DE4102992C1 - Snap-action switch - has contact carriers and coil springs located against projections in housing and displaced by contact frame - Google Patents

Abstract

The electrical switch has a main housing (1) with an actuator pin (23) inserted through a top aperture to engage with a moving part (19) that retains snap-action spring elements (28,29). A carrier (7) for fixed contact pairs (7a,7b) is secured to a cover (17). The movable contact carriers (2,3) each have a coil spring (4,5) and are located at the rear of the housing and locate against projections (8,9). The carriers are displaced by the contact frame (10). ADVANTAGE - Contact arrangement avoids contact bounce.

Description

Switchgear with jumping behavior, consisting of egg housing with a swivel-mounted housing cover, an actuator that on switching insert works, two fixed contacts and two springy gela Contact bridges, with the switch insert off a switching plunger consists of a contact frame is surrounded by the switching plunger in axial direction under the action of the actuation element is movable and the contact frame under the effect of two on the contact frame and on Switch plunger supporting springs from one stable position snapped into a second and that Contact system operated.

The switching mechanism of known jump or Snap switch is based on the effect of Spring springs between the housing wall and movable switching plunger are arranged. Passes through the switching plunger the horizontal zero position of the Springs, these reverse their force effect and accelerate the switching plunger and the with the Switch plunger mechanically connected switching bridge.

DE-OS 29 43 415 describes such Snap switch, with two fixed contacts and at least one contact between one Position in which he is against the fixed contacts is pressed and is movable to an open position, the moving contact on a Actuating shaft is attached, which in the Switch housing can be moved and with this via a  Dead center exceeding device is connected, of the springs, which has one end in the Switch housing attached and with its other end in a displaceable on the operating shaft Slider are attached.

DE-OS 28 17 815 describes another Snap switch with one over a plunger actuated contact bridge. Here are two Snap springs between the plunger and the Contact bridge arranged which is exceeded a deadlock the contact bridge relative and move in opposite directions to the plunger.

Another electric snap switch type mentioned in DE-OS 31 15 339 specified. The switch has an actuator on the while the switch is pressed Line of action of a spring changed so that the movable contact element with a snap movement moved away from the fixed contact element.

The jump or snap switches mentioned have a mechanical coupling between the switching plunger and Contact bridge, which has the disadvantage that relatively large bruises occur. The assembly of the switch elements at This known switch is assembled complicated and time-consuming.

The invention has for its object a Jump switches of the type mentioned at the beginning improve that bounce behavior between the moving contacts and fixed contacts at the contact tacting is largely avoided and also easy and quick installation of all switches elements is made possible.  

According to the invention, this object is achieved by that the housing has supports in which the Contact bridges and those attached to the contact bridges set compression springs, the switch insert and the fixed contacts are positively stored and centered are and that all the elements in the housing are arranged in layers one above the other, with in the two possible switch position end positions a me mechanical decoupling of the contact frame from the Contact bridge of the closed contact occurs, by the areas of the driver from the contact take off by a approach path.

Further advantageous embodiments of the invention are characterized in subclaims 2 to 6.

According to the invention, the contact bridges are mecha nisch connected with compression springs in the supports of the housing and the first contact bridge against the contact surfaces of a first fixed contact presses and the second contact bridge against the surface s of the driver molded onto the contact frame presses.

The main advantages are that every festival Contact is formed so that it with the An Locking device for flat cable line one piece kiges element forms and that the fixed contacts Grasp the contact frame and in the on the housing wall supports are stored, whereby the fixed contacts in every switching phase of the Switch insert are mechanically decoupled.

Finally, it is advantageous to have a device is arranged in the housing cover such that them for the flat cable as strain relief works.

The invention is based on an embodiment Example of the snap switch according to the invention Explanation with the aid of the drawing be recognized.

In the drawing shows

Fig. 1 is an exploded view of the jump scarf ters,

Fig. 2 is a sectional view of the leap switch,

Fig. 2a shows an enlarged detail of Fig. 2 to illustrate the mechanical decoupling of the contact frame of the contact bridge,

Fig. 3 is a perspective view of the switch insert and

Fig. 4 is a perspective view of the fixed contact with the integrated connection device for ribbon cables.

Fig. 1 shows an exploded view of the switching device with Sprungver hold. The switching elements which can be mounted in layers in the housing 1 are the first contact bridge 2 , the second contact bridge 3 with their compression springs 4 , 5 , the switching insert 19 , the first fixed contact 6 and the second fixed contact 7 . In the illustrated Rei henfolge is also the assembly of the Schaltelemen te, although initially the switch insert 19 c by the angled contact arms 6, 6 d, 7 c, 7 d of the fixed contacts 6, is performed. 7 The ends 4 a, 5 a of the compression springs 4 , 5 engage in the housing support 8 and in the housing support 8 a, which is not visible in FIG. 1, a. The fixed contacts 6 , 7 are inserted into the support 15 , 16 and the opposite supports of the housing wall not visible in FIG. 1, the switch insert 19 resting on the support 17 and inevitably getting into its correct position. In the assembled state, the contact bridge 2 contacts the contact surfaces 7 a, 7 b of the second fixed contact 7 . The driver mer 11 , 11 a of the contact frame 10 presses against the spring force of the compression spring 5 and keeps the make contact (contact bridge 3 and fixed contact 6 ) geöff net. The contact frame 10 is non-contact by the contact arms 7 c, 7 d, 6 c, 6 d of the fixed contacts 6 , 7 . The actuating element 23 is inserted through the guide 25 into the housing 1 and engages mechanically in the adapter device 14 of the drive tappet 26th If the actuating element 23 is actuated, the drive plunger 26 performs an axial movement. The springs 28 , 29 move into the horizontal position, which is reached at the zero point of the switching process. Immediately after passing this zero point, the spring force of the springs 28 , 29 acts and accelerates the contact frame 10 in the opposite direction to the drive plunger 26 . The normally closed contact (contact bridge 2 and fixed contact 7 ) only opens when the zero point of the springs 28 , 29 is passed because only at this point in time the driver 11 , 11 a acts on the contact bridge 2 and this by the spring force of the springs 28 , 29 acts against the force of the compression spring 4 , accelerates opens. By this acceleration of the contact frame 10 , the normally open contact closes suddenly and the driver 11 , 11 a of the contact frame mechanically detaches from the contact bridge 3 of the closed normally open contact. The path of the contact frame 10 is always longer in a switching operation by the approach path x than the distance covered by the contact bridge 2 , 3 from the open end position of the make or break contact to the closed end position.

In Fig. 2 is a sectional view of the switching device with jumping behavior Darge provides. The switchgear is in the rest position. A return spring 27 holds the actuating element 23 in the rest position. The contact frame 10 is due to its snap mechanism in a stable position and has the contact bridge 3 against the spring force of the compression spring 5 from the fixed contact 6 ( not visible here) by means of its driver 11 . By the action of force in the axial direction on the actuating element 23, the snap mechanism of the contact frame 10 acts, which then moves suddenly in the opposite direction. The driver 11 bumps after the approach path X on the contact bridge 2 and lifts it against the spring force of the compression spring 4 from the fixed contact 7 . The contact bridge 3 makes contact with the fixed contact 6 and the driver 11 separates from the contact bridge 3 by the approach path X.

In Fig. 2 is also clarified that the pressure piece 21 of the housing cover 24 during the closing process of the housing cover 24 with appropriate introduction of the ribbon cable 30 , the contacting in the connecting device 20 of the one-piece fixed contacts 6 , 7 causes. The device 22 in the housing cover 24 provides strain relief for the connected flat ribbon cable 30 .

FIG. 2a shows an enlarged detail of FIG. 2 to illustrate the mechanical decoupling of the contact frame from the contact bridge.

Here, the mechanical decoupling is made clear, which is achieved by the approach path x between the contact frame 10 and the closed contact 7 .

FIG. 3 shows a perspective view of the switching insert 19. This illustration shows the side facing the bottom of the housing 1 . The switching insert 19 consists of a contact frame 10 , a switching plunger 26 and the springs 28 , 29th The principle of action of the springs 28 , 29 supported by the contact frame 10 and the switching plunger 26 is known and will not be explained in more detail here. In the adapter 14 of the switching plunger 26, the actuating element 23 engages. The balcony-like projections 11 , 11 a are formed directly on the contact frame. With their surfaces 12 , 13 and 12 a, 13 a, they grip switching bridges 2 and 3 during the switching process.

Fig. 4 shows a perspective view of the fixed contact with the integrated Anschlussvorrich device for ribbon cables. The contact arms 7 c, 7 d and 6 c, 6 d are angled in such a way that they grip the contact frame 10 of the switch insert in a non-contacting manner in the mounted state. The contact arms 7 c, 7 d and 6 c, 6 d in the supports from 15 , 16 of the opposing walls of the housing 1 . The connection device 20 for ribbon cable is integrated in the fixed contact piece 6 , 7 , the elements being designed as a one-piece injection molded part.

Claims (6)

1.Switching device with jumping behavior, consisting of a housing with a swivel-mounted housing cover, an actuating element that acts on a switching insert, two fixed contacts and two spring-loaded contact bridges, the switching insert consisting of a switching plunger which is surrounded by a contact frame through which the switching plunger is movable in the axial direction under the action of the actuating element and the contact frame engages under the action of two springs supported on the contact frame and on the switching plunger from a stable position into a second and actuates the contact system, characterized in that the housing ( 1 ) Has supports ( 8 , 8 a, 9 , 15 , 16 , 17 ) in which the contact bridges ( 2 , 3 ) and the compression springs ( 4 , 5 ) attached to the contact bridges ( 2 , 3 ), the switching insert ( 19 ) and the fixed contacts ( 6 , 7 ) are positively embedded and centered and that all in the housing ( 1 ) bef indli chen elements are arranged in layers one above the other, with mechanical decoupling of the contact frame ( 10 ) from the contact bridge ( 2 , 3 ) of the closed contact takes place in the two possible switch position end positions by the surfaces ( 12 , 12 a, 13 , 13 a) lift the driver ( 11 , 11 a) from the contact bridge ( 2 , 3 ) by an approach path (x). 2. Switching device with jumping behavior according to claim 1, characterized in that the contact bridges ( 2 , 3 ) are mechanically connected to compression springs ( 4 , 5 ) which engage in supports ( 8 , 8 a) of the Ge housing ( 1 ) and the first contact bridge ( 2 ) presses against the contact surfaces ( 7 a, 7 b) of a first fixed contact ( 7 ) and the second contact bridge ( 3 ) against the surfaces ( 12 , 12 a) of the driver frame ( 10 ) molded onto the contact frame ( 10 ) 11 , 11 a) presses. 3. Switching device with jumping behavior according to claims 1 and 2, characterized in that each of the fixed contact ( 6 , 7 ) is shaped such that it forms a one-piece element with the connecting device ( 20 ) for flat cable processing. 4. Switching device with jumping behavior according to claims 1 to 3, characterized in that the fixed contacts ( 6 , 7 ) encompass the contact frame ( 10 ) and in the supports located on the housing wall from supports ( 15 , 16 ) are embedded. 5. Switching device with step behavior according to claims 1 to 4, characterized in that the fixed contacts ( 6 , 7 ) are mechanically decoupled from the switching insert ( 19 ) in each switching phase. 6. Switching device with jumping behavior according to claims 1 to 5, characterized in that a device ( 22 ) in the Ge housing cover ( 24 ) is arranged such that it acts as a strain relief for the flat cable line ( 30 ).