SU484588A1 - Block of controlled arrays - Google Patents

Description

one

The invention relates to high-voltage impulse technology, in particular, devices for generating strong impulse currents and pulsed magnetic or electric fields.

Blocks of controlled arresters are known, containing a series of two-electrode discharges and a source of illumination. However, in known blocks at high voltages, the source of illumination cannot be positioned close to the spark gaps of the arresters, while the arresters reliably work only at voltages very close to the static bit when the probability of spontaneous trials sharply increases. The initiation of a laser beam requires technically complex and expensive auxiliary equipment and does not solve the problem of synchronous multichannel energy switching.

The purpose of the invention is to provide initiation of synchronous discharge and increase reliability of operation. This is achieved by the fact that the block of controlled arresters is equipped with a housing made in the form of a confocal system of elliptical mirrors, in the regions of the focal points of which are located the electrodes of the arrays and the source of illumination.

FIG. Figure 1 shows a case of a five-wavelength spike consisting of four mirrored from inside confocal ellipsoids of rotation, section; in fig. 2 - a handful of four pairwise confocal and coaxial mirrored from the inside ELLIPSOIDS of rotation, Serving as a body of a five-rugged discharge unit, section. In the areas of the focal points 1, 2, 3, 4, electrodes of the arresters 5, 6, 7, 8 are installed. In the common focal point a, there is a source of the auxiliary spark illuminator 9

(for example, a trigotron or plasma clot from a laser spark).

Elliptical mirrors spatially separate the source of the spark of illumination and gap gaps and serve to create an avalanche-like mode of increasing the density of the light flux at the focal points as it enters the discharge unit.

Thus, the use of the luminous flux from the discharging arresters causes the dischargers to accidentally fail to work, and creates a positive feedback mode between all the arresters. Radiator bodies are conveniently made by turning a lathe on a lathe from

aluminum (duralumin) modules, which are halves of ellipsoids of rotation and confocal fragments of two or more halves of ellipsoids of rotation. Windows are bored in the areas of the focal points, through which electrodes are inserted inside the bushing insulators. The mirror surface is made by polishing the modules from the inside, it can be improved by spraying aluminum. The modules are assembled in a sealed configuration as shown in FIG. 1 or FIG. 2. The processes of evacuating the gas filling system and ventilation are carried out through valves installed on the discharge housing. The bushing insulators are made of fluoroplastic or preciglum and are provided with seals that allow the outside to adjust the size of the gap between the electrodes. The gas filling, the pressure, the gap between the electrodes and the material of the electrodes are entirely determined by the mode of operation.

Optimal materials for electrodes are metals with a low electron work function, high thermal conductivity, high heat resistance and low

the resistance of the oxide film on the working surface.

Gas filling essentially determines the material of the electrodes. Apparently, hydrogen argon filling with zirconium electrodes is optimal.

However, electrodes of beryllium bronze or carbon, even in an atmosphere of air, give quite good results.

Subject invention

A unit of controlled arresters containing a series of two-electrode arresters and an auxiliary source of light, characterized in that, in order to ensure the initiation of a synchronous discharge and increase reliability of operation, it is equipped with a housing made in the form of a confocal system of elliptical mirrors in the areas of focal points which are located the electrodes of the arresters and the source of illumination.