JP3124264B2 - Recycling method of printing plate material and printing machine - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the regeneration of a printing plate material.
The present invention relates to a method and a printing machine.

[0002]

2. Description of the Related Art As a general printing technique, digitization of a printing process is in progress. In this method, an image and a document are created by a personal computer, the image data is digitized by reading the image with a scanner or the like, and a printing plate is directly produced from the digital data.
This can save labor in the entire printing process and facilitate high-definition printing.

Conventionally, as a plate used for printing, a so-called PS plate having anodized aluminum as a hydrophilic non-image area and having a hydrophobic image area formed by curing a photosensitive resin on the surface thereof. Has been commonly used. In order to produce a printing plate using this PS plate, a plurality of steps are required, and it takes a long time to manufacture the plate, and the cost is increased. Therefore, the time required for the printing process is reduced, and the cost of printing is reduced. Is difficult to promote. In particular, printing of a small number of copies causes an increase in printing cost.

[0004] When printing of one picture is completed, the plate must be replaced and the next printing must be performed, and the plate has been thrown away. Further, in the PS plate, a plate cannot be directly produced from digital data, and the production of a printing plate is an obstacle in promoting digitization of a printing process.

[0005]

To solve the above-mentioned drawbacks of the PS plate, there has been proposed a method for facilitating the production of a printing plate corresponding to digitization of a printing process, and some of them have been commercialized. For example, a laser absorption layer such as carbon black is coated on a PET film, and a silicon resin layer is further coated thereon. An image is written with a laser beam to cause the laser absorption layer to generate heat, and the heat burns the silicon resin layer. A method of making a printing plate by skipping, or applying an oleophilic laser absorbing layer on an aluminum plate, and further burning off the hydrophilic layer applied thereon with a laser beam in the same manner as described above to obtain a printing plate. Methods, etc. are known. With such a method, it is possible to make a plate directly from digital data, but after printing one pattern, the next printing can not be done unless it is replaced with a new plate, so the plate used once is It is still discarded.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to reproduce a printing plate material that can be reused while being digitized in a printing process.
A method and a printing press.

[0007]

The present invention employs the following means in order to solve the above-mentioned problems. That is, the claims
The method for regenerating a printing plate material according to 1 is to directly or
Contains a titanium oxide photocatalyst formed through an intermediate layer
A coating layer, and the surface of the coating layer has at least one of
Is higher than the band gap energy of the titanium oxide photocatalyst
Irradiation of light with a wavelength with high energy makes it hydrophilic
And a hydrophobic part which is not irradiated with the light
In the method for regenerating a printing plate material having
After wiping the ink on the surface of the coat layer,
Higher than the band gap energy of the titanium oxide photocatalyst
Electrochemical treatment while irradiating light of wavelength with energy
By applying, the hydrophilic portion of the surface of the coat layer
It is characterized in that it is converted to hydrophobic and the printing plate material is recycled.
You.

[0008] The invention according to claim 2 is the invention according to claim 1.
The method for regenerating a printing plate material according to claim 1, wherein the electrochemical treatment
Is to immerse the surface of the coat layer in an electrolyte solution,
The process is characterized by applying a voltage to the base material.
According to a third aspect of the present invention, there is provided the printing method according to the second aspect.
A method for regenerating a printing plate material, wherein the electrolyte solution comprises NaS
It is characterized by being an O ₄ aqueous solution.

As described above , light irradiation and electrochemical treatment are combined on the surface of the coating layer in which at least a part thereof shows hydrophilicity and the remaining part shows hydrophobicity in the plane of the printing plate material. By applying, the entire surface of the coat layer can be converted to a hydrophobic surface. This conversion from hydrophilicity to hydrophobicity by light irradiation and electrochemical treatment is a new effect discovered by the present inventors. In addition, the following
The step of writing an image with light is referred to as plate production. Further , at least a part of the surface shows hydrophilicity, the remaining surface of the coating layer containing the titanium oxide photocatalyst showing hydrophobicity, the step of uniformly hydrophobicizing the entire surface,
Reproduction of the plate.

[0010] The invention according to claim 4 is a printing machine.
Formed on the surface of the substrate directly or via an intermediate layer,
Printing plates with a coating layer containing titanium oxide photocatalyst
A plate cylinder for winding and ink on the surface of the coating layer
A plate cleaning device for wiping off the coating layer,
Higher than the band gap energy of the titanium oxide photocatalyst
Electrochemical treatment while irradiating light of wavelength with energy
An electrochemical treatment apparatus for performing
In part, the band gap energy of titanium oxide photocatalyst
By irradiating light with wavelengths higher than
A writing device for exposing the hydrophilic portion.
It is characterized by that.

The invention according to claim 5 is the invention according to claim 4.
The printing machine according to claim 1, wherein the electrochemical processing device includes the plate cylinder.
A transparent electrode with a built-in ultraviolet light source that is approached with a gap,
An electrode connected to the transparent electrode with a built-in ultraviolet light source and the plate cylinder.
And a gap between the plate cylinder and the transparent electrode incorporating the ultraviolet light source.
Bei the an electrolyte solution supply nozzle for supplying an electrolyte solution
It is characterized by having. Further, according to claim 6,
A printing press according to claim 5, wherein the electrolyte solution is
The liquid is an aqueous NaSO ₄ solution.

[0012] According to this, it is possible to carry out continuous printing work without stopping the printing press and without interchanging the work of changing the printing plate material.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a cross-sectional view that also shows the surface of the printing plate material according to the present embodiment. In FIG. 1, a substrate 1 is made of aluminum.
It can be said that the use of aluminum as a base material of a printing plate is a general form, but the present invention is not limited to this.

An intermediate layer 2 is formed on the surface of the substrate 1. As the intermediate layer 2, for example, silica (Si
Silicon-based compounds such as O ₂ ), silicone resin and silicone rubber are used as the material. Among them,
As the silicone resin, silicone alkyd, silicone urethane, silicone epoxy, silicone acryl, silicone polyester and the like are used. The intermediate layer 2 is formed to ensure adhesion between the base material 1 and a coat layer 3 described later and to improve adhesion.

On the intermediate layer 2, a coat layer 3 containing a titanium oxide photocatalyst is formed. On the surface of the coat layer 3, a portion which shows hydrophobicity in an initial state at the time of plate production and shows hydrophilicity by irradiating light having a wavelength higher than the band gap energy of the titanium oxide photocatalyst, for example, ultraviolet light, appears. It is possible to do. This property is due to the property of the titanium oxide photocatalyst. This will be described later in detail.

The coating layer 3 is provided for the purpose of improving the above-mentioned property, that is, the conversion property from hydrophobicity to hydrophilicity, or for improving the strength of the coating layer 3 and the adhesion to the substrate 1. The following substances may be added. Examples of the substance include silica compounds such as silica, silica sol, organosilane, and silicon resin; metal oxides or hydroxides of zirconium and aluminum; and fluorine-based resins.

As the titanium oxide photocatalyst itself, there are a rutile type and an anatase type. In the present embodiment, both can be used, and a mixture of both may be used. Further, in order to increase the resolution of the image written on the plate surface to enable high-definition printing, and to consider forming the coating layer 3 having a small thickness, the particle diameter of the titanium oxide photocatalyst should be 0.1 μm or less. Is preferred.

As the titanium oxide photocatalyst to be used, those which are commercially available and which can be used in the present embodiment are specifically listed as ST-01, manufactured by Ishihara Sangyo.
ST-21, processed products ST-K01, ST-K03, water dispersion type STS-01, STS-02, STS-21, and SSP-25, SSP-20, SSP-M, CSB manufactured by Sakai Chemical Industry , C
SB-M, paint type LAC TI-01, AT manufactured by Teika
M-600, ST-157 and the like. However, it is a matter of course that the present invention can be applied to other than these titanium oxide photocatalysts.

The thickness of the coating layer 3 is 0.01 to 10 μm.
Is preferably within the range. This is because if the film thickness is too small, it is difficult to make full use of the above-mentioned properties, and if the film thickness is too large, the coat layer 3 is liable to crack, which causes a reduction in printing durability. This is because Since the crack is remarkably observed when the film thickness exceeds 20 μm, it is necessary to recognize 20 μm as the upper limit even if the above range is relaxed. Actually, it can be said that a general thickness is about 0.1 to 3 μm.

The coating layer 3 may be formed by appropriately selecting a sol coating method, an organic titanate method, an evaporation method, or the like. At this time, for example, if the coating method is adopted, in addition to the titanium oxide photocatalyst and the above-mentioned various substances for improving the strength of the coat layer 3 and the adhesion to the substrate 1, Solvent, crosslinking agent,
A surfactant or the like may be added. The coating liquid may be a room temperature drying type or a heat drying type, but the latter is more preferable. This is because increasing the strength of the coating layer 3 by heating is advantageous for improving the printing durability of the plate.

The operation and effects of the printing plate having the above-described configuration will be described below. First, in an initial state at the time of producing a printing plate material, the surface of the coat layer 3 is adjusted so that the contact angle of water is at least 50 ° or more as shown in FIG. By the way, it is more preferable that the contact angle is 80 ° or more. In this state, it is difficult for water to adhere to the surface of the coat layer 3 as can be seen from FIG.
That is, since the so-called water repellency is extremely high, it can be said that, conversely, a state in which the hydrophobic ink for printing easily adheres to the surface of the coat layer 3 has appeared.

The above-mentioned "initial state at the time of plate production"
May be considered as the start of the actual printing process. More specifically, for a given given image, it can be regarded as indicating a state when digitized data is already prepared and this is to be written on a plate material.

Next, the surface of the coat layer 3 in the above state is irradiated with ultraviolet rays as shown in FIG. The ultraviolet irradiation is performed in accordance with the digital data relating to the image described above so as to correspond to the data. In addition,
The term “ultraviolet light” as used herein means light having a wavelength higher than the band gap energy of the titanium oxide photocatalyst. More specifically, it is ultraviolet light including light having a wavelength of 400 nm or less.

As shown in FIG. 2, the surface of the coat layer 3 becomes hydrophilic as shown in FIG. This is due to the action of the titanium oxide photocatalyst. As a result, the area of the surface of the coat layer 3 irradiated with the ultraviolet rays has a water contact angle of 10 ° or less. This state has the opposite relationship to the state of the hydrophobic surface. That is, the water spreads on the surface of the coat layer 3 in the form of a film, but it becomes impossible for the hydrophobic ink for printing to adhere to this surface.

In addition, the method of causing the hydrophilic portion to appear based on the image is simple because the ultraviolet irradiation area may be simply controlled based on the digital data on the image. Is possible. In other words, unlike a conventional PS plate in which a hydrophobic portion is formed by reacting a photosensitive resin, the printing plate material according to the present embodiment can be easily adapted to digitization of a printing process.

Incidentally, the mechanism by which the titanium oxide photocatalyst is rendered hydrophobic by irradiation with ultraviolet light is generally described as follows. Fig. 3 when the titanium oxide photocatalyst is hydrophobic
As shown in (a), on the surface, oxygen O ²⁻ is titanium T
It is connected like a bridge between i ⁴⁺ . When this is irradiated with ultraviolet rays as shown in FIG. 3 (b), a bridge oxygen O ^2-
Becomes an O atom and separates from the surface, and the separated O
Two adjacent T by two electrons emitted from ^2-
i ⁴⁺ is reduced to Ti ³⁺ . Then, water molecules in the atmosphere are adsorbed on the oxygen-deficient portion in FIG. 3B, and a hydrophilic film is formed because a water molecule film is formed on the surface of the coat layer 3 (FIGS. 3C and 3D). ). In addition, the state covered with the hydroxyl group is a metastable state, a state in which ultraviolet rays are not irradiated,
For example, by leaving it in a dark place, it tends to gradually move to a stable hydrophobic surface.

When the above processing is completed, the coating layer 3
Apply hydrophobic ink for printing to the surface. Then, for example, a printing plate as shown in FIG. 4 is manufactured. In this figure, the shaded portion is the portion that has not been subjected to the hydrophilic treatment, that is, the hydrophobic portion,
Therefore, the image portion 4 to which the hydrophobic ink has adhered is shown, and the remaining white portion, that is, the hydrophilic portion, indicates the non-image portion 5 to which the hydrophobic ink was repelled and the hydrophobic ink was not adhered. ing. As the pattern emerges in this way, the surface of the coat layer 3 has a function as a printing plate. When applying the hydrophobic ink for printing to the surface of the coat layer 3, it goes without saying that the ink may be applied in a state where the ink and the dampening water are mixed. Thereafter, a normal printing process is executed and the process is terminated.

Next, the plate reproducing process will be described. First, after the ink, dampening water, paper powder, and the like attached to the surface of the coat layer 3 after printing are wiped off, the surface of the coat layer 3 is immersed in an aqueous electrolyte solution to apply a voltage to the substrate 1. At this time, ultraviolet rays may be applied to the surface of the coat layer 3 simultaneously with the application of the voltage. By performing such an electrochemical treatment, the entire surface of the coat layer 3 becomes hydrophobic,
It will return to the "initial state at the time of plate production" again. If this surface is again irradiated with ultraviolet rays, a new printing plate can be produced. In short, the printing plate of the present embodiment can be reused, in other words, can be repeatedly used.

As described above, the hydrophilic surface which is originally in a metastable state tends to gradually shift to a hydrophobic surface which is in a stable state. It is presumed that since the reaction of oxidizing Ti ³⁺ to convert it to Ti ⁴⁺ is accelerated, the time of hydrophobization is remarkably shortened.

FIG. 5 is a graph summarizing the above description. This is a graph in which the horizontal axis represents time (or operation) and the vertical axis represents the contact angle of water. With respect to the printing plate material in the present embodiment, the contact angle of the surface (that is, the hydrophobic or hydrophilic state) is obtained. Shows how the time changes with time or operation.

According to this, first, the initial surface of the coat layer 3 shows high hydrophobicity with a contact angle of water of 80 ° or more, which means “the initial state at the time of plate production” (point A in FIG. 5). It is. Thereafter, a printing plate was prepared by irradiating ultraviolet rays so that at least a part of the surface of the coating layer 3 was a hydrophilic non-image area and a non-irradiation area was a hydrophobic image area, and a straight line C in FIG. The printing is performed as shown in FIG. When the printing is completed, the surface of the coat layer 3 is cleaned of deposits and stains on the surface of the coat layer 3, and the surface of the coat layer 3 is again hydrophobic (point A ′ in FIG. 5) by the above-described electrochemical treatment. The printing plate material is reused.

As described above, the printing plate material of the present embodiment has the advantage that the cycle can be speeded up, in addition to the advantage that it can be reused. That is, according to the above, in either case of imparting hydrophobicity or imparting hydrophilicity, the operation for realizing them does not take much time. Therefore, the entire printing process can be completed very quickly.

In the following, more specific examples relating to the production and printing of a printing plate material confirmed by the present inventors will be described. First, the area is postcard size, thickness is 0.
A 3 mm aluminum substrate was prepared, and a primer LAC PR-01 manufactured by Sakai Chemical Industry was applied to the substrate and dried. The thickness of the primer after drying was 0.8 μm. In addition, this primer layer corresponds to the intermediate layer 2 in FIG. Then, apply the titanium oxide photocatalyst coating agent LAC TI-01 manufactured by Sakai Chemical Industry Co., Ltd. and dry it at 100 ° C.
A coat layer 3 containing a 0.7 μm titanium oxide photocatalyst was formed. The contact angle of water on the surface of the coating layer 3 was measured using a CA-W type contact angle meter manufactured by Kyowa Interface Chemical Co., Ltd. for this printing plate. The result was 84 °, indicating sufficient hydrophobicity as an image area. It was confirmed that it was in the initial state at the time of plate production.

Next, the substantially central portion of the printing plate, which is in the initial state at the time of plate preparation, is masked with a square black paper having a side of 2 cm, and the unmasked portion has an illuminance of 40 mW / c.
Immediately after irradiating ultraviolet rays of m ² for 1 minute, the contact angle of water was immediately measured with a CA-W type contact angle meter on the ultraviolet-irradiated portion, and the contact angle was 6 °, indicating sufficient hydrophilicity as a non-image area. Indicated. This plate material was transferred to SAN PRINTING MACHINES's SAN
OFF-SET 220E Installed on a DX-type card printing machine, using Toyo Ink's HYBECO B-Red MZ and Mitsubishi Heavy Industries fountain solution lysoferro 1% solution, print speed on eye vest paper 25
Printing was performed at 00 sheets / hour. As a result, no ink was attached to the plate surface of the portion irradiated with the ultraviolet rays, and a red image of a square having a side of 2 cm corresponding to the masked plate portion could be printed on the paper surface.

Next, an embodiment relating to reproduction of a printing plate material will be described. First, a printing plate material from which ink, fountain solution, paper powder, and the like adhering to the plate surface were wiped clean was immersed in an aqueous solution of NaSO ₄ (concentration: 0.1 M). Then, lead wires were connected to the base material of the plate, and while applying a voltage of +0.5 V to the printing plate material, ultraviolet rays having an illuminance of 40 mW / cm ² were irradiated for 5 minutes. afterwards,
Immediately after measuring the contact angle of water at several points on the entire plate surface with a CA-W type contact angle meter, the contact angle was 80 to 82 °, showing sufficient hydrophobicity as an image area. It was confirmed that the time was in the initial state.

The printing was performed by using a printing machine 10 as shown in FIG. That is, the printing machine 10
A plate cleaning device 12, an electrochemical processing device 13, a writing device 14,
An inking roller 15 and a blanket cylinder 16 are provided. The printing plate is wound around the plate cylinder 11 and installed.

In the printing machine 10, the step of regenerating the printing plate whose printing has been completed as described above is performed as follows. First, the plate cleaning device 12 is brought into contact with the plate cylinder 11, and the ink, fountain solution, paper dust and the like adhering to the plate surface are wiped clean. Then, the plate cleaning device 12
From the plate cylinder 11 and the transparent electrode 13 with a built- in ultraviolet light source.
The electrochemical treatment device 13 is brought close to the plate cylinder 11 until the gap between the plate cylinder 1 and the plate cylinder 11 becomes about 100 to 200 μm. As a result, the surface of the printing plate is subjected to a hydrophobic treatment as described above,
It is reproduced in the initial state at the time of plate production. At this time, plate cylinder 1
An electrolyte solution (aqueous solution of NaSO ₄ in the above-described embodiment) 132 is supplied to the surface of the printing plate material 1 above through an electrolyte solution supply nozzle 133. The UV light source
A power supply 134 is connected to the built-in transparent electrode 131 and the plate cylinder 11.

Thereafter, the electrochemical treatment device 13 is moved to the plate cylinder 11.
Then, based on the digital data of the image prepared in advance, the image is written on the surface of the reproduced coat layer 3 by the ultraviolet rays emitted from the writing device 14. When the above steps are completed, the inking roller 15 and the blanket cylinder 16 are brought into contact with the plate cylinder 11. Then, the paper 17 is transported so as to be in contact with the blanket cylinder 16 and in the direction of the arrow shown in FIG.
Continuous printing is performed.

As described above, the printing plate material according to the present embodiment can be changed from hydrophobic to hydrophilic by irradiating light having a wavelength having energy higher than the band gap energy, which is a known property of the titanium oxide catalyst. By combining the property of converting to hydrophilic and the property of converting from hydrophilic to hydrophobic by light irradiation and electrochemical treatment found by the present inventors, it is possible to reuse it and discard it after use. The amount of plate material can be significantly reduced. Therefore, the cost of the printing plate can be reduced significantly. In addition, since image data can be directly written on the plate material from digital data relating to the image by light (ultraviolet light), digitalization of the printing process has been performed, and a considerable amount of the digital printing has been made. It is possible to reduce time or cost.

Further, since it is possible to re-convert the printing plate material and regenerate the surface of the coating layer 3 on a printing machine,
It is also possible to speed up the printing operation. In the above example, since the image writing on the surface of the coat layer 3 is also performed on the printing press, a quicker operation can be performed.

[0041]

As described above, the printing according to the present invention is performed.
According to the method for regenerating a printing plate material, the hydrophilic portion can be converted to hydrophobic by performing light irradiation and electrochemical treatment on the surface of the coat layer. Therefore, the printing plate material can be reused or reused, and it is not necessary to dispose of the printing plate at the end of printing unlike the conventional printing plate material. Can be.

According to the printing press of the present invention , the printing plate can be produced and reproduced on the printing plate material on the printing press. Therefore, continuous printing can be performed without interchanging printing plates. Work can be performed, and therefore
This speeds up the printing operation.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view illustrating a configuration of a printing plate material. This figure also shows a state in which the surface of the coat layer shows hydrophobicity.

FIG. 2 is a cross-sectional view of a printing plate material showing a state in which the surface of a coat layer shows hydrophilicity.

FIG. 3 is an explanatory diagram for explaining conversion from hydrophobicity to hydrophilicity in a titanium oxide photocatalyst.

FIG. 4 is a perspective view showing an example of an image (image area) drawn on the surface of a coat layer and an example of the ground (non-image area).

FIG. 5 is a graph showing a state of conversion from hydrophobic to hydrophilic and a conversion from hydrophilic to hydrophobic on the surface of a coat layer along time (or operation).

FIG. 6 is an explanatory diagram illustrating an example of a configuration of a printing press.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Substrate 2 Intermediate layer 3 Coat layer 10 Printing machine 11 Plate cylinder 12 Plate cleaning device 13 Electrochemical treatment device 131 Transparent electrode with built-in ultraviolet light source 132 Electrolyte solution 133 Electrolyte solution supply nozzle 134 Power supply 14 Writing device 15 Inking roller 16 Blanket cylinder 17 paper

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-11-78272 (JP, A) JP-A-10-250027 (JP, A) JP-A-11-208134 (JP, A) JP-A-11- 123807 (JP, A) JP-A-11-123805 (JP, A) JP-A-11-123806 (JP, A) JP-A-11-123804 (JP, A) (58) Fields investigated (Int. ⁷ , DB name) B41N 1/14 B41C 1/10 B41F 7/02

Claims (6)

(57) [Claims] (1)  Directly or through an intermediate layer on the surface of the substrate
Formed, comprising a coating layer containing a titanium oxide photocatalyst,
At least a part of the surface of the coating layer is made of titanium oxide.
Has higher energy than the band gap energy of the catalyst
Part converted to hydrophilic by irradiating light of wavelength
And a hydrophobic portion which is not irradiated with the light.
In the method of recycling printing plate materials, After printing, the ink on the surface of the coat layer was wiped off.
Then, the band gap energy of the titanium oxide photocatalyst is determined.
While irradiating light of wavelength with higher energy
The hydrophilicity of the surface of the coat layer
Special feature is to convert the part to hydrophobic and regenerate the printing plate.
The method of recycling printing plate materials. (2)  The electrochemical treatment may be performed using the coating layer
The surface is immersed in the electrolyte solution and a voltage is applied to the substrate.
2. The seal according to claim 1, wherein the processing is an addition processing.
How to recycle the printing plate. (3)  The electrolyte solution is NaSO _Four In aqueous solution
3. The printing plate material according to claim 2, wherein
Raw method. (4)  Directly or through an intermediate layer on the surface of the substrate
With a coating layer containing a titanium oxide photocatalyst formed
A plate cylinder for winding the printing plate material, Plate cleaning for wiping ink on the surface of the coat layer
Equipment and A band gap of the titanium oxide photocatalyst is formed on the coat layer.
Do not irradiate light with wavelength higher than
An electrochemical treatment device for performing electrochemical treatment; At least a part of the surface of the coating layer has a titanium oxide
Wave with energy higher than the band gap energy of the medium
A book that exposes a hydrophilic part by irradiating long light
A writing device, A printing machine comprising: (5)  The electrochemical treatment device, Transparent built-in UV light source that comes close to the plate cylinder with a gap
Electrodes and An electrode connected to the transparent electrode with a built-in ultraviolet light source and the plate cylinder.
Source Electrolysis in the gap between the plate cylinder and the transparent electrode with built-in ultraviolet light source
An electrolyte solution supply nozzle for supplying an electrolyte solution, The printing according to claim 4, comprising:
Machine. 6.  The electrolyte solution is NaSO _Four In aqueous solution
6. The printing press according to claim 5, wherein: