EP0607566A1 - Push-button switch - Google Patents

Abstract

A push button switch, in particular a mains switch, has contacts (4 to 7) fixed to the housing and at least one contact bridge (8, 9) which can be moved by means of a plunger (10). A jump switch (24, 25, 26) is effective between the plunger (10) and a manually operated switch slide (22). A locking device for the slide switch has a link (27) and a locking lever (28) engaging in it. When pushed in, the slide switch alternately goes into the on position and the off position. In order to avoid damage to the latching device when the slide switch is loaded manually against the pushing-in direction, the latching parts release a movement of the switch slide against the pushing-in direction. <IMAGE>

Description

The invention relates to a push button switch, in particular a power switch, with contacts fixed to the housing and at least one contact bridge movable by means of a plunger, with a spring switching mechanism which is active between the plunger and a manually operable slide switch, and with a latching device for the slide valve, which acts as a latching part as a backdrop and has a locking lever engaging in it, the slide switch pushing in against the force of a return spring displacing one locking part relative to the other locking part and alternately going into the switched-on position and the switched-off position.

Such push button switches are used in consumer electronics devices, in particular in television sets.

Such a push button switch is described in DE-AS 1 590 503. The locking device is formed there by a locking spring which is fixed to the housing and engages in a backdrop of the slide switch.

Similar push button switches also result from DE 35 45 938 A1, DE-AS 1 300 603, DE-PS 1 690 203, DE-OS 20 65 104, DE-AS 21 16 776, DE-OS 31 50 046 and DE-OS 33 32 371. With all these push button switches there is the problem that if the slide switch is forcibly loaded against its normal direction of insertion, there is a risk that the latching device will be mechanically damaged. Such incorrect actuations must be expected, since the user does not always know the correct mode of operation from the outset. The risk of damage to the aforementioned pressure switches in the event of violent incorrect actuation also exists because the latching devices have to be constructed very small and generally consist of plastic, so that it cannot be assumed that all parts can be designed so stably that they are also withstand violently wrong types of operation.

From DE-PS 36 44 437 a push button switch is already known with a locking device in which a locking element is held by means of a spring means that can be avoided. The spring means protects the locking device in the event of overuse in the direction of the touch.

The object of the invention is to propose a pushbutton switch of the type mentioned, in which there is no risk that the latching device will be damaged when the slide switch is manually loaded against the direction of insertion.

According to the invention, the above object is achieved in a pushbutton switch of the type mentioned at the outset in that one of the two locking parts in engagement forms a locking part on the slide switch and the other latching part is pressed against a stop of the housing by means of the return spring of the slide switch, and that the latched part pressed against a stop of the housing is immovable when the slide switch is pressed in and can be displaced in relation to the housing against the pushing-in direction when the slide switch is actuated manually, wherein it takes part in the movement of the locking part which is designed to be stationary on the slide switch and with which it is in engagement.

It is thereby achieved that the switch slide, which is latched in a latching position, in particular the switch-on position, then when it is pulled - incorrectly - it does not offer any resistance to this train, which loads the latching parts in a damaging manner. If the slide switch is pulled, both locking parts make this movement until the slide switch finds a stop fixed to the housing. In this case, the locking part which is pressed against a stop of the housing by means of the return spring and which cannot be displaced when the slide switch is pushed in, can be displaced against the push-in direction against the push-in direction when the slide valve is manually actuated, the movement of the other locking part which is stationary on the slide switch and with which it engages stands, participates. Switching can take place, but this does not pose any particular risk.

In a preferred embodiment of the invention, the link is formed on the switching slide and the locking lever is guided on the switching slide, the locking lever being pressed against a stop of the housing by means of the return spring.

The stop of the housing is preferably a notch into which a rounding of the locking lever is pressed.

Figur 1

eine Aufsicht eines Drucktastenschalters in Ausschaltstellung, teilweise geschnitten,

Figur 2

eine Seitenansicht des Drucktastenschalters in Ausschaltstellung, im Schnitt,

Figur 3

eine Figur 1 entsprechende Darstellung des Drucktastenschalters in Einschaltstellung

und

Figur 4

eine Figur 2 entsprechende Ansicht des Drucktastenschalters in Einschaltstellung.

Further advantageous refinements of the invention result from the subclaims and the following description of an exemplary embodiment. The drawing shows:

Figure 1

a top view of a push button switch in the off position, partially cut,

Figure 2

a side view of the push button switch in the off position, in section,

Figure 3

a representation corresponding to Figure 1 of the push button switch in the on position

and

Figure 4

a view corresponding to Figure 2 of the push button switch in the on position.

A housing (1) of the push button switch has a base part (2) and a cover part (3). Two pairs of contacts (4.5 and 6.7) are attached to the bottom part (2). A contact bridge (8.9) is assigned to each contact pair (4.5 or 6.7). It is a two-pole switch.

A plunger (10) is slidably mounted on the base part (2) in the direction of the longitudinal axis (L). The plunger (10) has two chambers into which compression springs (11, 12) are inserted. These are supported on the one hand on a pin (13) of the chamber and on the other hand on the contact bridge (8 or 9). For this purpose, the contact bridge (8 or 9) has an indentation (14). The contact bridges (8, 9) protrude on both sides of the longitudinal axis (L) through openings (15) in the plunger (10) in which they have play.

A spring-elastic tongue (16) is formed on the plunger (10) and interacts with a hump (17) formed on the base part (2) in the manner described in more detail below. A first slope (18) of the hump (17) and a first slope (19) of the tongue (16) form a first pair of friction surfaces. A second slope (20) of the hump (17) and a second slope (21) of the tongue (16) form a second pair of friction surfaces (cf. FIG. 2, FIG. 4).

On the bottom part (2) a slide switch (22) is slidably mounted in the direction of the longitudinal axis (L), which projects in the direction of the longitudinal axis (L) beyond the housing (1) and outside the housing (1) a receiving pin (23) for forms a push button, not shown.

An arm (24) is formed on both sides of the longitudinal axis (L) on the slide switch (22). A compression spring (26) is arranged between each of the arms (24) and an extension (25) of the plunger (10). As a result, a snap switch is formed between the plunger (10) and the slide switch (22).

An approximately heart-shaped link (27) is formed on the slide switch (22) and is used to guide a locking lever (28). The locking lever (28) engages with a hexagonal profile (29) in the link (27). On the outside of the base part (2) there is a notch (30) into which a rounded portion (31) of the locking lever (28) engages. The locking lever (28) also has an extension (32) outside the base part (2) which engages in a compression spring (33) which is also the return spring (33) for the slide switch (22). The return spring (33) lies in a chamber (34) of the slide switch (22) and is held in this by a projection (35).

The rounding (31) of the latching lever (28) is offset from the engagement surface of the return spring (33) on the extension (32) (cf. FIG. 2, FIG. 4). This creates a tilting moment that presses the pin (29) of the locking lever (28) into the link (27).

The locking lever (28) has a bevel (36) on its side facing the return spring (33), so that the locking lever (28) tends to be mounted in the notch (30) with its pin (29) in a preferred direction pivot - in Fig. 1, 3 to the right -.

The push button switch described is easy to assemble by machine. For this purpose, all parts can be inserted from the same side (in FIG. 1 perpendicular to the plane of the drawing, in FIG. 2 from the right into the base part 2). The springs described can also be used mechanically. In the same direction, the cover part (3) is placed, which in Figures 1, 3 only to the left of Longitudinal axis (L) is shown. Pins (38) and pins (39) formed on ribs (37) engage in bores (40) of the base part (2). A lower peripheral edge (41) of the base part (2) forms a support for a circuit board, not shown, with which the contacts (4 to 7) can be connected. The contacts (4 to 7) are protected inside the edge (41) so that no particles can reach the contacts (4 to 7) from the outside.

The function of the described push button switch is approximately as follows:
In the switch-off position shown in FIGS. 1, 2, the slide switch (22) is pressed against a stop (42) by means of the return spring (33). The compression springs (26) are relatively relaxed and the plunger (10) is pressed by them against a stop (43). The compression springs (11, 12) press the contact bridges (8, 9) against the edges (44) of the openings (15). The contact bridges (8,9) are spaced from the contacts (4,5 or 6,7).

If the switch is to be switched, then the slide switch (22) is moved in the push-in direction (E). The link (27) moves with a guide section (47) relative to the pin (29) of the locking lever (28). When moving the slide switch (22), the compression springs (26) are tensioned, which go over their dead center. Until then, the plunger (10) remains motionless. After the dead center is exceeded, the compression springs (26) act in the opposite direction, so that the plunger (10) is now accelerated against the direction of insertion (E). After a movement that is initially free in the stroke (a) (cf. FIG. 2), the second slope (21) of the tongue (16) meets the second slope (20) of the hump (17), these slopes now abutting one another as friction surfaces. These friction surfaces now slide against one another while pivoting the tongue (16), as a result of which the movement of the plunger (10) is braked, so that the contact bridges (8.9) then hit the contacts (4.5 and 6.7) when braked. Contact bouncing is thereby avoided or at least reduced. After the contact bridges (8.9) hit the contacts (4.5 or 6.7), the plunger (10) moves so far that the edges (44) of the contact bridges (8.9) remove. The contact pressure is now guaranteed by the compression springs (11 or 12).

When the slide switch (22) is released, the pin (29) of the locking lever (28) goes into a locking receptacle (45) of the link (27). The push button switch is now in the switch-on position shown in FIGS. 3 and 4.

If the slide switch (22) or its push button is pulled forcibly in the pulling direction (Z) in a manner not provided for the actuation of the switch, then the locking device, namely the link (27) or the locking lever (28) in push button switches according to the prior art. , damaged. If the pushbutton switch on the slide switch (22) is pulled in the direction (Z), the link (27) takes the locking lever (28) in the direction of pull (Z). This is possible because the locking lever (28) is not in this direction (Z) on the housing (1), but is supported by the pressure spring (33) on the slide switch (22). The slide switch (22) is therefore free to move in the direction of pull (Z). If the slide switch (22) is moved to such an extent that it hits the stop (42), then the plunger (10) snaps in the manner described in more detail below by means of the compression springs (26) of the spring switch from the switched-on position to the OFF position.

To regularly switch the pushbutton switch from the switch-on position to the switch-off position, the slide switch (22) is actuated in the push-in direction (E). The slide (27) moves relative to the pin (29) of the locking lever (28), so that the pin (29) the locking receptacle (45) under the action of the compression spring (33) pressing on the slope (36) in the direction of Arrow (A) leaves (see. Fig. 3). After a short stroke (b), which only has to be large enough for the pin (29) of the locking lever (28) to go out of the locking receptacle (45), the slide switch (22) meets an edge (46) of the base part (2 ). Until then, the plunger (10) is stationary and held by the compression springs (26) so that its compression springs (11, 12) have the necessary contact pressure between the contact bridges (8.9) and the contacts (4.5 and 6.7 ) maintained.

The slide switch (22) is then released or slowly manipulated in an undesirable manner. In both cases it moves under the action of the return spring (33) in direction (Z). The compression springs (26) stretch to their dead center. Shortly before reaching the dead center begins to move the plunger (10) in direction (E). Because of the free stroke (c) existing between the edges (44) and the contact bridges (8,9), the contact bridges (8,9) are not yet acted upon by the edges (44). Between the first slope (18) of the hump (17) and the first slope (19) of the tongue (16) there is a free stroke (d) in the switched-on position, which is smaller than the free stroke (c). The bevels (18, 19) acting as friction surfaces therefore meet one another before the edges (44) act on the contact bridges (8, 9). The friction surface pairing of the bevels (18, 19) means that the snap-in of the plunger (10) or the contact bridges (8, 9) is delayed. The edges (44) of the plunger (10) only meet when the friction surfaces formed by the bevels (18, 19) have slid against one another, the spring-loaded tongue (16) pivoting and the tension state of the compression springs (26) increasing the contact bridges (8, 9), the bevels (18, 19) having separated from one another. The contact bridges (8.9) suddenly snap off the contacts (4.5 or 6.7). The push button switch then comes into the switch-off position shown in FIGS. 1 and 2.

Before the point of transition is reached, at which the contact bridges (8,9) suddenly detach from the contacts (4,5 or 6,7), the user can manipulate the slide switch (22) without, however, the contact bridges can bring a state in which they lie on the contacts (4.5 or 6.7) with insufficient contact pressure. If the slide switch is manipulated, for example, into an intermediate position in which the bevels (18, 19) already lie against one another and the compression springs (26) in the region of their dead center then there is still no dangerous increase in the contact resistance between the contact bridges (8.9) and the contacts (4.5 or 6.7) and there is also no danger of manipulable arcing.

The bevel (19) parallel to the bevel (18) and the bevel (21) parallel to the bevel (20) have different angles of inclination which are adapted to the described modes of operation. As a rule, the bevels (18, 19) are steeper than the bevels (20, 21) because the bevels (18, 19) serve to increase the effect of the springs (26) as energy stores and the bevels (20, 21) are only braking should work.

It is favorable that the tongue (16) is relieved both in the switched-on position and in the switched-off position - that is, for the longest time - and is only deflected during the switching. It is also possible to design the spring-loaded tongue (16) on the base part (2) and to provide the hump (17) on the plunger (10).

However, the pair of friction surfaces (18, 19; 20, 21) can also be designed so that they are not at an angle to the direction of insertion (E), but parallel to it. A resilient element is not necessary in this case. The surfaces leading to increased friction can then be designed with a corresponding surface structure.

It can also be provided that the locking lever (28) is mounted in the base part (2). It is then supported in this by means of an additional spring, which enables it to be taken along when moving in the direction of pull (Z). In reverse of the conditions described, it is also possible to mount the locking lever (28) on the slide switch (22) and then to provide the link (27) on the base part (2). If the locking lever (28) does not leave the movement of the slide switch (22) free when pulling in the pulling direction (Z), the link (27) can instead be mounted such that it follows the movement of the locking lever (28) during such a movement.

Another switching contact (48) is shown in FIG. This is used, for example, to display the respective switching state of the push button switch. Reference number list 02/93 EP 1 casing 32 approach 2nd Bottom part 33 Return spring 3rd Cover part 34 chamber 4-7 Contact 35 head Start 8.9 Contact bridge 36 Weird 10th Plunger 37 Ribs 11.12 Compression spring 38.39 Cones 13 Cones 40 drilling 14 Indentation 41 edge 15 breakthrough 42.43 attack 16 tongue 43 edge 17th Hump 45 Rest 18.19 first slope 46 edge 20.21 second slope 47 Guide section 22 Slide switch 48 Switch contact 23 Locating pin 24th poor a Stroke 25th Continuation b Stroke 26 Compression spring c Free lift 27 Backdrop d Free lift 28 Locking lever A direction 29 hexagonal tenon E Direction of indentation 30th score L Longitudinal axis 31 Rounding Z. Direction of pull

Claims (5)

Pushbutton switch, in particular mains switch, with contacts (4 to 7) fixed to the housing and at least one contact bridge (8,9) movable by means of a spring plunger (10), with a spring switch (24, 25, 26) which is located between the spring plunger (10) and a manually operable slide switch (22) is effective, and with a latching device (27, 28) for the slide switch (22), which as latching parts has a link (27) and a latching lever (28) engaging in it, the selector slide (22) when pressed against the force of a return spring, the one locking part moves relative to the other locking part and alternately goes into the on position and the off position,
characterized,
that of the two engaging locking parts (27, 28), one locking part (27) is formed on the slide switch (22) and the other locking part (28) by means of the return spring (33) of the slide switch (22) against a stop of the housing (1) is pressed, and that the latching part (28) pressed against a stop of the housing (1) cannot be displaced when the slide switch (22) is pressed in and when the slide switch (22) is actuated manually against the pushing-in direction (E) relative to the housing (1) is displaceable, whereby it (28) participates in the movement of the latching part (28) which is designed to be stationary on the slide switch (22) and with which it (28) is in engagement. Pushbutton switch according to claim 1,
characterized,
that the link (27) is formed on the slide switch (22) and the locking lever (28) is guided on the switching slide (22) and that the locking lever (28) is pressed by the return spring (33) against a stop of the housing (1) is. Pushbutton switch according to claim 1 or 2,
characterized,
that the stop of the housing (1) is a notch (30) into which a rounding (31) of the locking lever (28) is pressed. Pushbutton switch according to one of the preceding claims 1 to 3,
characterized,
that the stop (30) of the housing (1) is formed on the outside thereof. Pushbutton switch according to claim 3 or 4,
characterized,
that the curve (31) is offset from the engagement surface of the spring (33) on the locking lever (28).

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