SU1171860A1 - Electromagnetic mechanism with forced closing - Google Patents

Abstract

FORCED ON ELECTROMAGNETIC MECHANISM containing a winding made of I n identical sections, terminals for connecting a power source and switching elements, the beginning of each section, except the first, connected to one of the terminals for connecting a power source through a switching element, the beginning of the first section connected to to connect the power source, the end of each section, except the last one, is connected via a switching element to the other terminals for connecting the power source to The end of the last section is connected to a terminal for connecting a power source directly, characterized in that, in order to increase speed, reliability and expand the operational capabilities of the electromagnetic mechanism, the winding contains an odd number of sections, the winding sections being directly connected in series so that each subsequent section is counter-connected in relation to the previous section. & 00 05

Description

applies to electromagnets; electric drives can be used;

Invention [of technology and the creation or alternating reception of electromagnetic mechanisms, electromagnets of electromagnetic brake clutches, contactors, etc.

The purpose of the invention is improving speed, reliability and expanding the operational capabilities of the electromagnetic mechanism.

constantly different devices, for example,

In FIG. 1 shows a diagram of an electromagnetic mechanism with forced excitation; in FIG. 2 - the same as where the forcing elements are made on the 15 opening contact, shunted by the capacitor.

Its winding consists of three identical sections 1-3 (the number of the latter can only be odd), connected “alternately opposite each other. The winding of the electromagnetic mechanism is connected to the power source 4 by a key 5. Sections 1 and 2 on one side of the winding and sections 2 and 3 on the other are shunted by forcing elements 6 and 7. 25

The electromagnetic mechanism operates as follows.

In the starting period, the boosting elements 6 and 7 are simultaneously brought into a conductive state. Sections 1-3 of the winding 30 by forcing elements 6 and 7 are connected in parallel and in concert with each other. After the magnetic field reaches the required value or after exposure to the opening contacts of its own core (Fig. 2), the boosting elements are transferred to a non-conducting state. The starting mode ends, and the working current flows through the sections of the winding. The magnetizing force of section 2 is directed against the magnetizing forces of sections 1 and 3. In the operating mode, the magnetizing force of one of the two extreme sections 1 or 3 is used. One of the pairs of counter-connected sections in this mode has only active resistance in addition to the resistance of one of the considered extreme sections.

The proposed device provides increased performance, since the force factor is 9 already with a three-section winding.

The electromagnetic mechanism works especially reliably and effectively when using a shunt element from a disconnecting key, in parallel with which a capacitor is connected, which is activated at the end of the stroke of the moving core of the electromagnetic mechanism. The value of the capacitance of the capacitor is chosen so that the core movement remaining after opening the contacts is passed due to its charge. When the winding is disconnected from the power source, the capacitors are discharged into counter-connected sections. In this case, the magnetic flux in the sections and in general in the winding does not occur. The latter does not prevent the return of the core of the electromagnetic mechanism to its original position.

When using an electromagnetic mechanism of low power, only capacitors can serve as forcing elements. The proposed electromagnetic mechanism can be made to work from an alternating current source and has increased speed and reliability.

Claims (1)

ELECTROMAGNETIC MECHANISM WITH FORCED TURNING ON, containing a winding made of η identical sections, terminals for connecting a power source and switching elements, with the beginning of each section except the first connected to one of the terminals for connecting a power source through a switching element, the beginning of the first section is connected with a terminal for connecting a power source, directly the end of each section, except the last, is connected through a switching element to another terminal for connecting a power source, the end of the last section is connected to the output for connecting the power source directly, characterized in that, in order to improve performance, reliability and expand the operational capabilities of the electromagnetic mechanism, the winding contains an odd number of sections, and the winding sections are directly connected in series so that each subsequent section is connected in opposite in relation to the previous section.