SU519783A1 - Relay to switch with magnetic interlock - Google Patents

Description

nickname and operation of reed switches after passing control currents through one group of control excitation windings and through another control group; in fig. 5 is a side view of the relay shown in FIG. four.

The relay contains a core I of a semi-rigid magnetic material (for example, an alloy of 35KX12 or remendyur). The core can be made in the form of a rod with a round, rectangular nln other section, or in the form of a plate.

Reed switches 2 and 3 (or, respectively, groups of reed switches) are attached to core 1 by means of magnetic flow steel (for example, Armco) flux pipes 4 and 5, with the mounting points of the reed switches separated from each other and alternating so that the core 1 is conventionally divided into three sections 6 , 7 and 8, on which control windings are applied, for example 9 and 10.

In order to provide the alternating processing functions of both groups of reed switches (switching) and magnetic blocking, it is necessary that a magnetic flux is created in the middle section 7 of the core, which ensures the operation of both groups of reed switches 2 and 3, therefore the attachment points of the reed switches to core 1 must alternate, for example, 4a, ba, 46, 56.,

Each of the control windings 9 and 10, as shown in FIG. 2, can have two oppositely wound parts 9a and 96, 10a and 106, with the winding 9a winding on one of the outermost sections of the core, for example 6, the windings 96 and 106 both on the middle section 7, and the winding 10a-on the extreme section 8 cores.

In order to provide the switching function, it is necessary that the windings 9a and 10a, wound by the outer sections 6 and 8 of the core 1, create magnetic fluxes directed towards each other in them, i.e. the windings 9a and 10a can be wound counter to each other and are controlled by pulses of the same direction, or cannot be wound according to, but then must be controlled by pulses of different directions.

Similarly, windings 9 and 10 need not be two-piece. It is possible to wind three windings instead of these two windings, one for each section of the core.

The relay works as follows.

When a control current is applied, for example, to the winding 9 (Fig. 3), the flows in sections 8 and 7 successively in one direction are added, as a result of which the reed switches 3 are closed. The reed switches 2 are open, as there are attached identical magnetic poles. If we apply current to the winding 10 (Fig. 4), then the closure of the contacts 2 and the opening of the contacts 3 similarly occurs.

Thus, the extreme sections of the core are not remagnetized during operation, they are always magnetized in opposite directions and their functions are similar to permanent magnets. The windings 9a and 10a in the extreme sections serve to prevent a partial change in the magnetic state of the extreme section during the remagnetization of the middle part. The number of turns in these windings in connection with this is small (approximately 1/3 of the number of turns of winding 96 and 106.

The proposed relay has closing and opening contacts with a very simple magnetic circuit without permanent magnets and with only one core of the simplest form (rectangular or any other cross section). It allows you to increase speed, reduce power consumption and consumption of copper winding, because only a part of the core (one of the three sections) and the inductance of the relay is small in the working cycle. The reliability of the relay increases, since when the contacts open, the poles of the same name are created at the ends of the springs and the springs are pushed away from each other and their probability of sticking decreases. In addition, there are no second (spurious) trigger points when the operating current is significantly exceeded due to the fact that the core is re-magnetized along a rectangular hysteresis loop with saturation.

Claims (1)

Invention Formula A relay with magnetic interlock, containing two groups of reed switches for closure, flow lines, a core of semi-rigid magnetic material and a control winding wound on the core, characterized in that, in order to simplify the design of the relay, the flow lines of each group of reed switches are connected to the core so that divide it into three areas on which the windings are applied, and the windings applied to the outer sections are included opposite. Sa X