JPH01308688A - Two-layer structure mesh for screen printing and manufacture thereof - Google Patents

Abstract

PURPOSE:To easily obtain a screen mesh having durability by electrically plating with copper or silver or both on a mesh forming part of a material composed of one or more of nickel, chromium, iron, carbon fiber as a cathode. CONSTITUTION:A mesh forming part 31 made of metal having scarcely deformable property by a tension of the combination of one or more of nickel, chromium, iron, carbon fiber. Then, with the forming part as a cathode, the part is electrically plated with any or both of metals having plasticity by bending such as copper and silver. Thus, a screen mesh 32 of a 2-layer structure is formed. Since the forming part 32 of the copper and silver has plasticity even if the mesh is bent though the mesh forming part of the one or more of the materials has scarcely deformable property by a tension, the wires for forming the mesh 31 are not cut due to fatigue.

Description

DETAILED DESCRIPTION OF THE INVENTION Field and Object of the Invention The present invention relates to mesh structures in screen printing.

In screen printing, as shown in Figure 1, the four circumferences of a screen (mesh-like fabric) 3 are fixed under tension to a printing frame.
On top of this, a plate film (resist) is applied manually or by photochemical method.
Printing is performed by creating a plate, making a plate, and extruding a shallow ark-shaped intraocular screen printing ink through the lean surface onto the surface of the printing material placed on the bottom surface of the plate.

Screen printing can use a wide variety of inks and has a thick ink layer, so it has excellent weather resistance and chemical resistance. For this reason, it has recently been used for printing printed circuit boards such as IC circuits.

By the way, the screen 3 of screen printing is usually formed of a metal mesh, but as shown in FIG. is always under tension.

In addition, since the screen is bent at the tip P of the squeegee, the surface of the screen that comes into contact with the printing material is always bent once for each printing process during operation. .

By the way, the mesh is usually screen printed.

Many used nickel, and sometimes meshes made of chrome or iron were also used.

However, although meshes made of these metals have the property of being difficult to deform under tension, they have poor ability to move when bent, so when used for a long period of time, these materials that make up the mesh The purpose of this invention is to provide a method for manufacturing metal products.

(Structure of the Invention) The structure of the present invention is as follows: - A mesh component made of any one of nickel, chromium, iron, carbon fiber, or a combination of these materials is used as a cathode, and copper is placed on top of this as a cathode. - A method for producing a two-layer mesh for screen printing by electroplating one or both of the silver layers.

■Screen printing by electroplating nickel, chromium, iron, or a combination of these materials on a mesh component made of copper, silver, or both, using this as a cathode. A method for manufacturing a two-layer mesh.

■A screen made by combining a component made of copper, silver, or both with a component made of nickel, chromium, iron, carbon fiber, or a combination of two or more of these materials. The printing press consists of a two-layer mesh.

Either fold the station wire in the same way as a normal mesh, or as shown in Figure 3, (a) make a scratch 51 in the same shape as the mesh on the glass plate (b)
) A glass plate is immersed in silver nitrate to deposit a thin film 6 of silver on the surface of the glass.

(C) Of the precipitated silver, silver 6 in the form of a glass plate other than the silver 61 in the groove portion is removed.

(d) Using the silver 61 in the groove portion as a cathode, electroplating with a metal such as nickel is performed to form the screen mesh 3.

On the other hand, the applicant of the present invention, unlike the above-mentioned manufacturing method, uses a photosensitive layer and electroplating to improve the aspect ratio (the ratio of the height of the lines constituting the net divided by the width). He invented a method for forming meshes with high numbers. Any mesh produced by any manufacturing method or a semi-finished product of the mesh can be used as a constituent part of the mesh in the manufacturing method described in (1) and (2) above.

As shown in FIG. 4, the method for forming a mesh according to the present invention described in (1) above forms a mesh component 31 made of a metal that is resistant to deformation under tension due to the combination of the four materials.

Furthermore, a combination of several materials such as nickel, chromium, iron, and carbon fiber is a combination of these metals alone, for example, by first forming a mesh part with nickel and then electroplating chromium. When superimposing them as raw materials, and alloys of some or all of these (i.e.
(Metals are not simply mixtures or solid solutions of metals, but mixtures of metals with carbon, silicon, etc.) (also included).

(b) Next, using the mesh component according to (a) above as a cathode, one or both of the metals having resistance to bending, such as copper alloy, are electroplated.

In addition, when electroplating both copper and silver, they are electroplated separately in sequence, and in the case of electroplating in which copper and silver are overlapped, and in the case of electroplating of copper and silver alloy. There are cases where this is done.

In the manufacturing method (2) above, as shown in FIG. , carbon fiber cannot be electroplated).

In addition, mesh-shaped components made of both copper and silver include cases in which single metals of copper and silver are layered, cases in which an alloy of copper and silver is used, and cases in which nickel, chromium, and alloys of copper and silver are used. When electroplating a plurality of iron materials, there are cases in which single elements of these metals are sequentially electroplated and cases in which alloys of these metals are electroplated.

As described above, the screen mesh 3 having the two-layer structure shown in (1) is formed by the manufacturing methods (1) and (2) above.

When both copper and silver are used, there are two types: cases where they are made into a mold, cases where an alloy of these is used, and cases where multiple materials such as nickel, chromium, and iron are used. There are two types of molds: cases in which a simple substance of these metals is formed into a mold, and cases in which an alloy of some or all of these metals is used.

6(b) and 6(c), the constituent part 31 made of nickel fist chromium/iron/carbon fiber and the constituent part 32 made of copper/silver are shaped into a rectangular layer.
As shown in the figure, there is also a structure in which one of these completely covers the other.

(Actions and Effects of the Invention) Even if the screen mesh with the above two-layer structure is subjected to tension by the tip of the squeegee,
Similar to conventional nickel plating, the mesh component made of nickel, chromium, iron, carbon fiber, or a combination of these materials has a property that it is difficult to deform under tension. On the other hand, even if the mesh is bent by the tip of the squeegee, since the copper/silver component 32 has reversibility, it is extremely unlikely that the wires forming the mesh 31 will be cut.

Moreover, such a two-layer mesh as described in (1) above can be easily formed by simply performing electroplating as in the methods described in (1) and (3) above.

Thus, the present invention provides a relatively durable product.

[Brief explanation of the drawing]

Figure 1: A sketch showing an overview of Niscreen printing Figure 2: Niscreen is subjected to tension by a squeegee, and
A sectional view showing a bent state. FIG. 3: A sectional view showing a conventional nickel screen manufacturing process. FIG. 4: A sketch showing a manufacturing process according to claim (1). FIG. 5: Patent claim. Diagram 6 showing the manufacturing process described in range (6). Cross-sectional view of the metal wire constituting the two-layer mesh of the present invention 1 - Glass plate 11 - Groove 12 - Extracted silver 2 - Squeegee 311 Screen 31 - A mesh component made of nickel, chromium, iron, carbon fiber, or a combination of these materials (however, in Figures 4(a) and (b), carbon fiber is included; In the figures (a) and (b), carbon fibers are included in the mesh component 4, the printing material 5, the glass plate 5, the scratches on the glass plate 6, the thin film 61 caused by silver plating, and the part deposited on the inner thin layer of the silver thin film. Applicant's agent Nao Akao Fire younger brother Figure 2 Figure 3 ((L) (i)) (C) Figure 4 (α) (b) Figure 5 (a) (W) Figure 6 (α) (b) CC)

Claims (15)

[Claims] (1) A mesh component made of nickel, chromium, iron, carbon fiber, or a combination of these materials is used as a cathode, and copper, silver, or both are placed on top of this as a cathode. A method for producing a two-layer mesh for screen printing by electroplating. (2) The two-layer mesh according to claim (1), characterized in that the material that is a combination of several nickel, chromium, iron, and carbon fibers uses each of nickel, chromium, and iron alone. manufacturing method. (3) The method for manufacturing a two-layer mesh according to claim (1), wherein a part or all of the material made of a combination of a plurality of nickel, chromium, iron, and carbon fiber is an alloy. (4) The method for producing a two-layer mesh according to claim (1), characterized in that electroplating is performed sequentially with both copper and silver. (5) A method for manufacturing a two-layer mesh according to claim (1), characterized in that electroplating of alloys is performed for both copper and silver. (6) For screen printing by electroplating nickel, chromium, iron, or a combination of these materials as a cathode on the mesh component made of copper, silver, or both. A method for manufacturing a two-layer mesh. (7) The constituent parts of the mesh are made of both copper and silver.
Claims characterized in that silver alone is used (
6) The method for manufacturing the two-layer mesh described above. (8) Claims characterized in that the constituent parts of the mesh made of both copper and silver use an alloy of copper and silver (6)
) A method for producing a two-layer mesh for screen printing as described in . (9) A method for producing a two-layer mesh for screen printing, which comprises sequentially electroplating a plurality of materials including nickel, chromium, and iron. (10) A method for producing a two-layer mesh for screen printing, characterized by electroplating a part or all of a plurality of materials combining nickel, chromium, and iron with an alloy. (11) Screen printing by combining a component made of copper, silver, or both with a component made of nickel, chromium, iron, or a combination of two or more of these materials. Double-layer mesh for use. (12) A two-layer mesh for screen printing according to claim (11), characterized in that the component consisting of both copper and silver uses a single substance of copper and silver. (13) A two-layer mesh for screen printing according to claim (11), characterized in that the constituent parts made of both copper and silver use an alloy of copper and silver. (14) The two-layer mesh for screen printing according to claim (11), characterized in that a plurality of materials such as nickel, chromium, iron, and carbon fiber are used individually. (15) The two-layer mesh for screen printing according to claim (11), characterized in that an alloy is used for part or all of the plurality of materials of nickel, chromium, iron, and carbon fiber.