DE1265870B - Relay contact arrangement - Google Patents

Description

Relay Contact Arrangement The invention relates to a relay contact arrangement with fixed contacts and with a contact spring carrier that can be moved against spring force, the leaf springs with moving contacts holds, with the moving contacts in Closing direction are biased and stops provided on the contact spring carrier absorb the preload in the lifted state of the contacts. Such relays are mostly used as small electromagnetic relays for telecontrol, telecommunication and Telecommunications used for the reliable separation of different electrical circuits in electromechanical machine controls, for strengthening contacts in electrical Circuits as well as for the actuation of safety devices of electromechanical, electro-hydraulic, electro-pneumatic or other type.

The most frequently used relay types are round and flat relays. The disadvantage of these types lies in the design of their contact spring sets, since these Contact spring sets prevent shock and bounce-free work. The adjustment the numerous contacts of this known relay is very complex because of the construction the contact sets and a large number of individual parts for actuating the contacts with unavoidable tolerances is necessary. Furthermore, they are through the adjustment set contact pressures also as a result of the previous large Bending work not constant over time.

Another disadvantage of the known relay is that the contact springs the contacts can only be attached to the contact spring carrier in a complex process can. In most cases, the contact springs are pressed into the contact spring carrier or inserted into corresponding recesses of the same. In a known relay The contact pieces are of the type mentioned above by means of special helical springs biased. These coil springs are each in the middle of the contact pieces arranged, with the associated stops located on the contact carrier also located in the middle of the same, so that also in this known relay to a large extent undesired bounce vibrations and inaccurate contacts occur. In addition, the known relay is structurally and in terms of assembly due to the contact pressure ensuring coil springs expensive. In contrast, the invention is the The object of the invention is to design a relay of the type described above so that it is structurally simple and cheap to manufacture and assemble, with the adjustment of contact springs should largely be dispensed with due to the design of the relay. Farther a bounce-free and shock-free contact should be made by the relay, whereby the Contacts from the very first moment of contact with the required contact pressure should lie against each other. This is according to the invention in a relay with the initially mentioned features achieved in that the movable contacts on by deformation prestressed leaf springs are arranged and that the stops of the contact spring carrier are in the immediate vicinity of the contacts. A relay designed in this way can be keep structurally very small and has a very precise contact, since the movable Contacts already in the first moment of making contact with pre-tension on the fixed contacts so that an undesired creeping contact does not occur. By appropriate choice of preload, which corresponds to the contact pressure, for example can, the two contacts are immediately with the required when making contact Contact pressure on each other. Since the stops of the contact spring carrier are in the immediate Are close to the contacts, the leaf spring can in the rest position under spring force on them issue. If the movable contact is in its working position, i. H. in contact brought with the fixed contact assigned to it, its leaf spring is released in the first moment of contact from their stop, so that the movable contact rests against the fixed contact with the bias of the leaf spring. In the further course the movement of the contact spring carrier connected to the leaf springs becomes the leaf spring stretched even further by a small amount. This is the amount of pressure increase therefore low, because the spring characteristics of the pretensioned leaf springs in comparison runs very flat to non-prestressed leaf springs.

As a rule, the contact spring carrier is supported by the armature of a relay actuated. One advantage of the inventive design of the relay is that that the pressure force of the return spring acting as counter pressure to the armature pressure is kept small can be, although there is still a sufficient path of the contact springs that is sufficient to compensate for mechanical tolerances and contact wear. Same There is also an advantage in the transition to the working position and in the working position of the Relay noticeable. In this case, the flat characteristics result in the preloaded contact springs after closing the contacts only a slight increase in pressure. The anchor travel required is therefore significantly less than for such relays, the movable contact springs of which are not preloaded. As both on the normally closed contact side as well as on the normally open contact side there is enough path for the Contact spring carrier, so-called Mitgang, is available and during production of the contact spring carrier and when the fixed contacts are pressed into a base plate high mechanical accuracy without any special effort due to corresponding compression molds can achieve, it is not necessary to use the relay according to the invention or its contact springs to adjust.

In a further embodiment of the invention is on the opposite of the stop Side of the leaf spring and at a distance from this stop a support for the Leaf spring is provided on the insulating part. Through this design of the subject matter of the invention The contact sets of the relay can only be accessed by sliding them into the contact spring carrier are attached, where they are then held by their bias.

The leaf springs are advantageous towards the contact side, for example formed concave by a kink. This is used to pretension the leaf spring bent kink when inserted into the contact spring carrier then stretched out elastically again.

According to a further proposal according to the invention, electrical contacts that are not separated, for example in the case of changeover contacts, the supports omitted. The two leaf springs lying next to one another are useful in this case connected by a web which is guided in a recess of the insulating part is.

The invention is illustrated below with reference to the drawings Embodiments explained in more detail. It is shown in FIG. 1 the contact part a relay according to the invention in view, FIG. 2 an enlargement of a section the F i g. 1, Fig. 3 a single contact spring in the unloaded state, FIG. 4 shows a further exemplary embodiment in the view according to FIG. 2, fig. 5 a double contact spring according to FIG. 4 in the unloaded state, F i g. 6 is a view in the direction of arrow VI according to Fig. 4.

Like F i g. 1 shows, in a relay according to the invention, contact springs in the form of leaf springs 2, 2a with preload formed by inherent deformation are arranged on a contact spring carrier 1 designed as an insulating part and movable in the direction of arrow 16. The contacts 3 and 3a arranged at both ends of each contact spring 2 and 2a are assigned fixed contacts 8 and 8a, which are fastened, for example, in a base plate of the relay, not shown in detail. The contact spring carrier 1 can be displaced in guides 10 and 11 by means of corresponding sliders 12, 12 a, which are arranged at its front and rear ends in the direction of displacement arrow 16. The front slide 12 is in drive connection with an armature of the relay in a manner not shown, while a helical compression spring 13 placed around the slide 12a is arranged between the rear guide 11 and the contact spring carrier 1. Of course, the illustrated contact spring part can also be arranged in other contactors - for example in switches and the like - than in a relay.

Like F i g. 2 clearly shows, two contact springs 2, 2a designed as contact bridges are arranged next to one another on the contact spring carrier 1 in such a way that their contacts 3 and 3a face away from one another. In the rest position, the contact springs rest on stop surfaces 6 and 6a of the contact spring carrier 1, which are each on the side of the fixed contacts 8 and 8a assigned to the contact springs 2 and 2a and in the immediate vicinity of the contacts 3, 3a. In their central area, the two leaf springs 2, 2a, which are arranged next to one another, rest on a common support 14 of the contact spring carrier 1, which is located between the two springs 2, 2a. The leaf springs 2 or 2a have a shape according to FIG. 1 before being installed in the contact spring carrier 1. 3. In the case of the one shown in FIG. The embodiment of a contact spring shown in FIG. 3 is provided with a bend 15 in its central region, such that the leaf spring 2 encloses an obtuse angle on the side of its contacts 3. The contact springs 2 and 2a are installed in the contact spring carrier 1 in such a way that they are pretensioned. For this purpose, the stops 6 and 6 a and the supports 14 are arranged; that the leaf springs 2 and 2a can only be inserted into the contact spring carrier by stretching the bend 15. The stop surfaces 6 and 6 a are formed by cams 6 b on the contact spring carrier 1 designed as a plate, each of which has two stop surfaces 6 and 6 a .

If the contact spring carrier 1 is, for example, tightened by a Relay armature connected to it moved in the direction of arrow 16, the contacts touch 3 a in the course of this movement, the fixed contacts 8 a assigned to them. At the moment the first contact loosen the bias against the stop surfaces 6 a Leaf springs 2 a of these stop surfaces, so that the contacts 3 a with the bias on the fixed contacts 8 a. At the same time, the contacts 3 are released from the Fixed contacts 8 assigned to him in that the stop surfaces 6 of the contact spring carrier 1 apply to the leaf springs 2 connected to them and the contacts 3 in the further The course of this movement stand out from the fixed contacts 8.

Due to the inventive design of the contact spring part shown the contact is made suddenly and largely free of bumps and bounces. Farther an adjustment of the contact springs when assembling the contact spring part is not possible necessary there. the Kontaktei or 3a through the stop surfaces "6 and 6a in their exact location. Another advantage is that the spring characteristic of the pretensioned springs runs very flat, whereby the in the direction of arrow 16 on the contact spring carrier 1 acting control force and thus also the this counteracting pressure force of the helical spring 13 can be kept small.

The assembly of the contact springs 2, 2a is extremely simple, since this only attached by pretensioning and pushing into the contact spring carrier 1 can be.

In the case of the FIGS. 4 to 6 illustrated embodiments the contacts 3 ', 3 a' are designed as electrically non-separated contacts, as is the case, for example, with changeover contacts. The contact springs 2 ', 2a 'are formed in one piece and have for this purpose in their middle Area a common approximately U-shaped bent tab 4 as a support. the Tab 4 lies with contact springs 2 ', 2 a' built into the contact spring carrier 1 in a corresponding recess 5 of the contact spring carrier 1 and secures the contact springs 2 ', 2s' against lateral shifting. To avoid that the contact springs 2 ', 2 a 'fall in the vertical direction from the plate-shaped contact spring carrier can, noses 7 are provided on the cams 6 b ', which the contact springs 2', 2 a 'partially encompass.

Claims (10)

Claims: 1. Relay contact arrangement with fixed contacts and with a contact spring carrier which can be moved against spring force and which holds leaf springs with movable contacts, the movable contacts being preloaded in the closing direction and stops provided on the contact carrier absorb the preload when the contacts are lifted, characterized in that that the movable contacts (3, 3a) are arranged on leaf springs (2, 2a) pretensioned by their own deformation and that the stops (6, 6a) of the contact spring carrier (1) are in the immediate vicinity of the contacts (3, 3a) . 2. Contact arrangement according to claim 1, characterized characterized in that on the side of the leaf spring opposite the stop (6, 6a) (2 or 2 a) and at a distance from this stop (6, 6 a) a support (14) for the leaf spring is provided. 3. Contact arrangement according to claim 1 or 2, characterized characterized in that in each case two leaf springs (2, 2 a) with contacts facing away from one another (3, 3 a) have a common support (14). 4. Contact arrangement according to claim 3, characterized in that the support (14) forms a part with the insulating part (1) is formed. 5. Contact arrangement according to one of the preceding claims, characterized in that in the case of electrically non-separated contacts (3 ', 3 d), for example in the case of changeover contacts, the two springs (2', 2a ') are connected to one another by a web (4). 6. Contact arrangement according to claim 5, characterized in that the web (4) in a recess (5) of the insulating part (1) is performed. 7. Contact arrangement according to one of the preceding claims, characterized characterized in that the insulating part (1) is designed as a plate, on one of which Surface the stops in the form of two stop surfaces (6, 6a) each Cams (6 b) are provided. B. Contact arrangement according to one of the preceding Claims, characterized in that the cams (6 b) the leaf springs (2 ', 2 ä) in the area of the side opposite the plate with lugs (7) or the like. 9. Contact arrangement according to one of the preceding claims, characterized in that that the preload corresponds to the contact pressure required when making contact. 10. Contact arrangement according to one of the preceding claims, characterized in that the leaf springs (2, 2a, 2 ', 2a') are concave towards the contact side, for example by a bend (15). Publications considered: German Auslegeschrift No. 1166 895.