DE3202579A1 - Relay with a bridge contact arrangement - Google Patents

Abstract

The bridge contact arrangement of the relay contains two elongated mating contact springs (11, 12) which are arranged with their longitudinal extent parallel to the base plane of a base body (1) but standing on end one above the other, and in addition a bridge contact spring (7) which is arranged parallel to the mating contact springs (11, 12) in the base body. The bridge contact spring (7) is connected to a bearing pin (22) and is supported via said pin in the base body (1). It is supported at its free ends on one side on an edge (21) of the base body (1) and on the other side on the operating slide (6). In consequence, it is provided with the maximum possible free spring length, which leads to a low relay power consumption. <IMAGE>

Description

Relay with bridge contact arrangement

The invention relates to a relay with a bridge contact arrangement with two in an insulating base body with their contact-making ends parallel arranged mating contact elements and with one on both mating contact elements connectable bridge contact piece, which is attached to a bridge contact spring mounted in the base body attached and by an anchor over a parallel to the base plane of the base body movable slide is operable.

Relays with bridge contact sets are usually used for switching high loads are used because of the double interruption via the bridge contact a particularly large effective contact distance between the two related Counter contact elements can be achieved.

Such relays, however, have so far mostly had a size that corresponds to theirs Installation in printed circuit boards or the like is not possible.

In known bridge contact relays, the mating contact elements are just like the bridge contact spring in the base body standing perpendicular to the base plane arranged. This results in either a large overall height of the relay, or the available spring travel is only short, so that in this latter case the power required for switching is relatively large. With a relay this Art (DE-OS 24 49 457) is the bridge contact spring with a bearing edge in the base body stored. In this case, additional measures must be taken to prevent the to hold movable contact elements and to apply the spring force for resetting.

The object of the invention is to provide a relay of the type mentioned at the beginning to be designed so that a high switching capacity with a long electrical life is achieved in a relay with a low overall height, with an optimal adaptation the resilient contact elements on the magnet system have a low power consumption is guaranteed.

According to the invention, this object is achieved in that the mating contact elements and the bridge contact spring each standing upright with its longitudinal extension in extend substantially parallel to the base plane of the base body and that the bridge contact spring is arranged freely bendable over its entire length, with which the bridge contact piece bearing flat side rests against a bearing pin standing vertically in the base body and opposite the bearing pin with one end at an edge of the base body and the other end is supported on the slide.

The inventive arrangement of the contact elements with their Longitudinal extension to the base plane achieves a relatively flat structure without this must lead to a short spring length. It is by the invention Storage of the bridge contact spring the greatest possible active spring length at the same time low strength stress achieved. The feather is not as usual with one End attached or clamped, but freely movable over its entire length and only supported at three points. To move the bridge contact spring to avoid, it is expediently firmly connected to the bearing pin, for example by spot welding; this bearing pin itself can be movably mounted in the base body be. In an expedient embodiment, this bearing pin is at about 2/3 the length of the bridge contact spring, calculated from the length of the bridge contact End, arranged.

The mating contact elements can also be designed as springs be biased with their contact-making ends opposite the bridge contact Seder and rest against a stop on the base body. These mating contact elements, possibly clamped in longitudinal grooves of the base body via rigid spring carriers be.

It can be useful that at least one of the mating contact elements embedded separately in an insulating carrier and with this in a longitudinal groove of the base body is attached. This means that particularly strict insulation requirements can be met to be met. For example, a material that is particularly resistant to tracking can be used for the carrier can be used if the base body itself does not consist of such Material.

In one embodiment of the invention, the two mating contact elements are anchored with their fastening ends offset from one another in the base body and the bridge contact spring arranged between them, wherein the first mating contact element extends essentially over its entire length next to the bridge contact spring, while the second mating contact element with a cranked middle part is the bridge contact spring crosses and lies with its free end over the first mating contact element.

The second mating contact element can be bent with its cranked one Central part to be supported on a nose of the base body. Due to the location of the support point the spring rate of this second mating contact element can be determined.

In another expedient embodiment, both are mating contact elements in one plane, possibly together with rigid spring supports, in an insulating material support embedded and attached to this in the base body. In this case, the insulating material carrier also a bearing bush for the bearing pin of the bridge contact feather own. In addition, a recess can be provided in which the bridge contact spring is movably arranged, while at its upper edge partially by an extension of the insulating material carrier is covered.

The invention is illustrated below on the basis of exemplary embodiments Drawing explained in more detail. 1 to 4 show a relay with a bridge contact arrangement in different views, Fig. 5 and 6 a modified embodiment of the before relay shown, Fig. 7 shows a modified embodiment of the contact arrangement In a relay according to FIG. 1, FIG. 8, a contact carrier from FIG. 7 is embedded Mating contact elements.

The relay according to FIGS. 1 to 4 has a base body 1, which with an attached cap 2 forms a housing.

A magnet system constructed in a conventional manner is located in the base body 1 constructed with a coil 3, a yoke 4 and an angular armature 5, the Transferring switching movements via a slide 6 to a bridge contact spring 7 will. This carries a bridge contact 8, which when the anchor is tightened the contact pieces 9 and 10 of the two mating contact springs 11 and 12 brought into contact will. These mating contact springs 11 and 12 are located with their free ends 11a and 12a one above the other and are biased against a stop 13 of the base body 1. the first mating contact spring 11 is attached to a spring support 14 and with this clamped together in a slot 15 of the base body 1. By twisting the The spring support 14 is held in the base body 1 in a form-fitting manner at the connection end 14a. In addition, a rib 16 is used for non-positive fastening of the spring carrier and Counter-contact spring in the base body slot 15. The second counter-contact spring 12 is attached to a spring support 17 and with this via the twisted Connection end 17a and the housing rib 18 anchored in a slot 19 of the base body. To with its free end 12a parallel to the free end 11a of the first mating contact spring to lie, the second mating contact spring 12 is bent in its middle part 12b and with this middle part crosses the bridge contact spring 7 below it. How results from the figures, so the first mating contact spring 11 is just like the bridge contact spring 7 arranged close to the bottom of the base body 1, while the second mating contact spring 12 is higher so that they cross the bridge contact spring and with its free end 12a over the free end 11a of the first mating contact spring can lie.

To ensure that the mating contact springs 11 and 12 are lifted differently To avoid their support 13, their respective spring rate must be the same. In order to achieve this, the mating contact spring 12 has its middle section 12b supported on a nose 20 of the base body. Thus, by the location of this nose 20 the spring rate of the substantially longer counter-contact spring 12 to that of the first mating contact spring 11 are adapted.

It is particularly important to adapt the force path characteristics of the Bridge contact spring 7 to the magnet system. When actuating the relay, the large one should Contact opening with an increase in the spring rate of the bridge contact spring that is as flat as possible be bridged. With the given space and given spring cross-section becomes the greatest possible active spring length with at the same time the lowest possible strength stress Achieved by mounting on columns with a cantilever and asymmetrical loading. The bridge contact spring 7 is accordingly not firmly clamped at either end, but with one end on an edge 21 of the base body and with its other end on Slide 6 supported. Opposite these supports is between the two the A bearing in the form of a bearing pin 22 is provided at the ends. This bearing pin 22 is connected to the bridge contact spring 7, for example by welding, and rotatably mounted in a corresponding recess 23 of the base body 1. When actuated the bridge contact spring 7 via the slide 6 can thus be compensated for in length the support points take place. The restoring force results from the assignment the support points 21 or 6a and the bearing pin 22.

The bridge contact spring 7 is in the longitudinal direction through the bearing point 23 of the bearing pin 22 secured in a form-fitting manner.

Slipping out of the bearing point is also prevented by a pin 24 of the cap 2 prevented (Fig. 4).

The magnet system is normally positively and non-positively in the base body attached. The frictional connection is achieved by a press fit over the ribs 25 of the base body 1 manufactured. In addition, the yoke tooth 26 is in a recess 27 of the base body glued in and thus attached in a form-fitting manner.

The actuating slide 6 is in a slot 28 of the base body 1 led. It is secured against falling out by molded teeth 29. The protective cap 2 finally is about locking teeth 30 and 31 of the base body, which in recesses 32 and 33 intervene, held non-positively and positively.

In FIGS. 5 and 6, a modification of FIGS. 1 and 3 is somewhat another embodiment of the relay described above is shown. The relay is with the base body, the magnet system and the interaction of the contact elements set up exactly as described above. Only the second mating contact spring 12 is not used directly in the base body 1, but in an insulating carrier 34 embedded, which in turn is then embedded in a recess 35 of the base body is inserted with a press fit. This insulating material carrier consists of a material resistant to tracking and has molded ribs 36. Together with a rib 37 formed on the base body 1, these ribs 36 result in a defined one Installation of the insulating material carrier 34 on the base body walls 38 and 39.

By embedding the mating contact spring 12 in the insulating material carrier 34 their spring rate is determined by the clamping plane 40, so that a support on a nose 20 as in Fig. 1 is not required. The insulating material carrier 34 has on its top a roof-shaped projection 41, which leads to the anchor 5 or to the Yoke 4 creates large insulation distances for the embedded mating contact spring 12. Due to the twisted connection 17a, the spring support 17 together with the insulating material support 34 fastened in a form-fitting manner in the base body 1.

In Fig. 7 a further embodiment is shown.

It is in the base body 51, like the previous embodiments is provided with a magnet system 4, 5 and an actuating slide 6, an insulating material carrier 52 attached, in which two mating contact springs 53 and 54 are embedded one above the other are.

They therefore run in contrast to the mating contact springs described above 11 and 12 parallel one above the other over their entire length. The insulating material carrier 52 also forms the receptacle and the counter bearing for the bridge contact spring 55 their bearing pin 56. The Brukkenkntaktfeder 55 is in a recess 57 between protruding walls 58 and 59 of the insulating material and arranged in this Recess around the bearing pin 56 is arranged to be rotatable. She is with her one end at the housing edge 60 and at its other end at the end 6a of the actuating slide 6 supported. The roof-shaped over the bridging contacts are breaking down Wall 59 of the insulating material carrier 52 has for the introduction of the bearing pin 56 in the bearing shell 61 has an inlet slot 62 with inlet bevels 63.

For non-positive fastening of the insulating support 52 in the base body 51 deformable ribs 64 are formed on the insulating support, through which the Insulating material carrier on the opposite wall 65 of the base body 51 is defined to be in contact is brought.

Fig. 8 shows the insulating support 52 in a side view the embedded mating contact springs 53 and 54. These are in the embedding area connected to spring supports 66 and 67, the ends 66a and 67a of which lead out downwards and are designed as connecting lugs. By twisting these ends 66a and 67a the insulating material carrier 52 can additionally be fastened in a form-fitting manner in the base body 51 will. An insulating extension 68 is also formed on the insulating support 52, which extends between the two mating contact springs 53 and 54 and for enlargement serves to isolate the two.

11 claims 8 figures

Claims (11)

Claims Relays with bridge contact arrangement with two in one insulating base body with their contact-making ends mating contact elements arranged in parallel as well as with a bridge contact piece that can be connected to both mating contact elements, which is attached to a bridge contact spring mounted in the base body and through an armature via a slide that can be moved parallel to the base plane of the base body can be actuated, that is, that the mating contact elements (11, 12; 53, 54) and the bridge contact spring (7; 55) each standing upright with their longitudinal extent extend essentially parallel to the base plane of the base body and that the back contacts (7; 55) are freely bendable over their entire length is arranged, with the flat side carrying the bridge contact piece (8) rests against a bearing pin (22; 56) standing vertically in the base body (1; 51) and one end opposite the bearing pin at an edge (21; 60) of the base body (1; 51) and is supported with the other end on the slide (6). 2. Relay according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the bridge contact spring (7; 55) is firmly connected to the bearing pin (12; 56) and that this is movably mounted in the base body (1; 51). 3. Relay according to claim 1 or 2, d a d u r c h g e -k e n n z e i c h n e t that the bearing pin (12; 56) at about 2/3 the length of the bridge contact spring (7; 55), calculated from the end carrying the bridge contact (8), is located. 4. Relay according to one of claims 1 to 3, d a d u r c h g e k e n n z e i n e t that the mating contact element elements (11, 12; 53, 54) designed as springs and with their contact-making ends (via, 12a) opposite the bridge contact spring (7; 55) are biased and on a stop (13) of the The base body (1; 51) are in contact. 5. Relay according to one of claims 1 to 4, d a d u r c h g e k e n n z e i c h n e t that the mating contact elements (11, 12) optionally over rigid spring supports (14, 17), clamped in longitudinal grooves (15, 19) of the base body (1) are. 6. Relay according to one of claims 1 to 5, d a d u r c h g e k e n n z e i c h n e t that at least one of the mating contact elements (12) in a Insulating carrier (34) embedded and with this in a longitudinal groove (35) of the base body (1) is attached. 7. Relay according to one of claims 1 to 6, d a d u r c h g e k e n n z e i c h n e t that the two mating contact elements (11, 12) with their fastening ends are anchored offset against each other in the base body (1) and the bridge contact spring (7) is arranged between these, wherein the first mating contact element (11) extends essentially over its entire length next to the bridge contact spring (7), while the second mating contact element (12) with a cranked middle part (12b) the bridge contact spring (7) crosses and with its free end (12a) above the first Counter contact element (11) is located. 8. Relay according to claim 7, d a d u r c h g e k e n n -z e i c h n e t that the second mating contact element (12) with its cranked middle part (12b) is supported on a nose (20) of the base body (1). 9. Relay according to one of claims 1 to 6, d a d u r c h g e k e n n z e i n e t that the two opposing clock elements (53, 54) in one plane, possibly together with rigid spring carriers (66, 67), in an insulating support (52) embedded and fastened with this in the base body (51) are. 10. Relay according to claim 9, d a d u r c h g e k e n n -z e i c h n e t that in the insulating support (52) a bearing bush (61) for the bearing pin (56) the bridge contact spring (55) is molded. 11. Relay according to claim 9 or 10, d a d u r c h g e -k e n n z e i c h n e t that the insulating material carrier (52) has a recess (57) for guidance the bridge contact spring (55).