DE2651427A1 - Electrophotographic copying onto sheet with fine surface indentations - giving high resolution of final image obtd. by toner transfer - Google Patents

Abstract

Method consists of forming an electrostatic charge image on the photoconducting recording layer of an intermediate (temporary) recording sheet, colour with toner, then transferring the resultant toner image to the final recording sheet by direct contact and then, after the temporary sheet has been removed, fusing the final image on the latter sheet. The final recording sheet has a large number of small depressions distributed as a lattice over its surface. Pref. the lattice pitch of the depressions is smaller than the desired image resolution. The depressions may be conical in shape or parabolic. The small depressions concentrate the image-forming particles in a very large number of small groups or points, which reduce the coarseness of the image and lead to a high degree of resolution. It is thus possible for an electrophotographic image producing process to achieve a degree of resolution comparable with that of photographic or lithographic reproduction.

Description

Electrophotographic imaging process and

Record carrier for carrying out the method The invention relates to an electrophotographic imaging process in which on the photoconductive The recording layer of an intermediate recording medium contains an electrostatic charge image generated and colored this charge image with electrostatically attractable toner is, and in which the resulting toner image then on a seek temporary contact with the intermediate recording medium, final Transferred to recording medium and then peeling off the final recording medium from the intermediate recording medium to the surface of the final recording medium is melted.

A device for performing such a method is shown below many others, the German patent specification 15 72 330.

Copies produced by means of this known method show, at least compared to photographic or lithographic reproductions, one relative great graininess.

The cause of this graininess is that from image location to image location fluctuating Number of dye particles that develop during the development of the latent electrostatic Image to be deposited.

This irregularity, in turn, can have substantial causes such as unevenness of the photoconductor, fluctuation in developer particle size, roughness of the image carrier, locally different adhesiveness of the image carrier for dye particles, or functional Causes, such as local and temporal fluctuations in the charge on the photoconductor, locally fluctuating exposure, currents and turbulence during the development process or have the mathematical statistics of particle deposition. Especially the last one Influencing factor, namely the random character of the particle secretion, leads to the Uniformity of the deposited eilchenensemble a not to be fallen short of local fluctuation, which can only be achieved through special measures to order the Particle build-up can be remedied.

According to the invention, a final record carrier now arrives for use, which has a large number of grid-shaped depressions on its surface wearing. The grid division of the depressions of the final image is advantageous load-bearing layer is less than or equal to that required for the finished copy Image resolution, and it becomes a recording medium surface provided with conical pits or a recording medium surface provided with parabolic depressions used.

According to a further advantageous feature of the invention, the Transferring the toner image to a final copy carrier, at least its surface in the area between the grid depressions a relatively low wettability for has the fusing toner, and the fixing of the toner image is done in two Stages, wherein in the first stage the flow of the emollient toner into the Screen depressions and, in the second stage, the melting of the toner to the bottom the grid depressions is effected. Generally, that of the photoconductive layer Amount of continuously distributed toner particles transferred to the final image carrier converted into a discrete number of regularly distributed pixels, their total area is smaller than the total area of the continuously distributed amount of toner. Included The equation f = fo Må with J (< 1, where N is the number of toner particles that hit a surface element in the initial state and fo is the area occupied by these particles when distributed continuously means.

In this method according to the invention, as a result of the concentration of the particles that form the image are distributed over a discrete number of regularly Pixels in particular a significant reduction in graininess when the area of the individual pixels to a power of Number of particles is proportional, where the exponent is less than one. This can e.g. Reach depressions with a conical or parabolic surface line. Particularly favorable results are obtained with a higher order parabola, the cross section of which approaches a rectangle. A deposit of toner particles that interferes with the process on the recording medium surface outside the pits is by a for the melting or already melted toner particles difficult to wet surface at least the areas of the recording medium located outside the depressions and prevented by a two-stage fixing process.

A recording medium for carrying out the method according to the invention is characterized in that its surface by means of a calendering process or the like. Has embossed grid depressions, the surface line of the grid depressions of the general formula y - const. | x | 1 / n with n t 1 follows. E.g. the grid depressions be formed by conical cells or by parabolic cells. Advantageous the recording medium has one of the molten toner particles relatively heavy wettable surface. The grid-like depressions in the Embossed surface of a barite sheet of paper.

The undamaged surface of the baryta-coated paper is relatively small receptive to melted toner powder, while Im area of the indentations the original, slightly more absorbent paper structure with the melted one Toner powder comes into contact and thereby the cooling toner firmly with the recording medium connects.

The invention is explained in more detail in the drawing. Figure shows 1 shows a section through a recording medium surface which has a uniform Layer of toner particles in random distribution carries, Figure 2 is a section through the record carrier along the line II-II in Figure 1, Figure 3 the View of a recording medium with conical depressions from above, FIG 4 shows a section through a recording medium according to FIG. 3 along the line IV-IV in Figure 3, Figure 5 shows the view of the recording medium according to Figures 3 and 4 during a certain process stage; FIG. 6 shows a section through the recording medium along the line VI-VI in FIG. 5, and FIG. 7 shows a section through a recording medium with parabolic depressions.

Figures 1 to 6 show a recording medium 1, which with one is the wetting of the recording medium surface by the melting toner particles 3 aggravating top layer 2 is provided. The recording medium can e.g. consist of normal writing paper with a baryl layer. In the recording medium 1, conical depressions 4 are embossed, e.g. by means of a calendering process.

These recesses, which are arranged in the form of a grid, face each other in both coordinate directions have a distance or a grid division d. the conical ones Depressions 4 enclose a cone angle '<. Obey their surface lines the general formula y = const. xi 1 / n with n n 1. The surface area of the depressions enclosed amount of toner 6 is then calculated as f = const. V 2/3, where V represents the volume of the enclosed amount of toner 6.

According to FIG. 7, parabolic cells 7 are embossed in the recording medium 1, which are also arranged at a distance d from one another. Its surface line obeys the equation y = | xx 1 / n with nt 1. The surface of the enclosed amount of toner 6 is here f = const. V Ah +1 In Figures 1 and 2, an ensemble of particles is shown homogeneously distributed on the image carrier, whose numerical surface density, corresponding to the photometric image density, fluctuates around the mean value q, and which is to be converted into a discrete number of regularly distributed image points, the area of which is proportional to f is a power of the amount of dye M from which the individual pixel is built up, where the exponent; is less than 1: £ 0. N 1. (1) A simple model for representing the relationships between image density D, mean number of toner particles per unit area q and image density fluctuation 6 D is based on the application of the binomial distribution to the position of deposited dye particles. Assuming that the image density D obeys the law of the geometric coverage of a white area A with completely opaque (black) particles of cross-section a, AD - log A-qa (2), the standard deviation of the image density from its mean value results the laws of mathematical statistics the expression In equation (2), the area f covered by the color bodies is proportional to the number of grains present and their cross-section covered qa. (4) If there is a non-linear relationship between the covered area and the number of grains present, for example in the form = qaa, (5), equation (4) is modified and changes to the following form: In Table 1, values of D are calculated for various shape exponents.

Table 1: 42 j D (for a = 25 µ², A = 104 µ², Dmax = 2, D = 1) 1 0.108 0.9 0.073 0.75 0.035 0.66 0.021 0.50 0.0038 0.33 0.00016 It is found that the Density fluctuation # D, which manifests itself as graininess, with decreasing exponents j also decreases sharply.

A non-linear relationship between the area covered and the amount of dye indicated here by the number of dye particles arises whenever the dye is not in a theoretically infinitely thin layer is applied to the image carrier, but in the form of bodies of finite extent, only one cross-sectional area of which contributes to the image carrier coverage.

If the above is applied to the distribution shown in FIGS. 1 and 2, it can be seen that in this distribution many photometric measurements carried out from measurement field to measurement field would result in a frequency distribution of the density of the dye particles 3 per measurement field, the standard deviation of which is given by Eq. (3) is determined and, as Table 1 shows, has the value 0.108, for example. In contrast, FIGS. 5 and 6 show a calendered image carrier 1 provided with conical depressions 4 after taking over a xerographic powder image, in which the dye particles 3 are random, that is, obeying a statistical distribution law, which is caused by one or more of the substantial and / or functional causes listed above is given, are distributed. The majority of the dye particles 3, shown here as spheres of the same size for the sake of simplicity, have already collected in the conical depressions 4, while another part is still on the connecting webs between the depressions. A certain order has already been established in this first stage. Now become the toner particles. 3 heated so far in the course of the fixing process that they melt, they will with a suitable choice of their thermoplastic material and the substrate 2 due to the surface tension melt together to form spheres that do not wet the substrate 2, flow into the conical depressions 4 and these up fill up to a certain extent, as shown in Figures 3 and 4. After cooling, the image carrier surface 2 is no longer covered randomly with individual or coagulated toner particles 3, but with a regular arrangement of image points 6, the area of which has the value f 7 (3V tgd) 2/3 = const. q 2/3 if V is the volume of the pixel cone proportional to the fused color particle number. Since the exponent 2/3 is valid for the relationship between the covered area and the number of color particles, it can be seen from Table 1 that the density fluctuation, which is caused by a color particle number fluctuating per pixel cone, only has the value 0.021, i.e. only 19 »Of the original value.

If one goes over to the general cone, whose surface line, like figure 4 shows that a curve y = to xi 1 / n with n C 1 is obtained for the cover area as a function of the number of particles 2n f = const. q 2n + 1.

Table 2 shows the assignment of n to j or to the density fluctuations.

Table 2: n j #D [%] 1 2/3 19 1/2 1/2 3.5 1/3 2/5 0.5 1/4 1/3 0.15 It can be seen from this table that calendering of the image carrier 1 in the form of cones 7 with parabolic surface lines a very effective suppression who can achieve granularity.

Claims (13)

Protection claims 1.! Electrophotographic imaging process, at which on the photoconductive recording layer of an intermediate recording medium generates an electrostatic charge image and this charge image with electrostatic attractable toner is colored, and in which the so created The toner image is then temporarily transferred to the intermediate recording medium brought into contact final recording medium transferred and after Peeling off the final recording medium from the intermediate recording medium the surface of the final recording medium is melted, thereby characterized in that a final recording medium (1, 2) is used, which has a large number of grid-shaped depressions (4, 7) carries. 2. Imaging method according to claim 1, characterized in that the grid division (d) of the depressions (4,?) of those bearing the final image Layer less than or equal to the image resolution required for the finished copy is. 3. Imaging method according to claim 1 or 2, characterized in that that a recording medium surface provided with conical depressions (4) is used. 4. Imaging method according to claim 1 or 2, characterized in that that a recording medium surface provided with parabolic depressions (7) is used. 5. Imaging method according to one of claims 1 to 4, characterized in that that the toner image is transferred to a final copy carrier, the surface of which (2) at least in the range between. the grid depressions (4, 7) a relatively small Has wettability for the fusing toner, and that the fixation of the toner image takes place in two stages, the first stage being the inflow of the emollient Toner into the grid depressions and, in the second stage, the melting of the toner is effected at the bottom of the grid depressions. 6. Imaging method according to one of claims 1 to 5, characterized in that that transferred from the photoconductive layer to the final image carrier lot of continuously distributed toner particles (3) into a discrete one Number of regularly distributed pixels (6) is transferred, the total area (f) is smaller than the total area (fo) of the continuously distributed amount of toner. 7. Imaging method according to claim 6, characterized in that for the area of the discrete image point (6) the equation f I fo M j with a < 1 applies, where M is the number of elements that meet a surface element in the initial state Toner particles and fo that occupied by these particles when distributed continuously Area means. 8. Recording medium for carrying out the method according to a of claims 1 to 7, characterized in that its surface by means of a Xalander process or the like. Embossed grid depressions (4, 7). 9. Recording medium according to claim 8, characterized in that the surface line of the grid depressions (4, 7) of the general formula const. i x | 1 / n with n t 1 follows. 10. Recording medium according to claim 8 or 9, characterized in that that the grid depressions are formed by conical cells (4). 11. Record carrier according to Claim 8 or 9, characterized in that that the grid depressions are formed by parabolic cells (7). 12. Record carrier according to one of claims 8 to 11, characterized marked; that the recording medium (1) is one of the melted toner particles has relatively difficult to wet surface (2). 13. On recording medium according to claim 12, characterized in that that the grid-like depressions (4, 7) in the surface (2) of a barite Sheet of paper (1) are embossed.