KR200407349Y1 - Apparatus for producing sheet glass using the downdraw method - Google Patents

Abstract

In order to improve the quality of the outer surface (surface) and increase the dimensional uniformity of the sheet glass manufactured by the down-draw method, the present invention stably forms a thermal change (temperature) difference in the inner surface of the molten and flowed glass, resulting in a change in glass viscosity. The present invention provides a device for controlling the speed of the flow, the present invention is easy to remove and replace the inner surface in the thickness direction of the glass melt melt flows from the slotted orifice (flow drawer plate of the draw stabilizing (Brawle Stabilizing Baffle Blade) Or a resistor), so that the upper end is close to the slotted orifice or enters the inner surface of some orifices so that the glass is discharged on both sides, and the glass is in contact with the resistor and flows down. At the same temperature, surface contact resistance is created, In this way, the glass water flowing out to the surface of the orifice relatively flows freely and has a uniform temperature condition so that the degradation of surface quality and dimensional uniformity due to the unevenness of the orifice and the discharge glass temperature can be eliminated. do.

 Down draw, draw adjuster, resistor, sheet, glass, LCD, PDP, orifice

Description

TECHNICAL APPARATUS FOR MANUFACTURING SHEET GLASS USING DOWN DRAW PROCESS {FORMING APPARATUS OF SHEET GLASS USING THE DOWN-DRAW METHOD}

1 is a conceptual diagram of a downdraw method to which a drawing adjusting plate (resistive body) of the apparatus for manufacturing sheet glass using the downdraw method of the present invention is applied;

Figure 2 is a simplified cross-sectional schematic diagram including a chamber and the draw adjustment plate for producing sheet glass,

3 is a simplified front view schematic diagram including a chamber and a drawing plate for producing sheet glass;

4 is a conceptual diagram showing a shape change in a high temperature state and a room temperature state of the drawing adjusting plate;

5 is a view illustrating the shape of the cross-sectional grain of the sheet glass according to the manufacturing method,

6 is a block diagram showing a temperature control method of sheet glass and a drawing adjusting plate.

The present invention relates to an apparatus for producing a glass sheet, which is a thin glass of 3 mm or less, used as a glass substrate such as a TFT LCD, and more particularly, to provide better smoothness and surface quality in glass products produced by a downdraw method. The present invention relates to a sheet glass manufacturing apparatus using a down-draw method for inserting a drawing adjusting plate (resistor) to the inner surface of the glass to make the temperature uniform and to control the flow of viscosity.

Conventional sheet glass manufacturing methods include a float method , a downdraw method , a redraw method, and an overflow downdraw method, also known as a fusion method, which is patented by Corning in the United States.

The Float method was developed by Pilkington as a US patent in 1952. The molten glass is poured into a chamber covered with molten tin plate, a liquid support with a higher density than glass, and flows in a state of floating over molten tin in a reducing atmosphere. As a technique to improve, it is mainly applied to the production of large plates, such as for construction, and has been further improved in recent years is applied to the glass molding for display is applied as a method to economically produce a large original (mother glass).

The down draw method is to cool the molten liquid glass by pouring it into an agitator and integrating it or through the separately formed lower discharge holes (Orifice, Slot), which flows down into the sheet shape and is pulled downward in the vertical direction. Lose. The thickness of the glass substrate is obviously dependent on the accuracy of the discharge hole and is determined by adjusting the cooling rate by the drawing speed pulling the sheet and the temperature of the air surrounding the glass. This technique is known to be suitable for producing thin glass substrates.

The reedlow process generally involves preforming the glass composition into a lump with some form, reheating the glass and drawing it downward to form a thinner sheet product.

The overflow downdraw method is a Corning patent in 1964, and when molten glass is supplied to a trough formed in a wedge-shaped refractory body known as 'isopipe', the molten glass overlies the upper layer of the trough on both sides. Flow. These two sheets meet at the bottom or root of the isopipe and fuse together into a single sheet. The single sheet is then sent to a drawing device remote from the root and to control the thickness of the sheet at the rate of drawing.

However, these methods have been continuously developed with the recent development of display technology, but the recent application of sheet glass for TFT LCD has its advantages and disadvantages in terms of size and thickness, and quality and economic efficiency of production.

When using the Float Method (Float Method) is a technique that can be produced more economically to produce a substrate of size 2.5m or larger by drawing in the horizontal. However, a thinner substrate, a larger substrate, and the like may require additional polishing because of problems with contamination, scratches, and flatness of the lower contact surface.

In contrast, the down-draw method flows the molten glass vertically through a long, long discharge hole (Orifice, Slot) and is cooled only by air and simultaneously drawn out by the roller below, so the thickness of the sheet is controlled by the drawing speed. Done. However, the thick glass at the time of ejection from the hole has to be maintained at a relatively low temperature or quenching in comparison with other methods, and therefore, it is very difficult to keep the temperature of the glass of the elongated discharge hole uniformly throughout. In addition, the effect of self weight and self temperature is greater than that of the drawing device installed at the lower end immediately after the discharge, and the discharge hole including precise control of the surface and inner temperature in the state of the entire sheet width for thickening or the thick glass material immediately after the discharge. Elaborate control of quality will influence quality.

In the down draw method, the sheet glass manufacturing method through the control of the discharge hole is applied in the early manufacturing industry. US Patent No. 1,759, 229 describes a down draw method for producing sheet glass. The sheet form is formed by the rectangular shape spread, but the slit nozzle and the spread are non-linear structure due to the shape of the working glass container (Receptacle), and there is a limit to the perfect planar and homogeneous thickness, US Patent No. 1,829,639 controls the nozzle Although the upper and lower portions of the glass are both open structures, high quality is limited.

Among the down-draw methods, a method of using a plate-shaped drawing rod (slits or nozzles such as platinum or the like) for achieving high quality is described in Japanese Patent (2-217,327). The glass melt is directed downward through the slits provided at the bottom of the refiner. The surface quality of the sheet glass is improved through the surface of the drawing rod equipped with the drawing bar, but the drawing bar for stabilizing the glass is fixed at both sides in the glass and the upper debiteuse needle for blocking the glass. As an open type structure, the flow control of glass is limited.

In addition, the German patent ( As 15 96 484) has a structure in which a drawing rod in the form of a streamlined feather is provided at the bottom of the slit nozzle in a vertical direction, and the drawing rod is exposed at the bottom. Limited to.

Another German patent (International Application No. PCT / EP2001 / 14654) implements a slit or drawing rod made of platinum, etc., which makes it possible to control the temperature due to the difference in elevation between the molten glass and the slit nozzle as the discharge part as temperature control at the inlet. The glass melt discharged from the nozzle is moved downwardly along both sides of the drawing rod and merged at the lower end of the drawing rod to form a glass ribbon. Such vertical drawing rods start inside the molten glass and cannot be sufficiently thick in thickness, thus limiting the temperature control of the drawing rods. In addition, the vertically descending glass has a limited time in which the thickness quality or the surface quality can be sufficiently improved in relation to the surface tension, viscosity, and falling speed.

As a result, precise temperature control is required because the temperature of glass discharged and the area of drawing in the drawn area are affected by the holding time and ambient temperature of the drawn rod. Especially, the drawn rod in the molten glass maintains quality in maintenance and operation. It is necessary to have high standards for this.

The down draw method should be considered carefully because the forming method affects the installation environment up to the draw area as well as melt molding.

Japanese Patent (PTC / JP2000 / 04898) is a method of minimizing distortion through a mechanical tension that spreads the glass of the direct method using a slit through a three-row roller in the vertical direction and spreads widely on the basis of the triceps. This is considered to allow sufficient cooling when the molten glass passes through the first slit, and Japanese Patent 10-291826 also proposes a method of forming a flat sheet glass by mutually limiting the circumferential speeds of the cooling roller and the drawn roller. In addition, the present invention proposes a method of applying the tension in the width direction by installing the roller in an oblique multiple. This shows that the type and viscosity of the glass and the manner in which the sheet glass is manufactured differ from each other.

The overflow downdraw process, also known as the fusion process, is a patent registered in US Pat. No. 3,338,696 (developed by Corning, USA ) and is still in practice and is widely used in the manufacture of AMLCDs glass.

After the molten glass overflows the upper layer of the fireproof body isopipe, the molten glass is combined again in the lower layer and flows down into a single sheet. Therefore, the outside of the glass surface does not come into contact with anything other than air, so post-processing is required. There will be no. Therefore, excellent exterior quality can be obtained and economical manufacturing is possible.

However, when the molten glass is slowly cured while passing directly through the isopipe outer weir, the size of the isopipe containing the molten glass must be overflowed uniformly by its own weight while maintaining the high temperature glass condition as compared to other methods. In addition, the structure must be manufactured as a large-scale facility to cope with sagging and thermal changes due to substantial high temperatures and mechanical loads, and at the same time, each structure is manufactured through a structural analysis for glass composition and product manufacturing conditions. This is inevitable, and includes the inconvenience of time-consuming replacement of parts of the device or changes to product models, or of timely repair or return to normal manufacturing conditions.

In addition, U.S. Patent (10 / 826,097 or International Application No. PCT / EP2001 / 14654, Sheet Glass Forming Appartus) also requires that expensive equipment made of platinum, etc., prior to molding meets limited design requirements to form Virgin Glass. It must be right. Therefore, slopes and weirs inclined to the temperature or viscosity of the glass in forming gutters (or isopipes) must be accompanied by precise dimensions and precise glass temperature control, and thus the structure of temperature, viscosity and production conditions (linear throughput). Inconvenience that requires structural analysis in advance.

Therefore, the object of the present invention for solving the above problems is to provide the tip in an acute or streamlined state so that the free fall by gravity and the flow of contact with the resistor easily, the resistor and the glass are wetted in close contact with the slope of the side wall. An apparatus for producing sheet glass using a downdraw method that flows down to a state and forms an onion zone for moving at a higher speed from glass on the outer surface is provided.

In addition, another object of the present invention is to divide the middle part of the glass that melts and flows down into the discharge hole (Orifice, Slot) in the down-draw method into a knife-type resistor installed at the lower portion of the inner surface of the glass at the same time as the surface contact on the surface of the thermal valve resistor The present invention provides an apparatus for producing sheet glass using a downdraw method that enables a control at an appropriate temperature to maintain a constant flow rate of the glass, and also enables a speed control according to the temperature of the inside and the outside of the glass.

The purpose as described above is, in the apparatus for producing sheet glass, the upper end portion has a slanted angle and the symmetrical streamline so that the molten glass material passing through the stirrer in the melting furnace flows through the surface while the glass material flows down the surface. It further comprises a resistor having a form of, wherein the glass material flows down the surface of the resistor while the temperature of the glass is controlled to be combined again by the apparatus for producing sheet glass using the down-draw method Is achieved.

In addition, according to the present invention, it is preferable that the resistor has a heating element built in the upper and lower so that the internal temperature of the glass is controlled by the resistor.

In addition, according to the present invention, the glass material discharged from the slot-shaped discharge hole is precisely left in the thickness direction by the upper end of the resistor. In order to separate, the discharge hole is preferably expanded so that the resistor enters into the discharge hole.

In addition, according to the present invention, the resistor is made of a refractory or heat-resistant metal, it is preferable that the surface is attached platinum or platinum alloy.

In addition, according to the present invention, it is preferable that the resistor further includes a structure for inserting a cooling line capable of heating and cooling through the heater from the inside and the outside to easily control the flow of the glass.

In addition, according to the present invention, it is preferable that the resistor can adjust the inclination in the vertical direction, the left and right, and the longitudinal direction so as to control the flow amount of the molten glass.

In addition, according to the present invention, it is preferable that the resistor has a structure in which a predetermined space is secured and a tension shaft is embedded to adjust the tension therein to correct linearity.

In addition, according to the present invention, the resistor, it is preferable that a thin plate of 1mm or less thickness is used to produce an alkali-free sheet glass used as the LCD substrate.

In addition, according to the present invention, it is preferable that a thin plate having a thickness of 3 mm or less is used to produce the PDP glass or the sheet glass for automobiles.

Hereinafter, with reference to the accompanying drawings to describe a preferred embodiment of the present invention.

1 is a conceptual diagram of a down-draw method applying a drawing adjustment plate (resistance body) of the apparatus for manufacturing sheet glass using the down-draw method of the present invention, Figure 2 is a schematic cross-sectional schematic diagram including a chamber and a drawing adjustment plate for producing sheet glass. .

In addition, Figure 3 is a simplified front part schematic diagram including a chamber and a drawing adjustment plate for producing sheet glass, Figure 4 is a conceptual diagram showing the shape change in the high temperature and room temperature state of the drawing adjustment plate.

5 is a figure which illustrates the shape of the cross section of the sheet glass by the manufacturing method, and FIG. 6 is a block diagram showing the temperature control system of the sheet glass and the drawing adjusting plate.

1 is a cross-sectional view for explaining the basic function of the process of discharging the molten glass material and the portion where the resistor acts as an embodiment of the present invention.

The molten glass 1, which has passed through the stirrer from the melting furnace, maintains a constant temperature and passes through an orifice 3 (orifice or slot) that is a discharge hole via a narrow discharge passage 2a of the refractory 2 having a structure for discharge. It flows downward through it.

The lower end of the orifice (3) is given the position of a knife-shaped pull-out stabilization plate (referred to as a resistor) (4), which is continuously maintained at a high temperature close to the temperature of the molten glass (1) The position of the resistor 4 is finely adjusted by the electric and mechanical device in the vertical direction (Z-axis in FIG. 1), left and right (thickness direction; X-axis in FIG. 1), and inclination (Z-axis height at both ends of the Y-axis in FIG. 1). You can control it.

The tip portion 41 of the resistor 4 is close to the discharge portion orifice 3, or a part of the resistor 41 is deeply introduced into the discharge portion orifice 3, so that the glass object 10 discharged through the orifice 3 is discharged. The inside is separated by both ends by the resistor front end 41, so that the sliding movement in the direction of the lower end portion 42 in the wet state instead of free fall.

The resistor 4 has an isotropic lozenge or other streamlined structure, and the upper and lower portions each have a built-in heating device 45, a control device 43, and a cooling control device 47, and a plurality of temperatures for temperature control. The sensor unit 46 is provided inside. The outside of the resistor 4 has a flat surface and an upper heating chamber 6 having several external heating elements 5 on each side of the resistor 4 so that the discharged glass material flows stably without overlapping. It is arranged in the middle of the lower constant temperature chamber 7 having a cooling function so that it can be stably drawn out.

In the present invention, the resistor 4 is maintained at a high temperature (usually around 1100 ° C.) by a heating element to form a temperature close to the temperature of the actually discharged glass, which is used to absorb heat and release heat by contact with the glass. In view of the above, it is preferable to determine the optimum temperature (1150 to 1250 ° C in the case of LCD glass) in which glass water flows down through the manufacturing process experiment to maintain a uniform temperature.

That is, the resistor further includes a structure for inserting a cooling line capable of heating and cooling through a heater from inside and outside to easily control the flow of the glass, the glass material is used as an LCD substrate As the alkali-free glass, for highly viscous glass having a density of 2.45 g / cm 3 or less, a strain point of 650 ° C. or more, and a liquefaction temperature of about 1100 ° C. or more, the temperature of the surface glass flowing down from the resistor is preferably about 1150 to 1250 ° C.

This is a conventional down draw method which forms a glass material having a sheet form through the discharge hole, and immediately cools and draws the molten glass with a viscosity of 10 ^5.4 dPa.s. The resistor 4 capable of position control is installed at the lower end of the in orifice 3, and the amount of the glass material 10 discharged is determined as the insertion depth 10b of the resistor 4 when the width 10a of the orifice is determined. It is controllable, and as the contact with the resistor 4 decreases, the descending speed becomes slower, which makes it possible to control uniformly and smoothly, although the viscosity is lowered to the level of 10 ^4.0 dPa.s or the viscosity is 10 ^5.4 dPa.s. Even if it is higher, it is possible to play a uniform amount of discharge, and the speed of flowing down depends on the temperature of the glass material by the temperature of the resistor 4 and the external heating element 5 and the upper heating chamber 6.

The glass material is already determined by the straight portion 2a and the tip orifice 3, which are discharge passages, and the inner surface portion of the glass is in contact with the resistor 4, which is separated into two sheets of glass and flows very slowly. Usually, the amount (thickness) of the glass is formed to be somewhat larger (thick) than the amount (thickness) of the glass of the downdraw method or the overflow downdraw method to start the contact flow on the side wall of the resistor 4.

In addition, the glass body 12 separated by the side wall of the resistor has a free surface, and the glass body is further subjected to radiant heat by the heating element 5 in the heating chamber 6 together with the force to descend by its own weight. Since the viscosity is lowered from the surface, it flows downward at a faster speed, and the inner surface is in contact with the resistor to flow down at a slow speed, so that there is an onion zone of the so-called glass water is gradually peeled off.

Therefore, even if the glass material 11 of the surface discharged in contact with the orifice 3 contains defects such as a slight bend at the time of initial discharge, the surface is exposed to the free area while passing through the long inclined section of the resistor 4. The surface tension is flattened, and the surface quality is smoothly restored by the flow of the onion area, so that a defect-free glass surface is formed and moved to the lower end of the resistor 4.

The lower part of the resistor 4 is disposed in the constant temperature chamber 7 to maintain a more uniform temperature, and a cooling control mechanism 47 capable of heating and cooling means is provided therein so as to ride on both side walls of the resistor 4. In the region 14 where the molten glass 13 comes down, the sheet glass having a flat and excellent surface is formed again.

In the present invention, the resistor 4 is directly contacted with high temperature molten glass in actual production, so it may be easily worn, eroded, or elaborated after installation due to thermal expansion.

As the material of the resistor 4, it is hardly worn on contact with glass, and is made of a refractory block that is statically pressurized as a creep resistant refractory material (henceforth referred to as 'iso-pipe') for precise surface processing. I think it is desirable. Iso-pipes are mainly made of refractory comprising isostatically pressurized zircon refractories, ie mainly ZrO ₂ and SiO ₂ . For example, ZrO ₂ · SiO ₂ or an equivalent amount with a theoretical composition of a material of ZrSiO _4, means that ZrO ₂ and SiO ₂ at least made of a zircon refractory material containing 95 wt% of the material together.

In addition, some of the body of the resistor 4 may be made of molybdenum or other metals having excellent heat resistance, and in some cases, the tip portion 41 or the upper portion, which is a part in direct contact with the glass, has the least effect on the quality of the molten glass. Alternatively, the structure may be fabricated to cover the surface with platinum + alloy.

Resistor 4 made of refractory or metal should be designed to have a smooth and good surface structure and to have minimal deformation to thermal changes due to heating and cooling. It is manufactured to be processed so that any shape abnormality forming bubbles or defects does not occur.

2 to 4 show the features of the present invention and a second specific example according to the present invention, showing a longitudinal cross-sectional view and a side view of the apparatus for manufacturing sheet glass.

In FIG. 2, the molten glass has a process of forming a sheet glass through four sophisticated process steps. In the molten glass supply unit A, glass of uniform conditions is discharged, and the glass material 12 uniformly distributed by the resistor 4 in the primary forming unit B having the heating chamber 6 is a heating element 5. As the flow down by self weight is accelerated downward by), the glass body 13 having a uniform temperature distribution is formed by the lower end of the resistor 4 and the constant temperature chamber 7 in the secondary forming part C. It is gradually cooled through the external cooling device (9), and finally at the lower end portion 42 of the resistor 4, the glass that was separated on both sides again to form a thin sheet glass 14 for drawing.

The combined sheet glass 14 is pulled downward while being pulled tightly to be drawn with a more accurate dimension in the diffusion part D, and the final molding is completed while cooling and heat treating. The diffusion portion (D) follows the same principle as other sheet glass manufacturing methods in general.

In the present embodiment described below, only elements that function important to the present invention will be described. The reason is that those skilled in the art of manufacturing sheet glass can be sufficiently applied and applied, and unlike the present embodiment, more effective methods and conditions can be selected through experiments.

In FIG. 2, as the distal end portion of the resistor is centered on the middle portion of the glass body 10 flowing down when the molten glass 1 is seen in cross section, the change in the flow of the left and right glass bodies is smaller, and thus the temperature difference on the left and right sides is smaller. Can be a stable product. For this purpose, together with precise temperature management of the molten glass (1), the molten glass material (1) flows uniformly by the primary management of the linear discharge groove (2a) for maximum laminar flow and the dimension of the orifice (3) at the end. In addition, the characteristics of the manufacturing plant may change at all times, and in particular, in consideration of deterioration due to long-term use and the like, the discharge part cooling mechanism 33 and the supply pipe 34 for cooling material which can finely control the local discharge temperature of glass. Is provided.

In general, glass has no vortex flow, but even temperature control inside the molten glass is extremely difficult. For uniform flow, the length 10c of the straight part outlet at the end of the orifice is the orifice width (10a in FIG. 1; X-axis direction). At least 2 times) is considered to be necessary, and in view of the insertion depth (10b of FIG. 1) of the resistor tip 41 of the present invention, it is considered desirable for the purpose of the present invention if the decision is made through a test.

In FIG. 2, the heating chamber and the constant temperature chamber equipped with the resistor 4 have several heating elements 51 and 52 for controlling temperature of each chamber, and auxiliary heating devices 60w, 70w and 80w installed inside the refractory wall. To maintain a uniform temperature, and the constant temperature chamber is provided with a cooling device 72 and a conduit 73 for supplying a cooling material.

Each chamber is composed of a fireproof wall (8) for maintaining the temperature difference, the barrier wall 61 is provided between the chambers, the air flow inlet 65 is not provided in the open space 65 of the gap where the glass flows down The air inlet 67 is attached to have a pressure (positive pressure or negative pressure) chamber in each chamber unit.

In addition, the air inlet 67 is preferably supplied with a high temperature glass material, especially filtered air to prevent oxidation, adhesion of foreign matters, or the like, or inject nitrogen (N ₂ ) gas in some cases. .

Like the resistors, the heating devices 50 and 51 are designed such that there is no temperature gradient in the width direction Y of the sheet glass, and in particular, the heating element of the control unit B has a sufficient amount of heat for the glass to flow down and fine temperature control. Is produced by.

The external heat generating device 51 of the lower portion of the resistor 4 is capable of precise temperature control together with the cooling device 72, which plays a major role in flowing as the glass is stretched. Therefore, this zone is an onion zone, and the temperature of the glass, the resistor and the surrounding atmosphere (including the heating element and the cooling device) plays a major role in the linear processing rate or production speed, which is the drawing performance of sheet glass.

FIG. 3 shows the side structure of FIG. 2. As an example of the structure including the drawing device, the integrated sheet glass 15 passing through the resistor 4 has convergence due to surface tension at both ends 15e. Diffusion rollers 84 are provided to prevent the occurrence of beads having a thickened edge. The diffusion roller 84 is formed to have a thin edge so that movement control is performed on an up and down height that can be brought into close contact with the lower end of the resistor 4 as much as possible. In addition, it is installed with an angle 84a inclined outward in order to compensate for the point that the sheet is expanded thin when spreading, and the sheet glass of this part is not used as a product as the surface scratched glass 16e.

In addition, the diffusion roller 84 has a tapered shape and at the same time has a heating and cooling structure, and the drawing speed, the surface temperature of the roller, and the inclination angle are comprehensively controlled.

In addition, both ends of the resistor 4 are provided with a shaft shaft 48 capable of micro-position control of the resistor 4.

The lower end tension rollers 86 and 88 of FIG. 3 illustrate the rollers applied to the downdraw method.

In the present invention, both ends 16e of the sheet glass may have excessive space in the width direction Y between the orifice and the resistor when the resistor tip 41 is introduced into the orifice 3. It is desirable that both ends of the orifice have a streamlined structure and at the same time have a concave end structure.

4 shows a thermal deformation of the resistor 4, which has a normal shape 401 under normal high temperature conditions, but a normal temperature shape 403 with its inner surface contracted at room temperature before use, and also shows a shrinkage amount 404 in the length section. Will have This is because at the high temperature, the upper end portion U of the shaft center 402 is a high temperature and the lower end portion L is a relatively low temperature, so that the difference 405 of the contraction value of the upper and lower ends is corrected in advance in the design stage. In addition, the inclination angles (40a and 40b in FIG. 1) of the tip portion (41 in FIG. 1) and the left and right side walls are several times so that the optimum flattening and uniform thickness are corrected at the point where the sheet glass is formed (see 14 in FIG. 1). Optimal values can be reflected during modeling and production testing.

At the same time, the resistor 4 is made of a structure in which the bending is weakly left and right in the resistor 4 itself in preparation for the thermal deformation of the orifice 3 and the bending deformation in the longitudinal direction (Y-axis) according to long-term use. It is preferable. For example, left and right bending refers to a structure that controls deformation such as 0.1 to 0.3 mm level with respect to 2,000 mm in the longitudinal direction (Y-axis), and a normal form 401 'and a bent form ( 403 'is a structure in which the deformation amount 406 is provided with respect to the normal central axis 402, which can be provided with a device for imparting a constant tensile / compression stress at the left and right ends in the longitudinal direction of the resistor 4. .

Figure 5 shows the pattern of the cross-sectional grain of the sheet glass according to the flow of the glass in the present invention.

In the sheet glass end face 150 of FIG. 5, the cross-sectional grain 150a generated according to the flow of the general float glass is opposite to the tin melt contact surface in the flow (for example, the opposite side is 152 when the contact surface is 151). It is difficult to maintain the same temperature at the same temperature, and thus the shape of the grain 153 biased to one side in the central portion 154.

150B in FIG. 5 is the shape of the grain 155 generated by the glass flow of the conventional downdraw technique without a drawbar.

The downdraw method of vertical descent cools the surface first, thus increasing the amount of draw from the inside. Therefore, to implement the grain (155) of the same type of wood grain.

150c of FIG. 5 is a form manufactured according to the present invention, in which the internal flow is delayed by the resistor 4 so that the grain 156 is formed in a dense form on both sides with respect to the central portion 157, and thus the other two methods mentioned above. More. The uniform and dense grain shape on both sides of the central portion 156 contributes to the improvement of the bending strength of the glass material.

The control device of the resistor 4 of the sheet glass manufacturing apparatus of the present invention is shown in FIG.

The glass water flowing out of the orifice 3 of the melting furnace 1 is measured by a plurality of non-contact sensors (T1, T2---Tn) and the thermometer side mechanism 501, and the resistance of the baffle (4) is measured. The temperature is measured by the lower temperature measuring mechanism 502 by another non-contact sensor T1, T2,---Tn at the lower end and flowing down while passing through, and at the same time, the resistance itself temperature 504 is also measured. Thus, the central heater 500 controls the air heater to the pipe of the heater 45 for heating the resistor again and the cooler 119 for local cooling through the calculation and precise control program.

In addition, the air cooling will be back through the elaborate measurement 503 through the outlet.

The air cooling rod 44 for precisely controlling the temperature inside the resistor is preferably supplied with high temperature air or nitrogen gas of 500 ° C. or higher rather than cooling water or cooling oil so that the temperature control of the glass flow does not have a sudden control change. Do.

In addition, since the position of the pipe may be changed in the resistor, the size of the hole for selecting the insertion depth or controlling the degree of air discharge is preferably determined through experiments at the initial stage of operation, and manual control is preferable.

The central controller 500 simultaneously controls the position coordinates of the resistor controller 506 with reference to the temperature of the resistor and the flow rate sensor 505 of the glass. Apart from the resistive control device of this sheet glass (Fig. 6), another sheet glass drawing control device (not shown) is secured, which is similar to the conventional down-draw drawing control device.

In the present invention, the purpose of the production of sheet glass which is superior to the conventional down draw method is that the control device requires more precise measurement of the position, and the method can be sufficiently designed together with the designer and the engineer of the manufacturing process.

In addition, the technology of the present invention is used in the manufacturing process of drawing downward from PDP glass or automobile glass and other glass having strength and smoothness, as well as the production of low-alkaline glass sheets used as glass substrates such as TFT LCD in the down draw method. It is also useful in the future, especially in the future, the technology has been further developed to utilize the present invention to form a method that can penetrate specific metal ions into the molten glass base material by thermal or electrical method from the resistor of the middle part of the sheet glass After the cooling, the metal may be reduced (precipitated) to contribute to the production of the functional glass of the heat reflection glass (or Roy glass, etc.).

(Reference) Examples of implementation conditions:

The following example is an alkali-free glass used as an LCD substrate and is a range of optimum conditions for high viscosity glass having a density of 2.45 g / cm 3 or less, a distortion point of 650 ° C. or higher, and a liquefaction temperature of about 1100 ° C. or higher. It can fully adjust according to a physical property and the conditions of a manufacturing apparatus, or productivity (drawing speed per hour).

* Glass discharge temperature: 1,100 ~ 1,200 ℃

* Temperature above the resistor: 1,200 ~ 1,250 ℃

* Resistance bottom temperature: 1,150 ~ 1,200 ℃

        (Or glass bottom temperature:)

* Ambient temperature of control chamber: 800 ~ 1000 ℃ (external heating element is inactive)

* Glass discharge rate: (Reference value about 50 ~ 100 mm / min.)

* Drawing speed of sheet glass: (reference value around 1,500 ~ 3,000mm / min.)

The present invention, as described above, in the process of manufacturing sheet glass in the down-draw method, the glass material discharged from the large-size molding is difficult to separate as a resistor and at the same time lower the flow rate of the inner surface surface relatively smooth surface quality The formation of a large-size sheet glass is made possible, and at the same time, the temperature and flow rate control for forming the sheet glass outside the melting furnace can be more uniformly controlled, thereby facilitating management of the manufacturing process.

In addition, the apparatus for producing sheet glass using the down-draw method of the present invention can easily change or repair the molding apparatus and improve the process conditions quickly and easily so that it does not affect the operation of the melting furnace, so that the conventional agitator, isopipe, orifice, etc. Relatively fewer problems, defects or accidental failures can occur during start-up, shutdown and restart, and remarkably less hours and days of stabilization after replacement.

In addition, in the apparatus for producing sheet glass using the downdraw method of the present invention, while the glass material flows down the outside of the resistor, the outer surface is exposed to the free surface for a relatively long time and is cooled by the downdraw method to increase the viscosity of the glass material. The surface defects are offset and flowed down for a short time by the vertical draw rod, one of the downdraw methods, to form a better surface quality than the surface is flattened.

Claims (9)

In the manufacturing apparatus of sheet glass, The upper end portion has a slanted angle and a symmetrical streamlined resistor so that the molten glass material 1 passing through the agitator from the melting furnace passes through the orifice 3 and flows down the surface. 4) is further included, and the glass material 1 flows down the surface of the resistor 4 while the temperature of the glass material 1 is adjusted to be combined again using a downdraw method. Apparatus for producing sheet glass. The method of claim 1, Production of sheet glass using the down-draw method, characterized in that the resistor 4 has a heating element 5 built in the upper and lower ends so that the internal temperature of the glass 1 is controlled by the resistor 4. Device. The method of claim 2, The glass material 1 discharged from the slot-like orifice 3 is precisely left in the thickness direction by the upper end of the resistor 4. The sheet glass manufacturing apparatus using the down-draw method, characterized in that the orifice (3) is extended so that the resistor (4) enters into the orifice (3) so as to separate. The method according to claim 1 and 3, The resistor (4) is made of a refractory or heat-resistant metal, the surface of the sheet glass manufacturing apparatus using the down-draw method, characterized in that the platinum or platinum alloy is attached to the surface. In claim 1, The resistor 4 further includes a structure for inserting a cooling line capable of heating and cooling the heater from the inside and the outside to easily control the flow of the glass, using a down-draw method. Apparatus for producing sheet glass. The method of claim 5, The resistor (4) is a device for producing sheet glass using the down-draw method, characterized in that the inclination of the vertical, vertical and horizontal directions can be adjusted so as to control the flow amount of the molten glass (1). The method of claim 6, The resistor (4) is a device for producing sheet glass using the down-draw method, characterized in that it has a structure to secure a predetermined space and to incorporate a tension shaft to adjust the tension therein to correct the linearity. The method of claim 1, The resistor (4), the sheet glass manufacturing apparatus using the down-draw method, characterized in that the thin plate of 1mm or less thickness is used to produce an alkali-free sheet glass used as the LCD substrate. The method of claim 1, The resistor (4) is a sheet glass manufacturing apparatus using the down-draw method, characterized in that a thin plate of 3mm or less thickness is used to manufacture PDP glass or automotive sheet glass.

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