JPH0572263B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a screen printing apparatus used for forming thick film members of conductors or insulators on insulating plastic substrates using screen printing technology.

(Prior Art) In recent years, screen printing devices have been widely used for printing electronic circuits because, although they are essentially simple, the amount of pasty ink transferred is precisely constant and a predetermined thickness can be easily obtained. has been done.

An example of the conventional screen printing apparatus mentioned above will be described below with reference to the drawings. FIG. 3 shows a cross-sectional view of a conventional screen printing device. In FIG. 3, 2 is an insulating plastic substrate, 1 is a printing table on which it is placed by suction, 3 is a suction exhaust for suctioning the insulating plastic substrate 2, 4 is an insulating urethane rubber squeegee, and 5 is the above-mentioned A metal holder for the squeegee 4, 6 a conductive or insulating paste ink, 7 a plate frame on which a printing plate 8 is stretched, and 10 an insulating plastic holder when the squeegee 4 moves in the direction A in the figure. Board 2
A conductive or insulating thick film printed on the surface of a

The operation of the screen printing apparatus configured as described above will be explained below. First, the conductive or insulating paste ink 6 supplied onto the printing plate 8 moves in the direction A in the figure while pressing on the printing plate 8, that is, the screen made of polyester, Tetron, nylon, silk, stainless steel, etc. The conductive or insulating paste ink 6 is ejected from the openings in the printing plate 8 by the squeegee 4, and a thick film printed portion 10 is formed on the insulating plastic substrate 2.

(Problems to be Solved by the Invention) However, in the above configuration, printing defects as shown in FIG. 4 occur. FIG. 4 is a surface view showing the surface of an insulating plastic substrate printed using a conventional screen printing apparatus. In FIG. 4, 2 is an insulating plastic substrate, and 10
Reference numerals a, 10b, and 10c are conductive or insulative thick-film printed parts, and 60 and 61 are defective parts of almost shoot failure and shoot failure, which are comprised of the printed parts 10a, 10b, and 10c. These defective portions occur due to the following reasons.

(1) An insulating urethane rubber squeegee presses a screen made of polyester, Tetoron, nylon, silk, stainless steel, etc. while moving the plate surface at high speed. Due to friction, the squeegee is charged with static electricity, and the plate is charged with static electricity during printing. Due to the influence of static electricity, the paste ink may sag, resulting in printing defects.

(2) Since the insulating plastic substrate is used by adsorbing it to the printing table, the insulating plastic substrate is charged with static electricity due to the friction with the air during suction, and the paste ink is charged due to the influence of the static electricity. The paper may become blurred, resulting in printing defects.

In other words, the insulating urethane rubber squeegee and the insulating plastic substrate have high electrical insulation properties and very high specific resistance, so they are easily charged with static electricity, and this does not easily leak. Therefore, during printing, the insulating urethane rubber squeegee and the insulating plastic substrate are charged with static electricity, causing printing failures and producing defective portions 60 and 61.

As a countermeasure, generally, the static electricity charged on the insulating plastic substrate is removed using a static eliminator immediately before printing. Although it is possible to remove static electricity that has been charged in a previous process other than the printing process, The static electricity that sometimes occurs cannot be essentially eliminated,
There was a problem in that printing defects occurred.

In view of the above-mentioned problems, the present invention provides a screen printing device that can perform good printing with a simple configuration.

(Means for Solving the Problems) In order to solve the above problems, the screen printing apparatus of the present invention includes a conductive squeegee whose one end is electrically grounded, and a metal squeegee whose one end is electrically grounded. The printer is equipped with a metal plate frame equipped with a conductive printing plate such as a stainless steel screen electrically grounded at one end or an antistatic screen.

(Function) With the above-described configuration, the present invention has the following features: [] Even when the conductive squeegee presses and moves against the plate surface made of a stainless steel screen or an antistatic screen and rubs it, the conductive squeegee is not charged with static electricity and the conductive squeegee is not charged with static electricity. It flows to the ground by the squeegee and the above plate.

[] Even for insulating plastic substrates, a metal printing stand with one end grounded allows the static electricity generated by friction with the air during suction to be absorbed by the metal printing stand without being charged on the insulating plastic substrate. Flows to earth.

Due to the effects of [] and [] above, there will be no printing defects due to the influence of static electricity during printing.

(Embodiment) A screen printing apparatus according to an embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a sectional view of a screen printing device.
In Fig. 1, 11 is an insulating plastic substrate 1.
It is a metal printing stand on which 2 is adsorbed and placed, and 1
3 is a suction exhaust for adsorbing the insulating plastic substrate 12, 14 is a conductive squeegee, 15
is a metal holder for the squeegee 14;
6 is conductive or insulating paste ink, 1
7 is a metal plate frame on which a conductive printing plate surface 18 such as a stainless steel screen or an antistatic screen is stretched, and 20 is a metal plate frame with a conductive squeegee 14 at
It is a conductive or insulating thick film printed part that is printed on the surface of the insulating plastic substrate 12 when the insulating plastic substrate 12 is moved in the direction, and 30 is an electrically conductive or insulating thick film printed part that is printed on the surface of the insulating plastic substrate 12. It is a conductive part that is grounded to earth. 40 is a conductive part that is electrically grounded from one end of the metal printing table 11, and 50 is a conductive part that is electrically grounded from one end of a conductive printing plate surface such as a stainless steel screen or an antistatic screen through the metal plate frame 17. It is a conductive part that is grounded.

The screen printing apparatus configured as above will be described below. FIG. 1 is a sectional view for explaining the operation of the screen printing apparatus of the present invention, and FIG. 2 is a surface view showing a good thick film printed part obtained using the screen printing apparatus.

First, in FIG. 1, an insulating plastic substrate 12 is connected to a metal printing table 1 whose one end is grounded.
1 by the suction exhaust 13. On the other hand, while pressing the conductive or insulating paste ink 16 supplied to the conductive printing plate surface 18 whose one end is grounded, the screen surface is pressed against the conductive printing plate surface 18, that is, the stainless steel screen or the antistatic screen. A conductive or insulating paste ink 16 is ejected from the openings of the conductive printing plate 18 by the conductive squeegee 14 moving at high speed in the direction A in the figure, and the thick film printing area is applied onto the insulating plastic substrate 12. 20 is formed.

Next, in FIG. 2, good thick film printing parts 20a, 20b,
20c is obtained.

As described above, according to this embodiment, in a screen printing machine that performs thick film printing on an insulating plastic substrate, a conductive squeegee with one end electrically grounded and a metal squeegee with one end electrically grounded are used. By providing a printing plate and a metal plate frame equipped with a conductive printing plate such as a stainless steel screen with one end electrically grounded or an antistatic screen, the conductive squeegee can move the conductive printing plate surface at high speed. Even when pressed and moved and rubbed, static electricity flows to ground through the conductive squeegee and conductive printing plate without being charged. In addition, even for insulating plastic substrates, static electricity generated by friction with air during suction and suction by a metal printing stand with one end grounded can be removed from the metal printing stand without being charged on the insulating plastic substrate. Flows to earth. Therefore, the influence of static electricity during printing can be completely eliminated.

In addition, in the first embodiment, the conductive squeegee 1
4. As a result of the experiment, the materials are natural rubber, chloroprene rubber, polyurethane rubber, silicone rubber,
Rubber materials such as butyl rubber, styrene butadiene, butyl rubber, etc. have a volume resistivity of 0.5×10 ²
Good results for static electricity were obtained in the range of ~2×10 ⁷ (Ω·cm).

(Effects of the Invention) As described above, according to the present invention, in a screen printing machine that performs thick film printing on an insulating plastic substrate, a conductive squeegee whose one end is electrically grounded and a conductive squeegee whose one end is electrically grounded are used. The conductive squeegee is electrically conductive by providing a metal printing table that is electrically grounded and a metal plate frame that is equipped with a conductive printing plate surface such as a stainless steel screen or an antistatic screen that has one end electrically grounded. Even when the printing plate surface is pressed and moved at high speed and rubbed, static electricity does not become charged and flows to the ground due to the conductive squeegee and the conductive printing plate surface.Also, even in the case of an insulating plastic substrate, a metal with one end grounded Static electricity generated by friction with the air during suction and suction by a manufactured printing table flows from the metal printing table to the ground without charging the insulating plastic substrate.
There are no defects during printing caused by the influence of static electricity, and good printing can be obtained.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of a screen printing device according to an embodiment of the present invention, FIG. 2 is a surface view showing good printing in the screen printing device of FIG. 1, and FIG.
The figure is a sectional view showing a conventional screen printing device, and FIG. 4 is a surface view showing printing including defects in the conventional screen printing device. 11... Metal printing stand, 14... Conductive squeegee,
18... Conductive printing plate surface, 30, 40, 50... Earth grounding.

Claims (1)

[Claims] 1. In a screen printing machine that performs thick film printing on an insulating plastic substrate, a conductive squeegee with one end electrically grounded, a metal printing table with one end electrically grounded, and one end Stainless steel screen electrically grounded,
Alternatively, a screen printing device comprising a metal plate frame equipped with a conductive printing plate such as an antistatic screen.