TWI635366B - Composite material screen and manufacturing method thereof - Google Patents

Abstract

The invention mainly provides a composite material screen, which comprises: a net frame; a net cloth comprising a plurality of metal warp threads and a plurality of metal weft lines staggered up and down, the plurality of metal warp threads by a first predetermined tension and a plurality of metal weft lines And being stretched and fixed on the frame by a second predetermined tension; and a polymer material layer covering the mesh cloth, and the polymer material layer comprises a plurality of opening patterns; wherein the plurality of metal warp materials are stainless steel, and the plurality of metals The weft material is tungsten steel or titanium metal, and the plurality of opening patterns do not have a plurality of metal warps, wherein the strength of the second predetermined tension is greater than the strength of the first predetermined tension, and the plurality of metal warps and the plurality of metal wefts of different metal materials The system is engaged with each other; further, the present invention also provides a method for manufacturing a composite material screen.

Description

Composite material screen and manufacturing method thereof

The invention relates to a printing screen, in particular to a printing screen formed by weaving warp and weft of different materials.

In the prior art, the structure of a solar cell usually includes a finger bar and a bus bar, and most of the solar cells are designed with a very fine "finger electrode" to The photoelectrons collected in the active area are transferred to a larger "monolithic electrode" and then passed to the component's circuitry. In order to increase the efficiency of the solar cell, the finger electrode is designed to be fine and high, so that the height and width of the solar cell structure are better, and the energy conversion efficiency is high. In the prior art, the finger electrodes are distributed perpendicular to the whole chip electrode and distributed on the germanium wafer (wafer) in an equidistant manner. As the netting technology is improved, the finger electrodes are also thinner.

In the prior art, finger electrodes are fabricated by screen printing. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic view for explaining a printed pattern of a finger electrode on a screen in the prior art. Referring to FIG. 1, in a conventional screen printing technique for printing a finger electrode, a plurality of warp threads 12 and a plurality of weft threads 14 are woven to form a mesh cloth, and then the mesh cloth is rotated by an angle (22.5). Or 30 degrees, it is fixed on a frame 10 to form a screen 1. Then, an emulsion layer 16 is coated and formed on the mesh, and then a plurality of opening patterns 18 are formed on the emulsion layer 16 by exposure and development. The purpose of turning the mesh to an angle is to make a plurality of openings. The pattern 18 avoids the staggered nodes of the plurality of warp threads 12 and the plurality of weft threads 14 as far as possible, and finally the operator can use the doctor blade to press the mesh cloth to scrape the ink, so that the ink is printed on the printed matter through the plurality of opening patterns 18. Line (finger electrode) for printing purposes.

However, in the above prior art, when the plurality of warp threads and the plurality of weft threads are woven to form the mesh, the same warp and the plurality of wefts are made of the same material, such as stainless steel, tungsten steel, etc., and all the openings and the wire diameter are the same. . After the opening pattern 18 is formed, the plurality of opening patterns 18 (the plurality of opening patterns, that is, the pattern ink-transmissive areas of the finger electrodes) often include interlaced nodes of warp and weft, and the interlaced nodes of the warp and weft are usually Causes poor printing and ink transmission.

Furthermore, in the case of a finger electrode pattern which is currently printed to 50 micrometers, 40 micrometers, 30 micrometers or less to 20 micrometers, the mesh cloth usually uses 360 mesh numbers, a wire diameter of 16 micrometers, or 380 mesh numbers. The wire diameter is 14 micrometers. The cross-section of the warp and weft of the mesh of such a structure is more likely to block the ink from being broken, affecting the quality, and the solar energy conversion efficiency is low, which becomes a bottleneck to be overcome.

Further, although in the prior art, the opening pattern opening is aligned between the two warp or weft lines to avoid including the interlaced nodes of the plurality of warp and weft lines in the opening pattern. However, this type of alignment is quite labor intensive, resulting in a low process yield.

For the above reasons, how to form a new type of screen to prevent the warp and weft lines from being interlaced in the opening pattern so that the opening pattern is smoothly passed through during printing is a problem to be solved.

In view of the above disadvantages of the prior art, the main object of the present invention is to provide a composite material screen comprising: a mesh frame; a mesh fabric comprising a plurality of metal warp threads and a plurality of metal weft threads interlaced up and down, and a plurality of metal warp threads. And a first predetermined tension and a plurality of metal weft threads are stretched and fixed on the frame by a second predetermined tension; and a polymer material layer is coated with the mesh cloth, and the polymer material layer comprises a plurality of opening patterns; wherein The plurality of metal warp wires are made of stainless steel, the plurality of metal weft wires are made of tungsten steel or titanium metal, and the plurality of opening patterns do not have a plurality of metal warp threads, wherein the strength of the second predetermined tension is greater than the strength of the first predetermined tension, and different metals The plurality of metal warp threads and the plurality of metal weft threads of the material are engaged with each other.

Preferably, the polymer material layer is etched by an etching solution or a laser to form a plurality of opening patterns, and the complex opening patterns do not have a plurality of metal warps.

Preferably, the plurality of opening patterns are formed between any two adjacent metal warps such that the plurality of metal warp threads are not present in the plurality of opening patterns.

Preferably, the intensity of the second predetermined tension is between 120% and 150% of the intensity of the first predetermined tension.

Preferably, the polymer material used in the polymer material layer is one of PET, PE, PI, PU, PVC, PP, PTFE, PMMA, PS or other polymer synthetic materials.

In another aspect, the present invention also provides a method for fabricating a composite material screen, which comprises the steps of: weaving a plurality of metal warp threads and a plurality of metal weft threads in a staggered manner to form a mesh cloth; The thickness of the plurality of metal warps is stretched and fixed on a frame frame by a first predetermined tension and a plurality of metal weft wires at a second predetermined tension; and the mesh cloth is coated with a polymer material to be in the mesh cloth Forming a polymer material layer thereon; and forming a plurality of opening patterns on the polymer material layer by an etching method; wherein the plurality of metal warp wires are made of stainless steel, the plurality of metal weft wires are made of tungsten steel or titanium metal, and the plurality of opening patterns are There is no plurality of metal warp threads, wherein the intensity of the second predetermined tension is greater than the intensity of the first predetermined tension.

Preferably, the etching method is to etch the polymer material layer by an etching liquid or a laser, so that the polymer material layer includes a plurality of opening patterns, and the metal etching liquid or the laser etching is performed to pass the plurality of metals in the plurality of opening patterns. The warp is removed.

Preferably, when rolling the mesh cloth, the plurality of metal warp threads and the plurality of metal weft wires of different metal materials are mutually engaged, and the plurality of metal warp threads and the plurality of metal weft threads are stretched and fixed on the frame, and then set The intensity of the second predetermined tension is between 120% and 150% of the intensity of the first predetermined tension.

Preferably, a polymer material in a film form is bonded to the mesh cloth by thermocompression bonding or bonded through a glue to coat the polymer material with the mesh material.

Preferably, a liquid form of the polymer material and the mesh are wet coated, scraped, immersed, spin coated, spray coated or slit coated. In one way, the polymer material is coated with a mesh cloth.

Other objects, advantages and novel features of the invention will be apparent from

Reference will now be made in detail to the exemplary embodiments illustrated in the drawings All figures are represented by the same element symbols as the same or similar parts. Please note that these drawings are drawn in simplified form and are not drawn to exact scale.

2a is a schematic view for explaining the structure of a mesh and a frame in a composite material screen according to an embodiment of the present invention. Referring to FIG. 2a, a composite material screen according to an embodiment of the present invention includes a mesh 2 formed by interlacing a plurality of metal warp threads 22 and a plurality of metal weft wires 24, and the mesh cloth 2 is first rolled and rolled. After being pressed, it is stretched and fixed on a frame 20. In an embodiment of the invention, the material of the plurality of metal warp threads 22 is stainless steel, and the material of the plurality of metal weft wires 24 is tungsten steel or titanium metal. Among them, the hardness of stainless steel is 5.5, the hardness of tungsten steel and titanium metal is 9. When the plurality of metal warp threads 22 and the plurality of metal wefts 24 of different hardness are rolled, the hardness of the complex metal weft 24 is lower and the hardness is lower. The plurality of metal warp threads 22 will be snapped together.

In addition, when the material of the plurality of metal warp threads 22 is stainless steel, and the material of the plurality of metal weft wires 24 is tungsten steel or titanium metal, the wire strength of the plurality of metal weft wires 24 is greater than that of the plurality of metal warp wires. Therefore, the plurality of metal warp threads 22 and the plurality of metal weft threads 24 are stretched and fixed to the frame 20, and the tensile strength for stretching the plurality of metal weft wires 24 can be adjusted to be higher than the tensile strength of the tensile complex metal warp threads 22. %-50%, preferably 30% or 40% (i.e., the tensile strength for stretching the plurality of metal wefts 24 is from 120% to 150% of the tensile strength for stretching the plurality of metal warp threads 22, preferably 130% or 140%) to further engage the plurality of metal warp threads 22 and the plurality of metal weft wires 24 to each other and to enhance the engaging effect.

Fig. 2b is a schematic view of a scanning electron microscope (SEM) for explaining the structure of the region A in Fig. 2a. Referring to FIG. 2b, it can be seen from the SEM image of FIG. 2b that the plurality of metal warp threads 22 and the plurality of metal weft wires 24 have a higher hardness of the plurality of metal wefts 24 and a lower hardness of the plurality of metal warp threads 22 after the rolling action. They will be snapped together to stabilize the structure of the mesh 2.

FIG. 3a is a schematic view for explaining the structure of a composite material screen comprising a polymer material layer according to an embodiment of the present invention. Referring to FIG. 3a, after the mesh cloth 2 is stretched and fixed to the frame 10, a polymer material is used to cover the mesh cloth 2, and a polymer material layer 26 is further formed on the mesh cloth 2, and the polymer material is formed. It is a material composed of a compound with a relatively high molecular weight and has a relatively high structural strength. Therefore, when the plurality of metal warp threads 22 and the plurality of metal weft wires 24 in the mesh cloth 2 are engaged and fixed to each other, the present invention can further coat the mesh cloth 2 by the polymer material layer 26 to strengthen and stabilize the mesh cloth 2 structure.

In one embodiment of the present invention, the polymer material used for the polymer material layer 26 is one of PET, PE, PI, PU, PVC, PP, PTFE, PMMA, PS or other polymer synthetic materials. In addition, in an embodiment of the present invention, the polymer material in the form of a film may be combined with the mesh cloth 2 by thermocompression bonding, so that the polymer material is coated with the mesh cloth 2 and the polymer material layer 26 is formed; After the polymer material is used as a film, a layer of glue is applied to the polymer material or to the mesh cloth 2, and then the mesh cloth 2 and the polymer material are adhered and bonded through the glue. The polymer material is coated with the mesh 2 to form the polymer material layer 26. In other embodiments of the present invention, the polymer material in a liquid form and the mesh 2 may be wet-coated, scraped, immersed, spin-coated, spray-coated or narrow. One of the slit coatings is combined to coat the polymer material 2 with the polymer material to form the polymer material layer 26.

FIG. 3b is a schematic view showing a cross-sectional structure of a composite material screen comprising a polymer material layer according to an embodiment of the present invention. Referring to FIG. 3b, in the cross-sectional structure, it can be clearly seen that the polymer material layer 26 covers the plurality of metal warp threads 22 and the plurality of metal weft wires 24 in the mesh cloth 2 to further strengthen and stabilize by the polymer material layer 26. The overall structure of the mesh 2 .

It is worth mentioning that in the conventional screen printing process, a fixed process is required at the interlaced nodes of the complex warp and the complex weft to stabilize the structure of the mesh. For example, the staggered junctions of the plurality of warp threads and the complex weft threads can be fixed by means of spot welding, hot pressing, electroforming, electroplating, and laser welding, and then the mesh is stretched and fixed to the net. Frame to form a screen. However, this type of fixing makes the structure of the interlaced nodes of the complex warp and the complex weft more complicated (for example, the use of spot welding will thicken the structure at the staggered nodes), and thus the structure is complicated. Interlaced nodes are more likely to block ink penetration, causing wire breaks and affecting print quality.

In contrast, the present invention first forms a mesh 2 by bonding the metal warp threads 22 and the metal weft wires 24 having different hardnesses to each other to form the mesh cloth 2, and then covering the mesh cloth 2 with the polymer material layer 26 to further strengthen and stabilize. The overall structure of the mesh 2 . In this way, the composite material screen of the present invention can omit the fixing step in the conventional process, thereby effectively avoiding further complicating the structure at the interlaced nodes of the plurality of metal warp threads 22 and the plurality of metal weft wires 24.

4a is a schematic view for explaining the structure of a composite material screen according to an embodiment of the present invention. Referring to FIG. 4a, in an embodiment of the invention, the polymer material layer 26 or the plurality of metal warp wires 22 are etched by an etching solution, a metal etching solution or a laser, and a plurality of openings are formed on the polymer material layer 26. The pattern 28 is finally formed into a composite material screen 3, which is a finger electrode for printing in a solar cell structure. Wherein, the polymer material layer 26 may be first etched away by laser or etching solution to form a plurality of opening patterns 28, and then the plurality of metal warp threads 22 in the plurality of opening patterns 28 are etched away by laser or metal etching solution. More specifically, the polymer material layer 26 may be first etched away by laser to form a plurality of opening patterns 28, and then the plurality of metal warp wires 22 in the plurality of opening patterns 28 are etched away by a metal etching solution.

Wherein, when the plurality of metal warp wires 22 in the polymer material layer 26 or the plurality of opening patterns 28 are etched by the etching liquid or the metal etching solution, the metal wires 22 and the plurality of metal weft wires 24 of different metal materials are etched to the metal. The liquid may have different reactions. In the present invention, only the plurality of metal warp wires 22 (stainless steel material) are etched away by the metal etching solution, so that the plurality of metal warp threads 22 are not present in the plurality of opening patterns 28. In addition, if the plurality of metal warp threads 22 in the polymer material layer 26 or the plurality of opening patterns 28 are etched by laser (the melting point and vaporization point of the polymer material and the metal warp and the metal weft are different, and the plurality of metal wefts 24) The anti-laser cutting strength is greater than the complex metal warp 22), and the energy and wavelength of the laser can be adjusted, so that the laser only etches away the plurality of metal warp 22 (stainless steel), and the laser does not hurt the lightning The plurality of metal wefts 24 having a large cutting strength are produced, and thus, the plurality of metal warp threads 22 are not present in the plurality of opening patterns 28.

After the plurality of metal warp threads 22 in the plurality of opening patterns 28 are removed, the interlaced nodes of the plurality of metal warp threads 22 and the plurality of metal weft lines 24 can be avoided in the plurality of opening patterns 28 to improve the printing of the composite material screen 3 The amount of penetration of the ink also overcomes the situation in which the disconnection occurs due to the staggered nodes. Furthermore, since the composite material screen 3 has been first fixed by fixing the metal warp 22 and the metal weft 24 having different hardnesses, and then covering the mesh with the polymer material layer 26, it is further strengthened and stabilized. The overall structure of the mesh cloth, so the mesh of the composite material screen 3 does not break due to etching.

4b is a schematic view of an SEM for explaining the structure of an opening pattern according to an embodiment of the present invention. Referring to FIG. 4b, it can be seen from the SEM diagram of FIG. 4b that after the polymer material layer 26 and the metal warp 22 are removed by etching, an opening pattern 28 not including the metal warp 22 can be formed, as shown in FIG. 4b. It is clearly seen that only the plurality of metal wefts 24 are included in the opening pattern 28.

Figure 4c is a schematic view showing the cross-sectional structure at the position of the A-A hatching in Figure 4a of the present invention. Referring to FIG. 4c, it can be seen from the cross-sectional structure of the composite material screen 3 that the plurality of metal warp threads 22 are not included in the plurality of opening patterns 28, and the remaining polymer material layer 26 can be stabilized in the composite material screen plate 3. The overall structure of the mesh.

FIG. 4d is a schematic view of an SEM for explaining the structure of the mesh in the composite material screen according to an embodiment of the present invention. Referring to FIG. 4d, in order to further clearly show the structure of the plurality of opening patterns 28, the present invention also uses an SEM image to assist the description. It should be understood that the plurality of metal warp threads 22 and the plurality of metal weft lines 24 are not shown in FIG. 4d for clarity. Polymer material layer. As can be seen from FIG. 4d, the metal opening 22 is not included in the plurality of opening patterns 28, and the metal warp 22 which is not etched away is still engaged with the plurality of metal wefts 24.

FIG. 5a is a schematic view for explaining the structure of a composite material screen according to another embodiment of the present invention. Referring to FIG. 5a, in another embodiment of the present invention, the plurality of opening patterns 28 can be directly formed between any two adjacent metal warp lines 22 by an etching process, so that the plurality of opening patterns 28 are not The staggered junctions of the metal warp 22 and the metal weft 24 are included. However, in the formation process of the plurality of opening patterns 28, process errors (such as alignment errors, mesh process tolerances) are inevitably generated, thereby generating an erroneous opening pattern 281, which may be further etched by a metal etching solution or a laser. The metal warp 22 in the wrong opening pattern 281 is removed to avoid the entire composite material screen 3 having to be scrapped in whole due to a small number of false opening patterns 281.

FIG. 5b is a schematic view for explaining the structure of a composite material screen according to still another embodiment of the present invention. Referring to FIG. 5b, in another embodiment of the present invention, the polymer material layer 26 may be etched at an angle with the plurality of metal warp wires 22, and a plurality of opening patterns 28 may be formed to further form a composite material mesh. Version 4. Similarly, any metal warp 22 is not included in the slanted plurality of opening patterns 28.

FIG. 5c is a schematic view for explaining the structure of a composite material screen according to still another embodiment of the present invention. Referring to FIG. 5c, in another embodiment of the present invention, the composite material screen 5 includes not only a plurality of opening patterns 28 for printing a plurality of finger electrodes, and the composite material screen 5 further includes a whole sheet electrode for printing. The opening pattern 30, in this way, can directly print the electrode structure of the entire solar cell using the composite material screen 5.

It is worth mentioning that the structure of the whole-piece electrode printed by the opening pattern 30 does not need to be thin and high as the structure of the finger electrode, so the interdigitation of the plurality of metal warp threads 22 and the plurality of metal weft lines 24 The influence of the node on the opening pattern 30 is small, so in the process of etching the polymer material layer 26 and forming the plurality of opening patterns 28 and the opening pattern 30 by the etching liquid, the metal etching liquid or the laser, only the etching is performed to remove the plural number. The plurality of metal warp threads 22 in the opening pattern 28 do not remove the plurality of metal warp threads 22 in the opening pattern 30 to save slurry consumption and cost in the process.

Figure 6 is a flow chart for explaining the method of fabricating the composite material screen of the present invention. Referring to FIG. 6, the manufacturing method of the composite material screen of the present invention comprises a weaving step S10, a rolling step S12, a step S14, a polymer material coating step S16, and an etching step S18.

In the weaving step S10, a plurality of metal warp threads are stretched by a looms (not shown), and a plurality of metal wefts are interlaced in a manner of being interlaced with a plurality of metal warp threads to form a mesh. The metal warp material is made of stainless steel, and the metal weft is made of tungsten steel or titanium metal.

In the rolling step S12, the mesh is rolled into a desired thickness, and at the same time, the rolling step can bond the metal warps of the different metal materials and the metal wefts to each other to stabilize the mesh. The structure.

In the step of step S14, the metal warp threads are stretched and fixed to a frame frame by a first predetermined tension and the metal weft threads at a second predetermined tension. Wherein, the tensile strength for stretching the metal weft threads can be adjusted to be higher than 20%-50%, preferably 30% or 40% (i.e., for stretching) of the tensile strength of the metal warp threads. The tensile strength of the metal weft threads is from 120% to 150%, preferably 130% or 140%, of the tensile strength for stretching the metal warp threads to further the metal warp threads and the metal weft threads Engage each other and strengthen the fit.

In the polymer material coating step S16, the mesh is coated with a polymer material to form a polymer material layer on the mesh. The polymer material used in the polymer material layer is one of PET, PE, PI, PU, PVC, PP, PTFE, PMMA, PS or other polymer synthetic materials. In addition, in the coating process of the polymer material layer, the polymer material can be coated as a film, and then bonded to the mesh cloth by thermocompression bonding, so that the polymer material is coated with the mesh cloth. Or forming the polymer material layer; or, by using the polymer material as a film, applying a layer of glue on the polymer material or the mesh cloth, and then the mesh cloth and the polymer The material is bonded and bonded through the glue, so that the polymer material is coated on the mesh material to form the polymer material layer; or the polymer material may be used as a liquid, and then wet coated with the mesh cloth. a method of one of a method, a squeegee coating, a immersion coating, a rotary coating, a spray coating or a slit coating, so that the polymer material is coated with the mesh to form The polymer material layer.

In the etching step S18, the polymer material layer is etched by an etching method (using an etching solution or a laser), and a plurality of opening patterns are formed on the polymer material layer, and finally a composite material screen is formed. The pattern of openings is a finger electrode for use in printing a solar cell electrode structure. The etching method may be that the polymer material layer is first etched away by a laser or an etching solution to form the opening patterns, and then the laser or metal etching solution is used to etch away the openings in the opening patterns. Metal warp; more specifically, the polymer material layer may be first etched away by laser to form the opening patterns, and then the metal warp threads in the opening patterns are etched away by a metal etching solution .

Wherein, in the etching of the polymer material layer or the metal warp threads in the opening patterns by an etching solution or a metal etching solution, the metal warp wires of the different metal materials and the metal weft wires are etched to the metal The liquid may have different reactions. In the present invention, only the metal warp wires (stainless steel material) are etched away by the metal etching solution, so that the metal warp threads are not present in the opening patterns. In addition, if the polymer material layer or the metal warp threads in the opening patterns are removed by laser etching (the melting point and vaporization point of the polymer material and the metal warp and the metal weft are different, and the metals The anti-laser cutting strength of the latitude is greater than the metal warp), and the energy and wavelength of the laser can be adjusted, so that the laser only etches the metal warp (stainless steel), and the laser does not hurt the resistance. The metal wefts having a large laser cutting strength, such that the metal warp threads are not present in the opening patterns.

In addition, in the manufacturing method of the composite material screen of the present invention, the number of metal warp and metal weft is 1:1, however, the user can adjust the proportion according to the requirement of the opening pattern and achieve the required screen. tension. Furthermore, in the embodiment of the present invention, the metal warp wires are made of stainless steel. However, since the etching step S18 is to etch the portion of the opening pattern, copper or other metal may be used in the non-opening pattern portion. Material to interlace the woven mesh.

It can be seen from the above that the present invention forms a mesh by weaving metal warp threads and metal wefts of different materials, and then covering the mesh with a polymer material to form a composite material screen, and finally by etching liquid, The metal etching solution or laser etching method etches away the polymer material and a portion of the metal warp to form a plurality of opening patterns that do not include the metal warp. In this way, the interlaced nodes of the plurality of metal warp threads and the plurality of metal weft lines appear in the opening patterns to improve the penetration amount of the ink in the composite material screen printing, and also overcome the interlaced nodes. A situation in which a disconnection occurs during printing.

In describing a representative example of the invention, the present specification has been presented as a specific sequence of steps of the method and/or procedure of the invention. However, to some extent, the method or program does not rely on the specific order of steps set forth herein, and the method or program should not be limited to the particular order of the steps described. As will be appreciated by those skilled in the art, other sequences of steps are also possible. Therefore, the specific order of steps set forth in this specification should not be construed as limiting the scope of the claims. In addition, the scope of the patent application of the method and/or procedure of the present invention should not be limited to the performance of the steps in the order presented, and those skilled in the art can immediately understand that the order can be changed and still maintain the spirit of the present invention. Within the scope.

Those skilled in the art should be aware that changes can be made to the above examples without departing from the broad inventive concepts. Therefore, it is understood that the invention is not limited to the specific examples of the invention, and is intended to cover the modifications of the invention and the scope of the invention as defined by the appended claims.

1‧‧‧Web Edition

10, 20‧‧‧ net frame

12‧‧‧ warp

14‧‧‧Weft

16‧‧‧Layer layer

18‧‧‧ opening pattern

2‧‧‧Mesh

22‧‧‧Metal warp

24‧‧‧metal weft

26‧‧‧ Polymer layer

28‧‧‧Open pattern

281‧‧‧Error opening pattern

3, 4, 5‧‧‧ composite material screen

30‧‧‧ opening pattern

A ‧‧‧ area

S10, S12, S14, S16, S18‧‧ steps

The foregoing summary of the preferred embodiments of the invention, as well as For the purposes of illustrating the invention, various examples are now shown in the drawings. However, it should be understood that the invention is not limited to the precise arrangements and devices disclosed.

1 is a schematic view showing a printed pattern of a finger electrode on a screen in the prior art; FIG. 2a is a schematic structural view showing a mesh and a frame in a composite material screen according to an embodiment of the present invention; FIG. 2b is a schematic view of the present invention; FIG. 2a is a schematic view of a scanning electron microscope (SEM) of the structure of the region A in FIG. 2a; FIG. 3a is a schematic structural view showing a composite material screen comprising a polymer material layer according to an embodiment of the present invention; FIG. 4a is a schematic structural view of a composite material screen according to an embodiment of the present invention; FIG. 4b is a schematic view showing an opening pattern of an embodiment of the present invention; FIG. Figure 4c is a schematic cross-sectional view showing the AA hatching in Figure 4a of the present invention; Figure 4d is a schematic SEM view showing the structure of the mesh in the composite material screen according to an embodiment of the present invention; A schematic structural view of a composite material screen according to another embodiment of the present invention; FIG. 5b is a schematic structural view of a composite material screen according to still another embodiment of the present invention; Figure 5c is a diagram illustrating the structure of the composite material of the screen according to another embodiment of the present invention; and FIG. 6 is a flowchart illustrating the composite material of the present invention, a screen manufacturing method.

Claims (8)

A composite material screen comprises: a mesh frame; a mesh cloth comprising a plurality of metal warp threads and a plurality of metal weft threads staggered up and down, the metal warp threads being passed by a first predetermined tension and the metal weft threads a second predetermined tension is stretched and fixed on the frame; and a polymer material layer covering the mesh, and the polymer material layer includes a plurality of opening patterns; wherein the metal warp material is stainless steel, The metal weft is made of tungsten steel or titanium metal, and the metal warp threads are not included in the opening patterns, wherein the strength of the second predetermined tension is greater than the strength of the first predetermined tension, and the different metal materials are The metal warp threads and the metal weft threads are engaged with each other, wherein the strength of the second predetermined tension is between 120% and 150% of the strength of the first predetermined tension. The composite material screen according to claim 1, wherein the polymer material layer is etched by an etching solution or a laser to form the opening patterns, and the opening patterns are not provided. Metal warp. The composite material screen according to claim 1, wherein the opening patterns are formed between any two adjacent metal warps such that the metal warp threads are not included in the opening patterns. The composite material screen according to claim 1, wherein the polymer material used in the polymer material layer is PET, PE, PI, PU, PVC, PP, PTFE, PMMA, PS or other polymer. One of the synthetic materials. A method for fabricating a composite material screen comprises the steps of: weaving a plurality of metal warp threads and a plurality of metal weft threads in a staggered manner to form a mesh; rolling the mesh into a desired thickness; The metal warp wire is stretched and fixed on a frame frame by a first predetermined tension and the metal weft wires at a second predetermined tension; the mesh cloth is coated with a polymer material to form a mesh on the mesh cloth. a polymer material layer; and forming a plurality of opening patterns on the polymer material layer by an etching method; wherein the metal warp wires are made of stainless steel, the metal weft wires are made of tungsten steel or titanium metal, and the openings are The metal warp threads are not included in the pattern, wherein the strength of the second predetermined tension is greater than the strength of the first predetermined tension, wherein when the mesh is rolled, the metal warps of different metal materials are simultaneously When the metal wefts are engaged with each other, and the metal warp threads and the metal wefts are stretched and fixed on the frame, the strength of the second predetermined tension is set to be the intensity of the first predetermined tension. 1 20%-150%. The method for fabricating a composite material screen according to claim 5, wherein the etching method is to etch the polymer material layer by an etching solution or a laser, so that the polymer material layer includes the opening patterns. And removing the metal warp wires in the opening patterns through the metal etching solution or the etching of the laser. The method for fabricating a composite material screen according to claim 5, wherein the polymer material in a film form is bonded to the mesh in a thermocompression bonding manner or bonded through a glue to bond the polymer. The material wraps the mesh. The method for fabricating a composite material screen according to claim 5, wherein the polymer material in a liquid form and the mesh are wet-coated, scraped, immersed, The polymeric material is coated with the mesh by a combination of one of spin coating, spray coating or slit coating.