RU1777526C - Electric discharge laser with diffusion cooling - Google Patents

Abstract

FIELD: laser technology. SUBSTANCE: laser has optical resonator 1, two discharge sections 2 with main electrodes 3 and auxiliary electrodes 5, 6. Pulse voltage source 7 generates sequences of voltage pulses to be applied to auxiliary electrodes 5, 6. Auxiliary electrodes are manufactured in the form of conductive strips applied to outer surface of dielectric tube. Electric discharge which burn between main electrodes 3 of sections excites gas mixture. Increased power of radiation is obtained thanks to stabilization of heat instability of discharge in sections integrated with one common gas volume with the use of lateral auxiliary discharge. Additional increase of power is achieved thanks to use of negative feedback stabilizing discharge and embracing either main power supply source 4 or pulse voltage source 7. EFFECT: increased radiation power. 3 cl, 4 dwg

Description

 The invention relates to the field of quantum electronics and can be used to excite high-power gas lasers with diffusion cooling of the working mixture.

A device for a gas laser with diffusion cooling of the working mixture is known, which consists of a liquid-cooled discharge tube, inside which a gas-discharge plasma is created using a system of electrodes. At the ends of the discharge tube are placed resonator mirrors. The limiting value of the radiation power, which is achieved in CO ₂ lasers with diffusion cooling, is 30–40 W / m. This value is limited by the rate of heat removal to the walls of the discharge tube.

 From design considerations associated with limiting the magnitude of the discharge voltage and the dimensions of the installation, it is advisable to produce powerful diffusion lasers with a long active medium in the form of a series of shorter tubes. Radiation passes through these tubes sequentially using a system of rotary mirrors, combining them into a common resonator. The disadvantage of such lasers is discontinuities in the tubes and the associated loss of radiation in the rotary mirrors and the gaseous medium of ballast volumes.

 The closest in technical essence and the achieved result is an electric discharge laser, which contains an optical resonator, which is a rigid case, at the ends of which resonator mirrors are installed in the alignment devices. Two discharge sections are installed sequentially inside the rigid body along the optical axis, each section comprising a dielectric tube, at the ends of which the main electrodes are located, and on the outer surface of each dielectric tube there is an auxiliary electrode made in the form of an electrically conductive coating.

 The disadvantage of the prototype is the low radiation power, since a necessary condition for the stable operation of the discharge is the presence of ballast volume between the sections. There is no electric discharge in this volume and, therefore, the active medium is not excited. This, as well as absorption of radiation in the ballast volume, limits the output power of the laser.

 The aim of the invention is to increase the radiation power.

This is achieved by the fact that in an electric-discharge laser with diffusion cooling containing an optical resonator, two discharge sections are mounted in series along the optical axis of the resonator, each section comprising a dielectric tube, at the ends of which there are main electrodes, one of which located between the sections, is made common to both sections, the main electrodes are connected to the main power source, and on the outer surface of each dielectric tube there is an auxiliary elec a kind made in the form of an electrically conductive coating and connected to a pulse voltage source, each section is equipped with a second auxiliary electrode, which is also connected to a pulse voltage source, in each section the auxiliary electrodes are made in the form of strips located along the tube axis with gaps symmetrically relative to the tube axis, dielectric tubes are installed so that they are adjacent to the main electrode located between them, and the source of the pulse voltage is made so that the amplitude of its pulses U _and satisfies the relation
U _and > 2Ud / l, where U is the static breakdown voltage between the main electrodes of the same section at the operating parameters of the laser gas mixture;
d is the inner diameter of the dielectric tube;
l is the length of the dielectric tube.

 To increase the radiation power, each bit section can be equipped with a current meter, the main power supply is made in the form of two adjustable units and is equipped with a difference circuit and an inverter, while the inputs of the difference circuit are connected to the outputs of the current meters, and its output is connected directly to the control input of one unit and through the inverter to the control input of another unit of the main power source.

 To increase the radiation power, each section can be equipped with a current meter, the pulse voltage source is made in the form of two adjustable blocks and is equipped with a difference circuit and an inverter, while the inputs of the difference circuit are connected to the outputs of the current meters, and its output is connected directly to the control input of one adjustable block and through the inverter to the control input of another unit of the pulse voltage source.

 In FIG. 1 shows a block diagram of a device; figure 2 is a section of a tube in section aa; figure 3.4 - options for the construction of controlled power sources.

 The device contains an optical resonator 1, a dielectric tube 2, the main electrodes 3, the main power supply 4, the first auxiliary electrode 5, the second auxiliary electrode 6, a pulse voltage source 7.

 The device operates as follows.

 The pulse voltage source generates a pulse train with a period between pulses shorter than the characteristic plasma recombination time. A capacitive auxiliary discharge arising in the laser gas medium under the action of electric pulses applied to the electrodes 5, 6 maintains a high conductivity of the medium due to Townsend ionization of the gas. An electric discharge that burns in two sections of the tube between the main electrodes 3 excites the gas mixture. The discharge is powered by the main power source 4 connected to the electrodes 3. Radiation is generated at a sufficiently high degree of excitation of the medium using an optical resonator 1.

 Figure 3 presents the construction option of the main power source, which contains adjustable units 8, current meters 9, differential circuit 10, inverter 11.

 The main power source operates as follows.

 The signals of the outputs of the current meters 9 are fed to a difference circuit 10, the output of which forms a signal proportional to the difference of the currents. This signal regulates (in opposite directions) the voltage of blocks 8 in such a way that a change in the input power compensates for the flow of gas from one section to another.

 In FIG. 4 shows an embodiment of a device that includes adjustable pulse units 12.

 The device in this embodiment works as follows. The signals from the outputs of the current meters 9 are fed to a difference circuit 10, the output of which is a signal proportional to the difference of the currents. This signal regulates (in opposite directions) the amplitude of the voltage pulses that the adjustable units 12 generate so that a change in the input power compensates for the flow of gas from one section to another.

An auxiliary pulse discharge, which is excited by high voltage pulses, in the direction perpendicular to the axis of the tube, serves to control the conductivity of the gas. Townsend gas ionization during discharge pulses increases the plasma density. Between pulses, there is no independent ionization of the gas, since the intensity of the main discharge that burns between the electrodes of the section is not large enough, the gas-discharge plasma recombines. The voltage amplitude of the auxiliary pulses is chosen so that self-ionization in the auxiliary discharge would compensate for the loss of charged particles between pulses. The duration of the auxiliary discharge current is limited by the distributed capacity formed by the outer surface of the tube with a metal coating and the inner surface of the tube in contact with the gas-discharge plasma. The design of the electrodes is highly stable auxiliary discharge, since the development of local plasma disturbances is limited by the distributed capacity. The emerging type of discharge makes it possible to more efficiently excite the active medium of the laser, since the voltage of the main discharge can be regulated and chosen so that the excitation efficiency of the upper laser level is maximum, and the discharge burns steadily in both sections when the above relation is fulfilled for the pulse amplitude U _{and the} pulse voltage source .

PRI me R. The discharge device used dielectric tubes with an internal diameter of 2 cm and a length of 120 cm (with two sections of 60 cm each), auxiliary electrodes made in the form of a copper coating deposited on the outer surface of the tubes (tube glass thickness 1 mm). A pulsed voltage source generated pulses with a duration of 100 ns, an amplitude of 5 kV, and a frequency of 10 ⁴ Hz. The resonator consisted of a deaf copper mirror with a radius of rounding of 5 cm and a flat mirror of ZnSe. The gas mixture of CO ₂ : N ₂ : He at a ratio of 1: 9: 20, a pressure of 30 torr. The maximum output power of the radiation is 60 W or 50 W / m.

Claims (3)

1. ELECTRIC DISCHARGE LASER WITH DIFFUSION COOLING, comprising an optical resonator, two discharge sections arranged sequentially along the optical axis of the resonator, each section including a dielectric tube, at the ends of which there are main electrodes, one of which located between the sections, is common for both sections while the main electrodes are connected to the main power source, and on the outer surface of each dielectric tube there is an auxiliary electrode, made in the form of an electrically conductive coating and connected to a pulse voltage source, characterized in that, in order to increase the laser radiation power, each section is equipped with a second auxiliary electrode, which is also connected to a pulse voltage source, in each section the auxiliary electrodes are made in the form of strips along the axis of the tube with gaps symmetrically relative to the axis of the tube, and the dielectric tubes are installed so that they are adjacent to the main electrical kind, and the source of the pulse voltage is made so that the amplitude of its pulses U _and satisfies the relation
U _and > 2Ud / l,
where U is the static breakdown voltage between the main electrodes of one section at the operating parameters of the laser gas mixture;
d is the inner diameter of the dielectric tube,
l is the length of the dielectric tube.  2. The laser according to claim 1, characterized in that each discharge section is equipped with a current meter, the main power supply is made in the form of adjustable units and is equipped with a difference circuit and an inverter, while the inputs of the difference circuit are connected to the outputs of the current meters, and its output is connected directly to the control input of one unit and through the inverter to the control input of another unit of the main power source.  3. The laser according to claim 1, characterized in that each section is equipped with a current meter, the pulse voltage source is made in the form of two adjustable units and is equipped with a difference circuit and an inverter, while the inputs of the difference circuit are connected to the outputs of the current meters, directly connected to its output to the control input of one adjustable unit and through the inverter to the control input of another unit of the pulse voltage source.

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