JPH0330983A - Method for printing fine image - Google Patents

Abstract

PURPOSE:To enhance finish quality by curing ink by ultraviolet rays while a printing plate and a material to be printed are brought to a close contact state and washing the material to be printed to remove the ink remaining on a non-image part, that is, a flat part. CONSTITUTION:Ink 3 is placed on a part or whole of the surface of a printing plate 1 on which a desired image is baked. As the ink 3, ultraviolet curable ink is used. Next, a transparent body 2 to be printed, for example, glass is superposed on the printing plate to be strongly bonded to the surface thereof under pressure by a press machine until recessed parts 5 are filled with the ink 3 and the excessive ink is extruded from the periphery of the body to be printed along with the ink on a flat part 4. In this pressure bonded state or a pressure-free closely bonded state, the whole is irradiated with ultraviolet rays on the side of the body 2 to be printed 2 to cure the ink. After curing, the printing plate 1 is separated from the body 2 to be printed and the body 2 to be printed is washed to remove the remaining ink 3' of the flat part.

Description

[Detailed description of the invention] <Industrial application field> The present invention relates to a method for printing fine images.

The fine image described here refers to a stripe shape, dot shape, etc. with a line width of 100 microns or less to about 20 microns.

Such fine images are created during the manufacturing process of glass substrates with transparent electrodes used in liquid crystal display devices, etc., such as the formation of a resist film when etching according to a circuit.
It is used for electronic parts.

<Prior Art> In the field of electronic components, fine images have conventionally been formed using techniques such as photolithography. The photolithography method has high resolution and dimensional stability, and can produce high-quality products, but it requires the steps of applying photoresist, drying, applying a mask, exposing, developing, and washing with water. The process is complicated and the number of steps is large, so the cost is generally high.

On the other hand, the printing method was introduced to produce products in large quantities at a lower cost. Images can be easily formed by printing and drying ink. Conventionally, rough images have been formed by printing methods such as screen printing. However, in the printing method, the line width is 100 microns to 7
The limit is 5 microns, and for images with a line width smaller than this, there is no limit to the photolithography method.

<Problem to be solved by the invention> With conventional printing methods, the dimensions of the finished image are distorted from the design values, and there are limits to resolution due to the physical characteristics of ink transfer, making it impossible to form fine images. It is the cause.

-The printing method used for Ilffl will be specifically described as an example.

In the screen printing method, the gauze deforms due to tension, and in the offset printing method, ink transfer occurs through a cylindrical blanket cylinder, so there is deformation that shortens in the printing direction, and the design value This is the cause of distortion.

The physical precision of ink transfer will be explained with reference to the drawings. Fig. 5a shows the state of the ink being stringy, and b shows the thread 9 of a. FIG. 3 is a cross-sectional view for explaining the shape of an image after it has been cut. Ink 3. However, the printing plate or blanket cylinder surface□
Rubber on the surface 14. and printing material 2. When they are separated, the rubber 14° and the printing medium 2. At a fine level, threads 9. The rubber 148, the printing medium 2. Due to surface tension on each side, a rounded convex portion 10
, form. In the concave portion between the threads, the amount of ink decreases, and the thread 9. The concave portion 11. form. Therefore, the surface of the ink coating of the image formed on the printing medium 2 has large and small irregularities caused by the ink. The convex portion 1
03. The concave portion 11° is not only due to the unevenness of the ink film surface,
As shown in FIG.
．． This results in a decrease in resolution and the inability to form fine images.

Means for Solving the Problems> The present invention relates to improvements for producing highly accurate products using a printing method that is inexpensive and capable of mass production. This reduces the jitteriness of printed images, increases resolution, and further reduces distortion and irregularities in finished dimensions, improving finish quality to the level of photoresist methods. It consists of the following steps.

a. The process of placing ink on the printing plate.

b. A step of applying surface pressure to the printing plate with the printing material.

A process in which ink is cured using ultraviolet rays while the C0 printing plate and printing material are in close contact.

d. Step of separating the printing plate and the printing material.

e. Washing the printing material to remove residual ink from non-image areas, that is, flat areas.

Details will be explained with reference to the drawings. FIG. 1 is a process diagram of the present invention using a transparent non-printing body and an intaglio or flat intaglio printing plate.

First, ink 3. Place an apricot. The ink is an ultraviolet curable ink, and is placed on the printing plate using a commonly used method such as an ink roller dispenser.

Next, a transparent printing body 23, such as glass, is attached to the printing plate 1.
Stack them on top and cover with strong surface pressure. Ink 3. is the concave portion 5. Fill the ink by the volume of the flat part 4.
Press with a press or the like until it is extruded from the periphery of the printing material together with the ink above. While the zero side is pressed together, or while the pressure is removed and the printing material remains in close contact, ultraviolet rays are irradiated from the printing material 2.0 side. , harden the ink. After curing, the printing plate 1. and the printing medium 2. 2.
and remove residual ink from the flat areas.

Recess 5. Ink-friendly, flat area 4. If a printing plate with ink repellency is used, the ink will be transferred to the recesses 5. by a non-ink roller or the like. It can only be placed on top.

FIG. 2 is a process explanatory diagram of the present invention using a printing plate in which the concave portions are transparent and the flat portions have light-shielding properties.

First, ink 3. put The ink is an ultraviolet curable ink, and is placed on the printing plate using a commonly used method such as an ink roller dispenser.

Next, a transparent printing body 21, such as glass, is attached to the printing plate 1.
Superimpose it on top to create a surface pressure layer. Ink 3. is the concave portion 5. Fill the ink by the volume of the flat part 4.
Press with a press or the like until it is extruded from the periphery of the printing material together with the ink above. With the surface pressure layer still in place, or with the pressure removed and still in close contact, ultraviolet rays are irradiated from the side of the printing plate 1 to harden only the ink in the recesses. After curing, printing plate 1. and printing material 2. Separate the printing material 2
．． to remove uncured ink from the flat areas.

<Function> By forming a surface pressure layer, ink 3. The ink is filled into the recessed part 5° by the volume of the recessed part, and the overflowing ink is poured into the flat part 4. The excess ink is pushed out from the periphery of the printing medium together with the ink above. When the surface pressure layer is completely completed, Figures 1 and 2
As shown in b of each drawing of FIGS. The flat portion 4. is filled with ink just in proportion to the volume. Ink is removed from the ink and sufficient ink is supplied.

In this invention, since the ink is hardened before the printing material and the printing plate are separated, there is no fine stringing caused by the ink that occurs when they are separated, and therefore there are no fine irregularities on the printing ink film, and printing is possible. The sharpness of the edges of the image has been almost completely improved. Furthermore, since the ink is transferred by the surface pressure layer and the ink is cured as it is, the designed image on the printing plate is reproduced without distortion.

Furthermore, if the concave portions of the printing plate are transparent and the flat portions are subjected to light-shielding treatment, ultraviolet rays can be irradiated from the side of the printing plate, so that the printing material can be either transparent or opaque.

Furthermore, if this printing plate is used, only the ink in the recessed areas is cured, and the residual ink in the flat areas is not cured, so there is an advantage that cleaning in the next step is easy.

<Example> In this example, a resist film necessary for manufacturing a transparent electrode circuit was formed using a Toshi waterless plate as a flat intaglio plate.

This will be explained with reference to FIG. First, the printing plate concave portion 5 is moved by the ink roller 15. After placing an ultraviolet curable resist ink on the substrate, a surface pressure layer was applied to the ITO surface of a glass substrate coated with indium oxide (ITO).

Next, this was placed in a press and pressurized. When the glass substrate is about 300 m, the pressure is 20 kg/cf. At this time, adding a slight amount of heat can further enhance the effect. After pressurizing for 2 to 3 minutes, it was taken out from the press, and the ink was cured by irradiating ultraviolet rays from the glass substrate surface. The printing plate is separated from the printing material and cleaned with alkali to remove residual ink on the flat top of the glass substrate.

The resulting fine image, as shown in FIG. 6a, has no irregularities, and therefore has no edge blemish, and accurately reproduces the concave portions on the printing plate as they are.

Comparisons were made with fine images produced by other printing methods. FIG. 6 is a cross-sectional view of a fine image produced by a typical printing method.

a is based on this invention, b is based on the letterpress printing method,
C is by lithographic offset printing, d is by intaglio printing, and e is by screen printing.

In the case of letterpress printing, the pressure of the plate causes the ink to form a relief bank on the outside of the convex portions on the plate, thus forming an image with a line width thicker than the set dimension. Because the amount of ink on the bank is not constant, smudges appear.

In the case of the lithographic offset printing method and the intaglio printing method, as mentioned above in the problem to be solved by the invention, unevenness and unevenness appear on the surface due to the physical characteristics of ink transfer. The difference in film thickness is due to the use of ink with a viscosity suitable for each printing method.

In the case of screen printing, surface irregularities and uneven edges appear due to the roughness of the gauze.

<Effect of the invention> A product according to the invention was measured.

The width of the uneven edges of the image has been reduced from the conventional approximately 10 microns to approximately 1 micron, resulting in an almost straight line in appearance, which is an accuracy that far exceeds the limits of conventional printing methods. As a result, the microscopic image, which was 100 microns at the mass production level and 50 microns at the experimental level, has now become 10 microns at the experimental level.
Now possible down to microns.

In addition, in terms of dimensional accuracy, distortion of about 50 to 100 microns conventionally occurred, but it can now be reduced to within about 10 to 20 microns, making it possible to achieve quality improvements comparable to the photoresist method. At the same time, if the surface of the printed film is flat and acts as a resist film, the etching conditions can be varied.

Furthermore, a disadvantage of the intaglio printing method is that the production cost of the intaglio printing plate is high, but according to this invention, the waterless plate normally used for planography can be used, so
It can be manufactured at a cost of about 0, and has the potential for general use.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram of the process of this invention using a transparent printing medium and an intaglio or flat intaglio printing plate. FIG. 2 is an explanatory diagram of the process of this invention using a printing plate in which the concave portions are transparent and the flat portions are light-shielding, and FIG. 3 is an explanatory diagram of an example. In FIG. 4, ab is a cross-sectional view for explaining fine stringiness caused by ink, a is stringiness, and b is unevenness formed as a result of a. Figure 5 ab
are diagrams showing the shape of a fine image formed under the influence of the physical characteristics of ink transfer, a is a plan view, and b is a diagram A-A.
FIG. FIG. 6a is a cross-sectional view of a fine image according to the present invention, FIGS. 6b-e are cross-sectional views of fine images formed by typical printing methods, b is one by letterpress printing, and C is a lithographic offset. d is by an intaglio printing method, and e is by a screen printing method. 1 is a printing plate, 2 is a printing material, 3 is ink, 3 is residual ink, 4 is a flat part, 5 is a concave part, 6 is an ultraviolet light source, 7 is a light shielding part, 8 is a transparent body, 9 is a thread-like part, 10 11 is a concave part, 12 is a bumpy part, 13 is extruded ink, 14 is rubber, 15 is an ink roller

Claims (4)

[Claims] (1) A direct printing method characterized by sequentially performing the following steps a to e. a. Step of placing ink on the intaglio printing plate. b. A step of surface-bonding a transparent printing material 2 to the intaglio printing plate 1. c. While keeping the transparent printing material 2 and the intaglio printing plate 1 in close contact with each other, irradiating the transparent printing material 2 with ultraviolet rays from the side;
The process of curing ink. d. A step of separating the printing medium 2 and the intaglio printing plate 1. e. Removing residual ink from the recesses 4 of the printing medium 2. (2) In the direct printing method according to claim (1), the intaglio printing plate 1 is a flat intaglio printing plate having ink affinity in the recessed portions 5 and ink repulsion in the flat portions. Printing method. (3) In the direct printing method according to claim (1), the intaglio printing plate 1 is an intaglio printing plate in which the concave portions 5 are transparent and the flat portions 4 are subjected to a light shielding treatment. A direct printing method characterized in that, in step c, ultraviolet rays are irradiated from the side of the intaglio printing plate 1 to cure the ink. (4) The direct printing method according to claim (3), wherein the printing medium 2 is opaque.