SU871248A1 - Vacuum arc extinguishing chamber with protecting device under the loss of vacuum - Google Patents

Description

The invention relates to electrical equipment, in particular to contactors with vacuum interrupter chambers (VDK).

Vacuum interrupter chambers with protective devices for loss of vacuum are known, in which the protection circuit is connected to an insulated screen and one of the current leads £ 1}. In a vacuum circuit breaker with such a chamber, a device for monitoring the pressure in the VDK is connected to the terminals of the fixed contact and the insulated screen, the circuit of which has a voltage source of 10-15 kV, a current relay and auxiliary contacts. With increasing pressure in the VDK and the occurrence of a glow discharge between the contacts of the VDK and the screen, a relay is activated, which gives a signal about the deterioration of the vacuum and prevents the switch from being deflected. The disadvantage of the protective device is the need for a high-voltage power supply, in the complexity of the circuit.

Also known is a vacuum circuit breaker with a device responsive to a pressure change t2j. thirty

The vacuum interrupter chamber contains movable and fixed contacts and an electrode inserted into the chamber and connected to one of the terminals.

A transformer is located on the current lead of the fixed working contact, one terminal of the secondary winding of which is connected to the metal part of the housing, and the other terminal to the discharge electrode. A discharge electrode is mounted on the metal part of the camera body in a transparent insulator. If the vacuum is broken, an ion current arises between the discharge electrode and the metal part of the housing and a glow is observed in the transparent insulator.

Since in the event of a complete loss of vacuum, a high voltage is required to ignite the discharge, this creates additional safety requirements for maintenance personnel. The placement of the discharge electrode in a transparent insulator complicates the design of the chamber.

The aim of the invention is to simplify protection.

This goal is achieved by the fact that in a vacuum arrester with a protection device in case of loss, a vacuum containing movable and motionless. contacts and an electrode inserted inside the chamber and connected to one of the terminals, this discharge electrode is located at the non-contact gap at a distance from each of the contacts exceeding the contact solution.

The use of such a vacuum interrupter chamber with a protection device in case of loss of vacuum eliminates the need for a high-voltage power supply and simplifies the protection circuit.

The drawing shows a diagram of the proposed VDK with a protection device in case of loss of vacuum.

A reed switch 2, a direct current source (about 20 V) and a discharge electrode 3 are connected in series with the first current lead 1. The discharge electrode is inserted into the chamber and is electrically isolated from the second current lead 4 · This electrode is located at the contact gap at a distance from each of the contacts of the current leads 1 and 4, exceeding the contact solution. Reed contacts 5 are included in the circuit breaker of the vacuum contactor

At a permissible vacuum in the VDK (of the order of 10 “. ⁴ mmHg), when the arc · arises during switching in the contact gap, the electrons from the arc column reach the discharge electrode. But with an allowable vacuum, there are few charged particles in the gap between the discharge electrode and each of the contacts, the resistance of this gap is large and therefore the current in the circuit of the reed switch coil is practically zero, and the contacts of the reed switch are open.

With increasing pressure in the chamber, a glow discharge lights up, the space between the discharge electrode and the contacts ionizes, the resistance of the gap between the discharge electrode and the current lead contact drops, current flows in the discharge electrode circuit. The magnitude of this current can be varied depending on the voltage of the source at a certain degree of pressure in the VDC, i.e. you can choose the voltage at the source (as it turned out, about 20 V) so that the reed switch is switched on when a glow discharge occurs in the chamber. If the chamber completely lost the vacuum, then during switching, when an arc arises between the contacts, the gap between the discharge electrode and the contacts is ionized in the same way as when a glow discharge occurs (in this case, the arc even jumps to the discharge electrode), and a current appears in the reed switch circuit sufficient to operate the reed switch. The contacts of the reed switch are closed and include a circuit for disconnecting this section of the circuit.

The protective device has a simple electrical circuit without auxiliary contacts and a high-voltage voltage source.

This vacuum interrupter chamber with a protection device in case of loss of vacuum can be used in vacuum electrical apparatuses where high reliability is required, for example, in explosive atmospheres.

Claims (2)

With a vacuum loss device containing a mobile and stationary device, contacts and an electrode inserted into the chamber and connected to one of the terminals, this discharge electrode is located near the contact gap at a distance from each of the contacts above the cement. thief contacts. The use of such a vacuum interrupter chamber with a loss-vacuum protection device eliminates the need for a high-voltage power supply and simplifies the protection circuit. The drawing shows a diagram of the proposed VDK with a protection device in case of vacuum loss. In series with the first current lead 1, a reed switch coil 2 is connected to a constant current source (approximately 20 V) and a discharge electrode 3. The discharge electrode is inserted inside the chamber and electrically isolated from the second current lead 4. This electrode is located at the contact contact gap at a distance from each of the contacts of the current leads 1 and 4, which exceeds the contact solution. The contacts of the reed switch 5 are included. In the circuit for disconnecting the vacuum contactor. With an allowable vacuum in VDK (on the order of 10 mm Hg), when an arc occurs when switching in an intercontact gap, electrons from the arc column reach the discharge electrode But when the allowable vacuum of charged particles is in the gap between the discharge electrode and each there are few of the contacts, the resistance of this gap is large and therefore the current in the circuit of the reed switch coil is almost equal to zero, and the contacts of the reed switch are open. When the pressure in the chamber increases, the glowing discharge ignites, the space between the discharge electrode and the clock ionizes, the gap resistance between the discharge electrode and the current lead contact falls in the discharge electrode circuit. The magnitude of this current can be varied depending on the source voltage. at a certain degree of pressure in VDK, i.e. It is possible to choose the voltage at the source (as it turned out, on the order of 20 V) so that the reed switch is turned on when a glow discharge occurs in the chamber. If the camera has completely lost the vacuum, then when switching, when an arc occurs between the contacts, the gap between the discharge electrode and the contacts is ionized in the same way as when a glow discharge occurs (the arc even jumps to the discharge electrode) and in the circuit the reed switch there is a current sufficient to trigger the reed switch. The reed switch contacts are closed and turn on the circuit to turn off this part of the circuit. The protective device has a simple electrical circuit without auxiliary contacts and a high-voltage source. This vacuum arc-suppressing chamber with a protection device in the event of vacuum loss can be used in vacuum electrical apparatus where high reliability is required, for example in explosive environments. Claims Vacuum arc-suppressing chamber with a protection device for vacuum loss, containing movable and fixed contacts and an electrode inserted into the chamber and connected to one of the terminals, characterized in — that, in order to simplify protection, said electrode is located at the contact gap from each of the contacts in excess of the contact solution. Sources of information taken into account in the examination 1.Patent dUA 3403927, cl, 317-62, 1966. 2. Japanese Patent I 49-12055, class, 59 H 141, 1974 (prototype). one Nr