KR100502737B1 - Pumping apparatus for solid laser - Google Patents

Abstract

According to the present invention, a conductive medium having a refractive index similar to that of an injection lens that absorbs an excitation beam scanned from a semiconductor laser diode and emits the same to a solid laser medium (crystal) positioned at the center of the diffuse reflector is provided to the diffuse reflector. It relates to a solid state laser pumping device capable of increasing the amount of excitation beam delivered to the solid state laser medium by filling.

Description

Solid state laser pumping device {PUMPING APPARATUS FOR SOLID LASER}

The present invention relates to a solid state laser pumping apparatus.

More specifically, the diffuse reflector may have a conductive medium having a refractive index similar to that of a jet lens that absorbs a pumping beam scanned from a semiconductor laser diode and emits the same to a solid laser medium (crystal) positioned at the center of the diffuse reflector. The present invention relates to a solid state laser pumping device capable of increasing the amount of excitation beams delivered to the solid state laser medium by filling in the.

In addition, the injection lens is narrowed toward the emission side from the absorption side for absorbing the excitation beam from the semiconductor laser diode toward the emission side for emitting the excitation beam to the solid laser medium, and the solid-state laser pumping so as to be located a predetermined space away from the solid laser medium Relates to a device.

In general, in order to obtain laser light from a laser resonator, a solid laser medium must be pumped from a ground state to an excited state. In the case of a solid laser medium, a discharge tube and a semiconductor laser diode are mostly used as a pumping light source. do.

1 shows a conventional solid state laser pumping apparatus. A solid laser pumping apparatus will be described with reference to FIG. 1.

The conventional solid state laser pumping apparatus includes a laser semiconductor diode 10 that scans an excitation beam and a prism that absorbs the excitation beam that is scanned from the laser semiconductor diode 10 and emits it to the solid laser medium 40. And a cylindrical reflector 30 and a solid laser medium 40, a cooling tube 50 is located inside the reflector, and a solid laser medium 40 at the center of the cooling tube 50. This is arranged.

The prism 20 is inserted into a slit formed in the reflector 30 and filled with air outside the cooling tube 50, that is, between the cooling tube 50 and the reflector 30.

Therefore, the excitation beam emitted from the prism 20 is incident into the air, the refractive index of the prisms (20, n_1) is 1.52, the refractive index of the air (n_2) is 1.00, so the excitation beam is incident into the air from the prism 20 The beam is partially refracted and partially reflected by Snell's law, which will be described later.

Therefore, the excitation beam emitted from the prism 20 is not well transmitted to the solid state laser medium 40.

Therefore, the prism 20 applied to the solid-state laser pumping device is absorbed to absorb the excitation beam from the semiconductor laser diode 10 so that the excitation beam has a higher conductivity to the solid-state laser medium 40. From the side toward the emission side for emitting the excitation beam to the solid state laser medium 40, the emission side end was formed to be pointed.

However, since the excitation beam transmitted to the solid state laser medium 40 is small due to the difference in refractive index between the prism 20 and the air, an effective oscillation of the solid state laser medium 40 cannot be expected, and some excitation beams are reflected to reflect the semiconductor laser diode ( The lifetime of 10) is also reduced.

In addition, since the end of the discharge side should be pointed at the time of manufacturing the prism 20, there was a difficulty in processing.

Accordingly, an object of the present invention is to provide a solid state laser pumping device which allows a large amount of excitation beams emitted from a jet lens to be absorbed by a solid state laser medium.

In addition, an object of the present invention is to provide a solid-state laser pumping device for facilitating processing since it is not necessary to point the discharge end of the injection lens.

In order to achieve the above object, in one embodiment of the present invention, a semiconductor laser diode for scanning a pumping beam; An injection lens formed to narrow toward an emission side for emitting the excitation beam from an absorption side for absorbing the excitation beam scanned from the semiconductor laser diode; A cylindrical diffuse reflector having a slit formed to insert the emission side of the jet lens; A conducting medium filled in the diffuse reflector; And a solid laser medium disposed at the center of the diffuse reflection body and spaced apart from the jet lens and absorbing an excitation beam emitted from the jet lens to oscillate atoms.

In addition, the present invention is the refractive index (n ₁₎ and the refractive index of the conductive medium (n ₂₎ of the injection lens

The problem mentioned above is solved by the solid-state laser pumping apparatus characterized by the above-mentioned.

In addition, the present invention solves the above-mentioned problems as a solid-state laser pumping device, characterized in that the conductive medium is the same as the refractive index of the injection lens.

These objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

2 and 3 show a perspective view according to an embodiment of the solid state laser pumping apparatus according to the present invention, and FIG. 4 is a view for explaining the types of injection lenses.

As shown in FIG. 2, the solid-state laser pumping apparatus according to the present invention includes a semiconductor laser diode 1 that scans an excitation beam and an absorption that absorbs the excitation beam that is scanned from the semiconductor laser diode 1. Cylindrical eggs in which the slit is formed so that the injection lens 2 is formed narrower toward the emission side 2b emitting the excitation beam from the side 2a and the emission side 2b of the injection lens 2 is inserted. A reflector 3, a conducting medium 5 filled in the diffuse reflector 3, and a center of the diffuse reflector 3, spaced apart from the spray lens 2 by a predetermined space, It consists of a solid laser medium 4 which absorbs an excitation beam emitted from 2) and oscillates atoms.

The semiconductor laser diode 1 is used as a pumping light source. That is, it becomes a source for supplying the excitation beam so that the solid laser medium 4 is oscillated. The semiconductor laser diode (1) can increase the pumping efficiency than the conventional discharge tube and because the thermal effect of the laser medium is less appear in recent years the use range is expanding.

The injection lens 2 absorbs the excitation beam scanned from the semiconductor laser diode 1 and focuses and emits the excitation beam so that the excitation beam can be effectively focused on the solid state laser medium 4.

Accordingly, the injection lens 2 has a large area on the absorption side (part 2a in FIG. 2) that absorbs the excitation beam from the semiconductor laser diode 1, and focuses the excitation beam on the solid state laser medium 4. It forms so that it may become narrow toward the discharge side (part 2b of FIG. 2) which discharge | releases to the side.

In particular, the absorption side 2a of the injection lens 2 has an arc shape as shown in FIG. 4B or 4C to increase the focusing rate of the excitation beam scanned from the semiconductor laser diode 1.

4A to 4C show various shapes of the jet lens 2, the right side is an absorption side for absorbing the excitation beam from the semiconductor laser diode 1, and the left side is for emitting the excitation beam to the solid state laser medium 4. The discharge side is shown.

The emitting side 2b of the jet lens 2 is inserted into a cylindrical diffuse reflector 3 in which a slit is formed so that the jet lens 2 can be inserted, and the emitting side 2b is the diffuse reflector It is separated by a predetermined space from the solid-state laser medium 4 located at the center of (3).

The conducting medium 5 is filled in the diffuse reflector 3. That is, the solid state laser medium 4 disposed at the center of the diffuse reflector 3 is wrapped in the conducting medium 5.

Glass having the same refractive index as the injection lens 2 (refractive index = 1.52) may be applied to the conductive medium 5. That is, the glass is disposed between the solid laser medium 4 and the diffuse reflection body 3.

One embodiment of a solid state laser pumping device in the case where the conducting medium 5 is glass as described above is shown in FIG. 3. At this time, the cooling tube 6 is installed outside the solid state laser medium 4. Reference numerals 8, 9, and 10 that are not described refer to the exemplary embodiment of FIG. 2.

The conducting medium 5 is a medium through which the excitation beam emitted from the injection lens 2 can be well transmitted to the solid state laser medium 4, and also cools the temperature of the solid state laser medium 4. .

To help understand the conducting medium 5 of the present invention, a Snell's law will be described with reference to FIG. 5.

Refractive index n ₁ When the light going straight to the medium is incident on the medium having the refractive index n ₂ , the direction of travel is called 'refraction', and the incident angle ( ) And the angle of refraction ( The ratio between) is always constant, which is called the refractive index of medium 2 with respect to medium 1.

And, whatever the angle of incidence for the two mediums satisfy the following Equation 1, the value of Equation 1 below always represents a constant value, which is called 'Snell's law'.

When a medium with a large index of refraction enters a small medium, light incident at a certain angle is not refracted and reflected because there is no way to satisfy Snell's law. This boundary angle is called a critical angle and is called total reflection.

Therefore, the refractive index of the injection lens 2 and the conductive medium 5 preferably satisfies Equation 2 below.

When the excitation beam is incident from the jet lens 2 onto the conductive medium 5, the excitation beam is not reflected at the interface between the jet lens 2 and the conductive medium 5 and is absorbed mostly by the solid laser medium 4 directly.

On the other hand, if the refractive index of the injection lens 2 is significantly different from that of the conductive medium 5, total reflection occurs when the excitation beam is incident on the conductive medium 5 at an angle greater than or equal to a critical angle. Since the conductivity of the excitation beam transmitted to the lower is reduced, the pumping efficiency of the solid laser medium 4 is lowered, and the lifetime of the semiconductor laser diode 1 is also shortened.

In this case, there has been a method of increasing the conductivity of the excitation beam transmitted to the solid state laser medium 4 by sharpening the tip of the emitting side 2b of the injection lens 2 in order to reduce the critical angle. Filling the diffuse reflector 3 with a conductive medium 5 having a refractive index substantially the same as or similar to the refractive index of the jet lens 2 so that the tip of the emission side 2b of the jet lens 2 is not sharpened. do.

In addition, by using the conductive medium 5 similar to the refractive index of the injection lens 2 as described above, it is possible to further increase the cooling efficiency of the solid laser medium 4.

The excitation beam absorbed by the solid state laser medium 4 oscillates the solid state laser medium 4 to emit laser light having a wavelength corresponding to the characteristics of each solid state laser medium 4.

In the present invention, the refractive index n ₁ of the injection lens 2 and the refractive index n ₂ of the conductive medium 5 are Is most preferred. If the ratio of the refractive index is less than 0.875, the reflection loss due to total reflection in the injection lens 2 becomes large, and if the ratio of the refractive index exceeds 1.13, most of the light passing through the injection lens 2 is transmitted to the conductive medium 5. As a result, reabsorption occurs to the injection lens 2 again. When the ratio of the refractive index changes by 10%, the light loss is about 7-8%.

The present invention is not limited to the embodiments described above, and various modifications and changes can be made by those skilled in the art, which are included in the spirit and scope of the present invention as defined in the appended claims.

As described above, the present invention fills the inside of the diffuse reflector with a conductive medium having a refractive index almost similar to that of the injection lens that absorbs and emits the excitation beam scanned from the semiconductor laser diode to the solid laser medium. The excitation beam emitted at achieves the effect of improving the conductivity conducted by the solid state laser medium.

Therefore, the lifetime of the semiconductor laser diode can be greatly improved.

Further, as part of a method for preventing the excitation beam from being reflected from the emission side of the injection lens, it is not necessary to sharpen the emission end of the emission lens, thereby achieving an effect of facilitating the processing of the injection lens.

1 is a perspective view showing a conventional solid state laser pumping apparatus

Figure 2 is a perspective view showing a solid state laser pumping apparatus according to the present invention

Figure 3 is a perspective view showing another embodiment of a solid state laser pumping apparatus according to the present invention

4 is a view for explaining types of injection lenses;

5 is a diagram for explaining Snell's law.

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

1: semiconductor laser diode

2, 8: injection lens

3, 9: diffuse reflector

4, 10: solid state laser medium

6: cooling tube

5, 7: evangelism medium

Claims (3)

A semiconductor laser diode 1 for scanning a pumping beam; Injection lents (2) formed so as to become narrower toward the emission side (2b) for emitting the excitation beam from the absorption side (2a) for absorbing the excitation beam scanned from the semiconductor laser diode (1); A cylindrical diffuse reflector (3) having a slit formed so that the emitting side (2b) of the jet lens (2) is inserted; A conducting medium 5 filled in the cylindrical diffuse reflector 3; A solid laser medium 4 disposed at the center of the cylindrical diffuse reflector 3 and spaced apart from the jet lens 2 and absorbing an excitation beam emitted from the jet lens 2 to oscillate atoms Solid laser pumping device, characterized in that. In claim 1, Refractive index (n ₁₎ and the refractive index of the conductive medium (n ₂₎ of the injection lens, Solid laser pumping device characterized in that. The method of claim 1 or 2, wherein the conductive medium is Solid laser pumping apparatus, characterized in that the same as the refractive index of the injection lens.