DE2333484C3 - Electromagnetic relay - Google Patents

Description

The invention relates to a polarized electromagnetic relay with two flux guide parts lying opposite each other with the interposition of permanent magnets at a certain distance, with an excitation coil arranged between these fluO guide parts and an armature which actuates the movable contacts, protrudes through the inside of the excitation coil and can be pivoted in this so that each the two armature ends protruding beyond the two end flanges of the excitation coil rests in each case on one of the two flux guide parts in the two end positions of the armature and the armature thus magnetically connects the two flux guide parts in these positions.
Such a relay is already known (DT-AS

12 68 743). This relay consists of a relatively large number of and Complicated parts whose spatial allocation to one another is not very precise and therefore definitely requires considerable adjustment work so that the relay is cumbersome to assemble This relay requires a separate carrier plate, on which the contact springs are in separate work must be attached, and in a separate operation via connecting pieces with must be connected to the flow guide parts. Since these connecting pieces are made of thin sheet metal, which are also bent during assembly, is therefore not an exact alignment of the one to be actuated Given contact springs with the actuating elements attached to the armature ends, so that here considerable adjustment processes are necessary. Such an adjustment is also mechanical Influences that change the exact position of the carrier plate in relation to the pole pieces can easily be canceled out. Furthermore, not only the flow guide parts consist of only difficult bending operations Parts, but it is also difficult to assemble the entire relay, as the individual parts of nested on different sides and additionally welded when nested Need to become. So the two flow guide parts are about additional support parts and the intermediate parts Permanent magnets welded together in a lateral direction. Then the coil build up pushed down between the flow guide parts and welded from below to the flow guide parts. Then the flow guide parts are on the existing in separate, complicated operations with the Contact spring equipped carrier plate placed and welded to it. Such an assembly can can only be carried out by machine by means of a complicated and expensive device. Mainly causes but the support plate provided requires additional space.

It is the object of the present invention to develop such a relay in such a way that there is none separate carrier plate for the moving and fixed contacts is more required, so that the relay Easier to manufacture and, moreover, much more compact in overall structure.

Based on a relay of the type mentioned at the outset, this object is achieved in that the two Flow guide parts essentially have the shape of flat, square frames and with the large ones Side surfaces of this frame are facing each other that laterally at the anchor ends between the in each case superimposed legs of the flow guide frame extending arms are attached, the the moving contacts carry fixed contact springs from between the flux guide frames arranged spacers are held from insulating material and between each superimposed Legs of the flux guide frame extend in the direction of the two anchor ends, the Training and arrangement of the individual parts of the relay is made such that the external dimensions of the relay in the are essentially given by the outer edges of the two flux guide frames.

These external dimensions of the relay given by the outer edges of the flux guide frame possibly by the coil dimensions or by a casing laterally surrounding the flux guide frame be crossed, be exceeded, be passed.

In such a configuration of a relay, the carrier plate of the known relay is completely omitted, and there is also no need for the contact springs to be shaped and fastened separately on this base plate and the fastening elements for attaching the permanent magnets. Besides, all of them are Welding processes to connect the individual parts to one another are unnecessary. The individual elements of the Rather, relays can be sandwiched together in a simple manner, so that when his Assembly can be done in a simple manner so that first of all a flux guide frame on a horizontal surface is placed, then the coil body with the anchor located in it, the spacer body with the contact springs in between and the permanent magnets on this flux guide frame are placed and the second flux guide frame is placed over it. Both flow guide frames then only need to be held together by suitable means. This assembly is extremely simple and also results in a structure in which the position of all parts through the solid flow guide frame, which are kept at a certain distance by the permanent magnets in between will be determined. The flux guide frame and their fixed distance to each other determine namely the exact position of the bobbin and thus the rotating armature and the contacts of the Contact springs, so that the arms attached to the rotating armature ends over the bobbin, preferably consist of insulating material, already have an exact alignment to the contact springs in terms of structure. This spatial assignment or alignment of the individual parts is due to the flow control frame and the permanent magnets formed solid structure extremely safe and can also through external influences are not impaired.

According to a further embodiment, arms are attached to the side of the anchor ends, which the movable Wear contacts. Similar arrangements of the moving contacts are found in other relay designs known (FR-PS 14 38 558 and additional patent specification 90 112). There, however, the arms are against the stop surfaces the armature projecting projections attached, which leads to an increase in the relay dimensions leads. In addition, the contact surfaces of the movable contacts are opposite in the known arrangement movable to the armature, while here they are preferably rigidly connected to the armature. Through this a maximum lifting speed of the contacts from each other is achieved, since the contact surfaces are in move their entire area with the same acceleration as the rotating armature. This has a positive effect on the With regard to contact erosion, because of the high speed of the contact surfaces of the Moving contacts cannot easily develop a powerful and longer-lasting spark. At the same time, however, due to the rigid arrangement of the contact surfaces of the movable contacts, the The relay's tendency to bounce is significantly reduced, since the contact surfaces are rigid with the mass of the Armature are connected, which in interaction with the magnetic forces is not a vibratory structure represents sufficient quality.

Although, in principle, the spacers can be provided at different points, FIG advantageously provided that the spacers between the superimposed Flußführungunss-

frame are arranged in the area of the corners of the frame. This results in a particularly compact design and an extremely favorable storage for the fixed contact springs.

Another advantageous embodiment is that on the flanges of the excitation coil body formed projections between the legs of the superimposed flow guide frame - the Position-securing excitation coil - intervene. In this way, the bobbin is in a simple manner sandwiched assembly of the relay stationary with respect to the flux guide frame, so that also the rotating armature mounted in the bobbin one with respect to its stop surfaces on the Flußführungsteilen receives fixed storage.

Another advantageous embodiment provides that the spacers and the bobbin are formed from elastically resilient insulating material. on this simple way is despite manufacturing tolerances that always occur, especially during manufacture the spacer, the contact springs and the coil body, ensured that the distance of the Flußführungsteile is exact and only from the permanent magnets or the permanent magnets and magnetically conductive spacers is determined.

The two flow guidance frames can in principle be held together by any suitable means will. It is particularly useful, however, to fix all the individual parts of the relay in the corners of the Provide flux guide frame and the spacer penetrating rivets. Thus, a total of only four connections at the corners of the flux guide parts are required for the overall integrity of the relay. At the same time, the contact springs and the spacers, but also the coil form, are well in their location recorded. Until the rivet is inserted, all individual parts of the relay can be in be layered on top of each other in a sandwich-like manner, in which case all parts are finally fixed by the rivets will.

Another useful embodiment provides that at least one of the spacers of each contact spring arrangement one in the area of the spacer that covers the adjacent flux guide frame on the outside and is therefore electrical at this point having insulating extension. This extension can also act as an anti-twist device for the spacer body and the springs clamped in therewith serve and above all prevents a, for example, of a contact spring downwardly guided solder connection in electrical contact with the corresponding flux guide part comes.

The storage of the contact springs at the corners of the relay between the spacers enables two contact springs with their contact surfaces facing each other to have the same contours and the two contact springs at their clamped ends either extending in the direction of the contact springs or angled at 90 °, the electrical connection of the contact springs have serving narrow extensions. Since in this way the extensions of the contact springs always have only a small part of their width, the extensions with mutually facing contact surfaces of two springs always have a lateral distance from one another, which ensures the trouble-free establishment of an electrical connection. If two contact springs with their contact surfaces facing each other are provided at each corner of the relay , then all springs mounted at the corners have the same contours, so that only a few different parts are advantageously required for a sandwich construction. If more than two contact springs with their contact surfaces facing each other are required at the corners, the extensions can be attached at right angles to the longitudinal edge of the contact springs, so that

ίο then on another side surface of the relay are feasible.

Another embodiment provides that the arms arranged on the rotating armature are movable Contacts are designed as surface contacts. The movable ones are expediently in this case Contacts via flexible connecting pieces in conductive connection with the connection points of the Relay to the outside. This not only creates a simple conductive connection with the movable ones Contacts created, these themselves are also more easily than attached to the arms Contact surfaces formed, resulting in a particularly rigid connection of the movable contacts with the Anchor and the resulting advantages already mentioned.

The rotary armature can normally be pivoted about a fixed axis of rotation within the excitation coil. Due to the completely symmetrical structure of the entire relay, however, there is also the possibility that the rotary armature is inserted into the coil body without a fixed bearing of its axis of rotation. In this way, complex devices for mounting the rotating armature axis can be avoided if necessary. With safety hcitsrclais, so those relays where a Signalsequenzkon must be given tact safety, however, a storage of the axis of rotation of the armature is essential. In such a case it is necessary for the anchor to move under the influence of an external excitation; not moved or not moved so far that the egg closes contacts which it should actually close in terms of excitation if one of the previously closed contacts is welded due to overload. This prevents the axle bearing of the armature, but only if the welded contact does not follow the new armature movement. In order to achieve this without additional effort, one of the spacers can protrude between two contact springs arranged one above the other and be designed in such a way that it has a connection close to its free end for each of the contact springs. In this way, each contact spring can be tensioned in the direction of the flux guide parts when the associated contacts are closed, in order somil to generate the necessary contact pressure; but if the contact is welded and the armature wants to switch again, the spring welded to the corresponding contact surface provided on the arm attached to the arm can only be bi; be taken to the stop . At this moment, any further armature movement is blocked if its axis is supported sufficiently free of play. Thus, the non-welded contact surfaces cannot come into contact with their mating contacts and thus no previously open contacts can be closed.

All electrical connections - including those for the excitation coil - can be routed between the two flux guide frames up to the side edge of the de!

Relay. Because of the parallel flow guide frames and anyway This is easily possible with the contact springs mounted in the corners of the spacers. By this way that Leading out electrical connections, which is particularly important for small relays, becomes a The largest possible distance between the electrical connections is achieved. Those facing away from the swivel anchor The ends of the contact springs can be placed laterally in a simple manner in order to form soldered or plug-in connections be bent down on the relay or they can be directly on the side of the relay contact elements for the form the electrical connection of the relay.

At least one of the spacers of each contact spring arrangement can be made with a one-part or multi-part, be connected to the frame laterally surrounding casing. This way it becomes an easy one Receive lateral encapsulation of the relay, which seals it off dust-tight or hermetically, depending on the version. The sheathing can be made in one piece with the spacers, for example by injection molding getting produced. The middle spacer body is preferably with the casing connected. However, the remaining spacers can also be molded in one piece, by being connected, for example, to the middle spacer body by thin webs which, when Contraction are deformed so that the contact springs are held in place. With the sandwich-like Mounting the relay is the sheathing in a simple manner together with the spacers assembled.

This wrapping offers another advantage. Especially with small relays with special many contact and coil connections to accommodate all of these on the outer circumference of the relay, what is mandatory for a printed circuit board version, or if there are fewer connections, a certain selection where you want to lead the connections, and thus a constructive relief too obtained, namely the casing can be provided with grooves, each of which by a half Grid dimensions offset from one another base areas, the electrical connections are provided. The connections are therefore always set forward and backward in comparison to each other. This allows about twice as many Place connection options on the outer circumference of the relay, as this without the provision of Grooves in the casing would be possible. The base areas are expediently perpendicular extending grooves offset from one another by half a grid.

For simple encapsulation of the relay, the openings on the outside are expediently large side surfaces of the flux guide frame and / or the side surfaces of the relay between the superimposed flow guide frames sealed with foils. Because through the two flow guide frames a stable structure that limits the relay on all sides is formed in this way can be extremely beneficial simple and reliable encapsulation of the relay can be made. The foils can be made Plastic or metal are made and are ideally suited for printing

An embodiment of the invention is shown below Explained in more detail with reference to the drawings In the drawings shows

F i g. 1 is a perspective view of a relay designed according to the invention, parts of the Relay shown cut or broken away for the purpose of better visualization of the relay structure are and

Fig. 2 is a perspective view of a part an embodiment which is somewhat different from FIG. 1.

In Fig. 1, 1 and 2 are two contoured, rectangular FlußfUhrungsrahmen designated, zwisehen which on opposite sides each have a permanent magnet and a magnetically conductive spacer is arranged, with only one permanent magnet 3 and one intermediate piece 4 in the drawing are visible. These permanent magnets and intermediate

Ij pieces are precisely ground and determine the Distance between the two flow guide frames 1 and 2 from each other. In the area between the openings the flux guide frame 1 and 2, a coil body 6 carrying an excitation coil 5 is arranged in

which a rotating anchor 7 by means of its axis of rotation 8 and in the bobbin latched plastic disks 9 is pivotably mounted so that its ends each can come into contact with diagonally opposite legs of the flow guide frame.

At each end of the rotating armature 7 two insulating arms 10 and 11 are attached laterally, the can for example consist of plastic and provided by means of one in each at the anchor end Slot 12 inserted magnetizable rod 13 are attached. Each of these arms 10 and 11 has its top and bottom each have a movable contact 14 and 15 in the form of a Contact surface, which is thus moved with the rotating armature 7 and represents a loose contact.

Each of the movable contacts 14 and 15 is a contact surface of a roller contact 16 a Contact spring 17 or 18 opposite. These contact springs are each accommodated between at the corners Spacers 19, 20 and 21 stored. The flow guide frames 1 and 2 and those at all Spacers 19, 20 and 21 located at corners with the associated contact springs 17 and 18 by a rivet 22 provided at each corner of the relay is compressed and held. The spacers 19, 20 and 21 as well as the contact springs 17 and 18 and the flux guide frames 1 and 2 do not have all shown recesses and projections through which a rotation lock of the contact springs and the spacer is guaranteed. Such a projection can, for example, consist of that on the spacer body 19 provided angled extension 23 exist, which is in a corresponding recess of the Flux guide frame 1 engages and at the same time provides insulation from the flux guide frame 1 represents along the extensions 24 of the contact springs 17 and 18, optionally shown in dashed lines can be guided below. A similar, upwardly angled end can also be used for isolation from the other the flow guide frame 2 on the spacer body 21 may be provided. The contact springs 17 and 18 are with the same contours. Since they are arranged with their contacts 16 facing one another, this results in that the extensions 24 are laterally spaced from one another.

The fixed connection of the FlußfUhrungsrahmen mitteis the rivet 22 is at the same time the The coil body 6 is held in its fixed position within the relay, since there are projections provided on it

such as the projection 34 shown of the coil flange between the flux guide frame. On this projection 34 is at the same time an electrical connection 35 for the excitation coil 5 attached and laterally outwards. '

As can be seen, each of the movable contacts 14 and 15 is provided with a long, longitudinally of the Rotary armature lying and serving as a power supply, soft, flexible connecting piece 25 in Connected in the form of a soft spring, which via the respective associated spacer body 20 to the outside is led to the edge of the relay. In addition, there are two permanent magnets on each of the arms 10 and 11, respectively 26 and 27 attached, each having a flow component in the direction of the contact surfaces 14 and generate 15. This Fiußkomponenie has the effect that, for example, between the contact surface 15 and the roller contact 16 resulting sparks a force in the direction of the longitudinal extension of the roller contact 16 is exercised so that the spark is driven in the longitudinal direction of the roller contact.

In the illustrated embodiment, the ends of the contact springs 17 and 18 and the connecting pieces 25 each designed so that electrical connections 28 are created at the spacers 20 of the corners. These can be in contact with springs 29 of a plug connection 30 into which the entire relay can be inserted isi. The springs 29 have downwardly pointing soldering pins 31 which, for example, are soldered onto a card can be. The connector 30 consists of a frame in which on two opposite Pages recesses 32 are provided through which the relay on at least one of its Flußführungsteile can be taken for pulling out.

The contact surfaces of the movable contacts 14 and 15 are firmly seated on the armature. So it lies - there the Connecting pieces 25 hardly have a spring force - essentially an oscillation structure before that through the large anchor mass and the magnetic force is marked. At the moment the Contacts, the anchor inertia is so great that it continues unperturbed. Are bounce vibrations not possible at this point. When the anchor hits the flux guide frame 1 or 2 or on one The separating plate 33 provided there, the magnetic forces are very great; the anchor does not bounce back; possible, because here, too, an air cushion partially absorbs the anchor energy. A small bounce back of the anchor would Incidentally, do not have any effect because the elasticity of the spring 17 or 18 absorbs this.

The spacers 20 are designed by means of stops 36 and 37 provided on them so that they prevent the contact springs 17 and 18 from following the movable contacts 14 and 15 in the opening direction, which is required not only for safety relays, but also for a perfect fast Picking up the contacts is useful

In the example shown, it is provided that the rotating armature 7 is mounted on its axis of rotation 8. However, since the relay is completely symmetrical with respect to the axis of rotation 8 and the longitudinal axis of the armature, so that the distribution of the movable masses and the magnetic forces is also completely symmetrical, the rotating armature does not need to be supported if signal sequence contact reliability is not required Rotary armature 7 then nevertheless retains its prescribed position within the bobbin 6. The rotary armature can additionally be guided through the connecting pieces 25.

The connecting pieces 25, which are designed as springs, can, due to the space available between the flux guide frames due to the relay construction, be designed in such a way that, despite being thick enough for large switching currents (as a feed to the movable contacts 14 and 15), bending and torsion are used have a low spring constant, which is of particular importance with regard to high contact forces and optimal design of the relay. Their ends can either be led out as connections 28 through a spacer or laterally in the area of the magnet system.

The embodiment shown in the drawing clearly shows that a simple encapsulation of the Relay is possible by, for example, on the openings of the flux guide frame 1 and 2 and laterally, the two flux guide frames 1 and 2 overlapping. Foils are glued. These slides can vary depending on desired quality of the encapsulation of the relay made of plastic or metal. Such Metal foils could, for example, be welded on in a hermetically sealed manner.

In FIG. 2, part of a casing 38 is shown, which is connected to the central spacer bodies 20 and the stops 36 and 37 is made in one piece. The spacers 19 and 21 are also the same molded onto the spacer body 20 by being connected to it by thin lateral webs. This casing 38 is assembled together with the spacers when the relay is assembled and thus encloses the relay laterally, so that the distance between the yokes 1 and 2 is covered laterally will. The relay is thus encapsulated at the side at least in a dust-tight manner. The sheath 38 can consist of several parts, for example of two parts according to the method shown in FIG. 2 consist of the part shown or be made from a single piece.

On the outer circumference, the casing 38 is provided with grooves 39 and 40, the base areas of which are offset from one another by half a grid dimension and which carry the electrical connections 28 for the contact springs and the coil connections. In this way it is possible to accommodate a particularly large number of contact and coil connections on the outer circumference of the relay without insulation difficulties occurring. These connections can consist of downwardly bent soldering lugs or simple connections that interact with the springs 29 of the plug connection 30. In the latter case, of course, the tongues 29 are designed in such a way that their shape corresponds to the depth of the grooves 39 and 40. To produce the connections 28, slots 41 are provided in the casing 38, into which the extensions 24 of the contact springs or corresponding lines of the coil connections are inserted . In the case of a hermetic encapsulation, these slots can easily be closed even further afterwards. In addition, it can be seen that this casing is firmly connected to the flux guide frame in a simple manner by connecting these flux guide frames at their corner points by means of rivets 22 or the like, while at the same time the contact springs are held in their new position by slots in the casing and the rivets will.

For this purpose 2 sheets of drawings

Claims (15)

Patent claims: 1. Polarized electromagnetic relay with two interposed permanent magnets at a certain distance opposite flux guide parts, with an between these flux guide parts arranged excitation coil and an actuating the movable contacts, the interior of the excitation coil protruding and in this armature pivotable in such a way that each of the two armature ends protruding beyond the two end flanges of the excitation coil into the both end positions of the anchor rests against one of the two flux guide parts and the anchor thus in these positions the two flux guide parts each magnetically connects, thereby characterized in that the two flow guide parts (I, 2) are substantially flatter in shape have a square frame and with the large side surfaces of these frames facing each other are that laterally at the anchor ends between the superimposed legs of the Flux guide frame (1, 2) extending arms (10, 11) are attached to the movable Koniakte (14, 15) that fixed contact springs (17, 18) from between the flux guide frame (1, 2) arranged spacer bodies (19, 20, 21) made of insulating material are held and between each superimposed legs of the flux guide frame (1,2) in the direction of the two anchor ends extend towards, wherein the design and arrangement of the individual parts of the relay is made in such a way that the outer dimensions of the relay are essentially due to the outer edges of the two flow control frames (1,2) are given. 2. Relay according to claim 1, characterized in that the spacers (19, 20, 21) between the superimposed flux guide frame (1, 2) arranged in the area of the corners of the frame are. 3. Relay according to claim 1 or 2, characterized in that on the flanges of the excitation coil body (6) formed projections (34) between the legs of the superimposed Flux guide frame (1, 2) - to secure the excitation coil (5) in position - engage. 4. Relay according to one of claims 1 to 3, characterized in that the spacer body (19, 20, 21) and the coil body (6) are formed from elastically flexible insulating material. 5. Relay according to one of claims 1 to 4, characterized in that for fixing all Individual parts of the relay the corners of the flux guide frame (1, 2) and the spacers (19, 20, 21) penetrating rivets (22) are provided. 6. Relay according to one of claims 1 to 5, characterized in that at least one of the Spacer bodies (19, 20, 21) of each contact spring arrangement in one in the region of the spacer bodies (19, 20, 21) the adjacent flux guide frame (1, 2) covering the outside and thus on this Has point electrically insulating extension (23). 7. Relay according to one of claims 1 to 6, characterized in that always two with their Contact springs (17, 18) facing each other are contours of the same shape and the two Contact springs at their clamped ends either extend in the direction of the contact springs or narrow ones, angled by 90 °, for the electrical connection of the contact springs Have extensions (24). 8. Relay according to one of claims 1 to 7, characterized in that the on the on. Rotating anchor (7) attached arms (10, 11) arranged movable contacts (14, 15) are designed as surface contacts. ίο 9. Relay according to one of claims 1 to 8, characterized in that the movable contacts (14, 15) have flexible connecting pieces (25) are in conductive connection with the connection points of the relay to the outside. '5 10. Relay according to one of claims 1 to 9, characterized in that one of the spacer bodies (20) is in each case between two one above the other arranged contact springs (17, 18) protrudes and is designed such that it is for each of the Contact springs has a stop (36, 37) located close to their free end. 11. Relay according to one of claims I to 10, characterized in that all electrical connections (28) - including those for the excitation coil (5) - Between the two flux guide frames (1, 2) through to the side edge of the relay are led. 12. Relay according to one of claims 1 to 11, characterized in that at least one of the spacer bodies (19, 20, 21) of each contact spring arrangement with a one-part or multi-part casing laterally surrounding the frame (1, 2) (38) is connected. 13. Relay according to claim 12, characterized in that that the casing (38) with grooves (39, 40) is provided, on whose mutually offset base surfaces the electrical connections (28) are provided. 14. Relay according to claim 13, characterized in that the bases of the perpendicular extending grooves (39, 40) are each offset from one another by half a grid. 15. Relay according to one of the preceding claims, characterized in that the after outer openings of the large side surfaces of the flow guide frame (1, 2) and / or the Side surfaces of the relay between the superimposed flux guide frame (1, 2) with Foils are closed.