DE4309618A1 - Polarised electromagnetic relay - Google Patents

Abstract

The relay comprises a base (1) having stationary mating contact elements (11, 12, 13, 14), a coil (21, 22, 23, 24), a permanent magnet (28) and a rocker-type armature (31) which is arranged between the base and the coil, is connected to moving contact elements (33, 34) and is mounted on the base (1) via supporting strips (37, 38), the supporting strips at the same time being used as electrical connections for the moving contact elements. The fastening between the supporting strips (37, 38) and bearing supports, which are constructed as connecting elements, of the base (1) is effected on a plane running at right angles to the base plane of the base, the supporting strips (37, 38) being bent with curved sections into this vertical plane. In consequence, the contact separation can be set without any tolerances even during production, and it is not dependent on the tolerances of the individual parts. The design makes it possible to produce the individual parts without any problems and cost-effectively, and enables accurate assembly without any requirement for subsequent adjustment. <IMAGE>

Description

The invention relates to a polarized electromagnetic Relay with

• - A base made of insulating material with its bottom side defines a basic level and defines at least two standing counter-contact elements and two bearing supports for an anchor is attached,
• - A coil attached to the base with the bottom plane parallel axis, one core and two with the ends the core-connected pole pieces,
• - A permanent magnet arrangement in the area of the coils forms a center pole of a first pole direction and On the pole shoes, there are opposite poles generated pole direction,
• - arranged approximately parallel to the coil axis, approximately in the middle around a parallel to the base plane swivel-mounted, flat rocker anchor,
• - A contact arrangement with the anchor firmly connected at least two embedded in an insulating carrier movable contact elements, each with an egg interact with the counter-contact elements, and
• - Two out as flat bearing strips with a U-shaped contour formed bearing elements, each with a first Legs partially embedded in the insulation carrier are on opposite long sides of the anchor kick and over an arcuate central section a second leg on an associated bearing support are attached.

Such a relay is known from EP 0 423 834 A2. This relay, like others, is basically similar assembled miniature relays are the different assembly pen, i.e. the base with the fixed contact elements,  the anchor with the movable contact elements and the spu lenbaugruppe, stacked on top of each other what to a summation of the manufacturing tolerances of the individual parts leads. So it is according to the known relay EP 0 423 834 A2 the anchor is fastened via bearing elements which in the form of torsion bars and parallel to the base plane fastening arms also parallel to the ground flat lying support surfaces are attached lying. The Distances between the armature connected to the contact springs and the base with the fixed contact elements on the one hand and the magnet system with the permanent magnet of others on the one hand are thus firm through the manufacture of the individual parts given. That means on the one hand the individual parts very much have to be manufactured with little tolerance and therefore complex, that, however, the remaining tolerances in the Total assembly. How to get out of the magnetic circuit formulas without can be calculated further, especially the situation spread of the permanent magnet with a more or less large air gap stored anchor square in the available force, so that the dimensioning of the coil depends essentially on the accuracy of the armature air gaps in production can be put.

The aim of the invention is to provide a relay of the type mentioned Kind of constructive design and a manufacturing or Assembly procedures for this indicate that the tolerances of the Individual parts have no influence on the accuracy of the position of the anchor with the movable contact springs. So regardless of the accuracy of the individual parts the movable contact elements and in particular the anchor be mounted in the correct position, so that a subsequent Ju is largely avoided.

According to the invention, this is the goal of a relay gangs mentioned achieved in that the two camps ribbons with their arched, exposed middle section ten vertically downwards in a common, to the ground plane  and kinked plane perpendicular to the longitudinal axis of the anchor, so that their respective second legs in the common plane stand vertically upwards, where they belong with the respective are welded to the bearing support.

In the case of the invention, the previous layer construction is therefore used for leave the anchor attachment, rather the attachment takes place tion of the movable armature contact assembly perpendicular to Ground level standing mounting surfaces. So that can Anchor contact assembly already in the manufacture be brought into the correct position and fixed there without the height tolerances of the individual parts in this position hen.

As a joining base for the anchor assembly and for the entire re In an expedient embodiment, lais serves the duration gnet, since this is manufactured very precisely and dimensionally stable and can be connected to the pole pieces. Then at the Installation of the relay of the anchors exactly in terms of duration magnets positioned and fixed, so it only comes out on that this permanent magnet with respect to the Gegenkon clock-bearing base is set with low tolerance. For this purpose, the permanent magnet with the appropriate Ab withstanders, for example with side lugs corresponding areas of the base.

Further configurations of the relay are in the subclaims Chen specified.

To produce the relay contains a convenient procedure the following steps:

• - The coil is with the pole pieces and between the Pole magnets arranged permanent magnets connected,
• - The anchor connected to the contact spring arrangement between the coil or the permanent magnet and the one with the Coil-connected base arranged so that both Sides each have a bearing band on one perpendicular to the  The ground level bearing support rests and the anchor held in one end position by the permanent magnetic flux will, and
• - Finally, the bearing belts are bent in the Position welded to the associated bearing supports.

In a particularly advantageous embodiment of this procedure rens the two bearing belts in one to the bottom plane parallel direction slightly bent before turning on their associated bearing supports are welded on. To this Way you achieve that the elastic during assembly bent bearing belts again after this assembly step stretch and anchor in the storage area by a small amount Remove the given amount from the permanent magnet. Thus everyone surface friction between armature and permanent magnet avoided.

The invention is described below using an exemplary embodiment explained in more detail with reference to the drawing. Show it

Fig. 1 shows a relay according to the invention designed in a longitudinal section,

Fig. 2, the relay of Fig. 1 seen in a horizontal section, clock spring by the armature assembly, from above the movable Kon,

Fig. 3, the movable contact assembly in a plan view,

FIGS. 4 and 5 show two different sectional views IV-IV and VV in each case transversely to the coil axis, and

Fig. 6 is a side view of the relay of Fig. 1 with a cut cap.

The relay shown in the drawing has a fla chen base 1 with four embedded mating contact elements 11 , 12 , 13 (not visible) and 14 , the contact sections 11 a, 12 a, 13 a and 14 a are exposed at the top of the base and their Terminal lugs 11 b, 12 b, 13 b and 14 b each emerge vertically from the underside of the base. Underneath the contacting sections 11 a, 12 a, 13 a and 14 a recesses 15 are provided in the base, so that a con tact adjustment is possible.

A coil assembly 2 is arranged on the base 1 . It comprises a coil former 21 , which carries a winding 24 between two flanges 22 and 23 and receives a core 25 in an axial opening. On the ends of the core 25 , two pole pieces 26 and 27 are attached, which form downward direction towards the base of each pole ends 26 a and 27 a. Between these pole ends 26 a and 27 a, a flat, rod-shaped permanent magnet 28 is arranged parallel to the coil axis and to the base plane and firmly connected to the two pole shoes 26 and 27 . The permanent magnet is magnetized with three poles and has, for example, a north pole in its center and a south pole at both ends.

A movable armature assembly 3 is arranged between the base 1 and the magnet system or the coil assembly 2 that is firmly seated on the base. It consists of an armature 31 , which is stamped from a ferromagnetic sheet metal so that it can roll as a rocker armature with its central part on the central pole of the permanent magnet 28 and with its ends 31 a and 31 b each have a working air gap with the two pole ends 26 a and 27 a of the pole shoes 26 and 27 forms. The anchor 31 be sits at least on its underside an insulating wall 32 , which is formed in the present example as an encapsulation of the armature 31 , but which could also be connected to the armature in another way, for example by gluing on a film or the like. On the insulating wall 32 two tabs 32 a and 32 b are formed on the side of the armature ( FIG. 6), which on the one hand serve to facilitate assembly for the power supply lines when the armature and spring assembly are joined, and on the other hand, a displacement of the armature in the longitudinal direction during switching prevent.

With the anchor, a movable spring set in the form of two center contact springs 33 and 34 is connected to a common insulating material 35 . The connection is made for example by means of deformable plastic pin 36 of the insulating wall 32 on the anchor. The two center contact springs 33 and 34 each have two contacting ends 33 a and 33 b or 34 a and 34 b, which are split in the present example in two spring tongues to increase the contact reliability. The contact-making ends cooperate with a respective one of the underlying contact-making portions of the contact elements together, that is the contact-making end 33 a with the Kontaktab section 11 a, the end 33 b a with the contact portion 12, the contact end 34a with the contact portion 13 a and the Contact end 34 b with the contact section 14 a.

Each of the center contact springs 33 and 34 also has a power supply or a bearing band 37 or 38 which extends in a U-shape on the outside of the contact arrangement or of the core and outside of the insulating jacket 35 . However, this U-shaped bearing band 37 or 38 is not parallel to the base plane as in known relays, but is bent out of the original circuit board plane of the center contact springs 33 and 34 by 90 °, so that their respective arcuate central sections 37 b and 38 b are vertically downward from the spring plane, while their first legs 37 a and 38 a are partially embedded in the spring plane 35 in the Isolierstoffum envelope and their second legs 37 c and 38 c are perpendicular upwards from the spring plane. In Fig. 3, the bearing tapes are also shown in dashed lines in their original shape in the plane of the board.

For attachment and storage of the armature assembly are anchored in the base 1 on both sides of a bearing support 17 or 18 , which form the tabs 17 a and 18 a leading out for the center contact springs 33 and 34 . The bearing strips 37 and 38 can now be welded to these bearing supports 17 and 18 , which extend perpendicular to the base plane. Since the contact plane between the bearing supports and the bearing tapes extends perpendicular to the base plane, the bearing tapes 37 and 38 and with them the entire anchor assembly can be moved in height before final attachment and thus positioned and attached in the correct position. Due to the bent in a vertical plane bearing tapes there is also the advantage that the spring rates of the center contact springs in both switching directions are approximately the same size, so that the burn-off safety of the normally closed contact and the normally open contact are approximately the same size. In addition, the spring rate can be easily adapted by changing the bearing strips, for example shortening or lengthening the arc-shaped sections, to the force-displacement cure ven of the magnet system without the other construction having to be changed.

When installing the relay, the armature assembly 3 is first placed loosely on the base, then the bearing supports 17 and 18 are anchored or bent, and finally the coil assembly 2 (magnet system) is placed on the base with dimensional accuracy. The underside of the permanent magnet 28 or the top of the base 1 serves as the joining base level between the magnet system and the base. In the present example, the permanent magnet 28 has two lugs 29 on both sides (see FIG. 6), which rest on corresponding support walls 19 of the base 1 . As a result, the predetermined dimension between the permanent magnet and the base, in particular the anchored in the base contact sections 11 a, 12 a, 13 a and 14 a, is obtained. It should also be mentioned that previously in the Mon days of the magnet system, the permanent magnet 28 was fixed by four laser welds at the points 28 a precisely on the pole pieces. The pole pieces for their part are pressed onto the core 25 with penetration, which results in a low magnetic resistance. In the case of the base 1, in turn, the exact predetermined dimension between the joining base on the support walls 19 and the contact sections 11 a, 12 a, 13 a and 14 a is achieved by embossing in the recesses 15 .

After the dimensionally accurate placement of the coil assembly on the base, the loosely inserted armature 31 is attracted by the permanent magnet and brought into one of its two end positions according to FIG. 1 or FIG. 6. The bearing belts 37 and 38 are now also at the correct height on their bearing supports 17 and 18 and can be welded to them. Since the bearing tapes, as shown in Fig. 6, near their BEFE stigungsstelle between the two lugs 32 b of the insulating wall 32 of the armature, the anchor can practically no longer move ben in the longitudinal direction after fastening supply. As a result, there is practically no friction path when the armature rolls off the center pole of the permanent magnet. However, changes in length could result from the effects of temperature on the assembled parts, which could result in tension and cause friction. For this reason, it is advisable to provide a minimal, defined air gap between the armature and the permanent magnet, which is set in the following way:

As shown in FIG. 6, the armature 31 is held in an end position by the permanent magnet 28 . Now each resilient bolt (not shown) presses in the direction of arrow 40 against the two bearing bands 37 and 38 in order to bulge them slightly resiliently. In this bent state, the bearing belts 37 and 38 are then welded to their respective bearing supports 17 and 18 . If you let the bearing strips spring back into their stretched position, they lift the anchor in the bearing by a defined small air gap from the permanent magnet, thus preventing any bearing friction. But it would also be possible to manufacture this small air gap in another way, for example by inserting a thin distance gauge, or to carry out the welding process with parts that were previously brought to a certain temperature, e.g. B. a temperature that is outside the permissible limit temperature of the relay.

With a cap 41 attached to the base, the relay is completed. The housing obtained in this way can of course be sealed in a conventional manner, the flow of casting resin into the interior of the relay being prevented by appropriate design of the interlocking parts of the base, magnet system and cap.

Claims (14)

1. Polarized electromagnetic relay with a base ( 1 ) made of insulating material, which defines a base level with its bottom side and in which at least two fixed counter contact elements ( 11 , 12 , 13 , 14 ) and two bearing supports ( 17 , 18 ) for an anchor ( 31 ) are attached,

• - A coil ( 21 , 22 , 23 , 24 ) fastened on the base ( 1 ) with an axis parallel to the base plane, a core ( 25 ) and two pole shoes ( 26 , 27 ) connected to the ends of the core,
• a rod-shaped permanent magnet ( 28 ) which forms a central pole of a first pole direction (N) in the region of the coil center and generates poles of an opposite pole direction (S) on the pole shoes,
• - An approximately parallel to the coil axis, approximately in the middle of a parallel to the base plane with central axis pivoted, flat rocker armature ( 31 ),
• - A with the armature ( 31 ) Kontaktanord voltage with at least two embedded in an insulating carrier ( 35 ) movable contact elements ( 33 , 34 ), which che optionally interact with one of the mating contact elements ( 11 , 12 , 13 , 14 ), and
• - Two as flat bearing strips ( 37 , 38 ) with U-shaped con ture bearing elements, each with egg nem first leg ( 37 a, 38 a) are partially embedded in the insulating material carrier ( 35 ), on opposite longitudinal sides of the armature ( 31 ) emerge and are attached to an associated bearing support ( 17 , 18 ) via a bow-shaped central section ( 37 b, 38 b) with a second arm ( 37 c, 38 c),

characterized in that the two bearing strips ( 37 , 38 ) with their arcuate exposed central sections ( 37 b, 38 b) are bent vertically downward into a common plane perpendicular to the base plane and to the longitudinal axis of the anchor, so that their respective second legs ( 37 c , 38 c) stand vertically upwards in the common plane, where they are welded to the associated bearing support ( 17 , 18 ). 2. Relay according to claim 1, characterized in that the bearing strips ( 37 , 38 ) are each connected to one of the movable contact elements ( 33 , 34 ) and that the bearing supports ( 17 , 18 ) with connecting elements ( 17 a, 18 a) for these contact elements are connected. 3. Relay according to claim 1 or 2, characterized in that the permanent magnet ( 28 ) rests on the base ( 1 ) as a joining base with lateral shoulders ( 29 ). 4. Relay according to one of claims 1 to 3, characterized in that the insulating material carrier ( 35 ) is fastened by means of deformed pins ( 36 ) in recesses of the armature ( 31 ). 5. Relay according to one of claims 1 to 4, characterized in that the armature ( 31 ) on the movable contact elements ( 33 , 34 ) facing side carries an insulating layer ( 32 ). 6. Relay according to claim 5, characterized in that the insulating layer ( 32 ) is formed by partially embedding the armature ( 31 ). 7. Relay according to claim 5, characterized in that the insulating layer is part of the insulating substrate ( 35 ) of the movable contact elements ( 33 , 34 ). 8. Relay according to one of claims 1 to 7, characterized in that a pair of shock protection lugs ( 32 a, 32 b) is provided on the longitudinal sides of the armature, which in each case one of the bearing strips ( 37 , 38 ) close to the fastening point on the bearing support ( 17 , 18 ) with little play in the longitudinal direction of the armature ( 31 ). 9. Relay according to claim 8, characterized in that the shock protection lugs ( 32 a, 32 b) are part of an embedding of the core ( 31 ). 10. Relay according to one of claims 1 to 9, characterized in that the movable contact elements ( 33 , 34 ) on egg nem in the insulating support ( 35 ) have a portion serving as a fuse constriction. 11. A method for producing a relay according to one of claims 1 to 10, characterized by the following steps:

• - The coil ( 21 , 22 , 23 , 24 ) is connected to the pole pieces ( 26 , 27 ) and the permanent magnet ( 28 ) arranged between the pole pieces,
• - With the contact spring arrangement ( 33 , 34 ) connected to ker ( 31 ) is arranged between the coil ( 21 , 22 , 23 , 24 ) or the permanent magnet ( 28 ) and the base connected to the coil ( 1 ) so that a bearing band ( 37 , 38 ) abuts on both sides on a bearing support ( 17 , 18 ) perpendicular to the base plane and the armature ( 31 ) is held in an end position by the permanent magnetic flux, and
• - Then the bearing strips ( 37 , 38 ) are welded to the associated bearing supports ( 17 , 18 ).

12. The method according to claim 11, characterized in that the bearing strips ( 37 , 38 ) before welding in a direction parallel to the base plane elastically bent and zen in this bent position with the associated Lagerstüt ( 17 , 18 ) are welded. 13. The method according to claim 11 or 12, characterized in that the magnet system with the coil ( 21 , 22 , 23 , 24 ), the pole pieces ( 26 , 27 ) and the permanent magnet ( 28 ) first with support portions ( 29 ) of the permanent magnet ( 28 ) is positioned precisely at a distance from the base ( 1 ) and that the bearing strips ( 37 , 38 ) connected to the ker ( 31 ) are then attached at precise distances to the permanent magnet ( 28 ) on their bearing supports ( 17 , 18 ).