SU111529A1 - Contactless magnetic relay - Google Patents

Description

In automatic control systems and telemechanical devices, non-contact magnetic relays with a magnetic core carrying the "start," stop, "power," "load, and" blocking windings are widely used.

In such relays, the windings are superimposed on two magnetic cores made of ferromagnetic material with a rectangular hysteresis loop, as a result of which the relays have a lot of weight and size, a complicated circuit and require a significant consumption of active materials.

To eliminate these drawbacks, it is suggested, according to the invention. In order to carry out a magnetic core from a single core, it is not dry, all its windings are indicated, of which the interlock winding is closed on a circuit containing two half-wave rectifiers, an electric capacitor and two resistances.

This circuit serves to change the magnetic state of the core when the start-up impulse arrives, to receive the next supply impulse and continuously output impulses to the load circuit until the stop is received.

The drawing shows a diagram of the proposed relay.

On the core /, made of a material with a rectangular hysteresis loop, five windings are superimposed: 2 - power, 3 - blocking, 4 - starting, 5 - stopping and (5 - loadWinding 3 is closed on a circuit containing two half-wave rectifiers 7, electric capacitor 8 and two active resistances 9.

The proposed relay operates as follows.

In the initial magnetic state of the core, the passage of the positive half-wave of the current through the valve 10 and the winding 2 does not change the magnitude of the induction in the core and in its windings do not induce ed-c.

No. 111529-2 -

When a negative half-wave of current flows through the valve //.- (impulse "start), the magnetic state of the core changes and a negative emf appears in its windings. However, these e-ds. cannot create currents in windings 3 and 6, since their circuits are closed by valves 7 and 12. The next positive supply pulse flowing through valve 10 and winding 2. will cause a new change in the magnetic state of the core and on all the windings in TC .ds

E. d. S-, induced in winding 6, passage through valve 12, creates a current pulse in load 13 (the load may be a light bulb, a winding of another relay, etc.), and the emf induced in the winding 3, charges capacitor 8,

Subsequently, at a negative half-cycle of the supply current (when no current flows through the winding 2), the capacitor 8 through the resistance 9 discharges at the center of the winding 5, as a result of which the magnetic state of the core changes and is prepared to receive the next positive half-wave of the supply current. At the next half-wave of the supply current, a current pulse will again appear in the load 13 and a capacitor 8 will be charged.

Thus, after the arrival of a pulse, “the start-up of the relay gives out to the load all the time the current pulses in time with the positive half-waves of the supply current.

To stop the output pulses from being output to the winding 5, a pulse is "stopped" from an unauthorized source at a time when current does not flow through the winding 2. This pulse creates a flow in the core opposite to the flow created by the discharge of the capacitor 8 and the starting pulse.

The magnetizing force of the winding 5 is chosen such that it is greater than the sum of the magnetizing forces of the windings 2 n 3. Therefore, at the next positive half-wave of the supply current, the relay will not work, i.e. will no longer issue pulses to the load.

Subject invention

Claims (2)

1. Contactless magnetic relay with magnetic core, carrying the "start," stop, "power, load and" lock windings, which is so that, in order to reduce the weight of active materials and reduce the size of the device, the magnetic core is formed from one core carrying all of these windings, of which the interlock winding is closed to a loop containing two half-wave rectifiers, an electric capacitor and two active resistances, and which serves to change the magnetic state of the core when the start-up pulse arrives Ensuring the reception of the next "feed pulse and the continuous output of pulses to the load circuit until the pulse is received" stop. 2. In the relay of claim 1, the use of an electric capacitor connected to the winding circuit “start or stop” to delay the resulting starting or stopping pulses for the duration of the current flow in the winding “power supply. 12 13 9 FV