DE2347414C3 - Process for eliminating the residual charge in the background during electrophotographic image reproduction - Google Patents

Description

The invention relates to a method for removing the residual underground charge according to the preamble of the patent claim 1. Such a method is known, for example, from DT-AS! 5 22 595.

In the known methods of electroradiography with photo-conductive plates, for. B. those made of amorphous Selenium, the surface of the plate is charged positively or negatively to a high potential (approx. 1 to 3 kV). The plate prepared in this way is then exposed to the radiation so that it is photo conductive Layer a change in conductivity in the sense of the intensity distribution in the image is obtained. Through this a corresponding discharge takes place at the irradiated areas. The charge image obtained in this way can then be used with various means known in electrophotography can be made visible. Most common is z. B. depending on the charge with colored pigment, especially the dusting dielectric F ^ powder.

When the charge image is generated, the The surface of the photo conductive plate compared to the base is usually charged to 1.5 to 3 kV. in the During the exposure process, this charge is reduced by a few 100 volts to create the image. Even oine Underexposed selenium plate differs from a normally exposed plate only in the contrast. the Basic density corresponds to that of a correctly exposed plate. The particles of dielectric paint powder, which are also referred to as toner particles, orientate themselves when approaching the charge image essentially to the generated by the charge differences, possibly by separately created auxiliary fields overlaid fields. The toner granules must be selected so that they can despite the high residual charge in the background still give a picture of the plate. They must therefore not be too sensitive, i. H. not to fine-grained and provided only with a relatively low specific charge.

According to DT-AS 15 22 595, between taking the charge image and making it visible to eliminate the differences in charge in the image areas to be covered with toner large background residual charge, a charge that is reversed to the charge in the picture is applied will. As a result, the subsurface is neutralized and the pictorial mountain of charges can be better developed. This can be done, for example, in a corona discharge ao high discharge voltage take place, the discharge electrodes at a large distance from the image area are arranged. However, this method has not been able to be introduced into the image acquisition technique because the the entire surface of the receptacle is subjected to a uniform charge. But the leveled uneven pictorial charge distribution, d. H. the image contrast becomes undesirable decreased. This can be explained by the fact that the charge carriers follow the field lines and the places of higher potential more discharged than those of lower potential.

The invention is based on the object of a method for removing the residual underground charge a charge image generated on a photo-conductive layer according to Oberbcgnll of claim 1 To at least preserve contrasts. This task is according to the invention by the in the characterizing part this claim resolved specified measures.

By acting on the charged photoconductive ones provided with the pictorial mountain of charges Layer by means of a charge carrier source, which is scanned over the area to be acted upon Area is guided at a distance that is in the order of magnitude of the desired image resolution and in that the charge carrier source is operated in the current saturation range, it is ensured that on an equally strong charge is applied to all points of the receiving surface, regardless of how high the load is straight at the point in question. This only results in a lowering of the underground charge and an undesired leveling of the contrasts is omitted because of the smaller distance lateral evasion of the load carriers to remote locations of higher loads is prevented.

To lower the charge, all devices are suitable with which surfaces in the aforementioned Meaning that they can be evenly charged with charges. A suitable facility to achieve this the method according to the invention consists of γιο a generator for ions, from which particles charged against the charge of the plate break down the Effect basic charge. For this purpose, the receiving plate carrying the charge image is placed in an electric field brought, in which the ions, whose sign is opposite to the charge, towards the plate be accelerated. In the case of a positive charge on the selenium plate, negative ions or electrons. The source can be, for example, a gap which is arranged parallel to an edge of the plate. The source will

then passed in the specified distance, adapted to the desired image charge, over the selenium plate on which the charge image of the image is located. The distances result in an order of magnitude of approximately 0.03 to 0.07 mm if the resolution aimed at with conventional X-ray images is to be achieved. If, in accordance with the second part of the characterizing part of claim 1, care is taken to ensure that the field strength is always in the saturation value of the source-selenium plate discharge path, the current ji surface element is constant and independent of the charge. In this case, the same amounts of charges per unit of area always flow onto the selenium plate per unit of time, then the charges at all points on the plate are reduced by the same potential value Points of the selenium plate to lower the same point. It is expedient to strive for a potential distribution whose lowest value is so far above zero that with a certain degree of certainty no image reversal is obtained.

Measuring devices for determining surface charges are z. B. Oscillating capacitor instruments. This makes it possible to achieve optimal lowering of the potential by measuring over known electronic means coupled to the potential and this is thus kept constant. To the Distribution of the ions used to break down the basic charge can also be the source and fixed the plate can be moved. It just depends. that the charged particles are distributed evenly.

As sources for generating ion currents Corona stretches with an auxiliary electrode take place. Radioactive substances can also be used for ionization.

A scanning electron beam can also be a suitable electron source. Such sources are z. B. High vacuum tubes in which the electrons are generated and then accelerated. A window made of a thin foil made of beryllium, aluminum, etc. is provided for the electrons to exit the tube. Windows made of substances that react with the electrons can also be used, such as a few tenths of a millimeter thick beryllium foil that has a coating on the inside of the tube on which the electrons are converted into X-rays. These then pass through the layer of beryllium, on the outer surface of which a layer jo which converts X-rays into electrons is attached so that the energy transported through the window in the form of X-rays is again available as an electron beam. Both conversion layers can / .. B. consist of an approximately 1 to 3 μm thick vapor deposition, etc. with platinum, gold or another heavy metal. The window itself can have the shape of a strip, the length of which corresponds approximately to the width of the xero plate, and the electron beam can be set in a scanning back and forth movement. The exposed Xeroplate is then moved a short distance past the window in order to obtain the desired coverage with electrons. As in the case of the aforementioned arrangement, the tube can also be moved here instead of the plate.

Subsequent to the discharge process according to the invention, which is assigned to the developing device Setup or in an upstream device such as a special cassette the charge image is developed. This can be done by any development process take place as it is known from ionography or electrophotography.

Details of the invention are further explained below with reference to the exemplary embodiments shown in the figures

Fig. 1 is shown partially broken away a cassette with a corona discharge unit for Implementation of the invention is designed in the

F i g. 2 shows an arrangement in which the charge is balanced by means of a cathode ray tube, in which

2a shows a section from the electron exit window that used in the arrangement of FIG Tube and in the

F i g. 3 schematically shows the effect of the invention in a diagram.

In Fig. 1, 1 denotes the cassette in which the receiving plate 2 is located, in which as the actual receiving layer a 300 μm thick selenium layer 3 on the 2 mm thick aluminum sheet The plate 2 is behind the radiolucent cover 5 made of aluminum and arranged parallel to it on the floor 6. In parallel to one of the limitation of the rectangular plate 2 is the gap electrode 7 of a known corona discharge unit. This will operated by direct current of 6 kV from source 8. The gas located in the space 9, i. H. air from atmospheric pressure, ionized. The ionized particles of air thus obtained then diffuse through the gap 10 through the 0.05 mm distance therefrom Surface of layer 3 too. As a result, after the generation of the charge image from the onto the plate applied basic charge, which is 1.5 to 3 kV, the remaining underground charge can be neutralized. But so that there is an even lowering of the base charge at all points and the pictorial Distribution of the charges of the charge pattern is not disturbed, is for the stable transport of the electrode 7 at the rear end of the electrode 7, a motor 13 is arranged, which via the dashed line Gear 14 acts on the rack 15 which is mounted in the rear side wall 16 in the groove 17. Also in the FIG. 1 removed front wall of the cassette 1 is a corresponding one Guide groove. As a result, by means of this electrode 7, which in the direction of arrow 18 evenly over the Plate 2 can be moved away, the neutralizing charge will be uniformly distributed. After The transfer of the plate 2 into one takes place in a known manner to compensate for the remaining underground charges Developer unit. This is where the visible image is created on the charge image. The effectiveness of the invention results in the above already described and on the basis of FIG. 3 further explained way.

The arrangement according to FIG. 2 is located in a light-tight, sealed off, not particularly shown Space to prevent additional exposure of the iotoconductive layer 19 of the plate 20, which corresponds to that which is denoted by 2 in FIG. 1. The plate 20 is between the rollers 21 moved past the gap 23 of the tube 24 in the direction of the arrow 22. The roles 21 and 2Γ only take hold on the carrier 25 of the plate 20 in order to protect the selenium layer 19. The tube 24 is formed so that the length of the gap 23 of the width of the plate 22 transversely to

Corresponds to the direction of movement, so that the entire surface of the layer 19 can be covered with electrons of the beam 26 shown in dashed lines. As the electron exit window 27 that closes the gap 23 in a vacuum-tight manner, a loop arrangement is used, which consists of the actual window layer 28, a 0.2 mm thick beryllium sheet, which is coated on both sides with a layer 29 and 30 of platinum, which is 2 μm thick is (see Fig. 2a). In this layering, shown in enlarged detail n in FIG. 2a, the electrons 31 on the inner plane layer 30 cause a conversion into X-rays which penetrate well through the layer 28 made of beryllium. On the outside, electrons are again generated on the platinum layer 29 from the X-rays i <. These are then brought to the layer 19 in the beam 26 due to the high voltage of approximately 200 kV applied to the layer 19 from the source 33 via the ground connection 34. _{The beam 31 is set in a scanning back and forth motion along the window 27 by the 2C} arrangement symbolized as coils 35 and 36, so that the entire width of the plate 20 is swept over. The scanning is set so that each point of view is irradiated with electrons for a period of 0.5 msec. With a 25 focal spot of 50 μm and a voltage of 20 kV with an electron beam of 0.1 mA strength, a current of 0.01 uA results in the beam 26. At the aforementioned focal spot, a current density of 5x10 "A / cm ^{2 is obtained} With the above-mentioned dwell time, a surface capacity of 10 "» F / cm ^{2 is transferred} . This means that despite the poor efficiency of the double conversion in the window 27, a very rapid reduction in the basic charge of the plate 20 is possible. By means of the amplifier 37, which is 35 via lines 38 and 39 between the electrically conductive roller 2Γ resting on the plate 20 and the Wehnelt cylinder 40, the measuring resistor 37 'located between the line 38 and earth can be used in a manner known per se the electrons applied to the plate 20 in the beam 26 are controlled. In this way, for example, the charge transferred in the electron beam 26 to the surface of the layer 19 can be kept constant because the incident beam 26 is measured at any moment and readjusted via the Wehnelt cylinder 40. By any other setting of the effect of the amplifier 37, however, a change in the modulation transfer function of the system can also be obtained. A contrast increase is z. B. achieved if the amplifier ₅ o ker 37 is set so that at image points at which the scanning beam 26 at low potential of the

40

45 plate 20 hits, an excessive balance of the charge takes place and at points of high potential accordingly too little balance. If this process is reversed, the potential differences are leveled, ie the contrast of the image is reduced. However, other changes in the contrast, for example only partial changes, can also be set. So you can z. B. compensate for coarse contrasts in favor of fine contrasts more, - by influencing the beam 26 in) differently depending on the change in the potentials of the image points.

In the representation chosen in FIG. 3, the charge mountains are plotted on a reduced scale, which is located on the plate 19 in a line between the edges 41 and 42 through the receptacle the surface of the layer 19 results. The ordinate 43 is the charge and the abscissa 44 is the location. d. H. the distance from the edge 41 is applied. The horizontal 45 represents the basic charge of the plate 20. When recording, the change in the electrical conductivity of the layer 19 is charged the bright wedge of the pixels correspondingly partially discharged. This leads to a charge distribution corresponding to curve 46. Its course corresponds completely to curve 47. Only that absolute location. d. H. the charge heights differ from each other by a uniform amount. the The difference between the two curves 46 and 47 ■ is the amount that one effected according to the invention uniform reduction of the charge. But it follows from this that the fluctuations recorded in curves 46 and 47 in curve 46 relative to Total load is less important than in curve 47, in which the total load is in comparison to the location of the curve 46 is lower. The dashed curve 48 is through the above Contrast enhancement was created. Here, pixels with a low potential are stronger and those with a high potential less well balanced. The ups and downs of curve 46 are greater when transitioning to curve 48 Keep distances from each other.

Although the advantages of the invention, as explained above, are mainly important in the production of fluoroscopic images with X-rays and similar penetrating rays, they can also be beneficial in the production of images with visible light etc. You can get bigger contrasts - achieve. Δ U means the potential difference between any two points and U the mean potential.

1 sheet of drawings

ft 991

Claims (5)

Patent claims: - J. Procedure for the elimination of the residual underground charge a charge image generated on a photo-conductive layer, in which the charge image limit charges of opposite polarity are applied, characterized in that that the application by means of a charge carrier source is carried out by scanning the to acting surface is guided at a distance that is in the order of magnitude of the desired Image resolution is, and that the charge $ carrier source is operated in the current saturation range. 2. The method according to claim 1, characterized that the charge carrier source is a corona discharge device with a spa'telectrode is used. 3. The method according to claim 1, characterized in that an electron beam source is used as the charge carrier source. 4. Apparatus for performing the method according to claim 3, characterized by a light density Cassette for a plate (20) carrying the charge image, a cathode ray tube (24), which has a strip-shaped, with the electron beam scanned electron exit window (27), which extends across the charge image transversely to the scanning direction, and characterized in that the Electron exit window of the cathode ray tube light-tight over the charge image to be scanned in the cassette can be guided. 5. Apparatus according to claim 4, characterized in that the cathode ray tube has the intensity of the electron beam (26) controlling measuring and regulating arrangement (37 to 40) is assigned.