DE3150210C2 - Electrical snap switch - Google Patents

Abstract

Electrical snap-action switch with at least one pair of spaced-apart fixed contacts attached to the housing, a movable contact bridge with contact platforms formed on both ends with at least one contact on each platform, as well as a plunger-like trigger located in the middle between the fixed contacts as an actuating element that simultaneously acts as a Carrier for the snapping moving, double interrupting contact bridge is used. To achieve increased contact reliability, the switch is provided with twin contacts, in which the all-round oscillation of the contact system required for four-point support is achieved in that the insulating pieces (17, 18) positioned between the contact platforms of the contact bridge - or between contact bridges (15) arranged one above the other - and connecting elements (19, 20) clamped to the actuating element (25) on the contact platforms or insulating pieces (17, 18) are blade-mounted in a known manner and point-supported (23, 24) on the actuating element (25). The point bearing (23, 24) opens up possibilities to adjust the snap time easily from outside the housing.

Description

The invention relates to an electrical snap-action switch according to the preamble of claim 1. Such a snap switch H from DE-OS 17 815 is known.

Snap-action switch with connecting elements, which are both on the contact platforms and on the Actuators are cutting edge bearings have the disadvantage that the moving contact bridge system with the actuator a relatively rigid system which only forms a degree of freedom of movement, and although it has in the direction of actuation. In the course of the frequently decreasing switching loads to the mV and mA ranges, while at the same time increasing demands on reliability in relation to the Contact resistance, it is advantageous to provide the individual contact points with twin contacts.

Since, in parallel with increasing demands on contact reliability, so do the demands on the Accuracy of the switching time have increased and

This inevitably means readjustment when replacing the snap-action switches in systems with fixed specifications Switching times is required, today options are required on the snap-action switching elements from the outside, so without removing housing parts and the like.

CLOSE this adjustment.

With snap switches according to the generic term two basic principles, one time with resilient contact bridges and rigid connecting elements

elements (between the contact platform and the actuator) and the other time with rigid contact bridges and resilient connecting elements.

Snap switches with a resilient contact bridge are known from German patent specification 9 75 831, is a snap-action switch with two resilient contact bridges, which thus becomes a two-circuit changer described in German patent specification 17 65 712. A snap switch with a rigid or two Contact bridges and resilient connection elements is known from the German OS 28 17 815

What these principles have in common, as shown there, is that the contact platforms at With one-bridge version, one contact each for the NC and NO function, with two-bridge versions Only carry one contact per contact point. A doubling of the contact points so-called twin contacts are the snap springs if there are two-sided cutting edges or the rigid connecting elements in DE-PS 17 65 712 not provided. But there is something like that Snap-action switches also with devices for opening must be provided, according to the requirement of VDE 0660 (that the switch with Inevitable opening such switches are to be understood, the contact pieces when switching off at least reliably separated on part of the actuation path without the interposition of elastic drive elements are) elastic in the direction of the contact closing and opening movement, d. H. resilient contact bridges the end.

Up to now, doubling the contacts to twin contacts required special constructions as in British Patent 15 93 948. The necessary separation of the contact system from However, the jump system has major disadvantages in terms of contact reliability at low actuation speeds as explained in the magazine ETZ vol. 101 (1980) issue 4 on pages 220 and 221 has been

A snap switch known from British patent specification 10 88 083 is electrical with two provided contact bridges that are separate from one another and are each mounted on cutting edges. Each contact bridge are assigned to two pairs of fixed contacts. To ensure reliable contact here, the Bearings of the contact bridges allowed so much play that they can balance, so that both Contact points of the double-interrupting contact bridge come to rest. It is not intended and with this solution shown, it is also not possible to use the individual contact point with twin contacts closing in parallel to provide.

From US patent specification 25 71 453 a snap switch is known, which has a resilient contact bridge with single contacts The purpose of this switch is to meet a large number of switching tasks by simply modifying them. Twin contacts are not provided here either, and a force opening in the sense of VDE 0660 is not described. This switch has an adjustment option.

Another known from US Patent 42 16 358 snap switch is also with a provided resilient contact bridge which cooperates with two fixed contact pairs and in which the Contact bridge each has a double break. Particular attention is paid to the fact that welded contacts Lei actuation are broken. To ensure this, they are opposite Fixed contacts arranged on pivoting plates, which can be moved by drivers on the actuator are. Welded contacts roll off on each other until the weld breaks There are no plans to increase the contact reliability by means of twin contacts.

Another type of forced control is used in one of the German Auslegeschrift 19 35 225 known snap-action switch achieved in that a driven by a cam of the actuator Swivel lever acts on a resilient contact bridge. The movable contact bridge is over this Lever arm pressed unless only a spring deflection of the contact bridge occurs to increase the contact reliability are not provided here either.

Furthermore, a snap contact is known from the German Oifenlegungsschrift 26 13 555, which is also known at Reliably switches with a minimum actuation stroke wedge-shaped groove of a forked co-operation lever and a wedge-shaped groove of the actuating member is pivotably mounted in this way Changeover contact created, which can be controlled by various actuators. A double interruption is not provided, and the possibility of designing the individual contact point as a twin contact is not recognizable.

Another possibility is the time of switching, i.e. the time of the snap adjust shows the OS 29 13 913. But since this is is a snap switch in which the contact system is separated from the snap mechanism is this principle for the aforementioned reasons of contact security at slow actuation speed not optimal. In addition, there is the adjustment of the snap point only with the housing or removed possible if there is a corresponding opening in the housing.

Based on the snap switch received from DE-OS 2817815, the present invention is based on the object of increasing the contact reliability in such an arrangement and to store the contact bridge so that the contact bridge is as freely movable as possible and all contact points with the smallest possible contact differences the fixed contacts.
According to the invention, this object is achieved by the features according to the characterizing part of claim 1.

This is at Zw ^; Single contacts gives the contact system the opportunity to adjust to the position of the fixed contacts. Small remaining differences in position of the four support points can also be compensated for with the rvar massive Kentakt bridges, which are easily twisted in the contact system. A particularly preferred embodiment of the point support, with regard to a spatially fixed fixation of the pendulum center point and thus preventing the contact bridge system from moving out laterally, is characterized by the features according to claim 2.

In the construction requiring the least number of components, it is desirable that the actuator is designed in one piece or that a rotary body to achieve a wear-optimized construction is inserted into the actuator. In this

The case is that part of the actuator in which the rotational body is inserted, with regard to friction and wear behavior to the friction partner "Housing" optimized, the rotating body in relation to its friction partner "connecting element".

Is the pressed-in rotational body dimensionally to a Fixed tolerance end position, a snap adjustment can be achieved that the position of the im Actuator frictionally inserted rotational body with an adjusting screw in the direction of its Is displaceable longitudinal axis and against the contact system or against the contact bridge.

It can be useful to adjust the snap point in both directions. In this case it is proposed according to a further development that the rotary body is longitudinally displaceable in the actuating member is arranged and against the force of a supported between the rotating body and the actuating member Compression spring adjustable with a Justicrichrsube -Elin In this case, it is advisable that the force of the pretensioned compression spring is adjustable over its entire length Area has a higher numerical value than that in the direction of the compression spring, but opposite Acting force component of the snap springs.

Next, to achieve an additional overtravel, the compression spring is to be dimensioned so that after Actuation of the snap switch via the actuator and reaching the end position of the contact system and the rotating body, the actuating member by compressing the compression spring under certain circumstances has an additional overrun path up to the block height.

Is the contact reliability of the contact points provided with twin contacts sufficient and also the Contact reliability increasing free mobility of the point-supported contact system for very small ones Operating speeds not yet exhausted. can be used between the actuating plunger and the rotating body Compression spring be dimensioned so that it is along the path of the actuator compared to that of her counteracting component of the snap springs or the resilient contact bridge exerted force in the area of the snap point stronger, towards the end position of the actuator but is weaker than this component and that it has a flatter characteristic than the snap springs having.

In this embodiment, too, the snap points are adjustable in that the point of equilibrium between the compression spring and the one counteracting it Component of the snap springs is adjustable with an adjusting screw.

With all possible designs, it makes sense that a degree of freedom of the pendulum movement of the contact bridges by lugs of each insulating piece, which face the respective adjacent housing walls, is narrowed.

The exemplary embodiments of the invention are explained with reference to the figures

F i g. 1 shows a representation of a snap-action switch with the cover cut off and the contact system cut through and a partial section through the actuating member with the rotary body pressed in. The left half the figure shows the position of the contact system when the actuator is pressed: the right side the Rest position of the snap switch,

F i g. 2 shows a section through the switch of FIG. 1 to the right of the center line along line I-1, to the left of the Center line, according to line H-II,

3 shows a section through the switch of FIG. 1 along the line IH-IIl.

Fig. 4 Sections through the point support (solid of revolution and connecting element),

F i g. 5 shows a section through an actuating element and, in principle, shows a contact system with only one contact bridge, and FIG
F i g. 6 shows a section through an actuator

ίο longitudinally displaceable rotating body.

The snap switch shown in Figs. 1 to 3 comprises a housing 1 and a cover 2 with the Clip 3 (Fig. 2) into holes 4 (Fig. I) of the housing I is being held. An actuating member 5 is attached to the upper collar 6 (FIG. 1) of the housing 1 and via webs 7 (Fig. 1 and 3) in grooves 8 (Fig. 3) of the housing 1 guided. A cylinder spring 9 (Fig. 1) presses the actuator 5 into its rest position, the Stop 10 (Fig. 1) the rest position of the actuator S fixed.

The fixed contacts II, 12 are the working contact (NO contact) assigned, the fixed contacts 13, 14 to the normally closed contact (NC contact). Between the fixed contacts on the one hand 11, 12 and 13, 14 on the other hand the contact system consisting of contact bridges is freely movable 15, 16, which are joined to form a unit via the insulating bodies 17, 18. The two snap springs 19, 20 are between the cutting edge bearings 21, 22 of the insulating body 17, 18 and the two point bearings 23, 24 clamped in the rotating body 25.

With the aid of Figure 3, the construction of the contact bridges is described in detail, the contact bridge 15 is in plan view: The contact platforms 15a and 15 £> associated twin contact pairs 26,27 and 28,29 are interconnected via the narrow webs A 1 and A 2 and electrically connected to one another with the likewise narrow webs BX and B 2. Via the punctiform contact points 23, 24, the contact system is able to rely largely on the possibly existing differences in position between the contact pairs 26, 27/28, 29 and the four support points of the fixed contacts (the two support points of the fixed contact 11 are shown in Kig. 2 with Ua and Wb referred to), to the extent that three of the four contact points have come into contact. Since the point-like contact points allow the contact bridges, which are deliberately designed to be torsionally unstable due to the narrow webs A 1, A 2 or Bi, B2, to twist relatively easily, the fourth contact point also comes to rest in the course of the snap action with small contact force differences.

The free wobble mobility of the contact system requires guidance to the housing parts 1, 2. to For this purpose, the lugs 17a and 176 are on the insulating body 17, and the lugs 18a and 186 are on the insulating body 18 molded

In Fig. 4 are the punctiform Aniagestetlen 23,24 between the connecting elements, in the example shown the snap springs 19 and 20 and the Rotary body 25, explained in more detail. This has a circumferential groove 30. To avoid that the snap springs 19, 20 migrate in the direction of the arrow C, d. H. leave their planned symmetry, the Snap springs circular arc-shaped cutouts 31, the radius of which to ensure the point bearing points in all operationally possible positions of the rotary body 25 for the position of the snap springs 19, 20 must be equal to or greater than the radius of a circle

which is given by the points 24, 32, 33 on its circumference. The points 32, 33 are here the intersection points of the line X \ -X2 with the line Y \ -Y2 and, on the other hand, the lines Y \ -Y2 with the circumferential lineZ

With FIG. 5, the possibility of adjusting the spatial position of the rotary body 25 firmly pressed into the actuating member 5 is explained. During the assembly process, the rotary body 25 is pressed into a bore 5a of the actuating member 5 until it rests on surface 34. The pin 35 of the rotary body 25 protruding into the bore 5a has undercuts 36 to achieve a clear press fit. When parts 5 and 25 lie one on top of the other on surface 34, the pre-travel path is D and the overrun path is the path £. The theoretical snap point results when the dimension of the path D has become zero.

In the example of FIG. 5, the contact system consists of only one contact bridge 49, on which the snap springs 50, 51 shown symbolically Vi engage via insulating pieces 52, 53 via blade bearings 21, 22. The fixed contacts are labeled 54a, 54b and 55a, 55Z>.

In the case of the adjustment shown as an example, it is expedient in terms of construction to determine the advance path To lay individual part dimensions in such a way that an adjustment always assumes that the lead is too large Has.

To reduce the distance D , the screw 37, which rests on the rotating body 25 at 38, is adjusted so that the rotating body 25 is pressed out of the bore 5a in such a way that the undercuts 35 dig into the bore 5a. The course D is then reduced by the amount by which the rotary body 25 is pressed out of the actuating member 5, the caster increases by this distance. The reset point results from the sum of the adjusted distance £ plus the contact opening F. Of course, it is possible at any time to make the rotary body 25 and screw 37 in one piece. This only requires designing the rotary body in such a way that it is inserted in the actuating member 5 so that it is longitudinally displaceable and provided with a safeguard against unintentional rotation.

In Fig. 6, the rotary body 39 is freely displaceable in the longitudinal direction G in the actuating member 40, the path of which is predetermined by the stops 41 and 42. For this example, the return spring 43 was arranged at the lower end 44 of the rotary body 39. The rotation lock is given by a square 39a.

If the compression spring 45 is dimensioned in such a way that its spring force lies over the entire adjustable range above the spring force component of the snap spring, which acts against the force of the compression spring 45, snap conditions similar to FIG. 5 result. The difference to the construction according to FIG. 5 lies in the quite significant advantage that after reaching the end position of the rotating body 39 - the distance D plus £ corresponds to the FIG. 5 - the actuating member 40 can be pushed in even further until either it rests at 42 or the compression spring rests 45 turn to turn. With the adjusting nut 46, which is supported at 47 on a collar of the actuating member and against which the compression spring 45 presses the adjusting nut 46, the snap time can be adjusted in both directions.

When dimensioning the compression spring 45 in such a way that it is along the path of the actuating element compared to the counteracting component of the force exerted by the snap springs and / or the resilient contact bridge in the area of the snap-action marker, but is weaker towards the end position of the actuating element as this component and that it has a flatter characteristic than the snap spring, there is a so-called double snap function, as described in DE-OS 29 13 913. The difference between this solution and the one disclosed in DE-OS 29 13 913 lies in the enormous advantage that no bearings to be introduced in the actuating element are required and the adjustment of the snap time from the outside via the adjusting nut 46 is possible. In this construction, the amount of advance travel results from the figure shown in FIG. 5 indicated distance D minus the distance X (not shown) by which the compression spring 45 can be compressed by the shoulder 48. The switch-back point is also reduced by this amount X, that is, the differential travel, which normally corresponds to the contact distance F (Fig. 5) (when the compression spring 45 cannot be compressed by the snap spring force component), increases by the amount X twice, so F + (x2 A ^ is. the function of the positive opening means may on the basis of F i g. 1 and will be explained. 2, the two forced opening levers 56, 57 are mounted at 56a and 57a in the housing 1 and cover 2.

After pressing the actuator 5 and reaching the switching point of the contact system, however, switching prevented for some reason comes after moving another Distance, which takes into account the operationally occurring burn-off on the contacts, at 58 resp. 59 the rotating body is in operative connection with the cortactic bridge and thus forcibly triggers an open of the normally closed contact (NC contact).

For this purpose 4 sheets of drawings

Claims (10)

Patent claims: 1.Electric snap-action switch with a housing, with at least one pair of fixed contacts attached to the housing, with either a movable contact bridge or two longitudinally parallel and spaced apart movable contact bridges and interconnected via two insulating bodies, with contact platforms with at least one molded contact platform at both ends of each contact bridge Contact on each contact platform as well as a plunger-like trigger arranged centrally between the fixed contacts and displaceable parallel to its longitudinal axis as an actuating element, which serves as a carrier for the snap-moving, double-interrupting contact bridge or contact bridges and has a recess on two sides facing away from each other, in which each a snap spring n ?. ^: * one end is supported, the other end of which when using a contact bridge is mounted on a blade on one of the contact platforms and when using two contact bridges is mounted on a blade on one of the insulating pieces, characterized in that on each contact platform (15a, 15b) transversely to the longitudinal axis each contact bridge (15, 16), each of which can be twisted, two contacts (26, 27, 28, 29) are provided next to one another, and that the section (25, 39) of the actuating member (5, 25, 39, 40) , ar which the snap springs (19, 20, 50, 51) are in contact, is designed to be rotationally symmetrical to its longitudinal axis and has a circumferential groove (30) as a recess in which the punctiform contact points (23, 24) of the be: appfedern (19, 20.50, 51) are provided. 2. Electrical snap switch according to claim 1, characterized in that the snap springs (19, 20, 50, 51) on the actuating member (5, 25, 39, 40) each have a circular arc-shaped recess (31) whose radius is greater than the radius of the actuating member (25, 39) at the contact point. 3. Electrical snap switch according to claim 1 or 2, characterized in that the actuating member (5, 25, 39, 40) is in two parts, such that a rotating body (25, 39) is inserted into the actuator (5,40). 4. Electrical snap-action switch according to claim 3, characterized in that the position of the im Actuating member (5) frictionally inserted rotary body (25) with an adjusting screw (37) in Is displaceable in the direction of its longitudinal axis and away from the actuating member (5). 5. Electrical snap switch according to claim 3, characterized in that the rotary body (39) is arranged longitudinally displaceable in the actuator (40) and against the force of an between Rotary body (39) and actuator (40) supporting compression spring (45) with an adjusting screw (46) is adjustable. 6. Electrical snap switch according to claim S, characterized in that the force of the biased Compression spring (45) over its entire adjustable range is greater than that in the direction the compression spring (45), but opposing force components of the snap springs (19, 20, 50, 51). 7. Electrical snap switch according to claim 5 or 6, characterized in that the compression spring (45) is dimensioned so that after actuating the snap switch via the actuating element (39,40) And reaching an end position of the contact system and the rotary body (39), the actuating member (40) by compressing the compression spring (45) under certain circumstances has an additional overtravel up to its block height 8. Electrical snap switch according to one of claims 5 to 7, characterized in that the Compression spring (45) is dimensioned so that it is along the path of the actuating member (39, 40) in comparison to the counteracting component of the force exerted by the snap springs (19, 20, 50, 51) stronger in the area of the snap point, but towards the end position of the actuating member (39, 40) is weaker than this component and that it has a flatter characteristic than the snap springs (19, 20,50,51) 9. Electrical snap-action switch according to one of the preceding claims, characterized in that the rotary movement of the two contact bridges (49) about the axis of the rotationally symmetrical section of the actuating member (5, 25, 39, 40) by lugs (17a, 17b, 18a, 186; each insulating piece (17, 18), which face the respective adjacent housing walls, is narrowed 10. Electrical snap-action switch according to one of the preceding claims, characterized in that that in the housing parts (1,2) positive opening levers (56, 57) are mounted, which after pressing of the actuator (5,25,39,40) and not after Once the contact system has snapped, a non-positive connection between the rotationally symmetrical Section of the actuator (5, 25, 39, 40) and the intermediate insulating pieces (17, 18, 52,53) or the one contact bridge.