JPH03205886A - Output control method for laser tube - Google Patents

Abstract

PURPOSE:To obtain stabilized high output by generating discharge under the condition where a cylindrical body whose inner diameter is slightly larger than the outside diameter of a tube main body is mounted so that it may be covered, keeping no contact with the outer periphery of the tube main body and adjusting an optical shaft of a reflecting mirror so that its output may be maximized. CONSTITUTION:After an attempt is made to insert a laser tube 2 into a cylindrical body 21 where the inner diameter of an adjustment support device 1 is slightly larger than the outside of a tube body 11, a fixing screw 22 is lightly fastened under control so that the laser tube 2 may supported with a thrusting member 25 at the tip of the screw 22 without contact with the cylindrical member 21. Then, high voltage is applied between electrodes 13 and 14 so that discharge may be generated within the tube main body 11. The electric discharge produces heat which increases the temperature of the tube main body 11, thereby creating a thermally saturated state in a few minutes. Therefore, a few minutes after the discharge starts, an attempt is made to insert the tip of a screwdriver into each recessed slot 17 and adjust the optical shafts KJ of an output mirror 15 and a total reflection mirror 16 so that the laser output may be maximized.

Description

[Detailed Description of the Invention] [Summary] Regarding a method for adjusting the output of a laser tube that emits laser light, the present invention provides a method for adjusting the output of a laser tube that emits laser light, so that when the tube is actually installed in a device and used, the output does not decrease significantly as in conventional methods. The purpose of the present invention is to provide a method for adjusting the output of a laser tube, and the present invention is to provide a laser tube comprising a tube body filled with gas and discharged therein, and a pair of reflecting mirrors attached to both ends of the tube body. In this output adjustment method, a cylindrical body whose inner diameter is slightly larger than the outer diameter of the tube body is placed over the outer periphery of the tube body in a non-contact manner, and an electric discharge is caused within the tube body, and the output is adjusted. The optical axis of the reflecting mirror is adjusted so as to maximize the optical axis.

[Industrial application field]

The present invention relates to a method for adjusting the output of a laser tube that emits laser light.

In general, gas lasers are easy to continuously oscillate and have good coherence of output light, so their use is expanding as a light source for various character and code reading devices, optical measurement devices, and the like.

Along with this, there is a demand for higher performance and lower cost of laser tubes.

[Conventional technology]

Generally, when a gas laser is used, it generates heat and the temperature of the laser tube increases. Since a gas laser is used housed in a suitable housing for safety reasons or functional design requirements, the wall of the laser tube becomes quite hot. Therefore, the laser tube is distorted due to temperature changes from the start of use until it reaches a stable state, which changes the alignment of the reflecting mirror, causes the optical axis to fluctuate, and the output of the gas laser to fluctuate.

In particular, gas lasers used in barcode reading devices and the like in POS terminals are entirely sealed in a unit to protect them from water droplets dripping from products. As a result, heat dissipation is poor, and the temperature of the laser tube drops from room temperature to 6 degrees Celsius within a few minutes after the start of use.
The angle increases to about 0 to 70 degrees, and as a result, the laser output drops to about 70 to 80% compared to the initial level. By the way, the output adjustment of the laser tube is performed at the time of the final adjustment before shipping the laser tube at the factory, or when the laser tube is readjusted during maintenance. According to the conventional output adjustment method, the laser tube is supported by an unenclosed support stand, a discharge is caused in that state, and the optical axis of the reflector is adjusted so that the output of the gas laser becomes the rated or maximum output. There is.

[Problem to be solved by the invention]

Therefore, according to the conventional laser tube output adjustment method, the laser tube is exposed to the atmosphere during adjustment, and heat radiation is good, so the temperature of the wall of the laser tube does not rise much.

In other words, in the conventional adjustment method, adjustment is performed so that the output is maximized when the temperature of the wall of the laser tube is considerably lower than the actual usage state.

Therefore, when the laser tube is attached to a barcode reader or the like and actually used, the temperature rises considerably as described above, which causes a problem in that the output is significantly reduced.

In view of the above-mentioned problems, the present invention aims to provide a method for adjusting the output of a laser tube, which does not cause the output to decrease as much as in the past when actually installed in a device and used. There is.

[Means for solving intelligence problems]

In order to solve the above-mentioned problems, the present invention provides a tube body 11 filled with gas and in which discharge is performed, as shown in FIG.
and a pair of reflecting mirrors 15 and 16 attached to both ends of the tube body 11, the inner diameter of which is larger than the outer diameter of the tube body 11. While a slightly larger cylindrical body 21 is placed over the outer periphery of the tube body 11 in a non-contact manner, a discharge is caused within the tube body 11, and the optical axis KJ of the reflector 15.16 is adjusted so that the output is maximized. It is characterized by adjusting.

[For production]

The cylindrical body 21 prevents heat dissipation from the tube body 11 and raises the temperature of the tube body 11 to the temperature when actually used within a short time.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

1 is a sectional front view showing an adjustment support device 1 for a laser tube 2 according to the present invention, FIG. 2 is a right side view of FIG.
The figure is an enlarged view of the electrode 13 in FIG.

The laser tube 2 includes a tube body 11 and metal stems 12, 12 attached to both end surfaces of the tube body 11.
, electrodes 13 and 14 made of metal attached to each metal stem 12, and an output mirror l5 and a total reflection mirror 1 attached to the outer end surfaces of each electrode 13 and 14, respectively.
It consists of 6.

The tube body 11 is made of a glass tube, and has He inside.
-Ne and various other gases are filled, and a high voltage is applied between the electrodes 13 and 14 to excite and discharge.

The laser beam is repeatedly reflected between the output mirror 15 and the total reflection mirror 16, and is extracted to the outside through a hole in the center of the output mirror 15.

The electrodes 13, 14 are each provided with a groove 17, 17 for adjusting the optical axis near the middle in the axial direction, and the groove 17 has a narrow diameter portion 18, 18 whose outer diameter is smaller than the other portions.
It is 18.

Insert the tip of a screwdriver 〇R etc. into this groove 17 and rotate the driver DR in the direction of arrow M1, or rotate it in the direction of arrow M2.
By tilting in the direction, the narrow diameter portion 18 is tilted, although very slightly, and the alignment of the output mirror 15 and the total reflection mirror 16 changes. Therefore, driver DR
The optical axis KJ of the output mirror 15 and the total reflection mirror 16 is
can be adjusted.

Note that such a laser tube 2 itself is publicly known.

The adjustment support device 1 has an inner diameter larger than the outer diameter of the tube main body 11 by about 10 μm to several mm, and a cylindrical body 21 made of metal, plastic, or the like, and two positions in the axial direction of the cylindrical body 21 in the circumferential direction. It consists of fixing screws 22, 22, etc. screwed into three equally divided positions. A pressing member 23 made of synthetic resin, urethane rubber, or the like is attached to the tip of each fixing screw 22 for cushioning and heat transfer insulation. Note that this adjustment support device 1 itself is fixed to a base (not shown).

After the laser tube 2 is inserted into the cylindrical body 21 of the adjustment support device 1, by lightly tightening the fixing screw 22 and adjusting it, the tip of the screw 22 can be pressed without coming into contact with the cylindrical body 21. It is supported by member 23.

Next, a method for adjusting the output of the laser tube 2 will be explained.

As shown in FIG. 1, with the laser tube 2 supported by the adjustment support device 1, a high voltage is applied between the electrodes 13 and 14 to cause discharge within the tube body 11. Then, due to heat generation due to discharge, the tube body 1
1 rises, and since the cylindrical body 21 is close to the tube body 11 and covers it, the temperature rises to 60 degrees Celsius after a few minutes.
The temperature reaches a high temperature of about 70 degrees, reaching thermal saturation.

Therefore, several minutes after starting the discharge, for example, about 3 minutes, the tip of the driver DR is inserted into each groove 17 to adjust the optical axis KJ of the output mirror 15 and the total reflection mirror l6.
Adjust to maximize laser output.

When the adjustment is completed, the fixing screw 22 is loosened, the laser tube 2 is removed, the unadjusted laser tube 2 is newly attached, and the adjustment is made in the same manner as described above.

Note that the laser output of the laser tube 2 is measured by arranging a photodetector on the optical axis KJ on the output mirror 15 side and knowing the detected amount.

According to the embodiment described above, the output of the laser tube 2 can be adjusted at a temperature close to the temperature during actual use, so that when the laser tube 2 is attached to a Harcode reader or the like and actually used, The output does not drop significantly as in the conventional case, and high output can be stably obtained. Moreover, since the structure of the adjustment support device 1 is simple, the cost does not increase due to adjustment.

When adjusting the output, the laser tube 2 is pressed against the pressing member 23.
Since the contact area with the tube body 11 is extremely small and there is almost no heat conduction,
Accurate adjustment is possible without unevenness in the temperature of the tube wall of the tube body 11.

In the above-described embodiment, the driver DR was used to adjust the optical axis KJ, but it is also possible to use another tool with a flat tip. The length, inner diameter, thickness, etc. of the cylindrical body 21 are as follows.
It can be of various types other than those mentioned above. It is possible to increase or decrease the number of fixing screws 22. Alternatively, two of the three fixing screws 22 provided in the circumferential direction may be fixed pins that do not move, and only the remaining one may be a screw. A pressure pin that presses the surface may also be used. Further, other support members may be used in place of the fixing screw 22.

The present invention can be applied to power adjustment of various types of laser tubes.

〔Effect of the invention〕

According to the present invention, when a laser tube is actually installed in a device and used, its output does not decrease significantly unlike in the past, and high output can be stably obtained.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional front view showing a laser tube adjustment support device according to the present invention, FIG. 2 is a right side view of FIG. 1, and FIG. 3 is an enlarged view of the electrode in FIG. 1. In the figure, 1 is an adjustment support device, 2 is a laser tube, 11 is a tube body, 15 is an output mirror (reflector), 16 is a total reflection mirror (reflector), 21 is a cylindrical body, and KJ is an optical axis.

Claims (1)

[Claims] (1) The tube body (1) where gas is filled and discharge occurs
1) and a pair of reflecting mirrors (15) and (16) attached to both ends of the tube body (11), the output adjustment method of a laser tube (2) comprising: A cylindrical body (21) that is slightly larger than the outer diameter of the tube body (11) is attached to the tube body (11).
The reflector (1) is placed over the outer periphery of the tube body (11) in a non-contact manner to cause an electric discharge within the tube body (11), and the reflector (1) is placed so as to maximize its output.
5) A method for adjusting the output of a laser tube, which comprises adjusting the optical axis (KJ) of (16).