KR20150007095A - Glass remover - Google Patents

Abstract

A remover for display glass is disclosed. According to an embodiment of the present invention, the remover for display glass comprises: a glass gripping unit which grips glass to be removed from a film (EL) used in a process; multiple inclination separating units which are separated from one another in order to separate the film from the glass along with the glass gripping unit while transferring the film slantly to the glass at a predetermined angle; and multiple vacuum stages which are placed between the multiple inclination separating units in order to adsorb the film using vacuum pressure.

Description

[0001] Glass remover for display [

The present invention relates to a glass removing apparatus for a display, and more particularly, to a glass removing apparatus for a display which can easily and efficiently remove glass from a film without damaging the film.

Generally, a display device refers to a device for displaying output information in a computer or the like in characters or graphics. Here, the display device includes a cathode ray tube (CRT), a flat panel display (FPD), and the like. In recent years, a flexible display is provided in a display device. On the other hand, a flat panel display (FPD) is thinner and lighter than a cathode ray tube (CRT), which has been used mainly as a display in a TV or a computer monitor.

Here, the display includes a liquid crystal display (LCD), a plasma display panel (PDP), an organic light emitting diode (OLED), and the like. .

1 and 2 are operation diagrams of a general glass substrate film removing apparatus.

The apparatus for removing a film on a glass substrate shown in these figures is a device for removing a protective film for protecting the surface of a glass substrate from a glass substrate by using a rotary vacuum roll 10. The glass substrate at this time may be the LCD or PDP substrate described above.

2, the rotary vacuum roll 10 is rotated in the direction of the arrow A and the glass substrate moves in the direction of the arrow B, The protective film adhered to the substrate can be removed.

At this time, since the protective film removed from the glass substrate is not a problem even if it is damaged, the rotary vacuum roll 10 can be used and the protective film can be removed at a high speed.

However, unlike the LCD or PDP substrate used in FIGS. 1 and 2, in the case of an OLED substrate to be applied to an OLED flexible cell, a film (EL) is used and a glass is removed Therefore, the film should not be damaged when the glass is removed.

However, if the vacuum roll 10 shown in FIGS. 1 and 2 is used to use the film while removing the glass from such an OLED substrate, the glass-free film is formed on the surface of the vacuum roll 10 along the surface The film may be damaged because the film is curved while coming out.

In order to prevent the film from being damaged, it is necessary to use a vacuum roll having a large size (not shown). In this case, there is a problem that marks are left on the film by the vacuum holes formed in the vacuum roll.

Therefore, when the film is to be used while removing the glass from the substrate for OLED, it is difficult to apply the device of FIGS. 1 and 2 as it is.

As an alternative to this, it is possible to consider the technique of removing the glass while holding the center of the glass after the glass is adsorbed in vacuum, lifting the edge of the glass, and so on. However, A static electricity is generated between the glass and the PI layer of the flexible cell to cause damage to the film, so that it is difficult to apply and a new alternative is required.

Korean Patent Publication No. 10-2004-0021855 (Open date: March 11, 2004)

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a glass removing apparatus for a display which can easily and efficiently remove glass from a film without damaging the film.

According to an aspect of the present invention, a glass grasping unit for grasping a glass to be removed from a film (EL) used in a process; A plurality of slant separating units separated from the glass with the glass holding unit while slipping the film at a predetermined angle relative to the glass; And a plurality of vacuum stages, each of which is disposed between the plurality of slant separating units, and which adsorbs the film by vacuum pressure, may be provided.

The vacuum stage may further include: a pore-forming portion in which a plurality of pores are formed; A body portion connected to the pore forming portion; And a vacuum pump connected to the inside of the body part and discharging air to the outside through the pore forming part.

Each of the plurality of slant separating units includes a straight line section in which the glass holding unit is operated to grip the glass, and the glass and the film are linearly moved together; And a slope section inclined by a predetermined angle with respect to the straight line section and the film from which the glass is removed is moved independently.

The apparatus may further include a vacuum stage movement guide unit on which the vacuum stage is mounted and movable along the slope section.

The vacuum stage moving guide unit may include: a seating part on which the vacuum stage is seated; A rail body to which the seat portion is movably engaged; And a power transmission part connected to the seating part and transmitting the power so that the seating part is movable along the rail body.

Further, the vacuum stage moving guide unit may be provided with an LM guide.

And a film peeling unit inserted between the film and the glass to peel the film against the glass.

The film peeling unit may further include a front peeling unit disposed at a front end of the film and the glass with reference to a feeding direction of the tilting and separating unit, a side peeling unit disposed at a side of the film and the glass, And a rear end peeling unit disposed at a rear end of the glass.

The shear peeling unit includes: a shear film peeling blade inserted between the film and the glass at a front end of the film and the glass; And a front end blade supporting part coupled to the glass holding unit and movably supporting the front end film peeling blade.

The side edge peeling unit may include: a side film peeling blade provided so as to be rotatable so as to be inserted between the film peeled by the peeling unit and the glass; And a side end blade supporting portion for rotatably supporting the side film separating blade.

The shear peeling unit peels off the film and the glass from the front end of the film and the glass so as to be peeled from the side edge of the film and the glass through the peeled gap between the film and the glass, The peeling unit can be disposed close to the position at a point where the shearing peeling unit starts to peel the film from the glass.

The posterior peeling unit may include: a posterior film peeling blade inserted between the film and the glass at a rear end of the film; And a rear end blade supporting part coupled to the glass holding unit and movably supporting the rear film peeling blade.

The rear-end peeling unit may include an X-axis feeder for feeding the rear-end film peeling blade in the X-axis direction crossing the feeding direction of the slant separating unit; A Y-axis feeder for feeding the rear film peeling blade in the Y-axis direction, which is the feeding direction of the tilter separating unit; And a Z-axis transporting unit for transporting the rear film peeling-off blade in the vertical Z-axis direction.

Further, the inclined separation unit may be provided as a Poros tilting conveyor for porous glass separation.

Embodiments of the present invention have the effect of easily and efficiently removing glass from a film without damaging the film.

1 and 2 are operation diagrams of a general glass substrate film removing apparatus.
3 is a side view of a glass removing apparatus for a display according to a first embodiment of the present invention.
4 is a perspective view of a degassing unit and a vacuum stage in a glass removing apparatus for a display according to a first embodiment of the present invention.
5 is a partially enlarged perspective view of Fig.
6 is a partially exploded perspective view of a Foros tilting conveyor for glass separation in a glass removing device for a display according to a first embodiment of the present invention.
Figs. 7 to 9 are views showing steps of the respective operations of the glass removal device for a display according to the first embodiment of the present invention.
10 is a plan view of a front end peeling unit and a rear end peeling unit in a glass removing apparatus for a display according to a second embodiment of the present invention.
11 is a perspective view of a side-end peeling unit in a glass removing apparatus for a display according to a second embodiment of the present invention.
12 is a side view of a rear end peeling unit in a glass removing apparatus for a display according to a second embodiment of the present invention.
FIG. 13 is an enlarged view of the area B in FIG. 12, showing a state in which the film and the glass are peeled off by the rear film peeling blade.

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.

FIG. 3 is a side view of a glass removing apparatus for a display according to a first embodiment of the present invention, FIG. 4 is a perspective view of an inclined separating unit and a vacuum stage in a glass removing apparatus for a display according to a first embodiment of the present invention FIG. 5 is a partially enlarged perspective view of FIG. 3, FIG. 6 is a partially exploded perspective view of a Foros tilting conveyor for glass separation in a glass removing device for a display according to a first embodiment of the present invention, 1 is a view showing steps of each operation of a glass removing device for a display according to a first embodiment of the present invention.

As shown in these drawings, the glass separator for a display 100 according to the present embodiment includes a glass holding unit 200 for holding a glass 800 to be removed from a film 700, EL used in the process, The film 700 is separated from the glass 800 together with the glass grasping unit 200 while the film 700 is inclined with respect to the glass 800 at a predetermined angle and a plurality of inclined separations Unit 300 and a plurality of vacuum stages 400 disposed between the plurality of slant separating units 300 for sucking the film 700 by vacuum pressure.

3 and 5, the glass grasping unit 200 serves to grasp the glass 800 forming the upper layer on the work line where the glass 800 and the film 700 are bonded and transported. The glass holding unit 200 grips the glass 800 by a vacuum suction method.

Here, the glass gripping unit 200 includes a glass gripping member 210 for gripping and gripping the glass 800, and transfers 231, 232, and 233 connected to the glass gripping member 210 and for moving the glass gripping member 210 .

The glass holding member 210 is capable of gripping the glass 800 by vacuum and may have a plurality of suction nozzles 220 for suctioning the glass 800 by vacuum pressure.

Here, the plurality of adsorption nozzles 220 are components that substantially adsorb the glass 800, and one or more adsorption nozzles 220 may be disposed.

The transfers 231, 232, and 233 serve to move the glass holding member 210 holding the glass 800.

These transfers 231, 232 and 233 include a Z-axis transfer 233 for moving the glass holding member 210 to the Z-axis (see FIGS. 3 and 5) in the vertical direction with respect to the tilter separation unit 300, A Y-axis transfer 232 for moving the Y-axis transfer unit 210 to the Y-axis (see FIG. 5) in the conveying direction of the inclined separation unit 300 and an X-axis transfer And an X-axis transfer 231 for moving the glass holding member 210.

The transfers 231, 232, and 233 can be provided to be operable by a cylinder, a linear motor, or the like.

3 to 5, the slant separating unit 300 serves to slant the film 700 to the glass 800 at a predetermined angle.

In other words, by moving the glass holding unit 200 in a direction inclined by suction of the film 700 by the vacuum pressure, the slant separating unit 300 interlocks with the glass holding unit 200 to move the glass 800, The glass 800 can be easily removed.

Here, the plurality of slant separating units 300 may be arranged in a row, and a vacuum stage 400 is disposed between each of the plurality of slant separating units 300.

That is, the film 700 is attracted to the vacuum stage 400 as well as the inclined separation unit 300 by the vacuum pressure. A detailed description of the vacuum stage 400 will be given later.

If either one of the glass holding unit 200 and the slant separating unit 300 is too fast or too late to remove the glass 800 properly, And the slant separating unit 300 must be synchronously driven by a control unit (not shown).

This can be implemented in such a manner that the control unit adjusts the moving speed of the slant separating unit 300 to the transfers 231, 232, 233, or conversely, the moving speed of the transferring units 231, 232, 233 to the slant separating unit 300.

Meanwhile, in this embodiment, the inclined separation unit 300 may be provided with a porous glass separating porosity inclined conveyor 300a (see FIG. 6). That is, the inclined separation unit 300 is applied as a conveyor in which a vacuum is formed. However, the scope of the present invention is not limited to these matters.

Here, since the glass separating Poros tilting conveyor 300a has to transport the film while sucking the film by vacuum, a vacuum structure is applied to the glass separating poros tilting conveyor 300a.

6, a plurality of vacuum holes 331 are formed on the surface of the glass separating porosity oblique conveyor 300a, and the film is supported by the vacuum pressure formed in the vacuum hole 331 And a vacuum chamber 340 formed at a lower portion of the porous conveyance belt 330. The porous conveyance belt 330 includes a porous conveyance belt 330,

A vacuum slot 341 communicating with the plurality of vacuum holes 331 formed in the porous conveyance belt 330 is formed on the upper surface of the vacuum chamber 340.

Here, the vacuum chamber 340 is a portion fixed to the lower region of the apparatus, while the porous conveyance belt 330 substantially contacts the film to transfer the film. The porous conveyance belt 330 may be relatively movably coupled to the vacuum chamber 340 in the upper part of the vacuum chamber 340 along the conveying direction of the film.

With this structure, the inclined separation unit 300 provided with the Porous inclined conveyor 300a for separating glass for glass can adsorb the film 700 by the vacuum pressure.

3 to 5, each of the plurality of slope separating units 300 is operated such that the glass holding unit 200 is operated to grip the glass 800, and the glass 800 and the film 700 are linearly moved together And a slope section 320 which is inclined at a predetermined angle with respect to the straight line section 310 and in which the film 700 from which the glass 800 has been removed is moved independently.

Since the linear section 310 and the slant section 320 are provided in the slant separating unit 300 so that the glass holding unit 200 grasps the glass 800 from the linear section 310, Only the film 700 from which the glass 800 has been removed can be transported from the side 320.

Therefore, the glass 800 can be easily and easily removed from the film 700 without using the conventional structure shown in FIGS. 1 and 2. In particular, when the glass 800 is removed, It is possible to prevent the film 700 from being damaged.

On the other hand, it is possible to consider various situations, for example, when the vacuum is leaked from the inclined separation unit 300, or when the glass 800 and the film 700 are strongly adhered beyond a predetermined range, In such an operating environment, it may not be easy to separate the film 700 and the glass 800.

In order to easily peel off the film 700 and the glass 800 even in such a variety of situations, the glass removing apparatus 100 for a display according to the first embodiment of the present invention may further include a vacuum stage 400.

5, the vacuum stage 400 is disposed between a plurality of the slant separating units 300 and adsorbs the film 700 by vacuum pressure. Particularly, the vacuum stage 400 includes a slant separating unit 300, And may be disposed in the inclined section 320 in the display unit 300.

Although the vacuum stage 400 may not be disposed in the section where the film 700 and the glass 800 are moved in the linear section 310, The vacuum stage 400 is moved to the inclined section 320 for easy separation or separation of the film 700 and the glass 800 since the film 700 and the glass 800 start to be separated from each other, (800).

4, the vacuum stage 400 may include a pore forming part 410, a body part 420, and a vacuum pump (not shown).

The pore forming part 410 is provided on the upper side of the vacuum stage 400 to form a pore 411. Here, the pore 411 is a hole formed to allow air to flow, Air is exhausted through the pore forming portion 410 provided on the upper side of the vacuum stage 400.

The body portion 420 is connected to the pore forming portion 410 at the lower side of the pore forming portion 410 to form the body of the vacuum stage 400.

A vacuum pump (not shown) is connected to the inside of the body part 420 and sucks air so that air can be discharged to the outside through the pore forming part 410. That is, when the vacuum pump (not shown) is operated, the air existing between the film 700 and the pore forming portion 410 flows into the body portion 420 through the pore forming portion 410, do.

Thus, a vacuum pressure lower than the atmospheric pressure is formed in the pore forming portion 410, and the film 700 is adsorbed to the pore forming portion 410 and can be peeled from the glass 800.

Here, the vacuum stage 400 is disposed in the inclined section 320 and may be provided to move along the inclined section 320 (see arrows in FIG. 4).

That is, after the vacuum stage 400 is disposed at the start point of the inclined section 320 to initially peel the glass 800 and the film 700, the vacuum stage 400 continues along the inclined section 320 If the film 700 is adsorbed while moving, the glass 800 can be more easily separated from the film 700 without damaging the film 700.

When the vacuum stage 400 reaches the end of the inclined section 320 and the separation of the glass 800 and the film 700 is completed, the vacuum stage 400 is moved to the starting point of the inclined section 320 Return.

Here, when the vacuum stage 400 continues to move along the inclined section 320 and adsorbs the film 700, for example, even when the vacuum is leaked from the inclined separation unit 300, The film 700 can be separated from the film 700.

The vacuum degassing apparatus 100 may be provided with a vacuum stage moving guide unit 500 and the vacuum stage 400 may be mounted on the vacuum stage moving guide unit 500 Can be seated.

7 and 8, the vacuum stage moving guide unit 500 is movable along the inclined section 320. Since the vacuum stage 400 is seated on the vacuum stage moving guide unit 500, The vacuum stage 400 moves along the inclined section 320 when the vacuum stage moving guide unit 500 is moved.

Here, the vacuum stage moving guide unit 500 may include a seat portion 510, a rail main body 520, and a power transmitting portion 530.

The seating part 510 may be provided in a shape corresponding to the lower shape of the vacuum stage 400 and may be fixed or supported after the vacuum stage 400 is seated, (Not shown) or a support (not shown).

The rail main body 520 may include a rail to which the seating portion 510 is movably coupled and the seating portion 510 is coupled to the upper portion of the rail main body 520, .

The power transmission unit 530 is connected to the seating unit 510 to transmit power to the seating unit 510. The power transmission unit 530 includes various motors (not shown) And various connecting units for transmitting the rotational force of the motor.

The vacuum stage moving guide unit 500 may be provided as an LM guide unit. In this case, the vacuum stage 400 is coupled to the LM guide unit and moves along the inclined section 320, So that it can be adsorbed.

Hereinafter, the operation and effect of easily and efficiently removing the glass 800 from the film 700 without damaging the film 700 by the glass removing apparatus 100 for a display according to the first embodiment of the present invention will be described do.

7, a film 700 to which the glass 800 is adhered to the upper layer is conveyed in a state of being adsorbed along the linear section 310 of each of the plurality of the slope separation units 300.

When the film 700 reaches the working position for removal of the glass 800, the glass gripping unit 200 is operated by the transfers 231, 232 and 233 and then the glass gripping member 210 of the glass gripping unit 200 The glass 800 is gripped by vacuum.

At this time, the pressing unit (not shown) provided on the glass holding unit 200 can press the film 700, and the front surface of the film 700 is attracted to the surface of the tilting and separating unit 300 The glass holding unit 200 adsorbs the glass 800, whereby the failure of adsorption can be reduced.

Referring to FIG. 5, an ionizer 900 may be further disposed adjacent to the inclined separator unit 300 for ejecting the electrostatic discharge preventing fluid toward the glass, according to the present embodiment.

The ionizer 900 prevents static electricity from being generated between the glass and the PI layer of the flexible cell by injecting a static electricity generation preventing fluid toward the film and the glass during the operation of removing the glass from the film. The ionizer 900 is disposed on both sides of the inclined separating unit 300 and is capable of ejecting the electrostatic discharge preventing fluid to both sides of the glass.

On the other hand, even if the glass holding unit 200 holds the glass 800, since each of the plurality of the slant separating units 300 continuously moves the film 700, the glass holding unit 200 is moved to the glass 800 And the operation of moving the film 700 in the inclined direction in the inclined section 320 of each of the plurality of slant separation units 300 proceeds from the film 700 to the glass 800, Lt; / RTI >

8, the vacuum stage 400 is disposed in the inclined section 320 of the plurality of the slant separating units 300, and the glass 700 is moved from the glass 800 The film 700 can be sufficiently separated and the film 700 is adsorbed while moving along the inclined section 320 after the vacuum stage 400 is mounted on the vacuum stage moving guide unit 500, There is an effect that the glass 800 can be more easily and efficiently separated from the film 700 without damaging the film 700. [

Here, a film conveying conveyor (not shown) may be provided behind the inclined separating unit 300 to convey the film 700, which is connected to the inclined separating unit 300 to remove the glass. A glass loading part (not shown) on which the glass 800 removed from the film 700 is loaded may be provided around the film transfer conveyor (not shown).

9, after the glass is completely removed from the film, the glass holding unit 200 is returned to the original position after the glass 800 is loaded by the glass loading unit (not shown) by the transfers 231, 232, and 233 , The glass-free film 700 is conveyed to a post-process along a film transfer conveyor (not shown).

On the other hand, a shuttle (not shown) capable of vertically driving is disposed on the front portion of the slant separating unit 300, and a pickup unit (not shown) is provided on the front of the shuttle (not shown).

10 is a plan view of a front end peeling unit and a rear end peeling unit in a glass removing device for a display according to a second embodiment of the present invention, 12 is a side view of the rear end peeling unit in the glass removing apparatus for a display according to the second embodiment of the present invention. FIG. 13 is an enlarged view of the region B in FIG. 12, And the film and the glass are peeled off by the blade.

As shown in these drawings, the glass-removing device for a display 100 according to the second embodiment of the present invention includes a glass holding unit 200, a slant separating unit 300, a vacuum stage 400, Unit 600 as shown in FIG.

Here, the same parts as those of the glass removal device for a display 100 according to the first embodiment of the present invention among the glass removal devices 100 for a display according to the second embodiment of the present invention will be replaced with the above description, Hereinafter, the difference will be described.

In other words, the detailed structure of the glass holding unit 200 and the slant separating unit 300 will be referred to as the description of the above embodiment, and redundant description thereof will be omitted here.

10 to 13, the film peeling unit 600 is inserted between the film 700 and the glass 800, and serves to peel the film 700 against the glass 800. As shown in FIG.

The film peeling unit 600 may be configured to include at least one of a front end peeling unit 610, a side end peeling unit 620, and a rear peeling unit 630. However, the shear peeling unit 610 is preferably included for the initial peeling of the glass 800 and the film 700, but the scope of the present invention is not limited thereto.

10, the shearing peeling unit 610 is disposed at the front end of the film 700 and the glass 800 and is disposed between the film 700 and the glass 800 at the front end of the film 700 and the glass 800. [ And a shearing blade supporting portion 612 coupled to the glass holding unit 200 and movably supporting the shearing film separating blade 611. [

That is, the shearing film separating blade 611 is inserted between the film 700 and the glass 800 substantially at the front end of the glass 800 and inserted between the film 700 and the glass 800 So that the initial delamination between the film 700 and the glass 800 proceeds.

Considering that the initial peeling between the film 700 and the glass 800 may not be performed well when the surface tension between the film 700 and the glass 800 is large, When the tip of the peeling blade 611 is inserted between the film 700 and the glass 800 and moved, the initial peeling between the film 700 and the glass 800 can be progressed well by the physical force.

The shearing blade supporting portion 612 is a portion for movably supporting the shearing film separating blade 611 and the shearing blade supporting portion 612 is provided so as to be movable in the X axis, the Y axis, and the Z axis.

Here, the front end blade supporting portion 612 moves in at least one of the X axis, the Y axis, and the Z axis so that the front end of the shearing film peeling blade 611 is disposed in front of the film 700 and the glass 800 The front end of the shear film peeling blade 611 enters between the film 700 and the glass 800 and then the film 700 and the glass 800 are driven by the driving of the shearing film peeling blade 611, The entire area of the front side is initially peeled off.

Since the operation of the shear peeling unit 610 is the same as that of the subsequent peeling unit 630 described below, the detailed operation of the shearing peeling unit 610 will be described with reference to the operation of the peeling unit 630 I will replace it with explanation.

11, the side-edge peeling unit 620 is disposed on the side of the film 700 and the glass 800, and the film 700 and the glass 800, which are initially peeled off by the front-end peeling unit 610, A side edge film separating blade 621 provided so as to be rotatable to be inserted between the side edge film separating blade 621 and a side edge blade supporting section 622 which rotatably supports the edge film separating blade 621.

That is, after the shear peeling unit 610 has performed the initial peeling at the front end of the film 700 and the glass 800, the side end film peeling blade 621 is peeled from the left and right ends of the film 700 and the glass 800 The film 700 and the glass 800 are peeled off.

11, the side edge film separating blade 621 connected to and supported by the side edge blade supporting portion 622 has a gap between the film 700 separated by the front edge separating unit 610 and the glass 800 As shown in FIG.

When the glass holding unit 200 and the slant separating unit 300 continue to move the film 700 by the side edge film separating blade 621 inserted into the side between the film 700 and the glass 800, Can be separated from the glass 800 more smoothly.

The side-edge peeling unit 620 can be disposed close to the position at which the front-end peeling unit 610 starts to peel the film 700 and the glass 800. [ That is, the shear peeling unit 610 moves along the X axis at the front end of the film 700 and the glass 800, and the entire region of the front side of the film 700 and the glass 800 is initially peeled off.

The side edge film peeling blade 621 is inserted after the side edge film peeling blade 621 is pushed toward the initially peeled gap of the film 700 and the glass 800 by the shearing peeling unit 610, It should be in a position where it can be inserted into the initially peeled gap of the film 700 and the glass 800 when the side film separating blade 621 is rotated.

The shear peeling unit 610 is positioned at the point where the front ends of the film 700 and the glass 800 start to peel off the film 700 and the glass 800 through the X axis, the Y axis, and the Z axis The side edge peeling unit 620 is located close to the front edge peeling unit 610 and the film 700 is peeled from the film 800 through the peeled clearance between the film 700 and the glass 800, The glass 700 and the side edge of the glass 800 are peeled off.

12 and 13, the rear end peeling unit 630 is disposed at the rear end of the film 700 and the glass 800, and the film 700 and the rear end of the glass 800 at the rear end of the film 700 and the glass 800, And a rear end blade supporting portion 632 which is coupled to the glass holding unit 200 and movably supports the rear end film separating blade 631, have.

As described above, when the front end of the film 700 and the glass 800 are peeled off by the front end peeling unit 610, the side end film peeling blade 621 of the side end peeling unit 620 rotates, And the side edge of the glass 800 are peeled off.

The glass removing apparatus 100 for a display according to the second embodiment of the present invention includes a rear end peeling unit 630 to remove the film 700 and the glass 800 at a final point at which the film 700 and the glass 800 are peeled off. The rear end of the honeycomb structure 800 is peeled off, thereby enabling smooth and easy peeling.

More specifically, when the peeling of the glass 700 and the glass 800 proceeds in a predetermined range or more, the operation of the glass holding unit 200 and the slant separating unit 300 is stopped, 630 operate so that the rear film peeling blade 631 is inserted between the film 700 and the glass 800 at the rear end of the glass 800 (see FIGS. 12 and 13).

12, the rear end blade supporting portion 632 is a portion for movably supporting the rear end film separating blade 631. The rear end blade supporting portion 632 includes an X axis conveying portion 633 and a Y axis conveying portion 633. [ Axis, a Y-axis, and a Z-axis including a Z-axis transporting unit 634 and a Z-axis transporting unit 635. [

Here, the X-axis feeder 633 feeds the rear-end film stripping blade 631 in the X-axis direction that is the direction intersecting the feeding direction of the warp-separating unit 300, and the Y-axis feeding unit 634 feeds the rear- The Z-axis feeder 635 feeds the blade 631 in the Y-axis direction, which is the feeding direction of the slant separating unit 300, and the Z-axis feeding unit 635, in the Z-axis direction, which is the vertical direction.

That is, when the peeling process between the film 700 and the glass 800 proceeds in a predetermined range or more in a state where the glass 800 and the film 700 are respectively adsorbed to the glass holding unit 200 and the slope separating unit 300 The glass holding unit 200 and the inclined separation unit 300 are stopped.

At this time, the rear end blade supporting portion 632 is disposed at the rear end of the film 700 and the glass 800 as shown in FIG. 13 (a) by the Z-axis transporting portion 635.

13 (b), the rear film peeling blade 631 enters the space between the film 700 and the glass 800 due to the Y axis transporting portion 634, and then the X axis transporting portion 633 causes the film The entire area of the back side of the glass 700 and the glass 800 is peeled off.

When the film is reattached to the glass 800 due to the static electricity generated when the film 700 and the glass 800 are peeled off or when peeling is not easy due to the bond strength between the film and the glass 800 There is an effect that the Edo film 700 and the glass 800 can easily be peeled or separated.

Hereinafter, the operation and effect of the glass removing apparatus 100 for a display according to the second embodiment of the present invention will be described. However, a portion common to the display glass removing apparatus 100 according to the first embodiment of the present invention is replaced with the above description.

First, the film 700 to which the glass 800 is adhered to the upper layer is conveyed in a state of being adsorbed along the linear section 310 of each of the plurality of the slope separation units 300, (700) can be easily peeled off from the glass (800).

A shear peeling unit 610 disposed at the front end of the film 700 and the glass 800 on the basis of the feeding direction of the slant separating unit 300 is disposed on the side of the film 700 and the glass 800 And a rear end peeling unit 630 disposed at the rear end of the glass 800. The film 700 and the glass 800 may be configured to include a side edge peeling unit 620 and a film 700, ) Can be easily peeled off.

According to the display glass removing apparatus 100 of this embodiment having such a structure and operation, the glass 800 can be easily and easily removed from the film 700 without damaging the film 700 compared to the conventional structure of FIGS. 1 and 2 So that it can be efficiently removed.

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.

100: Glass for removing display device 200: Glass holding unit
300: a slant separating unit 310: a straight line section
320: Slope section 400: Vacuum stage
410: pore forming part 411: pore
420: Body part 500: Vacuum stage moving guide unit
510: seat part 520: rail body
530: Power transmission unit 600: Film peeling unit
610: Shearing peeling unit 611: Shearing film peeling blade
612: shearing blade supporting portion 620: side separating unit
621: Side edge film peeling blade 622: Side edge blade support
630: rear end peeling unit 631: rear end film peeling blade
632: rear end blade supporting portion 633: X-axis conveying portion
634: Y-axis feeder 635: Z-axis feeder
700: Film 800: Glass

Claims (14)

A glass grasping unit for grasping a glass to be removed from a film (EL) used in the process;
A plurality of slant separating units separated from the glass with the glass holding unit while slipping the film at a predetermined angle relative to the glass; And
And a plurality of vacuum stages arranged between the plurality of slant separating units, respectively, for adsorbing the film by vacuum pressure. The method according to claim 1,
The vacuum stage includes:
A pore-forming unit in which a plurality of pores are formed;
A body portion connected to the pore forming portion; And
And a vacuum pump connected to the inside of the body part and discharging air to the outside through the pore forming part. 3. The method of claim 2,
Wherein each of the plurality of slant separating units comprises:
A linear section in which the glass holding unit is operated to grip the glass, wherein the glass and the film are linearly moved together; And
And an inclined section which is inclined at a predetermined angle with respect to the straight line section and in which the film from which the glass has been removed is moved independently. The method of claim 3,
Further comprising a vacuum stage movement guide unit on which the vacuum stage is mounted and movable along the slope section. 5. The method of claim 4,
The vacuum stage moving guide unit includes:
A seating part on which the vacuum stage is seated;
A rail body to which the seat portion is movably engaged; And
And a power transmission part connected to the seating part and transmitting the power so that the seating part is movable along the rail body. 5. The method of claim 4,
Wherein the vacuum stage moving guide unit is an LM guide. The method according to claim 1,
And a film peeling unit inserted between the film and the glass to peel the film against the glass. 8. The method of claim 7,
The film peeling unit comprises:
A front end peeling unit disposed at a front end of the film and the glass with reference to a feeding direction of the slope separating unit; a side peeling unit disposed at a side end of the film and the glass; And a rear-end peeling unit. 9. The method of claim 8,
Wherein the shear peeling unit comprises:
A shear film peeling blade inserted between the film and the glass at a front end of the film and the glass; And
And a front end blade supporting part coupled to the glass holding unit for movably supporting the blade for peeling the front end film. 10. The method of claim 9,
The side-
A side-end film peeling blade provided so as to be rotatable so as to be inserted between the film peeled by the shearing peeling unit and the glass; And
And a side-edge blade supporting portion for supporting the side-edge film peeling-off blade in a rotatable manner. 11. The method of claim 10,
Wherein the shear peeling unit peels the film and the glass from the front end of the film and the glass so as to be peeled from the side of the film and the glass through peeled gaps between the film and the glass, Is arranged close to a position at a point where the shear peeling unit starts to peel the film from the glass. 9. The method of claim 8,
Wherein the succeeding-
A rear end film peeling blade inserted between the film and the glass at a rear end of the film; And
And a rear end blade supporting part coupled to the glass holding unit to movably support the rear film peeling blade. 13. The method of claim 12,
Wherein the succeeding-
An X-axis conveying unit for conveying the rear film separating blade in an X-axis direction that is a direction crossing the conveying direction of the tilter separating unit;
A Y-axis feeder for feeding the rear film peeling blade in the Y-axis direction, which is the feeding direction of the tilter separating unit; And
And a Z-axis transporting unit for transporting the rear-end film peeling blade in a vertical Z-axis direction. The method according to claim 1,
Characterized in that the inclined separation unit is provided as a Poros tilting conveyor for porous glass separation.

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