RU85748U1 - AUTOMATIC FAST SWITCH - Google Patents

Abstract

Automatic high-speed switch, comprising a switching electromagnet, consisting of a magnetic circuit, a coil and an armature, holding an electromagnet, consisting of a magnetic circuit, a coil and an armature, breaking and turning on a spring, a movable and fixed contact, characterized in that the armature of the switching electromagnet and the holding circuit magnet are firmly connected interconnected and mounted on an axis with the possibility of rotation around it, and on the same axis the anchor of the holding electron is rotatably fixed Nita, the outer edges of the movable contact.

Description

The utility model relates to electrical engineering, in particular to protective switching equipment, and can be used to protect electrical installations and direct current lines from overloads and short circuit currents.

High-speed automatic switches that are held in the on position due to magnetic flux in the working gap of the armature created by the current of the holding coil, and which trip when the specified magnetic flux is reduced, are known from the following sources:

1. Golubev A.I. High-speed circuit breakers, M, - L., Energia Publishing House, 1964, pp. 42-43.

2. Patent for utility model RU No. 333261.

3. Power equipment of traction substations of railways (collection of reference materials). Russian Railways OJSC, branch of the Design Bureau for Electrification of Railways, M. Transizdat Publishing House, 2004, pp. 238-242.

As the closest analogue, based on the number of common essential features, we can consider the circuit breaker for the second source (patent RU No. 333261).

This switch contains a movable and fixed contacts, holding an electromagnet with a magnetic circuit, a coil and an armature, disconnecting the spring, contact pressing spring and electromagnetic switching mechanism. The anchor and the magnetic circuit of the holding electromagnet are mounted on a common axis. The contact pressing spring is located between the switching mechanism and the magnetic circuit of the holding electromagnet. In this case, the switching mechanism is connected to the magnetic circuit of the holding electromagnet through a lever.

In the on position, the magnetic circuit and the armature of the holding electromagnet are attracted to each other due to the current in the coil of the holding electromagnet. The anchor of the switching mechanism is in an attracted position due to the holding current in the coil of the electromagnet of the switching mechanism.

For operational shutdown, it is necessary to interrupt the holding current in the coil of the electromagnet of the switching mechanism. Under the action of the breaking spring, the movable contact and the holding electromagnet go into the disconnected position, while the anchor and the magnetic circuit of the holding electromagnet remain attracted.

The signal from the current sensor (or other emergency shutdown sensor) interrupts the current in the coil of the holding electromagnet. Under the action of the breaking spring, the movable contact and the anchor of the holding electromagnet go into the off position, and the magnetic circuit of the holding electromagnet selects a dip under the action of the contact pressing spring and is attracted to the lever. The anchor of the switching mechanism remains in the drawn position.

The disadvantage of the switch is the high cost of energy consumption. During operation (in continuous mode - in the on position of the switch), both coils consume electric current, therefore, significant power is expended.

In addition, the kinematic connection of the holding electromagnet mechanism and the movable contact is made through an intermediate lever, which reduces the reliability and speed of shutdown.

The objective of the utility model was the development of a circuit breaker more reliable, compact and simple in design.

The technical result that is achieved by the utility model is to reduce power consumption during circuit breaker operation, increase speed, increase reliability of circuit breaker operation.

The specified technical result is achieved in that the circuit breaker is quick-acting, consisting of a switching electromagnet with a magnetic circuit, a coil and an armature, a holding magnet, consisting of a magnetic circuit, a coil and an armature, disconnecting and turning on springs, a movable and fixed contact is made so that the armature of the turning magnet and the magnetic circuit of the holding electromagnet is fixedly fixed to each other and mounted on a common axis with the possibility of rotation around it, and on the same axis eplen rotatably holding electromagnet armature, which is fixedly secured to the movable contact.

With this embodiment of the automatic high-speed circuit breaker, the opening of the contacts occurs without transmitting movement from the armature to the contact, which reduces the time it takes to open the circuit breaker. In addition, the switch in the on position is held by one coil, and the coil of the switching solenoid is completely de-energized, which indicates a decrease in power consumption by the switch. The absence of additional kinematic connections (reduction of structural elements) simplifies the design, increases reliability.

The utility model is illustrated by an example implementation.

Figure 1 schematically shows a patented switch in the off position; figure 2 is the same in an intermediate position; figure 3 is the same in the upstream position; figure 4 is the same in the off position.

The automatic high-speed switch contains a switching electromagnet with a magnetic circuit 1, coil 2 and an armature 3. The holding electromagnet is made of a magnetic circuit 4, coil 5 and an armature 6. The magnetic circuit 4 of the holding electromagnet and the armature 3 of the turning electromagnet are fixed stationary between each other and mounted on the axis 7 with rotation around her. An anchor 6 of a holding electromagnet is fixed on the same axis 7. Breaking spring 8 is placed with the possibility of impact on the anchor 6 of the holding electromagnet. The closing spring 9 is located on the side of the magnetic circuit 4 of the holding electromagnet and is fixed with the possibility of acting on the magnetic circuit 4. The switch contains a movable contact 10 and a fixed contact 11. The movable contact 10 is fixedly mounted on the armature 6.

The operation of the switch is as follows.

When the switch is turned on, a switching current is supplied to the coil 2 (Fig. 1). The armature 3 is attracted to the magnetic circuit 1. In this case, the magnetic circuit 4, rigidly fixed with the armature 3, rotates around the axis 7 to the armature 6. An air gap remains between the armature 6 and the magnetic circuit 4 (FIG. 2). After a certain period of time, a switching current is supplied to the coil 5, and the switching current from the coil 2 is transferred to the holding current. In this case, the anchor 6 and the magnetic circuit 4 are attracted to each other (figure 3). Accordingly, the movable contact 10 is rotated towards the stationary contact and stops in the upstream position (a gap δ remains between the contacts). At this moment, the holding current in the coil 2 is stopped, and the switching current of the coil 5 is transferred to the holding. When the coil 2 is de-energized, the armature 3 falls off from the magnetic circuit 1, and the anchor 6 and the magnetic circuit 4 rotate under the action of the switching spring 9 toward the on position, the contacts of the switch 10 and 11 are closed (figure 4). Breaking spring 8 during rotation of the armature 6 is compressed and provides sufficient force to open the switch.

When a short circuit current flows, the current in the coil 5 breaks. The armature 6 under the action of the efforts of the breaking spring 8 rotates around the axis 7 counterclockwise, and the magnetic core 4 under the action of the efforts of the switching spring 9 - clockwise. Contacts 10 and 11 immediately open (figure 1).

Due to the indicated design differences, a circuit breaker with a sufficiently short tripping time has been created, which ensures reliable and safe operation in operation.

Claims (1)

Automatic high-speed switch, comprising a switching electromagnet, consisting of a magnetic circuit, a coil and an armature, holding an electromagnet, consisting of a magnetic circuit, a coil and an armature, breaking and turning on a spring, a movable and fixed contact, characterized in that the armature of the switching electromagnet and the magnet circuit of the holding electromagnet are rigidly connected interconnected and mounted on an axis with the possibility of rotation around it, and on the same axis the anchor of the holding electron is rotatably fixed Nita, the outer edges of the movable contact.