KR100693945B1 - Infinity loop type laser beam cutting apparatus and cutting method using the same - Google Patents

Abstract

An infinite loope type laser beam cutting system capable of reducing the cost required for producing the laser beam by collecting and returning a laser beam that transmits glass and reusing the returned laser beam, and an infinite loope type laser beam cutting method using the same are provided. In a laser cutting system for cutting glass(40) using a laser beam generated from a laser beam generator(10), an infinite loope type laser beam cutting system comprises: a first optical fiber member(20) of which one end is connected to the laser beam generator, and of which the other end is disposed on an upper part of the glass; a beamsplitter(30) disposed between the other end of the first optical fiber member and the glass to split the laser beam; and a second optical fiber member(50) of which one end is disposed in a lower part of the glass, and of which the other end is disposed at a side part of the beamsplitter such that a laser beam that transmits the glass is returned to the glass again by the beamsplitter. The infinite loope type laser beam cutting system further comprises: a third collimator(63) installed between the first optical fiber member and the beamsplitter; a first collimator(61) and a first condenser lens(71) vertically installed between the beamsplitter and the glass; and a second collimator(62) and a second condenser lens(72) vertically installed between the glass and the second optical fiber member.

Description

INFINITY LOOP TYPE LASER BEAM CUTTING APPARATUS AND CUTTING METHOD USING THE SAME}

1 is a structural diagram of a laser cutting device according to an embodiment of the present invention,

2 is a flow chart of the infinite loop laser cutting method according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: laser beam generator, 20: first optical fiber member,

22, 52: isolator, 30: beam splitter,

40: glass, 50: second optical fiber member,

61: first collimator, 62: second collimator,

63: third collimator, 71: first condenser lens,

72: a second condenser lens,

S10: investigation step, S20: collection step,

S30: return phase, S40: re-investigation phase.

The present invention relates to an endless loop type laser cutting device and a cutting method using the same, and more particularly, to an endless loop type laser cutting device and a cutting method using the same by returning a laser beam transmitted through glass.

Liquid crystal displays (LCDs), plasma display panels (PDPs), and organic light emitting diodes (OLEDs) use glass substrates.

In order to cut such glass, conventionally, the glass was cut using a diamond wheel, which causes defects in products due to scattering of fine glass fragments generated during cutting, and causes many problems such as cracks or scratches. The glass, ie, the glass, is cut by using.

An apparatus and method for cutting glass using a laser, when irradiating a laser from the top of the glass, absorbs the energy of the laser in the glass, thereby causing the glass to thermally expand and cut.

However, such a conventional laser cutting device is a laser beam irradiated to the glass is not recycled after passing through the glass is extinguished, so to continuously irradiate the laser beam must continue to produce a laser beam and accordingly the production cost There was a much needed problem.

The present invention has been made to solve the above-mentioned problems, endless loop type laser cutting device that can reduce the cost required for the production of the laser beam by collecting and returning to the laser beam transmitted through the glass and using the same The purpose is to provide a cutting method.

In order to achieve the above object, the infinite loop type laser cutting device of the present invention, in the laser cutting device for cutting the glass using the laser beam generated in the laser beam generator, one end is connected to the laser beam generator, A first optical fiber member having the other end disposed on the glass; A beam splitter disposed between the other end of the first optical fiber member and the glass to split a laser beam; One end is disposed under the glass, and the other end is disposed on the side of the beam splitter, and the second optical fiber member is configured to cause the laser beam transmitted through the glass to be returned back to the glass by the beam splitter.

A third collimator is installed between the first optical fiber member and the beam splitter.

In addition, a first collimator and a first condenser lens are disposed vertically between the beam splitter and the glass, and a second collimator and a second condenser lens are disposed vertically between one end of the glass and the second optical fiber member. have.

An isolator is mounted at the other end of the first optical fiber member and the other end of the second optical fiber member.

In order to achieve the above object, the infinite loop laser cutting method of the present invention includes a method for cutting a glass using a laser cutting device, comprising: irradiating a laser beam to the glass using the laser cutting device; A collecting step of collecting the laser beam passing through the glass; A feedback step of returning the collected laser beam; And a re-irradiation step of irradiating the glass back to the glass.

At this time, the re-irradiation step, to irradiate the glass with the laser beam irradiated in the irradiation step and the laser beam fed back in the feedback step.

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

1 is a structural diagram of a laser cutting device according to an embodiment of the present invention.

As shown in FIG. 1, the laser cutting device of the present invention cuts the glass 40 used for LCD, PDP, etc., thereby, the laser beam generator 10, the first optical fiber member 20, and the beam splitter. (Beamsplitter 30), the second optical fiber member 50, isolators (22, 52), collimators (61, 62, 63), condenser lenses (71, 72) and the like.

The laser beam generator 10 is a device for generating a laser beam, it is preferable that the device for generating a yag (YAG) laser beam of 1030nm, the structure is the same as the conventional yag laser generator 10.

The use of the yag laser beam as described above is because the yag laser has a high transmittance, so as to be described later, the glass 40 can be easily transmitted and collected in the second optical fiber member 50 and reused.

Yagraser is a name that is named after yttrium (Y), aluminum (A) and garnet (G), and uses a garnet-like gemstone. It has a small wavelength and high transmittance.

The first optical fiber member 20 has an optical fiber inserted therein, one end of which is connected to the laser beam generator 10, and the other end of which is disposed above the beam splitter 30.

The beam splitter 30 is disposed between the other end of the first optical fiber member 20 and the glass 40 to divide the laser beam, so that the split ratio can be arbitrarily adjusted by the user.

In the present invention, it is preferable that a part of the laser beam is transmitted to the beam splitter 30 and the other part is set to be reflected by the beam splitter 30.

Similar to the first optical fiber member 20, the second optical fiber member 50 has an optical fiber inserted therein, one end of which is disposed below the glass 40, and the other end of the second optical fiber member 20 has the beam splitter 30. It is arranged on the side of.

Therefore, the laser beam transmitted through the glass 40 is input back to the side of the beam splitter 30 through the second optical fiber, and a part of the input laser beam passes through the beam splitter 30 and the other part thereof. Is reflected and re-irradiated to the glass 40 again.

Arrows in FIG. 1 indicate the traveling direction of the laser beam.

At this time, the isolators 22 and 52 are preferably mounted on the other end of the first optical fiber member 20 and the other end of the second optical fiber member 50, respectively.

The isolators 22 and 52 are circuit elements used as microwave or light wave transmission circuits, and have a function of transmitting electromagnetic waves in one direction of the transmission line but not in the opposite direction.

Laser beams reflected by the beam splitter 30 by the isolators 22 and 52 may be prevented from entering the other end of the first optical fiber member 20 or the other end of the second optical fiber member 50. have.

A third collimator 63 is disposed between the other end of the first optical fiber member 20 and the beam splitter 30, and a first collimator (between the beam splitter 30 and the glass 40). 61 and the first condenser lens 71 are disposed up and down, and a second collimator 62 and a second condenser lens 72 are disposed between the glass 40 and one end of the second optical fiber member 50. Make sure it is installed up and down.

The collimators 61, 62 and 63 are known optical devices for forming parallel rays, and the condensing lenses 71 and 72 are made of convex lenses that collect light rays.

As described above, the third collimator 63 is installed between the other end of the first optical fiber member 20 and the beam splitter 30, so that the laser beam irradiated through the first optical fiber member 20 through the optical fiber. Since it is radiated, it is slightly dispersed and radiated. The laser beam may be converted into parallel rays by passing through the third collimator 63 and introduced into the parallel beams in the beam splitter 30.

In addition, the first collimator 61 and the first condenser lens 71 are disposed vertically between the beam splitter 30 and the glass 40 so that the laser beam that has passed through the beam splitter 30 is received. The first collimator 61 converts the light into parallel rays again, and narrows the width by the first condenser lens 71 to irradiate the glass 40.

Then, the second collimator 62 and the second condenser lens 72 are provided between one end of the glass 40 and the second optical fiber member 50, so that the laser beam transmitted through the glass 40 While passing through the second collimator 62, the light is converted into parallel rays again, which are then focused again by a narrow laser beam while passing through the second condenser lens 72 to one end of the second optical fiber member 50. It can be easily collected.

At this time, by adjusting the height of the collimator (61, 62, 63) and the condenser lens (71, 72) it is possible to adjust the light condensing area of the energy, thereby enabling the adjustment of the cutting width can be precision processing.

2 is a flow chart of the infinite loop laser cutting method according to an embodiment of the present invention.

As shown in Figure 2, the cutting method of the present invention, the irradiation step (S10), the collection step (S20), the return step (S30), the re-irradiation step (S40).

The irradiation step (S10) is a step of irradiating a laser beam on the glass 40 using the laser cutting device.

The collecting step S20 is a step of collecting the laser beam transmitted through the glass 40.

The feedback step (S30) is a step of returning the collected laser beam back to the beam splitter 30.

The re-irradiation step (S40) is a step of irradiating the returned laser beam to the glass 40, and the re-irradiation step (S40) is a laser beam irradiated in the irradiation step, and the feedback is returned at the feedback step. The laser beam is irradiated onto the glass 40 together.

Hereinafter, the operation of the device as described above using the method described above.

First, the laser beam generated by the laser beam generator 10 moves through the first optical fiber member 20, which is radiated through the other end of the first optical fiber member 20, and the third collimator 63. ) Is converted into parallel rays and introduced into the beam splitter 30.

The laser beam introduced into the beam splitter 30 is partially reflected, and the rest of the laser beam is transmitted to the glass 40.

At this time, the laser beam irradiated to the glass 40 by the first collimator 61 and the first condenser lens 71 is converted into parallel light and then focused and irradiated onto the glass 40.

A portion of the laser beam irradiated onto the glass 40 is absorbed by the glass 40, and a portion of the laser beam passes through the glass 40.

The laser beam that has passed through the glass 40 is collected by the second collimator 62 and the second condenser lens 72 and flows into one end of the second optical fiber member 50.

The introduced laser beam travels along the second optical fiber member 50 and is radiated to the side of the beam splitter 30 through the other end of the second optical fiber member 50.

The laser beam emitted to the side of the beam splitter 30 is partially reflected and the other part is transmitted. At this time, the laser beam reflected by the beam splitter 30 is irradiated onto the glass 40 again.

In this case, a part of the laser beam flowing into and passing through the beam splitter 30 through the other end of the second optical fiber member 50 and the beam splitter 30 through the other end of the first optical fiber member 20. A portion of the laser beam that is introduced into and reflected by the light is irradiated onto the glass 40 together.

According to the present invention as described above it can be reused by circulating the laser beam transmitted through the glass 40 in an endless loop to save energy, it can reduce the cost of the laser beam production.

Infinite loop type laser cutting device and the cutting method using the present invention is not limited to the above-described embodiment, it can be carried out in a variety of modifications within the scope of the technical idea of the present invention.

According to the infinite loop type laser cutting device and the cutting method using the same of the present invention as described above has the following effects.

First, the laser beam transmitted through the glass can be returned to the glass to achieve the cost reduction required for the production of the laser beam, and the laser beam can be continuously supplied to the glass to be cut to efficiently irradiate energy. This allows the continuous supply of energy for cutting.

Second, by installing a collimator and a condenser lens, it is possible to convert the laser beam into parallel light, to condense the laser beam irradiated to the glass, and to easily accommodate the laser beam at one end of the second optical fiber member. have.

In addition, by adjusting the collimator and the condenser lens, the cutting width can be adjusted according to the condensing region of energy, thereby enabling precision processing.

Third, by mounting the isolator, the laser beam reflected by the beam splitter can be prevented from flowing into the other end of the first optical fiber member or the other end of the second optical fiber member.

Fourth, by generating the yag laser in the laser beam generator, the laser beam can be transmitted through a large amount of glass can increase the effect of the present invention.

Claims (6)

In the laser cutting device for cutting the glass using a laser beam generated by the laser beam generator, A first optical fiber member having one end connected to the laser beam generator and the other end disposed on the glass; A beam splitter disposed between the other end of the first optical fiber member and the glass to split a laser beam; One end is disposed under the glass, and the other end is disposed on the side of the beam splitter, and the second optical fiber member is configured to cause the laser beam transmitted through the glass to be returned back to the glass by the beam splitter. Endless loop type laser cutting device. The method of claim 1, Infinite loop type laser cutting device, characterized in that the third collimator is provided between the first optical fiber member and the beam splitter. The method according to claim 1 or 2, Between the beam splitter and the glass, a first collimator and a first condenser lens are disposed up and down, Infinite loop type laser cutting device, characterized in that the second collimator and the second condensing lens is installed up and down between the glass and one end of the second optical fiber member. The method of claim 1, And an isolator on each other end of the first optical fiber member and the other end of the second optical fiber member. In the method of cutting the glass using a laser cutting device, An irradiation step of irradiating a laser beam on the glass using the laser cutting device; A collecting step of collecting the laser beam passing through the glass; A feedback step of returning the collected laser beam; And a re-irradiation step of irradiating the glass back to the glass with the returned laser beam. The method of claim 5, The re-investigation step, And the laser beam irradiated in the irradiation step and the laser beam returned in the feedback step are irradiated on the glass together.

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