JP2016005898A - Cylinder type screen printer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cylinder type screen printer which hardly generates distortion in a printing image.SOLUTION: A cylinder type screen printer comprises: a printing cylinder 10 disposed in a horizontal direction on a base frame 1 disposed horizontally; a screen printing plate 20 disposed above the printing cylinder 10 for holding a base material film 40 between itself and the printing cylinder 10; and a squeegee 35 for pressing the screen printing plate 20. The screen printing plate 20 is prevented from moving horizontally. The printing cylinder 10 is supported in a rotatable and horizontally movable manner. The squeegee 35 is made horizontally movable in synchronization with the printing cylinder 10.

Description

  The present invention relates to a cylinder-type screen printing machine that performs printing by sandwiching a printing material between a printing cylinder and a screen plate.

  2. Description of the Related Art Conventionally, a cylinder type screen printing machine that performs printing by sandwiching a printing material between a printing cylinder and a screen plate is known. As shown in FIG. 6, the cylinder type screen printing machine has a cylindrical printing cylinder 90 that rotates around a cylinder shaft 90 a and a substrate 95 sandwiched between the printing cylinders 90 and is positioned above the printing cylinder 90. A screen plate 91 is provided, and a squeegee 92 is provided on the screen plate 91. In this cylinder type screen printing machine, a substrate 95 is fed between a printing cylinder 90 and a screen plate 91 from a feeder (not shown), the printing cylinder 90 rotates in the direction of the arrow, and the screen plate 91 is synchronized with the printing cylinder 90. Then, when moving in the direction of the arrow, a print pattern is printed on the substrate 95 through the squeegee 92.

  According to this cylinder type screen printing machine, the printing material 95 is sandwiched between the printing cylinder 90 and the screen plate 91 and wound around the outer peripheral surface of the printing cylinder 90. As described above, it is not necessary to consider the clearance between the printing material and the screen plate or the separation of the plate. Therefore, in the cylinder type screen printing machine, compared to the flat type screen printing machine, the print image is less likely to be stretched, blurred, or blurred. As an example of such a cylinder type screen printing machine, the one described in Patent Document 1 is known.

Japanese Unexamined Patent Publication No. 2014-30961

  However, in the above-described conventional cylinder type screen printing machine, the screen plate moves horizontally during printing. Therefore, when the screen plate shakes, the printed image is distorted.

  The present invention has been made in view of such conventional problems, and provides a cylinder-type screen printing machine in which a printed image is hardly distorted.

  In order to solve the above problems, the cylinder-type screen printing machine according to claim 1 is characterized in that a printing cylinder arranged in a horizontal direction on a horizontally arranged base frame, and a printing cylinder arranged above the printing cylinder. A cylinder-type screen printing machine provided with a screen plate that sandwiches a substrate to be printed with the printing cylinder and a squeegee that presses the screen plate. The cylinder is supported so as to be rotatable and horizontally movable, and the squeegee is horizontally movable in synchronization with the printing cylinder.

  The cylinder-type screen printing machine according to claim 2 is characterized in that a pedestal that is supported by the base frame so as to be horizontally movable, the printing cylinder is rotatably supported, and a pedestal driving unit that horizontally moves the pedestal, An elevating frame supported by the base frame so as to be movable up and down, and the screen frame is fixed to the elevating frame and the squeegee is horizontally movable by a squeegee driving means, the pedestal driving means and the squeegee driving The means is that the printing cylinder and the squeegee are synchronously controlled so as to horizontally move in synchronization.

  The cylinder-type screen printing machine according to claim 3 is characterized in that the substrate is a long base film unwound from an unwinder and wound up by a winder, and the base film of the printing cylinder An upstream guide roller that guides the base film, and an upstream guide roller that guides the base film, and a downstream side that guides the base film. A guide roller, and the top of the upstream guide roller and the top of the downstream guide roller are positioned below the top of the printing cylinder.

  In the cylinder type screen printing machine according to the first aspect, the printing cylinder is supported so as to be rotatable and horizontally movable. The squeegee is horizontally movable in synchronization with the printing cylinder. In addition, the screen plate is not horizontally movable. In other words, the screen plate is fixed, and the printing cylinder and the squeegee move while sandwiching the substrate to be printed, so that the screen plate does not shake. Therefore, according to this cylinder type screen printing machine, the printed image is hardly distorted. Furthermore, since the printing cylinder moves while rotating, no excessive force is applied to the substrate, and the printed image is less likely to be distorted.

  In the cylinder type screen printing machine according to claim 2, since the pedestal driving means for horizontally moving the printing cylinder and the squeegee driving means for horizontally moving the squeegee are controlled synchronously, the relative relationship between the tip of the squeegee and the top of the printing cylinder is achieved. The squeegee and the printing cylinder can be moved while maintaining the target position, making it possible to perform screen printing while the screen plate is fixed, and the printed image is hardly distorted.

  In the cylinder type screen printing machine according to claim 3, screen printing is performed in such a manner that the base film is lifted by the printing cylinder, and the base film is separated from the screen plate on the upstream side and the downstream side in the traveling direction of the printing cylinder. In addition, the base film can be automatically released by only the movement of the printing cylinder. Therefore, even a long base film can be printed without deforming the screen plate, and the print image is stretched, smeared, smudged, and the print image is distorted due to the screen plate shaking. It becomes difficult to occur.

The front view of the cylinder type screen printing machine of embodiment. The front view of the printing cylinder part in connection with the cylinder type screen printing machine of embodiment. The side view of the printing cylinder part in connection with the cylinder type screen printing machine of embodiment. The side view of a squeegee unit in connection with the cylinder type screen printing machine of embodiment. The figure which concerns on the cylinder type screen printer of embodiment, and shows the relationship between the printing roller at the time of printing, a screen plate, and a squeegee. Schematic of a conventional cylinder type screen printing machine.

  An embodiment embodying a cylinder-type screen printing machine according to the present invention will be described below with reference to the drawings. FIG. 1 is a front view of the cylinder type screen printing machine, and is a partial sectional view. As shown in FIG. 1, in this cylinder type screen printing machine, four support pillars 1a are erected at the four corners of a horizontally arranged base frame 1, and an elevating frame 5 is supported horizontally on the upper part of the support pillar 1a. ing. The elevating frame 5 can be moved up and down by a servo motor 4 which is a frame elevating means.

  A printing cylinder 10 is disposed on the base frame 1 in the horizontal direction. The printing cylinder 10 is horizontally movable by a servo motor 3 which is a pedestal driving means. A screen plate 20 is fixed to the lower part of the elevating frame 5 so that it cannot be moved horizontally. Further, a squeegee unit 30 is provided on the lifting frame 5. The squeegee unit 30 is horizontally movable by a servo motor 6 as squeegee driving means. A squeegee 35 is attached to the squeegee unit 30. The squeegee unit 30 is integrally provided with a doctor unit 36. A doctor (not shown) that coats the screen plate 20 with a paste is attached to the doctor unit 36.

  An upstream guide roller 8 and a downstream guide roller 9 for guiding the base film 40 are provided on the base frame 1. The upstream guide roller 8 is disposed on the upstream side (left side in FIG. 1) of the base film 40 in the printing cylinder 10, and the downstream guide roller 9 is downstream in the travel direction of the base film 40 in the printing cylinder 10 (see FIG. 1). 1 right side). The top of the upstream guide roller 8 and the top of the downstream guide roller 9 are positioned below the top of the printing cylinder 10. Thereby, the base film 40 is inclined downward from the printing cylinder 10 toward the upstream guide roller 8 and the downstream guide roller 9.

  In this cylinder type screen printing machine, after the substrate film 40 as the printing material is fed between the printing cylinder 10 and the screen plate 20 from an unillustrated unwinding machine, the printing cylinder 10 and the squeegee 35 are synchronized. It moves in the direction of the arrow and is printed on the substrate film 40. And when printing is completed, the printed base film 40 is wound up by a winder (not shown).

  As shown in FIGS. 2 and 3, two side plates 16 are erected on both ends of a flat pedestal 15 arranged horizontally on the base frame 1. A columnar cylinder shaft 11 is fixed at both ends of the cylinder shaft 11. A printing cylinder 10 is attached to the cylinder shaft 11. The printing cylinder 10 has a covered and bottomed cylindrical shape. Specifically, the cylinder shaft 11 passes through the center of the lid and bottom of the printing cylinder 10, and the printing cylinder 10 is supported by the cylinder shaft 11 via a ball bearing 12. As a result, the printing cylinder 10 is pivotally supported around the cylinder shaft 11. Therefore, when printing on the base film 40 by moving the printing cylinder 10, the printing cylinder 10 freely rotates according to the relative movement of the base film 40, and an excessive force is not applied to the base film 40. . In addition, two rails 2 are juxtaposed on the base frame 1. When the servo motor 3 is driven, the ball screw 3a converts the rotational motion of the servo motor 3 into a linear motion, and the pedestal 15 moves horizontally on the rail 2. In the present embodiment, the printing cylinder 10 is hollow, but is not limited thereto, and may be solid. Further, the cylinder shaft 11 may be formed integrally with the printing cylinder 10.

  As shown in FIG. 4, the squeegee unit 30 is configured by connecting two squeegee lifting adjustment mechanisms 32 at both ends of the joint plate 31. The squeegee lifting adjustment mechanism 32 includes a drive motor 32a, a cylinder unit 32b that is screwed up and down by the drive of the drive motor 32a, and an angle adjustment mechanism 32c that adjusts the angle of the squeegee 35. A squeegee holder 33 is mounted on the two cylinder units 32 b, and a squeegee 35 is attached to the squeegee holder 33. By driving the drive motor 32a, the squeegee 35 is moved up and down via the cylinder unit 32b, and the height of the tip of the squeegee 35 relative to the screen plate 20 is adjusted.

  Further, a guide plate 34 is provided on the outside of the two squeegee lifting adjustment mechanisms 32 so as to protrude horizontally. Two rails 7 are arranged side by side on the lifting frame 5. Thus, when the servo motor 6 is driven, the ball screw 6a converts the rotational motion of the servo motor 6 into a linear motion, and the squeegee unit 30 moves horizontally on the rail 7. When the squeegee unit 30 moves horizontally, the squeegee 35 also moves horizontally. The squeegee unit 30 is integrally provided with a doctor unit 36 having the same configuration as the squeegee unit 30. The doctor unit 36 is provided with a doctor (not shown) that serves to coat the screen plate 20 with a paste.

  An outline of a procedure for printing on the base film 40 in the cylinder-type screen printing machine having the above configuration will be described. First, the servo motor 4 is driven to lower the lifting frame 5 and the screen plate 20 and the squeegee 35 are lowered. Thereby, as shown in FIG. 5, the base film 40 is sandwiched between the printing cylinder 10 and the screen plate 20, and the squeegee 35 presses the screen plate 20. The servo motors 3 and 6 are driven in synchronization. As a result, the base 15 and the squeegee unit 30 move in parallel on the rails 2 and 7, and the printing cylinder 10 and the squeegee 35 move horizontally in the direction of the arrow shown in FIG. Thus, a predetermined print pattern is printed on the base film 40.

  Next, the servo motor 4 is driven to raise the elevating frame 5 to raise the screen plate 20 and the squeegee 35, and then the printed base film 40 is taken up by a winder. Finally, while the screen plate 20 and the squeegee 35 are raised, the printing cylinder 10 and the squeegee 35 are returned to their original positions while coating the paste on the screen plate 20 by a doctor, and one printing is performed. finish. By repeating the above operation, screen printing can be continuously performed on the long base film 40.

  A die coater may be attached instead of the doctor, and the screen plate 20 may be coated with the paste by the die coater simultaneously with the printing operation of the squeegee 35. In this case, the screen plate 20 is not coated with paste while the printing cylinder 10 and the squeegee 35 are returned to their original positions.

In the cylinder type screen printing machine of the embodiment, the printing cylinder 10 is supported so as to be rotatable and horizontally movable.
The squeegee 35 is horizontally movable in synchronization with the printing cylinder 10. Further, the screen plate 20 is not allowed to move horizontally. That is, since the screen plate 20 is fixed and the printing cylinder 10 and the squeegee 35 move while holding the base film 40, printing does not occur in the screen plate 20. Therefore, according to the cylinder type screen printing machine of the embodiment, the printed image is hardly distorted. Furthermore, since the printing cylinder 10 moves while rotating, no excessive force is applied to the base film 40, and the printed image is less likely to be distorted.

  In this cylinder type screen printing machine, the servo motor 3 that horizontally moves the printing cylinder 10 and the servo motor 6 that horizontally moves the squeegee 35 are synchronously controlled, so that the tip of the squeegee 35 and the top of the printing cylinder 10 are The squeegee 35 and the printing cylinder 10 can be moved while maintaining the relative position of the screen, and the screen printing can be performed in a state where the screen plate 20 is fixed, and the printed image is hardly distorted.

  Further, in this cylinder type screen printing machine, the screen printing is performed in such a manner that the base film 40 is lifted by the printing cylinder 10, and the base film 40 is the screen plate 20 on the upstream side and the downstream side in the traveling direction of the printing cylinder 10. Therefore, the base film 40 can be automatically separated by an operation that the printing cylinder 10 advances. Therefore, even if it is the elongate base film 40, it becomes possible to print without deforming the screen plate 20, and the print image resulting from elongation, blurring, blurring of the print image, and shaking of the screen plate 20 is also possible. It becomes difficult to produce distortion.

  The cylinder type screen printing machine according to the present invention has been described above with reference to the embodiments. However, the present invention is not limited to these embodiments, and can be appropriately modified and applied without departing from the technical idea of the present invention. Needless to say. For example, in this embodiment, the printing cylinder 10 is rotated by the frictional force between the printing cylinder 10 and the base film 40, but the printing cylinder 10 may be rotated by a motor.

DESCRIPTION OF SYMBOLS 1 ... Base frame, 3 ... Base drive means (servo motor), 4 ... Frame raising / lowering means (servo motor), 5 ... Elevating frame, 6 ... Squeegee drive means (servo motor), 8 ... Upstream guide roller, 9 ... Downstream Side guide roller, 10 ... printing cylinder, 11 ... cylinder shaft, 12 ... ball bearing, 15 ... pedestal, 20 ... screen plate, 35 ... squeegee, 40 ... substrate (substrate film)

Claims (3)

A printing cylinder disposed in a horizontal direction on a horizontally disposed base frame; a screen plate disposed above the printing cylinder and sandwiching a substrate between the printing cylinder; and
In a cylinder type screen printing machine comprising a squeegee for pressing the screen plate,
The screen plate is made immovable horizontally,
The printing cylinder is supported so as to be rotatable and horizontally movable,
The cylinder type screen printing machine, wherein the squeegee is horizontally movable in synchronization with the printing cylinder. A base that is supported by the base frame so as to be horizontally movable, and the printing cylinder is rotatably supported;
Pedestal drive means for horizontally moving the pedestal;
A lifting frame supported by the base frame so as to be movable up and down;
The elevating frame is provided with the screen plate fixed thereto and the squeegee is horizontally movable by a squeegee driving means,
2. The cylinder-type screen printing machine according to claim 1, wherein the pedestal driving means and the squeegee driving means are synchronously controlled so that the printing cylinder and the squeegee move horizontally in synchronization. The substrate is a long base film that is unwound from an unwinder and wound by a winder,
An upstream guide roller disposed on the upstream side of the printing cylinder in the running direction of the base film and guiding the base film;
A downstream guide roller disposed downstream of the printing cylinder in the traveling direction of the base film and guiding the base film;
3. The cylinder type screen printing machine according to claim 1, wherein a top portion of the upstream guide roller and a top portion of the downstream guide roller are positioned below a top portion of the printing cylinder.

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