DE3823829C2 - relay - Google Patents

Description

The invention relates to a relay with a Core, a yoke and a coil, as well as an anchor having magnet system and one in one Contact carrier body held contact system, from the Contacts at least one is movable by means of the armature, and which relay the magnet system and that Contact system each as an independent, with each other connectable units are formed.

Such a relay is known from DE 27 52 795 C2. The performance described in this document Small relay has one consisting of coil, yoke and armature Magnet system, which is arranged in a housing, which also houses the contact system. A disadvantage of the known relay is that the magnet system and the contact system only cumbersome and therefore from a manufacturing point of view, can be assembled in a complex manner can.

From DE 80 01 434 U1 is a relay with a Magnet system and one connected to it Contact system known, the connection of the Magnet system with the contact system via holding arms of the Contact system takes place. These side arms overlap the free leg of a yoke Relays on each side. So that becomes a flange Excitation coil of the relay on both sides of the  Support bracket supported so that lateral canting the excitation coil are excluded, thereby a vibration-proof attachment is achieved.

DE 35 06 345 C1 is an electromagnetic relay known, the one designed as a bobbin Has basic body, one between two flanges Winding carries. The coil body is velvet for insulation from the yoke Coil and core covered with an insulating cap. In continuation of the coil flange is also molded a contact pocket in the Contact elements are anchored.

To avoid these disadvantages, it is therefore the task of Invention a relay of the type mentioned above to train that a simple and Composable relay is formed, in which especially the exchange of the magnet system quickly and can be done easily.

According to the invention this is achieved in that the Magnet system is held in a coil housing that with the contact carrier body directly, preferably by means of a Snap lock connection is coupled.

The measures according to the invention in particular advantageously formed a relay in which the magnet system and the contact system are particularly light can be exchanged. This results in  advantageously a particularly simple structure of the Relay according to the invention, in particular a Snap snap connection the easy exchange of Contact sets guaranteed.

According to a further feature of the invention can be provided be that the coil housing of the magnet system with a Contact carrier body of the contact system rotatably connected is.

This not only enables good insulation between the magnet system and the contact set even with one very compact design, but also a very simple one Manufacture of the appropriate coupling between the Magnet system and the contact system that simply z. B. by appropriate springy approaches on one of the most Plastic-made components and corresponding Grid elevations can be formed, the one Snap snap connection result.

In this context, the invention can be further developed be provided that the snap catch connection between the coil housing and the contact carrier body by on the Coil housing arranged projections and from Protruding resilient arms are formed, the coupled with the contact carrier body Bobbin case from the protrusions of the latter  are engaged, thereby also fixing in the axial Direction is given.

In this way, a very safe and the location of the individual components in every direction receive.

Another thing can be with a relay in which the armature by means of an anchor spring pressed against a bearing edge of the yoke is also provided that the armature spring by means of a Snap catch connection is held in the coil housing.  

This enables a problem-free arrangement of the armature spring and thus a corresponding determination of the anchor relative to the bobbin case.

According to a further feature of the invention can be provided be that in the coil housing guides for receiving the Magnet system are arranged, which also stops and or or have slots which are provided with projections of the magnet system, especially the yoke interact and the location of the magnet systems in the axial direction of the coil housing.

This creates a precisely defined position of the magnet system, in guaranteed the bobbin case.

In the case of a relay with an L-shaped armature, a very simple coupling with the contact system be provided that on one leg of the armature with a a run perpendicular to the direction of movement of this leg the slot provided coupling part is arranged in whose slot is a contact spring on the contact carrier body-coupled coil housing, preferably with play, intervenes.

The invention will now be explained in more detail with reference to the drawing, which is an exploded view of a relay according to the invention shows.

The core 1 of the magnet system passes through the coil body 3 with the coil 3 a and is connected to the yoke 2, preferably by riveting; the armature 6 is mounted in the assembled state on the bearing edge 2 a of the yoke 2 . This edge has a rounded shape and forms part of an essentially exact cylinder jacket. This is achieved by a stamping of the yoke from a corresponding sheet metal by the application of an embossment 2 b in the area close to the edge, when it is attached, a corresponding shape is used to avoid the formation of a pomade of the end face. This results in a very exact mounting of the armature 6 and thus only a slight friction of the same on the bearing edge 2 a.

On the yoke 2 , an insulating cap 4 is attached, which represents a third insulating layer between the coil 3 a and the contacts 10 a, 11 a and 13 a, or their carrier. The two other insulating layers are formed by the coil body 3 , or its flange and the coil housing 5 , which has a closed bottom and into which the magnet system together with the insulating cap is inserted. Due to the three-layer structure of the insulation, it is possible to reduce its overall thickness, which is particularly advantageous for small circuit board relays.

The coil housing 5 a guide profile 5 is arranged d and 5 a slits serve their limiting as a stop for the c Before cracks 2 of the yoke. 2

The arranged at the insertion end of the coil housing 5 recesses are opposite to different projections of the end face of the coil body 3 and for receiving the connection pins 3 b for the coil 3 a and their diversions.

Protrusions 5 c and 5 e serve to receive and hold the armature spring 8 , which has two symmetrical, connected over the web 8 a interconnected support tab 8 b, which are provided with Rastausneh 8 d d. This locking recesses 8 d cooperate with on the inside of the projection 5 c arranged locking lugs 5 f, which are sawtooth-shaped and in the insertion direction of the armature spring 8 in the gap between the projections 5 c and 5 e remaining sloping rise. Since it comes through when inserting the armature spring 8 to a latching of the locking lugs of the coil housing in the Rastausneh lines 8 d of the armature spring 8th The armature spring is thus securely held in the coil housing.

The middle tab of the armature spring 8 serves as a positioning spring 8 c and engages in an indentation 6 f of the armature 6 , which has an embossing bulge 8 c, against which the positioning spring 8 c is supported. Alternatively, the positioning spring 8 c could also be straight.

The positioning spring 8 c engages below the bearing edge 2 a of the yoke 2 and exerts a weak moment driving the armature against its dropped position.

Since the width of the engagement in the indentation 6 f from the section of the positioning spring 8 c speaks the width of the impression ent, the armature spring 8 or its positioning spring provides, in addition to the pressure of the armature 6 on the bearing edge of the yoke 2, also for fixing the position of the armature in the direction the bearing edge 2 a.

The leg of the L-shaped armature 6 which bears on the yoke 2 or on the wall of the coil housing 5 which runs parallel to this has an extrusion coating 6 a made of plastic. This extrusion 6 a has at its end facing away from the corner region formed by the two legs of the armature on a cross-sectionally T-shaped extension 6 b, onto which a coupling part 7 can be slid on.

This coupling part 7 has a T-shaped groove 7 a, which is only open on the side facing the coil housing 5 , and can be pushed onto the shoulder 6 b, the shoulder engaging in the groove 7 a. To facilitate the assembly of the coupling part 7 , this locking knob 7 b, which snap into corresponding recesses, but the recesses allow a mutual displacement of the coupling part 7 with respect to the approach 6 b and in the direction of the longitudinal extension of the T-shaped extension 6 b have a correspondingly greater length than the locking knobs 7 b.

At the end facing away from the armature 6 , the coupling part 7 has a slot 7 d running between the shoulders 7 c, in which, in the assembled state, a switching spring 13 engages with its extension 13 e with little play.

The inclination of the sliding surfaces 6g of the projection 6b against the movement direction of the armature is less than the friction angle of the selected material pairing and thus chosen so that there is no self-locking, but a retained mutual movability of the projection relative to the coupling part. This ensures that the coupling part 7 is entrained by the armature 6 due to the closure of the groove 7 a by means of a wall in the tightening direction of the armature 6 , where, in the waste direction of the armature, the armature is initially engaged by the switching spring 13 engaging in the slot 7 d with play is carried over the coupling part 7 , the shoulder 6 b abutting the groove 7 a closing wall. After completion of the movement of the switch-over spring 13 due to the impact of the changeover switch 13a on the associated normally-closed contact 11a but allows the armature 6 due to its mass inertia continue its movement, wherein d is a change in voltage applied to the spring 13 wall of the slot 7 comes without tensioning of the spring 13 due to the forces exerted by the anchor on it. This is due to the fact that from the time of the changeover contact 13 a on the normally closed contact 11 a there is a large decoupling of the coupling part 7 from the armature 6 and this can move relative to the coupling part in the falling direction. The kinetic energy of the armature is thereby by the friction of the sliding surfaces 6 g of the approach 6 b on the opposite surfaces of the groove 7 a of the coupling part 7 , and the friction of the coupling part 7 , or its diaphragm wall, on the spring 13 at the by the inclination of the approach 6 b against the direction of movement of the armature conditional movement of the coupling part 7 in the direction of the spring 13 consumed or implemented in heat. In this way, a bouncing caused by the inertia of the armature of the switch contact 13 a is avoided. Furthermore, a bouncing of the armature 6 is avoided in conjunction with the restoring moment of the armature spring 8 .

The possible decoupling of the armature 6 from the coupling part 7 also increases the vibration resistance of the relay, since it does not form a closed oscillation system with the contact spring as in the conventional relays, but a decoupling between these parts is possible and therefore no resonance can occur. In addition, there is also a division of the masses, and the energy that can be stored in the individual partial masses when vibrations occur cannot add up due to the decoupling.

The magnetic system described above, comprising parts 1 to 8 c, can thus be constructed as a separate, independent structural unit that is independent of the contact system.

A contact carrier body 9 of the contact system has a series of slots and recesses which serve to receive the contact carriers 10 , 11 and 12 and are formed in accordance with the desired arrangement of the molded pins 10 c, 11 c, 12 c. For anchoring the contact carrier, these studs 10 b, 11 b, and 12b, on which a body of the contact carrier 9 and thus for a safe stop of the contact carrier ensure a corresponding pressure in slots or grooves. 9

The normally closed contact 11 a and the working contact 10 a are each attached directly to their contact carriers 11 and 10 . To the switch contact 13 a, however, is attached to a Umschaltkontaktfeder 13, in turn, is preferably connected to the Umschaltkontaktträger 12, by laser welding.

The pin 12 c and the sections 12 d and 12 e of the switch contact carrier 12 are guided in narrow slots of the contact carrier body 9 , whereas the bent adjustment web 12 a lies in a larger recess of the contact carrier body, so that an adjustment of the switch contact, in particular the normally closed contact pressure is possible by bending the adjustment web. This has the advantage that the part does not have to be resiliently bent since the contact carriers 10 , 11 and 12 are made of an easily deformable material, such as, for. B. semi-hard copper or brass can be produced. This also prevents the spring characteristic of the changeover contact spring 13 from being influenced by the adjustment.

The Umschaltkontaktfeder 13 itself is formed as a double spring, i.e., between the bracket 13 a of the changeover contact 13 is arranged a supporting spring tongue 13 f, the yoke 13 d has a in the slot 7 of the coupling part d 7 engaging projection 13 e. An angle 13 b is provided between the clamping point 13 c and the spring tongue 13 f.

By designing the changeover contact spring as a double spring, it is possible to form the working contact as a rigid contact, since the overstroke can be applied by the spring tongue 13 f, which can bend elastically ver 13 d relative to the bracket. Furthermore, in the illustrated switch contact spring 13 there is also a burn-up reserve, which is given by the just in case elastic resilient extension 13 e of the bracket 13 d. This results in a saving of parts compared to a conventional structure of a relay with resilient work contact, since the Wegbe limit required for resilient work contacts is eliminated.

The contact system described above, comprising parts 9 to 13 , can thus also be constructed as a separate, independent structural unit that is independent of the magnet system.

The connection of the magnet system with the contact system he follows in the embodiment shown in that coil housing 5 of the magnet system on its outer wall has locking lugs 5 b, which cooperate with the resilient arms 9 b of the contact carrier body 9 of the contact system. When the bobbin case 5 is inserted into the guide for the bobbin case 5 formed by the projections 9 c and 9 d, the arms 9 b are laterally deflected by the latches 5 b and, after the latches have been covered, lie on the wall of the bobbin case and again are attacked by the locking noses. This ensures a defined mutual position which is ensured in this way by this snap-in connection. A further securing of this position results from the sliding of the cover 14 onto the relay.

Alternatively, the coil housing 5 could be formed with grooves for guide springs of the contact carrier body, along wel wel the contact system on the magnet system rotatably pushed and z. B. could be glued to this.

The invention is above based on a switch Relay has been explained in which relay type the invention but is not limited. In the same way, the Invention also z. B. in a work or rest contact find relay application.

Claims (5)

1. Relay with a core, a yoke and a coil, such as an armature-containing magnet system and a contact system held in a contact carrier body, the magnetic system and the contact system being each formed as independent, interconnectable structural units, characterized in that the coil with core and yoke is held in a coil housing ( 5 ) which is coupled to the contact carrier body ( 9 ) directly by means of a snap-in connection ( 5 b, 9 b). 2. Relay according to claim 1, characterized in that the coil housing ( 5 ) with the contact carrier body ( 9 ) is rotatably connected. 3. Relay according to claim 1 or 2, in which the armature is pressed against the bearing edge of the yoke by means of an armature spring held in the coil housing, characterized in that the coil housing ( 5 ) comprises a further snap-in connection for fixing the armature spring ( 8 ). 4. Relay according to one of claims 1 to 3, characterized in that the snap-lock connection between the coil housing ( 5 ) and the contact carrier ( 9 ) by on the coil housing ( 5 ) angeord designated projections ( 5 b) and from the contact carrier body ( 9 ) End resilient arms ( 9 b) is formed, which in the case of the coil housing ( 5 ) coupled to the contact carrier body ( 9 ) are engaged behind by the projections ( 5 b) of the latter, which also provides a fixation in the axial direction. 5. Relay according to one of claims 1 to 4, with an L-shaped armature, characterized in that as a connec tion element on the one leg of the armature ( 6 ) with a egg transverse to the direction of movement of this leg slot provided coupling part ( 7th ) is arranged, in the sen slot ( 7 d) with the contact carrier body connected contact spring ( 13 ) engages with the contact carrier body coupled coil housing ( 5 ), preferably with play.