阅读说明：本技术 等离子体电子束处理喷墨印刷装置 (Plasma electron beam treatment ink jet printing device ) 是由 中岛兴范 明濑拓哉 金城润 盐崎大悟 于 2019-09-12 设计创作，主要内容包括：本发明的目的在于得到一种装置,即使在使用不含有光聚合引发剂的油墨来进行印刷的情况下也可切实地固化,并且可进行不使被印刷基材表面发生改性的印刷,此外,由于在各种颜色的印刷后,通过大气压等离子体使得油墨的点的表面固化,因此即使各种颜色的油墨的点发生重叠,也不会发生渗透,从而可得到高质量的图像。作为解决方法,提供有一种具有喷墨印刷部及电子束照射部的喷墨印刷装置,所述喷墨印刷部具备相对于被印刷基材(S)的移动方向而在垂直方向上移动且相对于被印刷基材(S)表面而平行移动的喷墨用喷嘴(N)以及等离子体喷出口(21),所述电子束照射部相对于该喷墨印刷部而在被印刷基材(S)的移动方向下游侧。(The purpose of the present invention is to obtain a device that can reliably cure even when printing is performed using an ink that does not contain a photopolymerization initiator, that can perform printing without modifying the surface of a substrate to be printed, and that can obtain a high-quality image without bleeding even when the dots of the inks of the respective colors overlap each other because the surfaces of the dots of the inks are cured by atmospheric pressure plasma after printing of the respective colors. The inkjet printing apparatus includes an inkjet printing unit including an inkjet nozzle (N) that moves in a direction perpendicular to a moving direction of a substrate (S) to be printed and moves parallel to a surface of the substrate (S) to be printed, and a plasma ejection port (21), and an electron beam irradiation unit that is located downstream of the inkjet printing unit in the moving direction of the substrate (S) to be printed.)

1. An inkjet printing apparatus comprising:

an inkjet nozzle that moves in a direction perpendicular to a moving direction of a printing substrate and moves parallel to a surface of the printing substrate;

a plasma ejection port;

and an electron beam irradiation portion on a downstream side in a moving direction of the printing substrate with respect to the ink jet nozzle and the plasma discharge port.

2. The inkjet printing apparatus according to claim 1, characterized by having: an inkjet printing unit including an inkjet nozzle and a plasma ejection port that move in a direction perpendicular to a moving direction of a substrate to be printed and move parallel to a surface of the substrate to be printed; and an electron beam irradiation unit on a downstream side of the inkjet printing unit in a moving direction of the substrate to be printed.

3. The inkjet printing apparatus according to claim 2, wherein the head having 1 or more inkjet nozzles has a plasma ejection port.

4. The inkjet printing apparatus according to claim 2 or 3, wherein the inkjet printing apparatus is for multicolor printing, the head provided with the inkjet nozzles is a head for each inkjet nozzle for each color, and each head is a head provided with a plasma ejection port.

5. The inkjet printing apparatus according to any one of claims 2 to 4, wherein the opening of the plasma ejection port is not directed toward the surface of the substrate to be printed.

6. The inkjet printing apparatus according to any one of claims 2 to 5, wherein the opening of the plasma ejection port is directed in the moving direction of the printing substrate so that the plasma ejected from the plasma ejection port is directed in the moving direction of the printing substrate.

7. The inkjet printing apparatus according to any one of claims 2 to 6, wherein a grounded, negatively charged or positively charged substrate that is in contact with the non-printing surface side of the substrate to be printed and is disposed on the opposite side of the substrate to be printed as viewed from the plasma ejection port is disposed in the inkjet printing portion.

8. The inkjet printing apparatus according to any one of claims 2 to 7, comprising a cap covering the plasma ejection port.

9. The inkjet printing apparatus according to any one of claims 2 to 8, characterized by being provided with:

an ink jet printing unit including an ink jet nozzle that moves in a direction perpendicular to a moving direction of a substrate to be printed and moves parallel to a surface of the substrate to be printed; and a cover covering the ink-jet printing portion,

and a plasma jet orifice is provided in the housing,

the ink jet printing unit has an electron beam irradiation unit on the downstream side in the moving direction of the printing substrate.

10. The printing apparatus according to claim 9, wherein the opening of the plasma ejection port does not face the surface direction of the substrate to be printed.

11. The printing apparatus according to claim 10, wherein the opening portion of the plasma ejection port is directed in a moving direction of the printing substrate so that the plasma ejected from the plasma ejection port is directed in the moving direction of the printing substrate.

12. The inkjet printing apparatus according to any one of claims 2 to 11, wherein a grounded, negatively charged or positively charged substrate that is in contact with the non-printing surface side of the substrate to be printed and is disposed on the opposite side of the substrate to be printed as viewed from the plasma ejection port is disposed in the inkjet printing portion.

13. The inkjet printing device according to claim 1, characterized in that there are provided:

an ink jet printing unit including an ink jet nozzle that moves in a direction perpendicular to a moving direction of a substrate to be printed and moves parallel to a surface of the substrate to be printed;

and a plasma ejection port on a downstream side in a moving direction of the substrate to be printed with respect to the ink jet printing portion,

the plasma discharge port has an electron beam irradiation portion on a downstream side in a moving direction of the printing substrate.

14. The inkjet printing apparatus according to claim 13, wherein the inkjet printing apparatus has 1 or more combinations of the inkjet printing portion which discharges only 1 color ink and the plasma ejection port which is provided on a downstream side of the inkjet printing portion in a moving direction of the printing substrate, and when there are 2, the 2 or more combinations are arranged in parallel in the moving direction of the printing substrate.

15. The inkjet printing apparatus according to claim 13 or 14, wherein the opening of the plasma ejection port is not directed toward the surface of the substrate to be printed.

16. The inkjet printing apparatus according to any one of claims 13 to 15, wherein the opening of the plasma ejection port is directed in the moving direction of the printing substrate so that the plasma ejected from the plasma ejection port is directed in the moving direction of the printing substrate.

17. The inkjet printing apparatus according to any one of claims 13 to 16, wherein a grounded, negatively charged or positively charged substrate that is in contact with the non-printing surface side of the substrate to be printed and is in contact with the non-printing surface side of the substrate to be printed is disposed on the opposite side of the substrate to be printed as viewed from the plasma ejection port.

18. The inkjet printing apparatus according to any one of claims 13 to 17, comprising a cap covering the plasma ejection port.

19. An inkjet printing apparatus comprising: an inkjet nozzle provided with a line head type nozzle for printing 1 color or more of ink; and a plasma ejection port provided on the downstream side in the moving direction of the printing substrate for each nozzle of each color.

20. An inkjet printing apparatus comprising: an inkjet nozzle provided with a line head type nozzle for printing 1 color or more of ink; and a plasma ejection port on a downstream side in a moving direction of the printing substrate, as viewed from the line head type nozzle, for each of the nozzles for printing 1 color or more.

Technical Field

The present invention relates to an inkjet printing apparatus.

Background

As described in patent document 1, it is known that the ink on a printing substrate immediately after ink jet printing is irradiated with ultraviolet rays at a low oxygen concentration to form a polymer in the surface layer of the ink, and then irradiated with an electron beam (hereinafter also referred to as "EB") to form a polymer in the deep part, thereby curing the entire ink.

Further, as described in patent document 2, it is known that the ink on the printing substrate immediately after the ink jet printing is subjected to corona discharge treatment in an atmosphere having an oxygen concentration of less than 20000ppm to polymerize the surface layer of the ink, and then irradiated with an electron beam to polymerize the deep part, thereby curing the entire ink.

According to these curing units, although it is not necessary to add a photopolymerization initiator to the ink, an atmosphere having a low oxygen concentration is required.

According to the background art described above, although it is possible to reliably cure an energy ray-curable ink containing no photopolymerization initiator, it is necessary to form a region having a particularly low oxygen concentration. In particular, as in the invention described in patent document 1, irradiation with ultraviolet light is sometimes required, and thus it is practically difficult to cure the surface layer of an energy ray-curable ink containing no photopolymerization initiator.

In the case of corona discharge treatment, it is difficult to stably perform the treatment without narrowing the distance between the electrodes to several millimeters or so. In this case, depending on the thickness of the printing paper and the degree of vertical movement of the moving printing paper, the ink may contact the electrodes before the surface of the printed ink is cured, thereby disturbing the printing. Further, depending on the strength of the corona discharge treatment, there is a possibility that the surface of a substrate to be printed such as paper to which no ink is attached is modified.

Patent document

Patent document 1: japanese patent laid-open publication No. 2017-132895

Patent document 2: japanese patent No. 6353618

Disclosure of Invention

The invention aims to provide a device which can reliably cure ink without containing photopolymerization initiator and can perform printing without modifying the surface of a printing substrate.

The present invention has been made to solve the above problems, and as a result, the following inventions have been completed.

1. An inkjet printing apparatus comprising: an inkjet nozzle that moves in a direction perpendicular to a moving direction of a printing substrate and moves parallel to a surface of the printing substrate; a plasma ejection port; and an electron beam irradiation portion on a downstream side in a moving direction of the printing substrate with respect to the ink jet nozzle and the plasma discharge port.

2. The inkjet printing apparatus according to claim 1, comprising: an inkjet printing unit including an inkjet nozzle and a plasma ejection port that move in a direction perpendicular to a moving direction of a substrate to be printed and move parallel to a surface of the substrate to be printed; and an electron beam irradiation unit on a downstream side of the inkjet printing unit in a moving direction of the substrate to be printed.

3. The inkjet printing apparatus according to claim 2, wherein the head having 1 or more inkjet nozzles has a plasma ejection port.

4. The inkjet printing apparatus according to claim 2 or 3, wherein the inkjet printing apparatus is for multicolor printing, the head provided with the inkjet nozzles is a head for each inkjet nozzle of each color, and each head is a head provided with a plasma ejection port.

5. The inkjet printing apparatus according to any one of claims 2 to 4, wherein an opening of the plasma ejection port is not directed toward a surface of the substrate to be printed.

6. The inkjet printing apparatus according to any one of claims 2 to 5, wherein the opening of the plasma ejection port is directed in a direction in which the substrate to be printed moves, so that the plasma ejected from the plasma ejection port is directed in a direction in which the substrate to be printed moves.

7. The inkjet printing apparatus according to any one of claims 2 to 6, wherein a substrate that is in contact with the non-printing surface side of the substrate to be printed and is grounded, negatively charged or positively charged is disposed on the inkjet printing portion on the opposite side of the substrate to be printed as viewed from the plasma ejection port.

8. The inkjet printing apparatus according to any one of claims 2 to 7, characterized by having a cap covering the plasma ejection port.

9. The inkjet printing apparatus according to any one of claims 2 to 8, characterized by being provided with: an ink jet printing unit including an ink jet nozzle that moves in a direction perpendicular to a moving direction of a substrate to be printed and moves parallel to a surface of the substrate to be printed; and a cover which covers the ink jet printing unit, has a plasma jet port provided therein, and has an electron beam irradiation unit on a downstream side of the ink jet printing unit in a moving direction of the substrate to be printed.

10. The printing apparatus according to claim 9, wherein the opening of the plasma ejection port does not face the surface of the substrate to be printed.

11. The printing apparatus according to claim 10, wherein the opening of the plasma ejection port is directed in a direction in which the printing substrate moves, so that the plasma ejected from the plasma ejection port is directed in a direction in which the printing substrate moves.

12. The inkjet printing apparatus according to any one of claims 2 to 11, wherein a substrate that is in contact with the non-printing surface side of the substrate to be printed and is grounded, negatively charged or positively charged is disposed on the inkjet printing portion on the opposite side of the substrate to be printed as viewed from the plasma ejection port.

13. The inkjet printing apparatus according to 1, characterized in that:

an ink jet printing unit including an ink jet nozzle that moves in a direction perpendicular to a moving direction of a substrate to be printed and moves parallel to a surface of the substrate to be printed; and a plasma ejection port provided with an electron beam irradiation portion on a downstream side in a moving direction of the substrate to be printed with respect to the ink jet printing portion and on a downstream side in the moving direction of the substrate to be printed with respect to the plasma ejection port.

14. The inkjet printing apparatus according to claim 13, wherein the inkjet printing apparatus has 1 or more combinations of an inkjet printing portion that ejects only 1-color ink and a plasma ejection port provided on a downstream side of the inkjet printing portion in a moving direction of the printing substrate, and when there are 2, the 2 or more combinations are arranged in parallel in the moving direction of the printing substrate.

15. The inkjet printing apparatus according to 13 or 14, wherein the opening of the plasma ejection port does not face the surface direction of the substrate to be printed.

16. The inkjet printing apparatus according to any one of claims 13 to 15, wherein the opening of the plasma ejection port is directed in a direction in which the substrate to be printed moves, so that the plasma ejected from the plasma ejection port is directed in a direction in which the substrate to be printed moves.

17. The inkjet printing apparatus according to any one of claims 13 to 16, wherein a grounded, negatively charged or positively charged substrate is disposed on the opposite side of the substrate to be printed as viewed from the plasma ejection port, in contact with the non-printing surface side of the substrate to be printed.

18. The inkjet printing apparatus according to any one of claims 13 to 17, characterized by having a cap covering the plasma ejection port.

19. An inkjet printing apparatus comprising: an inkjet nozzle provided with a line head type nozzle for printing 1 color or more of ink; and a plasma ejection port provided on the downstream side in the moving direction of the printing substrate for each nozzle of each color.

20. An inkjet printing apparatus comprising: an inkjet nozzle provided with a line head type nozzle for printing 1 color or more of ink; and a plasma ejection port on a downstream side in a moving direction of the printing substrate, as viewed from the line head type nozzle, for each of the nozzles for printing 1 color or more.

According to the printing apparatus of the present invention, in the inkjet printing, at least the surface of the dot of the printed ink is cured by the atmospheric pressure plasma and then cured by irradiation with the Electron Beam (EB), whereby both the surface and the inner surface of the dot can be reliably cured.

Further, since the surface of the dots of the ink is cured by the atmospheric pressure plasma after the printing of each color, an object is to obtain an apparatus which does not cause bleeding even if the dots of the inks of each color are overlapped, and which can obtain a high-quality image.

Another object of the present invention is to provide a device that can actively cure ink by irradiating atmospheric pressure plasma, and that can prevent the trajectory of ink from being disturbed or prevent the shape of the printed surface of temporarily printed ink from being disturbed by air flow.

Drawings

Fig. 1 is a schematic diagram of a cross section of a remote atmospheric pressure plasma generation part.

FIG. 2-1 is a view showing a case where an ink jet nozzle and a plasma jet orifice are integrally provided.

Fig. 2-2 is a view showing a case where the ink jet nozzle and the plasma jet orifice are integrally provided.

Fig. 2 to 3 are views showing a case where the ink jet nozzle and the plasma jet orifice are integrally provided.

Fig. 2 to 4 are views showing a case where the ink jet nozzle and the plasma jet orifice are integrally provided.

FIG. 3-1 is a view showing a case where an ink jet nozzle and a plasma jet orifice are integrally provided.

Fig. 3-2 is a view in which an ink jet nozzle and a plasma jet orifice are integrally provided.

Fig. 3-3 are views showing the case where the ink jet nozzle and the plasma jet orifice are integrally provided.

Fig. 4 is a view in which the ink jet nozzle and the plasma jet orifice are provided separately.

Fig. 5 is a view showing only the plasma jet apparatus in which the ink jet nozzle and the plasma jet orifice are provided separately.

Description of the symbols

10-atmospheric pressure plasma generating means; 11-a pair of electrodes; 12-an insulator; 21-a plasma ejection port; 30-atmospheric pressure plasma processing apparatus for pretreatment; 31-an electrode for discharge; 32-an insulating material; 33-a plasma-ejection tube; 34-supporting rolls; 36-a cover; 40-downstream atmospheric plasma treatment means; 41-discharge electrode; 42-an insulating material; 43-plasma jet pipe; 44-support rolls; 45-cover; g-gas for generating atmospheric pressure plasma; p-atmospheric pressure plasma; s-a substrate to be printed; n-inkjet nozzle.

Detailed Description

The apparatus of the present invention will be described in detail below.

(ink jet printing part)

The ink jet printing unit of the present invention may be configured to include various known ink jet nozzles and a nozzle corresponding to a known ink jet method.

The ink jet printing section is a printing target substrate that is known to be capable of ink jet printing, such as coated paper, plain paper, various resin films, and laminated films having a metal layer or a metal compound layer, and is capable of performing printing using a known principle.

As such an ink jet printing unit, there may be mentioned an ink jet printing unit including an ink jet nozzle that moves in a direction perpendicular to a moving direction of a substrate to be printed and moves parallel to a surface of the substrate to be printed, or an ink jet nozzle that is fixed in a line head (line head) system.

In this case, the transported print substrate may be supported by a backup roller rotating at a constant speed, but the backup roller may not be provided.

The inkjet nozzle is constituted by 1 or more nozzles corresponding to 1 or more colors. The printing data is calculated to determine a precise printing portion (a position at which ink is ejected from each nozzle) for each color, and the timing at which ink of each color is ejected from each ink-jet nozzle so that printing can be performed at the printing position, and then ink-jet printing is performed based on the calculation result.

(plasma jet nozzle (when integrated with an ink jet nozzle))

The plasma jet orifice in the present invention is an orifice for irradiating atmospheric plasma to cure the surface of a dot of ink printed on a substrate to be printed by introducing atmospheric plasma formed by the atmospheric plasma generating apparatus 10 shown in fig. 1.

The atmospheric pressure plasma generation device 10 shown in fig. 1 uses a plasma processing device, and includes: a discharge space having a blow-out port; and a pair of electrodes 11 for discharge, which are opposed to each other at an interval of about 0.5 to 5.0mm in order to generate an electric field in the discharge space, and which have insulators 12. In this plasma processing apparatus, when the plasma generating gas G is supplied to the discharge space, the pressure in the discharge space is maintained at about atmospheric pressure, a voltage is applied to the pair of electrodes 11 for discharge, and a discharge is generated in the discharge space by exceeding a discharge start voltage, atmospheric pressure plasma P is generated in the discharge space.

In the case of the serial head (serial head) system, the plasma jet port for performing the atmospheric pressure plasma irradiation may be provided on the same head as the inkjet nozzle, or may be provided separately from the inkjet head so as to be moved arbitrarily, or the like. Further, a plasma jet orifice for jetting atmospheric pressure plasma may be integrally provided in the line head type ink jet nozzle.

In the case of the serial head type and the line head type, the inkjet nozzles and the plasma ejection ports of any 1 color are provided in the same head, and a plurality of such heads are provided for each color. Further, as shown in fig. 2-1, the respective ink-jet nozzles N and plasma jet ports 21 for the plurality of colors may be provided on the same head. For example, as shown in fig. 2-2, the plasma ejection port 21 may be provided for each color on the downstream side of the nozzle N for each color of CMYK.

Further, as shown in fig. 2 to 3, a plasma jet port 21 may be provided downstream of these ink jet nozzles so that after printing by a plurality of ink jet nozzles of CMYK, the processing may be concentrated by atmospheric pressure plasma P.

In addition, the serial head system and the line head system may be provided with the arrangements shown in fig. 2-2 and 2-3.

As seen obliquely from below in fig. 2 to 4, the line head system basically has a structure in which a plurality of ink jet nozzles N and plasma jet ports 21 are provided above a print target substrate S so as to cross the width direction of the print target substrate.

Further, a cover C covering the plasma jet port 21 may be provided, and the plasma jet port may be provided toward the cover so as to increase the concentration of atmospheric pressure plasma in the atmosphere inside the cover.

The atmospheric pressure plasma used in the present invention includes all gases in which a raw material gas is modified by plasmatization.

The plasma jet orifice itself is provided between or in the vicinity of the nozzles of the respective colors for ink jet printing, and when moving integrally with these nozzles, the jet orifice for irradiating the ink immediately after printing with the atmospheric pressure plasma can be an orifice for irradiating the ink with the atmospheric pressure plasma with a diameter preferably in the range of 1 to 10mm, more preferably in the range of 1 to 5 mm.

The inkjet nozzle during printing can also reciprocate relative to the surface of the substrate to be printed. In this case, nozzles for ejecting atmospheric pressure plasma may be provided between the nozzles of the respective colors of the inkjet nozzles for printing of the plurality of colors. Further, not only the nozzles of the respective colors, but also 1 nozzle for ejecting the atmospheric pressure plasma may be provided on each of the outer sides (outer sides in the width direction of the printing substrate) of the nozzles located at both ends of the arranged nozzles of the respective colors.

Similarly, when the inkjet nozzles are provided in the line head system, a plasma ejection port may be provided between the nozzles of the respective colors of the inkjet nozzles for printing of the plurality of colors, or after printing with the inks of the plurality of colors, so that the atmospheric pressure plasma can be ejected to the inks of the plurality of colors.

Fig. 3-1 is a cross-sectional view of the device of fig. 2-1 viewed in the transverse direction. In fig. 3-1, the plasma jet port 21 is provided to jet atmospheric pressure plasma in the same direction as the ink jet nozzle N. Even with the apparatus having such a structure, sufficient printing and curing can be achieved. Further, a cap C covering the plasma ejection port 21 may be provided.

However, it is also necessary to prevent the ink cured in the opening of the ink jet nozzle N from being deposited by the atmospheric pressure plasma ejected from the plasma ejection port 21 for ejecting the atmospheric pressure plasma. Therefore, it is necessary to eject the atmospheric pressure plasma from the plasma ejection port 21 for the atmospheric pressure plasma, which is provided as a or B described below, so that the atmospheric pressure plasma ejected from the plasma ejection port 21 ejecting the atmospheric pressure plasma does not contact the ink jet nozzle N while colliding with the uncured ink adhering to the surface of the substrate S to be printed.

A. As shown in fig. 3-2, the plasma ejection port 21 for ejecting the atmospheric pressure plasma is disposed on the upstream side in the moving direction of the printing substrate S with respect to the ink jet nozzle N, and is disposed at a position on the same level as or closer to the ink jet nozzle N with respect to the printing substrate S so as to eject the atmospheric pressure plasma in the same direction as the moving direction of the printing substrate. Further, since the ink jet nozzle N is moved immediately after printing, the plasma ejection port 21 for ejecting the atmospheric pressure plasma can be provided in a direction for ejecting the atmospheric pressure plasma to the ink which is in a positional relationship not opposed to the ink jet nozzle N.

B. As shown in fig. 3 to 3, the plasma ejection port 21 for ejecting the atmospheric pressure plasma is disposed on the downstream side in the moving direction of the printing substrate S with respect to the ink jet nozzle N, and is disposed at a position on the same level as or closer to the ink jet nozzle N with respect to the printing substrate S so as to eject the atmospheric pressure plasma in the direction opposite to the moving direction of the printing substrate S. Further, since the ink jet nozzle N is moved immediately after printing, the plasma ejection port 21 for ejecting the atmospheric pressure plasma can be provided in the direction for ejecting the atmospheric pressure plasma to the ink which is in a positional relationship not opposed to the ink jet nozzle N.

In the case of using the apparatus shown in fig. 3-2 and 3-3, the atmospheric pressure plasma can be irradiated immediately after the ink of an arbitrary color is attached to the substrate to be printed, in response to the movement of the ink jet nozzle N and the discharge of the ink of an arbitrary color, and the atmospheric pressure plasma does not come into contact with the ink jet nozzle N, so that the ink cured in the ink jet nozzle N does not adhere to or accumulate.

In the case of fig. 3-2 and 3-3, the atmospheric pressure plasma may be made to collide with the inks of the respective colors immediately after the ejection at a timing before the ejection of the ink of the next color.

As a result, even if the ink of the next color is ejected, the color mixture with the ink of the previous color at least the surface of which is cured to some extent by the atmospheric pressure plasma does not occur, and the printed outline can be made clearer.

As shown in fig. 2-1 to 2-4, as the ink jet printing apparatus, a full-color ink jet nozzle N for printing may be provided on a print head, and a plurality of plasma ejection ports 21 corresponding to respective colors may be provided on the same print head, or a plurality of partial color ink nozzles of 3 colors, 4 colors, and the like may be provided on 1 head, and a plasma ejection port 21 may be provided for curing the ink of these colors, and further 1 or more heads may be provided, and a head having another ink color may be provided, so that full-color ink ejection may be performed as a whole, and the surface of each ink may be cured by plasma.

(plasma jet nozzle (when provided separately from the ink jet nozzle))

In the present invention, the plasma ejection port may be provided separately from the head of the inkjet nozzle. At this time, 1 or more heads for printing only 1 color are arranged along the moving direction of the printing target substrate. Further, 1 or more individual plasma jet apparatuses are provided on the downstream side of each head so as to correspond to each head.

In fig. 4, the inkjet nozzle N is a nozzle for ejecting ink of 1 color. In the case of performing multicolor printing, the ink jet nozzles N of the desired number of colors are provided downstream of the arrow indicating the direction of movement of the printing substrate S. Fig. 4 shows only 1 color, and ink jet nozzles N are provided at positions facing the backup roller R provided as needed.

After the ink of the 1 st color is printed by the ink jet nozzles N, the printed substrate is transported to the same downstream atmospheric pressure plasma processing apparatus 40 as the plasma processing apparatus shown in fig. 1. Here, a plasma processing apparatus is used which includes a discharge space into which an atmospheric pressure plasma generating gas G is introduced, which has an outlet and is formed of an insulating material 42, and discharge electrodes 41 which are opposed to each other at an interval of about 0.5 to 5.0mm in order to generate an electric field in the discharge space. In this plasma processing apparatus, when the pressure in the discharge space is maintained at about atmospheric pressure while supplying the plasma generation gas G to the discharge space, and a voltage is applied to the discharge electrode 41, and further, a discharge is generated in the discharge space by exceeding a discharge start voltage, atmospheric pressure plasma P is generated in the discharge space.

Then, the generated atmospheric pressure plasma P is irradiated on the ink on the printing substrate through the plasma discharge pipe 43. At this time, the cover 45 may be provided so as to increase the concentration of the atmospheric pressure plasma inside the cover 45.

In the case of inkjet jet printing in the line head system, a plasma processing device may be provided on the downstream side thereof for each head for printing 1 color ink of the line head system, and further, a plasma processing device may be provided on the downstream side thereof for each head for printing 2 colors or more of ink. Further, after printing of the full color ink, a plasma processing device may be provided downstream thereof so as to eject atmospheric pressure plasma to the ink of all colors.

Further, a backup roller 44 may be provided on the opposite side of the printing substrate S from the plasma discharge pipe 43, and the backup roller may be grounded or an electric charge opposite to the atmospheric pressure plasma may be applied so that the atmospheric pressure plasma of high concentration exists on the surface of the printing substrate S.

Fig. 5 shows an apparatus for treating ink on a printing substrate 104 on a roll 105 by ejecting atmospheric pressure plasma through an atmospheric pressure plasma introducing pipe 103 and a nozzle 102 provided at the tip end thereof, and the plasma discharge pipe 43 is fixed and a slit-shaped nozzle opening portion is formed so that the entire width of the moving printing substrate can be treated by adopting the configuration of the apparatus.

Alternatively, the atmospheric pressure plasma may be irradiated with the ink printed by the ink jet nozzle N as an important object by delaying the movement of the ink jet nozzle N in the width direction of the print target substrate by the amount of time for which the print target substrate moves from the ink jet nozzle N to the downstream atmospheric pressure plasma processing apparatus 40 and moving the plasma discharge pipe 43 in the same manner as the ink jet nozzle N.

Although not shown, the ink jet ink printing using the ink jet nozzle N shown in fig. 4 is configured such that the surface curing of the ink after printing by the downstream atmospheric pressure plasma processing apparatus 40 is performed as 1 unit, and the same number of units as the number of colors necessary for the entire printing is provided.

In fig. 4, a plasma treatment apparatus 30 for pretreatment may be provided upstream of the inkjet nozzle N. The surface of the substrate to be printed before printing can be subjected to plasma treatment by the atmospheric pressure plasma treatment apparatus 30 for pretreatment. As a result of the treatment performed by the atmospheric pressure plasma treatment apparatus 30 for pretreatment, plasma species remain on the surface of the printing substrate during printing. Therefore, when the inkjet printing is performed by the inkjet nozzle N, the charged groups formed by the plasma treatment remain, and therefore, the inside of the printing portion can be slightly cured after the printing.

The basic configuration of the pretreatment atmospheric pressure plasma processing apparatus 30 is common to the downstream atmospheric pressure plasma processing apparatus 40, and a plasma processing apparatus including a discharge space into which an atmospheric pressure plasma generating gas G is introduced, which has an outlet and is formed of an insulating material 32, and discharge electrodes 31 opposed to each other at an interval of about 0.5 to 5.0mm for generating an electric field in the discharge space can be used.

In this plasma processing apparatus, when the pressure in the discharge space is maintained at about atmospheric pressure while supplying the plasma generation gas G to the discharge space, and a voltage is applied to the discharge electrode 31, and further, a discharge is generated in the discharge space by exceeding a discharge start voltage, atmospheric pressure plasma P is generated in the discharge space.

Then, the generated atmospheric pressure plasma P is irradiated on the ink on the printing substrate through the plasma discharge pipe 33. At this time, the shield 36 may be provided in order to increase the concentration of the atmospheric pressure plasma inside the shield 36.

Further, a backup roller 34 may be provided on the opposite side of the substrate S to be printed with respect to the plasma discharge pipe 33, and the backup roller may be grounded or an electric charge opposite to the atmospheric pressure plasma may be applied so that the atmospheric pressure plasma of high concentration exists on the surface of the substrate S to be printed.

(arrangement of means for earthing or charging)

A support roller or a rod for supporting the non-printing surface of the substrate to be printed may be provided at a position facing the inkjet nozzle and/or the nozzle for ejecting the atmospheric pressure plasma with the substrate to be printed interposed therebetween. Further, by grounding the support roller or rod or previously charging the plasma particles with a polarity opposite to the polarity, the atmospheric pressure plasma can be attracted so that the plasma ejected from the plasma ejection port is redirected to collide with the ink on the substrate to be printed, and electric charges for increasing the plasma density on the surface of the ink on the substrate to be printed can be applied.

Further, a small mask may be provided so as to surround the plasma ejection port and the ink before curing on the printing substrate, and plasma may be ejected into the mask so that the plasma existing in the mask moves toward the printing substrate.

In this way, since the gas flow containing the plasma is caused to collide with the ink before curing on the printing substrate without directly colliding with the ink, the possibility of spreading of 1 dot or 1 outline of the ink can be reduced.

Further, by providing such a support roller or rod, the density of atmospheric pressure plasma in the ink jet nozzle and the atmosphere around the nozzle can be reduced at the same time. As a result, the ink cured on the inkjet nozzle can be prevented from adhering and accumulating.

(atmospheric pressure plasma generating apparatus)

As the plasma generating device for supplying plasma to the plasma ejecting port, a remote atmospheric pressure plasma generating device can be used. In the plasma, when a high voltage is applied between electrodes in a state of a high energy gas, discharge is generated. Atmospheric pressure plasma is plasma generated under atmospheric pressure, and is generally used for the purpose of hydrophilizing the surface of a substance or the like.

As such a device, for example, a plasma processing device as shown in fig. 1 can be used which includes a discharge space having a blow-out port, and discharge electrodes opposed to each other at an interval of about 0.5 to 5.0mm for generating an electric field in the discharge space. In this plasma processing apparatus, when the discharge space is supplied with the plasma generating gas G while the pressure in the discharge space is maintained at about atmospheric pressure, and a voltage is applied to the discharge electrode 31, and further, a discharge is generated in the discharge space by exceeding a discharge start voltage, plasma is generated in the discharge space.

The plasma treatment can be performed by blowing a gas flow P containing the plasma from the blowing port and jetting the gas flow P onto the molded body. Examples of such a plasma generating apparatus include plasma processing apparatuses available from RT series and APT series manufactured by water-logging chemical industries, and suitable plasma processing apparatuses available from dakuku corporation, and plasma generating apparatuses used in apparatuses described in japanese patent application laid-open nos. 2004-207145, 11-260597, and 3-219082.

Further, as a gas used for the atmospheric pressure plasma, air, oxygen, nitrogen, or the like can be used.

The distance between the electrodes is also dependent on the voltage applied, but a high-frequency, pulse wave, microwave, or other electric field may be applied to the electrodes to generate plasma.

Among them, the pulse wave is preferably applied in consideration that the time required for the rise and fall of the electric field (rise and fall means that the voltage continuously increases or decreases) should be short. In this case, the time required for the rise and fall of the electric field is preferably 10 μ s or less, and more preferably 50ns to 5 μ s.

The electric field strength generated between the electrodes in the plasma generator may be 1kV/cm or more, preferably 20kV/cm or more and/or 1000kV/cm or less, preferably 300kV/cm or less.

When an electric field is applied by a pulse wave, the frequency is preferably 0.5kHz or more, and may be about 10 to 20MHz, or about 50 to 150 MHz.

The electric power applied between the electrodes may be 40W/cm or less, preferably 30W/cm or less.

In order to obtain a stable plasma discharge, it is preferable that the electrode is not in direct contact with the gas. Therefore, it is preferable that the surface of the electrode is covered with an insulating film or the like by an arbitrary known method. Examples of such an insulating coating include vitreous materials such as quartz and alumina, and ceramic materials. In some cases, a dielectric having a permittivity of 2000 or less, such as barium titanate, silicon oxide, aluminum nitride, silicon nitride, or silicon carbide, may be used.

Such a remote atmospheric pressure plasma irradiation curing section is constituted by, for example, a unit constituted by an atmospheric pressure plasma generating section, a plasma irradiation nozzle, and the like, and a power supply section in the above-described known apparatus. In this apparatus, in order to uniformly process the object substrate in the width direction, a plurality of portions to which the atmospheric pressure plasma is ejected may be arranged in the width direction, or the nozzle may be shaped like a slit.

Fig. 1 is a schematic cross-sectional view of such a remote atmospheric pressure plasma generating unit 1. In fig. 1, the atmospheric pressure plasma generating gas G passes between a pair of electrodes 11, one of which is grounded and has a layer such as an insulator 12 formed on the surface thereof, and when the gas G passes through the electrodes, the gas G is plasmatized by a voltage applied between the electrodes. Although the gas flow containing the atmospheric pressure plasma P is shown in fig. 1 as directly colliding with the surface of the printed substrate S to be printed, the atmospheric pressure plasma may not be directly collided.

Further, the atmospheric pressure plasma ejected from the nozzle for ejecting the atmospheric pressure plasma may be irradiated in advance on the upstream side of the ink jet nozzle to the printing surface of the substrate to be printed supplied to the ink jet nozzle. In this case, the atmospheric pressure plasma can be left on the printing surface of the printing substrate for a short time, and the inkjet printing can be performed in the left state. As a result, the ink adhering to the surface of the substrate to be printed can be slightly cured at the adhering portion.

(Electron Beam irradiation part)

The electron beam irradiation part in the present invention functions to completely cure the entire inside and outside of the ink obtained by curing the surface of the ink of each color by irradiation of atmospheric pressure plasma at the same time as or after the ink jet printing is performed using the plasma jet port provided integrally with the ink jet nozzle or using the plasma jet port provided separately from the ink jet nozzle, upstream of the electron beam irradiation part. In this manner, by using the electron beam irradiation part and simultaneously spraying the atmospheric pressure plasma, the inkjet ink composition can be made to contain no polymerization initiator, no auxiliary agent therefor, or the like. Moreover, the borders of the adjacent colors are not penetrated, so that an image with high contrast can be formed.

As the electron beam generating device constituting the electron beam irradiating section, a known device can be used. Furthermore, an introducing/irradiating device for irradiating the ink on the printing substrate with the electron beam generated by the electron beam generating device may be provided.

In addition, as an atmosphere when the electron beam is irradiated, an atmosphere of an inert gas such as nitrogen gas or a rare gas is preferably formed in order to smoothly perform curing.

Further, it is necessary to pass the substrate to be printed through the electron beam irradiation section so that the electron beam generated by the electron beam generating device is uniformly irradiated to the ink on the surface of the substrate to be printed. In the electron beam irradiation unit, for example, an electron beam may be irradiated in a curtain shape on the printing surface of the substrate to be printed. In addition, although the acceleration voltage of the electron beam may be changed in time according to the specific gravity and the film thickness of the ink, it is preferably 20kV to 300 kV. The irradiation amount of the electron beam is preferably in the range of 0.1 to 20 Mrad.

By simultaneously irradiating the electron beam irradiation unit with atmospheric pressure plasma, an energy ray-curable inkjet printing ink can be cured. Further, it is not necessary to previously mix a polymerization initiator, a curing agent, a polymerization initiation assistant, and the like in the ink. Even if these components are not incorporated in the ink, the ink can be sufficiently cured.

Examples

A polyethylene terephthalate film having a width of 21cm was fed to a line inkjet printing apparatus at a printing speed of 12m/min, printed using the compositions of examples and comparative examples shown in table 1 below, and cured under the conditions shown in the respective examples and comparative examples. The amounts of the components in the table are by mass.

Further, the intercolor plasma curing gas species N2 is an atmospheric pressure plasma which is irradiated with a gas species of nitrogen gas at a gas flow rate of 30L/min from a slit having a width of 300mm every time printing is performed with inkjet printing inks of respective colors. EB irradiation with 30kGray90kV is a representation of electron beams generated at a voltage of 90kV by irradiating the ink with 30kGray in an atmosphere purified by nitrogen gas after full color printing.

(Intercolor penetration)

O: visually, no bleeding occurred between the adjacent different colors, and the outline was clear.

X: it was visually confirmed that bleeding occurred between adjacent different colors.

(film coating erasure)

O: the coating film was not wiped off 10 times with a cotton swab.

X: the coating film was wiped off when the coating film was rubbed 10 times with a cotton swab.

(tackiness)

O: the surface of the coating film was touched with fingers and the state of the surface of the coating film was visually observed without stickiness.

X: the surface of the coating film was touched with fingers and the state of the surface was visually observed to have tackiness.

(Table 1)

According to the above-described embodiment, the apparatus of the present invention can realize printing without causing color bleed, without causing the coating film to be erased, and without causing stickiness at the point where different colors come into contact with each other.

In contrast, in comparative examples 1 to 3 and 5 in which no intercolor plasma curing was performed, permeation occurred between colors in different colors in contact with each other. In addition, according to comparative example 4 in which EB irradiation was not performed, printing with removable coating and stickiness was formed.