DE69914682T2 - Optically writing printhead and optically writing printer - Google Patents

Description

The The invention relates to an optically writing printhead for one A printer capable of printing by an optical recording wavelength Select color and the density of developed color by the optical recording performance to control, for example, a printer that is using printing paper thereon applied photosensitive microcapsules and one with this Printhead equipped optically writing printer.

at one with printing paper with photosensitive Microcapsules working printer is used to form a latent Image scanned the printing paper by means of a printhead, the with three types of light (for example, red, green and blue light) emitting Sources equipped, and to carry out the development of a mechanical Print by means of a pressure roller on the printing paper with the on it trained latent image exercised. The printing paper is in made the way that you can evenly photosensitive on a base paper Applying microcapsules with a diameter of about 4 microns, on it an image receiving layer including developer applies and above laminated a polyester film. The microcapsules themselves are translucent and simply consist of tiny, made of gelatin transparent Capsules whose strength is chosen so is that they collapse under the mechanical pressure of the pressure roller.

If under the light types R, G and B a kind of light, d. H. monochrome Light, selected and on a full-color printing paper with three applied thereon Types of photosensitive microcapsules is emitted, react of the three types of photosensitive microcapsules, d. H. the M, Y and C microcapsules, only those photosensitive microcapsules with the light, which is a light-curing, complementary to the selected monochromatic light Contain material and harden out while the other two types do not harden. Will, for example, red light irradiated, that reacts in the photosensitive C microcapsules contained light-curing material with the red light and hardens out while the other two types of photosensitive microcapsules (i.e. Microcapsules M and Y) do not harden. When in this state printing by means of a pressure roller on the printing paper exercised the photosensitive M and Y microcapsules completely collapse, while the photosensitive C-microcapsules not depending on the extent of curing or only incomplete to collapse. This allows development materials of the colors M and Y are in contact with the image-receiving layer of the printing paper, and the corresponding area develops the color red, d. H. the Mixture of M and Y. The hue of the red color that makes up the mix M and Y varies according to the extent of curing of the photosensitive C microcapsules. The reason is in that the photosensitive C microcapsules collapse when even incomplete, and a color C developing material having the image-receiving layer got in contact. Likewise, upon irradiation of light the color becomes G the color green, d. H. the mixture of Y and C, developed. And if light of color B is irradiated, the color blue, d. H. the mixture as M and C, developed.

Short So, if one of three kinds of light different wavelength, d. H. R, G or B, selected and on the full-color printing paper with the applied three types of photosensitive microcapsules are irradiated, the area in which the selected light is radiated develops a color representing the mixture of M and Y, Y and C or C and M. When two kinds of light of the colors R, G and B are selected and to be irradiated on the full-color printing paper, the developed Area that with the selected two kinds of light is irradiated, one color according to M, Y or C. Areas that are not irradiated with any of these types of light develop a color that matches all the colors M, Y and C, d. H. Black, corresponds. Hue, color and brightness of the print are determined by adjusting the intensity of the incident light and the duration of the radiation.

A printhead for printing on a full-color printing paper having photosensitive microcapsules coated thereon according to the above-described method comprises, for example, U.S.P. 6 a printhead 1 with light emitting devices for selectively radiating light on the printing paper to form a latent image, a pressure roller 2 for applying pressure to the printing paper having the latent image formed thereon for carrying out the development, a carriage 3 , a paper transport mechanism 4 for the movement of the printing paper at a predetermined speed in one direction, a display unit 5 with semiconductor display devices, a drive part 6 and a control part 7 , The drive part 6 comprises a PWM type photosensitive control circuit for controlling the selective light output and the amount of radiation of the LEDs of the printhead 1 a carriage driving part for reciprocating the carriage 3 in a direction perpendicular to the direction of movement of the printing paper, a roller driving part for driving the pressure roller 2 a paper transport driving part for driving the paper transport mechanism 4 and a drive part for the display unit. In addition, the printer includes input means 8th for inputting image data by a flash memory card or transmitted signals of an imaging device, such as a digital camera, are provided, and adjusting means 9 for setting various parameters of the printer and for image processing in the control section 7 ,

As in 7 can be seen, shows an exemplary conventional printhead 1 for printing on full color printing paper nine on a head substrate 10 in three rows and three columns provided on LEDs. The first column is a red LED group consisting of the LEDs 11R1 . 11R2 and 11R3 , the second column is a green LED group consisting of the LEDs 11G1 . 11G2 and 11G3 , and the third column is a blue LED group consisting of the LEDs 11B1 . 11B2 and 11B3 , an aperture plate 13 has nine beam-limiting pores arranged in three rows and three columns. The first column is a beam confinement pore group for the red LEDs, consisting of the beam confinement pores 12R1 . 12R2 and 12R3 the second column is a beam confinement pore group for the green LEDs, consisting of the beam confinement pores 12G1 . 12G2 and 12G3 and the third column is a beam confinement pore group for the blue LEDs, consisting of the beam confinement pores 12B1 . 12B2 and 12B3 , The beam-limiting pores are each arranged so that they are concentric with the corresponding LEDs.

As described above, the printhead 1 not just one but three LEDs as light-emitting sources for the colors red, green and blue respectively. The reason for this is that when a latent image having a resolution that can be reproduced by the printer is to be applied to the printing paper having photosensitive microcapsules applied thereto, the light beams of the LEDs must be limited so that the color development diameter becomes approximately Resolution corresponds, and the light energy of only one LED per color is not sufficient. In this context, the color development diameter of the light beam means the diameter of the light beam local area of an LED as a light-emitting source on printing paper having photosensitive microcapsules applied thereon, ie the diameter of an exposure point that substantially corresponds to the pore size of the beam confinement pores in the aperture plate.

If four or more light-emitting sources per color are provided instead of the three light-emitting sources, sufficient light energy can be achieved. However, this is contrary to the requirements placed on a small printer, such as lower costs, smaller size and better energy savings, and is therefore not realistic. In addition, one might consider improving the sensitivity of the printing paper with photosensitive microcapsules applied thereto, but currently the situation is such that sensitivity can not be significantly increased for handling purposes. Therefore, in practice printheads are used with not just one, but two or three red, green and blue LEDs as light-emitting sources. In order to achieve sufficient light energy in this limited number of light-emitting sources, the pore size of the beam-limiting pores in the aperture plate 13 not equal to the resolution, but is chosen one and a half times the resolution (see the circles in 4 ). This entails the problem that pixels adjacent to the print pixel are also irradiated, the dispersibility of the print pixels is reduced and the image appears blurred. Moreover, because this blurred appearance of the image is caused by light energy, there is a problem that energy is wasted.

A The object of the invention is an optically writing Printhead capable of producing a clear latent image on photosensitive printing paper, such as a printing paper with photosensitive applied thereto Microcapsules, and one equipped with the printhead optically to provide writing printer. Another object of the invention is to put in an optically writing printhead, the Light-emitting module that emits a variety of light Sources for each of N (where N is an integer equal to or greater than 1) different types of light sources are applied to a substrate wavelength and contains an aperture plate, the module emitting at a predetermined distance from the light is arranged and having Strahlbegrenzungsporen, the therein Positions are formed, which are the light-emitting sources which emitted from the light-emitting sources Energy efficient for to use the optical recording.

In order to solve the above-described problems, an optical writing printhead is composed of at least a light emitting module having N kinds of light emitting sources deposited on a substrate and having different wavelengths for printing, and light emitting sources for preexposure provided for the respective wavelengths, and an aperture plate disposed at a predetermined distance from the light emitting module and having beam confinement pores formed therein at positions associated with the light emitting sources, and the pore size of the beam confinement pores in the aperture plate corresponding to the light emitting sources for printing determined so that the diameter of the developed color of the beam from the Strahlbegrenzungspo The emitted light beam is approximately equal to the resolution of the printer, while the pore size of the beam confinement pores in the aperture plate corresponding to the light emitting sources is larger than that.

When Light emitting sources for the pre-exposure will be light-emitting sources that are the same wavelength as the corresponding light emitting sources for Print, or white Light emitting sources, such as white LEDs used. As N types from light emitting sources to print, the different wavelength are those consisting of a red LED, a green LED and a blue LED, consisting of light emitting Discharge lamps or those consisting of incandescent lamps with a wavelength filter and optical shutters used.

to solution The problems described above also exist in an optical writing printhead, with the printing paper with it applied photosensitive microcapsules for forming a latent image scanned by means of an optically writing printhead and to carry out the Develop a mechanical pressure by means of a pressure roller applied the printing paper with the latent image applied thereto is, the optically writing printhead from at least one light emitting module and one at a predetermined distance from Light emitting module arranged aperture plate. The light emitting module consists of a red LED for printing, one green LED for printing and a blue LED for printing on one Substrate are provided, and a red LED for the pre-exposure, a green one LED for the pre-exposure and a blue LED for the pre-exposure, for the red, green or blue color are provided, and the aperture plate has beam confinement pores, formed therein corresponding to the LEDs for printing positions are, wherein the pore size of the Strahlbegrenzungsporen determined so that the diameter of the developed color of the emitted by the pores of the light beam about the resolution of Printer, and further Strahlbegrenzungsporen therein on the LEDs for the Preexposure corresponding positions are formed, wherein the pore size of this Beam limiting pores is determined so that the diameter of the developed color of the radiated by the beam-limiting pores Beam is larger as the resolution of the printer. With another optically writing printer instead of the red LED for the pre-exposure, the green LED for the Pre-exposure and blue pre-exposure LED white LEDs intended.

The Invention will be described below with reference to an illustrated in the drawing embodiment explained in more detail.

It demonstrate:

1 a perspective view of an embodiment of an optically writing printhead according to the invention;

2 a graphic representation of the printing properties of printing paper with applied photosensitive microcapsules, ie the relationship between radiant energy and density of the developed color;

3 a representation of a red line that has been printed on printing paper with applied photosensitive microcapsules and that corresponds approximately to the resolution of a printer;

4 a diagram for explaining the size and number of the radiation local circles and the number of beams in the case that the red line according to 3 printed and that printing paper is irradiated with photosensitive microcapsules applied thereto;

5 a cross section of an embodiment of a carriage with a printhead of a printer, which works with printing paper with photosensitive microcapsules applied thereto;

6 a block diagram of the construction of a printer that works with printing paper with applied photosensitive microcapsules; and

7 a perspective view of a conventional optically writing printhead.

In 1 showing an embodiment of the invention is a perspective view of a printhead used for printing on full-color printing paper 1 shown. The printhead 1 in 1 has a light-emitting module consisting of nine in three rows and three columns on a printhead substrate 10 applied LEDs. The first column is a red LED group consisting of the LEDs 11R1 . 11R2 and 11R3 , the second column is a green LED group consisting of the LEDs 11G1 . 11G2 and 11G3 , and the third column is a blue LED group consisting of the LEDs 11B1 . 11B2 and 11B3 ,

Among the nine LEDs that belong to the light-emitting module are in the first row on the substrate light-emitting sources for the pre-exposure, namely the red LED 11R1 , the green LED 11G1 and the blue LED 11B1 ,

In this context, pre-exposure means the previous irradiation of the medium immediately before the printing operation is performed on a medium on which an optically writing printhead can not record light unless a certain light level is given, as in, for example, US Pat Printing paper with applied photosensitive microcapsules is the case to apply a Lichtener power on the medium, in which the printing process can not be performed immediately, but immediately afterwards efficiently. In 2 are the printing properties of printing paper with applied photosensitive microcapsules shown. The horizontal axis corresponds to the light energy which an optically writing printhead applies to the printing paper while the vertical axis represents the printing density on the printing paper. In the case of printing paper with photosensitive microcapsules coated thereon with the in 2 The light energy used for the pre-exposure corresponds to a threshold value (at the point P of the characteristic curve) in which a transition from a state in which virtually no change is observed into a state in which a significant change is observed with increasing light energy ,

Among the nine LEDs of the light-emitting module are N kinds of light-emitting sources for printing, which are mounted on the substrate and have different wavelengths, namely three types of light-emitting devices of different wavelengths, ie the red LED 11R2 , the green LED 11G2 and the blue LED 11B2 in the second row and the red LED 11R3 , the green LED 11G3 and the blue LED 11B3 in the third row.

In an aperture plate 13 are formed in three rows and three columns nine Strahlbegrenzungsporen. The first column is a beam confinement pore group for the red LEDs, consisting of the beam confinement pores 12R1 . 12R2 and 12R3 the second column is a beam confinement pore group for the green LEDs, consisting of the beam confinement pores 12G1 . 12G2 and 12G3 , the third column, a beam-limiting pore group for the blue LEDs, consisting of the beam-limiting pores 12B1 . 12B2 and 12B3 , The beam-limiting pores are each arranged so that they face the corresponding LEDs.

In the above nine beam confinement pores, the pore size is the beam confinement pore 12R1 for the red LED, the beam limiting pore 12G1 for the green LED and the beam limiting pore 12B1 for the blue LED in the first row, the red LED 11R1 , the green LED 11G1 or the blue LED 11B1 in the first row on the printhead substrate 10 so determined that the diameter of the developed color of the light beam radiated from these beam confinement pores is greater than the resolution of the printer. In this case, this diameter is substantially larger than the pore size of the in the aperture plate 13 of the conventional printhead 1 according to 7 provided Strahlbegrenzungsporen.

In the above nine beam confinement pores, the pore size is the beam confinement pore 12R2 for the red LED, the beam limiting pore 11G2 for the green LED and the beam limiting pore 12B2 for the blue LED in the first row, the red LED 11R2 , the green LED 11G2 or the blue LED 11B2 in the second row on the printhead substrate 10 and the beam-limiting pore 12R3 for the red LED, the beam limiting pore 12G3 for the green LED and the beam limiting pore 12B3 for the blue LED in the second row, the red LED 11R3 , the green LED 11G3 or the blue LED 11B3 in the third row of the printhead substrate, it is determined that the diameter of the developed color of the light beam radiated from these beam confinement pores is approximately equal to the resolution of the printer.

A side plate 14 holds the aperture plate 13 at a predetermined distance from the printhead substrate 10 and also serves as a cover. Between the LEDs provided partition plates, which are intended to prevent the horizontal leakage of light from the LEDs are also provided in the printhead according to the invention, in 1 however omitted to clarify the positional relationship between the LEDs and the beam confinement pores.

5 shows a sectional partial view of an embodiment of the carriage 3 with a dedicated print head 1 and a pressure roller 2 , The sled 3 consists essentially of a generally box-shaped carriage element 18 that on a guide rail 21 runs, and a printhead receptacle 19 and a pressure roller holder 20 both at a lower portion of the carriage element 18 are attached. The sled 3 is moved back and forth by the carriage driving part in a direction perpendicular to the paper transport direction. It should be noted that a drive mechanism 22 for driving the carriage element 18 Part of a consisting of a drive motor and a power transmission slide drive part is. In the 1 not shown separating plates 15 are provided between the red LED group in the first column and the green LED group in the second column, or between the green LED group in the second column and the blue LED group in the third column.

According to one embodiment of an optically writing printer according to the invention is scanned in an optical writing printer, the printing paper with photosensitive microcapsules applied thereto by means of an optically writing printhead to form a latent image and on the printing paper with the latent image formed thereon to carry out the development means a pressure roller is applied, the optically writing printhead as shown in FIG 1 built up.

Specifically, the optically writing printhead used in the optical writing printer of the present invention comprises 1 that on the printhead substrate 10 provided light-emitting module, consisting of the red LEDs 11R2 and 11R3 for printing, the green LEDs 11G2 and 11G3 for printing, the blue LEDs 11B2 and 11B3 for printing and the red LED 11R1 for the pre-exposure, the green LED 11G1 for the pre-exposure and the blue LED 11B1 for the pre-exposure for the red, green or blue color, and the aperture plate 13 is disposed at a predetermined distance from the light-emitting module and contains the beam-limiting pores formed therein 12R2 and 12R3 . 12G2 and 12G3 respectively. 12B2 and 12B3 positions corresponding to the LEDs for printing, wherein the pore size of the beam confinement pores is determined such that the diameter of the developed color of the light beam emitted from these pores approximately matches the resolution of the printer and the beam confinement pores formed therein 12R1 . 12G1 and 12B1 the positions corresponding to the pre-exposure LEDs, wherein the pore size of the beam-limiting pores is determined such that the diameter of the developed color of the light beam emitted by these beam-limiting pores is greater than the resolution of the printer.

A printer according to the invention which prints on full-color printing paper with photosensitive microcapsules applied thereto, as described, for example, in US Pat 6 is shown includes the printhead 1 , the pressure roller 2 the sled 3 , a paper transport mechanism 4 , a display unit 5 with semiconductor display devices, a drive part 6 , a control part 7 , Input means 8th and adjustment means 9 , The control part 7 comprises a central processing unit, a ROM, a RAM, an input / output interface I / O and a bus connecting these elements. The drive part 6 comprises a PWM type photosensitive control circuit for controlling the selective light output and the amount of light emitting devices of the printhead 1 emitted light, a carriage driving part, a roller driving part, a paper transport driving part and a driving part for the display unit.

When printing on full-color printing paper with photosensitive microcapsules coated with the in 2 illustrated printing properties by means of in 1 illustrated optically writing printhead 1 which has the light-emitting module with the light-emitting sources for printing and the light-emitting sources for the pre-exposure, the exposure is performed by the print head 1 if this is in a through the arrow in 1 designated direction moves. Specifically, first, a pre-exposure is provided by the light-emitting sources for pre-exposure provided in the first row, ie, the red LED 11R1 , the green LED 11G1 and the blue LED 11B1 By passing this light through the appropriate beam-limiting pores 12R1 . 12G1 and 12B1 blast on the printing paper.

Immediately after the preexposure, the light emitting sources provided in the second row lead to printing, ie the red LED 11R2 , the green LED 11G2 and the blue LED 11B2 , in the first stage of the printing process, passing through the beam-limiting pores 12R2 . 12G2 and 12B2 Blast light onto the printing paper. Immediately after the printing operation of this first stage, the light emitting sources provided in the third row, ie, the red LED, lead 11R3 , the green LED 11G3 and the blue LED 11B3 , the second stage printing process by passing light through the corresponding beam-limiting pores 12R3 . 12G3 and 12B3 blast on the printing paper. This completes printing for a specific pixel.

It should be noted that 4 , where eighteen circles of the same diameter are arranged at regular intervals, with these circles the locations of the LEDs of the printhead 1 indicated by the corresponding Strahlbegrenzungsporen emitted light rays in the event that an in 3 Red line L shown, that is, a red line of the width corresponding to the resolution of the printer and a length equal to four times the resolution of the printer is printed on full-color printing paper with photosensitive microcapsules applied thereto. It should be noted that in 3 the fourteen squares W around the red line L indicate white data.

In 4 the case is shown that a printhead, each with one LED for the red, green or blue color and a respective Strahlbegrenzungspore of the same diameter for the exposure of all circles a, b, c and d is used with one LED per color. When white data is printed in this area, an area A is exposed twelve times since all the circles a, b, c and d are exposed by the LEDs for the three colors. When printing the in 3 1, one of the twelve exposures consists of an exposure for printing red data. Therefore, the area A is exposed twelve times, area B five times, area C four times, and area D twice. When using the in 7 The number of exposure times is in each case three times as high, as shown in the case of the conventional printhead with three LEDs in each case and one corresponding beam-limiting pore of the same diameter. How out 3 and 4 As can be seen, in the conventional printhead, the exposure number is not the same everywhere due to the LEDs in the print area of the red line surrounded by the white data. In the middle area the number is small, while in the peripheral area it is at most five times higher than in the middle area. This allows printing a clear red line like this in 3 is shown.

On the other hand, in the optical writing printhead of the present invention which uses preexposure and printing exposure, the exposure to the preexposure LEDs is effected by the beam confinement pores whose pore size is determined so that the diameter of the developed color of the light beam is larger than the resolution of the printer. ie in particular that the beam local circle is larger than the beam local circle in 4 and the exposure to the LEDs for printing by the beam confinement pores whose pore size is determined so that the diameter of the developed color of the light beam approximately matches the resolution of the printer. According to the present invention, the pre-exposure ray localizer circles overlap, as usual, but since the pre-light emitting radiation energy does not reach the threshold, but only approximately, the preexposure does not cause printing on the printing paper having photosensitive microcapsules applied thereto.

Immediately after the preparatory pre-exposure, the exposure is made by the LEDs for printing. Since the exposure to the pressure causes an increase in the light energy and the light energy immediately in 2 The pressure density begins to change immediately and increases along the in 2 shown characteristic substantially linear from. Moreover, since the exposure through the LEDs is for printing through the beam confinement pores whose pore size is determined so that the diameter of the developed color of the light beam approximately matches the resolution of the printer, adjacent beam localizing circles for printing do not overlap one another that an extremely clear pressure arises.

In the above-mentioned embodiment of the optically writing printhead in which three LEDs each for the red, green and blue colors are arranged in the three columns and the three rows, the pre-exposure LEDs are only in the first column. However, the second column may also contain the LEDs for the pre-exposure and only the third column the LEDs for the print. In this case, it is preferable that the pore size of the beam confinement pores in the second column in the aperture plate 13 corresponding to the pre-exposure LEDs in the second column, are determined so that the diameter of the developed color of the light beam emitted from these beam confinement pores is larger than the resolution of the printer.

It should be noted that an optical writing printhead according to the invention is not only designed in such a way that, as shown in FIG 1 shown as light-emitting sources for the pre-exposure used such light-emitting sources having the same wavelengths as the respective corresponding light-emitting sources for printing, but also using white light-emitting sources, such as white LEDs.

Likewise, an optical writing printhead according to the present invention can be performed not only in such a manner that as N kinds of light emitting sources of different wavelengths for the printing as in FIG 1 which uses light emitting sources composed of the red LEDs, the green LEDs, and the blue LEDs, but also using light emitting sources composed of charge lamps, wavelength filter filters, and optical shutters.

One inventive optically writing printer consists of an optically writing printhead with a light-emitting module, the light-emitting sources for the Pre-exposure and light-emitting sources for printing, and a arranged at a predetermined distance from the light emitting module Aperture plate with therein at the sources emitting light correspond, trained Strahlbegrenzungsporen, and the pore size of the Light emitting sources for the pressure corresponding beam limiting pores in the aperture plate is determined so that the diameter of the developed color of the from this Strahlbegenzungsporen radiated light beam, for example the resolution the printer matches while the pore size of the light emitting sources for the pre-exposure corresponding beam limiting pores in the aperture plate is larger as those with which the optically writing printhead with it the extraordinary Advantage that he is extremely clear can print.

In addition, while not only the pressure is not clear in a conventional optical writing printhead, but also in the Er According to this unclear pressure light energy is wasted, these disadvantages do not occur according to the invention and the light energy is used efficiently, resulting in various effects, such as improved energy savings, improved power savings and lower heat generation. Therefore, not only the optical writing printhead of the present invention but also a printer equipped with this advantageous printhead result in effects such as smaller size and lower cost.

Claims (9)

Optically writing printhead comprising: one light-emitting module, the N kinds of light-emitting sources contains for printing which are mounted on a substrate and have different wavelengths, and light emitting sources for contains the pre-exposure, the for the respective wavelengths are provided; and an aperture plate that is in a given Distance from the light-emitting module is arranged and beam-limiting pores formed therein at positions that the light-emitting Sources are assigned, wherein: the pore size of the beam-limiting pores in the aperture plate, which are the light emitting sources for printing are assigned, it is determined that the diameter of the developed Color of the light beam emitted by the beam-limiting pores is about equal to the resolution the printer is; and the pore size of the beam-limiting pores in the aperture plate, which are the light-emitting sources for the pre-exposure are assigned, is greater as those. An optically writing printhead according to claim 1, wherein the light-emitting sources for the pre-exposure, respectively have the same wavelengths like the corresponding light emitting sources for printing. An optically writing printhead according to claim 1, wherein the light-emitting sources for the pre-exposure white light sources are. An optically writing printhead according to claim 3, wherein the light-emitting sources for the pre-exposure white LEDs are. An optically writing printhead according to claim 1, wherein the N kinds of light-emitting sources for printing, the different wavelengths have a red LED, a green LED and a blue LED be formed. An optically writing printhead according to claim 1, wherein the N kinds of light-emitting sources for printing, the different wavelengths to be formed by light-emitting discharge lamps. An optically writing printhead according to claim 1, wherein the N kinds of light-emitting sources for printing, the different wavelengths comprise, are formed by filament lamps, which have a wavelength filter and optical locks use. Optically writing printer for scanning printing paper with photosensitive microcapsules on it with an optically writing Printhead are applied to form a latent image, and to exercise a mechanical pressure on the printing paper with the latent formed thereon Image using a pressure roller to perform a development, wherein the optically writing printhead comprises: a light-emitting Module containing: a red LED for printing, a green one LED for printing and a blue LED for printing on a substrate are attached; and a red LED for the pre-exposure, a green LED for the pre-exposure and a blue LED for the pre-exposure, each for red, green and blue colors are provided; and an aperture plate that seconded at a predetermined distance from the light-emitting module is and has: beam limiting pores formed therein at positions which correspond to the LEDs for printing, wherein the pore size of the beam limiting Pores so determined that the diameter of the developed color the light beam emitted by the pores is about the same the dissolution of the Printer is; and beam limiting pores formed therein at positions are the LEDs for correspond to the pre-exposure, wherein the pore size of the beam-limiting pores determined so that the diameter of the developed color of the Light beam emitted from the steel-limiting pores, larger than the resolution the printer is. An optically writing printer according to claim 8, wherein the red LED for the pre-exposure, the green LED for the pre-exposure and blue pre-exposure LED with white LEDs are replaced.