KR20210145664A - Automatic exchanging apparatus of cassette for ultra thin glass - Google Patents

Abstract

The present invention relates to an apparatus for automatically exchanging cassette for ultra-thin glass and, more specifically, to an apparatus for automatically exchanging cassette for ultra-thin glass, which can move ultra-thin glass, accommodated in a first cassette, to a second cassette and accommodate the same therein, or can accommodate ultra-thin glass, accommodated in the second cassette, in the first cassette. To solve the above problem, the apparatus comprises: a first feed shuttle into which a first cassette on which ultra-thin glass is loaded is fed; a first elevating unit for elevating the first cassette fed into the first feed shuttle; a first discharge shuttle for discharging the first cassette elevated by the first elevating unit; a second feed shuttle into which a second cassette in which the ultra-thin glass is to be accommodated is fed; a second elevating unit for elevating the second cassette fed into the second feed shuttle; a second discharge shuttle for discharging the first cassette elevated by the second elevating unit; and an articulated robot for transferring the ultra-thin glass, accommodated in the first cassette elevated by the first elevating unit, to the second cassette elevated by the second elevating unit.

Description

Automatic changer of cassette for ultra-thin glass {AUTOMATIC EXCHANGING APPARATUS OF CASSETTE FOR ULTRA THIN GLASS}

The present invention relates to an automatic exchange device for a cassette for ultra-thin glass, and more particularly, to move and accommodate the ultra-thin glass accommodated in the first cassette to the second cassette, or to accommodate the ultra-thin glass accommodated in the second cassette in the first cassette It relates to an automatic changer of a cassette for ultra-thin glass that can be made.

In recent years, electrical and electronic technologies are rapidly developing, and various types of display products have been released to meet the needs of a new era and the needs of various consumers. Accordingly, for use in various applications requiring flexible and bendable glass (glass), the demand for flexible glass articles is increasing. For example, flexible display devices for mobile phones, tablets, and other portable electronic devices include flexible glass that must be bent or folded without breaking. However, traditionally glass has been considered to be rigid in nature, and therefore alternative materials for use in place of glass have been considered.

As an alternative to glass (glass), polymer films made of polymer have been considered and studied for use in flexible display devices. In the case of such a polymer film, the mechanical strength is weak, so it merely serves to prevent scratches on the display panel, but it is weak in impact resistance, has low transmittance, and is known to be relatively expensive.

On the other hand, it is known that if the glass is made of ultra-thin glass of 0.1 mm (100 μm) or less in order to be applied to a flexible display product, this is satisfied.

Ultra-thin glass is manufactured using dip, spray, or dip & spray methods and is manufactured through processing methods such as grinding, but there is a high risk of breakage or breakage due to cracks in the process of making thin.

In addition, the manufactured ultra-thin glass is loaded into a cassette in the process of performing a cutting and polishing process, etc., and various types of cassettes have been developed.

Among the various cassettes, Patent Publication No. 10-1302191 discloses a cassette for loading and retaining a thin plate of a portable terminal.

The technology is coupled to the main body for accommodating the thin plate tempered glass and to prevent the flow of the thin plate tempered glass to support the thin plate tempered glass and the thin plate support portion coupled to the thin plate support to support the thin plate reinforced It includes an elastic support for elastically fixing the glass.

However, the ultra-thin glass should be loaded into a cassette suitable for the process in the process of performing various processes, and the cassette on which the ultra-thin glass is loaded according to the process should be replaced with another cassette suitable for this.

Registered Patent Publication No. 10-1302191 (2013. 08. 26.)

The present invention has been devised to solve the above problems, and an object to be solved in the present invention is to provide an automatic exchange device for cassettes for ultra-thin glass that can interchange the cassettes loaded according to the processing process of ultra-thin glass. .

The automatic exchange apparatus of the cassette for ultra-thin glass according to the present invention for solving the above problems is a first input shuttle into which the first cassette on which the ultra-thin glass is loaded; a first elevating unit for elevating the first cassette inserted into the first input shuttle; a first discharge shuttle for discharging the first cassette lifted by the first lifting unit; a second input shuttle into which a second cassette in which the ultra-thin glass is to be accommodated; a second elevating unit for elevating the second cassette inserted into the second input shuttle; a second discharge shuttle for discharging the first cassette lifted by the second lifting unit; And it characterized in that it comprises an articulated robot for transferring the ultra-thin glass accommodated in the first cassette lifted by the first lifting unit to the second cassette lifted by the second lifting unit.

Here, it may be configured to further include a vision unit disposed above the first discharge shuttle and the second discharge shuttle to detect the position of the ultra-thin glass that is adsorbed and transferred to the articulated robot.

In addition, the first input shuttle may include a pair of spaced apart rails; a slider moving along the rail; an input plate configured to slide on the slider and on which the inserted first cassette is seated; a seating plate disposed on the rear side of the rail and on which the first cassette moved by the slider is seated; and an up-down module installed on the slider to raise and lower the first cassette seated on the input plate, and descend from a position positioned on the upper part of the seating plate according to the movement of the slider to be seated on the seating plate. .

In addition, the first lifting unit is a vertical rail installed vertically from the first input shuttle to the first discharge shuttle; a lifting slider configured to be able to ascend and descend on the vertical rail; a horizontal rail installed horizontally on the elevating slider; and a seating module configured to be movable along the horizontal rail and seating the first cassette seated on the seating plate.

In addition, the first input shuttle, the first discharge shuttle, the second input shuttle and the second discharge shuttle further includes a sensing unit for detecting the movement of the first cassette and the second cassette, the sensing unit, for transmitting a signal sending module; and a receiving module for receiving a signal transmitted from the transmitting module. It is configured to include, and the transmitting module and the receiving module is characterized in that it is disposed in a diagonal direction with respect to the moving directions of the first cassette and the second cassette.

According to the present invention, since the ultra-thin glass accommodated in the first cassette can be moved and accommodated in the second cassette, or the ultra-thin glass accommodated in the second cassette can be accommodated in the first cassette, a cassette suitable for the processing process of ultra-thin glass It has the advantage of being interchangeable.

In addition, since the cassette is accommodated in the cassette based on the alignment position of the ultra-thin glass in the process of exchanging the cassette, there is an advantage that the ultra-thin organic material can be accurately accommodated in the cassette through the articulated robot.

1 is a front perspective view of an automatic exchange device for an ultra-thin glass cassette according to the present invention;
Figure 2 is a rear perspective view of an automatic exchange device for an ultra-thin glass cassette according to the present invention;
Figure 3 is a perspective view of the configuration according to the movement of the cassette in the automatic exchange device for ultra-thin glass cassettes according to the present invention;
4 and 5 are a perspective view and an exploded perspective view of the first input shuttle, the first elevator and the first discharge shuttle of the automatic exchange device for the ultra-thin glass cassette according to the present invention, respectively;
Figure 6 is a perspective view of the first input shuttle of the automatic exchange device for ultra-thin glass cassettes according to the present invention;
7 is a perspective view of the first elevating part applied to the automatic exchange device of the cassette for ultra-thin glass according to the present invention;
8 is a side view showing the operation process of the first lifting unit applied to the automatic exchange apparatus of the cassette for ultra-thin glass according to the present invention;
9 is a perspective view of a vision unit applied to an automatic exchange device for an ultra-thin glass cassette according to the present invention.

Next, a preferred embodiment of an automatic exchange device for an ultra-thin glass cassette according to the present invention will be described in detail with reference to the drawings.

Hereinafter, the same reference numerals are used for technical elements having the same function, and repeated detailed descriptions are omitted to avoid overlapping descriptions.

In addition, the examples described below are illustratively shown in order to effectively show the preferred embodiments of the present invention, and should not be construed to limit the scope of the present invention.

The present invention relates to an automatic exchange apparatus for a cassette for ultra-thin glass, and more particularly, to an automatic exchange apparatus for a cassette for ultra-thin glass that can move and load an ultra-thin glass loaded in a first cassette to a second cassette.

1 is a front perspective view of an automatic changing device for an ultra-thin glass cassette according to the present invention, FIG. 2 is a rear perspective view of an automatic changing device for an ultra-thin glass cassette according to the present invention, and FIG. 3 is an ultra-thin type according to the present invention It is a perspective view of the configuration according to the movement of the cassette in the automatic changer of the cassette for glass.

1 to 3, the automatic exchange device for an ultra-thin glass cassette according to the present invention is a first input shuttle 100, a first lifting unit 200, a first discharge shuttle 300, the second It is configured to include an input shuttle 400 , a second lifting unit 500 , a second discharging shuttle 600 , an articulated robot 700 , and a vision unit 800 .

The automatic exchange device of the cassette for ultra-thin glass of the present invention according to the above configuration puts the first cassette 10 into the first input shuttle 100 and the second cassette 20 into the second input shuttle 400 . When, each of the input shuttles 100 and 400 moves each of the inserted cassettes to the rear side, and each of the moved cassettes is raised and lowered by the first lifting unit 200 and the second lifting unit 500, and the first It is positioned on the rear side of the discharge shuttle 300 and the second discharge shuttle 600 .

The cassettes lifted by each of the discharge shuttles 300 and 600 adsorb and move the ultra-thin glass accommodated in one cassette selected by the articulated robot 700 to the other cassette. For example, when the ultra-thin glass is accommodated in the first cassette 10 and the second cassette 20 is empty, the articulated robot 700 is the ultra-thin glass accommodated in the first cassette 10 according to the set logic. The glass is adsorbed and moved to the second cassette 20 to accommodate it.

In this process, the vision unit 800 detects the position of the ultra-thin glass adsorbed by the articulated robot 700 and provides an accommodation position in the cassette in which the ultra-thin glass is to be accommodated to the articulated robot 700, and The robot 700 accommodates the ultra-thin glass in the cassette based on the position transmitted from the vision unit 800 .

In the first input shuttle 100 , the first cassette 10 on which the ultra-thin glass is loaded is put, and the put first cassette 10 is moved, and the first lifting unit 200 is the first input shuttle 100 . Elevates the first cassette 10 put in the , and the first discharge shuttle 300 discharges the first cassette 10 lifted by the first lifting unit 200 .

4 and 5 are a perspective view and an exploded perspective view of the first input shuttle, the first lifting unit, and the first discharge shuttle of the automatic exchange device for the ultra-thin glass cassette according to the present invention, respectively.

4 and 5, the first cassette 10 put into the front side of the first input shuttle 100 is moved to the rear side by the set logic.

Figure 6 is a perspective view of the first input shuttle of the automatic exchange device for ultra-thin glass cassettes according to the present invention.

6, the first input shuttle 100 applied to the automatic exchange device of the ultra-thin glass cassette according to the present invention is a rail 110, a slider 120, an input plate 130, a seating plate 140 ) and an up-down module 150 .

The rail 110 includes a pair of spaced apart rails (a left rail and a right rail spaced apart from the left rail and installed parallel to the left rail).

The slider 120 is disposed inside the rail 110 and moved along the rail 110 , and is moved in the front-rear direction along the rail 110 according to a set logic.

In the input plate 130 , the input first cassette 10 is seated. At this time, the first discharge shuttle 300 is disposed on the upper side of the first input shuttle 100 , and as the first input shuttle 100 and the first discharge shuttle 300 are vertically disposed, the first input shuttle The input plate 130 of (100) becomes difficult to put the first cassette (10).

Accordingly, the input plate 130 is configured to slide on the slider 120 , and is configured to be exposed from the rail 110 to the front outside.

That is, the input plate 130 is configured to further slide from the slider 120 to the front side, so that the input of the first cassette 10 is easily made.

The seating plate 140 is disposed on the rear side of the rail 110 , and the first cassette 10 moved by the slider 120 is mounted thereon.

In the above configuration, in the input plate 130 , an up-down module 150 is installed in order to seat the inserted first cassette 10 on the seating plate 140 .

The up-down module 150 is installed on the slider 120 and elevates the first cassette 10 seated on the input plate 130 , and according to the movement of the slider 120 , the seating plate 140 is moved. It descends from the upper position and performs a function of being seated on the seating plate 140 .

That is, the up-down module 150 is moved to the upper portion of the seating plate 140 in a state where the inserted first cassette 10 is raised to a predetermined height, and the up-down module 150 is moved to the seating plate 140 . The first cassette 10, which is lowered in a state positioned on the upper part of the , and raised by the up-down module 150 is seated on the seating plate 140 .

In other words, when the first cassette 10 is put into the input plate 130 while the up-down module 150 is lowered, the input plate 130 is moved to the upper side of the up-down module 150 . . In a state where the input plate 130 is positioned on the upper side of the up-down module 150 , the slider 120 is moved toward the seating plate 140 . In a state in which the slider 120 is moved toward the seating plate 140 , the up-down module 150 raises and lowers the first cassette 10 inserted into the input plate 110 while ascending and descending, and the up-down module 150 . ) in a state in which the first cassette 10 is raised and lowered, the slider 120 is moved to the lower portion of the seating plate 140 . The up-down module 150 is positioned between the seating plates 140 by the movement of the slider 120 .

When the up-down module 150 descends in a state where the up-down module 150 is positioned between the seating plates 140 , the lower edge of the first cassette 10 lifted by the up-down module 150 . is seated on the mounting plate 140 .

Thereafter, the slider 120 is moved to the front side of the rail 110 again to receive the subsequent first cassette.

7 is a perspective view of the first elevating unit applied to the automatic exchange device of the ultra-thin glass cassette according to the present invention.

7, the first elevating unit 200 applied to the automatic exchange device of the ultra-thin glass cassette according to the present invention is a vertical rail 210, a lifting slider 220, a horizontal rail 230 and a seating module. (240) is included.

The vertical rail 210 is installed vertically from the first input shuttle 100 to the first discharge shuttle 300 .

That is, the vertical rail 210 is disposed in the vertical direction, extends from the rear side of the first input shuttle 100 to the rear side of the first discharge shuttle 300 and is disposed in an upright state.

The lifting slider 220 is configured to be able to ascend and descend on the vertical rail 210 so as to be raised and lowered along the vertical rail 210 .

The horizontal rail 230 is installed horizontally on the elevating slider 220 .

At this time, the horizontal rail 230 is configured to pass between the seating plates 140 of the first input shuttle 110 .

The seating module 240 is configured to be movable along the horizontal rail 230 and seats the first cassette 10 seated on the seating plate 140 , and is horizontally moved along the horizontal rail 230 . A slider 241, a tilting unit 242 installed on the horizontal slider 241, a seating plate 243 installed on the upper portion of the tilting unit 242, and an upper front side of the seating plate 243 It is configured to include a grip unit (244) and a support plate (245) installed on the upper rear side of the seating plate (243).

An operation of the first lifting unit 200 according to the above configuration will be described with reference to FIG. 8 .

8 is a side view showing the operation process of the first lifting unit applied to the automatic exchange device for the ultra-thin glass cassette according to the present invention.

8, the left side is the front side and the right side is the rear side. In a state where the elevation slider 220 is lowered to the lower side of the vertical rail 210, the horizontal slider 241 rides the horizontal rail 230 in front. moved to the side When the horizontal slider 241 is moved to the front side, the first cassette 10 seated on the seating plate 140 of the first input shuttle 100 is positioned above the seating plate 243 .

That is, the seating plate 243 is positioned on the lower side of the first cassette 10 , and when the elevating slider 220 rises in this state, the first cassette 10 seated on the seating plate 140 . is seated on the mounting plate 243 . In a state in which the first cassette 10 is seated on the seating plate 243, the grip unit 244 is moved toward the support plate 245 to bite and hold the first cassette 10 seated on the seating plate 243. It is fixed (refer to (b) of FIG. 8).

In a state in which the first cassette 10 is seated on the seating plate 243 and gripped, the horizontal slider 241 is moved to the rear side, and the seating module 240 is out of the range of the seating plate 140 . position (see Fig. 8(c)).

Thereafter, the elevating slider 220 rises and is positioned at the rear side of the first discharging shuttle 300 , and in a state where the elevating slider 220 is located at the rear side of the first discharging shuttle 300 , the The tilting unit 242 is inclined toward the articulated robot 700 (see FIG. 8(d)).

The tilting operation of the tilting unit 242 may reduce the movement (movement) of the articulated robot 700 . In addition, the articulated robot 700 adsorbs and withdraws the ultra-thin glass accommodated in the first cassette 10, or the adsorbed ultra-thin glass is detached in the process of drawing the adsorbed ultra-thin glass into the second cassette. There are advantages that can be

When all of the ultra-thin glass accommodated in the first cassette 10 is moved to the second cassette according to the operation of the articulated robot 700, the seating module 240 of the first lifting unit 200 is returned to a horizontal state and , after moving to the front side along the horizontal rail 230, put down the first cassette 10 loaded on the seating plate of the first discharge shuttle, slide to the rear side, descend to the initial state (see Fig. 8 (a)) ) will be returned.

In the above configuration, the second input shuttle 400 into which the second cassette 20 is put and moved is the same as that of the first input shuttle 100 , and a second elevating and lowering for raising and lowering the inserted second cassette 20 . The configuration of the unit 500 is the same as that of the first lifting unit 200 , and descriptions of the second input shuttle 400 and the second lifting unit 500 will be omitted.

In addition, in the first discharge shuttle 300, the configuration of the input plate 130 is omitted from the configuration of the first input shuttle 100, and it only proceeds in the reverse order with respect to the driving order of the first input shuttle 100, so the detailed description is omit Of course, since the second discharge shuttle 600 is the same as the first discharge shuttle 300 , a detailed description thereof will be omitted.

The articulated robot 700 transfers the ultra-thin glass accommodated in the first cassette 10 lifted by the first lifting unit 200 to the second cassette 20 lifted by the second lifting unit 500 . perform the accepting function.

Although not shown in the drawing, the articulated robot 700 is provided with a base part standing up from the base surface and a first rotation shaft for rotating the first arm on the upper part of the base part, and a second rotation shaft on the upper part of the first arm. An arm is installed, a second rotating shaft is installed at an end of the second arm, a third arm is installed at an end of the second rotating shaft, and a third rotating shaft is installed at an end of the third arm. In addition, a hand is installed at the end of the third rotation shaft, and the rear surface of the base unit may be configured to include a driving unit that receives and supplies external power and provides a vacuum suction force.

As the articulated robot 700 can be applied with known technology, a detailed description thereof will be omitted.

In this case, the articulated robot 700 operated by the set logic may cause a predetermined position change in the process of adsorbing the ultra-thin glass accommodated in the first cassette 10 . In the process of accommodating the ultra-thin glass adsorbed by the articulated robot 700 in the second cassette in a state in which the positional change occurs, the ultra-thin glass may come into contact with other parts and be damaged.

Accordingly, the position of the ultra-thin glass adsorbed to the articulated robot 700 is detected, and the ultra-thin glass adsorbed by the articulated robot 700 is positioned in the process of being accommodated in the second cassette 20 based on the detected position. A configuration to correct for is required.

The vision unit 800 is disposed between the first discharge shuttle 300 and the second discharge shuttle 600 and detects the position of the ultra-thin glass that is adsorbed and transferred to the articulated robot 700 .

9 is a perspective view of a vision unit applied to an automatic exchange device for an ultra-thin glass cassette according to the present invention.

9, the vision unit 800 includes a vision vertical frame 810 installed on both sides, respectively, a horizontal vision frame 820 installed by connecting upper ends of the vision vertical frame 810, and the vision horizontal frame 820. The vision horizontal rail 830 installed parallel to the frame 820, the vision camera slider units 840 and 850 that are installed on both sides of the non-horizontal rail 830 and are installed to slide, respectively, the vision camera slider unit ( The vision cameras 860 and 870 and each of the vision cameras 860 and 870 that are installed in 840 and 850 to photograph the edges (edges) of the ultra-thin glass are installed below the edges (edges) of the ultra-thin glass. It is configured to include a non-alignment guide (880, 890) for guiding the standard of the alignment position.

With the above configuration, the articulated robot 700 moves the adsorbed ultra-thin glass to the lower side of the vision cameras 860 and 870, and the position of the adsorbed ultra-thin glass relative to the hand position of the articulated robot 700 will detect

Accordingly, when the position of the ultra-thin glass is detected by the vision unit 800, the articulated robot 700 corrects the position of the insertion operation based on the position detected in the state where the ultra-thin glass is adsorbed, and the corrected position Inserts the ultra-thin glass into the slot of the set second cassette according to this, removes adsorption in the inserted state, and then withdraws the ultra-thin glass to move the ultra-thin glass from the first cassette 10 to the second cassette 20 .

When all the ultra-thin glass of the first cassette 10 is moved to the second cassette 20 by the articulated robot 700, the first lifting unit 200 moves from the first input shuttle 100 to the first cassette ( 10), the first cassette is seated on the first discharge shuttle 300 in the reverse order of the seating order, and the process of seating another cassette seated on the first input shuttle 100 is repeated.

In addition, the first discharge shuttle 300 moves the first cassette 10 seated by the first lifting unit 200 to the front side.

Similarly, the second lifting unit 500 also places the second cassette on the second discharge shuttle 600 in the reverse order of the seating order of the second cassette 20 in the second input shuttle 400 , and the second The process of seating another cassette seated on the input shuttle 400 is repeated.

In the above configuration, the first cassette 10 and the second inputted to and moved to the first input shuttle 100 , the first discharge shuttle 300 , the second input shuttle 400 , and the second discharge shuttle 600 . A sensing unit 900 for detecting the presence or absence of the ultra-thin glass accommodated in the cassette 20 may be further included.

5, the sensing unit 900 is installed on the rail side of each shuttle 100, 300, 400, 500, the transmission module 910 for transmitting a signal (light) to one side of the rail ) is installed, and a receiving module 920 for receiving a signal (light) is installed on one side of the facing rail, and depending on whether the receiving module 920 receives a signal transmitted from the transmitting module 910 The presence or absence of ultra-thin glass accommodated in the cassette is detected.

At this time, the ultra-thin glass accommodated in the cassettes 10 and 20 is disposed perpendicular to the direction in which the shuttle moves. Accordingly, when the transmission module 910 and the reception module 920 are disposed perpendicular to the rail, it is difficult to detect the presence or absence of the ultra-thin glass because the thickness of the ultra-thin glass is quite thin. Accordingly, the transmitting module 910 and the receiving module 920 should be configured to be disposed in a diagonal direction with respect to the moving directions of the first cassette 10 and the second cassette 20 .

In the present invention, it has been described that the ultra-thin glass accommodated in the first cassette is moved and accommodated in the second cassette, but as can be accommodated by moving the ultra-thin glass accommodated in the second cassette to the first cassette, the first cassette and the second cassette may be changed according to the moving work situation.

According to the present invention, since the ultra-thin glass accommodated in the first cassette can be moved and accommodated in the second cassette, or the ultra-thin glass accommodated in the second cassette can be accommodated in the first cassette, a cassette suitable for the processing process of ultra-thin glass It has the advantage of being interchangeable.

In addition, since the cassette is accommodated in the cassette based on the alignment position of the ultra-thin glass in the process of exchanging the cassette, there is an advantage that the ultra-thin organic material can be accurately accommodated in the cassette through the articulated robot.

In the above, a preferred embodiment of the automatic exchange device for an ultra-thin glass cassette according to the present invention has been described, but the present invention is not limited thereto, and various modifications are made within the scope of the claims and the description of the invention and the accompanying drawings. It is possible to implement it, and this also falls within the scope of the present invention.

100: first input shuttle 110: rail
120: slider 130: input plate
140: seating plate 150: up-down module
200: first lifting unit 210: vertical rail
220: elevating slider 230: horizontal rail
240: seating module 300: first discharge shuttle
400: second input shuttle 500: second elevator
600: second discharge shuttle 700: articulated robot
800: vision unit 900: sensing unit
910: sending module 920: receiving module

Claims (5)

A first input shuttle 100 into which the first cassette 10 on which the ultra-thin glass is loaded;
a first elevating unit 200 for elevating the first cassette 10 put into the first input shuttle 100;
a first discharge shuttle 300 for discharging the first cassette 10 lifted by the first lifting unit 200;
a second input shuttle 400 into which the second cassette 20 in which the ultra-thin glass is to be accommodated;
a second elevating unit 500 for elevating the second cassette 20 put into the second input shuttle 400;
a second discharge shuttle 600 for discharging the first cassette 20 lifted by the second lifting unit 500; and
An articulated robot for transferring the ultra-thin glass accommodated in the first cassette 10 lifted by the first lifting unit 200 to the second cassette 20 lifted by the second lifting unit 500 ( 700);
Automatic exchange device of the cassette for ultra-thin glass, characterized in that it comprises a.
The method according to claim 1,
It is disposed above between the first discharge shuttle 300 and the second discharge shuttle 600 and further comprises a vision unit 800 for detecting the position of the ultra-thin glass that is adsorbed and transferred to the articulated robot 700. Automatic exchange device for ultra-thin glass cassettes.
The method according to claim 1,
The first input shuttle 100,
A pair of spaced apart rails 110;
a slider 120 moving along the rail 110;
an input plate 130 configured to slide on the slider 120 and on which the inserted first cassette 10 is seated;
a seating plate 140 disposed on the rear side of the rail 110 and on which the first cassette moved by the slider 120 is seated; and
The first cassette 10 installed on the slider 120 and seated on the input plate 130 is raised and lowered in a state positioned above the seating plate 140 according to the movement of the slider 120 . an up-down module 150 to be seated on the seating plate 140;
Automatic exchange device of the cassette for ultra-thin glass, characterized in that it comprises a.
4. The method according to claim 3,
The first lifting unit 200,
a vertical rail 210 installed vertically from the first input shuttle 100 to the first discharge shuttle 300;
a lifting slider 220 configured to be able to ascend and descend on the vertical rail 210;
a horizontal rail 230 installed horizontally on the elevating slider 220; and
a seating module 240 configured to be movable along the horizontal rail 230 and seating the first cassette 10 seated on the seating plate 140;
Automatic exchange device of the cassette for ultra-thin glass, characterized in that it comprises a.
The method according to claim 1,
In the first input shuttle 100, the first discharge shuttle 300, the second input shuttle 400 and the second discharge shuttle 600,
A sensing unit 900 for detecting the movement of the first cassette 10 and the second cassette 20 is further included,
The sensing unit 900,
a transmission module 910 for transmitting a signal; and
a receiving module 920 for receiving a signal transmitted from the transmitting module 920;
Is configured to include, the transmitting module 910 and the receiving module 920 are ultra-thin glass, characterized in that disposed in a diagonal direction with respect to the moving direction of the first cassette 10 and the second cassette 20 Automatic changer for cassettes for use.

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