RU80627U1 - ELECTROMAGNETIC DRIVE CIRCUIT BREAKER - Google Patents

Abstract

The utility model relates to electrical engineering, in particular, to electromagnetic drives of switching devices and is designed to disconnect emergency currents. The electromagnetic drive of the DC circuit breaker contains at least one movable and one fixed contact, which disconnects the spring, the spring of free tripping, the magnetic circuit with a holding coil, the main armature, the anchor of free tripping and traction. New is that the main anchor and the free trip anchor are mounted on the same axis, and the free trip anchor is located inside the magnetic circuit. This embodiment of the electromagnetic drive leads to a decrease in the length of the drive and increase insulation. In addition, reliability increases when emergency currents are switched off and maintainability is ensured. 1.p. f-ly, 5. fig.

Description

The utility model relates to electrical engineering, in particular, to electromagnetic drives of switching devices.

Electromagnetic drives of direct current circuit breakers are known, for example, certificate of the Russian Federation No. 27737 for utility model Н01Н 77/06 2003; patent No. 2239253 for the invention H01H 77/06 2003;

Reference book on the adjustment of electrical equipment of industrial enterprises. Ed. M.G. Zimenkova, G.V. Rosenberg, E.M. Feskova. - 3rd ed., Revised. and Dop.-M .: Energoatomizdat, 1983, S. 236-238.

The closest to the patent should be considered the electromagnetic drive of the circuit breaker according to the following source: patent No. 2239253 for the invention H01H 77/06 2003

This drive contains at least one movable and one fixed contacts, which disconnects the spring, the spring of free tripping, the magnetic circuit with a holding coil, the main armature, the anchor of free tripping and traction.

The disadvantage of this drive is the large size along the length of the magnetic circuit. An electromagnet coil is wound directly on the magnetic circuit, which leads to difficulties in providing insulation and the inability to replace it during repair work.

A useful model solves the problem of creating an electromagnetic drive of a DC circuit breaker, characterized by high reliability when disconnecting both large and low currents, maintainability,

and small in height and length. In addition, effective isolation of the drive coil from the magnetic circuit is provided.

The technical result of using the utility model is to reduce the length of the electromagnetic drive and increase insulation.

To ensure this, the main anchor and the free trip anchor are located on the same axis, while the free trip anchor is located inside the magnetic circuit. In addition, the main anchor is connected to the movable contact through the spring of free uncoupling by means of rods, and the anchor of free uncoupling has a movement limiter for said rods.

The essence of the utility model is as follows.

With this embodiment, the free trip anchor when disconnecting (falling off the core of the magnetic circuit) does not go beyond the dimensions of the magnetic circuit, that is, it works within the length of the magnetic circuit, which reduces the length of the drive as a whole. Due to the implementation of such a design of the magnetic circuit (the central core of the magnetic circuit is separated from the main part), it becomes possible to install a coil on the magnetic circuit, which makes it possible to strengthen the insulation. The speed of the drive is maintained at the prototype level, since the forces in the intermediate moving parts act only on compression and tension (no bending and torsion), which makes them less massive.

The utility model is illustrated by an example implementation. Figure 1 presents the electromagnet of the drive in the on position, figure 2 is a diagram of the electromagnetic drive of a constant current switch

current in the on position, figure 3 is a top view of the drive, figure 4 - the drive is shown in the up position, figure 5 is the same in the off position.

The electromagnetic drive of the DC circuit breaker contains a vertically movable contact 1, a fixed contact 2, a disconnecting spring 3, a free trip spring 4, a magnetic circuit 5 with a holding coil 6, the main armature 7, the free trip armature 8 and traction 9, 10.

The main anchor and the free trip anchor are mounted on the axis 12. The main anchor 7 is connected to the movable contacts 1 through the springs 4 by means of rods 9 and 10, pivotally connected to each other. The free trip anchor 8 has stops 11. The stops 11 are made in the form of rods arranged horizontally along the rods of the magnetic circuit. At one end, the stops 11 are pivotally attached to the free trip anchor 8, and the other end interacts with the rods 10 in the upstream position of the switch. The stops 11 are installed in the guides 13.

The electromagnetic drive of the DC circuit breaker operates as follows.

When a switching current flows through coil 6, the main armature and the free trip armature are simultaneously attracted to the magnetic circuit. The main anchor through the springs 4 and rods 9, 10 pulls the movable contacts along until the rods 10 abut against the stops 11. The main anchor continues to be attracted by compressing the springs 4. The drive remains in the up position (figure 4), while the holding coil flows switching current. Mobile contacts 1 do not close

with fixed contacts 2. This is necessary so that the contacts of the circuit breaker do not close while a large amount of switching current flows through the drive coil, since if the main circuit already has a short circuit, the drive will not be able to trip with the desired speed.

Then the holding coil switches to a smaller holding current. The free trip armature 8 cannot be held by the magnetic flux of the holding current in the drawn position, it falls off and releases the stops 11 (FIG. 2).

The springs 4 translate the contacts 1 to the on position and create a contact push with a failure 5, as shown in figure 2. The drive is ready for immediate shutdown. In this way, the circuit breaker can be tripped freely.

As can be seen from the description of the work, the free trip anchor when disconnecting (falling off the core of the magnetic circuit) does not go beyond the dimensions of the magnetic circuit, that is, it works within the length of the magnetic circuit, which reduces the length of the drive as a whole. Due to the implementation of such a design of the magnetic circuit (the central core of the magnetic circuit is separated from the main part), it becomes possible to install a coil on the magnetic circuit, which increases the insulation. The speed of the drive is maintained at the prototype level, since the forces in the intermediate moving parts act only on compression and tension (no bending and torsion), which makes them less massive.

Claims (1)

An electromagnetic drive of a DC circuit breaker, comprising at least one movable and one fixed contact, a disconnecting spring, a free trip spring, a magnetic circuit with a holding coil, a main armature, a free trip arm and a pull rod, characterized in that the main armature and a free trip armature located on the same axis, while the free trip anchor is located inside the magnetic circuit.