TW202138203A - Horizontal yarn printing screen plate and manufacturing method thereof that comprises a screen frame; a piece of mesh fabric that is fixed to the screen frame and comprises metallic wefts and metallic warps that are arranged up-and-down interlacedly; and a polymeric material layer that covers the mesh fabric - Google Patents

Abstract

A horizontal yarn screen printing plate comprises: a screen frame; a piece of mesh fabric that is stretched with a predetermined tension to fix to the screen frame and comprises a plurality of metallic wefts and a plurality of metallic warps that are arranged up-and-down interlacedly; and a polymeric material layer that covers the mesh fabric. The polymeric material layer includes a plurality of opening patterns, wherein there are no metallic wefts included in the opening patterns and the metallic warps arranged in the opening patterns are flattened shape. Further, the present invention also provides a manufacturing method of a horizontal yarn screen printing plate. The knotting-free printing screen plate has above described flattened horizontal yarns arranged adjacent to a scrape surface, which can improve a brushing-resistant service life of screen plate and uniformity of printing for thin lines, and enhance product performance efficiency and value at the same time.

Description

Horizontal yarn printing screen and its making method

The present invention relates to a printing screen and its manufacturing method, and in particular to a printing that enables the screen to print a fine line-width pattern with a flat appearance, reduces the height difference of the printed pattern, improves the printing efficiency and reduces the cost of the screen Screen and its manufacturing method.

The screen is an important tool for screen printing, and it can also be said to be an important basis for screen printing. It is mainly made of Tedlon fiber, nylon fiber or metal mesh material after weaving in the weft and warp directions, through a certain amount of The tension is expanded and fixed on the screen frame to form. The function of the screen is not only to form the pattern, but also to control the amount of ink that passes through during screen printing; therefore, the structure of the screen itself has a very large impact on the precision of printing, the thickness of the ink, and the amount of ink penetration. Impact.

The manufacturing principle of the screen plate is based on the chemical reaction of the mesh fabric formed by the weft and warp threads of the screen plate and the photosensitive emulsion to ultraviolet light to perform photosensitive plate making, so that the non-printed part is hardened by light to block the mesh. The printed part, because the photosensitive emulsion has not undergone a chemical reaction, will dissolve and hollow out when it meets with water to form the pattern required for printing. When performing screen printing, the operator can use a squeegee to apply pressure and then scrape the printing ink, so that the printing ink can print a pattern on the printed object through the hollow mesh. In addition, the screen production can also use laser to directly etch the polymer layer. , Without hurting the mesh, produce the required pattern, in order to achieve the purpose of printing.

FIG. 7 is a schematic diagram for explaining the cross-sectional structure of the laser direct etching printing screen in the prior art. Referring to FIG. 7, the printing screen in the prior art includes metal weft 901 and metal warp 903, and a polymer layer 30 is formed by coating the metal weft 901 and metal warp 903. However, in the conventional laser screen manufacturing process, it is particularly necessary to form the opening pattern 301 on the mesh fabric woven by the metal weft 901 and the metal warp 903, because the metal weft 901 and the metal warp 903 have The characteristics of the reflected light. The incident laser light R1 will become the reflected laser light R2 due to the circular metal warp 903 and the metal weft 901 with a weaving angle, resulting in the coating of the polymer layer 3011 near the opening pattern 301 It will be corroded by the reflected laser light R2 energy, which will cause holes in the side 3011 of the opening of the polymer layer, which will easily accumulate silver paste, which will cause the accumulation and sticking of ink, which will affect the ink separation ability, which will lead to the opening of the original screen that is expected to be hollowed out. The pattern 301 (that is, the line width of the printed part is less than 20µm) is caused by the cavities to form a silver paste blockage or cut point, which affects the ink permeability of the screen and the printing result.

In addition, the screens made with photosensitive emulsions are likely to have emulsion hardening stoppages at the openings due to the reflected side light during exposure at the knitting area, and side light problems. The line width <20um cannot be resolved, making the printing process easy. Screen plugging is interrupted, increasing printing time and cost. In order to achieve the required stability of ink penetration of <20µm fine lines, the industry currently uses full metal screens for printing. However, when the full metal screen is printed, it is easy to cause damage to the printed object and ink overflow when the full metal screen is attached to the printed object due to insufficient toughness. Therefore, the conventional screen manufacturing process is not only complicated and time-consuming, but also has poor results, making the printing quality unstable and failing to achieve the desired product quality.

Based on the above reasons, how to provide a gauze thickness non-knotted printing screen and its production method that can increase the life and uniformity of screen printing, so as to solve the structure of the steel wire yarn woven net of the screen. The printing height difference, unevenness and long-term stability caused by the angle, so that the material layer near the opening pattern on the mesh is not affected, and has a better ink penetration, which is a problem to be solved.

In order to achieve the foregoing objective, the present invention provides a knotless printing screen with horizontal yarns arranged on the scraper surface, comprising: a screen frame; A plurality of metal weft threads and a plurality of metal warp threads arranged in a staggered arrangement; and a polymer material layer covering the mesh, and the polymer material layer includes a plurality of opening patterns; wherein the opening patterns do not have the metal weft threads, And the metal warp threads in the opening patterns are flat.

Preferably, the mesh includes a central area mesh and a peripheral area mesh, the central area mesh includes the metal wefts and the metal warp yarns, and the surrounding area mesh includes a plurality of Tedlon wefts and a plurality of For Tetoron warp threads, the metal weft threads are not included in the opening patterns, and the metal warp threads in the opening patterns are flat.

Preferably, the flat metal warp threads are arranged in a horizontal state and arranged on the side of the scraper surface.

Preferably, there is an included angle between a central axis of a horizontal warp of each of the metal warp threads in the flat shape in the opening patterns and a central axis of a horizontal weft of one of the metal wefts, and the included angle The angle of is any angle in the range of 0 degrees to 180 degrees.

Furthermore, the present invention also provides a method for making a horizontal yarn printing screen, which includes the following steps: flattening a plurality of metal weft threads and a plurality of metal warp threads at a first predetermined tension; and flattening the flattened metal weft threads and the metal The warp threads are woven up and down in a staggered manner to form a mesh; the metal weft threads and the metal warp threads are stretched and fixed on a screen frame with a second predetermined tension, and a plurality of predetermined opening areas are placed The metal wefts are etched and removed; the metal warps in the predetermined opening pattern area are pressed into a flat shape and close to the doctor blade surface by a leveling process; the mesh cloth is covered by a polymer material , To form a polymer material layer on the mesh; and to form a plurality of opening patterns on the polymer material layer by a laser etching method, wherein the opening patterns do not have the metal wefts, and the The metal warp threads in the opening patterns are flat.

Preferably, the flat metal warp threads present a horizontal state.

Preferably, the mesh includes a central area mesh and a peripheral area mesh, the central area mesh includes the metal wefts and the metal warp yarns, and the wefts and the surrounding area meshes The warp threads are plural tetoron weft threads and plural tetoron warp threads, the opening patterns do not have the metal weft threads, and the metal warp threads in the opening patterns are flat.

Preferably, the leveling process is a roller jig leveling process, a magnetic suction type jig leveling process, or a hydraulic steel plate jig leveling process.

Preferably, in the magnetic leveling process, the metal warp threads are further arranged to form an angle with the central axis of a horizontal weft thread of one of the metal weft threads by a magnetic gripping tool.

Preferably, the angle of the included angle is any angle in the range of 0 degrees to 180 degrees.

The following is a more detailed description of the implementation of the present invention in conjunction with the drawings and component symbols, so that those who are familiar with the art can implement it after studying this manual.

FIG. 1 is a schematic diagram to illustrate the structure of a horizontal yarn printing screen according to an embodiment of the present invention; FIG. 2 is a schematic diagram to illustrate the A-A cross-sectional structure in FIG. 1. 1 and 2, the horizontal yarn printing screen 1 of an embodiment of the present invention includes a screen frame 10, a mesh cloth 20, and a polymer material layer 30, and the mesh cloth 20 includes a scraper surface S1 and a sticker Printing surface S2.

The mesh cloth 20 is stretched and fixed to the mesh frame 10 by a predetermined tension and includes a plurality of metal weft threads 201 and a plurality of metal warp threads 203 arranged alternately up and down. The polymer material layer 30 covers the mesh cloth 20, and the polymer material layer 30 includes a plurality of opening patterns 301, which are the print portions of the printing screen. Wherein, the opening pattern 301 does not have the metal weft 201, and the metal warp 203 in the opening pattern 301 has a flat shape. In addition, in an embodiment of the present invention, the metal weft 201 in the opening pattern 301 can be removed by an etching process, thereby forming a mesh-free opening pattern 301.

It is worth mentioning that, in an embodiment of the present invention, the flat metal warp 203 is in a horizontal state and close to the scraper surface S1, as shown in the state shown in FIG. Bring the metal warp 203 close to the scraper surface S1. In this way, in the process of forming the opening pattern 301 and etching away the metal weft 201, when the laser light R1 is incident on the metal warp 203, the laser light R2 will be vertical due to the flat shape of the metal warp 203. It is reflected back, thereby reducing the probability that the laser light R2 reflected laterally due to the weaving angle of the yarn will damage the wall surfaces on the front and back sides of the yarn in the opening pattern 301. Furthermore, in other embodiments of the present invention, only the portion of the metal warp 203 located on the scraper surface S1 may be set to a flat shape.

Fig. 3 is a schematic diagram for explaining the structure of a horizontal yarn printing screen according to another embodiment of the present invention. 3, in another embodiment of the present invention, the mesh 20 may be a composite mesh, that is, the mesh 20 may include a central area mesh 205 and a peripheral area mesh 207, the central area mesh The cloth 205 and the surrounding mesh cloth 207 can be combined by a composite edge 300. The central area mesh 205 includes a plurality of metal weft threads 2051 and a plurality of metal warp threads 2053. The surrounding area mesh cloth 207 includes a plurality of tetoron weft threads 2071 and a plurality of tetoron warp threads 2073, and the polymer material layer 30 covers the center Zone mesh 205, and the opening pattern 301 does not have the metal weft 2051, and the metal warp 2053 in the opening pattern 301 has a flat shape. The composite mesh is woven only in the central area mesh 205 using metal weft 2051 and metal warp 2053, so the production cost of the screen can be further reduced.

4 is a schematic diagram for explaining the cross-sectional structure of a horizontal yarn printing screen according to another embodiment of the present invention. In another embodiment of the present invention, there is an included angle d1 between a horizontal warp center axis L1 of the flat metal warp 203 and a horizontal weft center axis L2 of the metal weft 201 in the opening pattern 301, and the included angle d1 can be It is any angle in the range of 0 to 180 degrees. The advantage of arranging the metal warp 203 in the opening pattern 301 in an inclined state is that the amount of ink passing through the opening pattern 301 can be changed by the inclined metal warp 203, so that the amount of ink penetration becomes adjustable, and then Increase the versatility of the horizontal yarn printing screen of the present invention. In addition, the metal warp 203 is also close to the scraper surface S1.

Fig. 5 is a flow chart for explaining the method of making a horizontal yarn printing screen according to another embodiment of the present invention; Fig. 6 is a schematic diagram for explaining the preliminary structure of a horizontal yarn printing screen according to another embodiment of the present invention . Please refer to Figure 1, Figure 5 and Figure 6, the horizontal yarn printing screen manufacturing method of the present invention includes steps S10-step S20, step S10 is: the plurality of metal weft 201 and the plurality of metal warp 203 to a first predetermined tension Flattening, this step can be regarded as the first leveling operation; Step 12 is: weaving the flattened metal weft 201 and the metal warp 203 in a staggered manner up and down to form a mesh 20; Step S14 is: cutting the metal weft 201 And the metal warp threads 203 are stretched with a second predetermined tension and fixed on a screen frame 10, and the metal weft threads 201 in the predetermined opening pattern area A1, the predetermined opening pattern area A2 and the predetermined opening pattern area A3 are etched and removed; step S16 is: pressing the metal warp 203 in the predetermined opening pattern area A1, the predetermined opening pattern area A2, and the predetermined opening pattern area A3 into a flat shape by a leveling process, the predetermined opening pattern area A1, the predetermined opening pattern area A2, and the predetermined opening pattern area A2. The predetermined opening pattern area A3 is the set printing pattern, and this step can be regarded as the second stage of leveling operation to press the metal warp 203 into a thinner and flatter pattern; step S18 is: by a high The molecular material covers the mesh cloth 20 to form a polymer material layer 30 on the mesh cloth 20; and step S20 is: forming a plurality of opening patterns 301 on the polymer material layer 30 by a laser etching method, wherein the openings The pattern 301 does not have the metal weft threads 201, and the metal warp threads 203 in the opening pattern 301 are flat.

Among them, the leveling step of step S10 can pre-level the plurality of metal wefts 201 and the plurality of metal warps 203, so as to reduce the height difference between the plurality of metal wefts 201 and the plurality of metal warps 203 after weaving to form the mesh cloth 20, and It can make the subsequent leveling process more smoothly during leveling. Furthermore, the leveling process of step S16 can be a roller jig leveling process, a magnetic suction type jig leveling process, or a hydraulic steel plate jig leveling process. In other words, the horizontal yarn printing screen of the present invention In the manufacturing method, a roller or a jig contact process can be used to level the metal warp 203, or a magnetic non-contact process can be used to level the metal warp 203. In addition, in another embodiment of the present invention, the flat metal warp 203 presents a horizontal state.

On the other hand, please refer to FIG. 4 again. In the magnetic flattening process of step S16 in other embodiments of the present invention, the metal warp 203 can be further arranged with the polymer material by a magnetic flattening process. An included angle d1 is formed between the layers 30, which means that the flat metal warp 203 can be used to adjust the angle by magnetic attraction, so that the flat metal warp 203 of different angles can be used to change the transparency. The amount of ink. For example, the angle of the included angle d1 can be any angle in the range of 0 to 180 degrees.

Furthermore, similarly, please refer to FIG. 3 again. In other embodiments of the present invention, the mesh cloth 20 may be a composite mesh cloth, which means that the mesh cloth 20 may include a central area mesh cloth 205 and a peripheral area mesh. The cloth 207, the central area mesh cloth 205 and the surrounding area mesh cloth 207 can be combined by a composite edge 300. The central area mesh 205 includes a plurality of metal weft threads 2051 and a plurality of metal warp threads 2053. The surrounding area mesh cloth 207 includes a plurality of tetoron weft threads 2071 and a plurality of tetoron warp threads 2073, and the polymer material layer 30 covers the center Zone mesh 205, and the opening pattern 301 does not have the metal weft 2051, and the metal warp 2053 in the opening pattern 301 has a flat shape.

In summary, the present invention successfully provides a horizontal yarn printing screen and its manufacturing method. The horizontal yarn printing screen of the present invention is a printing screen with no knots in the opening pattern, and the metal yarn in the opening pattern is flat. Compared with the prior art, the flat-shaped yarn is overall The thickness can be reduced to 95~15%. For example, the thickness of the yarn is reduced by 50% from the original round diameter of 20μm to the thickness of the flat yarn of 10μm. This can improve the uniformity of screen printing and have an excellent printing aspect ratio, and make The polymer material layer near the opening pattern on the printing screen is not affected by laser etching, so that it has better ink penetration. Furthermore, the present invention can also adjust the angle of the flat-shaped metal thread yarn, so that the ink intake is better.

The above descriptions are only used to explain the preferred embodiments of the present invention, and are not intended to restrict the present invention in any form. Therefore, any modification or change related to the present invention is made under the same spirit of the invention. , Should still be included in the scope of the present invention's intended protection.

1: Horizontal yarn printing screen 10: Screen frame 20: Mesh 30: polymer layer / polymer material layer 201: Metal Weft 203: Metal warp 205: Central area mesh 207: surrounding area mesh 2051: Metal Weft 2053: Metal warp 2071: Tetoron Weft 2073: Tetoron Warp 300: compound edge 301: Opening pattern 3011: polymer layer / side of the polymer layer opening 901: Metal Weft 903: Metal warp R1: Laser light R2: Laser light S1: Scraper surface S2: Sticker surface L1: Central axis of horizontal warp L2: Central axis of horizontal weft yarn A1-A3: predetermined opening pattern area d1: included angle S10-S20: steps

Those with ordinary knowledge in the art can have a better understanding of the various aspects of the present invention and its specific features and advantages after reading the detailed description below with reference to the accompanying drawings. The accompanying drawings include: Figure 1 is a schematic diagram illustrating the structure of a horizontal yarn printing screen according to an embodiment of the present invention; Figure 2 is a schematic diagram illustrating the A-A cross-sectional structure in Figure 1; 3 is a schematic diagram illustrating the structure of a horizontal yarn printing screen according to another embodiment of the present invention; 4 is a schematic diagram illustrating a cross-sectional structure of a horizontal yarn printing screen according to another embodiment of the present invention; Figure 5 is a flow chart illustrating a method for making a horizontal yarn printing screen according to another embodiment of the present invention; 6 is a schematic diagram illustrating the preliminary structure of a horizontal yarn printing screen according to another embodiment of the present invention; and FIG. 7 is a schematic diagram illustrating a cross-sectional structure of a direct etching printing screen using a laser in the prior art.

10: Screen frame

20: Mesh

30: polymer material layer

201: Metal Weft

203: Metal warp

301: Opening pattern

S1: Scraper surface

S2: Sticker surface

R1: Laser light

R2: Laser light

Claims (10)

A horizontal yarn printing screen, including: A screen frame A mesh cloth which is stretched and fixed to the mesh frame with a predetermined tension and includes a plurality of metal wefts and a plurality of metal warps that are arranged alternately up and down; and A polymer material layer covering the mesh, and the polymer material layer includes a plurality of opening patterns; Wherein, the metal weft threads are not included in the opening patterns, and the metal warp threads in the opening patterns are flat. The horizontal yarn printing screen according to item 1 of the scope of patent application, wherein the mesh includes a central area mesh and a peripheral area mesh, and the central area mesh includes the metal wefts and the metal warps The mesh of the surrounding area includes a plurality of tetoron weft threads and a plurality of tetoron warp threads, the opening patterns do not have the metal weft threads, and the metal warp threads in the opening patterns are flat. According to the horizontal yarn printing screen of the first item of the scope of patent application, the flat metal warp threads are in a horizontal state and are arranged on one side of the scraper surface of the mesh cloth. The horizontal yarn printing screen according to the first item of the patent application, wherein a horizontal warp center axis of each of the flat metal warp yarns in the opening patterns and one of the metal weft yarns There is an included angle between the central axes of a horizontal weft yarn, and the included angle is any angle in the range of 0 to 180 degrees. A method for making a horizontal yarn printing screen includes the following steps: Flatten the plural metal weft threads and the plural metal warp threads with a first predetermined tension; Weaving the flattened metal weft threads and the metal warp threads in a staggered manner up and down to form a mesh; Stretching the metal weft threads and the metal warp threads under a second predetermined tension and fixing them on a screen frame, and etching and removing the metal weft threads in a plurality of predetermined opening areas; Pressing the metal warps in the predetermined opening pattern area into a flat shape by a leveling process; Coating the mesh cloth with a polymer material to form a polymer material layer on the mesh cloth; and A plurality of opening patterns are formed on the polymer material layer by a laser etching method, wherein the opening patterns do not have the metal weft threads, and the metal warp threads in the opening patterns are flat. According to the manufacturing method described in item 5 of the scope of patent application, the flat metal warp threads are in a horizontal state. The manufacturing method according to item 5 of the scope of patent application, wherein the mesh includes a central area mesh and a peripheral area mesh, the central area mesh includes the metal wefts and the metal warps, and the surrounding The wefts and the warp threads in the regional mesh are plural tetoron weft threads and plural tetoron warp threads. The opening patterns do not have the metal weft threads, and the metal in the opening patterns The warp has a flat shape. The manufacturing method according to item 5 of the scope of patent application, wherein the leveling process is a roller jig leveling process, a magnetic suction jig leveling process, or a hydraulic steel plate jig leveling process. The manufacturing method according to item 8 of the scope of patent application, wherein, in the flattening process of the magnetic jig, the magnetic jig is further used to arrange the metal warp threads to be aligned with the metal weft threads. An included angle is formed between the central axes of one of the horizontal weft yarns. The manufacturing method according to item 9 of the scope of patent application, wherein the angle of the included angle is any angle in the range of 0 to 180 degrees.

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