RU81597U1 - ARC SYSTEM - Google Patents

Abstract

The utility model relates to electrical engineering, in particular to protective switching equipment and can be used as part of protective contact switching devices. The arcing system contains contacts and an insulating casing. What is new is that the insulating body is made in the form of a hollow pipe with grooves on the inner surface located at intervals along the entire body, and through holes are made in each groove located on opposite sides relative to each other. The technical result is an increase in heat transfer from the electric arc to the environment due to its rotation between the grooves of the housing and reducing the impact of exhaust gases on the inner surface of the housing. 1. p. F-crystals, 2. FIG. heck.

Description

The utility model relates to electrical engineering, in particular to protective switching equipment, and can be used as part of protective contact switching devices. In DC circuit breakers, arcing systems are used to increase the breaking capacity. Such devices are known from the following sources:

1. A.I. Golubev. High-speed circuit breakers. - M. - L .: Energy, 1964, pp. 125-150;

2. O.B. Bron. Electric arc in control apparatus, part 2. - M.: Gosenergoizdat, 1954, pp. 298-307;

3. Patent RU No. 66114 H01H 73/18, 2007;

4. Patent RU No. 2028683 H01H 9/30, 1991;

5. O.B. Bron. Electric arc in control apparatus, part 2. - M .: Gosenergoizdat, 1954, p. 269 Fig. IX-28;

The closest analogue can be the interrupter circuit breaker system for the fifth source. This interrupter system comprises a housing with longitudinal parallel slots made of electrical insulation material and a magnetic blast system. The disadvantage of this arcing system is the large mass

device performance, which accordingly increases the cost of the device. The presence of a powerful magnetic blast system for pulling the electric arc into the gap region affects the manufacturability of the structure and complicates the process of its manufacture. A large number of parts reduces the reliability of the device.

The objective of the utility model is to create an arcing system with effective cooling of the arc and, as a result, its reliable extinction, and therefore reliable in operation and technological in the manufacture of the structure.

The technical result of the utility model is that the heat transfer from the electric arc to the environment increases due to its rotation between the grooves of the housing and the effect of exhaust gases on the internal surfaces of the housing decreases.

The essence of the utility model is that the insulating body of the arc extinguishing system is made in the form of a hollow pipe with grooves on the inner surface located through gaps along the entire body. Through holes are made in each groove located on opposite sides relative to each other.

The extinguishing system of the claimed utility model consists of an insulating body 1, the shape of which is made in the form of a hollow pipe. On each side of the case there are contacts 2, 3. On one of

The contacts mounted coil 4 to create a longitudinal magnetic field of the arc.

The extinguishing system is illustrated by an example implementation. The body of the arcing system is shown in figure 1. Figure 2 shows a diagram of an arcing system with open contacts. To explain the operation of the arcing system, Fig. 2 shows a coil creating a longitudinal magnetic field (the direction of the magnetic induction vector In the field is aligned with the direction of the electric current in the arc). This coil is an element of the design of the switch on which the arcing system is installed and can be either a coil of parallel or sequential magnetic blast. A longitudinal magnetic field can also be created with the help of permanent magnets.

The operation of the arcing system when disconnecting the short circuit current occurs as follows.

When the contacts 2, 3 open, an electric arc arises between them, which, under the action of the magnetic field of the coil 4 of the magnetic blast of the switch directed along the direction of the current in the electric arc, starts to rotate and twist into a spiral. The diameter of the spiral increases until the electric arc enters the grooves inside the housing. Electric arc,

touching the inner walls of the housing, it is intensively cooled and completely extinguished.

The operation of the arcing system when disconnecting small inductive currents occurs as follows. When the contacts 2, 3 open, an electric arc arises, which, under the action of the magnetic field of the coil 4 of the magnetic blast of the switch directed along the direction of the current in the arc, begins to rotate and twist into a spiral. At low currents, the force tending to increase the diameter of the spiral will not be enough to reach the grooves of the body by the electric arc. Arc extinction in this case will occur due to stretching of the electric arc and its rotation.

When changing the direction of the electric current of an open circuit, only the direction of rotation of the electric arc will change, which will in no way affect the disconnection of short-circuit currents and small inductive currents.

Thus, through the use of an insulating casing with grooves on the inner surface of the pipe located at regular intervals along the entire casing, the heat transfer from the electric arc to the environment increases due to its rotation between the annular grooves and the effect of exhaust gases on the inner surfaces of the casing is reduced, which increases service life of the interrupter system, increases reliability and efficiency

arc extinction. At the same time, the manufacturability of the arcing system assembly is improved due to the exclusion of the arcing system. To prevent ignition from hot exhaust coming out of the housing openings, blinds can be installed on the outside of the housing, which will increase the reliability of the entire system by an order of magnitude.

Claims (1)

An interrupter system comprising main contacts and an insulating casing, characterized in that the casing is made in the form of a hollow pipe with grooves along the inner surface located at intervals along the entire casing, and through holes are made in each groove located on opposite sides relative to each other.