RU797512C - Pulsed-alternating gas laser - Google Patents

Description

3

with

d

n

The invention relates to quantum electronics and can be used to create pulse-periodic lasers.

A gas laser excited by an electric discharge is known, comprising an electric-discharge chamber with electrodes, a heat exchanger and a compressor for pumping gas in a closed loop. The disadvantages of this laser include the high energy consumption for pumping and cooling the gas, which is greater than the maximum laser radiation power. The energy consumption for pumping gas is substantial, reduced in the well-known pulse-periodic laser. Fixed elerodes are mounted on the inside of the laser housing, and a cylindrical rotor Cj, electrodes and plate heat exchangers are mounted on the rotating shaft. When rotating the rotor of the tag1 exchanger, they move through the gas and cool it. The disadvantage of this laser is the low pulse repetition rate, because the heat sinks on the rotor are located between the electrodes. This reduces the number of electrodes that can be installed on the rotor, and therefore, the number of pulses during one revolution of the rotor.

The aim of the invention is to increase the laser power by increasing the pulse repetition rate.

This goal is achieved in that in a pulsed-periodic gas laser containing a housing with electrodes and a rotating shaft, there are mounted discs with holes on the shaft, and electrodes are fixed on the circumference of the discs parallel to the axis of the shaft; isolated from the shaft and between each other, while the working surfaces of adjacent electrodes are facing each other.

The invention is illustrated in the drawing, in FIG. 1, which shows a structural diagram of a laser in axial section, and FIG. 2 is a structural diagram of a laser in cross section.

The device is made as follows. A rotary shaft 2 is mounted in the housing 1, rotated by an electric motor 3. Disks 4 are fixedly mounted on the shaft 2, electrodes 5 are located around the disk. The heat exchanger b, electrical inputs 7 and 8, with sliding contacts, mirrors are fixed: 9 resonators.

. The electrodes 5 are metal bars of approximately triangular cross section with rounded corners.

The working surfaces of the electrodes have a convex shape of a special profile that provides the necessary degree of homogeneity of the gas discharge. The working surfaces of adjacent electrodes are facing each other and form discharge gaps between them. The gap, the axis of which at the moment of rotation coincides with the axis of the resonator formed by the mirrors 9, is operational.

The operation of the laser is as follows. After filling the housing 1 with a gas mixture of the desired composition, an electric motor 3 of the shaft rotary drive 2 and a pulse power supply (not shown) are turned on, the output circuits of which are connected to electrical inputs 7 and 8. The discharge will be excited every time when one axis coincides from the gaps with the axis of the resonator formed by the mirrors 9. The duration of the discharge pulse and radiation is approximately 1/100 of the pulse repetition period, therefore, the discharge and radiation pulse will occur almost unchanged Mr. position electrodes. In the pause between the radiation pulses, the disk 4 will rotate one step until the axis coincides with the next discharge gap with the axis of the resonator. During this time, the gas heated by the previous Impulse will leave the active Zone together with its pair of electrodes, and a freshly chilled portion of gas located between the next pair of electrodes 5 will take its place. Due to centrifugal forces, the gas will also shift radially, pass through the heat exchanger and return to the cooled to the electrodes 5 through holes in the disks 4. The gas circulation path in Fig. 1 is shown by arrows. Gas from the discharge gap should go one revolution of the disk 4 containing n electrodes, therefore, its speed of movement can be n times lower, where n is the number of electrodes than, for example, known lasers, and the power spent on it convection, ceteris paribus, in n less.

Beyond C4et, a decrease in the angular pitch between adjacent working positions of the discs 4 is achieved by an increase in the pulse repetition rate and. hence the laser power ..

(56) U.S. Patent No. 2,735,284. 331 / 94.5. published. 1973.

USSR copyright certificate N; 654120. cl. And 01 S 3/22. 1977.