KR20060109166A - Mother glass manufacturing table - Google Patents

Abstract

A mother glass machining table is provided to reduce the weight of the machining table by being applied to a machining table constitution of large-sized equipment moving and laser-machining a mother glass. A mother glass machining table includes a flat base plate(12). The base plate has a predetermined area so that a mother glass(18) can be located on the base plate. The base plate is formed of a complex material. One surface of the base plate on which the mother glass is located is coated with a ceramic. The base plate is formed of a complex material of carbon fiber. The glass machining table fixes the mother glass by vacuum suction.

Description

Mother Glass Manufacturing Table

1 is a perspective view showing a mother glass processing table according to the prior art,

2 is a perspective view showing a glass processing table according to a first embodiment of the present invention;

3 is a perspective view showing a glass processing table according to a second embodiment of the present invention;

4 is an exploded perspective view of the glass working table according to the second embodiment of the present invention.

<Explanation of symbols on main parts of the drawings>

12,22: base plate 14,24; Table transport

16,26: laser oscillator 18,28: mother glass

20: ceramic film 30: tempered glass

32: air flow path 34: air suction device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a glass processing table. In particular, the present invention is applied to a glass processing table configuration of a large equipment that moves and lasers mother glass, thereby reducing the weight of the processing table, improving flatness, and damaging the processing table by laser. It relates to a glass processing table to prevent the.

In general, a liquid crystal display device includes a liquid crystal panel and a planar overcurrent device formed on the rear surface of the liquid crystal panel. This liquid crystal panel is comprised by the arrangement substrate and color filter substrate which sandwich a liquid crystal layer between them.

1 is a perspective view showing a glass processing table according to the prior art.

In the conventional liquid crystal display (LCD) and plasma display panel (PDP) processing processes, a multi-faceted chamfering method is applied, and the multi-faceted chamfering method is a method of processing several small glasses in one mother glass.

As shown in FIG. 1, the mother glass 8 is placed on one surface of the table conveyed by the table conveying means 4, where the table is made of granite 2. Here, the stone slab 2 is made of stone and is made of a horizontal plate exactly and has a thickness of t1, and is manufactured by grinding to improve flatness so that the mother glass 8 is accurately leveled.

Then, when the laser beam is emitted from the laser oscillator 6 provided at a distance L from the table transport means 4, the laser beam is directed to the mother glass 8 at a distance of H1.

At the same time, the table conveying means 4 horizontally moves the stone slab 2 and the mother glass 8 integrally and sets the position to be cut, and the mother glass 8 is cut by the laser beam.

The glass processing table according to the prior art has recently increased the horizontal and vertical lengths of the mother glass 8 to be processed as the size of LCD and PDP has become extra large, and the mother glass 8 has been increased. The size of the stone tablet 2 also increased in proportion to the size of.

However, the transfer capacity of the table transfer means 4 is limited so that not only the processing speed of the mother glass is limited, but also the size of the mother glass 2 to be processed according to the capacity of the table transfer means 4 may be limited. The capacity and size of the driving device may be increased even if the driving device for driving the table transfer means 4 is replaced.

The present invention has been made in order to solve the above problems of the prior art, by forming a glass processing table by combining a ceramic coating or reinforced glass to a base plate made of a composite material, to reduce weight and improve flatness Furthermore, the object of the present invention is to provide a glass processing table in which wear is prevented during processing by a laser beam.

Glass processing table according to the present invention for solving the above problems is made of a composite material and has a flat base plate having a predetermined width so that the mother glass to be processed is seated; In one embodiment, the mother glass is seated on the base plate, characterized in that the ceramic coating.

In addition, the base plate is characterized in that made of a composite material consisting of carbon fibers.

The glass processing table according to the present invention for solving the above problems is a flat base plate made of a composite material and having a predetermined width so that the mother glass to be processed is seated; The base plate is characterized in that it comprises a flat tempered glass that is coupled to one surface on which the mother glass is seated.

In addition, the glass processing table is characterized in that for fixing the mother glass by vacuum adsorption.

In addition, the tempered glass is characterized in that a plurality of vacuum lines are formed so that the mother glass is vacuum-adsorbed to form a negative pressure.

In addition, the base plate and the tempered glass in the glass processing table is characterized in that coupled by vacuum adsorption.

In addition, the base plate is characterized in that a plurality of vacuum lines are vacuum-absorbed with the tempered glass to form a negative pressure.

In addition, the base plate and the tempered glass and the mother glass are sequentially vacuum-bonded to each other, and a plurality of vacuum lines are formed on the base plate and the tempered glass so that the negative pressure is formed by vacuum suction, respectively, and the vacuum lines are alternately arranged. It is characterized by.

In addition, the base plate is characterized in that made of a composite material consisting of carbon fibers.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing a glass processing table according to a first embodiment of the present invention.

The glass working table according to the first embodiment of the present invention is placed on the mother glass 18 on one surface of the glass working table conveyed by the table conveying means 14, as shown in Figure 2, wherein the glass working The table consists of a base plate 12 made of a composite material, one surface of which is coated with a ceramic film 20.

That is, the base plate 12 manufactures a base plate 12 that is accurately horizontally made using a composite material, and forms a ceramic film 18 by ceramic coating on one surface on which the mother glass 18 is to be seated.

Here, the composite material is divided into fiber-reinforced composite material and particle-reinforced composite material according to the structure of the reinforcing material, and is divided into polymer composite material, metal composite material and ceramic composite material according to the reinforcing material. Since the composite material is a light weight structural material having a specific gravity of only about 60 percent of the conventional granite, the base plate 12 has an effect of effectively reducing the weight of the base plate 12 compared to the conventional processing table.

In addition, since the base plate 12 has superior strength or comparable strength to steel, it does not easily sag even under the load by the mother glass 18, so that the flatness of the base plate can be maintained for a long time from the beginning, It is possible to produce a thinner thickness of t2 than the thickness t1. In particular, the carbon fiber of the composite material is about 70 times greater in strength than the polymer material, and thus more effective in terms of strength and vibration.

In addition, since the composite fiber is manufactured through chemical synthesis, it is easy to process flatly compared to the existing stone tablet, which is advantageous in terms of flatness.

Looking at the operation of the present invention configured as described above are as follows.

When the laser beam is emitted from the laser oscillator 16 provided at a distance L from the table transport means 14, the laser beam is directed toward the mother glass 18 positioned at a distance of H2.

At the same time, the table transfer means 14 horizontally moves the ceramic coated base plate to set the position to be cut, and the mother glass 18 is processed by the laser beam.

Here, the base plate 12 is a ceramic coating film is formed, the heat generated by the laser beam to protect the glass processing table so that the surface of the base plate 12 is not easily worn, and in the stone panel in the existing laser oscillator The distance H2 from the laser focus of the laser oscillator 16 to the mother glass 18 can be farther away than the height H1, thereby reducing wear by the laser beam.

3 is a perspective view showing a mother glass processing table according to a second embodiment of the present invention, Figure 4 is an exploded perspective view of a mother glass processing table according to a second embodiment of the present invention.

The mother glass working table according to the second embodiment of the present invention is placed on the mother glass 28 on one surface of the glass working table conveyed by the table feed means 24, as shown in Figure 3 or 4, Here, the glass processing table includes a base plate 22 made of a composite material and tempered glass 30 bonded to one surface of the base plate 22.

And since the base plate 22 is manufactured with a thickness of t2 like the base plate 22 according to the first embodiment of the present invention, the weight is reduced compared to the conventional processing table, glass in terms of strength and vibration Do.

Tempered glass fabricated flat on the same size as the base plate 22 is combined on the base plate 22 made horizontally using the composite material.

Here, the base plate 22 is combined with the tempered glass 30 by vacuum adsorption. For this purpose, the base plate 22 is formed with a vacuum line 22a at a predetermined interval continuously in one direction.

In addition, the tempered glass 30 is also vacuum-bonded to the tempered glass 30 also continuously in one direction in order to couple the mother glass 28 seated on the tempered glass 30 by vacuum adsorption ( 30a) is formed.

At this time, the vacuum line 22a formed on the base plate 22 and the vacuum line 30a formed on the tempered glass are alternately formed to sequentially adsorb and form a negative pressure.

And an air suction device 34 which sucks air to form a vacuum in the vacuum lines 22a and 30a separately from the glass processing table, and an air suction device 34 from the vacuum lines 22a and 30a. Furnace is provided with an air flow path to guide the air.

Looking at the operation of the present invention configured as described above are as follows.

When the air suction device 34 operates to suck air through the air flow path 32, a negative pressure is formed in the vacuum lines 22a and 30a to form the base plate 22, the tempered glass 30, and the mother glass. 28 is adsorbed and fixed integrally.

When the laser beam is emitted from the laser oscillator 26 provided with a distance L from the table conveying means 24, the table conveying means 24 horizontally cuts the mother glass assembly 40 integrally. The mother glass 28 is cut by the laser beam.

Here, the base plate 22 serves to disperse the laser beam by the tempered glass 30 fixed by vacuum adsorption, so as not to directly wear the base plate 22 to protect the glass processing table.

In addition, as in the first embodiment of the present invention, since the distance H3 from the laser focus of the laser oscillator 26 to the mother glass 28 can be farther away than the height H1 of the existing laser oscillator in the stone platform Reduce wear caused by the laser beam.

Glass processing table according to the present invention is configured as described above can be effectively reduced in weight compared to the conventional granite (Granite) because the composite material using a small specific gravity. Therefore, by making the base plate large, there is an advantage suitable for the extra large multi-faceted method.

In addition, since the base plate is excellent in strength and can be made thinner than that of the existing stone tablet, the base plate can not only reduce the wear by the laser by reducing the distance from the glass processing table surface at the laser focus, but also improve the initial flatness of the base plate. There is an advantage that can be sustained.

In addition, since the base plate is manufactured by synthesizing, there is an advantage that can have a high flatness compared to the conventional stone plate.

In addition, the glass processing table according to the first embodiment of the present invention has the advantage that the ceramic coating film is formed, so that heat generated by the laser beam is not easily worn on the surface of the base plate.

In addition, the glass processing table according to the second embodiment of the present invention, since the base plate, the tempered glass, and the mother glass are fixed integrally, so that the mother glass can be held flat and fixed, especially in the case of vacuum adsorption, the higher flatness There is a sustainable advantage.

In addition, the glass processing table according to the second embodiment of the present invention serves to disperse the laser beam by the tempered glass, there is an advantage that the base plate is not directly worn.

Claims (9)

A flat base plate made of a composite material and having a predetermined width so as to mount the mother glass to be processed; Glass processing table, characterized in that the ceramic plate is coated on the surface on which the mother glass is seated in the base plate. The method of claim 1, The base plate is a glass processing table, characterized in that made of a composite material consisting of carbon fibers. A flat base plate made of a composite material and having a predetermined width so as to mount the mother glass to be processed; Glass processing table comprising a flat tempered glass that is coupled to one surface on which the mother glass is seated in the base plate. The method of claim 3, wherein The glass processing table is a glass processing table, characterized in that for fixing the mother glass by vacuum adsorption. The method of claim 4, wherein The tempered glass is a glass processing table, characterized in that a plurality of vacuum lines are formed so that the mother glass is vacuum-adsorbed to form a negative pressure. The method of claim 3, wherein The glass processing table is characterized in that the base plate and the tempered glass in the glass processing table is combined by vacuum adsorption. The method of claim 6, And a plurality of vacuum lines formed on the base plate by vacuum suction with the tempered glass to form a negative pressure. The method of claim 3, wherein The base plate, the tempered glass and the mother glass are sequentially vacuum-bonded to each other, and a plurality of vacuum lines are formed on the base plate and the tempered glass so that negative pressure is formed by vacuum suction, respectively, but the vacuum lines are alternately arranged. Glass processing table. The method according to any one of claims 3 to 8, The base plate is a glass processing table, characterized in that made of a composite material consisting of carbon fibers.

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