DE1639417C - Electromagnetic multi-contact relay - Google Patents

Description

I 639417

The invention relates to an electromagnetic one Melir contact relay with a bobbin designed as a protective tube for the contacts and the armature imd at least one made of insulating material Contact carrier. S.

The known multi-contact relays, animal contacts are located in a protective tube, usually have KoiUaktzuiigen made of ferromagnetic material, when a coil is excited via an air gap or Konlaktabslaiid close. Inevitable touch satchel in the painterly look, different Clratbilduiig or deburring on the Konlaktzungen and unequal air gap cause that practical every contact with another achievement closes or olfnct. This so-called spreading is lost increase in size through a natural compression of the magnetic field lines over the first closed contact with corresponding thinning of the magnetic field lines over the still olfen contacts. Further disadvantages of this are known ten mechanical reed relays still consist in that

1. every single contact tongue because of the required Suspension must have a relatively smaller cross-section than this to lead the Magnetlusses and would be useful for generating suitable contact forces;

2. The relays must be built larger than is desirable to be reasonably usable To obtain cross-sections of the contact tongues;

3. The permissible switching capacity of the contacts must be kept relatively small, because the ferroinagnetic contact tongues can only be provided with a very thin layer of noble metal that does not resist an arc long enough

4. The efficiency is unfavorable because they conduct the electric current and ilen magnetic flux For reasons of isolation, contact blades cannot have a closed magnetic circuit. n>

There are also electrical sonic devices known which armature, pole shoes and contacts within have arranged a two-part bobbin and thus part of the above-mentioned disadvantages remove. At this switching device ^! however, the contact springs with the yokes are electrical connected, and the armature is also energized at least in the tightened state. Besides that These Schaltvoi directions have holes out at right angles foiinten lamellas, which, also as contact 5 " Stirrups are designed, current and lluss-carrying are and thus cannot be electrically isolated from one another.

Wide disadvantages of this known Sehaltvorrichluiiivii consist in the fact that the air gap does not depend on the tolerances of the painterial thicknesses, but also on the tolerances of the deformation of the holes or 1..UiR-IIcU and the two Spulctiköipcrliälflcii, and that, moreover, neither before nor After assembly, a reliable control of the contact point and the anchor return force is possible with a great deal of effort.

The invention eliminates these disadvantages by that see the contact carrier elwa in Spiilcninilte in I .äiu'sik '! Llung extends, at the same time as a carrier for the Pnlschiihc serves and has recesses, dun. h the Iletätiguiigsstiicke hinduichiMcifeii attached to the anchor.

Further details of the invention »1ml in
FIg, L to 5 shown.

FIG. 1 is a symmetrical envelope of section A-Ii of FIG. 2;

Figure 2 is a section of Pig centerline CD. I;

FI g. 3 is a section HF of FIG. 4, which lies in the axis of rotation X of the armature 7;

F i g. 4 is a section Ci-H of FIGS. 5, and

F i g. 5 is a section KL of FIG. 4th

The exemplary embodiment according to FIGS. 1 and 2 shows a contact carrier 3 made of insulation material on which both I'olsehuhc 14, 15 and the movable ones Contacts 10, 11 and the stationary contacts 22, 23 are fastened insulated from one another. The attachment canoe in a known manner by riveting or lapping with a corresponding recess in the Contact carrier 3 or by insulating plastic rivets or, similar to FIG. 5, by embedding. An armature retaining spring 18 supports the armature 6 on the pole piece 15. On the armature 6 is made of Isolalionsmaterial existing UeläligungsstückB preferably injected,! 'impulse of the oil actuator 8 protrude through the holes 24 of the contact carrier 3 provided for this purpose and actuate when the Coil 25 the contact spring »10, 11. The contact spring 10 lies with the normally closed contact force Preload on the stationary contact 22. The pair of contacts ″ 11, 23 is designed as a working contact. A cover plate 26 made of insulation material, which the contact carrier 3 either by gluing or Unisprit / .ung encloses is veibuiiden with the coil body. The type of connection depends on the Work tools of the coil body, the cover plate and the contact carrier. Hei use of ceramic Materials could be the Uerühruiigslläclieii metallized and then soldered, plastics are glued. The one made of ferromagnetic !!! Factory lolf The existing cap 20 is spot-welded, soldered or riveted to the two PoI shoes 14, 15 and thus closes the magnetic circle when the armature is attracted.

When Ausfülltungsbeispiel according ilen Fig.. \, 4 and 5, the contact carrier 4, 5 and the ends of the Spulenköipers 2 with matching conical! • 'laugh 27, 28, 2 ^l), 30 provided.

Both the movable contact springs 12, 13 and the stationary contact parts I ¹ ), 35 are angled so that the ends on one side of the relay are designed as contact connections 31, 32 and also with regard to the coil connections i. \, 34 in space for printed Circuits lie. This exemplary embodiment also shows that working, resting, switching and follow-up contacts can be formed at the same time in a bobbin serving as a protective tube.

The Aibcitskontakt wild from your contact pair Ll, .15 daduicli formed that emerges from the position of movable contact spring 13 and the stationiiieii Contact piece 35 results in a contact distance that bridges wildly when the armature 7 is tightened.

The normally closed contact results when the two contacts 4, a are inserted into the coil body 2 in that the movable contact spring I i hits an obliquely angled surface of the stationary contact part I ¹ J, slides on it and generates the closed contact force through the resulting spring preload . With the same! 1 Ifekl can

<f

of course you too »end of the movable contact spring 12 (to be angled at an angle, The normally closed contact takes place when the armature 7 is tightened via the actuating piece 9.

A changeover contact results in an electrical one Connection of the movable contact springs 12, 13, which also for economic reasons in the printed circuit board can be made.

A follow-up contact results solely from the

is filled out.

Claims (8)

Patent claims:
I Electromagnetic multi-contact relay with Actuating piece »m Mg. L guncuji m,« v ».w For example, the distance between the movable rest contact spring 10, IZ and that associated with this spring Piinpel of the actuation piece 8, 9 smaller as the corresponding distance to the normally open contact spring II, 13 plus the contact distance, then the normally closed contact opens inevitably before the normally open contact closes, analogously it can also bring about a compulsory contact of the normally open contact before the normally closed contact oilTnct. Another advantage of the invention results from the fact that in the same way as not in one Protective tube located contacts massive contact materials can be used because the contact point does not need to conduct magnetic flux. So are the movable ones in the example Contact springs 12, 13 slotted and with contact pins 36, which can also be welded or rolled on, provided. Likewise can the stationary contact parts 19, 35 can also be provided with a noble rivet insert. For the contact security it is necessary that between the actuating piece 8, 9 and the contact springs 10, 11, 12, 13 there is a distance known as pimping air when the armature 6, 7 is not tightened. More precisely, it is necessary that the armature is stored in a defined manner so that the pull-in and drop-out values of the armature are constant even after the relay is shaken. These two conditions are met in that pegs 37 are pressed into the armature and are supported in corresponding depressions or holes 38 in the pole piece 15, 16. An armature retaining spring 18, which engages in a known manner on the surface of the pole piece 15, 16 facing away from the bearing, holds the armature in a specific position. In order to reset the armature and at the same time ensure the pimping air, part 39 of armature 7 is slightly angled at a distance <i from the armature axis of rotation, V, so that only this part 39 _{5U of} the armature can be depressed by the armature retaining spring. The cap 21 has resilient tabs 40, which, so that both the magnetic flux is for _{r) 5} Guide appropriate touch and at the same time a holder of the cap ensured in the upper pushing on the Polsclnihen 16, 17 engage one. at least one _. the contact carrier (3), thereby " draws that the contact carrier is approximately in Coil center extends in the longitudinal direction, in the same line serves as a carrier for the pole pieces and has recesses through which attached to the armature Reach through the actuating pieces. 2. Electromagnetic Melu contact relay according to claim I, characterized in that animal Armature is mounted on a pole piece. 3. Electromagnetic Melu contact relay according to claim 1 and 2, characterized in that for armature return , the armature holding spring (18) presses around armature at a distance (11) from the axis of rotation (X) into its storage position. 4. Electromagnetic Melu contact relay according to claim 1 to 3, characterized in that preferably the stationary contact part (I ¹ J) is angled obliquely, whereby the movable contact spring (12) receives a preload required for the normally closed contact force. 5. Electromagnetic Melu contact relay according to claim 1 to 4, characterized in that a cap (20, 2t) made of ferromagnetic material on the pole pieces (14, 15, 16, 17) is attached. 6. Electromagnetic multi-contact relay according to claim I to 5, characterized in that the contact and coil connections in the pitch for printed circuits on one side are executed. 7. Electromagnetic Melu contact relay according to claim 1 to 6, characterized in that the contact sequence (opening of the normally closed contact before the normally open contact closes or vice versa) is inevitably determined. 8. Electromagnetic multi-contact relay according to claim 1 to 7, characterized in that the movable contact springs (12, 13) are slotted for the purpose of double contact and with precious metal are provided. '), Electromagnetic Melu contact relay according to claim 1 to 8, characterized in that the cap (21) is provided with tabs (40) which touch the pole row (16, 17). For this purpose I sheet drawings