KR102462342B1 - Apparatus for glass bending and method for bending using thereof - Google Patents

Abstract

The present invention relates to a glass bending apparatus and a bending method using the same, and more particularly, to a glass bending apparatus and a bending method by heat.
The method of bending by heating glass according to the present invention is to adjust the position and angle of at least one plate so that the heated glass is seated on two plates arranged to form a horizontal plane, and the angle between the plates is reduced and the distance is increased. characterized in that
According to the present invention, it is possible to prevent wrinkles due to shrinkage while the bending area of the glass is stretched as a whole in the bending process of the glass, thereby solving the polishing problem.

Description

Glass bending device with improved wrinkle properties and bending method using the same

The present invention relates to a glass bending apparatus and a bending method using the same, and more particularly, to a glass bending apparatus and a bending method having improved wrinkle resistance and whitening resistance.

The demand for curved glass processing is increasing in the fields of smartphones, TVs, monitors, and vehicle monitors. In order to process the curved glass, a thermoforming method is mainly used in which the glass is placed in a high-temperature furnace and heated, and then the glass is bent using a press.

This press thermoforming method enables rapid bending and is advantageous for small glass processing, but there is a difficult side in large size, and the side in contact with the press changes to white and fine wrinkles are formed on the back side of the bending. There is a disadvantage in that a polishing process is required after bending. In addition, polishing is a process that requires manpower, time and money, and there is a continuing demand for a manufacturing method or apparatus that can avoid it.

Republic of Korea Patent Publication No. 10-2017-34906 filed by LaserApps Co., Ltd. discloses a glass and tempered glass bending method using a laser. The molding time can be shortened by placing the glass plate on the heating chamber and the heated jig and preheating it, heating the curved part locally using a lamp and laser to quickly heat it to the processing temperature and then bending it. There is a problem that the treatment process is not solved.

An object to be solved in the present invention is to provide a new apparatus capable of bending glass without wrinkles by bending or whitening by pressing.

Another object to be solved in the present invention is to provide a new method capable of processing glass without wrinkles or whitening by pressing.

In order to solve the above problems, the present invention

After seating the heated glass on two plates arranged to form a horizontal plane, there is provided a glass bending method, characterized in that the angle and position of at least one plate are adjusted so that the angle decreases as the distance between the plates increases.

Although not limited in theory, the fact that wrinkles occur in the process of bending the glass by gravity or the press is that one side of the glass increases while the one side of the glass on the other side of the glass shrinks in the bending process. Adjust the angle of the plate so that the angle between the plates decreases while supporting the glass with the two plates, but the bending reference line of the glass is formed on the upper surface of the opposite side rather than the surface in contact with the plate. By preventing the upper surface from being reduced by adjusting the inclination as the distance increases, it is possible to eliminate wrinkles by removing the reduced portion in the bending process.

In the present invention, the angle between the two plates can be reduced by 1 to 45 °, preferably 1 to 40 °, more preferably 1 to 30 °, even more preferably 1 to 25 °, between the two plates The angle of is, for example, 179°, 178°, 177°, 176°, 175°, 174°, 173°, 172°, 171°, 170°, 169°, 168°, 167°, 166°, 165 °, 164°, 163°, 162°, 161°, 160°, 155°, 150°.

In the present invention, the angle between the two plates may be adjusted together or separately, and preferably, the angle between the two plates may be adjusted at the same time to reduce the stress applied to the glass during bending.

In the practice of the present invention, the inclination of the plate can be adjusted by raising or lowering one side of the plate, and raising or lowering one side while raising or lowering the other side can be adjusted. For example, it may be achieved through raising or lowering of the support member supporting the lower portion of the plate.

In a preferred embodiment of the present invention, the distance between the plates is adjusted to increase the distance between the upper surfaces of the two plates forming the horizontal plane, and the extent of the distance can be adjusted according to the thickness of the glass to be bent.

In another embodiment of the present invention, the inclination and position of the plate can be adjusted using a rotational shaft that rotates in a predetermined direction and a rotational arm that is coupled to the rotational shaft on one side and the other side is coupled to the plate.

In a preferred embodiment of the present invention, the angle and the distance between the two plates arranged to form a horizontal plane are a first axis of rotation located on the upper portion of the two plates, and the first axis of rotation is coupled to the first axis on one side and the other side is on one plate. A first pivoting arm to be coupled, a second pivoting shaft positioned on the same axis as the first pivoting shaft and rotating in the opposite direction, one side coupled to the second pivoting shaft and the other end coupled to the other plate, It consists of a second pivot arm having the same length as the first pivot arm.

In the present invention, the glass seated on the plate can be bent by adjusting the angle of the plate so that the bending portion is heated to a temperature above the glass transition temperature, preferably 100 ~ 600 ℃ higher than the glass transition temperature.

In the present invention, the heating of the glass may be made through convection, radiation, conduction, or a combination thereof, and preferably, the glass is first heated as a whole through preheating, and the glass is heated as a whole using a plate secondarily. and selectively tertiary heating of the bending portion of the glass through light such as laser or IR.

In the present invention, for the secondary heating, the plate may be a temperature controllable plate, preferably a plate whose surface temperature is controlled by internal heating.

In the practice of the present invention, the lower surface of the glass may be heated by a plate, and the upper surface may be heated by an upper cover plate disposed at a predetermined distance from the upper surface of the glass.

In the present invention, the bending portion of the glass may be heated through an optical heating device installed in the bending portion. In order to minimize loss due to convection of heat, the light heating device may be positioned in a gap between two plates spaced apart by a predetermined distance.

In the present invention, the bent glass can be demolded by cooling by lowering the temperature to below the glass transition temperature in the bent state, preferably at a temperature of 100 to 500 ° C. or less than the glass transition temperature to remove residual stress. It can be annealed by heating for a predetermined period of time.

The present invention in one aspect,

A plate portion comprising a first plate and a second plate; and

a heating unit for heating at least a portion of the glass to a bendable temperature or higher;

It provides a glass bending device comprising a; the distance between the first plate and the second plate increases as the distance between the two plates and the adjustment unit for adjusting the inclination of the at least one plate so that the angle decreases.

In the present invention, the plate may be a temperature controllable plate, preferably a surface temperature controllable plate. The plate may include an upper plate on which the glass is seated and a lower plate to be heated, and an air layer is formed at a predetermined distance between the upper plate and the lower plate so that heat generated from the lower plate is transferred to the upper plate by convection. It is desirable to prevent thermal agglomeration of the plate surface.

In the present invention, the plate may further include a top surface heating device to heat the top surface of the glass. The upper surface heating device may be a plate for upper surface heating.

In the practice of the present invention, the upper surface heating plate may be disposed adjacent to the glass, and each of the first plate is composed of two plates so as not to interfere with the angle adjustment of the first plate and the second plate in the adjacent state in the glass. It is fixed to the plate and the second plate spaced apart by a predetermined distance, the angle can be adjusted together with the first plate and the second plate.

In the present invention, the heating unit may be a device that is installed separately from the heating device of the first plate and the second plate to heat the glass, preferably a local heating device that locally heats the area where the glass is to be bent. . In the practice of the present invention, the local heating device may be an optical heating device, and in a preferred embodiment, the optical heating device may be a plurality of IR heaters or lasers focused on a bending area.

In the present invention, the inclination and angle adjusting device may include a fixed plate fixed to the lower end of the plate, an adjusting device for adjusting the angle and position of the plate, and a controller for controlling the adjusting device.

The present invention in one aspect,

preheating the sheet glass;

Seating the plate glass, a plate portion including a first plate and a second plate, and a glass bending device comprising an inclination adjusting portion for adjusting the inclination of the first plate and the second plate;

moving the glass bending device so that the heating unit heats the bending area;

heating the bending region by the heating unit;

bending the glass by adjusting the inclination and position of at least one plate so that the angle between the first plate and the second plate increases while the angle decreases;

cooling the bent glass by moving the glass bending device; and

demolding the cooled glass;

It provides a glass bending method comprising a.

In the present invention, the glass bending device includes a cover portion for heating the upper surfaces of the first plate and the second plate, the glass is slid and is seated by moving between the plate portion and the cover portion.

In the present invention, the cover plate in the glass bending device is heated to a predetermined temperature to heat the glass and prevent the surface of the glass from being cooled by the atmosphere.

According to the present invention, it is possible to prevent wrinkles due to shrinkage while the bending area of the glass is stretched as a whole in the bending process of the glass. In addition, it is possible to solve the polishing problem caused by this.

In addition, in the bending device according to the present invention, the cover can heat the glass, so that bending is possible without a separate high-temperature chamber. In particular, the effect of the present invention is remarkable in that it is difficult to maintain a uniform temperature in a large high temperature chamber as well as an expensive large high temperature chamber when bending a thin glass for a large display such as an automobile display or TV.

In addition, continuous operation is possible by the reciprocation of the bending device, so there is an effect of high productivity.

In addition, heat can be effectively used during bending, and the direction in which the glass is bent and the direction of the action of gravity are the same, so that gravity can be used for bending of the glass, so that a natural bending curve can be formed.

1 is a view showing a side of a glass bending device according to an embodiment of the present invention.
FIG. 2 is an enlarged side cross-sectional view of the plate part 100 and the cover part 200 in the glass bending apparatus of FIG. 1 .
Figure 3 is a comparative view showing the bending state of the glass bending device, Figure 3a is a state before bending, Figure 3b is a view showing a state after bending.
Figure 4 is a view showing a side of the glass bending device according to another embodiment of the present invention.
5 is a view showing a state after bending of the glass bending device according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail through examples. The following examples are intended to illustrate the present invention in detail, not to limit the present invention.

1 to 2, the flat glass 10 bending device 1 according to the present invention is a first plate 110 and a horizontal plane with the first plate 110 and is disposed spaced apart from each other by a predetermined distance A plate portion 100 including a second plate 120; and a first cover 210 spaced in parallel from the first plate 110 by a predetermined distance to cover an upper surface of the first plate 110; The second plate 120 is spaced parallel to each other by a predetermined distance to cover the upper surface of the second plate 120 , and the upper cover 200 part consists of a second cover 220 , and the first plate 110 and the second plate 120 . a heating unit 300 for heating the bending region B between the two plates 120; and an adjustment unit 400 for adjusting the inclination and spacing of the first plate 110 and the second plate 120 .

The plate part 100 is a second plate ( 120) are arranged side by side adjacent to the same height.

The first plate 110 includes a first upper plate 111 of a predetermined thickness supporting the lower surface of the flat glass 10 , a first heating plate 112 disposed under the first upper plate 111 , and the second 1 The first spacer member 130 for preventing the heating plate 112 from directly heating the first upper plate 111 is integrally formed. The first spacer 130 is formed along the edge of the first heating plate (112). The first heating plate 112 has a built-in first heating member 114 whose temperature is controlled therein, and the first heating member 114 may be a coil heated by electricity or a coil tube heated by a fluid. .

The second plate 120 includes a second upper plate 121 of a predetermined thickness supporting the lower surface of the flat glass 10 , a second heating plate 122 disposed under the second upper plate 121 , and the second upper plate 121 . The first spacer member 130 for preventing the second heating plate 122 from directly heating the second upper plate 121 is integrally formed. The first spacer 130 is formed along the edge of the first heating plate 122 . The second heating plate 122 has a built-in second heating member 124 whose temperature is controlled therein, and the second heating member 124 may be a coil heated by electricity or a coil tube heated by a fluid. .

The cover part 200 is spaced apart from the upper surface of the flat glass 10 to be bent and covered, and the first cover 210 and the second cover 220 are spaced apart from each other and arranged side by side.

The first cover 210 includes a first cover plate 211 having a predetermined thickness in a rectangular shape that covers the upper surface of the flat glass 10 , and a first cover heating plate disposed on the first cover plate 211 . (212) and the first cover heating plate 212 is made integrally with the first spacer member 130 for preventing the first cover plate 211 from being directly heated. The first spacer 130 is formed along the edge of the first cover heating plate 212 . The first cover heating plate 212 has a built-in first cover heating member 214 whose temperature is controlled therein, and the first cover heating member 214 is a coil heated by electricity or a coil tube heated by a fluid. can be

The second cover 220 includes a second cover plate 221 having a predetermined thickness in a rectangular shape that covers the upper surface of the flat glass 10 , and a second cover heating plate disposed on the second cover plate 221 . 222 and the first spacer member 130 for preventing the second cover heating plate 222 from directly heating the second cover plate 221 are integrally formed. The first spacer 130 is formed along the edge of the second cover heating plate 222 . The second cover heating plate 222 has a built-in second cover heating member 224 whose temperature is controlled therein, and the second cover heating member 224 is a coil heated by electricity or a coil tube heated by a fluid. can be

The first plate 110 and the first cover 210 are spaced apart by a first interval greater than the thickness of the flat glass 10 that is processed so that the glass can enter, and the first plate 110 is inclined in the bending process. When the inclination is adjusted, the second spacer member 140 fixed to the first plate 110 and the first cover 210 is located on one side so that the inclination can be adjusted at the same angle while maintaining the first interval. .

The second plate 120 and the second cover 220 are spaced apart by a second interval equal to the first interval greater than the thickness of the flat glass 10 that is processed so that the glass can enter, and the second plate 210 is When the inclination is adjusted and inclined in the bending process, the second spacer member fixed to the second plate 210 and the second cover 220 on the other side so that the inclination can be adjusted at the same angle while maintaining the second interval ( 140) is located.

The heating part 300 is disposed under the plate part 100 and passes through a gap between the first plate 110 and the second plate 120 to prevent blocking by the plate part 100 . It condenses and transmits heat. The heating unit 300 is composed of a plurality of IR light sources 310, and for effective transmission through the gap between the first plate 110 and the second plate 120, each angle is adjusted to collect light through the gap. do.

The inclination and distance adjusting unit 400 includes a first fixing plate 410 and a second fixing plate 420 for fixing the first plate 110 and the second plate 120, respectively, and an upper end of the first fixing plate The first support 411 is coupled to the plate 410 so that the angle can be adjusted, the lower end is movably coupled to the support plate 430 , and the upper end is the second fixed plate 420 . A second support 421 that is coupled as possible, the lower end of which is horizontally movable to the support plate 430 .

The distance between the first support 411 and the second support 421, the angle between the first support 411 and the first fixing plate 410, and the second support 421 and the second fixing The angle between the plates 420 is controlled by a controller (not shown).

The adjusting unit 400 includes a nut-type member 520 attached to a lower portion of the support plate 430 , a bolt-type rotation shaft 510 passing through the nut-type member 420 , and the bolt-type rotation shaft 510 . It is moved by the moving part 500 made up of the motor 530 which rotates.

The bending of the flat glass 10 using the flat glass 10 bending device 1 according to the present invention is performed as shown in FIG. 3 . As shown in FIG. 3A , the flat glass 10 is seated in a preheated state for bending on the first plate 110 and the second plate 120 spaced apart by a predetermined distance while forming a horizontal plane. The first plate 110 and the second plate 120 supporting the flat glass 10 and the first cover 210 and the second cover 220 covering the flat glass 10 are maintained at a high temperature. A heating unit 300 including an infrared heater is positioned below the gap between the first plate 110 and the second plate 120 to heat the lower surface of the flat glass 10 to a temperature of 1,200° C. or higher. A bending reference line (A) extending the upper surface of the flat glass 10 is set so that the upper surface of the flat glass 10 is not reduced during the bending process.

When the bending part B is sufficiently heated by the heating part 300 , the first fixing plate 410 fixed to the lower surface of the first plate 110 and the second fixing plate material fixed to the lower surface of the second plate 120 . The angle between the first plate 110 and the second plate 420 is adjusted to be 160° by adjusting the inclination of the plate material 420 by 10°, respectively. At the same time, the first plate 110 and the second plate 420 are fixed to each other by increasing the distance between the first support 411 and the second support 421, the upper surface of the flat glass 10 at the reference line (A) is reduced to prevent

The interval between the first support 411 and the second support 421 and the inclination of the first fixing plate 410 and the second fixing plate 420 are controlled by the controller.

In the state in which the plate glass 10 is bent, the heating by the heating unit 300 is stopped, the temperature of the plate unit 100 and the cover unit 200 is adjusted to cool the bent glass, and then the glass is formed by sliding. to demold The demolded glass is maintained in a post-heated state for a predetermined time for aging, and then the temperature is lowered to room temperature to terminate the bending process.

The preheated glass is seated again in the glass bending device from which the glass is demolded, and the bending is repeated.

4 and 5, the flat glass 10 bending device 1 according to another embodiment of the present invention is spaced apart by a predetermined distance while forming a horizontal plane with the first plate 110 and the first plate 110. A plate portion 100 including a second plate 120 disposed as a first cover 210 spaced in parallel from the first plate 110 by a predetermined distance to cover the upper surface of the first plate 110 . ), the second plate 120 is spaced parallel to each other at a predetermined distance to cover the upper surface of the second plate 120 , and the upper cover 200 part composed of a second cover 220 and the first plate 110 . ) and a heating unit 300 for heating the bending area (B) between the second plate (120); and an adjustment unit 400 for adjusting the inclination and spacing of the first plate 110 and the second plate 120 .

The plate part 100 is a second plate ( 120) are arranged side by side adjacent to the same height.

The control unit 400 is coupled to the first rotation shaft 451 on one side and a first rotation shaft 451 positioned on the upper portion between the first plate 110 and the second plate 220, and A first pivoting arm 452 coupled to the front of the upper surface of the first cover 210 having the other side fixed in parallel to the first plate 110, and the first pivoting shaft 451, and located on the same axis, A second pivoting shaft 461 positioned behind the first pivoting shaft 451 and rotating in the opposite direction to the first pivoting shaft 451, and one side having the same length as the first pivoting arm 452 and a second pivoting arm 462 coupled to the second pivoting shaft 461 and coupled to the rear of the upper surface of the second cover 220 having the other side fixed in parallel to the second plate 210 .

When the first pivoting shaft 451 and the second pivoting shaft 461 rotate in opposite directions by the same angle, the first pivoting arm 452 connected to the first pivoting shaft 451 and the second pivoting shaft 461, respectively. and the second pivoting arm 462 moves in opposite directions, respectively. The first pivot arm 452 and the second pivot arm 462 move in opposite directions along the arc of a circle having the first pivot arm 452 as a radius, respectively, and are coupled to the first pivot arm 452 . The first cover 210 and the first plate 110 and the second cover 220 and the second plate 120 coupled to the second pivot arm 462 also move in the opposite direction.

Accordingly, the flat glass 10 placed on the first plate 110 and the second plate 120 is a horizontal plane formed by the first plate 110 and the second plate 120 on the lower surface of the rotation shaft 451 . It stretches along the arc of a circle with the distance to the radius as the radius, and the upper surface is stretched along the arc of the circle with the distance from the rotation axis 451 to the upper surface of the flat glass as the radius, and the upper surface in the process of bending the lower surface It reduces wrinkles and prevents the formation of wrinkles.

In addition, when a length-controllable arm capable of controlling the length of the first pivoting arm 452 and the second pivoting arm 462 is used, the degree of bending of the flat glass can be adjusted.

1: Glass banding device
10: sheet glass
100: plate part
200: cover part
300: heating unit
400: control unit

Claims (14)

In the method of bending by heating glass,
After seating the heated glass plate on the two plates arranged to form a horizontal plane, the angle of at least one plate is adjusted so that the angle decreases as the distance between the plates increases, wherein the glass plate is characterized in that the upper surface and the lower surface are simultaneously stretched how to do it with According to claim 1,
Method, characterized in that the angle between the two plates is reduced by 1 to 45 °. According to claim 1,
Method characterized in that the bending reference line is set in the existing upper surface of the glass plate to be bent. According to claim 1,
The plate is a method, characterized in that the angle is adjusted by raising or lowering one side of each plate. According to claim 1,
The method of claim 1 , wherein the glass is heated using preheating, plate heating and bending area heating. 6. The method of claim 5,
The glass is a method characterized in that the lower surface is heated by the plate, the upper surface is heated by the cover plate. A plate portion comprising a first plate and a second plate; and
a heating unit for heating the bending area of the glass to a bending temperature;
Including; and a control unit for adjusting the inclination and position of at least one plate so that the distance between the first plate and the second plate decreases while increasing the distance.
Here, the glass plate seated on the plate portion is a glass bending device, characterized in that the upper surface and the lower surface are simultaneously stretched. 8. The method of claim 7,
The glass bending device is a glass bending device, characterized in that the existing bending reference line is set on the upper surface of the glass plate to be bent. 9. The method of claim 8,
The plate is a glass bending device, characterized in that it comprises an upper plate on which the glass is seated, a lower plate to be heated, and an air layer. 8. The method of claim 7,
The heating unit is a glass bending device, characterized in that the light heater. 8. The method of claim 7,
The heating unit glass bending device further comprising a plate for heating the upper surface. [Claim 12] The glass bending device according to claim 11, wherein the upper surface heating plate comprises two plates fixed to the first plate and the second plate, respectively. The method of claim 7, wherein the adjusting unit
A plate material fixed to the lower end of the plate,
an adjustment device for adjusting the angle and position of the plate; and
a control unit for controlling the regulating device
A glass bending device comprising a. The method of claim 7, wherein the adjusting unit
A first axis of rotation located on the upper portion of the two plates,
a first pivot arm having one side coupled to the first pivot shaft and the other end coupled to one plate;
a second rotational axis positioned on the same axis as the first rotational axis and rotating in the opposite direction;
a second pivot arm having one side coupled to the second pivot shaft and the other end coupled to the other plate, and having the same length as the first pivot arm, and
A control unit for controlling the degree of rotation of the rotation shaft
A glass bending device comprising a.

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