DE1720895U - ELECTROMAGNETIC RELAY. - Google Patents

Description

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dwell. I Electromagnetic relay.

STAHDARB EIEKTRIZITATS-GcßSELLSCHAFT AG 1.12.54. st sssi. (T.6; Z.2)

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MG / Reg. 1791 GH
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"Electromagnetic relay ¹ »

t in the? Telecommunications, it is known _t for directly or indi-ίί rect operation of the contact springs form of an electromagnetic relay Ί urch the armature this "as an angular armature and to store them at an edge of the yoke end. This cutting edge is produced by upsetting and it must also be processed * In addition, Special fastening means are required which press the armature against the cutting edge and hold it in place.Despite some modifications, this bearing and the fastening means always cause relatively high friction and are expensive to manufacture.

Relays with an E-shaped core-yoke cross-section are also known, whose flat armature is held in place by a double spring. This «double spring is with the contact spring set on the The yoke is attached and lies undulating on the top of the two Jjoehsohenkel so that the axis of rotation of the armature is also on the Surface of the yoke is arranged. As the component of the restoring force of the contact springs is directed approximately "opposite to the tightening component of the armature, the double spring holding the armature becomes only slightly stressed on pressure. In order to ensure that the anchor works properly, every deviation is through to limit this pressure to a minimum level, so that frictional forces can hardly occur. Such relays therefore have an additional counter-position for the armature. Such an anchor bearing Although it is easier to manufacture compared to armature bearings for relays of the former type, it can be used for the latter associated with difficulties.

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In the case of the relays, the yoke of which is arranged above the solenoid and whose angle armature points to the rear of the relay is unnecessary Although a storage by leaf springs, since the resulting component of Ankeranziug and restoring force of the springs against the armature the edge of the yoke presses, so that he only during his Waste through the 'additional fasteners in its location must be kept. Such "relays also have the aforementioned disadvantages because of the relatively large overall height There is a sufficiently large distance between the surface of the yoke and the relay spring set for the stroke of the actuating part of the armature have to be.

{ It has therefore already been proposed to design such relays in such a way that the forward-facing actuating part of the WinkeXankers grasps the contact springs at their front end. In this case, in contrast to the relays of the first-mentioned type, the component of the restoring force is directed upwards, so that the resulting component also runs obliquely upwards. In the case of the relays whose armature is arranged on the top of the yoke, a special counter-position must be created in this case to prevent the armature from deviating in the direction of the resulting component.

The innovation relates to electromagnetic relays of the latter Kind and aims to create a simple and low-friction storage while avoiding the disadvantages mentioned. You achieved this is due to the fact that the angle armature is mainly subjected to tensile stress in one Holder is mounted such that its axis of rotation is arranged below the yoke.

According to a further development of the innovation, the holder is preferred designed as a double, noisy leaf spring with the same Fastening means for the support body of the fixed contact springs is attached to the yoke and can be moved in its longitudinal direction to 'compensate for' tolerances and different thicknesses of the partition,

^; The firing is illustrated below using an exemplary embodiment. Figures 1 and 2 explained in more detail:

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1 shows the side view of the relay according to the innovation tightened anchor.

Fig.2 shows the individual parts of the magnetic circuit of the relay according to Fig. 1.

The magnetic circuit of the relay "consists of core 11 and yoke 1 and the armature 2 arranged perpendicular to the core axis. Core 11 and yoke 1 are made from one piece. The free end of yoke 1 protrudes beyond the front end of core 11. On the The coil body 10 is pushed on to the core 11. A leaf spring 3 is used to support the armature 2, and this leaf spring 3 is mainly subjected to tension when the relay is working Contacts attached to the underside of the yoke 1, Dex forward-facing actuating part 5 of the armature 2 is mounted on the front end of the leaf spring 3 and in turn carries the. _{Armature 2 r} arranged perpendicular to the core axis The armature stroke is deflected by 90 ° by the actuating part 5 and transferred to the actuating web 6 for "the movable wire springs, so that" the wire spring contacts 26 are opened and closed. The spring set 7 is guided at the fastening point in a known manner, not shown, by dowel pins and fastened together with the return spring 8 by a retaining clip 9 on the yoke 1.

When the anchor 2 is working, the front end of the leaf spring 3 becomes the resulting component of anchor pull and upward RucksteTI force 'the return spring 8 against the bottom of the yoke 1 pressed, which thus acts as a counter-position. Since the leaf spring 3 is mainly subjected to tension and hardly any rotation, With such a bearing, there are almost no frictional forces.

In the figure 2 only the individual parts of the Magjietkreis are shown, "while the contact spring set for the sake of clarity is not shown ..

The KexTi "11 and the yoke 1 d.es magnetic circuit consist of one Stüßk and are manufactured in a pre-casting process. Through this Subsequent processing of this part is not necessary. The material des-Kern-Jooh- ^ tackes contains alloy additives such as

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for example silicon, which reduce the width of the magnetization loop and thus the scatter in the magnetic Keep the properties of this material within narrow limits. The finished coil body 10 is pushed onto the core 11, in unconscious disgusting condition, shown in the figure. At the A pole face 12 can be pressed on the end face of the core 11 to improve the tensile force characteristic of the magnetic circuit. On the rear half of the yoke has 1 tier bores 13 and two Lateral recesses 14 »The holes 13 take not shown in detail Pins for guiding the spring set (7 in Fig, 1) while the two recesses 14 serve to guide the retaining clip (9 in Fig. 1) - the actuating part 5 has two bent lugs 15

* With these lugs 15, the actuating part 5 is on the two Legs 16 of the leaf spring 3 attached. The anchor plate 2 ″ is attached to the actuating part 5 by means of a screw connection (27 in FIG. 1). The leaf spring 3 and the actuating part 5 and "armature 2 connected to it is attached to the yoke 1, together with the one shown in" FIG Spring guide 4, screwed on by means of a screw (24 in FIG. 1) by means of the threaded hole 17 of the yoke 1. As for this fastening only one screw "(24 in Fig.1) is used, two passages 28 are" attached to the yoke 1, which provide an exact spring guide cause. The leaf spring 3 attached to the yoke 1 has two elongated holes 18, 'through which the passages 28 of the yoke 1 reach. 'This makes it possible to use any partition plate thickness and to compensate for any tolerances that may arise.

m shift or rotation to avoid DER leaf spring 3 and thus a non-parallel contact of armature 2 to the core 11 in the transverse direction of the relay, the leaf spring 3 is guided by the side walls of the guides on both side edges. The tab 19 which projects forward on the actuating part 5 lies opposite the nose which is attached to the spring guide and serves as a stop. The actuating web (6 in FIG. 1) can be easily adjusted by bending the tab 19. The two lateral, angled tabs 20 have incisions which serve to accommodate the actuating web (6 in FIG. 1). The armature 2 is attached to the actuating part 5 with screws (27 in FIG. 1) in such a way that, in the tightened state, the upper straight side rests against the yoke 1 with a small air gap, whereby a good transition of the magnetic flux is achieved.

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The "two holes 25 made in the armature 2 each take one separating pin not shown in detail. On the back of the yoke 1 two threads 21 are attached, which are used for fastening of the relay.

5 protection claims 2 sheets of drawings, 2 figs.

Claims (1)

MG / Reg. 1791-6 - tbSSSU ειλα ^ «ω *. 1.12.54. St 5881. (T. 6; Z.J S oh.utzan.sprEE.che 1. Electromagnetic relay with a perpendicular to the coil core arranged angle armature, the actuating part of which is directed to the front, characterized in that the angle armature (2,5) is mounted in a holder (3), which is mainly subjected to tensile loads, in such a way that its pivoting lug is arranged below the yoke (1) is. 2. Electromagnetic relay according to claim 1, characterized in that that the holder (3) is preferably designed as a double-armed leaf spring. 3. Electromagnetic relay according to claim 1 and 2, characterized in that that the bracket (3) with the same fastening means for the support body: "(4) of the fixed contact springs is attached to the yoke (1) and is displaceable in its longitudinal direction. 4. Electromagnetic relay according to claims 1-3, characterized in that that the yoke (1) serves as a counter-support for the resulting component of the tightening force and restoring force. 5. Electromagnetic relay according to claims 1-4, characterized in that that the armature (2) is detachably connected to the actuating part (5) and that this is at the free ends of the double-armed Leaf spring (3) is mounted. 23.XL.1954