RU2013136116A - HIGH-EFFICIENT GAS LASER DISCHARGE SYSTEM - Google Patents

Abstract

1. The discharge system of a high-performance gas laser, comprising extended first and second electrodes located in the laser housing defining a discharge zone between them; a preionizer placed on the side of one of the electrodes, made in the form of a uniform sliding discharge ignition system between an extended ignition electrode and an additional electrode located on the surface of a dielectric layer covering an extended metal substrate connected to an additional electrode, characterized in that the dielectric layer is made in the form of a direct a thin-walled dielectric tube either solid or longitudinally cut; on the outer surface of the dielectric tube, an ignition electrode and an additional electrode are placed along it, and the metal substrate is placed inside the dielectric tube so that at least part of the surface of the metal substrate is aligned with the extended part of the inner surface of the dielectric tube. 2. The discharge system according to claim 1, characterized in that the dielectric layer is made in the form of a solid dielectric tube, through the end of which an additional electrode is connected to a metal substrate placed inside the dielectric tube. The discharge system according to claim 1, characterized in that the dielectric layer is made in the form of a dielectric tube having a longitudinal section through which an additional electrode is connected to a metal substrate placed inside the dielectric tube. The discharge system according to claim 1, characterized in that the dielectric tube is made of ceramic, in particular AlO.5. Bit system

Claims (7)

1. The discharge system of a high-performance gas laser, comprising extended first and second electrodes located in the laser housing defining a discharge zone between them; a preionizer placed on the side of one of the electrodes, made in the form of a uniform sliding discharge ignition system between the extended ignition electrode and the additional electrode, located on the surface of the dielectric layer covering the extended metal substrate connected to the additional electrode, characterized in that the dielectric layer is made in the form of a straight thin-walled dielectric tube either solid or with a longitudinal section; on the outer surface of the dielectric tube, an ignition electrode and an additional electrode are placed along it, and the metal substrate is placed inside the dielectric tube so that at least part of the surface of the metal substrate is aligned with the extended part of the inner surface of the dielectric tube. 2. The discharge system according to claim 1, characterized in that the dielectric layer is made in the form of a solid dielectric tube, through the end of which an additional electrode is connected to a metal substrate placed inside the dielectric tube. 3. The discharge system according to claim 1, characterized in that the dielectric layer is made in the form of a dielectric tube having a longitudinal section through which an additional electrode is connected to a metal substrate placed inside the dielectric tube. 4. The discharge system according to claim 1, characterized in that the dielectric tube is made of ceramic, in particular Al ₂ O ₃ . 5. The discharge system according to claim 1, characterized in that either the additional or the ignition electrode of the sliding discharge ignition system is connected to one of the laser electrodes. 6. The discharge system according to claim 1, each point of the discharge zone between the first and second laser electrodes, each point of the discharge zone between the first and second laser electrodes is optically coupled / located in the line of sight, at least with a part / part of the surface of the ceramic tube between ignition and additional electrodes used to ignite a sliding discharge. 7. The discharge system according to any one of claims 1 to 6, characterized in that it contains two identical preionizers located on the sides of either the first or second electrode.