DE1940185U - RELAY ANCHOR WITH ADJUSTABLE STOP. - Google Patents

Description

Relay armature with adjustable stop

In the case of known armature arrangements for relays, not only is a considerable manufacturing outlay required, in particular for the tendon bearing, but additional components are often also required for the armature stop. In addition, to achieve a high level of resistance to shaking the relay, sufficient bearing and restoring forces must be available, which in many cases can only be generated with two separate pedals. In addition, in known arrangements, the movement of the armature often results in friction paths which result in increased wear of the relevant components and thus a shorter mechanical service life of the relay.

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( The specified disadvantages of known armature bearings are eliminated after firing in that a common Irchtfeder is used to achieve the bearing and restoring force of the armature, which is attached to a bead on both sides

f. cranked yoke and held on a wart of the anchor is, whereby to achieve a sharp-edged bearing point the /.nker made of two anchor plates, preferably connected by welding consists. In further training the innovation can

\ / nker have an inner armature plate facing the relay core and an outer armature plate bent at an angle. The inner anchor plate conveniently has the on its

^ cranked end of the yoke facing side a conical curvature. Since ¹ S is the horizontal end of the bent at an angle

LuiPcren / nkerblechs serves as an actuation thread for the contact spring set .

Its expedient further development of the innovation provides that the actuating arm of the outer armature plate independent of the / the stop of the inner anchor plate are adjustable. The anchor strike is supported in the rest position of the anchor on the yoke.

The advantages of the innovation according to the solution are not only that the bearing and armature restoring force is only from one single spring is applied, which is attached to the anchor without special fasteners, but also in the almost

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constant restoring force during armature actuation. Furthermore, the actuation arms are independently adjustable and affect neither the anchor bearing nor the anchor stop.

Further details of the innovation result from the following Description of an embodiment.

Show it:

1a, 1b and 1c, partially in section, the anchor bearing

after the innovation,

Fig. 2 is a special representation of the storage point

of the anchor with details of the effective support forces.

As can be seen in particular from FIG. In order to prevent the anchor from lifting off the end face 1 in the tightened state, a kenic embossing 4 is attached to the anchor plate 3. This is particularly vcn distributing because it "does not significantly increase the magnetic resistance. The depth of the embossing marked a depends on the maximum tolerance of Δ s.,

To put it simply, -YTe is a sharp-edged bearing point for the anchor There are two anchor plates available, namely that

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ft-.

? already mentioned anchor plate 3 and the anchor plate 5. The latter has an easily manufacturable bending radius ν _Λ and a

bearing radius r «. The armature plates 3 and 5 are connected by welding, with the plate 3 _{lying flush against radius r 2} and forming a flawless, sharp-edged bearing point. The symmetrically lying actuating arms 5a for the Kentakt spring sets, not shown, are weakened by a cross-sectional curve, | reduction in width so that subsequent bending of these arms does not damage the bearing point and also does not affect the stop of the armature.

'' Is referred to explain the Einstellnöglichkeit the armature stroke, the \ with h, is to serve T ^ c Figs., Corresponding to corresponding to the T 1a of the section CD. The setting of the

I armature stroke h takes place through the stop 3a of the armature plate 3

I To enable continuous adjustment in a simple manner

I enable, a window 8 is provided in which a dashed

I dotted * indicated auxiliary tool 9 is immersed. By bending

I of the stop 3a can be the desired armature stroke h within the

I required limits to be changed. The attack j5ä. ^ eI is found in the middle of the anchor consisting of the anchor plates 3 and I, so that when the anchor falls into the I Piuhelage it is intercepted centrally and in this way

I - there is no injury to the torso. The lateral layer

'' the anchor is fixed through the recess 1a of the yoke 1,

I where ereite b (Fig.1a) is available for the anchor.

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The two-sided beads 1b in the yoke 1 and the wart 3b in the anchor plate 3 are used to accommodate the armature spring 13s only 'is shown in FIG.

The armature spring 13 is held without special fastening means. The bearing arrangement is shown in FIG. 2 in a somewhat enlarged representation compared to FIGS. 1a to 1c shown. The armature spring 13 made of spring wire is supported on the beads 1b and the protrusion 3b and is generated in the process the horizontal and vertical bearing forces marked with H and V. The resulting force R is multiplied with the lever arm χ the armature restoring torque. The increase in force the armature spring 13 during the movement of the armature is extremely small, since the reduction in size of the lever arm 'χ and compensate for the increase in the resulting force R. This fact is especially important for relays with high response sensitivity really important.

It has already been mentioned that the armature spring 13 applies both the bearing force and the restoring force. Besides that this armature spring has the advantage that no additional fasteners are necessary for their mounting and one simple Kentage can be carried out by engaging the spring on the yoke and armature. Since the support points of the armature spring 13

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are located directly at Erehpunkt 1c of the anchor occurs

there is also only an extremely small friction path, which is even in

\ can be reduced to a certain extent by twisting the spring. The low-friction layer that can be achieved in this way necessarily results in only low wear and thus a relatively long mechanical service life.

7 protection claims 2 figures

Claims (7)

580 437-4.11.65 - 7 - PA 9/412/450 protection claims 1. Relay armature with adjustable stop, characterized in that that a common wire spring (13) is used to achieve the bearing and restoring force of the armature, which on two beads (1b) of the upwardly cranked yoke (1) and on a wart (5b) of the armature is supported, with the Reaching a sharp-edged bearing point from the armature two anchor plates, preferably connected by welding (3, 5) exists. 2. Relay armature according to claim 1, characterized in that the armature has an inner armature plate (3) facing the relay core (2) and an outer armature plate (5) bent at an angle. 3. Relay armature according to claim 2, characterized in that the inner armature plate (3) at its the cranked end of the yoke (1) facing side a conical ugung (4) owns. 4. Relay armature according to Ansiruch 2, characterized in that the horizontally extending end of the bent at an angle outer armature plate (5) serves as an actuating thread (5a) for the contact spring set. -8th- - 8 ■ PA 9/412/4 5 O 5. Relay armature according to claim 4, characterized in that the actuating arm (5a) by reducing the cross section is adjustable in width independently of the anchor stop. 6. Relay armature according to Claim 1 or the following, characterized in that that for the lateral fixation of the relay armature a recess (la) is provided in the middle of the yoke is. 7. Relay armature according to claim 4, characterized in that the outer armature plate (5) has two actuating arms and the inner armature plate (3) has a stop (3a) which, in the rest position of the armature, is on the yoke (1) supports.