FI77745B - ELEKTRISK TRYCKKOPPLING MED EN VRIDBART LAGRAD TRYCKBAOGE. - Google Patents

Abstract

1. Electric pushbutton switch with a pushbutton (11), a base (10) and a pivot-mounted pressure stirrup (4), designed as a pivoted slider, as well as with a one-piece contact rocker (2), which can be tilted about a fixed bearing into two stable switch positions and bears a switching link (3), the switching link (3) effecting the switching-over in each case in alternating engagement with push rods (5) of the pressure stirrup (4), and a spiral-shaped compression spring (6) arranged between the pressure stirrup (4) and the contact rocker (2) bearing against the switching link (3) on the one hand and against the pressure stirrup (4) on the other hand, stabilizing the respective switching position, characterized in that the base (10) is provided with one or more base extensions (15), which the pushbutton (11) closely encloses in a sliding fit, in that grooves (9) or slots are followed out on the inside of the guide walls (21) provided on the base extension or base extensions (15) in that bearing pins (8) integrally attached in the region of the pivot axis of the pressure stirrup (4) are borne and guided in the grooves (9) or slots, making possible a pivotal and translational movement of the pressure stirrup (4) in the space between pushbutton (11) and contact rocker (2), in that the grooves (9) or slots are widened funnel-like in upward direction in the region of the opening of the base extension or of the base extensions (15), in that this upper region is separated from a lower region, in which the bearing pins (8) of the pressure stirrup (4) can slide, by means of flexible projections (23), which act as stops determining the position of rest of the pressure stirrup (4), and in that the fixed bearing is designed as a bar (1) for the contact rocker (2).

Description

1 77745 Electric pushbutton with swivel-mounted pushbutton. - Elektrisk tryckknoppkoppling med en vridbart lagrad tryckbäge.

The invention relates to an electrical push switch according to the type definition of claim 1.

Pushbutton switches are usually constructed as double stable switches. In this case, the linear movement of the pushbutton is converted into a tilting movement acting on the electrical switching element by means of the coupling mechanism. With each further use of the pushbutton, the switching element in each case takes one of the possible switching positions.

It is known from DE-AS 1001741 and DE-AS 2548674 that the push button acts on a pressure arc which, when pressed down with the buffers formed on both sides, engages the corresponding recesses in the tipping element, which is forced into the second tipping position. Since the tilting element is again in contact with one contact element, its position change results in an electrical changeover. In order, on the one hand, to stabilize the respective switching position and, on the other hand, to return the pushbutton to its initial position, a compression-loaded helical spring is used, which is arranged between the pushbutton and the tilting element.

DE-OS 1515511 further discloses an electric pushbutton switch in which the contact element and the tilting element are connected to a tilting contact with a coupling link, in which case, however, two springs are required in these switches. In addition, the ring springs that are just connected to the tilt contact are only difficult to install.

Finally, as a closest prior art to GB-A-875203, a push-button switch 2 77745 comprises a "contact arm 5" pivotally mounted on a groove abutment as a one-piece and rigid tilt contact connecting a tilt element and a contact element. The "operating arm 3" corresponding to the printing arc of the object of the invention is connected to the pushbutton, whereby its transfer guide is also moved by means of a part of the pushbutton.

Increasing automation for serial products forces not only the reduction of the number of components to the minimum necessary, but also the appropriate design of the components to enable their mechanical installation. There are still considerable shortcomings in the known coupling devices in this respect, since on the one hand the number of components can be further reduced and on the other hand the structure of the coupling mechanics is poorly or not at all suitable for mechanical installation.

The object of the invention is to create a push-button switch which consists of as few parts as possible, in which case these parts must at the same time be shaped in such a way that automatic installation is possible. This object is solved by the features set forth in the characterizing part of claim 1. Preferred embodiments and further developments of the invention appear from the subclaims.

By combining the contact element and the tilting element into a one-piece tilting contact supporting the coupling link in a known manner, the number of parts is reduced and installation is also facilitated. In particular, the automatic installation is simplified by the fact that the tilting contact, which is pivotally mounted on a fixed bearing stage, can be very easily mounted on the coupling head. The same applies to the pressure arc, which acts as a pivoting shifter, since it is provided in the region of its pivot axis with bearing pins which can slide up and down in grooves or long holes. The guide secured by the grooves makes it easier to fit the swivel to the position and takes care of it

II

3 77745 concurrently ordered placements.

The grooves concave inside the guide walls formed in the base abutment are expanded upwardly at the opening of the base abutment in a funnel-like manner. In this way, it is easier to place the printing arc in the base. However, the upper funnel-shaped part of the groove is separated from the lower operating part, where the bearing shafts of the printing arc can slide, by means of elastic cams. These cams act simultaneously as responses and thus determine the rest position of the pressure arc.

Since the pins are arranged both centrally inside the pressure arc and also in the tip contact, the compression spring can be easily placed. The self-adhesive attachment of the compression spring to the pivot pins also allows for the pre-assembly of these parts. If necessary, the compression spring can also be attached to the pins of the tipping contact in a self-adhesive manner, whereby the pressure arc, the compression spring and the tipping contact can be mounted as a single unit on the base.

Since the push switch must fit into commercially available base housings, it is advantageous if it has only a small construction height. A feature which is crucial here is the arrangement of the bearing shaft in the pressure arc, which takes place in such a way that the pivot axis of the pressure arc is between both ends of the compression spring. In this way, and also because of the small distance between the buffers of the pressure arch adhering to the coupling links, it is possible to achieve a certain changeover coupling with a very small coupling stroke, which can be less than 3 mm.

The design of the pressure wedges in the pressure switch, which engage the wedge-shaped recesses in the pressure arc, is again installation-friendly, as it allows the parts to be easily joined together.

The compression spring is surrounded by similar symmetrically opposite parts of the printing arc 4 77745 and by pressing wedges formed on both sides of the push button. In this way, symmetrical distributions of compression forces are also obtained and inadvertent carrying of the compression spring with adjacent parts is prevented.

The turning angle of the printing arc is determined by the corresponding structure of the side walls of the base response forming the turning space, which act as a response.

The pushbutton switch may also be arranged as a multi-pole switch with two or more tilt contacts and two or more pushbuttons. With the corresponding structure of pushbuttons and pushbuttons, several switching units can be connected together or also separately. The pushbuttons must also provide good parallelism control. For this purpose, a base stop is arranged in the base, to which the push switch engages around the sliding stop. In addition, the base has guide holes into which the guide pins formed on the push button sink.

Further details and advantages of the subject matter of the invention will be described in more detail below with reference to the application examples shown in the figures.

Figure 1 shows the pushbutton in section, in which one of the two possible switching positions is engaged.

Fig. 2 shows the push switch with the push button pressed in the second switching position of the pivoting tilt contact, the section being set so that the other details of the switch are visible.

Fig. 3 shows a double switch with common pushbuttons in the section according to Figs. 1 and 2, however, turned 9Θ degrees.

Il 5 77745

Fig. 4 shows a top view of the push switch according to Fig. 3 without push buttons.

The push switch has a base 10 pivotally mounted on the bearing step 1 of the fixed contact part, a one-piece tilt contact 2 supporting the coupling link. The coupling link 3 has corresponding recesses which can be gripped by the bushing 5 of the push arc 4 formed as a pivot transfer. The printing arc 4 is further provided with bearing shafts 8 which can move in grooves 9, which in turn are formed in the guide walls 21 of the base stop. The pressing button 11 is formed with printing wedges 13 which, with their sharp tips, engage the wedge-shaped recesses 14 of the printing arc.

The double-stable coupling behavior of the push switch is determined by a helical compression spring 6. This spring 6 is inserted at both ends into pins 7, 20, the first pin 7 being formed centrally inside the pressure arc 4 and the second pin 20 in the middle of the coupling link 3. The compression spring 6 acts on the pushbutton 11 by means of the pressure arc 4 and the pressure wedges 13 and ensures that it returns to its initial position after pressing.

By means of its bearing shaft 8, the pressure arc 4 guided in the grooves 9 follows all the linear movements performed by the pushbutton il. At the same time, however, the bearing shafts 8 also allow the pivoting movement of the printing arc 4, whereby the possible pivot angle is limited by the side walls 22 bordering the pivoting space. above the recess. By pressing down the pressure arc 4 by means of the pushbutton li, the buffer 5 engages the coupling ball 3, so that it is pressed down unilaterally. In this case, the tilt contact 2 in each case turns to the second switching position. The compression spring 6, which is now compressed in the second direction by the coupling pin 3 77745, further transfers this compression to the pressure arc 4, so that this, after releasing the pushbutton 11, likewise moves to the second rest position.

The rectilinear movements of the pressure arch 4 are limited upwards towards the push button 11 by the cams 23. The cams 23 form a stop on the bearing shaft 8, which prevents the printing arc 4 from falling out of the base 1Θ when the push button is absent.

The pushbutton shown is a double stable switch. By unilaterally reducing the angle of the wedge-shaped recesses 14 of the printing arc 4 approximately so that when the pushbutton 11 is pressed according to Fig. 2, the side of the wedge-shaped recess 14 comes into contact with the side of the pressing button 5 on the corresponding side of the pressing button a push switch with only one stable position of the tilt contact 2. In this case, it is expedient to provide the pressure arc 4 with an inner rib which prevents the compression spring 6 from turning.

For the pure parallel control of the pushbutton 11, care has been taken that in the embodiment of the double switch of Fig. 4, base bases 15 are formed in the base 10, which tightly surround the walls of the pushbutton 11 in a sliding response. In addition, guide pins 16, 17 are formed on the pushbutton 11, which sink into the respective guide holes 18, 19 of the base 10. It is also apparent from the pushbutton view shown in Fig. 3 13.

Since the pivot axis of the printing arc 4, regardless of its current position, is always between the ends of the compression spring 6, advantageous lever ratios are obtained, so that a small tl 7 77745 spring force and correspondingly a small compressive force on the push button 11 and a very small push button 11

The push-button switch is installed by first placing the fixed contact parts in the base 10. Then the tilt contact 2 is placed on the bearing stage 1. Through the funnel-shaped bevels of the grooves 9, the printing arch 4 is now pressed into the base 10. In this case, the bearing shafts 8 of the rotary conveyor 4 slide over the resilient cams 23 into the grooves 9. The grooves 23 prevent the printing arch 4 from sliding back. The compression spring 6 attached to the first pin 7 of the pressure arc 4 at one end then strikes with its other end the second pin 20 of the tilt contact 2. Finally, the push button 11 can be set, whereby the retaining elements (not shown) prevent the push button from falling out.

In the structure of the push switch, which is fitted to the plaster housing, the entire internal coupling mechanism thus becomes below the carrier ring 12 in the wall plane. The support ring can then be fastened to the base 10 by means of rivets, screws or retaining members.

In a multi-button switch, in which several switching units are to be connected by means of a common pushbutton 11, it is advantageous to connect the pressure arc 4 of all the switching units rigidly by means of one step due to the synchronous connection of the tilt contact 2. In this case, the one-piece pressure arc 4 is guided and pivoted in the grooves 9 of the outer guide walls 12, while the inner guide walls 21 have an open groove in which the step moves freely.

Claims (9)

1. Electric pressure coupling with a pushbutton (11), an uftder layer (10) and a pivotal bearing, such as a pushbutton formed (4) and a tipping contact (2) in a part, supporting a coupling backing (3), which is pivotable to two stable coupling circumferences a stationary shaft, whereby the coupling backing (3) at its alternating contact with the frame (5) of the thrust member (5) impacts the respective gear coupling and where it between the thrust member (4) and the tipping contact (2) arranged, partly against the coupling backdrop (3) and partly against the helical-shaped pressure spring (6) supporting the respective coupling position, characterized in that the support (10) is provided with one or more support supports (15). ) on which or which pushbutton (11) slides tightly, that a locking (9) or a long h & l in the area of the support strut (15) formed on the inside of the support strut (15) on the inside has been hollowed out the pivot axis (4) pivot axis formed the bearing shafts Mr stored and controlled ice the pawl (9) or the long sleeve, through which the pivotal and offset movement of the pushbutton (4) in the space between the pushbutton (11) and the tipping contact (2) is possible, that the latch (9) or the long heel at the opening of the substrate or substrate attachments (15) is widened It is understood that this upper region is separated from the lower region in which the bearing axis (4) of the thrust shaft (4) can slip, through elastic cam (23), which act as the thrusts determined by the thrust position (4) resting position and that the stationary bearings of the pressure switch (2) are formed as a step (1). 2. Electrical pressure coupling according to claim 1, characterized in that in the case of the tipping contact (2), in each case pins (7,20) are arranged in the tipping contact (2) in which both ends of the pressure spring (6) are inserted. , whereby the compression spring (6) is self-affixed to the pins (7) of the swivel slider (4). Electric pressure coupling according to claim 1 or 2, characterized in that the pivot axis (4) of the pressure shaft (4) formed by the bearing shafts (8) lies between the