RU221120U1 - Output attenuation means - Google Patents

Abstract

The utility model relates to quantum electronics, namely to means of attenuating the output radiation of a slot-type gas laser with high-frequency excitation of the active medium, in particular, sealed slot CO ₂ lasers. The technical result consists in the implementation of the stated purpose, as well as in increasing the efficiency of attenuation of the output radiation. A means for attenuating the output radiation, containing two calibrated polarization-type attenuators mounted on an alignment table, each of which contains four plane-parallel polished zinc selenide plates installed at a Brewster angle to the radiation axis, while the plates of the first calibrated attenuator are rotatable around the optical axis radiation.

Description

Technical field

The utility model relates to quantum electronics, namely to means of attenuating the output radiation of a slot-type gas laser with high-frequency excitation of the active medium, in particular, sealed slot CO ₂ lasers.

State of the art

Currently, various materials are used to attenuate the output radiation, for example, KCl or ZnSe crystals with special coatings, producing from them attenuating elements of the output radiation. The disadvantage of the known attenuating elements is that these elements cannot change the transmittance, and in order to obtain a certain (required) transmittance, it must be specially selected. However, this is not always sufficient, since there will either be a small weakening or a strong one, i.e. a stepwise attenuation coefficient is obtained. In this case, it is necessary to have a fairly large number of different elements in stock, since such attenuation elements often burn from powerful radiation, etc.

Essence of a utility model

The technical result consists in increasing the efficiency of attenuation of output radiation.

The claimed technical result is achieved by the fact that the means for attenuating the output radiation, according to this utility model, contains two calibrated polarization-type attenuators mounted on an adjustment table, each of which contains four plane-parallel polished zinc selenide plates installed at a Brewster angle to the radiation axis, while the plates of the first calibrated attenuator are designed to rotate around the optical axis of the radiation.

Brief description of drawings

In fig. Figure 1 shows a conventional optical design of a laser with external corrective optics.

In fig. 2 shows a weakening means according to the present utility model.

The figures indicate the following positions: 1 – laser casing with a hole; 2 – pilot semiconductor laser; 3 – optical element; 4, 5 – calibrated attenuators; 6 – plane-parallel polished plates; 7 – electric motor.

Carrying out the invention

In fig. 1 output beam is output through a hole in the laser housing (1) and enters the axis imaging system, consisting of a pilot semiconductor laser (2) with a collimating lens and an optical element (3).

This optical element (3), mounted at an angle of 45 degrees to the beam axis and made of zinc selenide, has optical coatings that allow infrared laser radiation to pass through and almost completely reflect the visible red radiation of the pilot laser. The axes of both beams are aligned by adjustment.

Next, the infrared laser radiation is fed into a means for attenuating the output radiation (Fig. 2), which contains two calibrated attenuators (4 and 5) of the polarization type mounted on an adjustment table (not shown), each of which contains four plane-parallel polished selenide plates (6) zinc, installed at the Brewster angle to the radiation axis.

The first polarization attenuator (4) is gradient and has a variable transmittance from 100% to 0.7% (shown in figure 2 on the right).

As you can see, the polarizer plates installed inside are designed to rotate from 0 to 90 degrees around the optical axis of radiation by means, for example, of an electric motor (7), as a result of which the transmittance changes within the required limits.

The second attenuator (5) (shown left in FIG. 2) has a constant transmittance of 2%. In this case, the angle of rotation of the foot is selected experimentally and is rigidly fixed; no rotation is required.

Claims (1)

A means for attenuating the output radiation, containing two calibrated attenuators of the polarization type mounted on an alignment table, each of which contains four plane-parallel polished zinc selenide plates installed at a Brewster angle to the radiation axis, while the plates of the first calibrated attenuator are configured to rotate around the optical axis of radiation .