JP2690098B2 - Laser oscillation device - Google Patents

Description

The present invention relates to a laser oscillator such as a CO ₂ laser for processing, and more particularly to a laser oscillator having improved oscillation characteristics, reliability and maintainability.

[Conventional technology]

FIG. 7 shows the configuration of a laser oscillator for a CO ₂ laser according to the prior art. In the figure, an output coupling mirror 2 and a total reflection mirror 3 are installed at both ends of the discharge tube 1. Further, two metal electrodes 4 and 5 are attached to the outside of the discharge tube 1, and a high frequency voltage is applied between them by a high frequency power source 6 to generate a high frequency glow discharge in the discharge tube 1 for laser excitation. Be seen. The laser beam optical axis in the discharge tube 1 is 13,
The optical axes of the laser beams extracted from the output coupling mirror 2 to the outside are indicated by 14, respectively.

When the laser oscillator is activated, the entire interior of the device is first evacuated by the vacuum pump 12. Then, the valve 11 is opened, a predetermined flow rate of laser gas is introduced from the gas cylinder 10, the gas pressure in the device reaches a specified value, and then the vacuum pump is used.
Exhaust of 12 and introduction of make-up gas continue, and while the gas pressure is kept at the specified value, a part of the laser gas is continuously replaced with fresh gas, which prevents gas pollution.

Further, in FIG. 7, the laser gas is circulated in the apparatus by the roots blower 9. The purpose is to cool the laser gas. In the CO ₂ laser, about 20% of the injected electric energy is converted into laser light, and the other is consumed for gas heating. However, according to theory, the laser oscillation gain is − (3 /
2) Forced cooling of the laser gas is necessary to increase the oscillation efficiency because it is proportional to the power. Laser gas is about 100 m / s
It passes through the discharge tube at a flow rate of ec, flows in the direction shown by the arrow, and is guided to the cooler 8. Here, the heating energy due to the discharge is mainly removed. Since heat of compression is generated in the roots blower 9, the gas passes through the cooler 7 before being re-introduced to the discharge tube 1. Since these coolers 7 and 8 are well-known, detailed description will be omitted.

[Problems to be solved by the invention]

The conventional laser oscillator shown in FIG. 7 has the following problems.

First, since the roots blower is a low-speed rotary positive displacement fan, the size and weight are too large, and the laser oscillator itself becomes too large.

Secondly, there is a pulsating flow in the blast, which affects the laser output.

Thirdly, a considerable amount of vibration is generated from the roots blower 9, which adversely affects the pointing stability of the laser beam.

Fourthly, since a rolling bearing is used for the roots blower 9, the lubricating oil component is mixed in the laser gas to contaminate the optical parts, resulting in a decrease in output and mode deformation.
For this reason, high-power CO ₂ lasers constantly replace the laser gas, which accounts for a considerable portion of operating costs. Even if this is done, it is necessary to regularly replace or clean the optical parts, which requires a great deal of labor for maintenance. Also, the need for lubrication is a problem in maintenance.

[Means for solving the problem]

In the present invention, in order to solve the above problems, in a laser oscillating device for forcedly cooling a laser gas by a cooler,
A laser gas casing having a turbo blade that circulates a laser gas, a drive system casing that is connected to the turbo blade by a shaft, and in which a motor that rotates the turbo blade is arranged, the laser gas casing and the drive system casing. An intermediate chamber provided in the middle, having a first radial flow labyrinth seal with the laser gas housing, and having a second radial flow labyrinth seal with the drive system housing. A featured laser oscillator is provided.

[Action]

Since an intermediate chamber was provided between the laser gas casing and the drive system casing, and a radial flow labyrinth seal was provided between the laser gas casing and the intermediate chamber, and between the intermediate chamber and the drive system casing, respectively. It is well isolated from the drivetrain housing.

〔Example〕

 Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 shows a configuration diagram of a laser oscillator according to the present invention. The same elements as those of the prior art shown in FIG. 7 are designated by the same reference numerals, and the description thereof will be omitted and only the characteristic portions will be described. Instead of the Roots blower 9, the turbo blower is shown in Fig. 1.
15 is used. Since the turbo blower 15 has much higher efficiency than the roots blower, the compression heat can be ignored and the cooler 7 in the subsequent stage can be omitted. Although omitted in FIG. 1, it may be installed in some cases.

Fig. 2 shows the structure of the turbo blower. Here, the turbo blade 16 is a centrifugal blade, but may be a mixed flow blade or an axial flow blade. The turbo blade 16 is attached to the shaft, and is rotated at a high rotational speed of about 100,000 PRM by a motor composed of a rotor 17 and a stator 18 installed in a drive system case 22 different from the laser gas case 36. To be done. Therefore, the volume is smaller in inverse proportion to the rotation speed than the low-speed roots blower. As the bearings 19 and 20, rolling bearings or air bearings are used. Oil is used for rolling bearings, and air is used for air bearings.
Since it mixes into the laser gas from the opening 21 with 36,
In the present invention, the laser gas casing 36 and the drive train casing 22 are separated by the labyrinth seal 23.

2 shows a radial flow type labyrinth seal,
This may be of the axial flow type. The drive system casing 22 may be filled with laser gas at the same pressure as in the laser gas casing 36. At this time, the oil component from the drive system bearing prevents the labyrinth seal 23 alone from mixing in the laser gas. For further perfection, the drivetrain housing 22 may be evacuated by another pump 24. At this time, the oil component from the drive system bearings 19 and 20 is completely discharged to the outside of the drive system housing 22, so that the laser gas is not contaminated. Since the laser gas is discharged little by little through the labyrinth seal 23, this amount is replenished with fresh gas so that the laser gas pressure becomes constant. In the radial flow type as shown in FIG. 2, the centrifugal gas prevents the laser gas from flowing out.

FIG. 3 shows an example of a turbo blower having an axial flow type screw type labyrinth seal. In the figure, the labyrinth seal is made up of screws 25. The labyrinth seal 25 has a structure in which a gas flow is generated from the drive system housing 22 toward the laser housing as it rotates, and this prevents the flow of the laser gas. Will be reduced.

FIG. 4 shows the configuration of another turbo blower. In this configuration, the intermediate chamber 27 is interposed between the laser gas casing 36 and the drive system casing 22, and the intermediate chamber 27 is separated from the laser gas casing 36 by the labyrinth seal 23 and is separated from the drive system casing 22 by the labyrinth seal 26. Is isolated by. The drive system housing 22 may be in a vacuum state or filled with laser gas as described above. Let's say you have a vacuum. The intermediate chamber 27 may be filled with a laser gas having a pressure higher than that of the laser gas from the gas introduction pipe 29 and the valve 30. At this time, a slight gas flow is generated in the labyrinth seal 23 toward the laser housing 22. The labyrinth seal 26 also has a gas flow towards the drivetrain housing 22. Therefore, the oil component of the bearings 19 and 20 does not flow into the laser gas.

Further, the intermediate chamber 27 may be evacuated by the vacuum pump 28. At this time, since the laser gas is exhausted through the labyrinth seal 23, the portion is replenished with fresh gas. Further, since the oil component is discharged to the outside through the intermediate chamber 27, the laser gas is not contaminated.

The bearings 19 and 20 are composed of rolling or air bearings as described above, but since both are known techniques, detailed description thereof is omitted here.

The turbo blowers shown in FIGS. 2, 3, and 4 are applied to laser oscillators with an output of about 1 KW, but large turbo blades may be used for higher output, but this is costly. It is desirable to use a plurality of identical blades.

Fig. 5 shows the structure of a turbo blower with a laser output of about 2KW. In the figure, 32 is a turbo blower, and the bearings and the like are the same as those in FIG. The arrows in the figure indicate the direction in which the laser gas flows.

Two turbo blades 16 and 31 are attached to the top and bottom of the shaft. Since the bearing and the drive motor are expensive in this configuration, the configuration in which the bearing and the drive motor are integrated is advantageous in terms of cost. 17 is a rotor, 18 is a stator, 27a, 2
7b is an intermediate chamber.

Here, by mounting the turbo blades on the same shaft, the load fluctuations in the thrust direction are canceled out, and the thrust load becomes only a constant weight load, so there is an advantage that stability is increased.

Fig. 6 shows the structure of a turbo blower with a laser output of about 4KW. In the figure, 35 is a turbo blower, and the bearings and the like are omitted because they are almost the same as those in FIG. Here, a structure is adopted in which two units shown in FIG. 5 are arranged in parallel. The turbo blades 16 and 31 are driven by a motor composed of a rotor 17a and a stator 18a. The turbo blades 33 and 34 are driven by a motor including a rotor 17b and a stator 18b. 27a, 27b, 27c and 27d are intermediate chambers. The arrows indicate the direction of laser gas flow.

In the present invention, the structure of the blower is almost the same as that of FIG. 7 except the structure of the blower, but the efficiency of the blower is increased from about 35% in the case of the roots blower to 80%, so the heat of compression is reduced accordingly and the cooling of the latter stage is performed. The vessel can be omitted, but it can be much smaller.

If the blade material is made of a heat-resistant material such as ceramic, the cooler 8 can be omitted, and the same capacity as the cooler 8 may be installed in the subsequent stage (position of the cooler 7 in FIG. 7).

The present invention is particularly useful for high frequency discharge pumped CO ₂ lasers. In the case of DC discharge excitation, a turbulent flow must be generated in the gas flow in order to obtain a uniform discharge, so a high compression ratio is required for the blower, and the Roots blower is optimal for this purpose. On the other hand, turbulent flow is not necessary for high-frequency discharge excitation, and the characteristics of the Davo blower, such as low compression ratio and large blast capacity, are effective.

〔The invention's effect〕

As described above, in the present invention, the intermediate chamber is provided between the laser gas casing and the drive system casing, and the radial flow labyrinth seal is provided between the laser gas casing and the intermediate chamber and between the intermediate chamber and the drive system casing. Since the laser gas casing and the drive system casing are sufficiently isolated from each other, the optical components are not contaminated by the oil component of the lubricating oil.

In addition, deterioration of the laser output and the beam characteristics can be prevented.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of an embodiment of a laser oscillator of the present invention, FIG. 2 is a structural diagram of a turbo blower with a laser output of about 1 KW, and FIG. 3 is a structure of a turbo blower having an axial flow type screw type labyrinth seal. Fig. 4, Fig. 4 is a structural drawing of a turbo blower with another labyrinth seal, Fig. 5 is a structural drawing of a turbo blower with a laser output of about 2KW, Fig. 6 is a structural drawing of a turbo blower with a laser output of about 4KW, and Fig. 7 is conventional. FIG. 3 is a configuration diagram of a laser oscillation device of the CO ₂ laser of FIG. 1 ... Discharge tube 2 ... Output coupling mirror 3 ... Total reflection mirror 4, 5 ... Electrode 6 ... High frequency power supply 7, 8 ... Cooler 9 ... Roots blower 10 ... Gas cylinder 12 ... Vacuum pump 13 ... … Internal cavity laser beam optical axis 14 …… Outside cavity laser beam optical axis 15 …… Turbo blower 16 …… Turbo blade 17 …… Rotor 18 …… Stator 19, 20 …… Bearing 21 …… Aperture 22 …… Drive system Body 23 …… Radial flow labyrinth seal 24 …… Vacuum pump 25 …… Screw type labyrinth seal 26 …… Radial labyrinth seal 27 …… Intermediate chamber 28 …… Vacuum pump 29 …… Gas inlet pipe 30 …… Valve 31… … Turbo blade 32 …… Turbo blower 33, 34 …… Turbo blade 35 …… Turbo blower 36 …… Laser gas housing

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-58-14589 (JP, A) JP-A-59-159794 (JP, A) JP-A-59-159795 (JP, A) JP-A 62- 271973 (JP, A) JP 61-14775 (JP, A) Actually opened 62-97366 (JP, U) Actually opened 63-84970 (JP, U)

Claims (6)

(57) [Claims] 1. A laser oscillating device for forcibly cooling a laser gas by a cooler, wherein a laser gas casing having a turbo blade for circulating the laser gas, a motor connected to the turbo blade by a shaft, and rotating the turbo blade are arranged. A drive system casing, and a first radial flow labyrinth seal provided between the laser gas casing and the drive system casing, the first gas flow labyrinth seal being provided between the laser gas casing and the drive system casing. An intermediate chamber having a second radial flow labyrinth seal therebetween, and a laser oscillation device. 2. The laser oscillating device according to claim 1, wherein the intermediate chamber is filled with a laser gas having a pressure higher than that of the laser gas container. 3. The laser oscillation device according to claim 1, wherein the intermediate chamber is evacuated by a vacuum pump. 4. A laser oscillating device for forcibly cooling a laser gas by a cooler, comprising: a first laser gas casing having a first turbo blade for circulating a laser gas, and a second turbo blade for circulating a laser gas. And a drive system casing in which a motor for rotating the first turbo blade and the second turbo blade is arranged, which is coupled to the first laser blade and the second turbo blade by a shaft. A body, a first radial gas labyrinth seal is provided between the first laser gas housing and the drive system housing, and has a first radial flow labyrinth seal between the body and the drive system housing. A first intermediate chamber having a second radial flow labyrinth seal between the second laser gas housing and the drive system housing, and the second laser And a second intermediate chamber having a fourth radial flow labyrinth seal with the drive system casing, and a third radial flow labyrinth seal with the casing. Laser oscillator. 5. The first intermediate chamber and the second intermediate chamber are filled with a laser gas having a pressure higher than that of the first laser gas container and the second laser gas container. The laser oscillation device according to claim 4. 6. The laser oscillator according to claim 4, wherein the first intermediate chamber and the second intermediate chamber are evacuated by a vacuum pump.