KR100744648B1 - Laser beam shaping module - Google Patents

Abstract

A module for shaping a laser beam is provided to implement miniaturization by deforming Gaussian laser beam to flap top or ring type laser beam through reflection and refraction. A module for shaping a laser beam includes a body(10), a spectrum body(20), a reflector(30), and a refractive body(40). The body(10) with a flat cylinder shape changes the laser beam inputted to the inside of the body(10) to mutually progress in parallel by being made of a material with light permeability. The spectrum body(20) with a cone shape is protruded at a side where the laser beam of the body(10) enters. One part of the laser beam inputted at a side of the spectrum body is reflected and the other part of the laser beam is refracted to move to the body(10) by coating a surface of the spectrum body(20) with a light reflecting material. The reflector(30) is protruded on the body(10) to be positioned at a right side of the spectrum body(20). An opening unit(35) is formed to make the laser beam enter the spectrum body(20) on one side of the reflector(30). The refractive body(40) with the cone shape is protruded in an opposite side of the spectrum body(20) of the body(10) and a form and the size of the refractive body(40) are the same as the form and the size of the spectrum body(20).

Description

Laser Beam Shaping Module

1 and 2 are a perspective view showing the appearance of the laser beam shaping module according to a preferred embodiment of the present invention,

3 is a cross-sectional view showing the internal structure of a laser beam shaping module according to a preferred embodiment of the present invention;

Figure 4 is an exemplary view showing a form that the laser beam proceeds through the laser beam shaping module according to a preferred embodiment of the present invention.

5 is an exemplary view showing a laser beam progressing through a laser beam shaping module according to another embodiment of the present invention.

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

10: main body 20: spectroscopy

30: reflector 35: opening

40: refractive body 50: laser beam shaping module

The present invention relates to a laser beam shaping module, and more particularly, a laser beam shaping is performed by causing a Gaussian-type laser beam to be reflected and refracted by each of the mutually optimized components to be transformed into a flap-top type laser beam. The present invention relates to a laser beam shaping module that can realize miniaturization of an entire device, and also, that each component for laser beam shaping is made of the same material.

In general, laser beam shaping refers to a deformation of a Gaussian type laser beam into a flap top or ring type laser beam, and includes a fly's eye lens type, an aspherical type, and a deflection type.

Compared to other methods, the fly's eye lens method is relatively inexpensive and has advantages in that it can be used even if the profile of the laser light source is changed. Increasing the strength (intensity) has a disadvantage, such as breakage of the joint between the fly-eye lens.

The aspherical method is a method of shaping a laser beam by using two aspherical lenses. Although the beam shaping performance is excellent, it is difficult to manufacture the aspherical lens precisely and difficult to use when changing the laser profile. It is pointed out as a disadvantage.

The deflection method is a method of shaping a laser beam using a deflection element. The deflection method is excellent in shaping performance but has a high price.

In addition, the conventional laser beam shaping methods have a large size disadvantage due to their structural limitations. In particular, in the case of the aspherical surface, the length thereof is about 262 mm or more, and it is difficult to be incorporated into the miniaturization device.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a laser beam shaping means that can realize the miniaturization of the entire device for laser beam shaping.

Furthermore, another object of the present invention is to provide a laser beam shaping means that is easy to manufacture, each component is made of the same material for the laser beam shaping.

According to an aspect of the present invention, there is provided a laser beam shaping means for transforming a Gaussian type laser beam into a flap top type laser beam, the body comprising a light transmitting material; A convex protrusion is formed on the side where the laser beam of the main body enters, and the surface is partially coated with a light reflecting material so that some of the laser beams are reflected and the other part is refracted to proceed on the main body. Wow; It is formed to protrude to the main body so as to be located outside the spectroscope, an opening is formed on one side for entering the laser beam into the spectroscope, the inner surface is coated with a reflective material and the laser beam reflected from the spectroscope again A reflector for reflecting and traveling on the main body in parallel with the laser beam entering through the opening; A refractor formed protruding in a conical shape on the side opposite to the spectroscope of the main body so that the laser beam refracted by the spectroscope is refracted again and proceeds in parallel with the laser beam reflected from the reflector; Characterized in that configured.

The present invention having such a feature will be more clearly described through the preferred embodiment accordingly.

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

1 and 2 are perspective views showing the appearance of the laser beam shaping module according to the present invention, Figure 3 is a cross-sectional view showing the internal structure of the laser beam shaping module according to the present invention, Figure 4 is a laser beam shaping according to the present invention This is an exemplary view showing a form in which the laser beam proceeds through the module.

As shown, the laser beam shaping module 50 according to the present invention is for transforming a Gaussian type laser beam into a flap top type laser beam, the body 10, the spectrometer 20, and the reflector 30. And a refractive body 40.

The main body 10 has a shape of a substantially flat cylinder, and is made of a light-transmissive material, so that the laser beams traveling inwardly parallel to each other in a straight line form.

The spectroscopic body 20 is formed to protrude on the side (left side in the drawing) into which the laser beam of the main body 10 enters, and has a conical shape in shape. The surface of the spectroscope 20 is coated with a light reflecting material so that a part of the laser beam entering the spectroscope 20 is reflected, and the other part (the rest) is refracted and proceeds onto the main body 10. . Here, the amount of the reflected laser beam and the refracted laser beam among the laser beam entering the spectroscope 20 is determined according to the type, particle size, distribution and density of the reflective material coated on the surface of the spectroscope 20. Here, the surface of the spectroscope 20 is preferably coated so that 70% of the incoming laser beam is reflected and the rest (30% of the incoming laser beam) is refracted toward the main body 10 side. Do.

In addition, the angle of the spectroscope 20 reflects from the vertex of the cone in cross section according to the internal angle α formed by both inclined planes, and at this time, the cone of the cone 20 in the spectroscope 20 to induce vertical reflection It is preferable that the interior angle which both inclined surfaces form from a vertex falls in the range of 35 degrees-55 degrees.

The reflector 30 is formed to protrude from the main body 10 so as to be located outside the spectroscope 20, and an opening 35 is formed at one side thereof to enter a laser beam into the spectroscope 20. do. Here, the diameter of the opening 35 is preferably set to be the same as the bottom surface of the cone constituting the spectroscope 20 so that all the incoming laser beam can be guided to the spectroscope 20.

In addition, the inner surface of the reflector 30 and the inclined surface of the spectroscope 20 should be parallel to each other, which means that the laser beam reflected from the spectroscope 20 is reflected by the inner surface of the reflector 30 so that the main body When proceeding to the (10) side, to achieve a horizontal (hereinafter referred to as a horizontal progression) with the laser beam entering through the first opening 35.

As described above, the reflector 30 has a shape in which the vertex of the cone is omitted. As described above, the inner surface of the reflector 30 is coated with a reflective material so that the laser beam reflected from the spectroscope 20 is reflected again. In addition, an angle β of both inclined surfaces of the spectroscope 20 forms an angle β formed between both inner surfaces of the spectroscope 20 so that the reflected laser beam travels on the main body 10 in parallel with the laser beam entering through the opening 35. It should be in the range of 35 ° to 55 ° to be equal to the angle α. Of course, here, the inner surface of the reflector 30, unlike the surface of the spectroscope 20 described above, should be coated so that all incoming laser beams are reflected.

On the other hand, the refractor 40 is formed to protrude in a conical shape on the side opposite to the spectroscope 20 of the main body 10, in the shape and size, the same as the spectroscope 20 Is formed. Therefore, the angle γ formed by the two inclined surfaces from the vertex of the cone on the cross section of the refraction body 40 is in the range of 35 ° to 55 °.

The refraction body 40 as described above causes the laser beam refracted by the spectroscope 20 to be refracted again and proceed in parallel with the laser beam reflected from the reflector 30.

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Hereinafter, a process of transforming a Gaussian type laser beam into a flat top type laser beam by the configuration and structure described above will be described.

Initially, when the laser beam enters through the opening 35 of the reflector 30, the laser beam is reflected on the surface of the spectroscope 20 or refracted by the spectroscope 20 to continue onto the body 10. Proceed.

First, referring to the movement path of the laser beam reflected from the surface of the spectroscope 20, the reflected laser beam is reflected again on the inner surface of the reflector 30 and proceeds horizontally onto the main body 10. As a result, the laser beam is reflected on the surface of the spectroscope 20 and vertically moved as described above, so that the laser beam is separated on both sides of the spectroscope 20 on the main body 10. The laser beam does not proceed in the central portion of the main body 10.

In addition, the laser beam refracted by the spectroscope 20 is linearly inclined at a predetermined angle on the main body 10 and is then horizontally advanced by the refraction body 40 located on the opposite side of the spectroscope 20. do. Here, although the laser beam enters near the vertex of the spectroscope 20, the laser beam proceeds inclined on the main body so that the laser beam proceeds to a position spaced apart from the vertex of the refraction body 40.

Here, if the laser beam refracted at a specific portion of the spectroscope 20 is to proceed to the center of the refractor 40, the portion is coated with a reflective material so that the laser beam is the refractor 40 It can block the progression to the center of or close to).

Such a structure allows the laser beam to be entered on the basis of the spectroscope 20 to be separated to both sides, and blocks the progress of the laser beam at a vertex or a position adjacent thereto, and thus, a Gaussian form. The laser beam is converted into a laser beam in the form of a flap top.

Meanwhile, according to the present invention, when the coating of the spectroscope 120 is different (coating over the entire surface), it is possible to change the laser beam into a ring type.

In this case, the main body 110, the spectroscope 120, the refractor 140, and the reflector 130 may be coupled to each other to form the laser beam shaping module 150 in the same structure as described above.

However, the surface of the spectroscope 120 is coated so that 100%, that is, all of the laser beam is reflected. Therefore, the incoming laser beam does not proceed to the refraction body 140, but is all reflected by the spectroscope 120, and is also reflected by the reflector 130 again to the main body 110. In other words, the laser beam traveling outward from the main body 110 has a ring type shape.

As described above, the present invention is the entire apparatus for shaping the laser beam by allowing the advanced Gaussian-type laser beam is reflected and refracted by each of the components of the mutually optimized arrangement to be transformed into a flap top or ring-type laser beam There is an effect that can be miniaturized.

In addition, the present invention has the advantage that each component is made of the same material for the laser beam shaping, easy to manufacture.

Claims (7)

A laser beam shaping means for transforming a Gaussian type laser beam into a flap top or ring type laser beam, Body 10 and 110 made of a light transmissive material; Protrudingly formed in the conical shape on the side of the laser beam entering the main body (10,110), the surface is coated with a light reflecting material to reflect or refract the laser beam to enter the main body (10,110) Ores 20 and 120; Protruding to the main body (10,110) so as to be located outside the spectroscope (20,120), one side is formed with an opening 35 for entering a laser beam into the spectroscope (20,120), the inner surface of the reflective material A reflector (30,130) which is coated with and which causes the laser beam reflected from the spectroscope (20,120) to be reflected again and propagates onto the main body (10,110) in parallel with the laser beam entering through the opening (35); A laser beam protruding in a conical shape on the side opposite to the spectroscopes 20 and 120 of the main body 10 and 110 and refracted by the spectroscopes 20 and 120 is refracted again and reflected from the reflectors 30 and 130. Refractors 40, 140 to proceed in parallel with the; Laser beam shaping module, characterized in that configured to include. The method of claim 1, Laser beam shaping module, characterized in that the spectroscopic body (20,120) and the refractors (40,140) have the same size and shape. The method of claim 2, The spectroscopic body (20,120) and the refraction body (40,140) is a laser beam shaping module, characterized in that the internal angle formed by the two inclined surfaces from the vertex of the cone in the cross section 35 ° ~ 55 °. The method of claim 1, Laser beam shaping module, characterized in that the surface of the spectroscope 20 is coated so that 70% of the incoming laser beam is reflected, the rest is refracted. The method of claim 1, The surface of the spectroscope (120) is a laser beam shaping module, characterized in that the coating so that all incoming laser beams are reflected. The method of claim 1, Laser beam shaping module, characterized in that the inner surface of the reflector (30,130) and the inclined surface of the spectroscope (20,120) are parallel to each other in cross section. delete

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