EP0077017A2 - Polarised electromagnetic relay - Google Patents

Abstract

The relay has two U-shaped angled, parallel yokes (4, 5), between the parallel central sections (4a, 5a) a permanent magnet (6) is arranged and the free side legs (4b, 5b, 4c, 5c) in pairs upwards protrude. Between the pair of yoke legs (4b, 5b, 4c, 5c) there is also a U-shaped rotating anchor (7) with its legs (7b, 7c) angled downwards. The two yokes (4, 5) are embedded together with the permanent magnet (6) in a coil former (11). A trough-shaped base body (1), which is open at the bottom and carries a bearing for the armature (7) and embedded contact connection pins (3), is placed over this coil former (11). The base body forms, together with a housing cap (12), a cotactic space which is sealed off from the coil winding and from the outside atmosphere.

Description

The invention relates to a polarized electromagnetic relay with two U-shaped, parallel spaced yokes, which enclose at least one permanent magnet between them and whose central sections together form the core of a coil, one formed by an elongated ferromagnetic sheet, in its The center of gravity of the rotatably mounted anchor lies with its free ends between the pair of parallel legs of the yokes and forms a working air gap with each of these yoke legs.

A polarized magnet system of this type is known, which serves as a drive system for relays, alarm clocks and the like (DE-PS 966 845). However, there is no specific embodiment for a relay with several contacts which can be actuated by the armature. There is also no discernible separation of the contact space from the coil winding, as is often required for relays.

From DE-OS 27 23 430 a relay is also known, in which the actuation of several contacts and a hermetic separation between the coil space on the one hand and the contact space arranged above the coil on the other hand is provided in a compact design. In this known relay, only a single U-shaped yoke runs through the coil, which is guided into the contact space with two legs. A polarized relay can only be created there by a permanent magnet arranged in the contact space, this permanent magnet ent is neither coupled to the yoke leg ends in an elongated design or carried by a so-called H-anchor. Although an effective polarized system with bistable and monostable switching characteristics can be obtained, the H-armature is relatively large and heavy due to its two ferromagnetic sheet metal parts and one or more permanent magnets arranged between them, so that a relatively large mass must be moved when switching. In the two embodiments described there, however, the contact space is narrowed in any case by the permanent magnet or magnets.

The object of the present invention is to develop a relay of the type mentioned at the outset such that, in the most compact possible design, a plurality of contact elements can be actuated by an armature with the smallest possible mass, the contact space being hermetically sealed in a simple manner with respect to the coil winding and to the outside atmosphere.

According to the invention, this object is achieved in that the permanent magnet is arranged between the central sections of the two yokes and, together with them, is encased with insulating material in such a way that the armature, which is also U-shaped in the opposite direction to the yokes, has the coil winding on its side legs End faces overlap between the free legs of the yokes, the armature being mounted on a base body which, in the form of an inverted trough, covers the coil winding, is provided with openings in the area of the yoke legs and carries contact connecting elements anchored to the side of the coil.

In the construction according to the invention, the permanent magnet is together with the yokes with insulating material encased, for example encapsulated with plastic, and this encasement is then provided with the coil winding. In this way, not only is a stable bond between the yokes and the permanent magnet obtained, but there is also no need for separate manufacture of a coil former. It is also advantageous that a symmetrical structure of the relay is possible with a single permanent magnet. The contact room is then between the four. Yoke legs only a rod-shaped armature made of ferromagnetic sheet metal, so that a relatively large amount of space remains for the contact elements. The U-shaped shape of both the yokes and the anchor result in large pole faces in the working air gaps while at the same time making good use of space. Nevertheless, a sealing between the contact space and the coil space is made possible by the base body as the carrier of the armature and the contact elements, which is placed in the form of a trough over the coil winding.

The permanent magnet can extend within the coil between the two yokes over its entire length, whereby large coupling surfaces between the permanent magnet and the respective yoke are obtained. The properties of ferrite magnets can be exploited well here. The extension of the permanent magnet in its polarization direction between the two yokes is expediently chosen such that it corresponds exactly to the sum between the armature thickness and armature stroke. This makes it possible to use particularly simple flat sheet metal parts for the yokes and the anchor.

By coordinating the four working air gaps between the armature and the yokes, a bistable or a monostable switching characteristic of the relay can be set. In order to obtain a bistable characteristic, the area totals of the diagonally opposing pole faces of the armature and the yoke legs become the same chosen large. A monostable switching characteristic is obtained if the surface sums of the diagonally opposing pole faces are of different sizes. The first requirement is that the contact spring set acts symmetrically on the armature in both cases. Even with an asymmetrically acting spring set, the force-displacement curve of the magnet system can be adjusted by varying the pole faces. To support this adjustment, it is also expedient that in the monostable embodiment, separating plates are attached to two diagonally opposite pole faces of the yoke or the anchor will.

The anchor is expediently provided in its central region with a jacket made of insulating material, so that it can be mounted on a bearing journal of the base body by means of a bush molded into this jacket. In order to enable this central mounting, in this case the middle part of the armature is expediently provided with a bend which wraps around the bushing on one side.

In order to enable the above-mentioned simple embodiment of the armature with a completely flat sheet metal part, the armature can also be mounted by means of a bearing spring arranged on the base body, which supports the armature via spring tabs which are bent laterally be, whereby a tolerance compensation is made possible during assembly through the elongated holes.

The coil former expediently has flanges with sealing surfaces lying against the base body in the area of the yoke legs. The base body also expediently rests with its openings on the yoke legs and forms with its outer edge sealing surfaces against a housing cap placed over the entire relay. The base body on the one hand and the housing cap on the other hand can be connected by means of interlocking locking elements. In addition, the housing cap expediently has an edge that encompasses the base body and the coil body all around. After assembling the relay can. the space open to the outside and enclosed by this edge is filled with casting resin, whereby the entire coil space is sealed and at the same time sealed from the contact space.

• Fig. 1 bis 4 ein erfindungsgemäß gestaltetes Relais in vier verschiedenen Schnittansichten,
• Fig. 5 und 6 die Anordnung von Jochen und Dauermagnet vor und nach dem Ummanteln,
• Fig. 7 und 8 einen Anker aus Fig. 4 vor und nach der Ummantelung,
• Fig. 9 und 10 eine abgewandelte Ankerausführungsform, ebenfalls vor und nach dem Umspritzen,
• Fig. 11 eine Lagerfeder für den Anker,
• Fig. 12 ein Relais mit Lagerfeder und Anker in eingebautem Zustand.

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

• 1 to 4 a relay designed according to the invention in four different sectional views,
• 5 and 6, the arrangement of yokes and permanent magnet before and after sheathing,
• 7 and 8 an anchor of FIG. 4 before and after the casing,
• 9 and 10 a modified anchor embodiment, also before and after extrusion coating,
• 11 is a bearing spring for the armature,
• Fig. 12 is a relay with a bearing spring and armature in the installed state.

The relay according to FIGS. 1 to 4 has a base body 1 made of plastic, which is put over a coil 2 in the form of a trough with an open underside and carries in each case injected contact connection elements 3 on both sides of the coil.

The magnet system contains two U-shaped yokes 4 and 5, which are shown in FIG. 5 and 6 are shown in more detail. These yokes enclose between them a permanent magnet 6 which extends essentially over the entire length of the yoke middle sections 4a and 5a and is polarized in the direction between the two yokes. Between the pairs An upwardly directed yoke leg 4b, 5b and 4c, 5c is also an essentially U-shaped armature 7 with its downward leg 7b and 7c. The armature 7 is provided in its middle part 7a with an insulating jacket 8, into which a bearing bush 9 is molded. By means of this bearing bush 9, the armature is rotatably supported in the center on a bearing journal 10 of the base body 1.

By overmolding the unit from the two yokes 4 and 5 and the intermediate permanent magnet 6 with insulating material, a coil body 11 is formed, which supports the coil winding 2 and with its flanges 11a and 11b, each sealing contact surfaces 11c and 11d (Fig. 6) with respect to the middle part 1a of the base body 1 forms. In order to obtain the largest possible pole faces between the armature and the yokes 4 and 5, the armature grips with its side legs 7b and 7c in each case on the front side over the coil. lenflansche 11a and 11b down. In this area, the base body is lowered between the yoke legs 4b and 5b or 4c and 5c, so that it lies between the end of the armature legs 7b and 7c and the permanent magnet 6. With the circumferential wall 1b, the base body 1 bears all around on the housing cap 12, this side wall 1b each containing the injected contact connections 3 in two rows to the side of the coil.

Contact springs 3 and 13 'or fixed contacts 14 are welded or molded onto the contact connections 3 above the base body 1 or on both sides of the armature 7, which in the usual way form either break contacts or make contacts or changeover contacts. To form changeover contacts, the contact springs 13 and 13 'shown separately in FIG. 4 can each be connected to one another and welded to a common connecting pin. The contact springs 13 and 13 'are through Lugs 15 actuated, which are integrally formed on the casing 8 of the armature 7.

During assembly, the coil body 11 with the yokes 4 and 5 is first inserted into the base body, the yoke legs 4b, 5b, 4c and 5c being pressed through the recesses 1d and 1e of the base body 1 until the contact surfaces 11c and 11d on Fit base body 1. The anchor is inserted from above, and then the cap 12, which is made of plastic, is slipped over the base body, locking lugs 16 formed on the base body latching into corresponding recesses 17 in the cap. As a result, the base body is temporarily fixed in the cap. Thereafter, the downwardly open coil space 18 formed by the protruding edge 12a of the cap is poured out with casting resin. As a result, all contact surfaces between the coil body 11 and the base body 1 and between the base body 1 and the cap 12 are sealed. At the same time, the bushings 19 of the injected contact elements 3 are additionally sealed. The hardened cast resin also serves to stabilize the relay.

The structure of the yokes and the coil body is shown in FIGS. 5 and 6 in a perspective view. The yoke arrangement according to FIG. 5 is suitable for a bistable embodiment of the relay, since all yoke legs 4b, 5b, 4c and 5c 'are of the same design and not compared to this here. shown anchor have the same pole faces. In order to obtain a monostable embodiment, two diagonally opposed yoke legs, for example 5b and 4c, are changed such that the sum of their pole faces relative to the armature is smaller than the sum of the pole faces formed by the other two yoke legs 4b and 5c.

The two yokes 4 and 5 with the permanent magnet 6 in between are overmolded with plastic according to FIG. 6, whereby the bobbin 11 is formed. Flanges 11a and 11b are formed on this coil former 11 in the area of the yoke legs 4b, 5b, 4c and 5c, which flanges 11c and 11d have for contact with the base body 1 (see also FIG. 1). This enables a good seal between the coil winding and the contact space. In addition, each coil connection lugs 20 are fastened to the coil flanges by injection or by insertion.

7 and 8 show an armature 7, as was used in the relay according to FIGS. 1 to 4. The armature consists of a ferromagnetic sheet-metal part which has a lateral deflection in the central region 7a in order to make room for a bearing bush in the center of gravity. The two legs 7b and 7c are angled downwards and, as mentioned, engage between the paired yoke legs 4b and 5b or 4c and 5c according to FIG. 6. The armature shown in FIG. 7 is intended for a monostable relay. It therefore carries a separating plate 21 on two diagonally opposite pole faces. In the monostable embodiment, as shown in FIG. 8, all pole faces are of the same design.

Fig. 8 shows an armature 7 with a casing 8, on each of which actuating lugs 15 are molded for contact actuation. In addition, the bearing bush 9 already mentioned is formed in the central region.

A modified embodiment of the armature is shown in FIGS. 9 and 10. In this case, the anchor is designed in a particularly simple manner as a flat sheet metal part 27, the central part 27a of which extends straight between the side legs 27b and 27c which are angled downwards. 10 shows the encapsulation of the armature 27 with two plastic webs 28 and 29, on which in turn actuating lugs 15 are integrally formed.

9 and 10 can not be stored with a pin bearing according to the previous example. One possibility for mounting this armature via a bearing spring 22 is shown in FIGS. 11 and 12. This bearing spring 22 lies flat on the base body 1 and has in its central part 2 upwardly bent, angular spring tabs 22a which enclose the armature from both sides and are welded to the armature at points 22b. Since the spring tabs 22a are largely cut free and are only connected to the base plate of the spring 22 via the narrow webs _' 22c, they permit a slight deflection when the armature is switched over. For fastening on the base body 1, the spring 22 has elongated holes 22d, into which thermally deformable fastening pins 23 which are integrally formed on the base body 1 engage. Due to the elongated holes, tolerance compensation of the spring 22 with the armature 27 is possible. Such tolerance compensation is necessary since the armature would be over-determined by the mutual contact on the yoke legs 4b, 5b, 4c, 5c and by the attachment via the spring 22.

Claims (15)

1. Polarized electromagnetic relay with two U-shaped yokes arranged parallel and at a distance from one another, which enclose at least one permanent magnet between them and whose central sections together form the core of a coil, an armature formed by an elongated ferromagnetic sheet metal and rotatably mounted in its center of gravity with its free ends each between the pair of parallel free legs - the yokes and forms a working air gap with each of these yoke legs - characterized in that the permanent magnet (6) between the middle sections (4a, 5a) of the two yokes (4, 5 ) is arranged and, together with them, to form a coil body (11) with insulating material, that the armature (7), which is also U-shaped in the opposite direction to the yokes (4, 5), with its side legs (7b, 7c) the coil winding ( 2) on the end faces overlapping between the free legs (4b, 5b, 4c, 5c) of the yokes (4, 5) The armature (7) is mounted on a base body (1) which covers the coil winding (2) in the form of an inverted trough and has openings (1d, 1e) in the area of the yoke legs (4b, 4c, 5b, 5c) and carries contact connection elements (3) anchored laterally from the coil (2). 2. Relay according to claim 1, characterized in that the permanent magnet (6) in its polarization direction between the two yokes (4, 5) corresponds to the sum of armature thickness and armature stroke. 3. Relay according to claim 1 or 2, characterized in that the surface sums of the respective diagonally opposite pole faces of the Anchor leg (7b, 7c) and the yoke leg (4b, 5b, 4c, 5c) are the same size. 4. Relay according to claim 1 or 2, characterized in that the area totals of the diagonally opposed pole faces of the armature legs (7b, 7c) and the yoke legs (4b, 5b, 4c, 5c) are of different sizes. 5. Relay according to claim 4, characterized in that separating plates (21) are provided on two diagonally opposite pole faces of the yokes (4, 5) and the armature (7). 6. Relay according to one of claims 1 to 5, characterized in that the armature (7) in its central region (7a) is provided with a casing (8) made of insulating material and by means of a bush (9) molded into the casing on a bearing journal ( 10) of the base body (1), wherein the central part (7a) of the armature (7) has a bend which surrounds the bushing (9) on one side. 7. Relay according to one of claims 1 to 5, characterized in that the yokes (4, 5) and the armature (7) are designed as three flat sheet metal parts. 8. Relay according to claim 7, characterized in that the armature (7) is mounted on the base body (1) by means of a bearing spring (22), the armature being attached to at least one laterally adjacent spring tab (22a) of the bearing spring. 9. Relay according to claim 8, characterized in that the bearing spring (22) on both sides of the armature (27) has bent, angled spring tabs (22a). 10. Relay according to claim 8 or 9, characterized in that the bearing spring (22) is fixed by means of elongated holes (22d) on deformable fastening pins (23) of the base body (1). 11. Relay according to one of claims 1 to 10, characterized in that on the coil body (11) in the region of the yoke legs (4b, 5b, 4c, 5c) in each case flanges (11a, 11b) with sealing surfaces (11c) resting on the base body (1) , 11d) are formed. 12. Relay according to one of claims 1 to 11, characterized in that in the coil body (11) coil terminal lugs (20) are embedded. 13. Relay according to one of claims 1 to 12, characterized in that the base body (1) with its openings (1d, 1e) bears closely against the yoke legs (4b, 4c, 5b, 5c) and with. its outer edge (1b) forms sealing surfaces with respect to a housing cap (12). 14. Relay according to claim 13, characterized in that. that the base body (1) and the housing cap (12) are connected by means of interlocking locking elements (16, 17). 15. Relay according to claim 13 or 14, characterized in that the housing cap all around has a base body (1) and the coil body (11) overlapping edge (12a) and that the open space (18) surrounded by this edge (12a) Cast resin is filled.

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