DE2953712C1 - Record carrier for the electrophotographic production of two-color recordings and method for the electrophotographic production of two-color recordings with such a record carrier - Google Patents

Description

The advantages achieved with the invention are based on the following mode of operation: First, in the dark, a charge of a certain polarity is placed on the surface of the recording medium and thus on the surface of the upper, transparent, applied photoconductive layer. Since this layer does not conduct in the dark, it remains this charge on its surface, which in turn induces positive charges, that of the substrate of the recording medium through the lower photoconductive layer migrate to the interface between the two photoconductive layers. Since the lower photoconductive layer has a rectifying effect, this induced charge becomes trapped at the interface between the two photoconductive layers.

By charging with the opposite polarity, at least some of the charges with the first polarity are neutralized, but the charges are retained at the interface between the two photoconductive layers.

At the same time, on the lower surface of the lower photoconductive Layer induces a charge with the first polarity.

Will such a uniform charge pattern with a two-tone Image exposed imagewise, the result is an electrostatic, latent image, especially in the areas corresponding to the black areas Have charge and can therefore be developed with high resolution.

The invention is illustrated below with the aid of exemplary embodiments explained in more detail with reference to the schematic drawings. It shows Fig. yes to 1d representations of the various steps of the process for electrophotographic Making two-tone records, F i g. 2 a graph of the electrostatic surface potential of the recording medium during the various Steps of the method according to FIGS. Labis Id, and F i g. 3 shows a graph the relationship between the surface potential of the recording medium and the Ratio of the electrostatic charges of the photoconductive layers in the process for the electrophotographic production of two-color records according to the F i g. 1 a to 1 d.

In the electrophotographic process according to FIGS. 1 a to 1 d a recording medium 31 is used, which is an electrically conductive, grounded Contains substrate 31a. On the substrate 31a is a lower, photoconductive layer 31b formed on which an upper, transparent, photoconductive layer is applied is.

The upper, photoconductive layer 31c is transparent and sensitive for light red color.

The lower, photoconductive layer 31b is insensitive to light red color and consists of a semiconductor material with rectifying properties, such as selenium, so that positive charges (holes) in the dark of the substrate 31a through photoconductive layer 31b to the interface between the two Layers 31b and 31c arrive but do not migrate in the opposite direction can.

This method uses a corona charging device 32, which is fed by a negative DC voltage source 33, one in the dark negative charge applied to the surface of the recording medium 11. Since the The recording medium is not irradiated, is the upper photoconductive layer 31c non-conductive, so that the negative charges on the surface of the photoconductive Layer 31c remain. The negative charge on the surface of the photoconductive layer 31c induces positive charges on the substrate 31a through the lower photoconductive Layer 31 b to the boundary layer between the two photoconductive layers 31 bund 31c hike. Due to the rectifying effect of the lower photoconductive layer 31b becomes the induced positive charge at the interface between the two photoconductive layers 31b and 31c captured as they are not in the opposite Direction through the lower photoconductive layer 31b.

The second, shown in FIG. 1 b illustrated process step a positive charge by means of a coro- Naaufladungseinrichtung 34, which is from a positive (ileichspannungsqucllc 36 is fed to the recording medium 31 upset.

This charging also takes place in the dark, so that none of the layers 31b and 31c is conductive; this positive charge has the effect of being a part the negative charge. those on the surface during the first process step of the recording medium 31 has been formed. is neutralized. The positive one Charge at the interface between the two photoconductive layers 31 b and 31c remains behind. On the lower surface of the lower photoconductive layer 31b a negative charge is induced which is equal to the difference between the positive and negative charging.

As shown in FIG. 2 can recognize. becomes the size of the process step according to FIG. 1 b applied.

positive charge selected so that the negative charge on the surface of the recording medium 31 is reduced and smaller than the positive charge on the There is a boundary layer between the two photoconductive layers 31b and 31c.

The size of the second, positive charge is selected so that the relatively high, negative value of the surface potential of the recording medium 31 is reduced to a smaller negative value after the method step according to FIG. La if, according to the step of FIG. 1 b a positive charge is applied. The negative surface potential of the recording medium 31 after the method step according to FIG. 1b must be large enough to stick to the surface of the recording medium to create an electrostatic, latent image necessary for subsequent Development by means of a toner is sufficient.

The one in the manner described with two different polarities charged recording medium 31 is then with an image of a two-color Original exposed, i.e. an original that has black and red areas as well has a white background, as can be seen in Fig. Lc.

During this process step, the electrostatic surface potential remains negative in the black areas. Part of the positive charge is in the red Image areas neutralized. since there only layer 31c is photoconductive; by however, the remaining part of the positive charge becomes the surface potential of the recording medium 31 reversed from negative to positive. The two photoconductive ones Layers 31b and 31c are conductive in the white image areas to the surface potential decrease to essentially zero.

In Fig. 3 is the relationship between capacitances C 1 and C2 of the photoconductive layers 31b and 31c, respectively, between the charges Q 1 and Q2 and the surface potential shown in the black and red areas. Included the following theoretical relationships were used: For a cross-section through the record carrier 31, the charge is at the interface between the photoconductive layers 31b and 31c + Q 1 dS, and the charge on the surface of the photoconductive layer 31c is - Q 2 dS. Since the substrate 11a is grounded, a charge - (Q1-Q2) JS at the interface between the substrate 11a and the lower one Layer 116 induces the capacitances C 1 and C2 can be considered connected in series to be viewed as. The capacitors C1 store a charge of (Q 1 - Q 2) per Area unit. The capacitance C2 stores a charge of -Q2 per unit area.

The surface potential VB in the black image areas is given by The surface potential VR in the red image areas is given by By setting a parameter and substituting it into equations (1) and (2) gives The curve 37 shows the equation (4), ie the potential in the red areas. Curves 38, 39, 41 and 42 represent equation (3), ie the potential in the black areas, for values of C2 / CI which are equal to 1, 2, 3 and 4, respectively. From Fig. 3 it can be seen that the ratio C 1 / C2 should be as large as possible or that C2 should be as small as possible in comparison to CI. This increases the negative slope of the curve for the potential in the black areas and the electrostatic contrast between the black and red image areas increases.

In the following, curve 42 is to be considered as an example, at which is the ratio Cl / C2 = 1/4; from this curve it can be seen that at K = 0.5 the potential in the red areas is + 300V, while the potential in the black areas is -900 V. The electrostatic contrast is therefore 1 1200 Vl and thus lower than it is at higher values of C1 / C2 can be obtained. With an optimal selection of the values for C1.

C2 and K can be equal to or equal to the values of VR and VB as required be made unequal. In the last-mentioned case, unequal values for VR and VB may be useful to account for differences in the amounts of black and red toners to be able to compensate.

As an alternative to the one shown in FIG. 1 illustrated embodiment the DC voltage source 36 can be provided by an AC current source (not shown) be replaced. whereby a corona alternating current discharge on the recording medium 31 is applied.

The following are some practical examples of the embodiment according to FIG. 1 specified.

Example 1 Here, a recording medium with an aluminum substrate is used is used as the first photolcitcntlc layer selenium with a purity of 99.990 /) at 45 "('is vapor-deposited to a thickness of 10 µm: a second, 20 µm thick photoconductive layer consists of a 1: 1 mixture of poly-N-vinyl carbazole (l> VK) and 2,4,7-trinitro-9-pluorenone (TNF). The first photoconductive layer is sensitive to light of all colors except red, while the second, off a layer consisting of an organic photoconductor has a panchromatic color sensitivity Has.

This recording medium is charged to -7.0kV in the dark, which means a surface potential of -2400 V is created; then he will be in the dark with +4.7 kV, which creates a surface potential of -900V.

The surface of this recording medium is then worn through an illustration of a template with black lines and red lines on a white Illuminated underground. The surface potential is then in the black areas -860V, in the white areas -40V and in the red areas + 280V.

By developing the surfaces of the electrostatic latent image, which correspond to the black or red areas of the original, with a positive charged, black toner or a negatively charged, red toner with the help of a magnetic brush, you get a two-color, high resolution copy. The resolving power in the black areas is 5 to 7 lines / mm.

Example 2 The recording medium used here has an aluminum substrate on which a first photoconductive layer is applied to a thickness of 10 µm is; this first photoconductive layer consists of rose bengal sensitized Zinc oxide resin with a zinc oxide / resin weight ratio of 3 1, on top of this first photoconductive layer becomes a second photoconductive layer of the same organic Compound as used in Example 1 was applied to a thickness of 20 µm.

The first photoconductive layer is insensitive to red Light, however, sensitive to green light, while the second is photoconductive Layer has a panchomatic photosensitivity.

This recording medium is charged at +6.5 kV in the dark, which means a surface potential of + 1800 V is created. After that it gets -4.8 in the dark kV charged. whereby the surface potential is reduced to +600 V. This The recording medium is provided with an image of the same template as that used for Example 1 was used, exposed, whereby surface potentials of + 580 V, + 30V and -260 V arise in the black, white and red areas. Then the black areas are filled with negatively charged black Toner, and the red areas with positively charged, red toner by means of developed into a toner image by a magnetic brush developing device. The two-color copy has excellent resolution in the black Areas.

Example 3 This is a comparative example for Ulil the basic procedure mentioned at the beginning of the paragraph is used. I) icscr record carrier has an aluminum subsirate to which Sclen with a proportion of 10C, ew .- ') / o Tellurium is evaporated to a thickness of 10 µm at 74 "C; on the first layer a second layer of a dinitrofluorenone sensitized Bromopyrene applied to a thickness of 10 µm.

The second photoconductive layer is insensitive to light red color, while the first photoconductive layer has a panchromatic photosensitivity Has.

This recording medium is switched to - 1200 V and then in the dark Charged positively in the dark to the point where a charge of -800 V results. This recording medium is then provided with an image of the usual, exposed two-tone original, as used in the first two examples has been.

The measured surface potentials are in the black areas + 760 V, -40V in the white areas and -290V in the red areas. After developing this electrostatic, latent image by means of a negatively charged black toner and a positively charged red toner the black areas have a relatively poor resolution of 3 to 4 lines / mm.

Example 4 This example becomes essentially the same Process steps used as in Example 1 so that they were only repeated briefly should be.

The record carrier has a conductive substrate, any one first, applied to the substrate, photoconductive layer and a second photoconductive layer Layer formed on the first layer. those for light of a color A is sensitive and does not let light of this color A through. The word "any" means that any suitable material can be used which is suitable for light of the Color A is sensitive or not.

If the color A is red, the recording medium has an aluminum substrate, a layer of selenium with 10% by weight tellurium, which is heated at 74 "C is evaporated to a thickness of 10 µm on the substrate, and a layer of Copper phthalocyanine applied to the selenium layer in a thickness of 20 µm is.

The surface of this recording medium is first covered with a given polarity. a charge of the opposite polarity to capture. This first charge is followed by a second charge with an opposite one Polarity, which reduces the surface potential of the recording medium will.

This recording medium is then provided with an image an original exposed, the black and red areas on a white Has underground. In the red areas of the image, the outer or second photoconductive Layer. which is sensitive to light of red color, the red light does not pass through and thereby prevents the inner or first photoconductive layer from being influenced. The second layer, however, is due to the resulting reversal of polarity of the surface potential conductive.

In the white background areas both the inner as well as the outer photoconductive layer conductive, so that those present there Charges are dissipated and have essentially zero surface potential results.

The surface potential remains essentially in the white image areas at the same level as at the end of the second charge.

After exposure with the image of the original has the surface potential this recording medium has the same values as those given for Example 1 became.

The resulting. electrostatic latent image of the original becomes developed with black and red toner charged with the corresponding polarity, creating a two-tone copy.

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Claims (6)

Claims: 1. Recording medium for electrophotographic Making two-color records with an electrically conductive substrate and two photoconductive layers with different spectral sensitivity, the top layer of which is transparent. which can be charged with a first polarity, chargeable with opposite polarity and image-wise exposable with an original which contains black areas and areas of a different color, and in which the obtained, electrostatic image with two different toners different Color and polarity can be developed, characterized in that the upper, transparent, photoconductive layer (31c) sensitive to light of the other color (red) and the lower, photoconductive layer (31b) is insensitive to light of this color (red) and has a rectifying effect. 2. Recording medium according to claim 1, characterized in that the lower, photoconductive layer (31b) a layer of a rectifying Semiconductor is. 3. Recording medium according to claim 2, characterized in that selenium is used as a rectifying semiconductor. 4. Process for the electrophotographic production of two-color Recordings with a recording medium according to one of Claims 1 to 3, characterized characterized in that a) the record carrier with the first polarity in the dark is charged that b) the recording medium (31) also in the dark with the opposite polarity is charged, and that c) the record carrier (31) is exposed imagewise. 5. The method according to claim 4, characterized in that the two Charges can be carried out with different potential. 6. The method according to claim 4 or 5, characterized in that that charging is carried out by corona alternating current discharge. The invention relates to a recording medium for electrophotographic Production of two-tone records of those specified in the preamble of claim 1 Genus, as well as a process for the electrophotographic production of two-color Recordings with such a recording medium. From the earlier patent application P 28 25 385.2-51 is an electrophotographic Process for the production of two-color recordings, in which a recording medium which is an electrically conductive substrate and two photoconductive layers with different spectral sensitivity. of which the upper layer is transparent. This recording medium is charged with a first polarity. irradiated with light of one color uniformly. with partial neutralization of the first charge with opposite polarity and charged with an original imagewise exposed, the black one Contains faces as well as faces with a different color. The electrostatic image obtained is obtained with two different Toners of different colors and polarities developed into a two-color toner image. The disadvantage of this method is that the resolution for the surfaces a certain color, for example black, is inevitably worse than the one for the other color. In the following, this will be done using black / red templates and corresponding illustrations are explained. The areas of electrostatic imaging that represent the black surfaces correspond to the template, are through the charges of the interfaces between the inner and outer layer while determining the areas of electrostatic Figure, which correspond to the red areas of the original, by the charges of the Surface of the outer layer can be determined. This means that the resolution of the red areas is higher than that of the black areas. However, this is inconvenient because of business stationery and similar documents are printed in black rather than red and so that copies are also made; however, the color that is most used should be also have the best possible resolution. Another disadvantage of this procedure is this. that an additional total exposure of the charged recording medium must be carried out with light of a certain color; thereby the associated Copier has a complicated structure; there is also another process step added, so that the processing time is extended. The invention is based on the object of a recording medium for the electrophotographic production of two-color records of the specified To create a genus in which the black areas of the High resolution template can be copied. This object is achieved according to the invention by the in the characterizing part of claim 1 specified features solved. Appropriate embodiments are compiled in the subclaims. Another object of the invention is to provide a method for the electrophotographic production of two-color records with a to create such a recording medium in which there is no total exposure of the recording medium must be used. This object is achieved according to the invention by the in the characterizing part of claim 4 specified features solved. Expedient embodiments of this method are in the claims 5 and 6 indicated.