EP0252382A1 - Electrical switch - Google Patents

Abstract

An electrical switch, in particular an ignition starter switch for motor vehicles, is described which is designed for high switching currents. Rigid contact bridges (20), which are supported on a compression spring (22) that applies the contact closing pressure, are deflected via actuating cams (32) on a rotatable actuating member (31) and via plungers (35), the plungers being guided in a guide sleeve (36). a guide plate (37) are slidably guided parallel to the axis of rotation of the actuator. This guiding of the plunger is intended to prevent the forces acting on the plunger when the actuating member is rotated in the circumferential direction being transmitted to the movable contact bridges, which could lead to a displacement or tilting of the contact bridge.

Description

The invention relates to an electrical switch according to the features of the preamble of claim 1.

From DE-AS 1 908 799 an ignition starter switch for motor vehicles is already known, in which fixed contacts are fixed to a base plate and can be electrically conductively connected to one another via a movable contact bridge. These contact bridges are designed as leaf springs that generate the contact closing pressure. Such a switch is not suitable for switching currents greater than 50 A, because due to the thermal load occurring at such high currents, the resilient properties of the leaf springs deteriorate, which has a disadvantageous effect on the contact closing pressure and the contact resistance between the contacts.

The rotatable actuator in this switch according to DE-AS 1 908 799 carries actuating cams on the end face which act on a plunger which is fixed on one side to the contact bridge or the leaf spring and abuts the actuating cam with the other free end. When the actuator is rotated, forces act on this plunger in the circumferential direction, which are transmitted to the contact bridge because of the dimensionally stable connection between the plunger and the contact bridge, which can lead to a displacement and / or inclination of the contact bridge. This also affects the contact between the contact bridge and the fixed contact, which in turn can lead to increased contact resistance.

The present invention is therefore based on the object of improving the switch according to DE-AS 1 908 799 so that it can also be used to switch higher currents.

This object is achieved with the characterizing features of claim 1. The invention is essentially based on the idea that the lateral forces occurring when the actuator is rotated are not transmitted via the plunger to the contact bridge if this plunger is in a guide sleeve of a guide plate parallel to the axis of rotation of the actuator is guided. The rotary movement of the actuator is thus only converted into an adjustment movement parallel to the axis of rotation of the actuator. This prevents the contact bridge from tilting.

In a preferred embodiment, the plunger is designed as a separate part which is not connected to the contact bridge, because then, even if there is play between the plunger and guide sleeve after a long period of operation, transmission of the lateral forces when the actuating member rotates on the contact bridge is excluded.

The tappet should therefore act on the contact bridge with its one free end face, which is guided parallel to the axis of rotation of the actuating member via guide webs projecting from the base plate. For guiding the plunger and for guiding the contact bridge, independent means are provided, so that the adjustment direction of the contact bridge is not influenced even in the event of tolerance deviations with regard to the direction of the guide sleeve.

Since, in the case of a switch with these features, no forces deviating from the desired adjustment direction act on the contact bridge, according to a particularly preferred development of the invention, these contact bridges can be designed rigidly, the contact closing pressure being generated by an additional compression spring. In such an embodiment, the contact bridge can be optimized with regard to certain properties, for example low ohmic resistance and good heat dissipation, without having to take into account the required contact closing pressure, which is applied solely by the compression spring.

With an ignition starter switch, different consumers usually have to be connected to the same pole of a voltage source in different switching positions. This is solved in a structurally very simple manner with the features of claim 6. In this case, this fixed contact common to all contact bridges should in one piece have at least two contact lugs for connecting a power supply cable in each case. You can then use the power supply cables common in automotive engineering even with a heavily loaded switch and no special cable with an increased cross-section is required.

In such a switch with a plurality of contact bridges, each of which can be actuated by a plunger, all the guide sleeves for the individual plungers will be arranged along a straight line in the guide plate, because then the assigned actuating cams can be arranged on the actuating element on concentric circles with different radii and small switching angles can thus be realized . A compact switch design is also achieved.

• Fig. 1 einen Längsschnitt durch einen Schalter,
• Fig. 2 eine Ansicht auf die Grundplatte,
• Fig. 3 einen Schnitt durch den Schalter längs der Schnittlinie III-III in Fig. 2,
• Fig. 4 eine Ansicht auf die Führungsplatte,
• Fig. 5 einen Schnitt durch die Führungsplatte längs der Schnittlinie V-V in Fig. 4,
• Fig. 6 eine Ansicht des für alle Kontaktbrücken gemeinsamen Festkontaktes und
• Fig. 7 die Einhängung einer Kontaktbrücke in einen Festkontakt bei einer abgewandelten Ausführungsform.

The invention and its advantageous embodiments are explained in more detail below with reference to the exemplary embodiments shown in the drawing. Show it:

• 1 shows a longitudinal section through a switch,
• 2 is a view of the base plate,
• 3 shows a section through the switch along the section line III-III in FIG. 2,
• 4 is a view of the guide plate,
• 5 shows a section through the guide plate along the section line VV in FIG. 4,
• Fig. 6 is a view of the fixed contact common to all contact bridges and
• Fig. 7 the suspension of a contact bridge in a fixed contact in a modified embodiment.

A base plate 10 made of a temperature-resistant plastic carries a plurality of fixed contacts 11, 12, 13, 14 and 15, which are stamped from a board made of a suitable electrically conductive material. The fixed contacts 11 to 14 are formed at one end 16 as a contact lug for connecting a plug to a connecting cable and each carry a contact rivet 17 made of a noble metal at their other end. 6 has two contact lugs 16, 16 'for connecting a power supply cable, which are connected to the same pole of a voltage source. In this fixed contact 15, which is also punched out of a metal plate, a plurality of slots 18 are incorporated, in each of which one end of a rigid contact bridge 20 is suspended. At the other end, this rigid contact bridge 20 also carries a contact rivet 21, which cooperates with a contact rivet 17 on one of the fixed contacts 11, 12, 13 or 14. A coil pressure spring 22 is supported on the base plate 10 and generates the necessary contact closing pressure.

With the base plate 10, a switch housing 30 is locked, in which an actuator 31 is rotatably mounted. This rotatable actuating member 31 carries control cams or actuating cams 32 on the end face, which are arranged on concentric circles with different radii to the axis of rotation of the actuating member 31. These control cams or actuating cams 32 each interact with a tappet 35, which are guided in guide sleeves 36 of a guide plate 37 so as to be displaceable parallel to the axis of rotation of the actuating member 31. This guide plate 37 is fixed in a rotationally fixed manner within the switch housing 30. The tappets have a frustoconical tapered and rounded end 38 which cooperates with the actuating cams 32. On the opposite side, these plungers 35 have a mushroom-shaped extension 39, the free end face of which acts centrally on the associated contact bridge 20. Via this tappet 35, the associated contact bridge 20 can thus be deflected in a direction parallel to the axis of rotation of the actuating member 31 against the contact closing pressure of the compression spring 22. Since the plunger 35 is not connected to the contact bridge 20 and is guided over the major part of its axial length in the guide sleeve 36, forces which act on the plunger 35 when the actuating member 31 rotates in the circumferential direction cannot be transmitted to the contact bridge 20 will. This precludes a parallel displacement of the contact bridge or tilting of this contact bridge 20, so that perfect contact between the contact rivets 21 and 17 is ensured even after a long period of operation.

Each contact bridge 20 is guided on the one hand on the fixed contact 15 common to all contact bridges by hooking into the slot 18. At the opposite end near the associated fixed contact, the contact bridge 20 is also guided over guide webs 40 which protrude perpendicularly from the base plate 10, the distance between two guide webs 40 corresponding to the width B of the contact bridge 20. From FIG. 3 in particular it can be seen that the spiral compression spring 22 acts on the contact bridge 20 between the hanging point of the contact bridge 20 on the fixed contact 15 and the point of engagement of the plunger 35. Due to this arrangement of the spiral compression spring 22, a permanent current-conducting connection between the movable contact bridge 20 and the fixed contact 15 is ensured. When closing or opening a circuit, only the heavy-duty contact rivets 17 and 21 are stressed.

FIG. 2 shows that a plurality of contact bridges 20 are arranged in parallel next to one another, all of these contact bridges being hooked into the corresponding slots 18 of a common fixed contact 15.

Fig. 4 shows that a plurality of guide sleeves 36 are arranged in one piece on a guide plate 37 and along a straight line G. With this arrangement, a space-saving design is achieved, the actuating cams on the actuating member 31 being arranged on concentric circles, so that small switching angles can be achieved. With the chosen mirror-image arrangement of two guide sleeves on the left and right of a vertical central plane, two actuation cams are of course provided on the same circular path on the actuator. The use of only one guide plate for all plungers reduces the assembly effort and ensures the best possible parallel alignment of all plungers.

1 and 2 show in particular that two further fixed contacts 50 and 51 on the base plate 10 can be electrically conductively connected to one another via a roller-shaped contact web 52, this contact web 52 also being actuatable via a plunger 53. This plunger 53 is guided in a further guide sleeve 54 on the guide plate 37, which is in the opposite direction to the other guide sleeves 36 Guide plate 37 protrudes, as can be seen in particular from FIG. 5. The guide sleeve thus extends close to the associated contact bridge or contact web 52.

The following measures also contribute to improving the switching behavior or increasing the service life of this switch designed for high currents:

2 and 3 show that the fixed contact 15 common to all contact bridges 20 has an angled flange 60 which is used to enlarge the heat radiation area. In the embodiment according to FIGS. 2 and 3, this flange 60 also serves as a contact point for the movable contact bridges 20.

The contact plungers 35 are made of a material, preferably a plastic, with poor thermal conductivity properties but sufficient temperature resistance. This is to ensure that only small amounts of heat are transferred from the movable contact bridge 20 to the guide plate 37, which can consequently be manufactured from an inexpensive, less temperature-resistant material.

FIG. 7 shows another embodiment of the contacting of the contact bridge 20 with the fixed contact 15. The movable contact bridge 20 has an arcuate region 80 which pierces the slot 18 in the fixed contact 15. The movable contact bridge 20 is thus at two contact points, which are denoted by Z in the drawing, on the fixed contact 15, while in the embodiment according to FIGS. 1 to 6 there is only one contact point. This improves the current transfer at this transition point, which is not equipped with high-quality contacts.

In some versions of an ignition starter switch, a so-called buzzer contact is required, via which only low currents can be switched. For this purpose, a two-part actuating element 90 is provided axially in the rotatable actuating member 31, the two parts 91 and 92 being resilient are supported against each other. The actuating force introduced into the pot-shaped part 91 is thus transmitted via the compression spring 93 to the other part 92, which in turn presses a leaf spring 95 against a fixed contact 96 which is anchored in the base plate. When using such an inherently resilient actuating element, the contact pressure is largely independent of the actuating force. This principle could also be implemented in the known switch mentioned at the outset and independent protection is therefore claimed for the corresponding features.

Claims (15)

1. Electrical switch, in particular ignition starter switch for motor vehicles, with a base plate on which at least two fixed contacts are fixed in place, which can be electrically conductively connected to one another via a movable contact bridge, and with a rotatable actuating member which carries actuating cams on the end face which act on a plunger , over which the contact bridge can be deflected in a direction parallel to the axis of rotation of the actuating element counter to the contact closing pressure, characterized in that the plunger (35, 53) in a guide sleeve (36, 54) of a guide plate (37) parallel to the axis of rotation of the actuating element (31 ) is slidably guided. 2. Switch according to claim 1, characterized in that the plunger (35, 53) is guided as a separate part which is not connected to the contact bridge (20) in the guide sleeve (36, 54). 3. Switch according to claim 1 or 2, characterized in that the plunger (35) acts with its one free end face (39) on the contact bridge (20), which extends from the base plate (10) projecting guide webs (40) parallel to the axis of rotation of the actuator (31) is guided. 4. Switch according to at least one of the preceding claims, characterized in that the contact bridge (20) is rigid and is supported on a contact spring applying pressure spring (22). 5. Switch according to at least one of the preceding claims, characterized in that the contact bridge (20) is suspended at one end in an opening (18) of a fixed contact (15) and that the compression spring (22) between this suspension point and the point of application Tappet (35) acts on the contact bridge (20). 6. Switch according to at least one of the preceding claims, characterized in that a plurality of contact bridges (20) are arranged in parallel next to one another and these contact bridges (20) are contacted on one side with a single fixed contact (15) and on the other side in each case with one interact separate fixed contact (11,12,13,14). 7. Switch according to claim 6, characterized in that the fixed contact (15) common to several contact bridges (20) has in one piece at least two contact lugs (16, 16ʹ) for connecting a respective power supply cable. 8. Switch according to claim 6 or 7, characterized in that it has a preferably parallel to the contact bridges (20) angled flange (60) for several contact bridges (20) common fixed contact (15) to enlarge its heat radiation surface. 9. Switch according to at least one of the preceding claims, characterized in that the plunger (35, 53) for a plurality of contact bridges (20, 52) are each guided in a guide sleeve (36, 54) on a single guide plate (37). 10. Switch according to claim 9, characterized in that a plurality of guide sleeves (36) are arranged along a straight line (G) on the feed plate (37) and that each of the plungers guided in these feed sleeves on the actuating member (31) has corresponding actuating cams (32) on the end face. are assigned, which lie on concentric circular paths with different radii. 11. Switch according to at least one of the preceding claims, characterized in that the plungers (35, 53) are made of a heat-resistant, poorly heat-conducting material, in particular plastic. 12.Switch according to at least one of the preceding claims, characterized in that the guide sleeves (35, 54) on the guide plate (37) extend close to the associated contact bridge (20, 52). 13. Switch according to claim 12, characterized in that guide sleeves (36, 54) project from the guide plate (37) in the opposite direction. 14. Switch according to at least one of the preceding claims, characterized in that the contact bridge (20) has an arcuate region (80) penetrating the slot (18) in the fixed contact (15) and at two contact points (X) on the fixed contact (15 ) is present. 15. Switch in particular according to at least one of the preceding claims, characterized in that a two-part actuating element (90) for pressing a contact spring (95) against a fixed contact (96) is arranged axially displaceably in the rotatable actuating member (31), the two parts (91,92) are resiliently supported and guided.

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