RU57052U1 - ELECTROMAGNETIC MECHANISM OF HIGH-SPEED DC CIRCUIT BREAKER - Google Patents

Abstract

The utility model relates to electrical engineering, in particular to protective switching equipment, and can be used to protect against overloads and short circuits of electrical installations and direct current lines. The electromagnetic mechanism contains a magnetic circuit, an armature, a coil, a capacitor and controlled contacts. What is new is that the coil is made of two series-connected parts, and the capacitor forms an oscillating circuit with one of the parts of the coil. The technical result is an increase in the speed of the electromagnetic mechanism during shutdown due to the redistribution of the electromotive force of self-induction between parts of the coil and its dispersion in the oscillatory circuit. 1 p. Of formula 1 of FIG. heck.

Description

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

The electromagnetic mechanisms of high-speed DC switches are known, for example, from the books “DC Electromagnets” A.V. Gordon, A.G. Slivinskaya, M .: Gosenergoizdat, 1959, p. 417; High-speed circuit breakers, A.I. Golubev, M. - L., M .: "Energy", 1964, p. 54-56, 171, 172.

As a prototype, you can consider the electromagnetic mechanism, which contains a magnetic circuit, an armature, a coil, a capacitor and controlled contacts (High-speed circuit breakers, A.I. Golubev, M. - L., M .: "Energy", 1964, p. 54- 56, 171, 172).

During the operation of this mechanism at the time of shutdown during a drop in the holding current, the current passes through the entire coil. Shutdown does not occur until the value of the holding current is less than the value of the drop-off current of the armature.

Such an electromagnetic mechanism has insufficient speed at the time of its shutdown.

The technical result that can be achieved by using the patented electromagnetic mechanism is to increase its speed during shutdown.

To achieve this, in the electromagnetic mechanism, the coil is made of two series-connected parts, while the capacitor forms an oscillating circuit with one of the parts of the coil.

The essence of the patented utility model is that dividing the coil into two components reduces the inductance of the holding current circuit, and the creation of the indicated oscillatory circuit allows the redistribution of electromagnetic energy between the parts of the coil, which ensures the absorption of this energy in the oscillatory circuit with its specified parameters.

A decrease in the inductance of the electric circuit accelerates the demagnetization of the core of the electromagnetic mechanism, the transfer of this process into an oscillating circuit additionally accelerates the demagnetization process by converting part of the energy into an electrostatic capacitor.

The utility model is illustrated by an example of execution; the figure shows a diagram of a patentable electromagnetic mechanism of a high-speed DC switch.

The electromagnetic mechanism consists of a magnetic circuit 1, armature 2, a coil made of two series-connected parts 3 and 4 with the terminals H ₁ K ₁ and H ₂ K _2, respectively, a current-limiting resistor 5, a capacitor 6, and controlled contacts 7, 8, 9. Part 4 the coil together with the capacitor 6 forms an oscillatory circuit. Current-limiting resistor 5 is designed to reduce current from the value of the inclusive to the value of the holding. Contact 7 is controlled from an external source, for example, from a current sensor. Contact 8 is controlled via interlocking contacts from an electromagnetic control station. The controlled contact 9 is mechanically connected to the armature 2. The armature 2 is connected to the contacts of the switch by means of rods (not shown in the figure).

At the moment of switching on the electromagnetic mechanism, contact 7 is in the closed position. When contact 8 is closed, the switching current flows through the circuit: plus the power source, terminal H _{1 of} part 3 of the coil, winding part 3 of the coil, terminal K ₁ , terminal H _{2 of} part 4 of the coil,

winding of coil part 4, terminal K ₂ , closed contact 8, minus the power source. When the switching current flows along the indicated circuit, the armature 2 is attracted to the magnetic circuit 1. When it contacts the magnetic circuit, the closed controlled contact 8 opens, stopping the flow of the switching current. When contact 8 is opened, a circuit is created for the holding current plus the power source to go negative along the circuit: terminal H _{1 of} part 3 of the coil, winding of part 3 of the coil, terminal K ₁ , current-limiting resistor 5, controlled contact 7, minus the power source. In addition, at the moment of opening of contact 8, the controlled contact 9 is closed mechanically connected to the armature of the magnetic circuit, which connects the capacitor 6 parallel to the winding of part 4 of the coil, creating an oscillating circuit consisting of the inductance of part 4 of the coil and capacitor 6.

At the moment of shutdown of the electromagnetic mechanism, the controlled contact 7 opens, breaking the holding current circuit. As a result of this, the demagnetization of the magnetic system (magnetic core-armature-parts 3 and 4 of the coils) occurs, the confining flux begins to decline, which creates an electromotive force (EMF) of self-induction in parts 3 and 4 of the coil. Part of the energy of the self-induction EMF, due to the mutual induction of parts 3 and 4 of the coils, passes into the oscillating circuit formed by the part of the coil 4 and the capacitor 6, where it is consumed in the form of damped oscillations with an increased frequency, which reduces the decay time of the magnetic flux in the electromagnetic system and increases the decay rate Anchors of the electromagnetic mechanism.

Claims (1)

The electromagnetic mechanism of a high-speed DC switch containing a magnetic circuit, an armature, a coil, a capacitor and controlled contacts, characterized in that the coil is made of two series-connected parts, and the capacitor forms an oscillating circuit from one of the parts of the coil.