DE449119C - Relay system with stepped armature movement - Google Patents

Description

In the main patent 447 409 is a sensitive relay system with stepped armature movement described in which the armature assigned to the relay system is during its various partial movements moved around different pivot points.

The present invention now aims at a simple and easy adjustability of a such a relay system, which is achieved according to the invention in that the armature to which one of its pivot points is adjustable.

Fig. 2 shows the relay system from the rear.

Figure 3 is a side view of the relay system in the rest position.

Fig. 4 and 5 show the relay system in its two different working positions represent.

The actual relay consists of two coils 16 and 17, which act on the cores 61 and 62 are wound. The magnetic cores are with a common screw 63 on the iron yoke piece 41, which is arranged so that it is a little shorter than the one in Cores 61 and 62 of the coils 16 and 17 which cut off one another at the same height. The armature 47 is attached to the intermediate member 65 by means of the spring 50, which with one end to the intermediate member by 3a screws 45 and 46 and at the other end is attached to the anchor. The spring 50 is preferably made of non-magnetic Building material. The intermediate member 65 to which the armature 47 is attached is attached to the yoke piece 41 held adjustable by the screws 48 and 49. The anchor 47 is involved Help the lever arms 42 and 43 on the Fe-

the 21 and 22 etc. a. In the rest position, the armature 47 is closer to the core 62 than to the core 61, since it is attached with the aid of the spring 50 to the intermediate member 65, which rises a little from the yoke piece 41 relative to the upper connecting line of the cores 61 and 62. The intermediate member 65, which carries the armature 47, is fastened to the yoke piece 41 with the screws 48 and 49 ίο which fit into elongated slots of the intermediate member 65. This design makes it possible to adjust the anchor very easily by loosening the screws 48 and 49 and moving the intermediate link. The armature movement is limited by the rear stop 66 ¹ that inhibits backward movement of the lever 42 and therefore of the armature 47th A similar rear stop is provided for the lever 43, but this is not shown in the drawing. These stops are held in place by the same screws that attach the relay springs.

To describe the mode of operation of the step relay it is assumed that dia. Coil 17 is energized. A magnetic flux then runs through the core 62 of the Coil 17, through the yoke piece 41, the intermediate member 65 and the armature 47. The armature is attracted to the core 62. A portion of the power flow is also through the core 61 of the coil 16 extend; practices however, no attractive effect on the armature 47, since the core 61 is practical is short-circuited by the yoke piece 41 and the intermediate member 65. The main flow of forces therefore runs through the yoke piece 41, and the armature 47 is tightened, until it contacts the core 62 of the coil 17; it does not reach the core 61 of the coil 16 because As already mentioned, the armature 47 is closer to the core 62 due to its attachment as the core "6i. In this position the Anchor 47 only around certain springs, namely he removes the spring 20 from her Normally closed contact without bringing them into contact with their normally open contact; in the same Way, the spring 23 is moved. The contact springs 21 and 22 are in this phase not moved due to interruption of the intermediate insulation pieces. If the Winding 16 is excited, which, since it is without influence, happened regardless of it whether the coil 17 is energized or not, the armature 47 is fully attracted and relocates its pivot point on the spring 50 from one located close to the yoke piece 41 Place after the point where it touches the core 62. It will be understood that when the coil 17 is energized, the current will flow through the coil 16 the opposite direction to that flowing in the coil 17 Must have electricity. During this second movement, the springs 20, 22 and 23 touch theirs Normally open contacts, while the spring 21 comes loose from its normally closed contact. The magnetic one Power flow runs through the core 61, the core 62 and the armature 47, a certain one Amount due to the short circuit formed by the yoke piece 41.

From the above it follows that only the contact springs 20 and 23 are moved, if the coil 17 is energized alone, but that all contact springs are turned over, when the coil 16 is energized. It goes without saying that every other setting the contact springs can be made.

The spring 50 is made from a non-magnetic building material for the following reasons. It is sometimes necessary to energize the coil 16 without energizing the Pick up bobbin 17. Under these circumstances, it is necessary that the armature 47 its fulcrum, as described, shifts ^ _Wär.iiuiii ^ the :: Eedfir:, 5o ^ a; Us magnetic material, the armature 47 would strive to stick to the yoke piece 41, since there is practically no air gap between the armature 47 and the yoke piece 41 go. and thereby the anchor would be prevented from shifting its pivot point. This difficulty arises when the spring 50 is made from a non-magnetic building material not on.

After the design and mode of operation of the step relay has been explained, the way in which a rotary selector in which the relay is used works will be described. For this purpose it is assumed that a calling "subscriber, whose connection line on the exchange runs out into the preselector C (Fig. 1), wants to make a call." The subscriber status is not shown in the drawing, but is to be thought of as an automatic telephone station of the usual type which, when the handset is lifted, bridges the two line wires 11 and 12 and contains a call device, microphone and handset. Immediately after the bridge is made over the line cores 11 and 12, a circuit for the line relay 14 of the preselector C is closed in series over the two line cores. Relay 14 responds and closes a circuit at its contact 25, which includes the two coils 16 and 17 of the switching relay 15 and the rotary magnet 18 in series; at its contact 26 it connects the test arm 28 to the circuit just mentioned at a point halfway between the

switching relay and the rotary magnet. The operation of the preselector C now depends on whether its switching arms 27 to 29 are on a free or occupied connection line. If the line is busy, there is a ground potential at the test contact connected to the test arm 28. The switching relay 15 is short-circuited and ground directly to the rotary magnet 18 via the test arm 28, so that, working as a self-interrupter, it proceeds step by step to search for a free connection line. It is assumed, however, that the switching arms of the preselector C are on a free connection line when the receiver is picked up on the calling station, namely on the one connected to the contacts 30 to 32 in the drawing. In this case, immediately after the excitation of the line relay 14, the switching relay 15 is excited, in series with the rotary magnet 18. Relay 15 places when responding via its contact 22 earth to the test contact 31 and separates the wires at its contacts 20 and 23 11 and 12 of the calling station from the winding of the relay 14 and the earth. The subscriber loop is then connected to the occupied connection line via the switching arms 27 and 29 and the contacts 30 and 32.

Immediately after a group selector has been assigned, its line relay responds via the subscriber loop and closes the circuit for its associated delay relay. When responding, this prepares the incremental circuits for the occupied group selector and applies ground to the associated release wire, which closes a holding circuit for preselector C. This circuit runs from earth on test contact 31, test arm 28, working contact 22 through the windings 16 and 17 of the switching relay 15 in series and on through the winding of the rotary magnet 18 to the battery. Of course, the delay relay 14 keeps its armature attracted until this holding circuit is established. A branch of the holding circuit goes via wire 300 to the associated test contact in the multiple field of the line selectors that have access to the connecting line of the calling station. This wildly protects the speaking line against other occupancy in a known manner.

If the subscriber line is called so that the connection originates from a line selector, then earth is connected to the test line 300, which is still connected to the battery via the normally closed contact 25, the normally closed contact 21, the winding 17 of the switching relay 15 and the rotary magnet 18. It should be remembered here that the coil 17 can only lift the contacts 22 and 23 of the relay 15 from their normally closed contacts, but does not close their working sides. The other contacts of the relay 15 are not moved at this time due to the new design of the switched on stage relay. As a result of this switching process, the line of the called station is disconnected from its idle connections in preselector C , but without being connected via the switch arms of the preselector.

It can be seen from the above that the relay construction according to the invention makes the arrangement of a mechanical switching element between the armatures of the line relay 14 and the switching relay 15 in the preselector C superfluous. Of course, the use of this relay is not restricted to rotary selectors, but can be used wherever a step relay is required.

Claims (3)

Patent claims: 1. Relay system with stepped armature movement _see chap. and several pivot points for the armature according to patent 447 409, characterized in that the air gap between armature and cores (61, 62) can be changed by adjusting one of the pivot points of armature (47). 2. Relay system according to claim 1, characterized in that the armature (47) on an adjustable to the yoke piece (41) of the relay system Intermediate member (65) is movably attached. 3. Relay system according to claim 2, characterized in that the one The pivot point of the armature (47) defining the intermediate member (65) with the armature (47) together by changing its Position to the yoke piece (41) is adjusted in the direction of the coil longitudinal axes. 1 sheet of drawings.