JPH0523189B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Industrial Application Field The present invention relates to a mesh roll and a method for producing a mesh roll. In particular, the present invention relates to a mesh roll for lithographic printing and a method for manufacturing the mesh roll for lithographic printing.

(b) Conventional technology The mesh roll used in lithographic printing machines is generally made of copper, copper alloy, etc., which has ink affinity and hydrophobicity, and has many concave portions, which are fine cells, formed on its surface. The surface is formed in combination with other convex parts. The mesh roll performs the following functions in a lithographic printing press.
That is, the ink stored in the ink pan is taken out by the fountain roll, and then supplied from the surface of the fountain roll to the mesh roll, and the ink on the surface of the mesh roll is scraped off by a doctor blade.

Therefore, the ink remains in the cells, which are minute recesses formed on the mesh roll surface. The remaining ink is supplied to the form roll and plate cylinder (see JP-A-58-42463 "Mesh roll for offset printing", JP-A No. 58-56855 "Mesh roll for offset printing", JP-A No. 58-56856 "Mesh roll for offset printing"). ”, 59-204558 “Mesh roll for lithographic printing”).

(c) Problems to be Solved by the Invention The mesh roll needs to have wear resistance in order to withstand the action of constantly scraping off ink with a doctor blade. At the same time, ink affinity is also required in order to supply ink from roll to roll. Furthermore, hydrophobicity is also required to avoid deterioration of ink coverage due to excess water flowing back from the inked roller to the mesh roll.

Therefore, in order to improve wear resistance, the circumferential surface of the mesh roll is plated with a highly wear-resistant material (Japanese Patent Laid-Open No. 58-42463), or a hard layer is provided on the circumferential surface by nitriding (Japanese Patent Laid-Open No. 58-42463). (1983-204558) is known to occur.

On the other hand, for the purpose of improving the affinity with ink, it is known to form a porous layer on the circumferential surface of a mesh roll (Japanese Patent Laid-Open No. 58-56855). The inventor further proposed coating the entire circumferential surface of the mesh roll with an ultra-hard material such as ceramics as a means of improving wear resistance. Next, the surface of the ceramic layer is uniformly plated with a substance that has an affinity for ink, such as copper, and the mesh roll is polished so that the contact surface of the mesh roll with the doctor blade is polished by the friction pressure of the doctor blade during the printing operation or by a rotating grindstone. proposed. As a result, the surface of this mesh roll that comes in contact with the doctor blade becomes a smooth surface with a dense mixture of ceramic and copper, which provides excellent wear resistance due to the ceramic and ink affinity due to the copper. A mesh roll is obtained.

However, when this mesh roll is used for a long period of time, the surface of the mesh roll is abraded due to the friction pressure of the doctor blade, but this abrasion is more likely to occur, and the wear progresses more on the copper present on the surface than on the ceramic. Therefore, when used for a long time, the area ratio of ceramics on the surface of the mesh roll becomes larger than the ratio of copper, resulting in a problem that the ink affinity and hydrophobicity of the mesh roll decrease.

(d) Means for Solving the Problems This invention provides a mesh roll in which the base material is made of a material having ink affinity and hydrophobicity, and in which concave portions and convex portions are formed on the circumferential surface. , the mesh roll base material is exposed, and the boundary between the mesh roll convex surface and the mesh roll recess is an end face of a hard layer that has higher wear resistance than the mesh roll base material and is provided to cover the mesh roll base material's recess surface. and a mesh roll having concave and convex portions formed on its circumferential surface, and a mesh roll base material surface made of an ink-friendly and hydrophobic material, and a mesh roll base material made of a material more wear-resistant than the mesh roll base material. The conventional problems are solved by providing a method for manufacturing a mesh roll, which is characterized by forming a hard layer and then removing the hard layer from the surface of the convex portion of the mesh roll base material until the surface of the convex portion of the mesh roll is exposed. , provides mesh rolls with excellent ink affinity, hydrophobicity, and abrasion resistance.

(E) Effect A hard layer made of a material more abrasion resistant than the mesh roll base material is formed on the surface of the mesh roll base material, which is made of an ink-friendly and hydrophobic material and has concave and convex parts on the circumferential surface, and then the mesh roll is removed. The hard layer is removed from the surface of the mesh roll convex portion until the surface of the convex portion of the base material is exposed.

Then, the center part of the surface of the mesh roll convex part is
The mesh roll base material, which is an ink-friendly and hydrophobic material, is exposed, and the boundary between the mesh roll convex surface and the mesh roll concave part is the mesh roll base material provided to cover the concave surface of the mesh roll base material. A mesh roll is obtained in which the end face of the hard layer has a higher wear resistance than that of the mesh roll.

When this mesh roll is installed in a lithographic printing machine and operated, the center part of the surface of the mesh roll convex part is hydrophobic due to its affinity for ink, so ink is smoothly supplied to the adjacent rollers, and backflow from the inked roll is prevented. Since it has hydrophobicity against excess water, it is also possible to prevent deterioration of ink coverage.

On the other hand, the boundary between the mesh roll convex surface and the mesh roll recess is formed by the end face of a hard layer made of a harder material than the mesh roll base material and formed on the recess of the mesh roll base material.

Therefore, the wear resistance of the mesh roll convex portion against pressure contact with the doctor blade is borne by the end face of the hard layer, and wear of the surface portion of the mesh roll convex portion made of the mesh roll base material is prevented.

Furthermore, in terms of the mesh roll convex portion, the mesh roll base material convex portion having ink affinity and hydrophobicity and the hard layer having wear resistance are formed substantially parallel to each other from the mesh roll axis direction to the circumferential surface direction. And the wear caused by the doctor blade is
Since it occurs from the circumferential surface side, even if only the part of the mesh roll base material on the surface of the mesh roll convex part wears out slightly, the doctor blade will come into contact only with the end face of the hard layer after slight wear. The surface portion of the convex portion of the mesh roll base material is prevented from being further worn until the hard layer is worn to the extent that the doctor blade comes into contact with the surface of the convex portion of the mesh roll base material again.

In other words, the surface of the mesh roll convex portion wears out almost uniformly. Moreover, wear of the mesh roll convex surface due to long-term use will sequentially wear out the mesh roll base material convex surface and the hard layer end face. There is no significant change in the ratio between the hard layer end face and the hard layer end face having wear resistance.

(f) Examples FIG. 1 shows the manufacturing process of a mesh roll according to an example of the present invention, FIG. 2 shows a partially enlarged cross section of the mesh roll, FIG. 3 shows a partially enlarged surface of the mesh roll, and FIG. This will be explained with reference to FIG. 4, which shows a partially enlarged cross section.

1 is the mesh roll base material. The mesh roll base material 1 has a cylindrical shape and is made of copper, a copper alloy, or a material having similar ink affinity and hydrophobicity.

As shown in FIG. 1, a large number of mesh roll base material concave portions 2 are formed on the circumferential surface of the mesh roll base material 1, and in combination with the mesh roll base material convex portions 3, the circumferential surface of the mesh roll base material 1 is formed. The circumferential surface of the mesh roll base material 1 is coated with a material harder than the mesh roll base material 1, such as ceramics, to a thickness of 5 to 20 microns, or coated with a material harder than the mesh roll base material, such as titanium nitride, titanium carbide, hard chromium, or nickel composite. Plate the material to a thickness of 5 to 20 microns to form a hard layer. When the mesh roll base material 1 is made of soft copper, the surface of the mesh roll base material 1 may be underplated with a hard material such as nickel in order to increase the adhesion strength of the ceramic coating to the mesh roll base material 1.

If you want to further improve the ink affinity and hydrophobicity of the hard layer made of ceramics, titanium nitride, titanium carbide, hard chromium, nickel composite, etc. coated or plated on the surface of the concave portion 2 of the mesh roll base material, use the hard layer. 4
The surface is further coated or plated with 5μ to 20μ of copper or copper alloy.

Then, as shown in FIG. 2, the surface of the mesh roll is ground with a grindstone or the like until the mesh roll base material 1 is exposed at the center of the mesh roll convex portion 5. Then, as shown in FIG. 3, the mesh roll base material 1 is exposed at the center of the surface of the mesh roll convex part 5, but the hard layer 4 is exposed at the boundary part 7 between the mesh roll convex part 5 surface and the mesh roll concave part 6.
The end face of is exposed. When the hard layer 4 is coated or plated with copper, copper alloy, etc., the end face of the coating or plating layer 8 of copper, copper alloy, etc. is also exposed, as shown in FIG. The embodiment surface shown in FIG. 2 has a structure as partially enlarged in FIG. 3. That is, the mesh roll surface has many mesh roll recesses 6 engraved on the surface of the mesh roll base material 1 and whose surface is covered with a hard layer 4, or a hard layer 4 and a coating or plating layer 8, and a center part of the mesh roll base material 1. Consisting of the surface of the convex portion 3, the boundary portion 7 with the mesh roll concave portion 6 is the end surface of the hard layer 4 or the hard layer 4.
and a mesh roll convex portion 5 consisting of the end face of the coating or plating layer 8.

Therefore, a mesh roll having such a structure is attached to a lithographic printing machine and operated. Then, the ink stored in the ink pan is taken out by the fountain roll, and then supplied from the surface of the fountain roll to the mesh roll, and the ink on the surface of the mesh roll is scraped off by a doctor blade.

Therefore, ink remains in the cells, which are fine mesh roll recesses 6 formed on the mesh roll surface. At this time, the hard layer 4 of the mesh roll recess 6
If a coating or plating layer 8 made of copper, copper alloy, etc. is further formed thereon, the ink affinity is further improved. Furthermore, since the mesh roll base material 1 has hydrophobicity against excess water flowing back from the inked roll, deterioration of ink coverage on the mesh roll can be prevented.

On the other hand, the boundary part 7 between the mesh roll convex part 5 surface and the mesh roll concave part 6 is made of a material harder than the mesh roll base material 1 and is formed by the end surface of the hard layer 4 formed on the concave part of the mesh roll base material 1. .

Therefore, the wear resistance of the mesh roll projection 5 against pressure contact with the doctor blade is borne by the end face of the hard layer 4, and wear of the surface portion of the mesh roll projection 5 made of the mesh roll base material 1 is prevented.

Furthermore, in terms of the mesh roll convex portion 5, the mesh roll base material convex portion 3 having ink affinity and hydrophobicity and the hard layer 4 having wear resistance are formed approximately parallel to each other from the mesh roll axis direction to the circumferential direction. ing. Since the wear caused by the doctor blade occurs from the circumferential surface side, even if only the part of the mesh roll base material 1 on the surface of the mesh roll convexity wears out first, if the doctor blade wears out slightly, the doctor blade will move from the end surface of the hard layer 4. This prevents the surface portion of the convex portion of the mesh roll base material 1 from further abrading until the hard layer 4 wears down to the extent that the doctor blade comes into contact with the surface of the convex portion 3 of the mesh roll base material 1 again. . That is, the surface of the mesh roll convex portion 5 wears out almost uniformly. Moreover, the wear of the surface of the mesh roll convex part 5 due to long-term use,
Since the surface of the mesh roll base material convex part 3 and the end face of the hard layer 4 will be worn out sequentially, the surface of the base material convex part 3 having ink affinity and the hard layer having wear resistance occupying the surface of the mesh roll convex part 5. There is no major change in the ratio with the four end faces.

(g) Effects of the Invention Therefore, in this invention, concave portions and convex portions are formed on the peripheral surface, and the surface of the mesh roll base material made of an ink-friendly and hydrophobic material is coated with a material harder than the mesh roll base material. By forming a hard layer, and then removing the hard layer from the surface of the convex portion of the mesh roll base material until the surface of the convex portion of the mesh roll is exposed, the central part of the surface of the convex portion of the mesh roll has an ink affinity and hydrophobicity. The surface of the convex part of the mesh roll base material is made of a material having a hardness and has concave parts and convex parts on the circumferential surface, and the boundary part between the mesh roll concave part on the surface of the mesh roll convex part is made of a material that is harder than the mesh roll base material. At the same time, a mesh roll formed by the end face of the hard layer formed on the concave portion of the mesh roll base material is obtained. In this mesh roll, in terms of the mesh roll convex part, the mesh roll base material convex part having ink affinity and hydrophobicity and the hard layer having wear resistance are formed almost parallel from the mesh roll axis direction to the circumferential direction. has been done. Since wear caused by the doctor blade occurs from the peripheral surface side, the area ratio between the part with ink affinity and the part with wear resistance does not change significantly, and the wear resistance and ink resistance are maintained over a long period of time. Maintain affinity and hydrophobicity.

[Brief explanation of drawings]

Fig. 1 is a manufacturing process diagram of a mesh roll according to an embodiment of the present invention, Fig. 2 is a partially enlarged sectional view of the same mesh roll, Fig. 3 is a partially enlarged view of the same surface, and Fig. 4 is a partially enlarged sectional view of the same mesh roll.
The figure is a partially enlarged sectional view of another embodiment. 1...Mesh roll base material, 2...Mesh roll base material concavity, 3...Mesh roll base material convex part,
4...Hard layer, 5...Mesh roll convex portion, 6...
...Mesh roll recess, 7... Boundary part, 8... Coating or plating layer.

Claims (1)

[Scope of Claims] 1. In a mesh roll in which the base material is made of a material having ink affinity and hydrophobicity and has concave portions and convex portions on the circumferential surface, the center portion of the surface of the mesh roll convex portion is formed by the mesh roll base material. The boundary between the exposed surface of the mesh roll convex part and the mesh roll concave part is formed by the end face of a hard layer having higher wear resistance than the mesh roll base material provided to cover the concave surface of the mesh roll base material. Metsushi roll. 2. The mesh roll according to claim 1, wherein the mesh roll recesses further coat an ink-friendly and hydrophobic material on the hard layer. 3. The mesh roll according to claim 1 or 2, wherein the mesh roll base material is copper or a copper alloy. 4. The mesh roll according to claim 3, wherein the hard layer is made of ceramics. 5. The mesh roll according to claim 3, wherein the hard layer is a hard plated body made of titanium nitride. 6. The mesh roll according to claim 3, wherein the hard layer is a hard plating body made of titanium carbide. 7. The mesh roll according to claim 3, wherein the hard layer is a hard plated body made of hard chromium. 8. The mesh roll according to claim 3, wherein the hard layer is a hard plated body made of a nickel composite. 9. Claims 1, 2, and 3, in which the surface of the mesh roll base material is plated with a base plating.
The mesh roll according to item 4, item 5, item 6, item 7, or item 8. 10 A hard layer made of a material more abrasion resistant than the mesh roll base material is formed on the surface of the mesh roll base material, which has concave portions and convex portions formed on the circumferential surface and is made of an ink-friendly and hydrophobic material. A method for manufacturing a mesh roll, characterized in that a hard layer is removed from the surface of the convex portion of the mesh roll until the surface of the convex portion is exposed. 11. The method for manufacturing a mesh roll according to claim 10, wherein the hard layer surface of the mesh roll recess is further coated with an ink-friendly and hydrophobic material. 12. The mesh roll manufacturing method according to claim 10 or 11, wherein the mesh roll base material is copper or a copper alloy. 13. The method for manufacturing a mesh roll according to claim 12, wherein the hard layer is made of ceramics. 14. The method for manufacturing a mesh roll according to claim 12, wherein the hard layer is a hard plated body made of titanium nitride. 15. The method for manufacturing a mesh roll according to claim 12, wherein the hard layer is a hard plated body made of titanium carbide. 16. The method for manufacturing a mesh roll according to claim 12, wherein the hard layer is a hard plated body made of hard chromium. 17. The method for manufacturing a mesh roll according to claim 12, wherein the hard layer is a hard plated body made of a nickel composite. 18 The surface of the mesh roll base material is subjected to base plating.Claims 10, 11, 12, 13, 14, 15, and 16
A method for producing a mesh roll as described in Section 17.