DE3807411A1 - Snap-action switching element - Google Patents

Abstract

In the case of known snap-action switching elements, the problem arises of the position of the changeover points (switching point and switching-back point) being heavily influenced by contact erosion. The snap-action switching element has a snap-action spring arrangement (8) with two mutually opposite toggle levers (10, 11), one (12) of whose ends is supported in a mounting (13) fixed to the housing, and whose opposite end is supported in a lever holder (15) on the contact link (3), the toggle levers (10, 11) being prestressed with respect to one another at their outer ends (14) by a tension spring (16). The operating plunger (9) acts on the tension spring (16) so that the relative position of the operating plunger (9) with respect to the changeover point of the bistable snap-action spring arrangement (8) is always constant, irrespective of contact erosion. The snap-action switching element is used, for example, as a limit switch. <IMAGE>

Description

The invention relates to a snap-action switching element one housing and with one between two housing-fixed Contact pairs movable in two switching positions Contact bridge over a bistable snap spring arrangement is held in a switch position and by one acting on the snap spring arrangement in the housing guided operating plunger from the one switching position in the other switch position can be transferred.

Such snap switching elements are known from practice. There, the snap spring arrangement is pivotable in the housing mounted rocker arm, the free ends of which on the one hand on the Contact bridge and on the other hand on the actuating plunger are stored. The actuating plunger is in the housing pushed, the rocker arms of the bistable swivel Snap spring arrangement over a switch point in a second stable location. The contact bridge moves in the opposite direction the direction of actuation of the plunger and is determined by the Snap spring arrangement to the corresponding housing-fixed Contact pair pressed. The actuating plunger is opposite its direction of actuation spring-supported, so that when Release automatically returns to its original position, whereby the rocker arm after overcoming the switch point also be moved and the snap spring assembly again takes its first stable position. The contact bridge will by the snap spring arrangement now to the first Fixed contact pair pressed. One pair of contacts each usually belongs to a power circuit, while that other contact pair belongs to a control circuit. To the pair of contacts fixed to the housing belonging to the power circuit contact burn-off can occur over time. This Contact erosion affects the known Snap switching element the necessary displacement of the  Actuating plunger. In extreme cases, this can mean that at a massive contact erosion a switching of the Snap switching element is no longer possible.

The object of the invention is therefore a snap-action switching element of the type mentioned in such a way that a Contact erosion on the contact pairs fixed to the housing or Contact of the contact bridge has no influence on the actuation of the snap switching element.

This object is achieved in that the Snap spring arrangement two themselves in the switch positions inclined opposite rocker arm, each with one end in a housing-fixed storage and with the opposite end in a lever direction flexible lever bracket of the contact bridge are mounted, wherein the rocker arm by a on the lever mounts Contact bridge attacking spring are held, and that the Tappet for switching the contact bridge acts on the spring.

This design of the snap-action element has an effect a contact burn does not depend on the actuation of the Snap switching element. The bistable Snap spring arrangement snaps with the invention Snap-action element around when the direction of action of the spring the rocker arm lies in the longitudinal axis. Since the rocker arm with the opposite ends are fixed to the housing, this switchover point is always reached when the Actuating plunger a certain position relative to that Occupies housing. This position is independent of the situation the contact bridge, which is why a change in position of the Contact bridge in a switch position due to Contact erosion has no influence on the operation of the Has snap switching element. This will make the Operational safety of the snap switch element essential elevated.  

According to a preferred embodiment of the invention mutually facing ends of the two rocker arms in one bearing bracket fixed to the housing, in the area of the center the contact bridge is arranged and the spring as a die opposite ends of the rocker arm engaging Coil tension spring is formed. The actuating plunger can so directly on the spring windings of the coil tension spring act; in addition, only a housing-fixed bracket for the rocker arms are intended to be.

A particularly simple housing-fixed mounting of the rocker arms arises when the bearing block two, each to the Has rocker arms opening V-shaped recesses.

It is particularly advantageous if the V-shaped Recesses immediately adjacent to one another with their reason are formed in the bearing block, since then the switchover point the snap spring assembly is reached once the Center line of the coil spring the bottom of the V-shaped Recesses in which the rocker arms are mounted reached.

A simple mounting of the rocker arm on the contact bridge results if a trough-shaped on the contact bridge Feather strip is attached, at the free ends of the Lever brackets are formed. The free ends of the trough-shaped spring strips lie the V-shaped Recesses of the bearing block so that the rocker arm in the switch positions a slightly inclined position take in.

Advantageously, the lever mounts on the free ends of the trough-shaped spring strip to the Ends of the rocker arms are designed to be V-shaped opening. So the rocker arms are particularly easy in the snap element to install.  

Moving the coil spring using the Actuating plunger is particularly easy to carry out, if the actuating plunger two arranged in the plunger axis and opposite, the feathers between them has enclosing pressure projections. The pressure tabs can so directly on the center of the coil spring act if the actuating plunger is displaced in the housing becomes.

It is convenient if the distance of the pressure projections from each other is slightly larger than that Coil diameter of the coil tension spring. So is ensures that the coil tension spring in both Switch positions without the pressure protrusions of the Touch actuating plunger is excited, and indeed if the position of the contact bridge changes due to Contact erosion has shifted.

The snap element is particularly easy to operate, if the actuating plunger with a handling end from the Housing protrudes.

If the other end of the actuating plunger has one Compression spring against the direction of actuation of the ram on Housing is supported, becomes a monostable Snap-action element reached that after releasing the Actuating plunger always due to the action of the compression spring returns to a predetermined switching position.

The snap-action switching element according to the invention can be used in particular easy to assemble if the actuating plunger is in two parts is formed, with each part of the plunger one Has pressure projection. For assembling the snap element can then first the first plunger part in the housing be used. Then the contact bridge with the rocker spring assembly are used, after which the with tappet part formed on the handling end.

The following is an embodiment of the invention explained in more detail using a drawing. Show it:

Fig. 1 in a cutaway view of an inventive snap-action switching element with a contact bridge in a first switching position,

Fig. 2, the snap-action switching element of FIG. 1 with the bistable Kippfederanordnung shortly before the folding,

Fig. 3 shows the snap-action switching element from Fig. 1, in which the contacts of the contact bridge are glued to the housing contacts, and

Fig. 4 shows the snap-action switching element from Fig. 1 with the contact bridge in the second switching position.

Fig. 1 shows an enlarged cut-away view a snap-action switching element 1 with a housing 2 and a movable contact between two positions bridge 3.

Two housing-fixed contact pairs 4 and 5 are provided in pairs opposite one another in the housing 2 . In the exemplary embodiment described here, the contact pairs 4 are connected to a power circuit in a manner not shown in detail, while the contact pair 5 is connected to a control circuit. The contact bridge 3 has mating contacts 6 and 7 at its opposite ends, which cooperate with the contact pairs 4 and 5 in the respective switching positions.

The contact bridge 3 is held in the housing 2 via a bistable snap spring arrangement 8 . The bistable snap spring arrangement 8 has the same effect that the contact bridge 3 with its mating contacts 6 and 7 respectively abuts a contact pair 4 or 5 .

The transfer of the contact bridge 3 from a first switching position (cf. FIG. 1) to a second switching position (cf. FIG. 4) takes place via an actuating plunger 9 which acts on the snap spring arrangement 8 . The actual switching of the contact bridge 3 from the first switching position into the second switching position is effected at least in the normal case via the snap spring arrangement 8 without the actuating plunger 9 acting directly on the contact bridge 3 .

The snap spring arrangement 8 has two rocker arms 10 and 11, which are inclined in the switching positions. In one switching position, the rocker arms 10 and 11 are inclined upwards, while in the other switching position they are inclined downwards.

The rocker arms 10 and 11 are each mounted with one end 12 in a bearing 13 fixed to the housing and with the opposite end 14 in a lever holder 15 of the contact bridge 3 which is flexible in the lever direction. The rocker arms 10 and 11 are held by a coil tension spring 16 engaging the lever brackets 15 of the contact bridge. The housing-fixed bearing 13 is designed as a common bearing block for the mutually facing ends 12 of the two tilting rods 10 and 11 . The ends 14 facing away from one another are each held in a lever holder 15 of the contact bridge 3 . The helical tension spring 16 thus extends transversely to the actuating plunger 9 , the spring windings 17 being located below a pressure projection 18 of the actuating plunger 9 . The actuating plunger 9 acts directly on the spring windings 17 of the helical tension spring.

So that the spring turns 17 of the coil spring 16 are not hindered by the rocker arms 10 and 11 , a recess 19 is provided in each of them for the passage of the coil spring 16 .

In the bearing block 13 , V-shaped recesses 20 opening towards the rocker arms are provided for mounting the mutually facing ends 12 of the rocker arms 10 and 11 . The V-shaped recesses 20 directly adjoin one another with their recess base, so that the mutually facing ends 12 of the rocker arms 10 and 11 practically have a common pivot point.

In order to form the lever holders 15 on the contact bridge 3, a trough-shaped spring strip 21 is applied to the contact bridge 3, at the free upward projecting ends of the rod holders are formed 15th The free ends of the spring strip 21 are bent inwards so that they form a V-shaped trough with the upstanding legs of the spring strip 21 , in which the ends 14 of the rocker arms 10 and 11 are mounted.

In addition to the pressing projection 18 has disposed 9 in a further ram axis S of the operating plunger, and the pressure projection 18 opposite pressing projection 22. The two pressure projections 18 and 22 are spaced so far apart that the coil spring 16 with its spring turns 17 is arranged with play in between.

The actuating plunger 9 projects out of the housing 2 of the snap-action switching element 1 with a handling end 23 . At its other end, the actuating plunger 9 is supported on the housing via a helical compression spring 24 . The helical compression spring 24 acts counter to the actuation direction B of the actuation plunger 9 . The force of the helical compression spring 24 is dimensioned such that the contact bridge 3 automatically returns to the first switching position shown in FIG. 1 after the actuating plunger 9 is released .

The actuating plunger 9 is formed in two parts. One part, the upper part in the drawing, comprises the handling end 23 and the pressure projection 18th The second part comprises the helical compression spring 24 and the pressure projection 22 . Both parts of the actuating plunger 9 are inserted into each other over legs 25 and 26, the legs 25 9, the leg 26 extend beyond the side of the upper part of the actuating plunger of the lower part of the actuating plunger. 9 The legs 25 and 26 reach over the bearing block 13 fixed to the housing; they can be connected to one another by means of snap locks, but it is also sufficient if the legs 25 and 26 are simply inserted into one another, since the two parts of the actuating plunger 9 are held together by the helical compression spring 24 .

The contact bridge 3 has behind the legs 26 each a lateral shoulder 27 which is below the free ends of the legs 25 . To make the free ends of the legs 25 have pressure surfaces 28 which cooperate with the lateral shoulders 27 of the contact bridge 3 by a forced switch-over of the contact bridge 3, when caught, the mating contacts 6 at the pair of contacts 4 by contact welding and the snap spring assembly 8 alone not able is to cause the contact bridge 3 to switch (see FIG. 3).

From Fig. 2 it can be seen that the distance a between the pressure surfaces 28 of the free ends of the legs 25 and the contact bridge 3 is at least 0.5 mm when the snap spring arrangement 8 is immediately before turning.

The mode of operation of the invention is described in more detail below explained.

Starting from the first switching position shown in FIG. 1, in which the contact pair 4 is connected to one another via the contact bridge 3 , so that the power circuit is closed, the snap element 1 is to be switched over by moving the actuating plunger 9 in the actuating direction B. If the actuating plunger 9 is displaced in the actuating direction B in the housing, this is done against the resistance of the helical compression spring 24 . After a small distance, the pressure projection 18 touches the spring turns 17 of the helical tension spring 16 . As a result, the tension coil spring 16 is bent in the middle and pressed down. As soon as the line of action of the helical tension spring 16 , that is to say approximately its center line, lies at the level of the mutually facing ends 12 of the rocker arms 10 and 11 , the direction of force of the helical tension spring lies exactly in the longitudinal axis of the two rocker arms 10 and 11 . This position is shown in Fig. 2. The snap spring arrangement 8 is now at its switchover point. If the actuating plunger 9 is moved slightly further downward, the helical tension spring 16 suddenly pulls the outer ends 14 of the rocker arms 10 and 11 downward, so that the snap spring arrangement 8 reaches its second bistable position, as a result of which the contact bridge 3 is transferred to its second switching position (see Fig. 4). The counter contacts 7 are now on the housing-fixed contact pair 5 of the control circuit.

If the actuating plunger 9 is released, the helical compression spring 24 ensures that the pressure projection 22 of the actuating plunger 9 press against the windings of the helical tension spring 16 from below, whereby the helical tension spring is moved upwards until the force line of the helical tension spring 16 again in the longitudinal axis the rocker arm 10 and 11 is located. The rocker arms 10 and 11 then snap from bottom to top, whereby the contact bridge 3 is moved up into the first switching position.

The switching point of the snap spring arrangement 8 is always assigned to a predetermined actuating travel of the actuating push rod 9 in the inventive snap-action switching element. 1 Whenever the actuating plunger 9 is pushed so far into the interior of the housing that the center line of the helical tension spring 16 lies over the ends 12 of the two rocker arms 10 and 11 , the transition point is reached; at a further displacement of the actuating plunger 9, the snap spring assembly 8 moves into its other stable position, whereby the contact bridge comes 3 in the second switching position. It is clear from this that the position of the switching point is independent of any contact erosion on the pair of contacts 4 fixed to the housing or the associated mating contacts 6 of the contact bridge 3 . The same applies to the switch-back point (contact pair 5 fixed to the housing or the associated mating contacts 7 of the contact bridge 3 ).

Assuming that the mating contacts 6 weld to the contacts of the contact pair 4 , the force exerted on the contact bridge 3 by the snap spring arrangement 8 is not sufficient to move the contact bridge 3 from the first to the second switching position. This means that the helical tension spring 16 can be pressed further down by the pressure projection 18 of the actuating plunger 9 beyond the state shown in FIG. 2, without the snap spring arrangement 8 turning over (cf. FIG. 3). The actuating plunger 9 can be shifted further downwards by the amount a from the state shown in FIG. 2 until the pressure surfaces 28 rest on the free ends of the legs 25 on the lateral shoulders 27 of the contact bridge 3 . This state is shown in Fig. 3. If the actuating plunger 9 is pressed further down, the force acts directly on the contact bridge 3 via the legs 25 . Thus, it is possible to pull the counter-contacts fixed to the housing 6 of the pair of contacts 4 by the applied directly to the contact bridge 3 ram force. After the contacts 6 are separated from the contact pair 4 , the snap spring arrangement 8 jumps over, so that the snap switching element 1 assumes the position shown in FIG. 4.

From the above description it is clear that the forced switching of the snap switching element from the first switching position of the contact bridge 3 into the second switching position can take place without any translation lever, since the snap spring arrangement 8 is designed so that the actuating direction B of the actuating plunger 9 of the switching direction of the contact bridge 3 from the corresponds to the first switching position (see FIG. 1) in the second switching position (see FIG. 4).

Claims (11)

1. Snap-action switching element with a housing and with a contact bridge movable between two contact pairs in two switching positions, which is held in a switching position by means of a bistable snap spring arrangement, and which are actuated from the one switching position into the by an actuating plunger acting on the snap spring arrangement Another switch position can be transferred, characterized in that the snap spring arrangement ( 8 ) has two rocker arms ( 10 , 11 ) which are inclined in the switch positions, each with one end ( 12 ) in a bearing ( 13 ) fixed to the housing and with the opposite end ( 14 ) are mounted in a lever holder ( 15 ) of the contact bridge ( 3 ) which is flexible in the lever direction, the rocker arms ( 10 , 11 ) being held by a spring ( 16 ) acting on the lever holders ( 15 ) of the contact bridge ( 3 ), and that the actuating plunger ( 9 ) for switching the contact bridge ( 3 ) au f the spring ( 16 ) acts. 2. snap-action switching element according to claim 1, characterized in that the mutually facing ends ( 12 ) of the two rocker arms ( 10 , 11 ) are mounted in a housing-fixed bearing block ( 13 ) which is arranged in the region of the center of the contact bridge ( 3 ), and that the spring ( 16 ) is designed as a helical tension spring engaging the opposite ends ( 14 ) of the rocker arms ( 10 , 11 ). 3. snap-action switching element according to claim 1 or 2, characterized in that the bearing block ( 13 ) has two, each to the rocker arms ( 10 , 11 ) opening, V-shaped recesses ( 20 ). 4. snap-action switching element according to one of claims 1 to 3, characterized in that the V-shaped recesses ( 20 ) are formed with their base directly adjacent to each other in the bearing block ( 13 ). 5. snap-action switching element according to one of claims 1 to 4, characterized in that on the contact bridge ( 3 ) a trough-shaped spring strip ( 21 ) is attached, at the free ends of the lever mounts ( 15 ) are formed. 6. snap-action switching element according to one of claims 1 to 5, characterized in that the lever mounts ( 15 ) at the free ends of the trough-shaped spring strip ( 21 ) to the ends of the rocker arms ( 10 , 11 ) are V-shaped opening. 7. snap-action switching element according to one of claims 1 to 6, characterized in that the actuating plunger ( 9 ) has two arranged in the plunger axis and opposite, the spring ( 16 ) enclosing pressure projections ( 18 , 22 ). 8. Snap-action switching element according to one of claims 1 to 7, characterized in that the distance between the pressure projections ( 18 , 22 ) from one another is slightly larger than the winding diameter of the helical tension spring ( 16 ). 9. snap-action switching element according to at least one of claims 1 to 8, characterized in that the actuating plunger ( 9 ) with a handling end ( 23 ) protrudes from the housing ( 2 ). 10. snap-action switching element according to one of claims 1 to 9, characterized in that the other end of the actuating plunger (9) is supported via a pressure spring (24) counter to the actuation direction (B) of the plunger (9) on the housing (2). 11. Snap-action switching element according to one of claims 1 to 10, characterized in that the actuating plunger ( 9 ) is formed in two parts, each part of the plunger having a pressure projection ( 18 or 22 ).