KR20040095602A - The system which emits the laser wave length which is various from one medium - Google Patents

Abstract

PURPOSE: An apparatus for radiating various laser wavelengths from a medium is provided to obtain various lasers from the high-priced medium by installing a plurality of differently coated total reflectors in a resonator. CONSTITUTION: A resonator includes a medium, a plurality of total reflectors, a selector, and a partial reflector. The total reflectors(20) are formed at one end of the medium. The selector(100) is used for selecting one of the total reflectors in order to reflect a desired laser wavelength. The partial reflector(30) is formed at the other end of the medium. The partial reflector is used for radiating the laser wavelength to the outside through the total reflector selected by the selector and a reflection path. A motor(110) is installed at the selector in order to rotate the total reflectors.

Description

A device that emits various laser wavelengths in one medium {The system which emits the laser wave length which is various from one medium}

The present invention relates to a laser device that can obtain a variety of laser wavelengths in a single medium, and more particularly, by using the transmittance of the total reflection and the partial reflection of the laser device in accordance with the desired laser wavelength according to the transmittance of the total reflector, The present invention relates to a laser device that can be obtained from one device, and efficiently improves the economic burden of maintaining a plurality of laser devices having different laser wavelengths, maintenance, and space utilization according to the volume of the device.

Generally, laser is an abbreviation of "Light Amplification by stimulated Emission of Radiation". It means amplification of light by induced emission process. It is a device that amplifies or oscillates electromagnetic wave of very short wavelength by applying quantum mechanics. The characteristics of the laser are: first, excellent monochromaticity, second, even phase, easy to cause interference, third, straight, without spreading, good light collection, fourth, high energy density.

The principle of this laser generation is that when a substance is in an inverted distribution state, when one atom emits light at a certain moment and moves from the upper excited level to the lower excited level, the other excited atoms are stimulated to have the same wavelength. Light is generated in turn, and when two mirrors are cleaned on both sides of the excited material in parallel, the light reflects between the two mirrors, and the light is reciprocated.

On the other hand, the two parallel mirrors not only cause induced emission, but also create standing waves of light between the mirrors, and only light that meets this condition is amplified, and the amplified wavelength of the light is selected and becomes one, where 1 of the two mirrors is selected. If you make two mirrors that reflect most of the light but only a few percent of the light, only a portion of the amplified light between the mirrors is emitted outside, which is the laser beam.

In the schematic structure of such a laser device, a resonator having a total reflection mirror having a reflectance of 100% and a partial reflection mirror having transmittance and reflectance, and an object filled with a special atom (or molecule) is provided between the resonator. It consists of an amplifier to reciprocate the partial reflector, the light is amplified by the induction process to be a strong light, and the pump is a device that applies the light source energy from the outside so that the amplifier can be amplified.

In addition, depending on the state of the amplifier, it is divided into gas laser, liquid laser, solid laser, semiconductor laser, etc., and there are He-Ne laser, CO2 laser, Ar laser, etc. in the gas laser, and the dye of alcohol and ethylene glycol in the liquid laser. There are dye lasers that dissolve solvents and use them as amplifiers. Solid lasers include ruby and Nd: YAG, and GaAIAs are used for semiconductor lasers. Lasers emitted in the state of each amplifier are different. In addition, according to the type of laser generated, various uses are provided such as laser printers, medical equipment, mechanical equipment and military equipment.

Among them, the present invention mainly describes a laser device using an amplifier (hereinafter referred to as a medium) of a solid laser, which is a kind of laser commonly seen around us, such as laser welding, cutting, and cosmetic molding as a yag (Nd: YAG). It is not limited thereto.

The laser which is commonly oscillated in solid state laser using medium is 1064nm, which is used in various fields such as welding and cutting or removing body hair and hair root of the body. Not only the wavelength of the laser but also not yet identified, various wavelengths can be obtained in one medium.

In addition, the laser oscillated from the identified yag has a laser of 1320nm size and a laser of 964nm size, 1320nm laser is used for cosmetic molding such as wrinkle removal, and 964nm is still in use.

However, the laser device is an expensive device, and the maintenance cost is high along with the device facilities, and there is a problem in that the efficient space utilization is limited by the relative volume.

Accordingly, the inventors of the present invention as a patent application No. 2003-34192 which is the basis of the priority claim that the laser having a different size is emitted from one medium to perform a variety of operations according to the laser size with one laser device 1 is a resonance path diagram of a resonator in which a laser is generated.

Referring to FIG. 1, in the resonator 1 having a total reflection mirror 20 and a partial reflection mirror 30 formed at both ends of the medium 10 and the medium 10, the oscillator 1 oscillates in the resonator 1. The auxiliary device 40 is configured to obtain a laser of another wavelength in addition to the basic laser.

The auxiliary device 40 has a first auxiliary reflector 42 and the first auxiliary reflector coated to have a transmittance so as to convert the reflection path when a laser having a wavelength different from that of the fundamental wavelength is to be obtained. The second auxiliary reflector 44 coated with a reflectance to help amplify and reflect light by means of 42 and the light emitted by the medium 10 are guided through the first and second auxiliary reflectors 42 and 44. The shutter 50 is configured to block the first auxiliary reflector 42 to be amplified.

The shutter 50 provided in the auxiliary reflecting mirror 40 is provided on one side of the first auxiliary reflecting mirror 42 having transmittance, and transmits and blocks as necessary.

Looking at the operating state of the laser device configured as described above, when the medium 10 is to obtain the 1064nm, which is the basic laser wavelength, light is induced and emitted from the medium 10 by the pump 60, the front, partial reflector Light is amplified in the resonator 1 by (20, 30).

At this time, since the auxiliary device portion 40 provided in the resonator 1 is opened without being blocked by the shutter 50, the first auxiliary reflector 42 having a transmittance, before the amplification of the light, the partial reflector 20 ( 30) the first auxiliary reflector (42)-> total reflector (20)-> first auxiliary reflector (42)-> partial reflector (30)-> first auxiliary reflector (42)-> total reflector Reflected by (20)-> first auxiliary reflector 42-> partial reflector 30, light is amplified and a basic laser of 1064 nm wavelength is emitted.

2 is a schematic diagram showing a laser path when the first auxiliary reflector is blocked by a shutter in a conventional resonator. When a laser having a wavelength other than the 1064 nm basic laser is obtained, the shutter 50 of the auxiliary device unit 40 When one end of the first auxiliary reflector 42 is blocked, the light guided and emitted through the medium 10 is reflected by the first auxiliary reflector 42 having a reflectance function by the blocking of the shutter 50 and is provided at one end. The light is transmitted to the second auxiliary reflector 44 having the reflectance so that the second auxiliary reflector 44-> the first auxiliary reflector 42-> the partial reflector 30-> the first auxiliary reflector 42-> The light is amplified while being reflected by the second auxiliary reflector 44, and the laser having one wavelength size is emitted through the partial reflector 30 having transmittance and reflectance.

Therefore, two laser wavelengths can be obtained in one medium, which firstly eliminates the economic burden of having to equip the equipment separately, and reduces the burden on the maintenance of the equipment and the third equipment separately. In this case, there is an advantage in that the limitation of space usage used can be effectively used.

However, in order to obtain another laser, there is a complicated problem in that the first auxiliary reflector 42 and the second auxiliary reflector 44 need to be replaced in the auxiliary unit 40 of the laser device structure.

For example, if a laser of 1064 nm and 1320 nm can be obtained from the first auxiliary reflector 42 and the second auxiliary reflector 44 coated with a single different material, another coated first auxiliary reflector 42 and It is possible to obtain different laser wavelengths such as 1064nm and 936nm only by replacing them with the secondary reflector 44, so that only one laser wavelength can be obtained due to the limitation of the resonator and the auxiliary reflector. There are boundless limitations, and also if you want to obtain a different wavelength, there is a complicated problem of having to replace the other coated secondary reflector.

In addition, the laser has a fatal weakness, such as dust, there is a problem that expensive laser equipment breaks down when the dust penetrates by the operator's mistake when separating the device to obtain another laser as described above.

Accordingly, the present invention is to solve the above problems, the resonator is provided with a plurality of total reflection mirrors with different coating treatment, it is possible to obtain a variety of laser in the expensive medium, various operations can be performed in one device In addition, it is an object to provide a device that emits a variety of laser wavelengths in a single medium that can be maintained and efficient space utilization of the device.

1 is a schematic view showing a conventional resonator;

2 is a schematic diagram showing a laser path after a shutter is operated in a conventional resonator;

3 is a schematic diagram of a resonator according to the present invention;

* Explanation of symbols for the main parts of the drawings *

One ; Resonator 10; medium

20; Total reflection 30; Partial reflector

40; Auxiliary device section 50; shutter

60; Pump 100; Selection

In the resonator provided with a total reflection mirror and a partial reflection mirror formed at both ends of the medium and the medium according to the present invention for achieving the above object, the resonator has a plurality of total reflection mirror formed in one end, the desired laser among the plurality of total reflection mirror And a selection unit for selecting one total reflection mirror to reflect the wavelength, and a partial reflection mirror that is formed at the other end and that emits the laser wavelength to the outside through one total reflection mirror and the reflection path selected by the selection unit.

According to the present invention, it is preferable that a motor is formed in the selection unit to rotate a plurality of total reflection mirrors so as to select one of the desired total reflection mirrors.

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

3 is a schematic configuration diagram of a resonator. In the resonator 1 having a total reflection mirror 20 and a partial reflection mirror 30 formed at both ends of the medium 10 and the medium 10, the resonator ( 1) a plurality of total reflection mirrors 20 formed in one end, a selection unit 100 for selecting one total reflection mirror 20 so that a desired laser wavelength of the plurality of total reflection mirrors 20 is reflected, and formed at the other end It is formed as a partial reflector 30 which emits a laser wavelength to the outside through one total reflection mirror 20 and the reflection path selected by the selection unit 100.

In addition, the selector 100 forms a motor 110 to rotate the plurality of total reflection mirrors 20 to select one of the desired total reflection mirrors 20, and the driving method of the motor 110 is Any method may be employed as long as it can selectively select a plurality of total reflection mirrors 20.

In this case, in order to obtain a precise reflection path between the total reflection mirror 20 and the partial reflection mirror 30 selected from the plurality of total reflection mirrors 20 by the rotational force of the motor 110, the front surface selected by using a position sensor or a stopper is selected. It is also possible to employ one method to set the correct position of the reflector 20.

The operating state of the present invention configured as described above will be described.

First, when a switch (not shown) of a desired laser wavelength is operated in a control box (not shown), the motor 110 installed in the resonator 1 rotates, and a plurality of total reflection mirrors 20 provided at one end thereof are rotated. ) Rotate.

When the selected total reflection mirror 20 matches the reflection path of the partial reflection mirror 30, the rotational force of the motor 110 is stopped, and thus, the selected one of the total reflection mirror 20 and the partial reflection mirror 30 undergoes a laser generation process. Perform.

Since the laser generation process is a known method, description thereof is omitted.

In addition, when the user wants a different laser wavelength, the motor 110 installed in the resonator 1 rotates to rotate the selected total reflection mirror 20 to a position coinciding with the reflection path of the partial reflection mirror 30.

Therefore, a variety of lasers can be obtained through one expensive medium, and the manufacturing cost and equipment cost of the device can be lowered.

As described above, the present invention includes a plurality of total reflection mirrors having different coating treatments in the resonator, so that various lasers that can be emitted from an expensive medium can be obtained, and various operations can be performed by variously emitted lasers. In addition to being able to, it is possible to maintain and efficient space utilization by forming a single device.

The present invention is not limited to the above-described embodiments, and various changes can be made by those skilled in the art without departing from the gist of the present invention as claimed in the following claims. You will understand.

Claims (2)

In the resonator 1 having a total reflection mirror 20 and a partial reflection mirror 30 formed at both ends of the medium 10 and the medium 10, The resonator 1 includes a plurality of total reflection mirrors 20 formed at one end, A selection unit 100 for selecting one total reflection mirror 20 such that a desired laser wavelength is reflected among the plurality of total reflection mirrors 20; It is formed at the other end, the laser is a variety of laser in one medium, characterized in that it is formed of one total reflection mirror 20 selected by the selection unit 100 and the partial reflection mirror 30 to emit the laser wavelength to the outside through the reflection path A device that emits wavelengths. The method of claim 1, The selector 100 rotates a plurality of total reflection mirrors 20 so that a motor 110 can be selected to select one of the desired total reflection mirrors 20. Emitting device.