of the invention result from the following description and claims.

In the drawing a husführungbeispiel the invention is on hand some sketches indicating the individual process steps are shown, namely shows Fig. 1 is a schematic representation of the electrical charge a photosensitive or photoconductive plate using an Eorona discharge device, Fig. 2 shows the irradiation of a cassette containing the photosensitive plate contains, lying object with the help of X-rays, Fig. 3 and 4 the ansk iessenden process steps of the invention according to the development of the on the light sensitive plate produced the latent electrostatic image, Fig. 5 the electrostatic transferring the image that has become visible through development onto a separate transfer sheet, 6 shows the fixation of the transferred visible image with the aid of heat, and FIG. 7 is a diagram showing the potential distribution on a selenium surface according to Represents exposure to x-rays.

A selenium layer 1 is evaporated onto a thin aluminum plate 2 The thus produced and electrically charged, photosensitive plate 1, 2 can covered by a cassette-like cover plate 2a. Then this arrangement mounted under an X-ray tube 3 and on the cover plate 2a photographing or increasing Item 4 attached.

After irradiating the photosensitive plate 1, 2 with X-rays this plate is placed under a counter-electrode opposite the side layer 1 5 arranged for development, with the counter electrode 5 and the aluminum plate 2 can be connected to an energy source 6.

With the help of a developing device that works according to the dusting process 7, developer powder 8 and 8 ′ are dusted onto the selenium layer 1. That by it The image 10 made visible is then transferred to a transfer sheet 9 electrostatically and fixed with the aid of a heat source 11.

A corona discharge device is used to electrically charge the selenium layer 1 12 provided.

The invention is described below with reference to two specific exemplary embodiments explained in more detail.

Example 1 On the surface of a 1.4 mm thick aluminum plate 2 a 160 / u thick selenium layer 1 is vapor-deposited. This selenium layer 1 is in a dark room with a Eorona discharge device 1-2 as shown in FIG. 1 charged in such a way that it receives a surface potential of + 1000 volts. After this the photosensitive or photoconductive plate 1, 2 thus charged under the cassette-like Cover plate 2a has been accommodated according to FIG. 2 and as an object to be recorded 4, for example, a joint portion of a hand has been attached, irradiation is carried out from an X-ray tube 3 at a distance of 1 m with a maximum voltage of Tube of 70 KV and a current of 100 mA for a period of 0.14 sec. Then the surface potential of the selenium layer 1 is up 740 volts has been reduced in the sections corresponding to bone while other parts of the selenium layer, which include tendons, skin, flesh, etc. Have surface potential of about 400 volts. The potential distribution of a such an electrostatic latent image is shown schematically in FIG. In other words it means that between the bones and the other parts corresponding portions of the electrostatic latent image have a potential difference of about 340 volts.

Now is the time to develop this electrostatic latent image the powder cloud process or powder atomization process to form a visible image applied in which developing powder is blown onto the selenium layer 1. At the first development step is the counter electrode 5 at a distance of 1 cm across the selenium layer 1, as shown in Fig. 3, arranged, with the counter electrode a bias voltage of + 600 volts is applied. Then the latent image is made using developed by negatively charged blue developer powder 8. The blue developer powder 8 is hardly attracted to the parts of the selenium layer which are below 600 volts Have lying surface potential, while the developer powder of such Parts of the selenium layer are attracted to a potential higher than 600 volts have, for example, the corresponding to the bones of the picked-up object Image sections. Subsequently, without using a counter electrode 5 according to FIG 4 shows the latent image with the aid of negatively charged red developer powder 8 'additionally developed. The particles of the red developer powder are kept by everyone attracted to the image sections that have a positive potential.

The image 10 made visible in this way is then transferred to a transfer sheet 9 transferred in a known manner according to FIG. 5, whereupon the on the transfer sheet 9 located developer powder 8 and 8 'with the aid of a heat source 11 by heat fixed.

The image sections corresponding to the bones of the recorded object have been developed twice, i.e. H.

with both the blue and red developer powder, whereby these image sections appear purple, while the other image sections which match the tendons, skin, flesh, etc., just with red developer powder were developed. Therefore, an evaluation of the finished image is based on color differences possible what the readability or evaluability of the images compared to the previous The usual evaluation is significantly improved due to differences in density.

Example 2 On the surface of a 1.4 mm thick aluminum plate 2, a selenium layer 1 that is too thick is vaporized in a vacuum.

This selenium layer 1 is charged in a dark room in such a way that that it receives an electrical surface potential of + 250 volts. Then it will be a lower leg, in which 76 6 urograffine was injected as a contrast medium is, arranged on the cassette-like cover plate 2a and removed with the help of a 1 m X-ray tube 3 with a peak voltage of 80 KV and a power consumption of 300 mA for a period of 0.1 sec with X-rays.

This reduces the surface potential of the selenium layer in the sections which contain the contrast agent, hardly allow X-rays to pass through Tissue sections correspond to 1680 volts, in which the bones corresponding sections to 1370 volts and in the other sections corresponding to the skin Sections to 1050 volts. If one has such a potential distribution electrostatic latent image with a counter electrode 5 similar to Example 1, a voltage of + 1500 volts is first applied to the counter electrode and developed the latent image with the help of black developer powder. This developer powder then only has a higher potential than + 1500 volts showing image areas are attracted, which essentially correspond to the tissue parts, which contain the contrast agent. Then it is applied to the counter electrode applied voltage is reduced to + 1200 volts and the latent image is then reduced with the help of developed blue developer powder. This blue developer powder is used by everyone Image sections attracted that have a higher potential than - + 1200 volts, d. H. of the image sections corresponding to the tissue parts and the bones. In the end the latent image-still with the help of red developer powder without applying a Voltage developed at the counter electrode. The red developer powder is then from attracted to all parts of the picture that have any positive potential at all.

tine through three successive development steps with help from three different developer powders prepared in the manner described X-ray electrophotography has significantly improved readability or evaluability, because the different image sections are colored in such a way are differentiated from each other in that the sections corresponding to the tissue are black, the sections corresponding to the bones are purple and those corresponding to the skin, etc. Sections appear red. An image made visible in this way becomes visible after transmission on a transfer sheet or a picture carrier in the usual Fixed in a way that leaves a permanent image that can be reversed.

According to the present invention, differently colored developer powders are produced optionally or attracted to certain sections of the Xelen layer by the difference uses the surface potential of the electrostatic latent image, the developing process consists in having a counter electrode 5 opposite the electrostatic latent image bearing selenium layer 1 attaches to the bias voltage to be applied to the counter electrode 5 corresponds exactly to the surface potential Selects the selenium layer and then ensures that developer powder with predetermined Colors drawn from the image section corresponding to the relevant surface potential will. Thus, the various internal arrangements or structures of the to to be photographed or to be recorded object transferred and separated from each other be fixed in different colors. Therefore it is possible to have the most diverse inner structures of the object with many different colors of each other as desired to separate or distinguish so that the present invention excellent Functions and advantages, because you can easily read or evaluate with it Can produce images of parts of the human body, etc. that so far only difficult to recognize and evaluate with the help of X-ray images.

Patent claims:

Claims (3)

Patent application: Process for producing X-ray electrophotographs, an electrostatic layer on an electrically charged photoconductive layer applied latent image of an object to be photographed, this latent image made visible with the help of developer powder, then transferred to an image carrier and it is fixed there that a d u r c h e k e n n n z e i c h n e t,. that the different Image sections having electrical potentials one after the other with two or more different developer powders according to the existing potential difference to be developed. 2. The method according to claim 1, characterized in that one opposite that have a latent electrostatic image with different charge density Photoconductive layer carrying image sections attaches a counter electrode and to this counter electrode for a step-by-step development of the image. different Developer powders successively applies different electrical voltages, whereby the voltages applied to the counter electrode set a lower limit for the potentials of the photoconductive layer, which form image powder during subsequent development attract. 3. The method according to claim 1 or 2, characterized in that the electrostatic latent images on the photoconductive layer, one after the other is developed with differently colored developer powders. Blank page