DE3047608C2 - Electromagnetic relay - Google Patents

Description

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The invention relates to an electromagnetic relay with a vibrating armature located inside a coil body, the free end of which in at least one Gap of the magnetic circuit protrudes, and with a switching block structurally combined with the electromagnet, the at least two arranged on both longitudinal sides of a base made of insulating material Has switching groups, the fixed contacts of which can be actuated by the oscillating armature via insulating material elements Contact springs work together, and in which all connections are embedded in the socket.

Such relays are known, cf. B. the DE-AS

23 18 812, in particular its Fig. 19.

The object of the invention is to provide a relay of the type mentioned, in which on simple Way to facilitate the separation of the oscillating armature from the yoke ends during the initial phase of the switching process is achieved.

This problem is solved by the measures specified in the characterizing part of claim 1.

Although it is known from DE-AS 10 10 641, a To attach contact actuation part on the armature and at the same time the armature in the air gap area with a a thin layer of plastic to prevent anchor sticking. The disadvantage here is that that very different material thicknesses occur on the insulating part, which make production difficult. Especially the proposed overmolding or pressing proves to be problematic, especially since the anchor covering layer of insulating material may only be a few hundredths of a millimeter thick. Such difficulties can be avoided with the measures of claim 1 in an elegant way.

According to a preferred embodiment of the invention it is provided that each vector group from there is a working and a normally closed contact, the ends of which are in alignment with each other, while their middle ones, embedded in a base Sections are mutually offset.

These measures, which are essentially known from DE-OS 23 56 651, lead in connection with claim 1 to the advantage of the symmetrical structure. In this way, the same force-travel ratios can be achieved in both directions of actuation.

Further useful and advantageous developments of the subject matter of the invention are in the subordinate Claims set out

An exemplary embodiment is explained in more detail below with reference to the figures. It shows

F i g. 1 the relay according to the invention for 2-pole switching function in a perspective and exploded view Depiction;

2A to 2D show a plan view, a side view, a longitudinal section along the line VC-VC and a cross section along the line VD-VD in FIG. 2A of the switching block for the relay according to FIG. 1;

F i g. 3A and 3B the perspective representations of the actuation card controlled by the oscillating armature in an alternative embodiment and theirs Assignment to the magnet system;

Fig. 4 the individual components of the relay for 4-pole Switching function.

The electromagnetic relay having a two-pole embodiment according to FIGS. 1 and 2 comprises a switching block with two switching groups A and S, which each have two fixed contact pieces 1 and 2 on fixed contact terminals 3 and 4 and are aligned with one another in an opposite arrangement. Between the two fixed contact pieces 1 and 2 of each switching group A and B, the free end of a movable, resilient contactor 6, on which two movable contact pieces 5 are attached on opposite sides so that they are directly opposite the fixed contact pieces 1 and 2, surrounds. The contactor 6 is attached to a connecting terminal 7. The two switching groups A and ßsind disposed at the top of a group consisting of an insulating base 8 near its two longitudinal sides, on the underside of the terminal pins 3.7,4a and la of the terminals 3, 4 and 7 protrude. The fixed contact

clamp 4 of each of the two switching groups A and B have a substantially inverted Z-shape, with respect to the middle section 46 of which one leg of this Z-shape the terminal pin 4a aligned to one side at a right angle and the other leg 4c likewise forms terminal 4 aligned at a right angle in the opposite direction. On this other leg 4c there is also an extension 4 </ which is aligned at right angles to it, but which does not necessarily have to be present if instead it is used for the tavern! 4c resp. the fixed contact terminal 4 is realized an arrangement exactly opposite the fixed contact terminal 3. The two fixed contact terminals 3 and 4 of each switching group A and B are formed on a common metal strip which also has the connecting terminal 7 for the respectively associated movable contactor 6

To move the two movable contactors 6 of the two groups of shahs A and B , a block-shaped electromagnet 9 is provided. _r 5er experiences an arrangement on the upper side of the base 8. The electromagnet 9 comprises a bobbin 11 around which a two-part coil 12, 12a is wound. On the underside of this coil 12, 12a two parallel yokes 13 are arranged, which are held in contact at their central area with the two pole faces of a permanent magnet M , so that through one of the ends 14 of the two yokes 13 that are spaced apart from one another a gap is formed at one axial end of the coil 12, 12a, in which the one end of a vibrating armature 15 arranged within the coil body 11 borders The end protruding into the gap is attracted either by one or the other end 14 of the two yokes 13.

The spool body 11 is at both of its axial ends each provided with a flange 16 or 16a, of which the flange 16 has a greater thickness than the flange 16a and the support of the oscillating armature 15 are used. In the two side parts of the flange 16 are two essentially U-shaped connection terminals 17 for the coil wires of the coils 12 and 12a each embedded on their web part so that their legs 17a and 176 over the side parts of the flange 16 protrude. The coil wires of the two coils 12 and 12a are attached to the legs 17a, while the opposite these legs 17a longer legs 176 are plugged onto connection terminals 18, which like the terminals 3, 4 and 7 are embedded in the base 8 so that they are over the top of the base protrude above and their corresponding connecting pins 18a on the underside of the base 8 parallel to the Terminal pins 3a, 4a and 7a of the terminals 3, 4 and 7 are aligned. At the connection terminals J8 otherwise each have a notch 19 formed. 30 that the longer legs 176 of the clamps 17 secure Find out attachment to the terminals 18 when the electromagnet 9 is attached to the switching block will.

A substantially U-shaped card? G is plugged onto the oscillating armature 15 in such a way that its legs come to rest against the movable contactor 6 when the electromagnet 9 is plugged onto the switching block. This ensures that with the alternating movement of the oscillating armature 15 between the two ends of the yokes 13, the movable contact pieces 5 of the contactors 6 of the two switching groups A and B are alternately brought into contact with the contact pieces 1 and 2 of the fixed contact terminals 3 and 4 so to get a change between the normally closed and the normally open contacts.

To attach the electromagnet 9 to the switching block, its base 8 is along its longitudinal axis provided with two raised material reinforcements 21 and 22, in their opposite End faces vertically aligned recesses 23 and 24 are formed. The one material reinforcement 22 is also provided with a protrusion 25 protruding from it on the associated broad side of the base 8. The two material reinforcements 21 and 22 are in one with their facing end faces arranged such mutual spacing that between them the flanges 16 and 16a of the bobbin 11 be able to enclose and at the same time «»? in the recesses 23 and 24 projections 16c and 16c / formed on the flanges are guided. On the other hand, points the projection 25 has a width that through it the two yokes 13 on the through their two ends 14 created gap can experience a guide and thus the gap also to a precise positioning of the electromagnet 9 contributes to the base 8 of the switching block. It is thus also guaranteed that the longer legs 176 of the terminals 17 of the two coils 12 and 12a a precise positioning learn when plugging onto the terminals 18, so that after the assembly of the electromagnet 9 and the switching block only a cover 27 slipped over this common arrangement to complete the assembly of the relay.

In the modified embodiment of the electromagnet according to FIG. 3B, a card 20 is suitable F i g. 3A used, in which projections 20a are formed on one side, which in the between the Ends 14 of the two yokes 13 protrude formed gap and one opposite to that protruding in this gap End of the oscillating armature 15 have a slightly larger width, so that the oscillating armature ends 14 of the two Cannot directly touch yokes 13 and rather maintains a correspondingly small distance from them, so as to facilitate a separation from the yoke ends during the initial phase of the circuit.

In FIG. 4 shows a four-pole embodiment of the relay in which, in comparison to the two-pole switching relay, two further switching groups C and D are implemented, which are arranged at the corners of the switch 8 of the switching block facing away from the switching groups A and B, which in this embodiment is essentially twice as long as the switch block of the two-pole switching relay. The connection terminals 3, 4 and 7 of the two additional switching groups C and D are arranged symmetrically to those of the switching groups A and B , the plane of symmetry being defined by the connection terminals 18. A further projection 25 is formed on the base 8, which is provided on its broad side facing away from the one projection 25 and likewise encompasses a gap which is formed between the other ends of the two yokes 13. Another difference is that here no material reinforcement corresponding to the raised material reinforcement 21 is provided for the base 8 and instead only the

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15th

20th

25th

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raised material reinforcement 22 corresponding material reinforcements are provided on the two projections 25, which also have a recess 24, so as to serve the purposes of guiding the projections 16d on the thinner flanges 16a of the bobbin 1 1 are formed. The bobbin 11 of the electromagnet has an im Compared to that of the two-pole switching relay * 3, it is about twice as long and also has two split bobbins 12, 12a in a symmetrical arrangement to the thicker flange 16, which is shown in the plane of symmetry that corresponds to the terminals 18 is arranged. Also the two yokes

13 are about twice as long as the oscillating armature 15, which is also about twice as long can enclose its two ends in the column between the ends assigned to one another in pairs

14 of the two yokes IJ are formed. The oscillating armature 15 is arranged by projections of the thicker flange 16 arranged in the plane of symmetry so that it can perform a rocking movement when current passes through the coils and, with the help of the cards 20, the movable contactors 6 of the individual switching groups A to D for a change between moves the normally open and normally closed contacts. In addition, the thicker flange 16 arranged in the plane of symmetry is also provided with terminals 17 for fastening the coil wires and has a passage opening 16e which allows the coils arranged on both sides of this thicker flange 16 to be continuously wound.

For the above-described embodiments of the electromagnetic relay according to the invention is therefore of particular importance that the Festkontaktklernrnen respectively in each Schs'tgnjppc. The contact pieces attached to these are precisely aligned with one another with a simultaneously offset arrangement of their connecting pins, which makes it possible to specify an equal distance from the relevant terminal to which the movable contactor is attached for the two contact pieces arranged on the movable contactor. In this way, however, the same contact forces are achieved for the normally open and normally closed contacts of the relay, with the result that the performance characteristic of the relay is correspondingly improved. Due to the manufacturing process, it is also possible to arrange all the pins of the individual terminals exactly in alignment in the longitudinal direction of the base and to move this aligned arrangement for the individual switching groups to the outermost edge of the two long sides of the base, thus reducing the mutual distance between the two switching groups A. and B with a two-pole switching relay or the mutual distance between the switching groups C and D additionally provided for a four-pole switching relay is correspondingly large and there are no difficulties in inserting the upper mold into this enlarged space when shaping the base. Therefore, the individual material reinforcements 21, 22 including the recesses 23, 24 and the projections 25 can also be formed on the top of the base 8 without particular difficulties and thus ensure that the electromagnet on the switching block receives a firm hook, the assembly of the both blocks only requires a simple plug-in process and then an extremely compact design of the relay is obtained. On the other hand, the large space provided for the switching groups of the switching block also allows for a more compact design for the electromagnet while at the same time implementing such advantageous individual measures as the provision of a space between the two yokes, the freedom of contact with one end that can be achieved with the projections 20a of the card 20 of the oscillating armature 15 with the yoke ends 14, the formation of a projection 16 £> on the thicker flange 16 of the bobbin 11 for the purpose of arranging the yoke ends facing away from the gap at a precisely defined distance from one another, precise support for the oscillating armature through the projections 11a of the bobbin 11 and other advantageous measures which are readily apparent from the above description.

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45 Here are 4 sheets of drawings

Claims (5)

Patent claims: 1. Electromagnetic relay with a vibrating armature located inside a coil body, whose free end protrudes into at least one gap in the magnetic circuit, and with one with the Electromagnet structurally combined switching block, which consists of at least two on both long sides of one Has insulating material existing base arranged switching groups, the fixed contacts with work together by the oscillating armature via insulating material actuated contact springs, and in which all connections are embedded in the base, characterized in that the insulating component (20) arranged on the oscillating armature (15) for actuating the contact spring (6) is designed in such a way that it is through a projection (20a / the one slightly larger beard than the anchor end protruding into the gap (15) which prevents direct contact of the armature end with the yoke ends (14) (Fig. 3A). 2. Relay according to claim}, characterized in that each switching group (A. B) consists of a working and a normally closed contact whose ends carrying the contact pieces are aligned with one another, while their central sections embedded in the base (8) are mutually offset. 3. Relay according to claim 1 or 2, characterized in that the armature is mounted centrally and on forms both ends with the trussing column and that these gaps are ensured by insulating material components (20} arranged at both anchor ends (Fig. 4). 4. Relay according to one of claims 1 to 3, characterized in that the or each gap is formed by the opposite ends (14) of two parallel yokes (13) arranged in parallel and polarized by a permanent magnet (M) and that on the base ( 8) of the switching block, at least one projection (25) serving to position the one gap when the electromagnet (9) is plugged onto the switching block is formed (FIG. 1.4). 5. Relay according to claim I or 2, characterized in that on one flange (16) of the coil body (11) of the excitation coil (12, 12ajdes electromagnet (9) a projection (\ 6b) is formed, which between the with the gap facing away, opposite ends of the two yokes (13) borders (Fig. 1).