KR101694193B1 - Pad printing apparatus - Google Patents

Abstract

A pad printing apparatus is disclosed. A pad printing apparatus according to an embodiment of the present invention includes a work stage unit for supporting a substrate for a printing operation for forming a pattern on a substrate; A printing plate stage unit for supporting a printing plate on which a circular pattern for forming a pattern is formed; And a printing module having a blanket stamp which contacts the printing plate to transfer the circular pattern of the printing plate and contacts the substrate to form the pattern on the substrate but is elastically deformed upon contact with the printing plate or the substrate and a coating And a pad printing unit having a module.

Description

[0001] PAD PRINTING APPARATUS [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pad printing apparatus, and more particularly, to a pad printing apparatus capable of improving printing accuracy.

In applying the printing technique to the production of high value added products such as semiconductors and displays, it is necessary to provide a printing method which can realize very clear printing, and which does not deform the printing form and does not change the printing position accuracy even if the printing is repeated.

There is a reverse offset printing method which is very sharp and does not deform the printing shape due to repetition of printing.

As the reverse offset printing method, a roll-to-roll method in which a printing liquid is transferred from a gravure roll to a blanket roll or a roll-to-roll method in which a blanket roll is used as a plate type The printing plate is rotated by contact with the printing plate so that unnecessary printing liquid adheres to the plate type printing plate. A printing liquid is left on the blanket roll in accordance with the printing pattern, and the printing liquid transferred to the blanket roll is transferred to the substrate, to plate method.

On the other hand, in the inverse offset printing apparatus using a roll, the printing precision is determined by the synchronization precision of the roll rotation speed and the roll or substrate advance speed.

However, when the mechanical gear is used to synchronize the rotational speed and the running speed, there is a problem that the gear machining error manifests itself as a printing precision error.

Although the synchronization accuracy is improved compared with the method using the mechanical gear when the control gear is synchronized instead of using the mechanical gear, it is difficult to precisely synchronize the rotation speed and the advancing speed so that the printing precision is limited to some extent There is a problem.

In addition, swelling of the blanket roll occurs due to repetition of printing, thereby changing the diameter of the blanket roll, and in accordance with the diameter change of the blanket roll, And synchronization problems of linear driving may occur continuously.

In addition, in a roll type printing apparatus, in order to mount the blanket sheet with a uniform tension, a complicated mounting mechanism is required, and a blanket sheet having a limited life is to be replaced occasionally, Which is somewhat inefficient in terms of production efficiency.

On the other hand, the pad printing is a printing method in which a printing pattern is transferred by a pad to perform printing. In such a pad printing, when the object is mounted on the feeding jig, the printing pattern of the eroding substrate, The desired printing is performed on the surface of the paper.

However, the conventional pad printing method for performing such pad printing can simplify the structure of a device implementing the printing method as compared with the reverse offset printing method, but it is difficult to manufacture high value-added products such as semiconductors and displays due to lack of precision It is not used.

Accordingly, there is a need to develop a pad printing apparatus having improved precision than that of the past in order to be able to solve various problems of a roll-type printing apparatus and to be used for manufacturing high value-added products such as semiconductors and displays.

Korean Patent No. 10-0970191 (issued on July 14, 2010)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a pad printing apparatus capable of improving the printing accuracy while improving the conventional reverse offset printing method.

According to one aspect of the present invention, a pad printing apparatus according to the present invention comprises: a work stage unit for supporting a substrate for a printing operation for forming a pattern on a substrate; A printing plate stage unit for supporting a printing plate on which a circular pattern for forming the pattern is formed; And a blanket stamp having a blanket stamp which contacts the printing plate to transfer the circular pattern of the printing plate and contacts the substrate to form the pattern on the substrate, the blanket stamp being elastically deformed upon contact with the printing plate or the substrate, And a pad printing unit having a coating module for coating the printing fluid on the stamp.

Wherein the circular pattern is an engraved pattern for the pattern of the substrate and the blanket stamp is brought into contact with the printing plate in a state in which the printing liquid is coated so that the printing liquid remains on only the pattern corresponding to the engraved pattern of the printing plate, So that the pattern can be formed on the substrate.

The blanket stamp comprising: a stamp body forming a body; A blanket sheet to which the printing liquid is applied; And a blanket sheet support for supporting the blanket sheet in contact with the stamp body to form a pressurizing chamber coupled to the stamp body and having a space therein.

The blanket stamp is characterized in that the stamp body has a predetermined recessed shape and the central region of the blanket sheet support is thinner than both end regions and between the stamp body and the blanket sheet support, May be combined.

The blanket stamp may further include a sheet tension adjusting unit for adjusting a tension of the blanket sheet.

The blanket stamp may further include an air supply unit for supplying air to the pressure chamber.

The printing module may further include a stamp pressing portion for pressing the blanket stamp to the substrate or the printing plate.

The printing module may further include a stamp rotating part coupled to the blanket stamp to rotate the blanket stamp.

The stamp rotating part includes a stamp rotating shaft to which the blanket stamp is coupled, and the blanket stamp may be provided symmetrically with respect to the stamp rotating shaft.

The printing module further includes a printing frame for forming a frame, wherein the stamp rotating portion includes: a rotating motor to which the stamp rotating shaft is coupled; And a rotating unit case coupled to the rotating motor and coupled to the printing frame, wherein the stamp pressing unit is coupled to the rotating unit case to move the rotating unit case to press the blanket stamp.

The printing module may further include a lower limit coupled to the print frame to limit the downward movement of the blanket stamp to a predetermined area.

The coating module comprising: a thin film cap for applying a printing liquid to the blanket stamp; And a moving engagement portion that relatively moves the thin film decorating portion with respect to the blanket stamp.

The printing plate stage unit includes: a printing plate stage on which the printing plate is placed; And a printing plate stage moving unit connected to a lower portion of the printing plate stage to support the printing plate stage and move the printing plate stage.

The stage moving unit includes a stage support frame spaced apart from a lower portion of the printing plate stage and supporting the printing plate stage; A moving rail disposed long in the direction of the pad printing unit; And a movement driving unit connected to the stage support frame and moving the stage support frame along the movement rail.

The movement drive includes a ball screw disposed along the moving rail, the ball screw coupled to the stage support frame; And a driving motor coupled to the ball screw and rotating the ball screw in forward and reverse directions to reciprocate the stage support frame along the moving rail.

Embodiments of the present invention can improve the problems of the conventional reverse offset printing method and improve the printing accuracy as compared with the conventional art.

1 is a front view of a pad printing apparatus according to an embodiment of the present invention.
2 is a right side view of Fig.
3 is a view for explaining the structure of the blanket stamp in the region 'A1' of FIG.
FIG. 4 is a view for explaining a state where air is supplied to the blanket stamp of FIG. 3;
FIG. 5 is a view for explaining the structure of the blanket stamp in the region 'A2' of FIG. 2. FIG.
FIG. 6 is a view for explaining a stamp rotating part, a stamp pressing part and a lower limit in the area 'B' of FIG. 2. FIG.
7 is a perspective view schematically showing a printing plate stage unit of the pad printing apparatus of FIG.
8 is a plan view showing a main alignment mark and auxiliary alignment marks formed in the pattern circle of the printing plate of the pad printing apparatus of FIG.
FIG. 9 is a planar projection view of FIG. 7. FIG.
10 is an enlarged perspective view of the area A of FIG.
11 is a sectional view taken along the line VI-VI in Fig.
Fig. 12 is a plan view showing a state in which the printing plate stage of the printing plate stage unit of the pad printing apparatus of Fig. 1 is moved in the X-axis direction. Fig.
13 is a plan view showing a state in which the printing plate stage of the printing plate stage unit of the pad printing apparatus of Fig. 1 is moved in the Y-axis direction.
14 is a plan view showing a state in which the printing plate stage of the printing plate stay unit of the pad printing apparatus of Fig. 1 is rotated by an axis.
15 is a process flow diagram illustrating a printing process according to an embodiment of the present invention.

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.

The terms " one side " and " other side " used in this specification may mean a specified side, or do not mean a specified side, but any side of a plurality of sides may be referred to as one side, And the other side is referred to as the other side.

Also, as used herein, the term " bond " or " connection " refers to the case where one member and another member are directly 'coupled' or directly 'connected', as well as one member is indirectly Or indirectly connected to each other.

FIG. 1 is a front view of a pad printing apparatus according to an embodiment of the present invention, and FIG. 2 is a right side view of FIG.

Referring to these drawings, a pad printing apparatus 1 according to an embodiment of the present invention includes a work stage unit (not shown) for supporting a substrate 10 for a printing operation for forming a pattern on a substrate 10 A printing plate stage unit 200 for supporting a printing plate 20 on which a circular pattern M for forming a pattern is formed and an unnecessary printing liquid 20 And a pad printing unit 300 for forming a pattern on the substrate 10 by transferring the patterned printing liquid 30 to the substrate 10 by contacting the substrate 10 with the printing plate 20 . The pad printing unit 300 includes a printing module 400 having a blanket stamp 410 that is elastically deformed upon contact with the printing plate 20 or the substrate 10 and a printing module 400 having a blanket stamp 410, And a coating module (500) for coating the substrate (30).

In this embodiment, in order to improve the printing accuracy of a conventional roll type, a flat plate type blanket stamp (hereinafter referred to as " blanket stamp "), which is elastically deformed upon contact with the printing plate 20 or the substrate 10, 410) is used. This will be described in detail later.

In this embodiment, the circular pattern M formed on the printing plate 20 is an engraved pattern M formed at an engraved pattern corresponding to the pattern to be formed on the substrate 10. [ That is, when the blanket stamp 410 on which the printing liquid 30 is applied comes into contact with the printing plate 20, only the area of the blanket stamp 410 corresponding to the engraved pattern M formed on the printing plate 20, The engraved pattern M is formed on the printing plate 20 so that the printing liquid 30 in the remaining area is placed on the printing plate 20. [

Therefore, in the present embodiment, the blanket stamp 410 is contacted to the printing plate 20 first in a state in which the printing liquid 30 is coated, so that only the blanket stamp 410 corresponding to the engraved pattern M of the printing plate 20 is printed The liquid 30 remains and then the printing liquid 30 patterned on the blanket stamp 410 is transferred to the substrate 10 to finally form a pattern on the substrate 10.

In this embodiment, the coating module 500 of the pad printing unit 300 applies the printing liquid 30 to the blanket stamp 410 of the pad printing unit 300 and applies the printing liquid 30 to the blanket stamp 410, The printing plate stage unit 200 is moved from the initial position shown in Fig. 1 to the printing position, which is the lower position of the pad printing unit 300, and the printing plate stage unit 200 is moved back to the initial position The workpiece stage unit 100 is moved from the initial position shown in FIG. 1 to the printing position, which is the lower position of the pad printing unit 300, in order to form the pattern on the substrate 10 .

The pad printing unit 300 includes a printing module 400 having a blanket stamp 410 and a coating module 500 for coating the printing liquid 30 on the blanket stamp 410 as described above .

The printing module 400 includes a printing frame 420 for forming a frame, a blanket stamp 410 and a stamp pressing portion 430 for pressing the blanket stamp 410 onto the substrate 10 or the printing plate 20. [ A stamp rotating part 440 coupled to the blanket stamp 410 to rotate the blanket stamp 410 and a lower limiter 430 coupled to the printing frame 420 to limit the downward movement of the blanket stamp 410 to a predetermined area, (450).

FIG. 3 is a view for explaining the structure of the blanket stamp in the region 'A1' of FIG. 1, FIG. 4 is a view for explaining a state where air is supplied to the blanket stamp of FIG. 3, FIG. 6 is a view for explaining the stamp rotating portion, the stamp pressing portion, and the lower limit in the region 'B' of FIG. 2. FIG.

Referring to Figures 1 and 2 together with these figures, the print frame 420 forms a frame. The stamp rotation unit 440, the stamp pressing unit 430, and the lower limit 450 may be coupled to the printing frame 420.

3 and 4, the blanket stamp 410 directly contacting the printing plate 20 or the substrate 10 includes a stamp body 411 forming a body, A blanket sheet supporting body 413 for supporting the blanket sheet 412 in contact with the blanket sheet 412 and a pressurizing chamber 419 coupled to the stamp body 411 to provide a space therein, A sheet tension adjusting portion 415 for adjusting the tension of the blanket sheet 412 and an air supply portion 418 for supplying air to the pressurizing chamber 419.

This blanket stamp 410 can be easily replaced in a short time by removing and replacing itself, so that it takes a lot of time for a complicated operation to add a certain tension when replacing the blanket sheet 412 in the form of a conventional blanket roll Can be improved.

The predetermined area of the stamp body 411 has a predetermined depressed shape. The stamp body 411 having such a structure is combined with the blanket sheet support 413 to form a pressurizing chamber 419 into which air can be injected.

The blanket sheet support 413 is provided to be deformable when air is injected into the pressurizing chamber 419. 3 and 4) of the blanket sheet support body 413 are provided so as to be thinner than both end regions 413a (see FIGS. 3 and 4), and as shown in detail in FIG. 4, the central region 413b The central region 413b protrudes when air is injected into the chamber 419 and the air pressure is applied so that the blanket sheet 412 also protrudes from the central region and the blanket sheet 412 is pressed against the printing plate 20 or the substrate (20) or the substrate (10) from the central area upon contact with the substrate (10).

The stamp body 411 and the blanket sheet 412 and the printing plate 20 or the substrate 10 are brought into contact with the printing plate 20 or the substrate 10 from the central area of the blanket sheet 412 at the time of printing, The blanket sheet 412 can apply a uniform pressure to the printing plate 20 or the substrate 10 by buffering the processing accuracy and the flatness of the printing plate 20 or the substrate 10. [

On the other hand, an O-ring 414 (O-Ring) for sealing is coupled between the stamp body 411 and the blanket sheet support 413. Thus, even if air is injected into the pressurizing chamber 419, leakage of air can be prevented.

And the blanket sheet 412 must maintain a constant tension for printing at a uniform pressure. To this end, a sheet tension adjusting portion 415 for adjusting the tension of the blanket sheet 412 is provided. 5, the sheet tension adjusting portion 415 includes a fixing body (not shown) for fixing one end of the blanket sheet 412 to the stamp body 411, a fixing body 411 for fixing the stamp body 411 to the blanket sheet 411, A tension applying member 416 coupled to the other end of the blanket sheet 412 to apply a tension to the blanket sheet 412 and a guide member 412 which is coupled to the other end of the blanket sheet 412 to guide movement of the blanket sheet 412. [ (417).

When the tension applying member 416 applies appropriate tension to the other end of the blanket sheet 412 with this configuration, the one end of the blanket sheet 412 is fixed, so that the other end of the blanket sheet 412 is guided by the guide member 417, So that the blanket sheet 412 maintains a proper tension.

6, the stamp rotating unit 440 includes a stamp rotating shaft 441 to which the blanket stamp 410 is coupled and a rotary motor 441 to which the stamp rotating shaft 441 is coupled through a reducer and a coupling And a rotatable unit case 443 coupled to the print frame 420 and supporting the rotatable motor 442.

The blanket stamp 410 is provided symmetrically with respect to the stamp rotating shaft 441 of the stamp rotating portion 440. In this way, two blanket stamps 410 are provided around the stamp rotation axis 441 to move upward when coating, and to rotate downward to perform a printing operation. When the two stamps are rotated about the stamp rotation axis 441 Since one of them is installed, the other one can be coated at the time of printing, so that the tact time can be reduced.

On the other hand, the blanket stamp 410 must be pressed against the printing plate 20 or the substrate 10 for printing. For this purpose, a stamp presser 430 is provided.

The stamp pressing unit 430 is coupled to the rotating unit case 443 to move the rotating unit case 443 up and down and the stamp rotating unit 440 moves up and down when the rotating unit case 443 is moved up and down, When the rotary part 440 moves up and down, the blanket stamp 410 coupled with the stamp rotation axis 441 of the stamp rotation part 440 moves up and down. The blanket stamp 410 contacts the printing plate 20 or the substrate 10 to press the printing plate 20 or the substrate 10 when the stamp pressing portion 430 moves the rotating portion case 443 downward. Here, the expression that the stamp presser 430 presses the blanket stamp 410 downwardly means that only the blanket stamp 410 or the like is released to support the blanket stamp 410 or the like by self weight of the blanket stamp 410 or the like Of course I will.

And the lower limit of the blanket stamp 410 is limited by the lower limit 450.

Meanwhile, a coating module 500 is provided to coat the printing liquid 30 on the blanket stamp 410. Since the exposed surface shape of the blanket stamp 410 has a flat surface, it can be provided as a slit coater capable of uniform film coating.

In this embodiment, the coating module 500 includes a thin film cap 510 (see FIG. 2) for applying the printing liquid 30 to the blanket stamp 410, and a thin film cap 510 for applying the thin film cap 510 to the blanket stamp 410 And a moving unit 520 for moving the moving unit 520 relative to the moving unit 520. The thin film cap 510 is moved relative to the blanket stamp 410 by the moving unit 520 so that the printing liquid 30 is applied to the entire area of the blanket stamp 410 where the printing liquid 30 needs to be applied do.

Next, the printing plate stage unit 200 supports a printing plate 20 on which a circular pattern M for forming a pattern is formed. This printing plate stage unit 200 includes a printing plate stage 210 on which the printing plate 20 is placed and a support plate 210 which is connected to a lower portion of the printing plate stage 210 to support the printing plate stage 210, And a stage moving unit 230 for moving the stage moving unit 230 in the direction of the arrow 300.

The printing plate stage 210 is moved in the direction of the pad printing unit 300 in a state in which the printing plate 20 is vacuum-adsorbed on the upper surface.

At this time, the movement of the printing plate stage 210 is performed by the stage moving unit 230 that supports the lower portion of the printing plate stage 210.

The printing plate stage moving unit 230 includes a printing plate stage support frame 231 that is spaced apart from the lower portion of the printing plate stage 210 and supports the printing plate stage 210, And a movement driving unit (not shown) connected to the printing plate stage supporting frame 231 and moving the printing plate stage supporting frame 231 along the moving rail 233.

The movement driving unit includes a ball screw (not shown) disposed along the movement rail 233 and coupled to the printing plate stage support frame 231, and a ball screw (not shown) coupled to the ball screw and rotating the ball screw in the forward and reverse directions, And a driving motor (not shown) that reciprocates in the direction of the pad printing unit 300.

For example, the moving rail 233 is disposed long in the direction of the pad printing unit 300, which is the direction in which the printing plate 20 is moved.

The printing plate stage support frame 231 supporting the lower portion of the printing plate stage 210 is linearly reciprocated along the moving rail 233 while being connected to the moving rail 233. That is, after the printing plate stage 210 is moved from the preset initial position to the pad printing unit 300 side, the printing plate stage 210 is moved from the pad printing unit 300 side to the initial position.

The reciprocating motion of the stage 210 is performed by the rotation of the ball screw rotated in conjunction with the forward and reverse rotation of the driving motor.

On the other hand, when the blanket stamp 410 touches the printing plate 20 to leave only the printing liquid 30 corresponding to the negative pattern M of the printing plate 20, the blank pattern can be pressed to the substrate 10 to form a desired pattern have.

When the blanket stamp 410 is pressed against the printing plate 20, the blanket stamp 410 and the printing plate 20 should be aligned with each other.

The printing module 400 further includes an alignment vision unit (not shown) provided on one side of the blank stamp.

The alignment vision unit is formed by aligning the main alignment mark P1 and the main alignment marks P1 and P2 formed on the printing plate 20 as shown in FIG. 8 so that the blank stamp 310 and the printing plate 20 on which the negative pattern is formed are aligned. And photographs the auxiliary alignment marks P2 provided at predetermined intervals.

7, in aligning the blanket stamp 410 and the printing plate 20 on the basis of the primary alignment marks P1 and secondary alignment marks P2 photographed by the alignment vision unit, The printing plate stage unit 200 according to the present embodiment further includes a printing plate stage alignment unit 250. [

The printing plate stage alignment unit 250 moves the printing plate stage 210 relative to the blanket stamp 410 based on the plurality of alignment marks on the printing plate 20 taken by the alignment vision unit, The printing plate 20 is aligned.

The printing plate stage alignment unit 250 aligns the printing plate 20 with respect to the blanket stamp 410 by moving the printing plate stage 210 in the plate surface direction of the printing plate stage 210, for example, in the X axis direction, the Y axis direction, .

That is, the printing plate stage alignment unit 250 is coupled to the lower portion of the printing plate stage 210 to moveably support the printing plate stage 210.

The printing plate stage arranging unit 250 will be described with reference to FIGS. 7 and 9 to 11. FIG.

The printing plate stage alignment unit 250 is coupled to the upper surface of the printing plate stage support frame 231 and the lower surface of the printing plate stage 210 to connect the printing plate stage supporting frame 231 to the printing plate stage 210.

The printing plate stage aligning unit 250 is disposed substantially in a rectangular configuration with respect to the printing plate stage 210 so that the printing plate stage 210 is aligned with the plate surface direction (X axis, Y axis, and axial direction) As shown in Fig.

 The printing plate stage aligning unit 250 includes four stage unit aligning units 260a to 260d arranged in four corner areas of the printing plate stage 210 to allow the printing plate stage 210 to move relative to the blanket stamp 410, 260d.

When the four-stage unit alignment units 260a to 260d are arranged in the four corners of the printing plate stage 210, the blanket stamp 410 is supported by the printing plate stage 210 The printing plate stage 210 is not moved in any direction even if the pressing force is high. That is, it is possible to prevent the printing plate stage 210 from being pushed by the blanket stamp 410.

Further, the printing plate stage 210 itself can be finely moved easily and efficiently in the X-axis, the Y-axis, and the axial direction.

Hereinafter, for convenience of explanation, each of the four-stage unit alignment units 260a to 260d is divided into first to fourth-stage unit alignment units 260a to 260d along the counterclockwise direction with reference to the area A in FIG. 9, .

Each of the first to fourth stage alignment units 260a to 260d includes first to fourth drive motors 261a to 261d and first to fourth drive motors 261a to 261d, First through fourth ball screws 262a through 262d rotatable in forward and reverse directions by the four drive motors 261a through 261d and first through fourth ball screws 262a through 262d through the first through fourth ball screws 262a through 262d, First to fourth rotation supporting portions 267a to 267d provided on the opposite sides of the first to fourth driving motors 261a to 261d for rotatably supporting the ends of the first to fourth ball screws 262a to 262d, The first to fourth ball screws 262a to 262d and the first to fourth ball screws 262a to 262d which are movable along the longitudinal direction of the first to fourth ball screws 262a to 262d during rotation of the first to fourth ball screws 262a to 262d. 4 moving blocks 263a through 263d and the first through fourth moving blocks 263a through 263d and is freely movable in a direction intersecting the moving direction of the first through fourth moving blocks 263a through 263d First to fourth fixing blocks 264a to 264d fixed to the upper surface of the first to fourth intersecting blocks 264a to 264d and the lower surface of the printing plate stage 210, 265a-265d.

The first to fourth drive motors 261a to 261d are independently controlled by a control unit (not shown). That is, when the degree to which the printing plate 20 (M) vacuum-attracted on the printing plate stage 210 with respect to the blanket stamp 410 is deflected in the X-axis, the Y-axis, and the axial direction is calculated, The driving motors 261a to 261d are independently controlled to move the printing plate stage 210 through the movement of the first to fourth moving blocks 263a to 263d and the first to fourth intersecting blocks 264a to 264d .

For stable movement of the first to fourth moving blocks 263a to 263d, a plurality of first to fourth moving blocks 263a to 263d for guiding the movement of the first to fourth moving blocks 263a to 263d are formed on the upper surface of the stage supporting frame 231, And guide rails 266a through 266d are provided.

Accordingly, the first to fourth moving blocks 263a to 263d, which move along the longitudinal direction of the first to fourth ball screws 262a to 262d by the rotation of the first to fourth ball screws 262a to 262d, The first to fourth guide rails 266a to 266d can be stably moved along the first to fourth guide rails 266a to 266d.

As described above, the first to fourth moving blocks 263a to 263d are moved by the operation of the first to fourth driving motors 261a to 261d. However, unlike the first to fourth moving blocks 263a to 263d, the first to fourth intersecting blocks 264a to 264d are freely moved on the first to fourth moving blocks 263a to 263d.

To this end, as shown in Figs. 10 and 11, a plurality of protrusions 269a protruding upward from the upper surface of the first moving block 263a and having a through hole 268a formed therein, Is further movably coupled to the projection 269a to pass through the first intersection block 268a and is further provided with a movement axis 270 at least a portion of which is fixed to the first intersection block 264a.

Through this structure, the first intersection block 264a can freely move along the longitudinal direction of the moving shaft 270 from the upper surface of the first moving block 263a.

As shown in Figs. 10 and 11, the projections 269a and the moving shafts 270 are respectively provided in the second to fourth stage arranging units 260b to 260d in addition to the first stage arranging unit 260a The detailed description of the second to fourth stage arranging units 260b to 260d will be omitted for the sake of convenience.

The printing plate stage 210 can be more stably supported by arranging the first to fourth stage unit alignment units 260a to 260d in a rectangular shape in the four corners of the printing plate stage support frame 231. [

However, since the printing plate stage 210 must be moved in the X-axis, the Y-axis, and the axial direction as necessary for the alignment operation of the printing plate 20 (M) with respect to the blanket stamp 410, The arrangement direction of each of the portions 260a to 260d also functions as an important element.

In this embodiment, the first through fourth ball screws (260a through 260d) formed in the first through fourth unit alignment units 260a through 260d, respectively, so as to move the printing plate stage 210 in the X axis, Y axis, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, 262d, And the first to fourth drive motors 261a to 261d provided in the first and second drive motors 261a to 261d are positioned opposite to each other.

This structural feature allows the printing plate stage 210 to be easily moved in the X-, Y-, and axial directions (see FIGS. 12-14), thereby allowing more efficient alignment of the blanket stamp 410 . ≪ / RTI >

Hereinafter, the alignment operation of the printing plate 20 with respect to the blanket stamp 410 based on the primary alignment marks P1 and secondary alignment marks P2 on the printing plate 20 photographed by the alignment vision unit will be described As follows.

12, when the printing plate stage 210 is to be moved a predetermined distance in the right (X-axis) direction, the control unit operates the first and third driving motors 261a and 261c to drive the first and third The ball screws 262a and 262c are rotated in one direction. At this time, the second and fourth drive motors 261b and 261d are not operated.

Therefore, the first and third moving blocks 263a and 263c coupled to the first and third ball screws 262a and 262c are moved along the first to third guide rails 266a and 266c under the first and third ball screws 262a and 262c, respectively, And is moved in the right (X-axis) direction as shown.

At this time, although the first and third moving blocks 263a and 263c and the second and fourth moving blocks 263b and 263d located in the diagonal direction are fixed, the upper and the lower ends of the second and fourth moving blocks 263b and 263d The second and fourth intersection blocks 264b and 264d provided on the first and second movable blocks 263b and 263d move freely to the right.

By such a series of operations, the printing plate stage 210 is moved in the right (X-axis) direction as shown in Fig.

13, when the printing plate stage 210 is to be moved a predetermined distance in the upward direction (Y-axis direction), the control unit operates the second and fourth driving motors 261b and 261d, And the fourth ball screws 262b and 262d are rotated in one direction. At this time, the first and third drive motors 261a and 261c are not operated.

Therefore, the second and fourth moving blocks 263b and 263d coupled to the second and fourth ball screws 262b and 262d are moved along the second to fourth guide rails 266b and 266d, respectively, (Y axis) direction as shown in the figure.

At this time, the first and third moving blocks 263a and 263c positioned in the diagonal direction from the second and fourth moving blocks 263b and 263d are fixed, but the upper and lower ends of the first and third moving blocks 263a and 263c The first and third intersection blocks 264a and 264c provided on the first and third moving blocks 263a and 263c move freely upward.

By this series of operations, the printing plate stage 210 is moved in the upper side (Y axis) direction as shown in Fig.

14, when the printing plate stage 210 is rotated clockwise by a predetermined angle, the control unit operates all of the first to fourth driving motors 261a to 261d.

When the first to fourth driving motors 261a to 261d are operated, the first to fourth moving blocks 263a to 263d are driven by the first to fourth ball screws 262a to 262d rotating in one direction And the first to fourth intersecting blocks 263a to 263d are freely moved in the corresponding directions on the first to fourth moving blocks 263a to 263d so that as shown in Figure 14, The stage 210 can be rotated clockwise by a predetermined angle. As such, the rotating operation of the printing plate stage 210 as in Fig. 14 can be realized by appropriately combining the operations of Figs. 12 and 13. Fig.

The blanket stamp 410 is moved relative to the blanket stamp 410 to align the blanket stamp 410 with the printing plate 20 and the blanket stamp 410 is pressed against the printing plate 20, The patterned printing liquid 30 is left in the blanket stamp 410 while leaving the unnecessary printing liquid 30 left.

Next, the workpiece stage unit 100 includes a workpiece stage (not shown) for supporting the substrate 10 on the upper surface thereof so that the printing operation can be performed on the substrate 10 by the blanket stamp 410, A workpiece stage alignment unit (not shown) coupled to a lower portion of the workpiece stage alignment unit to support the workpiece stage in a plate direction so as to align the position of the workpiece stage with respect to the blanket stamp 410, And a work stage support portion (not shown) provided in the lower region to support the work stage alignment portion.

When the blanket stamp 410 contacts the printing plate 20, the printing liquid 20 corresponding to the engraved pattern M formed on the printing plate 20 is formed on the printing plate 20, 30 remain in the blanket stamp 410.

When the printing plate stage 210 returns to the initial position, the workpiece stage moves from the initial position to the blanket stamp 410 side so that the blanket stamp 410 contacts the substrate 10 on the workpiece stage, Respectively. Alignment of the substrate 10 on the workpiece stage with respect to the blanket stamp 410 must also be performed. This role is handled by a work stage alignment unit (not shown).

The workpiece stage, the workpiece stage moving unit, and the workpiece stage aligner are the same as those of the printing plate stage 210, the printing plate stage moving unit 230, and the printing plate stage aligning unit 250, and will not be described below.

Hereinafter, a printing process using the pad printing apparatus 1 according to an embodiment of the present invention will be described.

FIG. 14 is a flow chart illustrating a printing process according to an embodiment of the present invention. A printing process using the pad printing apparatus 1 according to an embodiment of the present invention will be described with reference to the drawings and FIGS. 1 to 13 together.

First, the coating module 500 applies the printing liquid 30 to the blanket sheet 412 of the blanket stamp 410.

Then, when the printing plate stage 210 moves from the initial position to the pad printing unit 300 and reaches the printing position, the printing liquid 30 is applied and the rotated blanket sheet 412 is transferred from the upper side of the printing plate 20 to the printing plate stage The blanket sheet 412 and the printing plate stage 210 are aligned by the alignment part. The blanket sheet 412 is lowered by the stamp pressing portion 430 and the blanket stamp 410 is contacted to the printing plate 20 loaded on the printing plate stage 210.

When the blanket sheet 412 is pressed against the printing plate 20 and then the blanket sheet 412 is separated upward from the printing plate 20, The printing liquid 30 of the printing plate 412 remains and the printing liquid 30 remains on the portion corresponding to the negative electrode pattern M of the printing plate 20 on the blanket sheet 412, do.

Then, the printing plate stage 210 is moved to the initial position, and the work stage is loaded onto the upper surface of the workpiece stage, and the substrate 10, which is supported on the upper surface of the workpiece stage, (300) side to reach the printing position.

The blanket sheet 412 of the blanket stamp 410 is then aligned with the blanket sheet 412 and the printing plate stage 210 by the printing plate stage alignment portion 820 at the top of the substrate 10.

The blanket sheet 412 is lowered in the direction of the substrate 10 by the stamp pressing portion 430 to press the blanket sheet 412 against the substrate 10 and then press the blanket sheet 412 against the substrate 10. [ So as to finally form a pattern on the substrate 10.

Air is injected into the pressurizing chamber 419 and the central area of the blanket sheet 412 protrudes so that the blanket sheet 412 is pressed against the printing plate 20 or the substrate 10 The blanket sheet 412 is brought into contact with the central area of the blanket sheet 412 and the working accuracy and flatness of the stamp body 411 and the blanket sheet 412 and the printing plate 20 or the substrate 10 are buffered It is possible to apply a uniform pressure to the printing plate 20 or the substrate 10.

The pad printing apparatus 1 having the flat-type blanket stamp 410 that can be elastically deformed according to the present embodiment and implementing the reverse offset printing method can be applied to the pad printing apparatus 1 in which the roll driving synchronization is unnecessary The printing accuracy can be improved without departing from the driving synchronization accuracy.

In addition, when replacing the blanket sheet 412 in the form of a conventional blanket roll, it takes a long time to perform a complicated operation to attach a predetermined tension to the blanket sheet 412, but the blanket stamp 410 itself can be easily removed and replaced in a short time.

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.

1: Pad printing apparatus 100: Workpiece stage unit
200: printing plate stage unit 230: printing plate stage moving unit
300: Pad printing unit 400: Printing module
410: Blanket stamp 411: Stamp body
412: blanket sheet 413: blanket sheet support
414: O-ring 415: Seat tension adjusting unit
416: tension applying body 417: guide body
418: air supply part 419: pressure chamber
420: print frame 430: stamp presser
440: Stamp rotation part 450: Lower limit
500: Coating module

Claims (15)

A work stage unit for supporting the substrate for a printing operation for forming a pattern on the substrate;
A printing plate stage unit for supporting a printing plate on which a circular pattern for forming the pattern is formed; And
A printing module having a blanket stamp which contacts the printing plate to transfer the circular pattern of the printing plate and contacts the substrate to form the pattern on the substrate, the blanket stamp being elastically deformed upon contact with the printing plate or the substrate; And a coating module for coating a printing liquid on the printing medium,
Wherein the blanket stamp comprises:
A stamp body forming a body;
A blanket sheet to which the printing liquid is applied;
A blanket sheet support for supporting the blanket sheet in contact with the stamp body to form a pressurizing chamber having a space therein; And
And an air supply unit for supplying air to the pressure chamber. The method according to claim 1,
Wherein the circular pattern is an engraved pattern for the pattern of the substrate,
Wherein the blanket stamp is in contact with the printing plate in a state in which the printing liquid is coated and contacts the substrate in a state in which the printing liquid remains only in a pattern corresponding to the engraved pattern of the printing plate, . delete The method according to claim 1,
Wherein the blanket stamp comprises:
Wherein the stamp body has a predetermined recessed shape,
The central region of the blanket sheet support is thinner than both end regions,
And an O-ring for sealing is coupled between the stamp body and the blanket sheet support. The method according to claim 1,
Wherein the blanket stamp further comprises a sheet tension regulator for regulating the tension of the blanket sheet. delete The method according to claim 1,
Wherein the printing module further comprises a stamp pressing portion for pressing the blanket stamp to the substrate or the printing plate. 8. The method of claim 7,
Wherein the printing module further comprises a stamp rotating portion coupled to the blanket stamp to rotate the blanket stamp. 9. The method of claim 8,
Wherein the stamp rotating portion includes a stamp rotating shaft to which the blanket stamp is engaged,
Wherein the blanket stamp is provided symmetrically with respect to the stamp rotation axis. 10. The method of claim 9,
Wherein the printing module further comprises a printing frame forming a frame,
The stamp rotation unit includes:
A rotating motor to which the stamp rotating shaft is coupled; And
Further comprising a rotating part case coupled to the rotating motor and coupled to the printing frame,
And the stamp pressing portion is coupled to the rotating portion case to move the rotating portion case to press the blanket stamp. 11. The method of claim 10,
The printing module includes:
And a lower limit coupled to the print frame to limit the lower movement of the blanket stamp to a predetermined area. The method according to claim 1,
The coating module comprises:
A thin film cap for applying a printing liquid to the blanket stamp; And
And a movable engaging portion for relatively moving the thin film embossment with respect to the blanket stamp. The method according to claim 1,
The printing plate stage unit includes:
A printing plate stage on which the printing plate is seated; And
And a printing plate stage moving unit connected to a lower portion of the printing plate stage to support the printing plate stage and move the printing plate stage. 14. The method of claim 13,
Wherein the stage moving unit comprises:
A stage support frame disposed at a lower portion of the printing plate stage and supporting the printing plate stage;
A moving rail disposed long in the direction of the pad printing unit; And
And a movement driving unit connected to the stage support frame and moving the stage support frame along the movement rail. 15. The method of claim 14,
The movement drive unit may include:
A ball screw disposed along the moving rail, the ball screw coupled to the stage support frame; And
And a drive motor coupled to the ball screw and rotating the ball screw in forward and reverse directions to reciprocate the stage support frame along the movement rail.

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