DE19637212A1 - Electromagnetic relay - Google Patents

Abstract

A relay has a coil (4) with a core subdivided into two yokes. Two core sections within the coil are electrically insulated from each other. Each yoke has a pole section (52, 62) and a contact connection (53, 63), and so an armature (7) which cooperates with the pole sections (52, 62) acts at the same time as a contact bridge. The relay can be easily produced by over-moulding the individual parts on a conveyor band.

Description

The invention relates to an electromagnetic relay with egg a flat core arranged within an excitation coil, the two pole sections emerging from the coil each Form pole faces, also arranged next to the coil Neten armature, which on excitation of the coil on both pole faces rests and in the absence of coil excitation by a return actuator is biased into a rest position in which he at least one of the two pole sections of the core is raised, and with a Kon actuated by the anchor clock arrangement

A relay of the type mentioned is from the DE 33 18 493 A1 known. There is a flat core in one Coil body embedded, with the pole ends of the core through an angled anchor can be bridged at both ends. The anchor carries a bridge contact spring, which with two also fixed contact elements anchored in the coil body cooperates. The coil with the armature is then replaced by a Enclosed housing cap, the lower one Edge is sealed with resin and sealed.

The aim of the present invention is to use a small relay to create a flat structure with few, simple Parts can be manufactured cost-effectively on the assembly line.

According to the invention, this is the goal of a relay gangs mentioned achieved in that the core by ei gaps filled with insulating material in two elec yokes that are isolated from one another, each of which is divided one of the outgoing contact terminal bil det, and that the interacting pole faces of the core and of the anchor form contact surfaces at the same time.  

Due to the separation of the coils provided according to the invention The core can be divided into two electrically insulated sections formed yokes at the same time as electrical contact elements serve when the coil is excited by the An ker bridged, so that in this way with a fold anchor in the form of an elongated sheet of both Ma gnetkreis the excitation coil as well as the electrical load circuit can be closed. The two yokes, their pole section expediently in the same plane as the core section te lie or at most with a corresponding modification Bend come to lie in a parallel plane, are very easy to manufacture and, preferably by order spray on the belt, very inexpensive to assemble. With the loosely inserted and freely movable anchor. Can be so NO contact or with additional on the pole cut soot arranged opposite side of the anchor contact elements an NC contact or a changeover contact ver real.

The armature can be reset to the rest position in conventional Licher way through a spring made of metal or plastic aims to be. However, the use is particularly advantageous of a duration arranged opposite the pole sections magnet that pulls the anchor to its rest position. The dhow One of the advantages of ermagnet is that it is also included closed relay can be trimmed to this Way to set the restoring force.

In the manufacture of the relay according to the invention is useful moderately first a coil former by extrusion coating two yokes or formed from their core sections and wound. Then the winding is done by partially overmolding ten coil formed a first housing part, in which the Pole surfaces of the pole sections are kept clear. Furthermore is a second, approximately trough-shaped housing part ge which forms a trough-shaped recess. To record the An kers owns and in which, if applicable, the mating contacts  elements are embedded. By joining the two housings parts with their open edges become a closed ge housing formed in which the anchor is freely movable. There at can by more or less strong deformation in the edge area of the abutting housing parts the armature stroke, which also corresponds to the contact distance.

The invention is based on exemplary embodiments hand of the drawing explained in more detail. It shows

Fig. 1 shows a relay according to the invention designed in Perspecti vischer view omitting the top Gehäusetei les,

Fig. 2, the relay of FIG. 1 including the upper Ge häuseteiles,

Fig. 3 shows a longitudinal section III-III of Fig. 2 along the coil axis,

Fig. 4 shows a longitudinal section IV-IV in FIG. 2 by the armature,

Fig. 5 is a cross-section VV through the relay of Fig. 2,

Fig. 6 is a longitudinal section corresponding to Fig. 4 with a little from gewandeltem structure

FIGS. 7 and 8 the overlap region of the core portions in the coil nerhalb in detail view with respect to FIG. 3 modified forms,

FIG. 9A to 9C, a contact scheme for the relay of FIG. 1 in three consecutive to 5 switching phases,

Fig. 10 is a contact scheme for the relay of Fig. 6.

The relay shown in FIGS. 1 to 5 has two substantially trough-shaped housing parts, namely an upper or first housing part 1 and a lower or two th housing part 2 , which are connected to one another with their open edges and thereby all functional elements of the relay close tightly. In the upper housing part 1 egg ne coil with a bobbin 3 and a winding 4 is arranged or anchored by extrusion coating. A core is formed within the coil by two yokes 5 and 6 , which lie with corresponding core sections 51 and 61 in the axial region of the winding 4 and overlap there with the interposition of an insulating layer 66 . As in FIG. 3, this overlap can be achieved by the step-like design of the core sections 51 and 61 . However, other designs are also possible, for example by means of obliquely cut core sections according to FIG. 7 or by a short distance from one another at the end facing opposite core sections 51 and 61 according to FIG. 8.

The two yokes 5 and 6 also form laterally protruding pole sections 52 and 62 , which lie according to FIGS . 1 to 5 in one plane with the core sections, but which could also be bent or bent if the relay is designed differently. The Polabschnit te 52 and 62 also serve as contact elements and are therefore coated in a manner not shown with contact material be; if necessary, the surface can also be slightly curved to ensure reproducible support of the anchor to be described. On the yokes also contact terminals 53 and 63 are integrally formed, which leads through the housing walls of the upper housing part 1 to the outside and are bent there. In addition, 3 coil terminals 31 are anchored in the coil body, which are connected to the winding in a manner not shown and which run on the outer side of the housing parallel to the contact terminals. All connection elements can be bent in the manner shown as solder pins or in a known manner in a connection plane to form SMT connections for the surface days (not shown).

In the lower housing part 2 , a trough-shaped Ausneh 21 is provided parallel to the coil axis, in which an armature 7 in the form of a rod or in the form of an elongated plate is arranged freely be movable below the pole sections 52 and 62 . In the example shown, it is pulled through a permanent magnet 10 into the rest position shown; the permanent magnet is preferably polarized in the longitudinal direction of the armature, but another polarization direction is also conceivable. Under the anchor ends are normally closed contacts 8 and 9 , which are anchored with associated contact connections 81 and 91 in the unte ren housing part 2 .

The function of the relay results from the structure shown. When the coil is excited, the armature is attracted to the two pole sections 52 and 62 . It therefore moves from the rest position according to FIG. 9A into the working position according to FIG. 9C. To avoid that he temporarily creates a contact bridge between the pole section 52 and the normally closed contact 9 during switching, the construction is designed somewhat asymmetrically. As shown in FIG. 4, the pole section 62 is kept somewhat narrower than the pole section 52 , so that when the armature is excited, its left end 71 is always first attracted to the pole section 52 (see FIG. 9B) and the right armature end 72 only then follows. In addition, the normally closed contact 9 is displaced somewhat from the armature end 72 towards the center, so that the armature end 72 rests on a step 22 of the lower housing part 2 when it is inclined, ie there is no longer any contact with the normally closed contact 9 . Accordingly, the intermediate position according to FIG. 9B is also passed through when the armature falls back after the excitation has been switched off. Due to an asymmetrical arrangement of the permanent magnet 10 , the desired switching sequence is also begün. The pole faces 54 and 64 , which also serve as contact surfaces, are usually coated with precious metal. In order to always ensure good contact, these surfaces as well as the surfaces of the rest contacts 8 and 9 are expediently provided with bulges.

Fig. 6 shows a modification of the relay in such a way that the armature does not act as a bridge changer as in the first example, but as a simple changer. For this purpose, in this second embodiment, the pole section 62 is bent downwards, so that the armature always remains tied to the pole section 62 with its end 72 , while its end 71 switches between the pole section 52 and the now only resting contact 8 . The associated circuit diagram is shown in Fig. 10. In this embodiment in particular, it is important that the pole faces 54 and 65 of the two pole sections are designed obliquely or arched so that the armature also provides the desired contact when tilted.

In the manufacture of the relay, the coil body 3 is first formed by partially overmolding the yokes 5 and 6 , in particular the core sections 51 and 61 . This coil former is provided with the winding 4 and then extrusion-coated again, as a result of which the upper housing part 1 is molded. The Polab sections 52 and 62 are at least with their Polflä surfaces 54 and 64 and 65 kept free. The lower housing part 2 is also produced by an injection molding process, wherein the normally closed contacts 8 and 9 and the permanent magnet 10 are embedded, if appropriate, and the trough-shaped recess 21 for the armature 7 is left out. Then the two Ge housing parts 1 and 2 are joined together and joined together at their edges, for example glued or welded with ultrasound. When joining, the armature stroke or contact spacing ª can be adjusted by deforming the edges of the two housing parts more or less. Vorzugswei se is on one of the housing parts, for example as shown on the obe ren housing part 1 , a circumferential web 11 is formed , which is more or less deformed when joining to produce the desired distance ª. Since all connections 31 , 32 , 53 , 63 and 81 , 91 are injected into their respective housing parts and are thus led out tightly, the tight gluing or welding of the two housing parts creates a tight relay housing in a simple manner.

Claims (12)

1. Electromagnetic relay with an excitation coil coil ( 4 ) arranged flat core ( 51 , 61 ), the two emerging from the coil sections ( 52 , 62 ) each form pole faces ( 54 , 64 ; 65 ), with one next to the coil to ordered armature ( 7 ), which rests on both pole faces when the coil is excited and is biased by a restoring force into a rest position in the absence of coil excitation, in which it is lifted off at least from one of the two pole sections of the core, and with one by the armature ( 7 ) operable contact arrangement, characterized in that the core is divided by an insulating space ( 66 ) into two electrically insulated yokes ( 5 , 6 ), each of which has a contact terminal ( 53 , 63 ) going outside the coil ( 4 ) ) forms, and that the interaction of the pole faces of the core ( 5 , 6 ) and the armature ( 7 ) simultaneously form contact surfaces. 2. Relay according to claim 1, characterized in that the restoring force is generated by a permanent magnet ( 10 ) on the opposite side of the pole sections ( 52 , 62 ) of the core ( 7 ). 3. Relay according to claim 1, characterized in that the restoring force is generated by a spring. 4. Relay according to one of claims 1 to 3, characterized in that the core sections ( 51 , 61 ) of the yokes are embedded in a coil former ( 3 ) made of plastic, with adjacent ends of the two core sections ( 51 , 61 ) with the interposition of the Coil body plastic partially overlap each other. 5. Relay according to one of claims 1 to 4, characterized in that the core sections ( 51 , 61 ) and the pole sections ( 52 , 62 ) embedded in the coil former ( 3 ) lie in a common plane or in parallel planes. 6. Relay according to one of claims 1 to 5, characterized in that the armature bridges two pole sections ( 52 , 62 ) opposite normally closed contacts ( 8 , 9 ) in its rest position, each provided with normally closed contact connections ( 81 , 91 ) are. 7. Relay according to one of claims 1 to 6, characterized in that the two working air gaps between the armature movable with both ends ( 7 ) on the one hand and the two pole sections ( 52 , 62 ) on the other hand are designed differently in order to move the armature to ensure a forward run of a given anchor end ( 71 ) relative to the other anchor end ( 72 ). 8. Relay according to one of claims 1 to 7, characterized in that the restoring force ( 10 ) acts asymmetrically on the armature ( 7 ) to generate a predetermined movement sequence. 9. Relay according to one of claims 1 to 5, characterized in that the armature ( 7 ) with one end ( 72 ) is tied to one of the pole sections ( 62 ), while with its other end ( 71 ) between a working position the second pole section ( 51 ) and a distant rest position can be switched. 10. Relay according to one of claims 1 to 9, characterized in that the coil body ( 3 ) with the Polab cut in an first housing part ( 1 ) is anchored that the armature ( 7 ) in a recess ( 21 ) of a second housing partly ( 2 ) is arranged and that the two, approximately wan-shaped housing parts with their open edges joined together to form a tight housing, through the walls of which contact and coil connections ( 53 , 63 ; 31 , 32 ; 81 , 91 ) are directed towards the outside are led. 11. Relay according to claim 10, characterized net that the first and / or the second housing part each by at least partially embedding those arranged in it Relay elements, with the exception of the armature, are formed. 12. Relay according to claim 10 or 11, characterized in that the parting plane between the two housing parts essentially parallel to the pole faces ( 54 , 64 ), such that when joining the two housing parts ( 1 , 2 ) by deformation of the Edge ( 11 ) on at least one of the housing parts, the height of the working air gap or the contact spacing is adjustable.