JPH0325425Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to an internal mirror He-Ne laser oscillator constructed by housing an internal mirror He-Ne laser tube in a cylindrical case.

(Prior art and its problems) The conventional internal mirror He-Ne laser oscillator has 1
Internal mirror He−Ne coaxially inside the cylindrical case
It was constructed by housing a laser tube and attaching lids to the front and rear sides. However, 1 like this
If a laser oscillator is configured using only cylindrical cases, the following drawbacks will occur.

Internal mirror He-Ne laser oscillation can be made compact considering its output, so internal mirrors have been used to the extent that the output is in the 10mW class.

However, in order to increase the output, it is necessary to increase the total length of the laser tube and the radius of curvature of the mirror that constitutes the resonator. For example, when the output increases approximately three times, the total length approximately doubles and the mirror radius of curvature approximately triples. When the overall length and the radius of curvature of the mirror are large, the change in laser output due to changes in the environmental temperature distribution near the laser tube becomes larger than when the overall length and the radius of curvature of the mirror are small. Therefore, the internal mirror He−Ne with large output, that is, large overall length and large radius of mirror curvature,
When the laser tube is housed in a cylindrical case, there is a problem in that the output decreases when the environmental temperature distribution changes, as explained above. Adjustment of the mirror is required to correct this and restore the previous output.

Incidentally, the mirrors are provided at both ends of the vacuum envelope via metal adjustment mechanism parts, and one side is at a high voltage potential due to the structure of the laser tube. The cylindrical case is usually made of aluminum, which has good heat conductivity.
The mirror adjustment mechanism on the high voltage side is insulated. Therefore, it is impossible to adjust it after storing it in the cylindrical case. Therefore, the conventional laser oscillator using a single cylindrical case has the disadvantage that only the low-pressure side mirror adjustment mechanism can be adjusted, and the output cannot be completely restored to the state before storage.

(Means for solving the problem) In order to solve this drawback, the present invention consists of a cylindrical case made up of two cylindrical parts, which are joined together with screws in the middle to form a single cylindrical case as a whole. Features. In other words, the first cylindrical case houses the other parts of the laser tube except for the high-pressure side mirror adjustment mechanism, and after adjusting both the high-pressure and low-pressure side mirrors,
The high voltage side is insulated and the high voltage side mirror adjustment mechanism is housed in a second cylindrical case. The drawings will be explained in detail below.

(Example) Figures 1 and 2 show an example of the present invention. Figure 1 shows an internal mirror He-Ne laser tube 1 housed in a first cylindrical case 2 and held with screws 3. This shows the state in which the As shown in FIG. 1, when most of the internal mirror He-Ne laser tube 1 except for the high-voltage potential side mirror adjustment mechanism 4 is housed in the first cylindrical case 2 and oscillated, the internal mirror He-Ne laser tube 1 before being housed is
Since the environmental temperature distribution near the Ne laser tube 1 differs from that after storage, the oscillation output of the laser changes in the direction of decreasing. Next, the oscillation output is restored by adjusting the high voltage potential side mirror adjustment mechanism section 4 and the low voltage potential side mirror adjustment mechanism section 5 to compensate for the decreased output. Thereafter, a front cover 6 is attached, and an insulating cap 7 is attached to the high-voltage potential side mirror support mechanism portion 4 for insulation treatment. A lead wire 10 extending from a stabilizing resistor section 9 is attached to the rear lid 8.

After recovering the laser output as described above, as shown in FIG.
The internal mirror He-Ne laser oscillator is completed. In this case, the second cylindrical case 11 only houses the high-voltage potential side mirror adjustment mechanism part 4, so it does not change the environmental temperature distribution near the internal mirror He-Ne laser tube 1, and therefore the laser oscillation output does not change.

(Effect of the invention) As explained above, since the cylindrical case constituting the internal mirror He-Ne laser oscillator is composed of two cylindrical case parts, the mirrors on both sides of the high voltage potential and low voltage potential can be adjusted, and the cylindrical Even after being stored in the case, the laser output remains unchanged.
A He-Ne laser oscillator can be manufactured.

[Brief explanation of the drawing]

1 and 2 are cross-sectional views of an internal mirror He--Ne laser oscillator according to an embodiment of the present invention. 1... Internal mirror He-Ne laser tube, 2... First cylindrical case, 3... Screw, 4... High voltage potential side mirror adjustment mechanism, 5... Low voltage potential side mirror adjustment mechanism, 6... Front side mirror adjustment mechanism. Lid, 7... Insulation cap, 8...
...Rear lid, 9... Stabilizing resistor part, 10... Lead wire, 11... Second cylindrical case.

Claims (1)

[Scope of utility model registration request] There is a mirror adjustment mechanism at both ends of the vacuum envelope that can adjust the angle of the mirror by plastic deformation of the metal, and the internal mirror He-Ne laser tube sealed with a mirror is housed in a cylindrical case with lids on the front and rear sides. In the internal mirror He-Ne laser oscillator configured by attaching the cylindrical case to two cylindrical parts, one of the cylindrical cases is configured to expose one of the mirror adjustment mechanisms at both ends of the laser tube. 1. An internal mirror He-Ne laser oscillator, characterized in that the other cylindrical case is adapted to accommodate an exposed mirror adjustment mechanism portion of a laser tube.