KR100831075B1 - Post-processing method of a printing cylinder for reuse - Google Patents

Abstract

A post-processing method of a printing cylinder for reuse is provided to considerably reduce the amount of film development waste water by electroless plating a printing cylinder in the film development waste water for plating silver film. A post-processing method of a printing cylinder for reuse includes the steps of: peeling off an existing printing film from the printing cylinder(S10); pickling and cleaning the printing cylinder(S20); removing various organic matters from a surface of the printing cylinder under electrolyte in an electrolysis method(S30); performing a first plating for forming inner sheath of printing film by plating nickel on the surface of the printing cylinder in the electrolysis method(S40); forming a glass layer for forming a silver film on the inner sheath in an electroless plating method by submerging the printing cylinder under film development waste water(S50); and performing a second plating for forming an outer sheath on the printing cylinder by plating copper on the silver film(S60).

Description

Post-processing method of a printing cylinder for reuse

The present invention relates to a post-treatment method for reuse of a printing cylinder, and more particularly, to post-treatment of stripping, washing, degreasing, nickel plating, and copper plating on the cylinder to reuse the iron cylinder used for gravure printing. In carrying out the work sequentially, electroless plating by film developing wastewater followed by nickel plating reduces the consumption of film developing wastewater used for electroless plating, improves the working process, especially degreasing the cylinder. The present invention relates to a post-treatment method for reuse of a printing cylinder to prevent deterioration of print quality caused by defects.

In general, the types of printing can be classified according to the method of applying the printing pressure, and can be roughly classified into flat pressure, pressure pressure, and rotation type. It can be divided into, and in recent years has been proposed a printing technology that does not require a separate press plate, such as electronic printing.

Here, the concave plate printing is a printing method in which the portion to be printed, that is, the line portion is formed concave on the printing plate so that the ink remains only in the line portion, is divided into two types of engraving recess printing and gravure printing.

Among these, gravure printing is another word of photo recessed plate printing which makes a printing plate with a screen used for photolithography. In particular, the gravure printing method is briefly described as follows.

First, arrange the surface of the printing cylinder well, and apply a photoresist on it. Then, the film original is wound around the cylinder and light-splunged to develop a line like a film on the cylinder. Then, the caustic part is dissolved by the corrosive solution to make it concave. This etching process has recently been replaced by laser engraving. The ink is applied onto the printing cylinder in which the concave line portion is formed, and then the ink on the entire cylinder surface except for the line portion is removed. Then, the printing cylinder is turned to print the shape of the wire part as it is on the printing paper.

In this way, in order to reuse the printing cylinder used for printing once, it is necessary to peel off the printing coating film on the surface, and to plate the new printing coating film 20 as shown in FIG. 1, the process according to FIG. 2. The explanation is as follows.

First, in the peeling step (S110), the existing printing coating film 20 is peeled off manually by the surface of the printing cylinder 10 removed from the printing press.

Next, in the washing step (S120), the printing cylinder 10, from which the printing coating film 20 is removed, is hung on a workbench, and the surface is wiped clean with strong acid such as hydrochloric acid, and the operator directly develops the film using a sponge or the like thereon. Rub off the wastewater. As such, the reason why the film developing waste water is applied to the surface of the printing cylinder is to form a thin silver film 50 on the surface of the printing cylinder in which the silver component dissolved in the film developing waste water is made of iron to release the printing coating film 20 from the surface of the cylinder, thereby peeling off. To make it easier.

Subsequently, in the degreasing step (S130), the surface is washed by washing with the printing cylinder 10 soaked in pure water for 3 minutes and rotating.

Next, in the first plating step (S140), the surface of the printing cylinder 10 degreased with water is plated with nickel, which is the inner skin 30 of the printing film. The reason for this is that it is not possible to directly plate copper having excellent corrosiveness or cutting property on the surface of the printing cylinder made of iron.

Finally, in the second plating step (S150), the copper constituting the outer skin 40 of the printed coating film is plated on the nickel plated film, which is the inner skin 30.

However, when the electrolytic method is used in the degreasing step in forming a new printing coating film 20 on the surface of the printing cylinder 10 as described above, since the silver film 50 formed on the surface of the printing cylinder is removed by applying film developing waste water, Since the printing coating film 20 is not liberated from the printing cylinder surface, peeling of the printing coating film becomes difficult. Therefore, since the electrolytic method is not used in the degreasing step (S130), it is impossible to remove contaminants such as oxides, hydroxides, metal salts or fats and oils attached to the printing cylinder 10, and poor adhesion to the printing coating film 20. , Defects such as poor gloss, scratches such as pinholes or fine marks, or lifts occurred.

The present invention has been proposed to solve the problems of the conventional post-processing method for reuse of the printing cylinder as described above, the degreasing operation on the surface of the printing cylinder in reproducing the printing coating on the surface of the printing cylinder used for printing Thereafter, during the printing film formation, that is, before the first nickel plating is finished and before the second copper plating, the electrolytic plating is performed on the surface of the printing cylinder by electroless plating of the silver film using film developing wastewater, so that the electrolytic method can be used in the degreasing step. It completely eliminates various contaminants and prevents the deterioration of the print coating film due to the contaminants, while electroless plating the printing cylinder with film development waste water, which greatly reduces the amount of film development waste water and reduces production costs. The goal is to improve the environment and reduce productivity. There is an enemy.

Therefore, the present invention, in order to achieve the above object, the peeling step of peeling off the existing printing film of the printing cylinder used for printing; A washing step of washing the printed cylinder from which the existing printing coating film has been removed in the peeling step, followed by washing with water to cleanly wipe off; A degreasing step of putting the printing cylinder whose surface is washed in the washing step into an electrolyte solution and removing various organic substances remaining on the surface of the printing cylinder by an electrolytic method; A primary plating step of plating nickel on the surface of the printing cylinder degreased in the degreasing step to form an inner skin of the printed coating film by electrolysis; A glass layer forming step of forming a silver film on the endothelium by an electroless plating method of dipping and rotating the printing cylinder in which the endothelium is formed on the surface in a film development wastewater in the first plating step; And a secondary plating step of plating copper on the silver film formed in the glass layer forming step to form an outer surface of the printing coating film.

According to the post-treatment method for reuse of the printing cylinder of the present invention, a glass layer forming operation in which a silver film is plated on the endothelium of the printing coating from film development wastewater to facilitate peeling of the printing coating film is performed by electrolytic method. Since degreasing is performed after degreasing, it is possible to increase the degree of completeness of the degreasing operation, thereby reducing the defective rate of the print coating film, thereby significantly improving the quality.

In addition, as a work for coating a silver film on the endothelial of the printing cylinder, by placing the printing cylinder in the film developing waste water and electroless plating, it is possible to significantly reduce the amount of film developing waste water to reduce the cost. In addition, work productivity can be improved by improving the working environment and simplifying the work process.

Hereinafter, a post-processing method for reusing a printing cylinder according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The post-treatment method for reuse of the printing cylinder of the present invention, in particular, peels off the copper-plated printing film on the surface of the printing cylinder which has already been etched or engraved with the printing pattern so that the printing cylinder used in the rotary concave printing press can be repeatedly used. It is a job to be able to engrave another print pattern by coating a new print coating film, as shown in Figure 3 largely peeling step (S10), cleaning step (S20), degreasing step (S30), primary plating step (S40) ), The glass layer forming step (S50), and the secondary plating step (S60).

Here, first, the peeling step (S10) is a step of peeling off the existing print coating film 20 attached to the surface layer of the printing cylinder 10 already used for printing, as shown in FIG. 10) The printed coating film 20 attached to the surface is peeled off manually by peeling as shown. At this time, as described above, the outer skin of the printed coating film 20 is made of copper, which is easy to process, the copper wire part showing the print pattern by etching by corrosion or laser engraving, and the inner skin of the printing cylinder 10 is made of iron. It is made of nickel that allows the copper sheath which is hardly attached to the surface to adhere well to the surface of the printing cylinder 10.

Next, the washing step (S20) is a step of washing the surface of the printing cylinder 10 peeled off the printing coating film 20 in the above peeling step (S10), as shown in Figure 5, again the first pickling step (S21), the second pickling step (S22), the washing step (S23) is divided into three steps.

Here, in the first pickling step (S21), the surface of the printing cylinder 10 is wiped off with a strong acid solution of 6-8% hydrochloric acid, more preferably 8% hydrochloric acid. The second pickling step (S22) is a step of washing the surface of the first pickled printing cylinder 10 again with sulfuric acid, and using the sulfuric acid solution of 6 to 8%, more preferably 8%, like hydrochloric acid. Wipe the surface of (10). Finally, in the washing step (S23), the surface of the printing cylinder 10, which is subsequently pickled with hydrochloric acid and sulfuric acid solution, which is a strong acid, is wiped clean with water, and then moved to the next step of degreasing.

The degreasing step S30, which is a next process, is a step of depositing the printing cylinder 10 in the electrolyte solution 70 and removing various foreign substances remaining on the surface by an electrolytic method, as shown schematically in FIG. In the preceding washing step (S20), the various oils and fats remaining on the surface are not removed.

To this end, the electrolytic solution 70 is filled in the electrolytic cell 71, the printing cylinder 10 and the SUS plate 60 are deposited in the electrolytic solution 70, and then the positive electrode is placed on the printing cylinder 10, and the SUS plate ( 60), each of the cathodes is hooked and subjected to electrolysis. At this time, an alkaline aqueous solution is generally used as the electrolyte solution 70. After the degreasing is completed, the printing cylinder 10 is pickled and washed with water and then sent to the next process.

Next, in the first plating step (S40), as shown in Figure 7a, in the step (S30) to the surface of the printing cylinder 10 is completely removed until the oil remaining on the surface in the printing coating film ( 20 to form the endothelium 30. As described above, plating nickel with the inner shell 30 of the printed coating film 20 is performed through the copper cylinder constituting the outer shell 40 of the printed coating film 20 and the printing cylinder 10 made of iron. And to increase the adhesive force between the printing cylinder 10 and the printing cylinder 10.

On the other hand, nickel plating on the surface of the printing cylinder 10 is performed by an electrolytic method, as shown in Fig. 7b, for this purpose, the electrolyte solution 90 is filled in the plating bath 91 and the nickel plate in the electrolyte solution 90. After depositing the 80 and the printing cylinder 10, the nickel plate 80 may be connected to the positive electrode and the printing cylinder 10 by the negative electrode. At this time, the plating may be performed by using the strike nickel plating method so as to increase the adhesion and the covering power of the nickel plating film. The printing cylinder 10 in which nickel plating is completed as described above is pickled and washed with water and then moved to the next step.

Next, as shown in FIG. 8A, the glass layer forming step S50 is performed by plating the silver film 50 on the endothelium 30 formed on the surface of the printing cylinder 10 in the first plating step S40. In order to allow the copper shell 40 to be plated on the silver film 50 to be easily peeled off when it is peeled off for reuse, the printing cylinder 10 may have a film developing wastewater 100 as shown in FIG. 8B. ), The silver component in the film developing wastewater 100 is deposited on the endothelium 30, which is a nickel coating film, by electroless plating for about 3 minutes by rotating about 43%. In this way, the printing cylinder 10 in which the silver film 50 was formed on the inner shell 30 is sent to the next process after water washing.

Finally, in the secondary plating step (S60), as shown in FIG. 9A, copper is plated on the silver film 50 formed in the above glass layer forming step (S50) to form the shell 40 of the printed coating film 20. To this end, as shown in FIG. 9B, the electrolyte 120 is filled in the plating bath 111, and the printing cylinder 10 and the ball-shaped copper ingot 110 are deposited in the electrolyte 120. Then, the anode is placed on the ingot 110 and the cathode is placed on the printing cylinder 10, and when the power is supplied, electrolysis occurs, and copper is formed on the silver film 50 of the printing cylinder 10 as shown in FIG. 9A. An envelope 40 is formed.

In this way, a new printing coating film 20 is formed on the surface of the printing cylinder 10, and the printing cylinder 10 on which the printing coating film 20 is newly formed has a desired printing pattern on the printing coating film 20 by etching or engraving. New engravings can be reused for print jobs.

1 is a partial front cross-sectional view of a printing cylinder showing details of a coating film of a printing cylinder surface plated by a conventional plating method.

FIG. 2 is a block diagram schematically illustrating a plating process for forming the coating film shown in FIG. 1.

Figure 3 is a block diagram schematically showing a post-processing method for reuse of the printing cylinder according to the present invention.

4 is a partial front cross-sectional view of a printing cylinder schematically showing the peeling step of FIG. 3.

5 is a partial front cross-sectional view of the printing cylinder schematically showing the washing step of FIG.

6 is a partial front cross-sectional view of the printing cylinder schematically showing the degreasing step of FIG. 3.

FIG. 7A is a partial front cross-sectional view of a printing cylinder in which an endothelial is formed by the first plating step of FIG. 3; FIG.

7B is a view schematically showing the first plating step of FIG. 3.

8A is a partial front cross-sectional view of a printing cylinder in which a silver film is formed on the endothelium by the glass layer forming step of FIG. 3.

8B is a view schematically showing the glass layer forming step of FIG.

FIG. 9A is a partial front cross-sectional view of a printing cylinder in which an envelope is formed on a silver film by the secondary plating step of FIG. 3; FIG.

9B is a view schematically showing a secondary plating step of FIG. 3.

<Description of the symbols for the main parts of the drawings>

10 printing cylinder 20 printing film

30: inner 40: outer

50: silver film 60: plate made of SUS

70,90,120: electrolyte 80: nickel plate

100: film development wastewater 110: copper ingot

Claims (3)

A peeling step (S10) of peeling off the existing printing coating film 20 of the printing cylinder 10 used for printing; A washing step (S20) of washing the print cylinder 10 from which the existing printing coating film 20 is removed in the peeling step (S10) and washing them by washing with water after washing them; A degreasing step (S30) of inserting the printing cylinder 10 whose surface is washed in the washing step (S20) into an electrolyte solution 70 and removing various organic substances remaining on the surface of the printing cylinder 10 by an electrolytic method; A primary plating step (S40) of forming a endothelium 30 of the printed coating film 20 by plating nickel by electrolysis on the surface of the printing cylinder 10 degreased in the degreasing step (S30); In the first plating step (S40), the silver film 50 is formed on the endothelium 30 by an electroless plating method in which the printing cylinder 10 having the endothelium 30 formed on the surface is immersed in the film development wastewater 100 and rotated. Forming a glass layer forming step (S50); And A second plating step (S60) of forming a shell 40 of the printing coating film 20 by plating copper on the silver film 50 formed in the glass layer forming step (S50); Post-treatment method for reuse. According to claim 1, The washing step (S20), Primary pickling step (S21) for wiping the surface of the printing cylinder 10 with 6-8% hydrochloric acid; A second pickling step (S22) of wiping the surface of the printing cylinder 10 pickled in the first pickling step (S21) with 6-8% sulfuric acid; And Washing step (S23) to wipe off the surface of the printing cylinder (10) pickled in the second pickling step (S22) with water; Post-processing method for reuse of the printing cylinder, characterized in that consisting of. According to claim 1, In the glass layer forming step (S50), the nickel component of the endothelium 30 formed on the surface of the printing cylinder 10 and the silver component dissolved in the film development wastewater 100 react in the first plating step (S40). After-treatment method for reuse of the printing cylinder, characterized in that to deposit the silver film on the endothelium (30).

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