SU1130929A1 - Protective spark-gap transmit -receive tube - Google Patents

Description

The invention relates to electrical engineering and radio engineering, in particular, to protection devices of high-frequency power systems for linear ion accelerators.

A three electrode arrester is known, which contains two main electrodes, one of which is hollow, and a firing electrode located between the main electrodes and connected to a conductive insert placed in the cavity of the main electrode. The arrester provides short delay times for Cl.

The disadvantage of the discharge is the impossibility of using it for protection of two or more communication lines.

Closest to the invention is a protective discharge containing at least one pair of coaxially mounted high voltage electrodes for connection to corresponding protected communication lines each of which forms a protective discharge gap with a common grounded hollow electrode divided by a partition with a through hole in two compartment, each of which is coaxially located one of these high-voltage electrodes and the ignition electrode mounted under a floating potential 2.

A disadvantage of the known discharge is the low response speed due to the delayed operation of protective discharge gaps relative to each other in the compartments of the grounded electrode, which leads to voltage imbalance in the communication lines.

The delay of the triggering of the discharge stubs is determined by two components: the time of movement of the discharge channel by the intrinsic field of the current from the initiation region to the protective discharge gap and its own delay time for the triggering of another protective discharge gap. Thus, the discharge time of the discharge depends on the current in the protective discharge gap, the length of the path of the discharge channel, as well as on the intensity and efficiency of the gas ionization in the adjacent protective discharge gap, which generally affects the speed of protection without allowing will increase the response rate of the trigger.

The purpose of the invention is to increase the response speed of the protection arrester.

This goal is achieved by the fact that in a protective arrester containing at least one pair of coaxially installed high-voltage

electrodes for connection to appropriate shielded communication lines, each of which forms a protective discharge gap with a common grounded electrode, separated by a partition with a through hole and two compartments, each of which is coaxially positioned with one of the high-voltage electrodes and the ignition electrode, installed at a floating potential, the wall of the grounded electrode is made with a cavity in which there is an additionally inserted conductive insert electrically connected to the ignition Electrode which are in the form of disks with sharp edges and are mounted in the gaps between the partition and the appropriate high voltage electrode.

Lig.1 shows the construct of the protective discharge circuit with one pair of high-voltage electrodes in Figure 2, the same with two pairs of high-voltage electrodes.

The arrester consists of a metal hollow case, which is grounded electrode 1 and divided by partition 2 into compartments 3, in which high-voltage electrodes 4 connected to communication lines (not shown) are coaxially mounted. Conductively installed in the cavity of partition 2 an insert 5, which is connected through openings in the partition 2 with the ignition electrodes 6 placed in the compartments 3, made in the form of disks with sharp edges.

In the case of protection by a two-line discharge voltage, it is made with one pair of coaxial high-voltage electrodes 1FIG.11, and in case of a four-line discharge protection, it is performed with two pairs of coaxial high-voltage electrodes (Figure 2).

Protective glitch works as follows.

The high voltage electrodes of the 4th discharge are connected to the appropriate communication lines, and the electrode 1 is grounded. Between the partition 2 of the electrode 1 and the high voltage electrodes 4, protective discharge gaps of the discharge are formed.

In the normal operating mode, the magnitude of the floating potential of the igniting electrodes 6 in the protective discharge gaps is determined by the amplitude and phase voltage of the voltages applied to the high voltage electrodes 4, In general, it is proportional to the algebraic voltages of the high voltage electrodes 4, and the value of the proportionality coefficient is determined by the ratio of geometric capacitances formed under

Claims (1)

PROTECTIVE DISCHARGE, containing at least one pair of coaxially mounted high-voltage electrodes for connection to the corresponding protected communication lines, each of which forms a protective discharge gap, with a common grounded hollow electrode, divided by a partition with a through hole into two compartments, in each of which is coaxially one of the high-voltage electrodes and an ignition electrode located under a floating potential are located, characterized in that, in order to increase the response speed, odka ground electrode is formed with a cavity in which is mounted additionally introduced conductive pad electrically connected to the ignitors, which are constructed as disks with sharp edges and set ^'g in the gaps between the partition and coot- g sponds high voltage electrode.