TWM462881U - Honeycomb screen and mask plate using the screen made - Google Patents

Abstract

A honeycombscreen and a mask plate using the screen made are used in the industrialproduction of precision printing. The screen is a honeycomb structure composedof interconnected polygonal arrays. Preferably, the shape of the honeycombstructure of the screen is a regular hexagon. The polygonal arrays (forexample, regular hexagonal arrays) are interconnected in a irregular polygonal structure. The technicalsolution using the edges of the irregular hexagonal structure as bridging linesto connect the corner points of the polygonal arrays may solve the problem ofthe unstable and weak screen structure used in conventional precision printingtechnology.

Description

Honeycomb mesh and mask version made using the same

The present invention relates to a honeycomb screen and a mask made using the screen, and more particularly to a honeycomb screen which can be used in industrial production for precision printing and using the screen The mask version.

With the rapid development of the economy, the consumption of energy is increasing, and the storage of non-renewable resources such as coal and oil is decreasing. This has prompted people to focus on new energy sources such as nuclear energy, solar energy, wind energy, biomass energy and geothermal energy. , ocean energy, hydrogen energy, etc.) continue to explore. Among them, as a source of many energy on the earth, solar energy plays an important role in the research of new energy. Solar cells are a core representative of solar energy applications.

Improving the conversion efficiency of solar cells is a major goal of solar cell research. In addition to the selection of battery substrate materials and the improvement of substrate fabrication technology, selecting a suitable printing stencil can also improve the conversion efficiency of the battery.

With the rise of the electronics industry and related industries, the application of precision printing and small-size packaging is becoming more and more extensive. In the process of precision printing and small-size packaging, the mask should be involved. Conventional masks include metal masks and composite masks. At present, the material of the metal type mask is generally a nickel-based alloy; and the composite type mask is relatively complicated, and includes a screen and a photosensitive material coated on the surface of the screen.

Chinese patent CN101241956 describes a method for manufacturing a large-area nano-thin film solar cell, which is mainly characterized in that a single DSSC is made into strips, and a strip-shaped single DSSC is connected in series to form a large-area solar cell by using a corrosion-resistant interconnect strip. A protective barrier layer is disposed on both sides of the corrosion interconnecting strip, or a low-resistance grid electrode prepared by a mesh printing method, and a protective film is coated on the surface of the low-resistance grid electrode, and then a low-resistance grid electrode covered with a protective film is used A plurality of strip-shaped single-cell DSSCs are connected in parallel to form a large-area solar cell, and a large-area solar cell side glass and a TCO contact surface are provided with a perfusion tank, and are pumped from the perfusion tank at a perfusion tank at one end of the large-area solar cell. After the electrolyte and dye, the pot is broken and then sealed.

Chinese patent CN102336051A discloses a solar cell mesh printing device, which comprises a printing blade, an auxiliary blade, a returning knife and a printing screen. The feature is that two baffle structures are mounted on the printing screen on both sides of the edge of the printing blade. The baffle structure is mainly composed of a baffle surface, a baffle frame and a mounting frame; the bottom of the baffle surface and the mesh surface can be separated or bonded by a flexible material; the edge of the returning knife and the printing scraper and the auxiliary scraper are blocked. The surface of the board is seamlessly contacted; the printing head drives the scraper and the returning knife to slide in contact with the baffle surface, so that the slurry moves in the range enclosed by the baffle surfaces, the scraper and the returning knife on both sides, so that the slurry does not move to the two Side flow.

Chinese patent CN202058761U discloses a screen printing crystal 矽 solar cell positive silver screen, comprising: a ruthenium, a main grid line, a chamfer, a sub-gate line, and a main gate line and a sub-gate line on the ruthenium. The main gate line and the sub-gate line are vertically disposed, and a chamfer is provided on the cymbal piece, which can be positive The surface electrode grid line is effectively expanded on the surface of the cymbal, the coverage area is increased, and the photocurrent is effectively collected, thereby improving the efficiency of the battery sheet.

Chinese patent CN101969082A discloses a solar cell manufacturing technology combining two mesh printing and engraving, which is used for manufacturing a solar cell with two printing electrodes, which includes engraving technology and two printing technologies, and the engraving technology system is: The groove is formed in the electrode grid line region on the surface of the cymbal to form an etched groove in the electrode grid line region; the two printing techniques are: a, the first printing electrode: filling the printed electrode slurry into the etching groove and drying Forming a first layer of electrodes in the etching groove; b, printing the second time electrode: printing the electrode on the outer surface of the first layer electrode to form a second layer electrode on the surface of the electrode surface of the chip.

The screens constituting the conventional composite mask are woven wire mesh or polyester mesh, etc., such meshes may cause the sizing effect of the final forming mask due to the characteristics of the woven warp and weft joints, such as: sizing Unevenness; in the production process of the actual mask, it is often necessary to first press the screen to minimize the effect of the braided screen. However, this operation does not completely avoid the adverse effects of the warp and weft nodes.

In view of this, the purpose of the present invention is to provide a honeycomb screen having a stable structure and high mechanical strength, and a mask made of the same, which is used for solving the screen used in the precision printing technology of the prior art. The structure is unstable and the mechanical strength of the screen is low.

In order to achieve the above and other objects, the present invention provides a honeycomb-like mesh which is a honeycomb structure in which polygonal arrays are connected to each other, and the polygonal structure constituting the mesh honeycomb structure is a regular hexagon.

In an embodiment of the present invention, the honeycomb mesh is provided with a non-normal hexagon array region, and the non-nual hexagon array region forms a specific pattern on the regular hexagon array, and the regular hexagon array They are connected by a non-positive hexagon which connects the sides of the corners of the regular hexagon as a bridge line.

In an embodiment of the present invention, the wire diameter r1 of the bridge wire and the wire diameter r2 of the wire mesh constituting the regular hexagonal region are in the range of 10 um. R1 R2 80um; the number of meshes forming a regular hexagonal region is 100 to 800 mesh.

In another embodiment of the present invention, the wire diameter r1 of the bridge wire and the wire diameter r2 of the wire mesh constituting the regular hexagonal region are in the range of 15 um. R1 R2 40um; the number of meshes forming the regular hexagonal region is 200 to 400 mesh.

In an embodiment of the present invention, the wire diameter of the wire mesh of the graphic area on the honeycomb screen is not larger than the wire diameter of the wire of the non-graphic area; the wire mesh of the graphic area on the honeycomb wire mesh The wire diameter of the wire is uniform, or the wire diameter of the two ends of the wire mesh of the graphic area on the honeycomb mesh is larger than the wire diameter of the middle portion.

In an embodiment of the present invention, the wire diameter of the wire mesh constituting the honeycomb screen pattern region is uniform; the wire mesh of the honeycomb wire mesh is continuous and non-woven.

In one embodiment of the present invention, the honeycomb web is generally formed in one piece and has a smooth surface and a structure without a woven warp and weft.

In one embodiment of the present invention, the honeycomb wire mesh described above is made by electroforming The material is pure nickel or nickel-based alloy.

In the above technical solution, a preferred technical solution is that the wire diameter of the wire mesh constituting the honeycomb screen pattern region is uniform; and the force buffering tape and the side connected to the buffer tape are disposed around the non-graphic area. The hole belt; the mesh of the honeycomb wire is a continuous non-woven type. The honeycomb mesh number is between 200 and 450 mesh, the wire diameter is between 15 and 30 um, and the thickness is between 15 and 30 um; the wire mesh of the graphic area on the honeycomb mesh The wire diameter is not larger than the wire diameter of the wire mesh of the non-graphic area; the wire diameter of the wire of the graphic area on the honeycomb screen is uniform, or the two ends of the wire of the graphic area on the honeycomb wire mesh The wire diameter is larger than the wire diameter of the middle portion. A preferred technical solution is that the honeycomb mesh is integrally formed and has a smooth surface and a structure of a woven-like warp and weft node. The honeycomb wire mesh system is obtained by electroforming technology and is made of a pure nickel material or a nickel-based alloy material.

The present invention also includes a mask made using the above-described honeycomb screen, the grid opening size of the mask pattern area being no larger than the size of the grid opening of the corresponding pattern on the honeycomb screen.

In the above technical solution, a preferred technical solution is that the pattern formed by the mesh opening of the corresponding pattern on the honeycomb screen is a set of mutually parallel lines corresponding to the gate lines of the mask.

Based on the above, the present invention provides a honeycomb wire mesh which has the following advantages: 1. The honeycomb wire mesh system is produced by electroforming technology, and has the characteristics of a flat surface and a non-woven type warp and weft node, which is produced by the same. The solar cell electrode printing screen is uniformly smeared during printing; 2. The honeycomb screen is in the direction corresponding to the fine grid line of the corresponding solar cell electrode printing screen. The upper screen wire reduces the barrier effect of the honeycomb screen on the printing paste.

Non-woven wire mesh, the surface of the wire mesh is smooth, and the mask plate made by the mask is not damaged by the unevenness of the surface during the cleaning and wiping process. The screen can be designed according to the needs of different opening ratio, wire mesh diameter and wire mesh shape to ensure the good sizing effect of the wire mesh while ensuring the life of the wire mesh.

Based on the above advantages, the solar cell electrode printing screen prepared by the honeycomb screen can print the "high aspect ratio" of the solar cell electrode grid structure, which is beneficial to the collection of current by the solar cell. Transmission, thereby correspondingly improving the conversion efficiency of the solar cell.

In order to make the above features and advantages of the present invention more comprehensible, the following embodiments are described in detail with reference to the accompanying drawings.

I‧‧‧ is the grid area

II‧‧‧ is a non-mesh area

III‧‧‧ is a partial area of the screen of the preset graphic

31‧‧‧ is a line

41‧‧‧ is a non-normal hexagonal area

42‧‧‧ is a graphical local area

41‧‧‧ is a non-normal hexagonal area

51‧‧‧ is the bridge line

52‧‧‧A wire mesh line in a regular hexagonal area

R1‧‧‧ is the width dimension of the non-normal hexagonal area

R1‧‧‧ is the width dimension of the non-normal hexagonal area

R2‧‧‧ is the opening size of the hollow strip

2,6,7,8,9‧‧‧ honeycomb wire mesh

1 is a schematic view showing the overall structure of the honeycomb screen; FIG. 2 is a partial enlarged view of the screen of FIG. 1; FIG. 3 is a schematic view showing the overall structure of the screen provided with a special grid structure; a partial enlarged schematic view of a screen having a preset pattern; FIG. 5 is a partially enlarged schematic view of FIG. 4; and FIG. 6 is a schematic structural view of a honeycomb screen; Figure 7 is a schematic view showing the structure of the honeycomb screen; Figure 8 is a schematic view showing the structure of the honeycomb screen; Figure 9 is a schematic view showing the structure of the honeycomb screen; and Figure 10 is showing the surface of the screen. Schematic representation of a layer of photopolymer.

The embodiments of the present invention are described below by way of specific embodiments, and those skilled in the art can readily appreciate other advantages and functions of the present invention from the disclosure of the present disclosure. The present invention can also be implemented or applied by various other specific embodiments. The details of the present specification can also be modified and changed without departing from the spirit and scope of the present invention.

It is to be understood that the structure, the proportions, the size and the like in the drawings are only used in conjunction with the disclosure of the specification for the understanding and reading of those skilled in the art, and are not intended to limit the creation. The qualifications of the implementation are not technically meaningful, and any modification of the structure, change of the proportional relationship or adjustment of the size shall remain in the interests of the creation and the purpose of the creation. The technical content disclosed in this creation can be covered. In the meantime, the terms "upper, lower", "one" and "bottom" as used in this specification are for convenience of description only, and are not intended to limit the scope of the creation of the creation. Changes or adjustments are considered to be within the scope of this creation if there is no material change in the material.

[Example 1]

The present invention provides a honeycomb screen, as shown in Fig. 1, which is a honeycomb structure composed of a polygonal array. Fig. 1 is a schematic view showing an overall structure of the honeycomb screen, and Fig. 2 is an enlarged view showing a portion I of Fig. 1 (i.e., a portion of the main body of the screen), Fig. 2 The polygonal shape of the nest structure of the honeycomb screen 2 shown is a regular hexagon, so that the design structure is stable, so that the mechanical strength of the screen is large.

Figure 3 is a schematic view showing another overall structure of the screen provided with a special grid structure on the basis of the above-mentioned honeycomb screen, the special grid structure forming a figure on the honeycomb screen body As shown in FIG. 3, one of the patterns is a plurality of sets of line structures, that is, the figure is obtained by an array of lines 31.

Figure 4 is a partially enlarged schematic view of the screen having the preset pattern, which corresponds to the portion III in Figure 3, and the non-normal hexagonal region 41 shown in the figure corresponds to the line in Figure 3. 31. The non-normal hexagonal region 41 is derived from at least one other set of other graphical arrays. The portion 42 in Fig. 4 is further enlarged to be the fifth figure. As shown in Fig. 5, the non-normal hexagonal region 41 is arranged in a regular pattern and connects adjacent two regular hexagonal regions. The bridge line 51 and the boundary of a partial regular hexagon are formed. Further, as shown in Fig. 5, the bridge line 51 is a set of equally spaced parallel screen lines. Preferably, the ends of the bridge lines 51 are connected to the corners of the regular hexagon.

The wire diameter r1 of the bridge wire 51 and the wire diameter r2 of the wire mesh 52 constituting the regular hexagonal region are r1 = 13, r2 = 80, and the mesh number of the regular hexagonal region is 200 mesh.

[Example 2]

The present invention provides a honeycomb-like mesh structure which is a honeycomb structure in which polygonal arrays are connected to each other, and the polygonal structure constituting the honeycomb structure is a regular hexagon. The other structure is the same as that of the first embodiment.

The wire diameter r1 of the bridge wire 51 and the wire diameter r2 of the wire mesh 52 constituting the regular hexagonal region The system is: r1=15, r2=40, and the number of meshes forming the regular hexagonal region is 400 mesh. By adjusting the wire diameter and mesh size, it is possible to control the reasonable opening ratio and the mechanical strength of the wire mesh to meet the different specifications of the next use.

[Example 3]

As shown in FIG. 6, the structure of the honeycomb screen is provided. The present invention provides a honeycomb screen 6 which is a honeycomb structure in which polygonal arrays are connected to each other, and the polygonal structure constituting the honeycomb structure is hexagon. The main structure is basically the same as that of Embodiment 1, except that the connection position of the bridge line and the hexagon is different or the relative positions of the two adjacent regular hexagonal areas that need to be connected are different.

The honeycomb wire mesh is an electroformed flat metal plate body made of a nickel-based alloy material; a regular hexagonal region of the outer edge of the honeycomb wire mesh, and a line of the wire of the wire The diameter of the radial dimension is larger than that of the intermediate portion, and the edge of the regular hexagonal region is connected to the edge of the regular hexagonal region for fixing.

[Embodiment 4]

As shown in FIG. 7, the schematic diagram of the structure of the honeycomb screen, the present invention provides a honeycomb screen 7, which is a honeycomb structure in which polygonal arrays are connected to each other, and the polygonal structure constituting the honeycomb structure is hexagon. The main structure is basically the same as that of Embodiment 1, except that the connection position of the bridge line and the hexagon is different or the relative positions of the two adjacent regular hexagonal areas that need to be connected are different.

[Embodiment 5]

As shown in FIG. 8 , which is a schematic structural view of the honeycomb screen, the present invention provides a honeycomb screen 8 which is a honeycomb structure in which polygonal arrays are connected to each other, and constitutes a polygonal structure of the honeycomb structure. The structure is a regular hexagon, and its main structure is basically the same as that of the first embodiment, and the difference is that the bridge line constituting the non-normal hexagonal region has a non-perpendicular relationship with the main system of the regular hexagonal region.

The honeycomb wire mesh is an electroformed flat metal plate body made of a nickel metal material. The regular hexagonal region of the outer edge of the honeycomb mesh has a wire diameter dimension at both ends of the wire mesh which is larger than a wire diameter of the intermediate portion, and has a side hole structure for fixing to the regular hexagonal edge.

[Embodiment 6]

As shown in Fig. 9, it is a schematic structural view of the honeycomb mesh. The present invention provides a honeycomb screen 9 which is a honeycomb structure in which polygonal arrays are connected to each other, and the polygonal structure constituting the honeycomb structure is a regular hexagon, and the main structure thereof is basically the same as that of Embodiment 1, and the difference is different. It is that the bridge line constituting the non-normal hexagonal region has a non-perpendicular relationship with the main system of the regular hexagonal region. The honeycomb wire mesh is an electroformed flat metal plate body made of a nickel metal material. The regular hexagonal region of the outer edge of the honeycomb mesh has a wire diameter dimension at both ends of the mesh line which is larger than a wire diameter of the intermediate portion, and a side hole structure for fixing is connected to the edge of the regular hexagonal region.

[Embodiment 7]

The present invention provides a honeycomb screen having a structure substantially the same as that of Embodiment 4, as shown in Fig. 10, a schematic view of the surface of the honeycomb screen coated with a layer of photopolymer. It corresponds to the area structure shown in Fig. 7, that is, the structure shown in Fig. 10 is coated or pressed with a layer of photopolymer based on the structure shown in Fig. 7, and the photopolymer is distributed in the regular hexagon of the screen. On the region and part of the non-normal hexagonal region, the region where the photopolymer is not coated or pressed forms an elongated opening with a bridge line, as shown in Fig. 10: the opening size R2 of the hollow strip The corresponding non-normal hexagonal region has a width dimension R1, R2 = 20um, and R1 = 300um.

[Embodiment 8]

The present invention provides a honeycomb screen having a structure substantially the same as that of Embodiment 5, the schematic view of which is coated with a layer of photopolymer. It corresponds to the area structure shown in Fig. 8, that is, a layer of photopolymer is pressed on the basis of the structure shown in Fig. 8, and the photopolymer is distributed in the regular hexagonal region of the screen and a part of the non-normal hexagonal region. Above, the region where the photopolymer is not coated or pressed forms an elongated opening with a bridge line, as shown in Fig. 10: the opening size R2 of the hollow strip The corresponding non-normal hexagonal region has a width dimension R1, R2 = 30 um, and R1 = 150 um.

[Embodiment 9]

The present invention provides a honeycomb screen having a structure substantially the same as that of Embodiment 9, a schematic view of the surface of the honeycomb screen coated with a layer of photopolymer. It corresponds to the area structure shown in Fig. 9, that is, a layer of photopolymer is pressed on the basis of the structure shown in Fig. 9, and the photopolymer is distributed in the regular hexagonal region of the screen and a part of the non-normal hexagonal region. The area where the photopolymer is not coated or pressed is formed into an elongated opening with a bridge line, and the dimensional relationship shown is: opening size R2 of the hollow strip Its corresponding non-normal hexagonal region has a width dimension R1, that is, R2 = 30 um, and R1 = 150 um.

[Embodiment 10]

The present invention provides a honeycomb screen comprising a grid area, a non-mesh area, the grid area being connected to a non-mesh area, the non-mesh area being disposed at a periphery of the grid area, the grid Zone by two groups a mutually perpendicular set of wire mesh lines, wherein a middle portion of the mesh region of the honeycomb mesh is provided with a pattern region, the pattern being constituted by a honeycomb wire mesh along a transverse or longitudinal wire; the honeycomb wire The mesh-free woven type warp and weft node has a structure integrally formed and has a smooth surface, that is, the honeycomb wire mesh system is formed into a continuous non-woven type.

Figure 2 is a partially enlarged schematic view of the wire mesh, which is composed of mutually interlaced wire meshes. In the present embodiment, the mesh number of the honeycomb wire mesh is 330 mesh, and the mesh routing diameter is 20um. The thickness of the wire mesh is 25 um.

FIG. 3 is a partially enlarged schematic view of the honeycomb screen force buffering strip. The diameter of the buffer strip varies according to a certain variation rule. The law described in this embodiment is shown in FIG. The wire diameter from the middle to the edge of the honeycomb mesh is gradually increased, that is, r1 is smaller than r2 and smaller than r3, such as: r1=20um, r2=30um, r3=40um. As shown in Fig. 1, the outer edge of the wire diameter of 40 um is connected to the edge hole area of the mesh. This design allows the mesh to withstand the tension provided by the outside when it is tight.

[Embodiment 11]

The present invention provides a honeycomb screen, the basic structure of which is the same as that of the first embodiment, and the transformed parts are as follows: the mesh number of the mesh is 400 mesh, the mesh routing diameter is 25 um, and the thickness of the mesh cloth is 20um.

On the basis of the above, the honeycomb screen has the following structural modifications: the honeycomb screen is provided with a pattern, and the pattern described in this embodiment is a group of non-normal hexagonal regions 41 which are parallel to each other. Lines, as shown in Figure 4. Figure 5 is shown in Figure 4. In the enlarged view of the 42 part, the 51 in Fig. 5 is the screen line of the non-normal hexagonal area 41 shown in Fig. 4, and the 52 is the screen line of the regular hexagonal area, the non-normal hexagonal A lateral screen line is absent from the shaped area 41.

Fig. 6 is an enlarged schematic view showing another embodiment of the portion III of Fig. 3, wherein the wire diameter of the wire mesh in the pattern area has the following regularity: the honeycomb wire mesh body diameter r1> the graphic area inner wire mesh line The wire diameter r4> the wire diameter r5 of the middle portion of the inner wire mesh of the graphic area; the wire diameter of the wire of the graphic area may be the following rule: as shown in Fig. 7, the wire mesh inside the graphic area The wire diameter of the wire is uniform, and there is a honeycomb wire mesh diameter r1 The wire diameter r6 of the wire mesh inside the graphics area.

Figure 8 is a partial schematic view of a mask after coating a masking substance on the honeycomb screen (corresponding to the portion shown in Figure 5), as shown in the opening of the mask shown in the figure. There is only one direction of the screen wire, which acts as a bridge line. Comparing FIG. 5 and FIG. 8 : the grid opening size of the mask pattern area is not larger than the corresponding pattern on the honeycomb screen. The size of the mesh opening, in particular, the mesh opening size of the mask pattern area is less than or equal to the size of the mesh opening of the corresponding graphic on the honeycomb screen. This design can reduce the coating difficulty factor of the mask material of the mask, and since the screen line has only one direction at the opening, relatively few bridge lines reduce the influence on the printing paste, and the mask version can be guaranteed. The cutting effect is good.

In summary, the honeycomb screen provided by the present invention is a honeycomb structure in which polygonal arrays are connected to each other, and the polygonal arrays are connected to each other to form a specific pattern; wherein, one of the preferred embodiments, the polygonal structure of the honeycomb structure It is a regular hexagon to form a regular hexagonal array; the regular hexagonal array is connected by a non-normal hexagon, and the non-normal hexagonal side is used as a bridge to connect the corner points of the regular hexagon, and the solution is solved. Know that the screen structure used in precision printing technology is unstable, and the screen The problem of low mechanical strength. Therefore, this creation effectively overcomes various shortcomings in the prior art and has a high industrial utilization value.

The above embodiments are intended to illustrate the principles of the present invention and its effects, and are not intended to limit the present invention. Anyone who is familiar with the technology can modify the above embodiments without departing from the spirit and scope of this creation. Therefore, the scope of protection of this creation should be as listed in the scope of patent application.

41‧‧‧Non-hexagonal area

42‧‧‧ graphic local area

Claims (10)

A honeycomb wire mesh is a honeycomb structure in which a polygonal array is connected to each other, and the mesh of the wire mesh honeycomb structure is a regular hexagon and constitutes a regular hexagonal array. The honeycomb screen of claim 1, wherein: the honeycomb screen is provided with a non-normal hexagonal array region, and the non-normal hexagonal array region forms a specific on the regular hexagon array The pattern, the regular hexagonal arrays are connected by a non-positive hexagon, which connects the sides of the corners of the regular hexagon as a bridge line. The honeycomb wire mesh according to claim 2, wherein the wire diameter r1 of the bridge wire and the wire diameter r2 of the wire mesh constituting the regular hexagonal region are in a range of 10 um ≤ r1 ≤ r2 ≤80um; the number of meshes forming the regular hexagonal region is between 100 and 800 mesh. The honeycomb screen according to claim 2, wherein the wire diameter r1 of the bridge wire and the wire diameter r2 of the wire mesh constituting the regular hexagonal region are in a range of 15 um ≤ r1 ≤ r2 ≤ 40 um; the number of meshes forming the regular hexagonal region is between 200 and 400 mesh. The honeycomb mesh according to claim 2, wherein: the wire diameter of the wire mesh of the graphic area on the honeycomb mesh is not larger than the wire diameter of the wire of the non-graphic area; the honeycomb wire The wire diameter of the wire mesh line in the graphic area on the net is uniform, or the wire diameter of the two ends of the wire mesh of the graphic area on the honeycomb wire mesh is larger than the wire diameter of the middle portion. The honeycomb screen of claim 1, wherein: the wire diameter of the wire mesh constituting the honeycomb screen pattern area is uniform; the mesh line of the honeycomb wire mesh is continuous and non-woven. type. The honeycomb mesh according to claim 1, wherein the honeycomb mesh is integrally formed and has a smooth surface and a structure of a woven-type warp and weft node. The honeycomb screen according to claim 7, wherein the honeycomb screen is obtained by electroforming, and is a screen made of pure nickel material or nickel-based alloy material. A reticle prepared by using the honeycomb screen of any one of the above-mentioned claims, wherein the mask pattern area has a mesh opening size not larger than the honeycomb shape. The size of the mesh opening on the screen corresponding to the graphic. The mask of claim 9, wherein: the pattern formed by the grid opening of the corresponding pattern on the honeycomb screen is a set of mutually parallel lines, which are opposite to the grid line of the mask. correspond.