SU522832A3 - Multielectrode Tubular Gas Discharge - Google Patents

Description

(54) MULTI-ELECTRODE TUBULAR GAS DISCHARGE

The invention relates to temperature-sensitive electrical adjustment devices that do not present a fire hazard during prolonged current and voltage overloads.

Multielectrode tubular gas dischargers with current leads are known.

The purpose of the invention is to provide fire safety conditions.

This is achieved by the fact that the gas discharger is enclosed in an electrically insulated case, thermal insulation material is placed between the case walls and the discharger, and the current leads are fused.

At the firm. i shows the proposed device, a general view; in fig. 2 is the same, front view; in fig. 3 is a section A-A in FIG. I (two modifications); in fig. 4 - floor lining of low-melting material (one of the options; 20 increased); in fig. 5 is a block diagram of the connection of a multielectrode tubular gas discharge with an electric circuit.

The tubular gas discharge 1 of a three-electrode type is enclosed in a housing 2, which is 25

may be of any shape or configuration, for example, rectangular (see Figs. 1-3), and may be made of any electrically insulating material. The gas gaps 1 are separated from the walls of the case by thermal insulating material 3 has current leads 4-6

The current lead 4 (see Fig. 2) contains a cylindrical shell 7, a hollow shell 8 of light-melting material, one end of which is electrically connected to the gas discharge electrode 1 through solder 9, and the other end of the hollow shell is electrically connected through solder 10 with solid rod 11 of electrically conductive wire. The other end of the rod 11 is connected with the tip 12. The floor of the shell 8 of a low-melting material can be made in the form of tightly packed granules of electrically conductive material (see Fig. 4), which, after reaching the pre-set temperature, melt and occupy only part of the volume previously occupied by the granules, causing this interruption of the electrical conductivity in the structure of the granules. The current lead 4 can be connected to the gas discharge 1 through solder 13 (see Fig. 3a), and the discharge itself is located in a cavity filled with thermally insulated, sealed material 14, and after reaching a predetermined temperature, the solder liquefies and flows into said cavity, as a result of which the electrical circuit between the gas discharge electrode and the current lead is broken.

The device works as follows.

The current leads 4 and 5 are electrically connected to the source of electrical energy, and the current lead 6 is connected to earth (see Fig. 5).

In case of overload on voltage, the gas discharge 1 ionizes, providing a direct path to the ground through the current lead 6 and shunt the ground to any overload.

When overloaded, the temperature of the tubular gas discharge rises, but due to the presence of thermal insulation material 3, heat energy is not dissipated into the environment, as in known devices, but is concentrated in the device itself, which raises the temperature of the current leads. After the temperature of the shell 8 reaches the melting point, the low-melting material will start to melt and flow into the said /

the cavity, causing an interruption in the electrical circuit between the current lead 4 and the gas discharge 1. The low-melting mass is configured such that its melting point is lower, the temperature at which the multielectrode tubular gas distributor becomes flammable.

This device is a one-time device and responds to overcurrent conditions. In this case, the current passing through the hollow shell 8 heats the fusible mass, and the molten mass, flowing, causes an electrical circuit to break.

Claims (1)

Invention Formula A multielectrode tubular gas discharge with current leads, characterized in that, in order to ensure fire safety conditions, the gas discharge is enclosed in an electrically insulated housing, thermal insulation material is placed between the housing walls and the discharge, and the SURFACE is in the form of fuses. FIG. one