FR2863935A1 - Dye sublimation printing method for printing photos on e.g. glossy paper, involves printing two parts of paper and overlap area in yellow color, magenta color and then in cyan color in respective printing passes - Google Patents

Abstract

The method involves printing a part (P1) of a paper and a color overlap area (R) in yellow color, magenta color and then in cyan color, in a primary printing pass. The overlap area and a part (P2) of the paper are printed in yellow color, magenta color and then in cyan color, in a secondary printing pass. The overlap area is printed with regressive intensity and with progressive intensity during the respective passes.

Description

Thermal sublimation printing method of a multiformat medium

  TECHNICAL FIELD OF THE INVENTION The invention relates to a thermal sublimation printing process of a multiformat medium. This method uses a thermal sublimation technology to print, in several printing passes, a medium that can have different formats.

  The invention finds applications in the general field of printing on a medium such as paper. In particular, the invention is applicable to the printing of digital photographs on glossy paper from a thermal sublimation technology printer.

  BACKGROUND ART OF THE INVENTION Currently, there are many techniques for printing on media and, in particular, on paper. A recent technique is to print digital photographs on glossy paper. This technique allows a user to obtain his digital photographs on paper, with a quality close to the photographs obtained with a conventional film process.

  This technique can be implemented with a thermal sublimation technology printer. For ease of use, printer manufacturers have made personal dye sublimation printers that can be connected to any personal computer. Thus, any user who has made digital photographs can print his photographs, on a specific paper, from his computer connected to a dye sublimation printer.

  Sublimation printing technology consists of generating the colors of the photograph (called simply photo) by successive diffusion of the three primary colors, namely yellow, magenta and cyan. For that, these colors are fixed, in the form of a wax, on a specific paper, called ribbon of colors. This color ribbon is transparent, covered with yellow, magenta and cyan waxes. These three primary colors form a series of invariable predefined sequences: first yellow, then magenta and finally cyan. Each color sequence has a specific dimension that corresponds to the length or width of the paper to be printed, depending on whether the printing is in the direction of the length of the photo or in the width without. For example, to print a 10 x 15 standard size photo, the color ribbon has three sequences (yellow, magenta, and cyan) of 10 x 15 dimensions, placed one after the other. The paper to be printed runs along the entire length of the color ribbon and a heating head is used to heat the ribbon with a greater or lesser intensity depending on the different zones of the photo, this intensity being a function of the color density that is wants to have on the picture.

  A fourth sequence placed after the cyan sequence comprises a layer of a protective material (called in English-coating terms) used to cover the entire photo, after printing, in order to protect it against ultraviolet rays. light, splashing water and other elements that could damage the picture.

  This technique has the advantage of being able to be used personally by the user who can print his digital photos himself. However, this method has the disadvantage that the color sequences have well defined dimensions that induce the paper format. As a result, if the color ribbon has color sequences of 10 x 15 cm, then the photos can only be printed in a 10x15cm format.

  Currently, for a user to make photographs of different sizes, he must have papers of different sizes and ribbons of colors of sizes adapted to each paper format. This therefore requires an investment, in terms of cost and space, for the user who must store these different papers and ribbons in anticipation of possible future use.

GENERAL DESCRIPTION OF THE INVENTION

  The purpose of the invention is precisely to overcome the disadvantages of the techniques described above. To this end, the invention provides a method for printing, by the thermal sublimation technique, papers of different sizes with standard format color ribbons. For this, the invention proposes to print the paper in two passes, or more, the first pass of printing a first portion of the paper with a lap area and the second pass of printing the second part of the paper with the same recovery area. It is thus possible to print a paper of a size larger than the format of the color sequences.

  More specifically, the invention relates to a method of printing a thermal sublimation support having a first printing pass consisting of printing a yellow color, then a magenta color and a cyan color. This method is characterized in that it comprises at least a second printing pass consisting of printing the yellow color, then the magenta color and the cyan color, the first pass including the printing of a first part of the support and a color recovery area, and - the second pass comprising printing said overlap area and a second portion of the support.

  Advantageously, the overlap zone comprises a first yellow overlap zone, a second magenta overlap zone and a third cyan overlap zone, the first zone adjoining the second portion of the support, the third zone adjoining the first portion of the support and the second zone being between the first and third zones.

  In a preferred embodiment of the invention, each color is printed in the overlap area with a decreasing intensity during the first pass and with a gradual intensity during the second pass.

BRIEF DESCRIPTION OF THE DRAWINGS

  The single figure shows a chronogram of the different printing steps, for two successive passes, according to the method of the invention.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION In the process of the invention, it is proposed to print the support, for example a paper, with the thermal sublimation technique, by successively applying several printing passes. In the embodiment to be described, two print passes are applied, one after the other. In the case where more than two passes are applied, the application of each pass is done in the same way as the application of the first pass as it will now be described.

  During the first pass, a first portion of the paper is printed as well as a covering area. In the second pass, the second part of the paper is printed together with the same area of coverage. This overlap area is located in the middle of the paper, between the first portion P1 of the paper and the second portion P2 of the paper. The middle of the paper is the middle of the length of the paper if it is printed in the direction of the length or the middle of the width of the paper if it is printed in the width direction. This overlap area extends across the full width of the paper if it is printed lengthwise or along the entire length of the paper if it is printed in the widthwise direction.

  As can be understood from the foregoing, the paper can be printed in length or width, the choice depending on, inter alia, the format chosen for the paper and the format of the color ribbon. In the following description, consider the case where the printing of the paper is in length.

  The single figure shows a chronogram of the different printing steps in the case of printing in two passes. In this figure, each rectangle schematically represents the paper to be printed, at a stage of its printing. Each printing step is thus represented by a rectangle, the first step being shown at the bottom of the figure. The fully printed paper according to the method of the invention is shown at the top of the figure.

  As seen in FIG. 1, the paper is divided into three parts: a first part P1, a second part P2 and a covering area R. The covering area R is divided into three zones a, b and c of size identical. The first zone, called zone a, is the overlap zone of the yellow color. This zone a is located at the limit of the second part of paper P2. The third zone, called zone c, is the area of coverage of the cyan color. This zone c is located at the limit of the first portion P1 of the paper. In other words, the area c adjoins the portion P1 of the paper and the area is adjacent to the second portion P2 of the paper. The second zone, called zone b, is the overlap area of the magenta color. This zone b is situated between zone a and zone c. In other words, looking from the left to the right of the figure, the paper has a first part P1 printed at the time of the first printing pass, then a covering area c, a covering area b, a covering area a and a second portion P2 printed during the second printing pass.

  During the first pass, the printing is done in four steps: printing of the yellow on the first part P1 of the paper as well as on the overlap areas b and c and printing with a progressive decrease in the intensity of the yellow in the area a printing of the magenta on the first portion P1 of the paper as well as on the overlap zone c and printing with gradual decrease of the intensity of the magenta in the area b, - printing cyan on the first portion P1 of the paper and printing with gradual decrease of the intensity of the cyan in the area c, - depositing a first protective layer on the first portion P1 of the paper, to the boundary between the first portion P1 and the recovery zone c.

  The second printing pass is carried out as follows: printing of the yellow on the second part P2 of the paper with progressive increase of the intensity of the yellow in the area a of covering, - impression of the magenta on the second part P2 of the paper as well as on the area a and printing with gradual increase of the intensity of the magenta in the area b of recovery, - printing of cyan on the second part P2 of the paper as well as on areas a and b of recovery and printing with increase progressive intensity of the cyan in the area c recovery, - deposition of a second protective layer on the total coverage area R and the second portion P2 of the paper.

  In the figure, the bottom rectangle shows the first step of the first print pass. The impression of the yellow color on the part P1 and the zones b and c is represented in speckles. The overlap zone is printed in yellow with a decreasing intensity (that is to say a gradual decrease) represented by more spaced speckles. The second part P2 of the paper is white because it is not printed.

  In the second step of the first pass, the magenta color is applied, represented by a right-to-left hatching, on the first portion P1 of the paper and the area c of overlap. The hatchings on the overlap zone b are further spaced to represent the degressive intensity of the magenta on the overlap zone b. The overlap zone a and the P2 portion do not have magenta printing.

  In the third step of the first pass, the cyan color is applied, represented by hatching from left to right, on the first portion P1 of the paper. The hatching on the overlap zone c is further spaced to represent the degressive intensity of the cyan on the overlap zone b. Areas a and b overlap and P2 do not include cyan printing.

  The fourth step of the first pass consists in covering the first part P1, totally printed, with a protective layer represented by zigzag lines. This protective layer must never cover the color recovery area, because it would prevent printing in this area, colors during the second printing pass.

  In the first step of the second pass, the yellow color is applied, represented by speckles, on the second part P2 of the paper and on the zone a. The speckles of the overlapping zone have the same spacing as those of the parts P1 and P2 to schematize the same intensity of the yellow. The printing of the yellow on the zone has, during the first printing pass, added to the printing of the yellow on the same zone a, during the second printing pass, provides the same intensity of printing in this area. zone a if the paper had been printed in one pass. The first part P1 is totally printed and protected. The recovery zones b and c are in the same state as in the third step of the first printing pass.

  In the second step of the second pass, the magenta color is applied, represented by right-to-left hatching, on the second part P2 of the paper and on the zones a and b. The hatchings of the overlap zone b have the same spacing as those of the portions P1 and P2 to schematize the same intensity of the magenta. Magenta printing on area b, on the first print pass, plus printing magenta on the same area b, on the second print pass, provides the same print intensity in this area. zone b only if the paper had been printed in one pass. The recovery zone c is in the same state as in the third step of the first printing pass.

  s In the third step of the second pass, the cyan color is applied, represented by hatching from left to right, on the second part P2 of the paper and on the zones a, b and c. The hatchings of the overlap zone c have the same spacing as those of the portions P1 and P2 to schematize the same intensity of the cyan. Cyan printing on area c, during the first printing pass, added to printing cyan on the same area c, during the second printing pass, provides the same print intensity in this area. area c only if the paper had been printed in one pass.

  The yellow, magenta and cyan colors are printed with a progressive intensity, that is to say a gradual increase in intensity, respectively, in zones a, b and c. In this way, the final intensity of these colors in zones a, b and c, after the first and the second printing pass, is the same as that which would have been obtained if the printing had been done in one print pass.

  At the end of this third step of the second pass, the paper is completely printed, on the parts P1, P2 and on the covering area R. The fourth step of the second pass consists in covering the part P2 and the covering area R a layer of protective material, schematized by zigzag lines. The protective layer, in this second printing pass, is placed at the edge of the first protective layer deposited during the first printing pass.

  The process as just described is carried out with a conventional printer and a standard color ribbon. To print all the paper, the paper is inserted into the printer and undergoes a first printing pass, as just described, with a first series of color sequences. The paper is then moved and undergoes the second printing pass, with a second series of color sequences.

  In the process just described, the recovery zones a, b and c are intended to avoid the creation of a break line, which would exist if the printing of each color stopped clearly, over the entire width of the paper. This break line would be, on the one hand, a spatial breakage because it is difficult to start a second printing pass exactly where the first pass ends and; on the other hand, a break in the intensity of the color. Indeed, as and when printing a paper, the temperature in the printer increases. It takes a little less energy to achieve the same intensity. Thermal compensation then makes it possible to obtain homogeneity between the beginning and the end of the printing. Without a color overlap area, intermediate between the first and the second portion of paper, the rupture zone would be visible at the boundary between the first portion of the paper and the second portion of the paper. The color recovery zone R thus makes it possible to avoid this line of rupture and to ensure a smoothing of the imperfections.

  In the process of the invention, the overlapping zone is advantageously divided into as many zones as there are colors to be printed. The overlap zone is thus divided into three zones, each of these three zones ensuring the recovery of a color. The overlap of each zone is made according to the same series of color sequences as the sequences imposed during the first printing pass. If the three-color overlap area were at the same location, then it would require six heat-up passes over the entire lap area. There would be a high risk of over-sublimation. For example, if you print the yellow color and print over the magenta color, then some of the scattered yellow color may go up in the magenta color ribbon, which has the effect of reducing the color intensity. yellow in the overlap area. There is then over-sublimation. Indeed, there is no additive property of the recovery. So, the higher the number of prints in one place, the more sensitive the paper is to over-sublimation. The division, in three successive zones, of the recovery zone makes it possible to limit these risks of over-sublimation. Indeed, in this case, each area a, b, c of recovery does not undergo printing each color printing pass. For example, the area has a single print on the first print pass; she.

  then undergoes three impressions during the second printing pass. Thus, like each zone a, b, c of the overlap zone, the zone a undergoes only four impressions, that is to say four heating steps, which reduces the risk of over-sublimation.

  In addition, the method of the invention makes it possible to respect the initial sequencing of the colors, that is to say, yellow, magenta and cyan, essential criterion for obtaining good color reproduction and therefore a good quality of printing. It is noted that in the invention, a color is applied only when the previous color is permanently printed. For example, magenta is only printed when the yellow has been permanently printed.

  As previously explained, the intensity of color printing has no additivity property. Also, to obtain a color intensity of 50%, it is not possible to make a first pass at 25% and a second pass at 25%. Indeed, applying twice 25% intensity of a color does not achieve the same result once 50% intensity of the same color. Also, to correct this effect of non-additivity, the invention proposes a corrective function to compensate for this phenomenon. This correction function consists of a correspondence table that gives the percentage of intensity to be applied to each pass to obtain the desired total intensity. This correspondence table is obtained through a calibration performed, either for each color, or generally for the set of colors.

  In the preferred embodiment of the invention, a correspondence table is produced by color. Each correspondence table is made by calibration, taking into account the characteristics of the paper, the color ribbon and the machine, in terms of the diffusion of the color in the paper. This calibration can be performed by printing a value of 100% and looking at the behavior of the printing for different percentages, between 1 and 100%. This calibration can be performed for a defined number of levels, for example between 10 and 20, all the other levels being deduced by interpolation.

  In one variant of the invention, a single correspondence table is produced making it possible to optimize the percentage to be applied globally for the three colors.

  Throughout the foregoing description, it has been described that the intensity of each color is degressive or progressive in areas a, b and c of overlap. However, the modulation of each color in these areas can be different from a variation of intensity. For example, the modulation of each color can be achieved by a variable spatial distribution. In this case, instead of modifying the intensity gradually (increasing or decreasing) at each printing pass, it is possible to modify the number of heating points in these zones. For example, the number of heating points can be reduced by half in the zone a of yellow overlap, during the first printing pass, and by three quarters of the number of heating points, during the second pass io d 'impression. The spatial distribution to be applied is given, as for the intensity, by a correspondence table.

  In one variant, the variation of the spatial distribution is combined with the variation of the intensity of the colors, in each zone a, b, c of overlap. This combination provides greater flexibility and a wider range of possible overlays.

  In these cases of variation of the spatial distribution, the separation between the different overlapping zones is not necessarily linear, as shown in the single figure. This separation can be performed in a random pattern.

  As can be understood from reading the foregoing, the method of the invention has the advantage of making it possible to print papers of different sizes using the same standard color ribbon. For example, a color ribbon whose color sequences make it possible to print a paper of size 10 × 15 cm can be used, with the method of the invention, to produce panoramic photos of a format of the order of 18 x 15 cm or 10 x 28 cm, which is twice the standard format which subtracts the width of the overlap area which may be, for example, of the order of 2 cm.

  The method of the invention also makes it possible to take pictures of even greater dimensions by making more than two successive passes. For example, a panoramic image can be printed, with the method of the invention, in a size of the order of 10 x 41, which corresponds to three printing passes in the direction of the length of the paper.

  The invention also makes it possible, by using color ribbons having color sequences smaller than the standard format, to combine two, three or more color sequences to obtain a photo of a chosen format. As a result, the method of the invention makes it possible to remove the constraint, present until now, on the size of the color sequences of the ribbon which imposes the size of the paper.

Claims (7)

  A method for printing a thermal sublimation medium comprising a first printing pass consisting of printing a yellow color, then a magenta color and a cyan color, characterized in that it comprises at least one second printing pass of printing the yellow color, then the magenta color and the cyan color, - the first pass comprising printing a first portion (P1) of the support and a color covering area (R), and - the second pass comprising printing said overlap zone (R) and a second portion (P2) of the support.   2 Method according to claim 1, characterized in that the overlap zone comprises a first zone (a) for covering the yolk, a second zone (b) for covering the magenta and a third zone (c) for covering the cyan, the first zone adjoining the second part of the support, the third zone adjoining the first part of the support and the second zone being between the first and third zones.   Method according to claim 2, characterized in that the first printing pass comprises: - the printing of the yellow color in the first, the second and the third overlapping areas, - the impression of the magenta color in the second and third overlapping areas; - printing the cyan color in the third overlap area; and the second printing pass comprising: - printing the yellow color in the first overlapping area; printing the magenta color in the first and second overlapping areas, printing the cyan color in the first, second, and third overlapping areas.   Method according to any one of claims 1 to 3, characterized in that each color is printed in the overlap area with a decreasing intensity during the first pass and with a progressive intensity during the second pass.     Method according to any one of claims 1 to 4, characterized in that it comprises, between the first and second passes, a first step of depositing a protective layer on the first part of the support and, after the second passes, a second step of depositing a protective layer on the second part of the support and on the overlap area.   Method according to any one of claims 4 and 5, characterized in that the decay and the intensity progression are defined in at least one correspondence table, as a function at least of the color diffusion capacity in the medium.   Method according to claim 6, characterized in that a correspondence table is established for each color.   Method according to any one of claims 1 to 3, characterized in that each color is printed in the overlap zone with a degressive spatial distribution during the first pass and a progressive spatial distribution during the second printing pass.