DE1265583B - Process for the production of a xerographic reverse copy of an original and device for carrying out the process - Google Patents

Description

Method of making a reverse xerographic copy of a Template and device for performing the method The invention relates to to a process for the production of a xerographic reverse copy from an original, in which a xerographic plate is charged evenly, then with the original imagewise exposed and then between a conductive pad and an opposite The electrode is kept at an elevated potential on the substrate by sputtering of a developing powder is developed.

In the basic process of xerography, as described in the U.S. Patent 2 297 691 is a xerographic plate containing a photoconductive Has insulating material layer, initially evenly in the dark on an electrostatic Potential on the order of a few hundred volts and then charged with exposed to a light-shadow pattern that selectively removes the electrical charge from the exposed areas of the photoconductive insulating material can flow off, whereby a latent electrostatic image is formed. will. This latent image can be developed or made visible by touching the surface of the photoconductive insulator brings into contact with finely divided, electrostatically attractive material, that from the surface of the photoconductive insulator according to the amount remaining on it Charge amount is attracted. The material to be electrostatically attracted can the photoconductive insulator, or it can be on another carrier, such as on a sheet of paper, so that it can be viewed more conveniently and to allow reuse of the xerographic plate and at the same time keep the picture.

The most varied types of image development are known. As part of Any of these methods can be used in the invention. A well-known one The method is particularly suitable for developing continuously toned images. This method is described in U.S. Patent 2,725,304.

Will produce a continuously tinted high quality reproduction at the If xerography is desired, it is usually glassy as a photoconductive insulator Selenium around 20 to 80 microns thick is used. However, there are others too known photoconductive insulators, such as sulfur, anthracene and photoconductive dispersions Material, such as zinc oxide or other photoconductive pigments in a transparent insulating binder.

It has been found that selenium and generally photoconductive insulating materials lose their electrostatic charge or their potential when exposed to light according to the following relationship: In this formula, ho is the initial potential, V is the potential that remains after exposure E, and 1c is a constant that depends on the particular photoconductive insulating material used and on the units of measurement. There is also a loss of potential in the dark, albeit a much smaller one.

This relation leads to the exposure of charges when they are with the relation between the charge on the photoconductive insulator and the density of the developed image as used in the method of U.S. Patent 2,725 304 or other development process, to an undesirably high level Contrast in the developed image when positive-positive development is done. A positive-positive development (also called charge area development) is that in which the parts of the xerographic plate that have the darkest parts of the light pattern were exposed and which accordingly hold back the largest amount of charge receive the greatest amount of material to be attracted in the development.

It is often desirable to have some type of development in xerography to use that as negative-positive development, reversal development or development uncharged areas is known. With this type of development, the parts get the xerographic plate corresponding to the brightest parts of the image pattern, the greatest amount of development. The development uncharged areas is particularly advantageous when it is desirable to use xerographic images of conventional silver halide negatives or the like. It was found that the development of uncharged areas in xerography is usually extraordinary results in low instead of extraordinarily high contrasts.

Accordingly, it is the object of the invention in a method to enable a contrast enhancement of the xerographic copy of the type mentioned at the beginning.

According to the invention, this is achieved in that the xerographic plate uniformly electrostatically only to a higher potential than that of the electrode is charged and that the image-wise exposure with the original takes place for so long until the potential on the xerographic plate in the per se not to be exposed Place is lower than the potential of the electrode.

When carrying out the method according to the invention, one comes across a steeper characteristic of the image density versus the exposure intensity than when one the xerographic plate first to an equal or lower potential than that the electrode is evenly charged electrostatically, in other words, the ratio the image density to the exposure level is in the heavily exposed areas of the xerographic Plate very large compared to the weakly exposed areas on the xerographic plate.

By selectable setting of the potential of the uniformly electrostatic The charged xerographic plate opposite the electrode can be used to monitor the image contrast control within certain limits of your choice. It is also possible to adjust the contrast to be controlled by choosing the medium exposure level.

A device for carrying out the method with a device for adjustable uniform charging of a xerographic plate and with a Device for adjustable exposure of the evenly charged xerographic The plate is characterized by a first actuator for changing the height of the Charge and the strength of the exposure in the same sense.

It is with increased charge of the electrostatic plate expedient, at the same time, to enlarge the mean exposure so much that also the weakly exposed areas of the xerographic plate by the exposure are so greatly reduced in their potential that the potential is lower than that of the electrode, so as not to have a mixture of positive and negative copies (direct and Reverse copy).

The invention is illustrated below using exemplary embodiments described on the drawings F i g. 1 shows a cross section through a developing apparatus, with which the invention can be carried out; F i g. 2 shows a family of curves from which the Relationship between the plate potential and the density of the image can be seen; F i g. 3 shows a family of graphs showing the relationship between the plate potential and exposure is evident; F i g. 4 shows a graphical method for Prediction of xerographic characteristic curves; F i g. 5 shows a series Characteristic curves obtained according to the invention; F i g. 6 shows a Curve showing the relationship between the gamma value and the initial potential is; F i g. Figure 7 shows a perspective view of an apparatus for implementation the invention.

In Fig. 1, there is schematically shown, partly in cross section, a developing apparatus for performing the development of uncharged areas. This apparatus comprises a xerographic plate 10 which is supported by a conductive support block 11 which in turn rests on the drive rollers 12, by means of which the plate 10 and the block 11 is moved back and forth. The xerographic plate 10 has a photoconductive insulating material layer 13 on a conductive base 14. An electrostatic charge pattern on the plate 10 can be generated by another apparatus, not shown, before the plate 10 is inserted into the apparatus according to FIG. 1 is introduced. A developing electrode 15 is arranged such that the distance between its substantially flat sub-plate and the surface of the xerographic plate 10 is a small fraction of 1 cm. The development electrode 15 has a slot 16 which directs a stream of fine electrostatically charged powder particles suspended in air against the surface of the xerographic plate 10 as the plate 10 is moved past the slot 16. This particle suspension is fed to the slot 16 via a line 17 by means of a powder cloud generator 18. Powder cloud generator 18 may be of any known type, for example as described in U.S. Patents 2,812,883 and 2,859,128. When developing uncharged areas, it is desirable to use a powder particle suspension which contains particles the majority of which is charged to the same polarity as the plate 10. Since the plate 10 is usually, though not always, positively charged, it should the powder cloud generator 18 would normally deliver a cloud of predominantly positively charged particles. A dust collector 19, which is of a commercially available design, with a suction fan connected to a dust filter, is connected via the line 20 to two suction openings 21 and 22 in the development electrode 15. The right-hand opening 22 sucks in most of the powder cloud that emerges from the slot 16, thereby directing the powder cloud over the surface of the xerographic plate 10. The suction opening 21 collects powder cloud residues which would otherwise escape into the surrounding atmosphere. The apparatus also has a single battery 23 which is connected to a potentiometer 24 with a fixed and a variable tap. The developing electrode 15 is connected to one tap via a wire 25, while the xerographic plate 10 is connected to the other tap via a wire 26, the drive rollers 12 and the carrier 11 .

In order to develop uncharged areas, the potential of the electrode 15 with respect to the plate 10 is adjusted by means of the potentiometer 24 so that it contains substantially the same potential as the highest potential on the surface of the photoconductive insulating material layer 13 at the time of development , so after the exposure, is. If the potential of the developing electrode 15 is set appropriately, there is essentially no electric field between the electrode 15 and those parts. of the xerographic plate that carry the greatest charge or have the greatest potential, therefore only a minimal amount of the developing powder in these areas is attracted to the plate. However, a strong electric field arises between the electrode 15 and the uncharged areas of the plate 10. These uncharged areas therefore attract a large amount of the developer powder. Accordingly, it is possible to develop a powder deposit on the plate 10, the density of which is approximately inversely related to the charge or the potential of the plate and thus also inversely to the degree of exposure.

F i g. 2 shows curves from which the typical relationship between the Reflection density of powder deposits produced with the apparatus according to FIG. 1 formed and the xerographic plate potentials leading to these precipitations led, can be seen. These curves correspond to bias potentials Vb of 125, 175, 225 and 275 volts of development electrode versus conductive pad the photoconductive layer. The measurements of the reflection density were carried out, after the powder is transferred from the xerographic plate onto a sheet of white paper will. It should be noted that the curves are somewhat non-linear. they show Maximum densities (or maximum blackenings) at plate potential 0 (in relation to conductive base) and a minimum density at a plate potential that is essentially is equal to the bias potential of the developing electrode. It can also be seen that densities begin to increase again when the plate potential is above the The bias potential of the developing electrode is increased. Because this proportion of the curves in practical cases it is not exploited, it is shown by dashed lines represented by solid lines. The powder density increases with the higher the plate potential on again, there then again an electric field between the plate and the development electrode exists, albeit of opposite polarity to that at low plate potentials. The emergence of development under these conditions is indicated by the presence of Powder particles in the developer cloud explained the charges opposite to that wear polarity desired for development.

The curves in this figure correspond to developments up to one Maximum density of about 2 can be performed. In general, longer development times result to an increase in the maximum achievable density. These longer development times but also lead to excessive powder deposition in all plate areas including those where powder deposition is undesirable. Excessive Shortening the development, on the other hand, reduces both the maximum density and also the overall density at all points. A density of about 2 was close to that optimal maximum density when using the apparatus according to FIG. 1 and the used Materials.

F i g. 3 shows a family of curves from which the relationship between the xerographic plate potential and the strength of exposure in arbitrary Units for different initial potentials can be seen. These curves correspond essentially in their form of the square root relationship given above, with the exception an additional curvature, which acts as a deviation from the square root relationship very low potentials was observed. F i g. 4 shows one form of graph Representation to explain the invention and to predict with the invention is suitable for the results to be achieved. In FIG. 4 four quadrants are shown. The lower right quadrant contains a family of decay curves when exposed to light, which shows the relationship between the xerographic plate potential for exposure in represent arbitrary logarithmic units. The special curves are that same as those in FIG. 3 specified. The lower left quadrant contains development curves, which is the relationship between development density and xerographic plate potential indicate. A single curve is shown, this is from FIG. 2 removed and corresponds to a development electrode bias of 225 volts. The top left Quadrant contains a single diagonal line that is only used to Points in the lower left quadrant with points in the upper right quadrant in Relationship. In the upper right quadrant there are xerographic characteristic curves representing the relationship of developed image density to exposure.

To determine a point on a characteristic curve, a Horizontal line from the light decay curve in the lower right quadrant to one Point drawn on the development curve in the lower left quadrant. Then it will be from this point a vertical line is drawn to a point on the diagonal, which lies in the upper left quadrant, and a horizontal line through the latter Point on the diagonal. The intersection of this latter horizontal line with a line running vertically upwards from the original point on the light decay curve is drawn defines a point on the desired characteristic curve. Dashed Lines in the figure illustrate the method of determining a point the characteristic curve. There are many such points in the upper right quadrant determined which are assigned to a corresponding number of points on a light decay curve a smooth curve can be drawn in the upper right quadrant, representing a xerographic characteristic curve representing exposure relates to density.

In the lower right quadrant, four such curves are shown for the purpose of explanation, which correspond to the four light decay curves. It can be seen that the curves have markedly different slopes and therefore correspond to different degrees of contrast in the reproduction of xerographic images. Obtaining a desired contrast is the main object of the invention. Curve 1 corresponds to the case where the initial plate potential is substantially the same as the developing electrode bias potential used during development. This corresponds to the usual technique. The other curves correspond to conditions where the initial plate potential is significantly higher than the development bias potential. These curves result in an increasingly higher contrast. The main reason for this higher contrast is the use of only the right-hand or steeper parts of the light decay curves 2, 3, 4, as shown in the lower right quadrant. It can also be seen from the figure that where higher contrasts are obtained it is necessary to make more exposure. Although not readily apparent from the figure, it is also true that the plate potential corresponding to the central part of each of the characteristic curves is substantially the same. Each of the characteristic curves with the exception of the first has a dashed portion corresponding to the increase in image density which occurs when the plate potential can exceed the potential of the developer electrode. This is generally undesirable and is avoided by providing sufficient exposure to ensure that substantially all of the portions of the xerographic plate are degraded in potential to a potential below the development bias potential.

F i g. 4 shows the different degrees of contrast that can be achieved by changing of initial potential and exposure are obtained, with the developer electrode bias is kept constant. However, the same results can be obtained by that the electrode bias is reduced instead of the initial potential being increased will. You can also do both at the same time. The main factor in controlling contrast is the degree to which the initial potential of the xerographic plate becomes the developer electrode bias potential exceeds. For practical reasons, however, it is usually convenient to use the To change the initial potential instead of the electrode bias potential. Becomes the bias potential changed, it is desirable to avoid excessively low potentials, which generally lead to poor quality developments. Will be the initial potential changed, it is comparatively best to avoid excessively high potentials, which can damage the plate or cause stains in the developed image can. The operating conditions described below are representative for a preferred range of values.

From Table 1 are the characteristics of the four curves in the upper right quadrant of FIG. 4 tabulated. Table 1 Curve 1 1 curve 2 curve 3 curve 4 V, ...... 225 volts 234 volts 256 volts 324 volts S1 ...... 0.45 0.26 0.13 0.06 S. ...... 0.15 0.15 0.16 0.13 S. ...... 1.15 0.98 0.74 0.46 St ...... 1.75 1.39 1.03 0.65 DS ..... 1.97 1.98 1.98 1.98 Dmax ... 2.08 2.08 2.08 2.08 Gamma 1.46 1.71 2.27 3.65 Contrast 1 2 3 4 The characteristic data compiled in Table 1 are defined as follows (cf. Air Force Specification MIL-P-4672A [8-16-1954]): V, = initial potential; S1 = difference in logarithmic exposure between points on the characteristic curve with reflectance densities of 0.04 above Dmin and 0.20 above Dmin; S., = difference in logarithmic exposure on the characteristic curve with reflectance densities 0.04 below D.ax and 0.20 below Dm, ax; Sp = difference in logarithmic exposure between points on the characteristic curve with reflectance densities 0.20 above Dmin and 0.20 below Dmax; St = difference in logarithmic exposure between points on the characteristic curve with reflectance densities 0.04 above Dmin and 0.04 below Dmax; DS = Dmax - Drnin; Dmax = maximum reflectance density; Dnaiaa = minimum reflectance density; F i g. FIG. 5 shows in more detail a family of four curves found experimentally, which generally correspond to the four theoretical curves in the upper right quadrant of FIG. 4 correspond. Each curve represents a relationship between the xerographic plate exposure in arbitrary units and the reflection density of an image developed on the plate. All curves relate to a bias potential of 225 volts. Table II below summarizes the key data for each curve. It can be seen that a very wide range of contrast or gamma value can be obtained. This range generally includes the range obtainable in conventional photographic prints using enlarging paper. Accordingly, in the xerographic development of uncharged areas, an equal degree of contrast difference can be obtained by suitable control as is obtained in ordinary photographic prints and in ordinary enlargement techniques. Table II # 1 # 2 # 3 # 4 Start plate potential in volts. 235 257 299 362 Relative exposure ... 3 8 19 35 SI. . . . . . . . . . . . . . . 0.31 0.29 0.11 0.09 S2 ............... 0.13 0.11 0.17 0.28 Sp ............... 1.10 0.85 0.64 0.49 St. . . . . . . . . . . . . . . . 1.54 1.15 0.93 0.86 DS. . . . . . . . . . . . . . . 1.78 1.82 1.82 1.79 Dmax. ..... ... .... 1.98 1.97 1.97 1.94 Gamma .......... 1.25 1.67 2.20 2.84 F i g. Fig. 6 shows an experimental graph showing the relationship between the gamma value of a developed xerographic image and the amount by which the initial potential exceeds the developer electrode bias potential.

It can be seen that a very extraordinary change in the Gamma value through a relatively small change in the initial potential and / or preload is to be obtained. With the help of such a curve, an operator in the frame of the invention make xerographic prints with greater print contrast and better more predictable control of print contrast than even introduced photographic ones Techniques is possible.

F i g. Figure 7 shows an apparatus for practicing the invention. He exists essentially from a photographic enlarger 30, which is located above a loading apparatus 31 and the electrical apparatus associated therewith is arranged. The enlarger 30 can be of any ordinary type suitable for capturing an image of a photographic To project negatives or the like. The loading apparatus 31 has a support frame 32, which holds all the elements in place and a base plate 33, which is in consists essentially of conductive material. On the base plate 33 is located a xerographic plate 10 made of a photoconductive insulating material layer 13 a conductive support 14. After the intended use of the plate 10, the conductive supports 14 are also omitted. A conductive rail 34 lies on one side of the frame 32 and a second rail 35 lies on the other side of the frame 32. The rail 34 is insulated from the frame 32 by means of insulators 36 attached, the rail 35 is attached directly to the frame 32. A loading rod 37 is slidably mounted in the frame 32, in such a way that it over the Plate 10 can be pushed at a small distance from this. This loading rod has a downwardly open channel-shaped part 38 made of conductive material, the carries blocks of insulating material 39 at both ends, between which a thin corona discharge wire 40 is curious. The loading rod 37 is in the frame 32 by hangers 41 and 42 held, which slide on the rails 34 and 35, respectively. The hanger 41 is with the Corona wire 40 connected while hanger 42 is connected to channel 38. On the frame 32 there is also a rotatable lead screw spindle 43 with a reversible guide stored, which the loading rod 37 over the plate 10 by means of the lead screw block 44 can move back and forth. The block 44 engages in the recess of the lead screw and is attached to the channel 38. An electric motor 45 is also on the Frame 32 is attached and used to rotate the lead screw 43. One High voltage source 46 is connected to the base plate 33 and therefore with both the conductive support 14 as well as with the rail 35 and the channel 38, namely by means of of a wire 47. It is also connected to the rail 34 and therefore to the Wire 40, specifically by means of a wire 48. The voltage source can be of conventional Be kind, it should deliver voltages on the order of 5000 to 10000 volts can. The voltage source includes a step-up transformer 49, a rectifier 50, a filter capacitor 51 and a bleeder resistor 52. Suitable common control devices, such as a microswitch (not shown), can be provided to stop the motor 45 and the loading rod 37 after the loading rod 37 has been pushed back and forth over the plate 10 and in its illustrated initial position has returned. Other mechanical ones can also be used Arrangements are used for this purpose. Becomes a corona discharge potential placed on the wire 48, and the loading rod runs over the plate 10, so is an electrostatic charge is applied to the plate 10. The strength of this charge can be achieved by changing the voltage applied to wire 48 or the voltage applied to it Current can be controlled.

As shown in FIG. 7 shows the input voltage of the high voltage source 46 supplied by a toroidal autotransformer 53. By setting the autotransformer 53, the corona discharge potential at the corona wire 40 can therefore be changed. The autotransformer 53 is set with the same insulating shaft 54 like toroidal autotransformer 55. A button 56 is on shaft 54, with which both autotransformers are to be adjusted at the same time. The autotransformer 55 supplies an alternating voltage to be set to the enlarger 30 via the timer 57. The autotransformer 53 is fed directly with mains alternating current. Of the Autotransformer 55, however, is replaced by another toroidal autotransformer 58 fed, which is equipped with a control button 59. Accordingly is the corona potential lying on the wire 48 and therefore on the corona wire 40 alone carries through the position of the knob 56 is determined while the one being fed to the enlarger 30 Voltage depends on the setting of both knobs 56 and 59.

In operation of the apparatus, the knob 56 is rotated to a position corresponding to the level of contrast desired and the knob 59 is rotated to a position corresponding to the average density of the negative to be projected by the enlarger 30. The motor 45 is then turned on and this causes the loading rod 37 to pass over the xerographic plate 10 and generate a potential thereon which is determined by the setting of the knob 56. Then the motor 45 is switched off and the timer 57 is energized, so that a light image is projected onto the plate 10 for a fixed period of time, the intensity of which depends on the setting of the buttons 56 and 59. After exposure, the plate 10 can be removed from the apparatus of FIG. 7 and stored in a separate apparatus such as that of FIG. 1, to be developed.

Since the contrast depends on the initial potential of the plate 10, the Contrast influenced by the setting of knob 56, which is the charge potential certainly. It has been found that when the charge potential increases the image contrast is increased, the required exposure is also increased had to become. For this reason, the knob 56 increases the input voltage of the Magnifier 30 and thus the light output of the magnifier 30 at the same time as the Increase in the charge potential applied to wire 40. Since photographic Negatives fluctuate in their average density among each other is another Ability to control exposure desirable given by button 59 which is the input voltage applied to the enlarger 30 versus the through the button 56 can increase or decrease certain. Will have a number of negatives reproduced, all of the same density but varying in contrast, thus, xerographic prints of uniform quality can be obtained by adjustment alone of button 56 can be obtained. The negatives have even contrast, however different density, so prints can be of uniform quality by sole Setting of button 59 can be obtained. Usually is it so that both buttons can be operated to change the contrast and in to compensate for the density of the negatives. Since the potential given to the plate 10 is generally not a linear function of the voltage applied to wire 40 and since the light output of the enlarger 30 is not generally a linear function .the voltage applied to it, it may be desirable to use the autotransformers 53 and 55 wrap nonlinearly to establish a suitable relationship between the initial potential and exposure as shown in FIG. 4 can be seen.

The apparatus according to FIG. 7 is shown solely for the sake of explanation. It can be seen that many changes to the procedure can be made, without leaving the idea of the invention. So can the most different types of loading apparatus in place of the loading rod 37 or other elements of the Loading apparatus 31 are used. Likewise, the enlarger 30 can be through contact exposure apparatus and other control devices can be used in place of those illustrated Autotransformers are set. The apparatus can also be used to work with flexible xerographic plates, including those in the form of a tape. Although the apparatus shown controls the contrast through Allowed changing the load, it can also be designed such that he controls the contrast by changing the developer electrode bias potential made possible by the output of the autotransformer 53 with a relatively low Voltage source is reconnected, which has a bias potential in a separate Development apparatus there.

A wide variety of devices are known which allow the degree of contrast of a photographic negative or the like to be determined. Devices are also known for determining the average transmission of a negative. Such devices can aid or replace the subjective judgment of an operator. Such devices can also direct the transformers of FIG. Press 7 so that the operation of the entire device is completely automatic. The apparatus of FIG. 7 may also be equipped with an electrometer which measures the potential on the xerographic plate 10 either before or after exposure to the enlarger 30, or in both cases. Such an electrometer can be used to measure the plate potential after exposure, providing a quick check of the accuracy of the exposure. It can also be used to automatically control exposure.

Claims (3)

Claims: 1. Process for making a xerograph 'see Reverse copy of an original with a xerographic plate evenly charged, then imagewise exposed with the original and then between a conductive pad and an electrode held at an increased potential with respect to the base is developed by dusting a developing powder, characterized by that the xerographic plate is only at a higher potential than that of the electrode is evenly charged electrostatically and that the imagewise exposure with of the original takes place until the potential on the xerographic plate is in the areas not to be exposed is lower than the potential of the electrode. 2. Device for performing the method according to claim 1 with a device for adjustable uniform charging of a xerographic plate and with a Device for adjustable exposure of the evenly charged xerographic Plate characterized by a first actuator (56) for changing the height the charge and the strength of the illumination in the same sense. 3. Set up after Claim 2, characterized by a second actuator (59) for changing the Strength of exposure regardless of the amount of charge.