JP2010094687A - Rolling roll and mesh for screen printing - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rolling roll having an easily formed fine surface pattern and surface hardness suitable for rolling. <P>SOLUTION: The rolling roll 7 is manufactured by a manufacturing method including a step S1 for applying a photosensitive resin 2 to an original plate 1 as a thin flat plate, exposing the plate using a mask 3 and corroding and cleaning the plate; a step S2 for bending the plate to form the flat plate into a thin cylindrical sleeve 4; a step S3 for applying nitriding heat treatment to the sleeve 4 to harden the surface; and a step S4 for inserting a hardened sleeve 5 into a roll base 6 and assembling them into the rolling roll 7. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a rolling roll and a screen printing mesh having a regular fine uneven pattern on the surface.

As is well known, in order to improve the surface paintability and design properties of a press-molded product or rolled material using a steel plate, an aluminum plate or the like as a base plate, a fine uneven shape may be formed on the surface.
In such a rolled material, two-dimensional parameters such as arithmetic average roughness Ra and PPI (peak per inch) measured with a stylus type surface roughness meter have predetermined values for the function of surface paintability. Surface irregularities are required. On the other hand, in order to provide a high added value in terms of design, patterned regular surface irregularities are required.
Regular surface irregularities are often formed by etching or the like after rolling and press forming of the base plate, but in order to reduce costs, surface processing is performed until rolling or press forming or simultaneously with rolling and press forming. It is hoped that. For this purpose, there is a method of adopting a rolling roll having a fine uneven pattern formed on the surface and forming a fine uneven shape on the surface while performing rolling and press forming.

Examples of the rolling roll having a fine concavo-convex pattern formed on the surface include a discharge dull roll, a scratch roll, and a shot dull roll used in steelworks. However, it is difficult to use these rolling rolls for surface processing with high design properties. This is because such rolling rolls are subjected to surface processing by electric discharge machining and shot blasting, and it is difficult to say that the rolling rolls have a surface irregular shape that is regularly patterned.
On the other hand, there is a rolling dull roll manufactured using a laser or an electron beam. However, with this processing method, the pitch of the surface irregularities is about several hundreds μm, and it is difficult to form a fine irregular pattern.

The techniques described above have already been disclosed in numerous patent documents.
For example, Patent Document 1 discloses a technique for forming a fine uneven pattern by shot blasting and etching. Further, as disclosed in Patent Document 2, there is known a technique for forming a pattern by melting a roll while moving a laser oscillator head so that a laser dull device can form a pattern with high accuracy.
Patent Document 3 discloses a method for forming protrusions on the roll surface by directly applying a resin mask to the roll and exposing the roll to form convex portions by plating. As shown in Patent Document 4, a method for forming a protrusion by laser melting a powder is also known.
JP 2000-317836 A Japanese Patent Laid-Open No. 2005-34865 JP-A-5-156492 JP 2005-7448 A

However, all of Patent Documents 1 to 4 are methods for directly forming a fine pattern on a roll having a hard surface, and special large-scale equipment is required to process a large roll of an actual machine. is there. In addition, there are the following problems when creating an actual roll.
That is, with the technique disclosed in Patent Document 1, it is clear that it is difficult to form a regular fine pattern when the hardness of the surface of the rolling roll is high.
The technique disclosed in Patent Document 2 can be applied to large rolls by modifying an existing laser dull device. However, if a regular fine pattern is formed by laser processing, the processing time is long and the processing cost is high. End up.

If the protrusion is formed by plating as in the technique disclosed in Patent Document 3, there is a high possibility that peeling occurs due to a large shear stress acting on the protrusion during rolling. It has been clarified in the field that it is inappropriate for processing.
In addition, even if the protrusions are formed by powder melting as in the technique disclosed in Patent Document 4, there is a problem in the bonding strength between the protrusions and the base material, which is inappropriate for surface processing of the rolling roll. It is.
Then, an object of this invention is to provide the rolling roll which has a regular fine uneven | corrugated pattern on the surface suitable for rolling of a metal plate etc. in view of the said problem. This rolling roll is suitable for producing a screen printing mesh.

In order to achieve the above-described object, the present invention takes the following technical means.
That is, the rolling roll according to the present invention includes a step of forming a concavo-convex pattern on the surface of a plate-shaped flat plate by an etching process, a step of forming a flat plate having the concavo-convex pattern formed on the surface thereof on a cylindrical sleeve, The sleeve is manufactured through a step of hardening the sleeve and a step of fitting the sleeve after hardening to the outer periphery of a cylindrical roll base.
With this configuration, since the etching process is performed in a flat plate state, a fine and regular uneven pattern can be easily formed on the surface of the flat plate without requiring a special apparatus. Thereafter, the shape is processed from a flat plate to a sleeve by bending. After forming into such a sleeve shape, the sleeve is cured to such an extent that it can be transferred and rolled, and after the curing, the sleeve is inserted into the outer surface of the rolling roll. For this reason, it is suitable for transfer rolling because it is flat and soft at the time of etching, and a fine uneven pattern can be easily formed on the surface and can be easily processed into a sleeve, is hardened in a sleeve shape, and is inserted into a rolling roll. A rolling roll with hardness can be obtained.

The rolling roll according to the present invention includes a step of forming a concavo-convex pattern on the surface of a plate-like flat plate by etching treatment, a step of forming a flat plate having the concavo-convex pattern formed on the surface thereof on a cylindrical sleeve, and a sleeve May be manufactured through a step of fitting the outer periphery of the cylindrical roll base and a step of curing the integrated sleeve and roll base.
Preferably, the Vickers hardness of the surface of the sleeve subjected to the curing treatment is Hv 500 or more.
Preferably, the sleeve has a seam that is generated when the ends of the flat plates are joined together.

More preferably, the concavo-convex pattern may be formed only on the center side surface of the plate-shaped flat plate.
Further, the screen printing mesh according to the present invention is a screen printing mesh provided with a plurality of openings on the surface of the mesh body for transferring the printing paste to the printing object, and the mesh body includes the opening. It is formed in the cross-sectional shape which curved so that it might move away from the said printing target object as it approaches the edge of a part.
In addition, it is preferable that the opening part of the mesh for screen printing is punched out using the above-mentioned rolling roll.

  The rolling roll according to the present invention has a regular fine uneven pattern on the surface, which is suitable for rolling metal plates and the like.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.
1 and 2 show an embodiment of a rolling roll according to the present invention.
As described above, when a sleeve molded into a roll shape after processing is used, since the processing is initially a flat plate, an existing surface fine processing technique can be applied. In particular, if a stainless steel plate or the like is a flat plate, a fine surface pattern can be easily created by photomask etching. However, such a material that can be easily etched is not suitable as a material for the rolling roll because it does not have sufficient strength.

On the other hand, the thin plate that can be etched can be plastically deformed, and it is easy to produce a cylindrical sleeve.
Therefore, the etched flat plate is formed into a cylindrical shape by roll bending or the like, and a sleeve is formed by welding. The sleeve is heat-treated to increase the hardness, and a roll base is formed by inserting a roll base serving as a core material of the roll. The roll base preferably has substantially the same shape as a normal work roll, but is not limited thereto.
The rolling rolls thus produced can easily change the surface form of the rolled material by exchanging the sleeve for each of various surface forms. In general, transfer rolling does not require a large reduction (the reduction ratio is less than 10%), so that it is not necessary to firmly join the sleeve and the roll base. When a large rolling reduction is required or when the rolling target is hard, the sleeve and the roll base may slip. In this case, the sleeve and the roll base are firmly joined by shrinkage fitting or the like. It can be rolled.

In FIG. 1, the process of manufacture of the rolling roll which concerns on this invention is shown.
The production process of the rolling roll includes a step S1 of forming a fine uneven pattern on the surface of the plate-like flat plate by etching, a step S2 of forming a flat plate having the uneven pattern formed on the surface thereof on a cylindrical sleeve, A step S3 for curing the sleeve and a step S4 for fitting the cured sleeve to the outer periphery of the cylindrical roll base are included.
Specifically, the base plate 1 is a metal material whose components are designed so that strength and wear resistance are increased by nitriding, and stainless steel is applicable.

The base plate 1 has an appropriate plate thickness of 10 mm or less in view of the ease of etching bending. This is because, when the work roll diameter is 30 mm to 1000 mm, if the plate thickness is increased, the unevenness etched on the surface during bending is plastically deformed and the uneven pattern is broken.
Next, a photosensitive resin is applied to the entire surface of the flat base plate 1 to form a photosensitive resin film 2. The photosensitive resin film 2 serves as a masking material in the etching process, and for example, a paint containing a material that is cured by ultraviolet light is used, and the thickness may be about 10 to 50 μm. As a method for forming the photosensitive resin film 2, a spray method or an electrostatic coating method capable of uniform coating over the entire surface is suitable.

Next, the pattern mask 3 is placed on the base plate 1 coated with the photosensitive resin film 2 and irradiated with ultraviolet light. For this mask 3, a pattern actually formed on the base plate 1 (for example, a pitch of 200 μm between recesses and a groove width of 70 μm) is formed large, and an optical lens is used to form a fine image. One photosensitive resin film 2 may be exposed.
By this mask 3, the uncured photosensitive resin film 2 remains in the portion of the photosensitive resin film where the ultraviolet light is blocked, and the cured photosensitive resin film 2 is formed in the portion of the photosensitive resin film through which the ultraviolet light is transmitted. Is done.

The pitch between the concave portions of the fine uneven pattern formed on the surface of the base plate 1 can be 200 μm or less, preferably 100 μm to 20 μm as described above. As described above, the groove width of the concave portion formed in is 70 μm or less, and preferably 40 μm to 10 μm.
Next, etching is performed on the base plate 1 to corrode portions corresponding to the uncured photosensitive resin film 2 to form concave portions. For the etching process, general electrolytic etching, chemical etching, or the like can be used. By this etching process, a recess having a depth of about 10 to 40 μm is formed on the surface of the base plate 1 by corrosion.

When the formation of the recess by etching is thus completed, the photosensitive resin film 2 left on the surface of the remaining base plate 1 can be removed according to a normal method such as brush cleaning or solvent treatment. Innumerable fine regular uneven patterns are formed on the surface of 1.
A thin cylindrical (pipe) shaped sleeve 4 having a diameter of, for example, 50 mm is formed by bending the etched flat plate. At this time, after winding the base plate 1 so that the uneven shape formed on the surface of the base plate 1 becomes the outer surface of the sleeve, and joining the “seam 8” where the ends of the base plate 1 abut each other by welding Polish the welded area and finish it smoothly. That is, in order to mold the base plate 1 which is a thin flat plate into the thin-walled cylindrical sleeve 4, there is a seam 8 in which the flat plate is joined to the cylindrical surface or / and the back surface. Although depending on the use of the metal product, the transferred and rolled metal product does not cause a problem even if there is a flaw due to the presence of the seam 8 itself. For example, when the base plate 1 is cut into a predetermined size and used after forming the concavo-convex pattern, it can be easily cut using the seam 8 as a mark for cutting.

That is, when rolling with the rolling roll 7, when the rolling roll 7 is rotated by one turn, one unit of product is often transferred. In such a case, the product unit can be distinguished by the seam 8 formed for each turn of the rolling roll 7, and can be easily cut without marking or tracking.
As shown in FIG. 5, it is also possible to form a concavo-convex pattern only on the central surface of a plate-shaped flat plate, and to form a portion where the concavo-convex pattern is not formed around the concavo-convex pattern. In this way, when the base plate 1 is cut and used as described above, the periphery of the concavo-convex shape can be used as a product mounting portion, which is convenient.

That is, in the product provided with the uneven pattern and the non-recessed pattern as described above, a part for bonding or welding is required to attach to other parts. However, the concavo-convex pattern formed by punching has low strength and is not suitable for attachment to other components. Therefore, by providing a non-processed non-concave pattern around the concavo-convex pattern and attaching it to other components using this non-concave pattern, it is possible to attach to other components without causing a decrease in strength.
Next, since the material (sleeve 4) suitable for etching and bending is soft in the first place, it cannot be used as a rolling roll in this state. Therefore, it is necessary to harden the sleeve 4 from the surface layer to a depth of about 30 to 500 μm. However, in normal quenching or carburization, the sleeve 4 is heated to a high temperature, and thus heat distortion is likely to occur, and such heat treatment cannot be applied.

On the other hand, for example, a nitriding heat treatment in which nitrogen is infiltrated into the surface of the material by heating to about 500 ° C. in NH ₃ gas to form a hardened layer of iron nitride has a low processing temperature and no volume change. Therefore, the nitriding heat treatment is suitable for the hardening treatment for the sleeve 4 as in the present invention. It is preferable that the surface hardness of the sleeve 4 is set to a Vickers hardness Hv 500 or more by this nitriding heat treatment. Especially preferably, it is good to set it as the range of Hv550-Hv1200.
The rolling sleeve 7 is completed by inserting the hardening sleeve 5 whose surface is hardened through the nitriding heat treatment into the roll base 6. The cured sleeve 5 created here is fitted into the roll base 6 by shrink fitting to produce a rolling roll 7. However, considering the ease of replacement of the hardened sleeve 5, it is not always necessary to use the rolling roll 7 by shrink fitting.

As shown in FIG. 4, there is no problem even if the rolling roll 7 is formed by performing a nitriding heat treatment after the sleeve 5 is fitted into the roll base 6 and integrated.
The thus-produced rolling roll 7 is a transfer and / or rolling roll having a hardness Hv of 500 or more, a fine and regular uneven pattern on the surface, and a seam in which a flat plate is joined to the cylindrical surface or back surface. .
The rolling roll 7 manufactured through the manufacturing process described above and an example of rolling using the rolling roll 7 will be described below.

On the base plate 1 of SUS304 having a plate thickness of 1 mm, irregularities having a cross section as shown in FIG. This base plate 1 was processed into a sleeve 4 by bending and hardened by gas nitriding. The sleeve 5 after the curing treatment was inserted into a roll base 6 having a diameter of 50 mm to form a rolling roll 7, and transfer rolling was performed by a four-high rolling mill provided with a pair of the rolling roll 7 and a backup roll having a diameter of 250 mm. Note that pure aluminum was used as the rolled material.
FIG. 3 is a laser micrograph of the rolled material surface after rolling. As is apparent from this photograph, fine and regular surface irregularities can be reliably formed on the rolled material (transfer material) by using the rolling roll 7 of this embodiment.

The rolled plate having fine and regular surface irregularities produced by transfer rolling using the rolling roll 7 of the present invention can improve the heat exchange efficiency, for example, and the heat medium circulation of the heat exchanger It is suitable to be used for a part.
As described above, the base plate 1 constituting the rolling roll 7 is flat and soft at the time of etching, and a fine uneven pattern can be easily formed on the surface. Even after etching, it is soft and easy to process into the sleeve 4. After being processed into a sleeve shape, it is cured and inserted into the roll base 6. For this reason, it is the rolling roll 7 of the hardness suitable for transfer rolling, Comprising: The rolling roll 7 which has a fine and regular surface uneven | corrugated shape on the surface can be obtained.

Next, a screen printing mesh 9 formed using the rolling roll 7 described above and a method for making the screen printing mesh 9 will be described.
As shown in FIG. 6, the screen printing mesh 9 includes a mesh body 10 and a plurality of openings 11 formed in the mesh body 10. These openings 11 are formed so as to penetrate the mesh body 10, and can supply the printing paste 12 supplied from the opposite side of the side facing the printing object 13 to the printing object 13. Yes. The plurality of openings 11 are regularly arranged like a grid on the surface of the mesh body 10 at equal intervals in the vertical and horizontal directions, and the printing paste 12 is uniformly supplied to the surface of the printing object 13 without unevenness. Is possible.

As shown in FIG. 7A, in the screen printing mesh 9 of the present invention, the mesh body 10 is formed in a cross-sectional shape that warps away from the printing object 13 as it approaches the edge of the opening 11. . The reason why the edge of the opening 11 in the mesh body 10 is formed in a warped shape is as follows.
That is, as shown in FIG. 7B, in the conventional mesh 14 in which the cross-sectional shape of the opening 11 in the mesh body 10 is rectangular, the mesh body 10 is pressed against the surface of the print target 13. The surface of the printing object 12 is in contact with the surface of the printing object 13 without gaps, and the printing paste 12 is less likely to wrap around between the surface of the mesh body 10 and the surface of the printing object 13. Therefore, the printing paste 12 is applied only to a portion corresponding to the opening 11, and it becomes difficult to uniformly transfer the printing paste 12 to the surface of the printing object 13.

  On the other hand, as shown in FIG. 7 (c), the conventional electroformed mesh 15 or SUS wire net formed by using electroformed nickel plating has a cross-sectional shape with rounded corners of the opening 11 in the mesh body 10. Thus, even when pressed against the surface of the printing object 13, a gap 16 is generated between them. Therefore, the printing paste 12 easily wraps around between the surface of the mesh body 10 and the surface of the printing object 13, and the ink paste spreads on the surface of the printing object 13 and the printing paste 12 is uniformly transferred. That is, in order to transfer the printing paste 12 uniformly, it is preferable that the surface of the mesh body 10 in contact with the surface of the printing object 13 is formed in a curved shape with respect to the printing object 13 side.

However, since the electroformed mesh 15 has an elliptical cross-sectional shape formed by thickening nickel, the mesh thickness cannot be reduced below a certain level, and the minimum mesh thickness is about 20 μm. Degree. In addition, since a SUS wire mesh requires a certain wire diameter for the SUS wire in order to weave the wire mesh, the minimum thickness of the mesh is about 10 μm. That is, it is difficult to form the mesh with a thickness of 10 μm or less with the electroformed mesh 15 or the SUS wire mesh.
Therefore, as shown in FIG. 8A, in the electroformed mesh 15, a space for holding the printing paste 12 formed in the opening 11 becomes longer in the thickness direction of the mesh. The printing paste 12 is held. As a result, when the printing paste 12 is transferred using this conventional mesh, a large amount of the printing paste 12 is transferred to the position corresponding to the opening 11, and the thickness of the printing paste 12 varies on the surface of the printing object 13. It becomes difficult to transfer the printing paste 12 to the surface of the printing object 13 with a uniform thickness.

Therefore, as shown in FIGS. 7A and 8B, in the screen printing mesh 9 of the present invention, the shape of the mesh body 10 with the edge of the opening 11 warped (in this embodiment, the radius of curvature is 20 μm). And the mesh is thinner than the electroformed mesh 15 (in this embodiment, about 5 μm), and a gap 16 is formed between the surface of the mesh body 10 and the surface of the printing object 13. ing.
In this way, the printing paste 12 wraps around the gap 16 and spreads on the surface of the printing object 13, so that the printing paste 12 can be transferred uniformly (evenly) to the surface of the printing object 13. Moreover, the space for holding the printing paste 12 formed in the opening 11 is shortened in the mesh thickness direction, and the amount (transmission volume) of the printing paste 12 held in the mesh is reduced. As a result, variation in the thickness of the print paste 12 on the surface of the print object 13 is suppressed, and the print paste 12 can be thinly and uniformly transferred to the surface of the print object 13.

Thus, in the screen printing mesh 9 of the present invention, the edge of the opening 11 in the mesh body 10 is formed in a warped shape, and the thickness of the mesh body 10 is reduced, whereby the printing paste 12 is applied to the print object 13. It can be applied uniformly and thinly over the entire surface, and can be printed with clear and sharp outlines.
The screen printing mesh 9 as described above can be produced as follows.
As shown in FIG. 9A, first, a composite plating plate 18 having a die layer 17 made of an elastic material such as aluminum and a plating layer made of a hard material such as nickel or titanium is prepared. Then, for example, the composite plating plate 18 is passed between the rolling roll 7 on which the concavo-convex pattern as shown in FIG. 2 is formed and the work roll provided below the rolling roll 7, and the surface of the plating layer is formed. Press with a rolling roll 7.

When the surface of the plating layer is pressed with the rolling roll 7 in this manner, as shown in FIG. 9B, the protrusion 19 has a depth that reaches the die layer 17 of the composite plating plate 18 until the protrusion 19 reaches the depth of the composite plating plate 18. The portion corresponding to the convex portion 19 on the surface of the plate 18 is pressed down to a depth that reaches the die layer 17.
On the other hand, when the rolling roll 7 is pressed, the position and pressure of the rolling roll 7 are adjusted so that the bottom surface 20a of the recess 20 of the rolling roll 7 remains away from the surface of the plating layer. If it does so, the part corresponding to the recessed part 20 of the rolling roll 7 in the surface of the composite plating board 18 will remain without deform | transforming. At this time, the portion corresponding to the concave portion 20 is deformed so that the edge on the side close to the convex portion 19 is inclined downward (downward) with the reduction of the portion corresponding to the convex portion 19. It is formed in a warped shape (curved shape).

Therefore, as shown in FIG. 9C, in the plated layer after rolling, a portion corresponding to the concave portion 20 of the rolling roll 7 remains curved upward, and a portion corresponding to the convex portion 19 is curved. It is punched below the part that has been cut.
Then, as shown in FIG. 9D, when the die layer 17 is dissolved, the punched-out portion of the plating layer melts together with the die layer 17, and only the downwardly curved portion of the plating layer remains. .
Finally, as shown in FIG. 9 (e), the curved plating layer is turned upside down and bent downward to be attached as the mesh body 10 to obtain the screen printing mesh 9.

  With respect to the screen printing mesh 9 obtained in this way, a conventional mesh 14 described in, for example, Japanese Patent Application Laid-Open No. 08-52951 has a rectangular cross-sectional shape of the edge of the opening 11 in the mesh body 10. Thus, when pressed against the surface of the printing object 13, the printing paste 12 is less likely to go around between the surface of the mesh body 10 and the surface of the printing object 13. Naturally, the printing paste 12 is applied only to the portion corresponding to the opening 11, and it becomes difficult to uniformly transfer the printing paste 12 to the surface of the printing object 13, and clear and clear printing is performed. I can't.

  On the other hand, the electroformed mesh 15 described in, for example, Japanese Patent Laid-Open No. 03-162995 cannot reduce the thickness of the mesh below a certain level as described above, and a large amount of printing paste 12 is retained in the opening 11. Is done. Therefore, when the electroforming mesh 15 is used to transfer the printing paste 12, a large amount of the printing paste 12 is transferred to the position corresponding to the opening 11, and the thickness of the printing paste 12 is the surface of the printing object 13. It varies. Naturally, it becomes difficult to transfer the printing paste 12 to the surface of the printing object 13 with a uniform thickness, and as with the conventional mesh 14, it is impossible to perform printing with clear and sharp outlines.

In contrast to these conventional meshes 14 and 15, in the screen printing mesh 9 of the present invention, by forming the edge of the opening 11 in the mesh body 10 in a warped shape and reducing the thickness of the mesh body 10, The printing paste 12 can be applied uniformly and thinly and uniformly over the entire surface of the printing object 13, and clear and clear printing can be performed.
It should be thought that embodiment disclosed this time is an illustration and restrictive at no points. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  In the above embodiment, the concavo-convex pattern is formed by pressing the rolling roll 7 against the composite plating plate 18 in which a plating layer such as nickel is formed on the aluminum die layer 17, and the die layer 17 is dissolved after the formation of the concavo-convex pattern. The dissolution method for forming the screen printing mesh 9 was exemplified. However, the rolling object having the uneven pattern may not be other than the composite plated plate 18. For example, a rolling roll 7 is pressed against a composite plate formed by bonding a hard metal plate such as nickel or titanium or a metal film to the die layer 17 to form a concavo-convex pattern. A printing mesh 9 can also be formed.

It is a figure which shows the manufacturing process of the rolling roll which concerns on this embodiment. It is detailed sectional drawing of the surface of the rolling roll which concerns on this embodiment. It is the photograph which showed the surface state of the rolling material by which the unevenness | corrugation was transcribe | transferred with the rolling roll which concerns on this embodiment. It is a figure which shows another manufacturing process of the rolling roll which concerns on this embodiment. It is a figure which shows the sleeve with which the uneven | corrugated pattern was formed only in the center side surface of a flat plate. It is a photograph which shows the opening part of the mesh for screen printing. (A) is the sectional view on the AA line of FIG. (B) is sectional drawing of the conventional mesh cut | disconnected by the same part as (a). (C) is sectional drawing of the electroformed mesh cut | disconnected by the same part as (a). (A) is a figure which shows transfer of the printing paste using the mesh for screen printing of this invention. (B) is a figure which shows transcription | transfer of the printing paste using an electroformed mesh. It is a figure which shows the manufacturing method of the mesh for screen printing of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Base plate 2 Photosensitive resin film 3 Mask 4 Sleeve 5 Hardening sleeve 6 Roll base | substrate 7 Rolling roll

Claims (7)

Forming a concavo-convex pattern on the surface of the plate-like flat plate by etching,
Forming a flat plate having the uneven pattern formed on the surface thereof into a cylindrical sleeve;
Curing the sleeve;
A step of fitting the cured sleeve into the outer periphery of the cylindrical roll base;
A rolling roll characterized by being manufactured through Forming a concavo-convex pattern on the surface of the plate-like flat plate by etching,
Forming a flat plate having the uneven pattern formed on the surface thereof into a cylindrical sleeve;
Fitting the sleeve around the outer periphery of the cylindrical roll base;
Curing the integrated sleeve and roll substrate;
A rolling roll characterized by being manufactured through   The rolling roll according to claim 1 or 2, wherein the surface of the cured sleeve has a Vickers hardness of Hv500 or more.   The said roll has a seam produced when the edge parts of the said flat plate are joined, The rolling roll in any one of Claims 1-3 characterized by the above-mentioned.   The said uneven | corrugated pattern is formed only in the center side surface of the said plate-shaped flat plate, The rolling roll in any one of Claims 1-4 characterized by the above-mentioned. Screen printing in which a plurality of openings for transferring the printing paste to a printing object are provided on the surface of the mesh body, and the openings are punched out using the rolling roll according to any one of claims 1 to 5. For mesh,
The mesh for screen printing, wherein the mesh main body is formed in a cross-sectional shape that warps away from the printing object as it approaches the edge of the opening. A mesh for screen printing provided with a plurality of openings on the surface of the mesh body for transferring the printing paste to the printing object,
The mesh for screen printing, wherein the mesh main body is formed in a cross-sectional shape that warps away from the printing object as it approaches the edge of the opening.