KR20130063145A - Printer - Google Patents

Abstract

PURPOSE: A printing device is provided to efficiently perform an align process on a film without a buffer roller and to simplify the printing device. CONSTITUTION: The winding roll(80a) of an unwinder(80) winds the film of a print object. The roll driving unit(80b) of the unwinder drives the winding roll in a forward direction to supply and rewind the film. A work stage(50) supports the lower part of the film and is arranged in a process line for the print process. A stage aligner interacts with the unwinder to align the film and drives the work stage in one direction. [Reference numerals] (AA) Film

Description

Print Device {Printer}

The present invention relates to a printing apparatus, and more particularly, it is possible to efficiently align the film even without using a buffer roller as in the prior art, thereby simplifying the apparatus, and above all, the contact type by the buffer roller. The present invention relates to a printing apparatus capable of aligning a film in a non-contact manner away from the method, thereby improving print quality.

Flat panel displays, such as liquid crystal displays (LCDs), plasma display panels (PDPs) and organic light emitting diodes (OLEDs), are assembled with various types of filters, such as electromagnetic interference (EMI) filters, for example, to monitor TVs, computers, or It is used as a display device of electronic products such as mobile phones, PDAs, digital cameras, and the like. The touch screen panel is installed on the display surface of the flat panel display described above, and is used to allow a user to select desired information while viewing the image display device.

The above-described substrates for LCDs, PDPs and OLEDs, or various kinds of films attached thereto, and touch screen panels generally require a printing process.

For example, for LCD substrates, R (Red), G (Green), and B (Blue) color resists should be printed on the surface with an appropriate arrangement structure, and for films such as EMI filters, it should be arranged like a checkerboard arrangement. The monochromatic or multicolor resist pattern with

In the former case, it is possible to consider using an electronic printing device such as an inkjet printer or a roll printer because the printing degree should be considerably high. In the latter case, a screen printer or a roll that is difficult to fix because the printing degree may be relatively low. One may consider using a roll to roll printing apparatus.

On the other hand, when using a screen printer for printing the film there is a problem of lowering the productivity in the structure has been studied how to use a roll-to-roll printing apparatus alternatively.

The roll-to-roll printing apparatus feeds a film to be printed on a plurality of lower rolls onto a stage using an upper roll, and then prints on the printing surface, which is the upper surface of the film, through a blanket roll on the stage. This method has the advantage of high speed printing compared to screen printer.

However, in the conventional roll-to-roll printing apparatus, since the upper roll contacts the printing surface, which is the upper surface of the film, and feeds the film, the printing surface may be contaminated by the upper roll. If the synchronous control of the roll is not properly performed, there is a fear that the film may be pulled with a constant tension and not be fed. Therefore, there is a need for a new concept of roll-to-roll printing that can improve productivity by eliminating these shortcomings and enabling high-speed printing, and the present applicant currently has such a technology. Is pending for examination.

Meanwhile, the conventional printing apparatus is provided with a separate buffer roller for aligning the film.

The buffer roller is disposed on the upper region of the film at one side of the stage where the film is aligned, and pressurizes the film downward while tensioning the film while feeding the film, thereby driving stability to the film. After the stop, the roller is raised to implement the buffer for alignment by the positional displacement difference of the roller to assist the alignment work.

However, in such a prior art, the structure of the printing apparatus may be somewhat complicated because a separate buffer roller must be provided in the printing apparatus, and after the buffer roller is contacted on the upper surface of the film, the pressure is applied downward to the film. Since the transfer proceeds, various problems are expected such that the print surface, which is the upper surface of the film, may be contaminated by the buffer roller, and thus the print quality may be deteriorated.

Korean Patent Office Publication No. 10-2009-0043196

Therefore, the technical problem to be achieved by the present invention is to simplify the device because the alignment process for the film can be efficiently carried out even without using the buffer roller as in the prior art, and above all, the contactless method by the buffer roller and the non-contact method In order to proceed with the alignment of the film to provide a printing apparatus that can improve the print quality.

According to an aspect of the present invention, the winding roll (winding roll) is wound around the film to be printed, and the winding roll is driven in the forward and reverse direction to supply the film wound on the winding roll to the work line that the printing operation proceeds or An unwinder having an opposite winding roll drive; A work stage supporting the film from below and arranged on the work line to perform the printing operation; And a stage aligner connected to the work stage and driving the work stage in at least one direction while interacting with the unwinder to align the film. An apparatus may be provided.

A film winding-up detection unit disposed adjacent to the unwinder and sensing a winding amount of the film wound on the winding roll; And a controller configured to control operations of the unwinder and the stage aligner based on the sensing information of the film winding amount detecting unit for the alignment operation on the film.

The control unit, when the film is adsorbed on the work stage, by further rotating the winding roll in the forward direction to release the tension on the film on the work line, the work stage aligner on the work stage on the The operation of the unwinder and the stage aligner may be controlled to perform an alignment operation on the film.

The controller may control the operations of the unwinder and the stage aligner such that the stage is moved to the winding roll and then reversed to release the tension on the film on the work line.

The control unit controls the operation of the unwinder and the stage aligner to rotate the winding roll in the reverse direction after the printing operation on the film so that the film released on the work line can be wound on the winding roll. can do.

A film feeder disposed to be movable on an opposite side of the unwinder with respect to the work stage, the film feeder pulling and feeding the film on the work line by a predetermined length after holding the film; can do.

A vision for photographing the degree of printing may be further provided at the rear of the work stage with respect to the direction in which the film is supplied.

The load cell may further include a tension control load cell disposed on the work line and contacting the film to measure the tension of the film.

The tension control load cell may be disposed in an area between the unwinder and the work stage.

The film winding amount detecting unit may be a laser sensor that detects the winding amount of the film wound on the winding roll by detecting a diameter of the winding roll by irradiating a laser toward the winding roll.

The apparatus may further include a plurality of up / down rollers provided to be movable up / down on both sides of the work stage to support the film.

It is provided on the work line, and may further include a plurality of guide rollers for guiding the transport of the film while supporting the film from the bottom.

Gravure spaced apart from the work stage and the resist applied to the outer surface; And a blanket roll transferring the resist from the gravure to apply the resist to the film on the work stage.

The gravure may be a gravure roll or a gravure plate.

A dispenser for applying the resist to an outer surface of the gravure; And a doctor blade disposed around the dispenser to remove unnecessary resist from the resist applied to the outer surface of the gravure.

The lower surface of the work stage may further include a support plate which is provided in parallel with the work stage at a spacing apart from the work stage, wherein the stage aligner, at least a portion of the stage is coupled to the lower surface of the work stage It may include four moving support units are respectively provided in the four corner regions of the upper surface of the support plate.

The moving support unit, the motor controlled by the control unit; A ball screw coupled to the motor and rotatable in a forward and reverse direction by the motor; A moving block coupled to the ball screw and movable along the longitudinal direction of the ball screw when the ball screw rotates; An intersecting block coupled to the moving block and freely moving in a direction crossing the moving block; Fixed portions fixed at both ends to an upper surface of the cross-block and a lower surface of the work stage; And at least one rail provided on an upper surface of the support plate to guide the movement of the movable block.

The moving support unit may include a plurality of protrusions protruding upward from an upper surface of the moving block and having through holes formed therein; A moving shaft movably coupled to the protruding portion so as to pass through the through hole, and at least a portion of which is fixed to the cross block; And a rotation support part provided on an opposite side of the motor with the ball screw therebetween to rotatably support an end of the ball screw.

According to the present invention, it is possible to efficiently align the film even without using a buffer roller as in the prior art, thereby simplifying the apparatus, and above all, freeing the film in a non-contact manner away from the contact method by the buffer roller. Printing can be carried out to improve print quality.

1 is a structural diagram of a printing apparatus according to an embodiment of the present invention.
2 to 10 are diagrams showing the operation of the printing apparatus shown in FIG. 1 step by step.
11 is a schematic perspective view of the work stage area.
12 is a schematic planar projection view of FIG. 11.
FIG. 13 is an enlarged perspective view of area A of FIG. 12.
14 is a cross-sectional view taken along line CC of FIG. 13.
15 is a schematic partial plan view of FIG. 1.
FIG. 16 is a diagram illustrating a state in which the work stage of FIG. 15 is moved along the X axis.
17 is a diagram illustrating a state in which the work stage of FIG. 15 is moved on the Y axis.
18 is a diagram illustrating a state in which the work stage of FIG. 15 is rotated along the θ axis.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

For reference, the film to be described below may include a film required in the flat panel display industry or similar IT industry, for example, an electromagnetic interference (EMI) filter, a flexible touch screen panel, and the like. It will be described as simply a film without distinguishing these.

1 is a structural diagram of a printing apparatus according to an embodiment of the present invention, Figures 2 to 10 are steps showing the operation of the printing apparatus shown in Figure 1, Figure 11 is a schematic perspective view of the work stage area FIG. 12 is a schematic plan view of FIG. 11, FIG. 13 is an enlarged perspective view of region A of FIG. 12, FIG. 14 is a sectional view taken along CC of FIG. 13, and FIG. 15 is a schematic partial plan view of FIG. 1. 16 is a diagram illustrating a state in which the work stage of FIG. 15 is moved along the X axis, FIG. 17 is a diagram illustrating a state in which the work stage of FIG. 15 is moved along the Y axis, and FIG. 18 is a diagram of FIG. It is a figure which shows the state with which the work stage rotated by (theta) axis.

Referring to these drawings, but mainly referring to FIG. 1, the printing apparatus of the present embodiment drives a winding roll 80a on which a film to be printed is wound and a winding roll 80a by driving the winding roll 80a in the forward and reverse directions. An unwinder 80 having an unwinder 80a which feeds or reversely winds the film wound on 80a to a work line in which a printing operation proceeds, and supports the film from below, and is disposed on the work line A stage aligner 70 connected to the work stage 50 and a work stage 50 through which a print job is performed, and for driving the work stage 50 in at least one direction to align the film. stage aligner, see FIG. 11).

In addition to these configurations, the printing apparatus of the present embodiment includes a gravure 10, which is disposed apart from the work stage 50, and a resist is applied to the outer surface, and the gravure 10 that is spaced apart from the work stage 50. Blanket roll 40 for printing while receiving the resist on the side and applying the resist to the film on the work stage 50, and dispenser 30 for applying the resist to the outer surface of the gravure 10. 4) and a doctor blade 20 disposed around the dispenser 30 to remove unnecessary resist from the resist applied to the outer surface of the gravure 10.

At this time, since the gravure 10 is applied as a gravure roll 10 in the present embodiment, gravure 10 will be described as a gravure roll 10 below.

Meanwhile, hereinafter, for clarity, the gravure roll 10, the dispenser 30, the doctor blade 20, the blanket roll 40, the work stage 50, the stage aligner 70, and the unwinder ( 80) and the configurations associated with it will be described in sequence.

First, the gravure roll 10 plays a role of transferring a resist to the outer surface of the blanket roll 40. Therefore, the gravure roll 10 and the blanket roll 40 are provided with substantially the same diameter and length.

If the gravure roll 10 is fixed in position, the blanket roll 40 may move toward the gravure roll 10 to transfer the resist from the gravure roll 10, and in the opposite case, the gravure roll 10 may be replaced by the blanket roll ( Transfer the resist as it moves towards 40). In the case of the present invention, the former case is applied.

Next, the dispenser 30 serves to apply a resist to the outer surface of the gravure roll 10. The resist may be black ink, monochrome ink of a different color, or color resist.

The dispenser 30 may be provided to be movable along the longitudinal direction of the gravure roll 10, to be able to move up and down at the corresponding position, or to be foldable in one direction. When such a structure is applied, the coating efficiency of the resist can be increased, and the interference with the surrounding structure can be avoided. Of course, the scope of the present invention need not be limited thereto.

As enlarged in FIG. 1, the outer surface of the gravure roll 10 is formed with an uneven pattern substantially covered with a resist (coated). The uneven pattern at this time may be both embossed or intaglio. If it is embossed, a resist is applied to the outer surface of the protruding uneven portion 10b (see FIG. 1) and transferred to the blanket roll 40. If it is an embossed form, the resist is formed inside the recessed recessed portion 10a (see FIG. 1). Is applied and transferred to the blanket roll 40.

However, when the blanket roll 40 transfers the resist from the outer surface of the gravure roll 10 and retransmits (prints) the film to the film, the gravure roll 10 is used to maintain the thickness of the resist pattern uniformly from the surface of the film. It may be advantageous that the uneven pattern formed on the outer surface of the intaglio form.

When the resist is applied to the outer surface of the gravure roll 10 by the dispenser 30, the resist should be applied only to the recessed portions 10a of the substantially intaglio shape as shown in the enlarged portion of FIG. However, when the dispenser 30 applies the resist to the outer surface of the gravure roll 10, it is difficult to apply the resist at a time such that the resist is selectively received only in the recessed portion 10a of the substantially engraved shape.

Therefore, when the dispenser 30 applies the resist to the outer surface of the gravure roll 10, the resist is widely spread on the outer surface of the gravure roll 10 and applied, and when the application is completed, except for the recessed groove 10a of the intaglio shape. By removing the resist applied to the face 10b, that is, unnecessary, it is possible to finally receive the resist only in the recess 10a. To this end, the doctor blade 20 is provided as a means for removing the unnecessary resist around the gravure roll 10.

The doctor blade 20 includes a knife holder 21 and a knife 22 coupled to the knife holder 21.

The knife holder 21 has a structure that can be easily attached and detached at a predetermined position of the doctor blade 20 in a one-touch form. The knife 22 has a length substantially similar to the length of the gravure roll 10, and is inclined with respect to the outer surface of the gravure roll 10 in a state where the tip thereof is in contact with the outer surface of the gravure roll 10. It scratches the outer surface.

Since the tip of the knife 22 is in contact with the outer surface of the gravure roll 10 in this way, when a resist is applied to the outer surface of the rotating gravure roll 10, the recess 22 of the intaglio shape is formed by the knife 22. The resist applied to the remaining surface 10b except for the above may be naturally removed. Therefore, the resist can be finally received only in the recess 10a.

Next, the blanket roll 40 receives the resist applied in the groove portion 10a (see FIG. 1) formed on the outer surface of the gravure roll 10, more specifically, on the outer surface of the gravure roll 10, and the work stage It is loaded onto 50 and serves to print a resist pattern on the film while moving and rotating towards the film fixed by adsorption in vacuum.

On the outer surface of the blanket roll 40, a sheet to which a resist is transferred from the gravure roll 10 is wound. The sheet used 40 times the appropriate limit should be replaced, so the blanket roll 40 is provided with sheet replacement means 41 for easily replacing the sheet. The sheet replacement means 41 serves to provide a certain tension to the sheet so that the sheet can be easily replaced, while the sheet is stretched and unwound without being lifted from the outer surface of the blanket roll 40.

As described above, in the case of the printing apparatus of the present embodiment, since the blanket roll 40 must transfer the resist from the gravure roll 10 and retransfer it to the film on the work stage 50, the blanket roll 40 Raising and lowering driving, horizontal driving and rotating driving should be possible. Therefore, the blanket roll 40 may be provided with a blanket roll driving unit (not shown) for lifting and lowering driving, horizontal driving, and rotational driving. Although not shown in FIG. 1 for the blanket roll driver for convenience, the lifting and lowering drive, the horizontal drive, and the rotary drive of the blanket roll drive may be applied to a cylinder, a linear motor, and a rotary motor, respectively.

Next, the work stage 50 is a place where the printing operation with respect to a film advances by the blanket roll 40 which is moved and rotated. The upper surface to which the film is contacted and adsorbed may be made of stone or made of metal.

Referring to FIG. 11, an air line 50a may be formed on the surface of the work stage 50. A plurality of vacuum holes (not shown) in which a vacuum is formed for adsorption of a film may be provided at an intersection point where the air lines 50a cross each other or on the air line 50a, and the vacuum holes may include porous air guide members ( Not shown) may be combined. The porous air guide member may be made of a porous material. Of course, instead of the air line 50a, only a plurality of vacuum holes may be formed.

A lower portion of the work stage 50 may be provided with a plurality of partitions (not shown) for partitioning the vacuum holes into a plurality of groups. The partitions may be formed to be recessed in a direction from the bottom surface of the work stage 50 to the upper surface. In this case, each of the partitions may be provided with an air supply or blow-out line (not shown) that can be individually controlled. Thus, when the air flow in one direction through the air supply or blow-out line is made the film can be adsorbed by the vacuum on the surface of the work stage 50, if the opposite air flow is made the film of the work stage 50 Slight injury may occur from the surface.

On the other hand, in the conventional roll-to-roll printing method, the alignment of the film has been performed before the printing operation by an edge position controller called EPC (Edge Position Controller), but in this case, the degree required in the process The alignment work for the film could not proceed efficiently. In particular, the alignment with respect to the (theta) direction of a film was difficult. Therefore, in the technical field which requires a relatively high degree, the degree of printing required could not be matched.

Thus, in the present embodiment, the film is adsorbed on the surface of the work stage 50 in a vacuum, the work stage 50 in the plane direction of the work stage 50, for example, the X-axis direction (see Fig. 16), Y By moving in the axial direction (see FIG. 17) and the θ axis direction (see FIG. 18), a relatively high degree of alignment work is performed on the film. To this end, that is, a stage aligner 70 is provided to align the film while moving the work stage 50 in the X-axis, Y-axis, and θ-axis directions.

In other words, at least a portion of the stage aligner 70 is coupled to the lower portion of the work stage 50 to support the work stage 50 to be movable. The stage aligner 70 will be described first with reference to FIGS. 11 to 14 as follows.

At least a portion of the stage aligner 70 is coupled to the lower portion of the work stage 50, and is substantially rectangular in shape with respect to the plate surface of the work stage 50, thereby moving the work stage 50 to the plate surface direction of the work stage 50. (X-axis, Y-axis and θ-axis direction) to support the movement.

Most of the stage aligner 70 is coupled to the upper surface of the support plate 58, and only a part thereof is coupled to the lower surface of the work stage 50 to connect the support plate 58 and the work stage 50. .

The stage aligner 70 includes four moving support units 70a to 70d respectively provided at four corner regions of the upper surface of the support plate 58. As a result, a position where four moving support units 70a to 70d are arranged is called a rectangular composition arrangement.

As such, when four moving support units 70a to 70d are arranged in four corner regions of the upper surface of the support plate 58, the four support members 70a to 70d have a more stable support structure than the three-point support type that can be expected. Even when the huge blanket roll 40 presses the work stage 50 at a high pressing force in the printing operation, the work stage 50 does not move arbitrarily. That is, the jungle can be minimized. Of course, it is natural that the work stage 50 can be finely moved easily or efficiently in the X-axis, Y-axis, and θ-axis directions.

Hereinafter, for convenience of description, each of the four moving support units 70a to 70d is referred to as the first to fourth moving support units 70a to 70d, respectively, in a counterclockwise direction based on the area A of FIG. 12. Let's explain.

Each of the first to fourth moving support units 70a to 70d is coupled to the first to fourth motors 71a to 71d and the first to fourth motors 71a to 71d to form a first to fourth motor ( The first to fourth motors 71a to 72d and the first to fourth ball screws 72a to 72d and the first to fourth ball screws 72a to 72d which are rotatable in the forward and reverse directions by 71a to 71d. 1st-4th rotation support parts 73a-73d provided in the opposite side of 71d) and rotatably supporting the edge part of 1st-4th ball screw 72a-72d, and 1st-4th ball screw 72a. First to fourth moving blocks 74a coupled to ˜72d and movable along the longitudinal direction of the first to fourth ball screws 72a to 72d when the first to fourth ball screws 72a to 72d are rotated. ˜74d) and first to fourth freely coupled to the first to fourth moving blocks 74a to 74d and freely moving in a direction crossing the direction in which the first to fourth moving blocks 74a to 74d move. Intersecting blocks 76a to 76d and first to fourth intersections at both ends The lock (76a ~ 76d) including first to fourth fixing part (77a ~ 77d) which is fixed to the lower surface of the upper surface and the workpiece carrier (50).

Each of the first to fourth motors 71a to 71d is independently controlled by a control unit. That is, when the degree to which the film adsorbed by vacuum on the work stage 50 with respect to the blanket roll 40 is distorted in the X-axis, Y-axis, and θ-axis directions is calculated, the controller controls the first to fourth motors 71a to 71d. ) Are independently controlled to allow the work stage 50 to be moved through the movement of the first to fourth moving blocks 74a to 74d and the first to fourth cross blocks 76a to 76d.

A plurality of first to fourth rails for guiding the movement of the first to fourth moving blocks (74a to 74d) on the upper surface of the support plate 58 for the stable movement of the first to fourth moving blocks (74a to 74d) 75a-75d are provided. Accordingly, a plurality of first to fourth moving blocks 74a to 74d moving along the longitudinal direction of the first to fourth ball screws 72a to 72d by the rotation of the first to fourth ball screws 72a to 72d. It is possible to stably move along the first to fourth rails (75a ~ 75d).

As described above, the first to fourth moving blocks 74a to 74d are moved by the operation of the first to fourth motors 71a to 71d. However, unlike the first to fourth moving blocks 74a to 74d, the first to fourth cross blocks 76a to 76d move freely on the first to fourth moving blocks 74a to 74d.

13 and 14, a plurality of protrusions 78a protruding upward from the upper surface of the first moving block 74a and having through holes 79a formed therein, and through holes. A moving shaft 59 is movably coupled to the protrusion 78a so as to pass through the 79a, and at least a portion thereof is fixed to the first intersecting block 76a. Through this structure, the first intersecting block 76a may freely move along the longitudinal direction of the moving shaft 59 on the upper surface of the first moving block 74a. Here, the configuration of the protrusion 78a and the moving shaft 59 is provided in the second to fourth moving support units 70b, 70c, and 70d in addition to the first moving support unit 70a shown in FIGS. 13 and 14, respectively. For the sake of convenience, portions of the second to fourth moving support units 70b, 70c, and 70d will be omitted.

The work stage 50 can be more stably supported by arranging the first to fourth moving support units 70a to 70d at four corner regions of the support plate 58. However, in order to align the film, the work stage 50 should be moved in the X-axis, Y-axis, and θ-axis directions as necessary, so that the arrangement direction of each of the first to fourth moving support units 70a to 70d may also be It is an important factor. In the present embodiment, the first to fourth balls formed on the first to fourth moving support units 70a to 70d, respectively, to move the work stage 50 in the X, Y, and θ axis directions. Screws 72a to 72d are disposed in substantially the same direction as those arranged along the diagonal direction on the upper surface of the support plate 58, but the first to fourth moving support units 70a to 70d disposed along the diagonal direction. The first to fourth motors 71a to 71d provided in the field are positioned in opposite directions to each other. Due to this structural feature, the work stage 50 can be easily moved in the X-axis, Y-axis, and θ-axis directions (see FIGS. 16 to 18), thereby performing alignment work on the film more efficiently. You can do it.

On the other hand, in the printing apparatus of the present embodiment in which the gravure roll 10, the dispenser 30, the doctor blade 20, the blanket roll 40, the work stage 50 and the stage aligner 70 are provided, In addition to one unwinder 80, a film winding amount detecting unit 81, a controller (not shown), a film feeder 82, a vision 84, a load cell 85 for tension control, and a plurality of The configuration of the up / down roller 87 and the plurality of guide rollers 88 is provided.

An unwinder 80 having a winding roll 80a and a roll driver 80a for driving the winding roll 80a in the forward and reverse directions serves to feed or reversely wind the film to a work line in which a print job is performed. .

The film winding-up detection unit 81 is disposed adjacent to the unwinder 80 and serves to detect the winding amount of the film wound on the winding roll 80a.

In this embodiment, the film winding amount detecting unit 81 detects the diameter of the winding roll 80a by irradiating a laser toward the winding roll 80a to detect the winding amount of the film wound on the winding roll 80a. It is applied to the sensor 81. However, the scope of the present invention is not limited to the object matter.

The controller (not shown) controls the operations of the unwinder 80 and the stage aligner 70 based on the sensing information of the film winding amount detecting unit 81 to align the film. Herein, the role of the controller will be briefly described, and the operation of the specific printing apparatus by the controller will be described later with reference to FIGS. 2 to 10.

In this embodiment, when the film is adsorbed on the work stage 50, the control unit further rotates the winding roll 80a in the forward direction to release the tension on the film on the work line, and then the stage aligner 70 is removed. Through this, the operation of the unwinder 80 and the stage aligner 70 is controlled such that the work on the film is aligned on the work stage 50.

That is, the controller controls the operation of the unwinder 80 and the stage aligner 70 such that the work stage 50 is moved to the winding roll 80a and then reversed to release the tension on the film on the work line. do. In addition, after the printing operation on the film, the control unit rotates the winding roll 80a in the reverse direction so that the unwinder 80 and the stage aligner can be wound on the winding roll 80a as much as the film is released on the work line. The operation of 70 is controlled.

The film feeder 82 is disposed to be movable on the opposite side of the unwinder 80 relative to the work stage 50, and after holding the film, the film feeder is pulled onto the work line by a predetermined length. It serves to supply. This film feeder 82 may be applied as a single axis robot.

The meandering feeding correction unit 90 may be provided around the film feeder 82. The meandering feeding correction unit 90 serves to correct the meandering feeding while the film is out of a predetermined feeding path or inclined obliquely.

The vision 84 is disposed at the rear of the work stage 50 with respect to the direction in which the film is supplied, and serves to photograph the printing degree. The luminaire 84a is provided on the opposite side of the vision 84 with the film in between.

The tension control load cell 85 is in contact with the film, that is, in contact with the film at the bottom of the film to measure the tension of the film. The measured information may be transmitted to the controller. The tension control load cell 85 may be disposed in an area between the unwinder 80 and the work stage 50.

A plurality of up / down rollers 87 are disposed on the work line to support the film, but in particular move up / down on both sides of the work stage 50 to bring the film down to the work stage 50. play a role of down. Since the plurality of up / down rollers 87 also support the film from below, the printing surface, which is the upper surface of the film, is not contaminated.

A plurality of guide rollers 88 are placed on the printing work line to guide the transfer of the film while giving tension to the film. 1, it can be seen that a large number of guide rollers 88 are provided for each position to guide the conveyance of the film while applying tension to the film. Since the plurality of guide rollers 88 also support the film from below, the printing surface, which is the upper surface of the film, is not contaminated.

The operation of the printing apparatus having such a configuration will be described in detail with reference to FIGS. 2 to 10.

As shown in FIG. 2, the winding roll 80a is rotated in the forward direction by the roll driver 80a while the film feeder 82 grips the film and moves by a predetermined distance, that is, one pitch, and stops. In this state, the up / down rollers 87 take an up state with respect to the work stage 50.

As the up / down rollers 87 supporting the film as shown in FIG. 2 are down as shown in FIG. 3, the film is disposed on the upper surface of the work stage 50, and then fixed by vacuum.

When the film is sucked and fixed to the upper surface of the work stage 50 by vacuum, the alignment operation for the film is in progress.

First, create a buffer for the alignment. That is, as the winding roll 80a is further rotated by a predetermined angle in the forward direction by the roll driving unit 80a, a buffer is generated in the section Z1 between the winding roll 80a and the work stage 50 in FIG. 4. That is, in the section Z1 between the winding roll 80a and the work stage 50 in FIG. 4, the tension of the film is released to be slightly sag.

Next, the work stage 50 is moved toward the film feeder 82 by the stage aligner 70 as shown in FIG. 5. Then, the buffer is shared in the section Z2 between the work stage 50 and the film feeder 82 in FIG. 5. That is, as the buffer in the section Z1 between the winding roll 80a and the work stage 50 is transferred to the section Z2 between the work stage 50 and the film feeder 82, the work stage 50 and the film feeder ( 82)) in the section (Z2) between the tension of the film is released and becomes a slightly stretched state. Thereby, the whole film arrange | positioned on the imaginary line which connects the winding roll 80a and the film feeder 82 except for the part which the film adsorb | sucked to the work stage 50 will be in tension state loosened slightly.

In this state, the alignment work for the film is performed. That is, the controller controls the operation of the stage aligner 70 so that the work stage 50 is moved in the X-axis direction (see FIG. 16), the Y-axis direction (see FIG. 17), and the θ-axis direction (see FIG. 18). The relative position of the film relative to the blanket roll 40 is to be aligned. Take a look at this.

For example, when the work stage 50 needs to move a predetermined distance to the right side (X axis) as shown in FIG. 16 in the reference state as shown in FIG. 15, the controller operates the first and third motors 71a and 71c. The first and third ball screws 72a and 72c are rotated in one direction. Of course, the second and fourth motors 71b and 71d are not operated. Then, the first and third moving blocks 74a and 74c coupled to the first and third ball screws 72a and 72c have the right side of FIG. 16 along the first to third rails 75a and 75c below them. Go to. At this time, although the second and fourth moving blocks 74b and 74d positioned in the diagonal direction with the first and third moving blocks 74a and 74c are fixed, the upper portions of the second and fourth moving blocks 74b and 74d are fixed. The second and fourth intersecting blocks 76b and 76d provided at the second side may freely move to the right on the second and fourth moving blocks 74b and 74d. Therefore, the work stage 50 can move to the right side (X axis) as shown in FIG. 16 through this series of operating mechanisms.

If the work stage 50 needs to move a predetermined distance to the upper side (Y axis) as shown in FIG. 17 in the reference state as shown in FIG. 15, the controller operates the second and fourth motors 71b and 71d at this time. The second and fourth ball screws 72b and 72d are rotated in one direction. Of course, the first and third motors 71a and 71c are not operated. Then, the second and fourth moving blocks 74b and 74d coupled to the second and fourth ball screws 72b and 72d are along the lower second to fourth rails 75b and 75d of FIG. 17. Go to. At this time, although the first and third moving blocks 74a and 74c positioned in the diagonal direction with the second and fourth moving blocks 74b and 74d are fixed, the upper portions of the first and third moving blocks 74a and 74c are fixed. The first and third intersecting blocks 76a and 76c provided at the upper side may freely move upward on the first and third moving blocks 74a and 74c. Therefore, the work stage 50 can move upward (Y-axis) as shown in FIG. 17 through this series of operating mechanisms.

If the work stage 50 needs to rotate at a predetermined angle (θ-axis) clockwise as shown in FIG. 18 in the reference state as shown in FIG. 15, the controller controls the first to fourth motors 71a to 71d at this time. Make everything work. When the first to fourth motors 71a to 71d operate, the first to fourth moving blocks 74a to 74d are moved by the operation of the first to fourth ball screws 72a to 72d that rotate in one direction. In addition, the first to fourth intersecting blocks 76a to 76d are freely moved in the corresponding directions on the first to fourth moving blocks 74a to 74d, and thus, the work stages 50 as shown in FIG. ) Rotates a predetermined angle clockwise. 18 may be easily implemented by appropriately combining the operations of FIGS. 16 and 17, and thus a detailed description thereof will be omitted.

Meanwhile, the alignment operation of the film is performed in the state of FIG. 6 in which the peripheral film area that is not adsorbed by the work stage is loosely processed. The alignment operation of the film is performed at the same time, and the dispenser 30 moves at the same time. A resist is applied to the outer surface of 10) (see Fig. 4).

After the resist is applied to the outer surface of the gravure roll 10, the doctor blade 20 is moved toward the gravure roll 10, so that the tip of the knife 22 except for the recessed recess 10a (see FIG. 1) is formed. Unnecessary resist applied to face 10b (see FIG. 1) is removed.

When the operation of the doctor blade 20 is completed, the blanket roll 40 is raised and then contacted with the gravure roll 10 to transfer the resist from the gravure roll 10, and then moved and rotated after being lowered. 50) to be retranslated (printed) onto a film fixed on the substrate.

When the print job is completed, the blanket roll 40 is returned to its original position as shown in FIG. 7 and the work stage 50 is also moved to the original position. As the work stage 50 is returned to its original position in the direction of the arrow of FIG. 7, the buffer of the section Z2 between the work stage 50 and the film feeder 82 disappears. That is, the film loosely loosened in the section Z2 between the work stage 50 and the film feeder 82 is tensioned while being stretched again.

Next, as the winding roll 80a is rotated by a predetermined angle in the reverse direction by the roll driving unit 80a as shown in FIG. 8, the buffer also disappears in the section Z1 between the winding roll 80a and the work stage 50. That is, the film loosely loosened in the section Z1 between the winding roll 80a and the work stage 50 is tensioned while being pulled back again.

Then, after the vacuum of the work stage 50 is released as shown in FIG. 9, the film is spaced upwardly from the work stage 50 as the up / down rollers 87 are operated up. Then, as shown in FIG. 10, the film feeder 82 grips the film to move further by a predetermined distance, that is, one pitch, and repeats the operation of FIGS.

According to the printing apparatus of this embodiment having such a structure, it is possible to efficiently align the film even if the buffer roller is not used as in the prior art, thereby simplifying the apparatus, and above all, in the contact method by the buffer roller. In addition, the film can be aligned in a non-contact manner, thereby improving print quality.

Although the present embodiment has been described in detail with reference to the drawings, the scope of the present invention is not limited to the above-described drawings and descriptions.

In the above-described embodiment, the gravure 10 is applied as the gravure roll 10, but the gravure 10 may be applied as a gravure plate having a plate shape.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

10: Gravure Roll 20: Doctor Blade
30: dispenser 40: blanket roll
50: work stage 60: drying unit
70: Stage Aligner 80: Unwinder
80a: winding roll 80a: roll drive unit
81: film winding amount detection unit 82: film feeder
84: vision 85: load cell for tension control
87: up / down roller 88: guide roller

Claims (18)

An unwinding roll including a winding roll on which a film to be printed is wound, and a roll driving unit which drives the winding roll in a forward and backward direction to supply the film wound on the winding roll to a work line in which a printing operation is performed or reversely. Winder;
A work stage supporting the film from below and arranged on the work line to perform the printing operation; And
And a stage aligner connected to the work stage and driving the work stage in at least one direction while interacting with the unwinder to align the film. . The method of claim 1,
A film winding-up detection unit disposed adjacent to the unwinder and sensing a winding amount of the film wound on the winding roll; And
And a control unit for controlling the operation of the unwinder and the stage aligner based on the sensing information of the film winding amount detecting unit for the alignment operation on the film. The method of claim 2,
The control unit,
When the film is adsorbed to the work stage, the winding roll is further rotated in the forward direction to release the tension on the film on the work line, and then the work stage aligner is used to freeze the film on the work stage. And controlling the operation of the unwinder and the stage aligner so that the in-work proceeds. The method of claim 3,
The control unit,
And control the operation of the unwinder and the stage aligner such that the stage is moved toward the winding roll and then reversed to release the tension on the film on the work line. The method of claim 3,
The control unit,
After the printing operation on the film, the winding roll is rotated in the reverse direction to control the operation of the unwinder and the stage aligner so that the film rolled on the work line can be wound on the winding roll. Printing device. The method of claim 1,
A film feeder disposed to be movable on an opposite side of the unwinder with respect to the work stage, the film feeder pulling and feeding the film on the work line by a predetermined length after holding the film; Printing apparatus, characterized in that. The method of claim 1,
And a vision for photographing the degree of printing in the rear of the work stage with respect to the direction in which the film is supplied. The method of claim 1,
And a tension control load cell disposed on the work line and in contact with the film to measure the tension of the film. 9. The method of claim 8,
And the tension control load cell is disposed in an area between the unwinder and the work stage. The method of claim 1,
The film winding amount detecting unit is a laser sensor for detecting the winding amount of the film wound on the winding roll by detecting the diameter of the winding roll by irradiating a laser toward the winding roll. The method of claim 1,
And a plurality of up / down rollers provided to be movable up / down on both sides of the work stage to support the film. The method of claim 1,
And a plurality of guide rollers provided on the work line to guide the transfer of the film while supporting the film from below. The method of claim 1,
A gravure which is spaced apart from the workpiece and onto which the resist is applied; And
And a blanket roll receiving the resist from the gravure and applying the resist to the film on the work stage. The method of claim 13,
The gravure printing apparatus, characterized in that the gravure roll (Gravure roll) or gravure plate (Gravure plate). The method of claim 13,
A dispenser for applying the resist to an outer surface of the gravure; And
And a doctor blade disposed around the dispenser to remove unnecessary resist from the resist applied to the outer surface of the gravure. The method of claim 1,
Further comprising a support plate provided in parallel with the work stage at a spaced interval from the work stage in the lower region of the work stage,
And the stage aligner includes four moving support units respectively provided at four corner regions of the upper surface of the support plate while at least a portion thereof is coupled to the lower surface of the work stage. 17. The method of claim 16,
The moving support unit,
A motor controlled by the controller;
A ball screw coupled to the motor and rotatable in a forward and reverse direction by the motor;
A moving block coupled to the ball screw and movable along the longitudinal direction of the ball screw when the ball screw rotates;
An intersecting block coupled to the moving block and freely moving in a direction crossing the moving block;
Fixed portions fixed at both ends to an upper surface of the cross-block and a lower surface of the work stage; And
And at least one rail provided on an upper surface of the support plate to guide the movement of the movable block. 18. The method of claim 17,
The moving support unit,
A plurality of protrusions protruding upward from an upper surface of the moving block and having through holes formed therein;
A moving shaft movably coupled to the protruding portion so as to pass through the through hole, and at least a portion of which is fixed to the cross block; And
And a rotation support part provided on the opposite side of the motor with the ball screw therebetween to rotatably support the end of the ball screw.

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