KR20010065390A - A apparatus for cut-off of glass by laser beam - Google Patents

Abstract

PURPOSE: A glass cutting device by using laser beam is provided which improves the speed for cutting and straightness of the glass by installing a laser preheating equipment on the front side of a laser cutting equipment or an auxiliary laser equipment on the rear side of the laser cutting equipment. CONSTITUTION: The glass cutting device comprises: (i) a work bench(T1) which fixes a flat glass to be cut(G1) and moves the glass; (ii) a laser preheating equipment(11) which is placed on the upper side of the glass having regular intervals and generates preheating laser beam(S11) to partially preheat the cutting part of the glass; (iii) a laser cutting equipment(12) which is placed on the rear side of the laser preheating equipment and generates cutting laser beam(S12) on the preheated cutting part of the glass; and (iv) a cooling equipment which is placed on the rear side of the laser cutting equipment and sprays cooling agent(S13) through a cooling nozzle(13) on the heated glass to cut the glass.

Description

Glass cutting apparatus using a laser beam {A apparatus for cut-off of glass by laser beam}

The present invention relates to a glass cutting apparatus using a laser beam to heat the cut portion of the flat glass by using a laser beam and then cool it to be cut. In particular, a pre-heating laser and a cutting laser are separately installed to cut the glass. The present invention relates to a glass cutting apparatus using a laser beam that can locally increase preheating to increase tensile stress and improve straightness and cutting speed.

Recently, with the development of glass processing technology, glass of various sizes and shapes has been provided for ornaments including electronic products and household goods. Among such glass processing techniques, the cutting process for determining the processing quality as a basic process is performed in various ways.

1 is a view showing the configuration of a glass cutting apparatus using a laser beam according to the prior art, Figure 1 (a) is a view showing the emission form of the laser beam and the injection form of the coolant, Figure 2 Figure is a cross-sectional view of the laser heating portion which is a component of the.

1 and 2, a laser heating unit 2 that emits a laser beam to heat a cut portion of the flat glass 1, and a plate glass 1 heated by the laser heating unit 2. Cooling sprayer (not shown) which injects a cooling water or a cooling gas through the cooling nozzle 3 so that it may be cut | disconnected by severe cooling.

In particular, the laser heating unit 2 is a spherical-cylindrical lens capable of concentrating the energy density of the laser beam emitted as shown in FIG. 2 to the heating portion of the flat glass 1. Lens 2 'is built in.

Therefore, in the case of cutting the flat glass 1, after the cut portion is heated using the laser heating unit 2, the cooling sprayer sprays the cooling water or the cooling gas through the cooling nozzle 3 while the laser heating unit is sprayed. It is moved coaxially with (2) to severely cool the heating part of the flat glass 1 to be cut.

However, since the heat distribution characteristic of the laser beam has Gaussian characteristics, the laser beam is emitted from the laser heating unit 2 in an elliptic form at the cut portion of the flat glass 1, and in particular, FIG. Heat is concentrated in the center of the ellipse shape as shown on the left side of).

On the other hand, conventionally, before cutting the flat glass 1, the flat glass 1 is cut directly using the laser heating unit 2 without a separate preheating process, or in some cases, the entire flat glass 1 is cut. After heating at about 100 degreeC, the flat glass 1 is cut | disconnected using the laser heating part 2. As shown in FIG.

Therefore, since there is conventionally provided heat for cutting the flat glass 1 only by the laser beam of the laser heating unit 2 when there is no preheating step, in order to sufficiently heat the cut portion of the flat glass 1. There is a problem in that time is consumed, and when the entire flat glass 1 is heated to about 100 ° C., a preheating process for cutting the flat glass 1 is additionally added, and unnecessary energy is consumed.

The present invention has been made to solve the above problems of the prior art, the object of which is to install a laser preheating mechanism for preheating in front of the laser cutting tool for providing the cutting heat required for glass cutting, or to the rear of the laser cutting tool It is to provide a glass cutting apparatus using a laser beam that can improve the cutting speed and straightness of the glass by providing an auxiliary laser mechanism for increasing the tensile stress.

1 is a configuration of a glass cutting apparatus using a laser beam according to the prior art, Figure 1 (a) is a view showing the emission form of the laser beam and the injection form of the coolant,

2 is a cross-sectional view of a laser heating unit, which is a part of FIG. 1;

Figure 3a is a perspective view showing the configuration of a first embodiment of a glass cutting device using a laser beam according to the present invention,

FIG. 3B is a plan view showing a laser cutting tool, a laser preheating mechanism, a laser beam and a coolant spraying form appearing on the flat glass which is a part of FIG. 3A;

Figure 4 is a graph showing the cutting speed vs. temperature of the flat glass according to Figure 3a and 3b,

5 is a perspective view showing the configuration of a second embodiment of a glass cutting device using a laser beam according to the present invention,

FIG. 6A is a plan view showing an embodiment of a laser cutting tool, an auxiliary laser device, a laser beam by a cooling device, and a coolant jet form appearing on the flat glass of some components of FIG. 5;

FIG. 6B is a plan view showing another embodiment of a laser cutting tool, an auxiliary laser device, a laser beam by a cooling device, and a coolant jet form appearing on the flat glass part of the components of FIG. 5; FIG.

<Explanation of symbols on main parts of the drawings>

11: laser preheating mechanism 12, 21: laser cutting tool

13, 23: cooling nozzle 22a, 22b: auxiliary laser mechanism

G1, G2: Flat Glass T1, T2: Work Table

S11 to S23: Distribution form of laser beam and coolant according to each embodiment

According to a first aspect of the glass cutting apparatus using a laser beam according to the present invention for solving the above problems, the worktable for fixing the glass to be cut to move to the cutting position, and positioned at a predetermined distance from the upper side of the glass A laser preheating mechanism for generating and outputting a preheating laser beam for locally preheating the cut portion of the glass, and for cutting into a cut portion of the glass preheated by the preheating laser beam located at a rear side of the laser preheating mechanism. And a laser cutting tool for generating and outputting a laser beam, and a cooling mechanism positioned at a rear side of the laser cutting tool and spraying a coolant through a cooling nozzle to quench the heated glass.

In addition, according to the second aspect of the present invention, the worktable for fixing the glass to be cut to move to the cutting position, and is positioned at a predetermined distance from the top of the glass to generate a laser beam for cutting to the cut portion of the glass A laser cutting tool for generating and outputting an auxiliary laser beam for weighting a tensile stress on a cut portion of the glass heated by the cutting laser beam, the laser cutting tool being positioned at a rear side of the laser cutting tool; And a cooling mechanism positioned at a rear side of the cooling mechanism to spray coolant through the cooling nozzle to quench the heated glass.

According to an additional feature of the second aspect, the laser assist mechanism is formed in each of the rear both side portions of the laser cutting tool.

In addition, the shape of the laser beam formed by the laser cutting tool and the laser assist mechanism is formed in any one of a U-shape or a triangular form.

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

3A, 3B, and 4 illustrate a first embodiment of a glass cutting apparatus using a laser beam according to the present invention. After fixing the flat glass G1 to be cut, the work table T1 moves to the cutting position, and is positioned at a predetermined interval above the flat glass G1 to locally cut the cut portion of the flat glass G1. A laser preheating mechanism 11 for generating and outputting a preheating laser beam S11 for preheating, and the flat glass G1 located at a rear side of the laser preheating mechanism 11 and preheated by the preheating laser beam S11. Laser cutting tool 12 for generating and outputting the laser beam S12 for cutting to the cut portion of the laser beam; and located at the rear side of the laser cutting tool 12 to spray the coolant S13 through the cooling nozzle 13 It consists of a cooling mechanism (not shown) in which the heated glass is quenched.

In particular, the temperature of the preheating laser beam (S11) is preferably about the same as the temperature of the cutting laser beam (S12). As shown in FIG. 3B, the preheating laser beam S11 locally preheats the cut portion of the flat glass G1, and the cutting laser beam S12 cuts the cut portion of the flat glass G1. Since it provides heat for cutting intensively, it can be seen that the length perpendicular to the cutting line of the flat glass G1 is much smaller than the cutting laser beam S12.

In addition, when the flat glass G1 is cut after being preheated by the laser preheating device 11, it can be seen that the cutting speed is significantly improved as shown in FIG. 4.

In this case, the laser preheating mechanism 11, the laser cutting tool 12, and the cooling mechanism sequentially cut the flat glass G1 while being coaxially moved in a direction 'A', which is the cutting direction of the flat glass G1.

In the operation of the first embodiment described above, first, when the flat glass G1 fixed by the work table T1 is moved to the working position, the laser preheating mechanism 11 performs a preheating laser on the cut portion of the flat glass G1. The beam S11 is generated and output. Thereafter, the laser beam S12 for cutting is generated and output through the laser cutting tool 12 at the cut portion of the plate glass G1 preheated locally by the laser preheating mechanism 11, thereby causing the plate to be cut. The cut portion of the glass G1 is to be heated to an appropriate temperature upon cutting quickly.

The cooling mechanism, which is coaxially moved from the rear side of the laser cutting tool 12, sprays the coolant S13 through the cooling nozzle 13 to the cut portion of the flat glass G1 heated to a predetermined temperature. The cut portion of) is rapidly cooled and cut.

Next, the second embodiment of the present invention shown in Figs. 5 and 6 is an auxiliary laser mechanism 22a for assisting the laser cutting tool 21 to cut the flat glass G2 fixed on the work table T2. 22b) is located behind the laser cutting tool 21, and at the same time, two are provided at both rear sides of the laser cutting tool 21, which are different from the above-described first embodiment.

That is, the cut portion of the flat glass G2 is heated by the cutting laser beam S21 generated and output from the laser cutting tool 21, and is located behind the laser cutting tool 21 while cutting the laser. Tensile stress is further applied to the cutting end of the flat glass G2 by the auxiliary laser beams S22a, S22a ', S22b and S22b' generated and output from the auxiliary laser mechanisms 22a and 22b coaxially moved with the mechanism 21. Weighted.

Thus, the shape of the auxiliary laser beams (S22a, S22a ', S22b, S22b') to increase the tensile stress is the auxiliary laser beam (S22a, S22a, around the rear end of the cutting laser beam (S21) as shown in Figure 6a) Both ends of the S22b may be collected so that the cutting laser beams S and the auxiliary laser beams S22a and S22b may have a 'Ｙ' shape as a whole.

Meanwhile, as shown in FIG. 6B, the auxiliary laser beams S22a 'and S22b' are arranged in parallel with each other in close proximity to the cutting laser beam S21, thereby cutting the laser beam S21 and the auxiliary laser beam S22a. ', S22b') may be formed to have a 'Δ' shape as a whole.

A cutting mechanism of the flat glass G2 heated by the laser cutting tool 21 and the auxiliary laser mechanisms 22a and 22b is coaxially moved behind the auxiliary laser mechanisms 22a and 22b (not shown). Is quenched and cut by the coolant (S23) sprayed through the cooling nozzle (23).

As a result, the present invention is a laser cutting tool after preheating the cut portion of the flat glass (G1, G2) through the laser preheating mechanism 11 to improve the cutting speed and straightness of the flat glass (G1, G2) (12) to provide the heat necessary for cutting, or to provide the heat necessary for cutting to the cut portion of the flat glass (G1, G2) through the laser cutting tool 21 so that the tensile stress is increased at the cutting end thereof. The auxiliary laser mechanisms 22a and 22b provide auxiliary heat.

In the glass cutting apparatus using the laser beam of the present invention configured as described above, a preheating mechanism is installed in front of the laser cutting tool that provides the cutting heat necessary for cutting the glass to generate and output a preheating laser beam, or the rear of the laser cutting tool. An auxiliary laser mechanism is installed on the side to generate and output an auxiliary laser beam that increases the tensile stress, thereby improving the cutting speed and the straightness of the glass.

Claims (4)

A working table for fixing the glass to be cut and moving to a cutting position, a laser preheating mechanism which is positioned at a predetermined distance from the top of the glass and generates and outputs a preheating laser beam that locally preheats the cut portion of the glass; A laser cutting tool positioned at a rear side of the laser preheating mechanism to generate and output a cutting laser beam to a cut portion of the glass preheated by the preheating laser beam; Glass cutting apparatus using a laser beam, characterized in that configured to include a cooling mechanism to quench the heated glass by spraying. A worktable for fixing the glass to be cut to a cutting position, a laser cutting tool positioned at a predetermined distance from the top of the glass to generate and output a laser beam for cutting to the cut portion of the glass, and An auxiliary laser device positioned at the rear side to generate and output an auxiliary laser beam in order to add tensile stress to the cut portion of the glass heated by the cutting laser beam, and positioned at the rear side of the auxiliary laser device to cool the coolant through a cooling nozzle. Glass cutting apparatus using a laser, characterized in that it comprises a cooling mechanism for spraying and quenching the heated glass. The method of claim 2, The auxiliary laser mechanism is a glass cutting device using a laser, characterized in that each formed on both rear portions of the laser cutting tool. The method according to claim 1 or 2, The shape of the laser beam formed by the laser cutting tool and the auxiliary laser mechanism is a glass cutting device using a laser, characterized in that formed in any one of the U-shaped or triangular form.