DE975831C - Snap switch - Google Patents

Description

The invention relates to electrical snap-action switches, consisting of at least one Pair of spaced-apart fixed contacts attached to the housing made of insulating material, one movable Contact bridge with a pair of contact platforms and at least one contact on each platform and a plunger-like trigger as an actuator, which also serves as a holder for the Snapping moving contact bridge is used.

The precise control of automatic machines often requires a large number of limit switches and small control parts. For industrial controls, the switches used must be in work reliably in rough operation and continuously at exactly the same point a process trigger, be it by a plunger, a sliding member or by other devices. Here It is desirable that the triggering processes be associated with extremely little force and movement. Snap switches are suitable for this, they can be used as contact parts in limit switches or relays will.

It is known to equip snap switches with contact bridges which are designed in the form of a frame are. The frames have trimmed extensions lying inside in the plane of the frame, which as Spring tongues on the actuator of the switch, e.g. B. a plunger attack such that the Bridge arched in the sense of a contact actuation in the opposite direction to the slide movement. Furthermore is

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it is known to assemble a contact bridge from two rocker parts mounted on the plunger in cutting edges, which are braced against one another by a helical spring in the sense of a contact actuation. Finally, it is known to design a contact bridge as a frame, in which the resilient member is designed to be self-resilient in the longitudinal direction of the bridge by means of a corrugated embossing of the bridge frame lying flat perpendicular to the actuation direction. In all known snap-action switches, the contacts are guided on an arc during the contact movement, which inevitably results in the moving contacts being bent relative to the fixed contacts. In addition, there are bending edges in which the bridges are stressed, which can lead to premature damage to the switch if there are large numbers of operations. Furthermore, a mechanical working memory, in particular for switch drives, is known in which the housing of the memory, which has an approximately rectangular shape in its cross-section, consists of a fully or partially resilient sheet metal frame, with oppositely bent, edgewise, strip-shaped spring parts used as ^a 5 opposite, resilient side walls are. A strip-shaped snap spring is clamped in the housing between the other two side walls, the spring force of which counteracts the spring force of the resilient side walls when it snaps through. In this working memory, the housing is held in a stationary manner on one of the non-resilient housing walls. The housing can therefore not act as a snap bridge which can be displaced in parallel in the actuating direction, as must be the case with the subject matter of the invention.

The invention is based on the object of building a snap switch which is robust and has a long service life despite low maintenance. Finally the snap switch is in on known way to produce from punched and cut light metal spring sheet metal parts. According to the invention the object is achieved in that the contact platforms by opposite Curved, edgewise, strip-shaped spring parts to form a longitudinally resilient bridge are connected and that a drive spring is clamped between the platforms so that their Spring force counteracts the force of the resilient bridge parts.

The purpose and advantages of the invention will become apparent upon studying the following while viewing the drawings.

Fig. Ι shows an overall view of the snap switch, which contains the basic components of the invention;

Fig. 2 is a top plan view of the switch with the front cover removed so that the snap mechanism becomes visible;

Fig. 3 shows the similar view as FIG. 2 with the difference, however, that the snap mechanism is in the second position;

Fig. 4 shows part of the movable contact bridge in the switch of the preceding Figures is arranged;

Fig. 5 finally shows the switch in a disassembled view.

The switch arrangement is a simply constructed housing part composed of a total of two pieces, which consists of a basic housing and a cover 2. The housing can be made of any electrical insulating material. A particularly suitable selection of these are the phenolic resin compositions which are generally used for this purpose. As can be seen from Fig. 2 and 3, the base plate carries ι two pairs of fixed contacts, which are denoted by 4 and 6, respectively. Said contacts are arranged side by side and with suitable pins 4a, such as the z. B. can be seen in Fig. 5, poured or pressed into holes in the base plate for fixing and supporting the fixed contacts. The pairs of contacts are spaced apart from one another, one above the other, so that the contact buttons 4 _& 6 and 6 ₆ each lie in a coaxial connecting line.

As can be seen from Figures 2 and 3, the movable contact bridge is general denoted by 8, arranged between the opposing fixed contacts. This bridge is over a single piece of electrically conductive spring material made of light metal, e.g. B. off Beryllium copper. The manufacturing process of the contact bridge includes a single one Stamping process and simple bending work to give the part the shape shown. The movable one Contact bridge comprises a pair of contact platforms 10 which, seen along the contact bridge, have the same spacing as the associated fixed contacts, with each of the contact platforms 10 is equipped with a contact piece 12 each above and below. These contacts are just like the fixed contacts 4 ^ and 6 ^ in a corresponding manner on the frame part, ζ. Β. attached by riveting, soldering or welding. the Contacts are preferably chosen in the form of a hood. The side edges of the contact platforms the movable contact bridges are connected to one another by completely flat spring parts 14, which are bent downwards in comparison to the flat surface of the contact platforms, that the width dimension of the spring parts 14 at an approximately right angle to the plane of the contact platforms and thereby the maximum rigidity in the direction of power transmission for the Contact connection improved. The contact platforms are with support surfaces 16 on their inner provided opposite edges, which are bent downwards. The wings 16 are with preferably centrally arranged recesses or openings 18 which are adapted so as to that they attach the extension 20 to the cutouts of the flat drive spring 22, as shown in FIG and 3 can be seen, record. The spring 22 is therefore clamped between the support surfaces 16. the

the compressive force that holds the spring 22 under arc tension is the resilience of the spring members 14 of the movable contact bridge. The spring 14 assumes the position under normal tension which is shown as a dash-dotted outline 14 ,, in FIG is.

A plunger assembly, indicated generally at 24, includes a push button 26, a pin 28 and a sheet metal part 30 which is slidable for vertical movement in matching recesses of the Base plate 1 is attached. A channel-shaped movable contact guide part 32, which from Sheet metal is made, takes the channel-shaped part 33 of the sheet metal part 30 of the plunger its underside and secures it. The movable contact guide part 32 has an edge 34 is provided, against the cutting edge-like inner edge which is in the groove side of the contact guide part 32 inserted leaf spring 22 sets. Both the movable contact guide part 32 and the flat springs 22 are provided with rectangular openings 36 and 38 which are attached to the pin 28 of the Tappet are adapted.

In the assembled state, the movable contact bridge is through the plunger between the lower and upper fixed contacts. As can be seen from Fig. 2, bridges the movable Contact bridge the lower pair of fixed contacts 4, while the plunger 24 is relaxed. The drive * spring 22 tries to stretch the spring 14 of the movable contact bridge with further tensioning force. This stretching movement causes a sliding and wiping movement of the movable contacts over the surface of the permanent contacts. This ensures the effective electrical connection between both improved. When the plunger is pressed down against the force of the return spring 40 the drive spring 22 stretches, and finally it bends in the opposite direction by. The counteracting forces of the drive spring 22 when compressing and the Spring 14 of the movable contact bridge when tensioning results in a vertical force component on the movable contact bridge, which grows with the displacement of the drive spring 22, so that ultimately at the moment when the force of the spring 22 is sufficiently great, the movable contact bridge is moved upwards. The separately increasing force of the movable contact bridge drives this abruptly from the lower pair of fixed contacts, rocking, into the contact connection with the upper pair of fixed contacts. For switches with low voltages and limited Electricity is that sliding and swiping motion to ensure good electrical power Contact connection, which is caused by the pushing away of foreign parts from the position between the contact surfaces, especially with these lateral arrangements between the contact surfaces, particularly desirable. If there is no such wiping movement, foreign parts result Arc and contact heating, which ultimately leads to surface damage to the contacts Have consequence. This surface damage exceeds the wear and tear caused by the described wiping movement is caused, considerable.

When the plunger 24 is released from the position shown in FIG. 3, the return spring drives 40 back the plunger into the position shown in FIG. It is advantageous to arrange the permanent contacts in such a way that that the end pieces are accessible from the bottom, from above or from the front of the housing are. The latter version is shown in the drawing.

If the material thicknesses of the spring 22 and the movable contact bridge 8 are selected correctly the mechanism for effective movement requires very small forces, even with regard to the orientation plane of the spring 14, which is relatively very stiff in the direction of the slide movement is. The structure of the switch according to the invention can be made very flat, as the moving Contact part is very narrow in relation to its length.

With regard to a long service life of silver or silver alloy contacts, it would be desirable, the mechanical wear caused by contact sliding and cleaning will be reduced to a minimum. However, this type of switch is used for very low voltages used, especially for voltages below the contact arc voltage, so have arrangements various disadvantages without a contact rocker. If the applied voltage is insufficient, the To penetrate the oxide layer on the contacts, so are switches without self-cleaning contacts Incorrect switching unavoidable. These disadvantages of known switch types are also associated with the switch according to the invention safely avoided by the contact friction occurring when switching.

Claims (6)

Patent claims: 1. Snap-action switches, consisting of at least one pair of spaced apart, on the housing Fixed contacts made of insulating material, a movable contact bridge with a pair Contact platforms and at least one contact on each platform as well as a plunger-like trigger as an actuator, which also serves as a holder for the contact bridge, which is moved snappingly, thereby characterized in that the contact platforms by oppositely curved, edgewise asked, strip-shaped spring parts are connected to a longitudinally resilient bridge and that a drive spring is clamped between the platforms in such a way that their spring force counteracts the force of the resilient bridge parts. 2. Snap switch according to claim 1, characterized in that the plunger-like trigger preferably acts on the drive spring via shoulder-like intermediate links. 3. Snap switch according to claim 1 and 2, characterized by a return spring, pre- preferably a spiral spring that is frictionally engaged with parts of the trigger and / or the drive spring connected is. 4. Snap switch according to claim 1 to 3, characterized in that the plunger-like Drive and the return spring are guided in parts of the insulating housing. 5. Snap switch according to claim 1 to 4, characterized by such a form-fitting Guiding the drive spring with the driving plunger that by guiding the The plunger is also reached at the same time the leadership of the movable contact bridge. 6. Snap switch according to claim 1 to 5, characterized in that the resilient contact bridge made of electrically conductive spring material, preferably made of light metal, e.g. B. made of beryllium copper. Considered publications: U.S. Patents Nos. 2466459, 2513053, 2516236, 2598856, 2629791; German Patent No. 525 853; Brochure from Schorch-Werke A. G., Rheydt, »Auxiliary switch«, order no. Ws 1068 from 1952. 1 sheet of drawings © 60Ϊ 615/357 9 ·. (209 691/1 10.62)