EP0399419B1 - Electric snap-action switch particularly micro switch - Google Patents

Description

The invention relates to an electrical snap-action switch, in particular microswitch, with a housing which has fixed and movable contacts, with a switching rocker which takes up the individual switching positions and is designed as a moving contact and which carries at one end two spaced-apart pivot axes around which the switching rocker is pivotally mounted on a holding bearing, with a switching spring engaging with one end on the switching rocker, which is attached with its second end to the housing and which pulls the switching rocker with its two pivot axes against the holding bearing and with a regionally mounted in the housing out of the housing outstanding movable actuator, wherein a region of the switching spring is arranged between two projections of the actuator and the actuator transfers the shift rocker into its switching positions during a movement, in this case the shift rocker is of a middle Switching position can be pivoted in one pivot direction about one pivot axis and in the other pivot direction about the other pivot axis. Such switches DE-GM 84 19 891 are because of their sudden switching and because of their several Switch positions like used. The disadvantage, however, is that the bearing points of the rocker arm are shifted to carry out the switching movement. Projections of the actuator frame the switch spring, but they do not grip the switch spring. However, the switching movement of the shift rocker takes place in that the bearing points of the shift rocker are shifted, the same applies to DE-AS 15 15 876). In another embodiment of DE-GM 84 19 891, the holding contact for the rocker arm is a fixed contact, but there the switching spring is attached directly to the actuator, so that relatively large movements had to be carried out so that a transfer of the rocker arm into a different switching position could take place. In addition, the actuator had to be particularly loaded with another spring so that the switch can be safely transferred to its individual switching positions. The actuator was then moved against the force of this second spring.

The object of the invention is to increase the field of application of the switch in a switch of the type mentioned, on the other hand, the switchover should take place safely, finally the switching spring itself should also exert a restoring force on the actuating element, the switch overall being a cheap construction as well as inexpensive manufacture. In addition, the switch should have a small size. This is done according to the invention in that the holding bearing is designed as a fixed contact, that the projections engage the switching spring when the actuating member moves and that the projections move areas of the switching spring when the actuating member moves, in this case the switching spring loads the actuating member via the projections Reset sense for setting the middle switching position of the shift arm.

The fact that the shift rocker is located on a fixed bearing designed as a fixed contact, precisely defined bearing points are given during the pivoting movement of the shift rocker, which ensures that the shift rocker is safe and in its individual switching positions can be moved suddenly. Characterized in that a central region of the switching spring is attacked directly by projections of the actuator and moved upon actuation, the entire spring follows the actuator directly when the actuator is moved, as a result of which the spring is deflected and further tensioned, so that finally when the switching point is reached is, a sudden changeover takes place. In addition, however, it is also ensured that a restoring force is exerted on the actuator by the framed spring, in such a way that the switching spring tries to hold the actuator either in a central position, in which the spring line of action lies between the two pivot axes, or at Release of the actuator returns to the middle position.

Advantageously, the actuating element that moves the switching spring is designed as a sliding actuation which protrudes with one or both ends of it as a handle from the housing. This configuration results in a simple construction of the switch, since the switching rocker can be moved by hand in both directions by means of the slide-like actuating member, and it automatically returns to its central position after the actuating member has been released. The handle with actuator can either be pulled out or pushed in to the Switching the shift rocker from the middle position or operating from two sides of the housing.

In another exemplary embodiment of the invention, the actuating element which moves the switching spring is designed as an actuating element which is rotatably mounted on the housing between the switching positions and which projects at least with its handle from the housing. The fact that the actuator itself is rotatably mounted on the housing ensures an accurate and safe movement of the actuator. In addition, the area of application of the switch can be increased further by the actuator, since the actuator can be controllable via a switching drum.

In a special exemplary embodiment of the invention, the shift rocker arm has two cutting edge bearings, which are parallel and spaced apart from one another and which act on the holding bearing. The two cutting edge bearings enable the swivel axes to be formed in a simple manner, and moreover a safe switching around both swivel axes is possible. It is recommended that the rocker arm is constructed as a folding contact which has the contacts in the folding area and whose folding ends forming the pivot axes are angled at an acute angle in opposite directions. This measure allows the shift rocker to be produced in a simple manner with its two pivot axes, the two pivot axes being able to be produced in a simple manner by the two bends. In addition, such a design of the swivel axis allows for a slight self-suspension of the angled folding ends Touching the contacts of the switching rocker with fixed counter contacts causes a slight intrinsic movement between the contacts, which destroys any oxide layers that hinder the current flow.

In another embodiment of the invention, the shift rocker is constructed in the form of an isosceles triangle in a transverse view. The main tip of the isosceles triangle carries the contacts, while the other two tips each form a pivot axis. Here, too, a shift rocker is produced in a simple manner, which has two shift axes, but is nevertheless inexpensive to manufacture.

In a further exemplary embodiment of the invention, the switching rocker made of sheet-like material is U-shaped. Her two legs forming the two pivot axes are divided into two areas by a slot, which are angled towards different sides. With such a configuration of the switching rocker, a simple plate-shaped material is required, in which two pivot axes spaced apart from one another can be formed by the bend.

In a further exemplary embodiment, a channel-like depression is provided on the holding bearing in the region of the two pivot axes of the shift rocker. The channel width corresponds to the distance between the two swivel axes. With such a design, the production of the counter bearing for the cutting-like bearings of the rocker arm is particularly easy to design.

Advantageously, in the middle position of the switching rocker arm, in which both pivot axes rest on the holding bearing, the force line of the switching spring lying perpendicular to the pivot axes runs between the two pivot axes. With such a design, the setting of the central position of the snap switch is achieved in a simple manner, while at the same time ensuring that the switching spring itself exerts a restoring moment in this central position on the switching rocker during a pivoting movement. Depending on the amount of spring force, the shift rocker is secured against swiveling. It is advisable here for the projections for the co-movement of the switching spring to be formed as boundaries of a recess in the actuating member which is guided in the manner of a link. With this design, the switching positions can be set in a simple manner by the switching rocker since, depending on the direction in which the actuating member is moved, the spring and thus the spring force line is displaced, so that the switching rocker pivots. In addition, due to the regionally encompassing the switching spring, the recess provides intermediate support for the actuator, switching spring and switching rocker when the switch is assembled.

Conveniently, when the switch is designed as a pressure switch, the actuator protrudes from the housing with one end as a handle, while a compression spring is provided at its other end, by means of which the actuator is preloaded in one direction. A transition into the individual switching positions occurs due to the different depths of penetration of the actuator into the housing.

In another embodiment of the invention, in which the switch is provided as a swivel switch, one arm of a pivotable angle lever engages in the receptacle of the link-like actuating element, while the other arm projects out of the housing as a handle. In this arrangement, the different switching positions occur by simply pivoting the angle lever, the special design of the switching spring in conjunction with the two pivot axes converting the pivoting lever itself into a central position with its handle.

In a special embodiment of the invention, the two projections of the actuating element, viewed in the longitudinal direction of the switching spring, engage the switching spring between the holding bearing and the second fastening point of the switching spring provided on the housing. This results in a secure tension of the switching spring during a rotary movement of the actuator, whereby even small angular amounts in the rotary movement increase the tension, moreover, even with small amounts of angle of rotation of the rotary actuator, the switch from one switching position to the other takes place suddenly. Nevertheless, the structure of the switch is simple. The pivot axis of the actuating element is advantageously arranged on the side of the holding bearing facing away from the projections, in order to achieve a reliable switchover with regard to the rotational movement even with very small angular amounts.

In an advantageous embodiment of the invention, the switch housing is constructed in two parts, in this case are on as an insert in the second housing part trained first housing part arranged the switching rocker, the fixed contacts and the switching spring. This measure ensures that the first housing part can be preassembled with the switching parts and can then simply be inserted into the other housing part. The rotary actuator is favorably mounted on the second housing in order to achieve a safe and simple bearing point for the rotary actuator, but nevertheless to ensure that a safe switchover of the switch is possible.

In a further exemplary embodiment, the rotary actuator is constructed in two parts from a handle part and a switching part, in this case the two parts are connected to one another in a rotationally fixed manner in the region of the axis of rotation of the actuator, with the handle part being able to be snapped into a receptacle of the switching part by a projection through the outer housing . This measure allows a cheap construction of the housing, moreover, after insertion of the one housing, it is possible to securely fix the two parts of the actuator.

The insertion openings in the second housing part can advantageously be sealed off from the housing insert and handling part by a sealing ring, in order to reliably protect the inside of the switch against the ingress of moisture and contaminants.

In order to further enlarge the field of application of the switch, the switching part of the actuating member has a compression spring at its end facing away from the axis of rotation, which prestresses the rotary actuating member in one direction of rotation. With this measure, the switch can be easily converted so that the switch can be moved from a first switch-on position to a switch-off position and then into a second switch position. Such a design will be chosen if the second switch-on position should only be switched on for a short time.

The pivotable actuating element advantageously rests with the free end of its handle part against a roller section provided with switching cams. As a result of this measure, the transfer into the individual circuits can be carried out simply by rotating the roller section.

Fig. 1

den Schnappschalter als Schwenkschalter,

Fig. 2

den Schnappschalter als Druckschalter,

Fig. 3

eine Draufsicht des Schalters nach Fig. 2, teilweise im Schnitt,

Fig. 4

ein weiteres Ausführungsbeispiel der Schaltschwinge,

Fig. 5

eine Seitenansicht der Schaltschwinge nach Fig. 4 und

Fig. 6

das kulissenartige Betätigungsglied.

Fig. 7

einen Schnitt durch das Schaltergehäuse gemäß der Linie VII - VII der Fig. 8,

Fig. 8

einen Querschnitt durch das Schaltergehäuse,

Fig. 9

einen Teilschnitt nach der Linie IX-IX der Fig. 8.

The subject matter of the invention is shown in the drawing in several exemplary embodiments, namely:

Fig. 1

the snap switch as a swivel switch,

Fig. 2

the snap switch as a pressure switch,

Fig. 3

2 shows a plan view of the switch according to FIG. 2, partly in section,

Fig. 4

another embodiment of the shift rocker,

Fig. 5

a side view of the rocker arm according to FIGS. 4 and

Fig. 6

the backdrop-like actuator.

Fig. 7

6 shows a section through the switch housing according to line VII-VII of FIG. 8,

Fig. 8

a cross section through the switch housing,

Fig. 9

a partial section along the line IX-IX of FIG. 8.

The switch shown in FIG. 1 has an outer housing 10 and an inner housing 11. The inner housing 11 is mounted as an insert in the outer housing 10. From the outer housing 10, a handle 13 protrudes from an opening 12, with which the switch can be moved into its various switching positions. In the switch shown in Fig. 1, the handle is pivotally provided. 10 also protrude from the outer housing 10, 14, 15, 16, which are mounted in the inner housing 11. The connection contact is formed in the interior of the housing as a holding bearing 17, while the connection contact 15 leads to a first stationary contact 18 and the connection contact 16 leads to a further stationary contact. As can be seen from FIG. 1, a shift rocker 20 is provided on the holding bearing 17. This rocker arm 20 is pivotable and connects to the two fixed contacts 18 and 19 depending on the switching position.

The rocker arm 20 is designed here as a folding contact. In this case, a double contact 22 is provided in the folding area 21, one part of which contacts the stationary contact 18 and the other part of which contacts the stationary contact 19.

The free ends 23, 24 which arise from the folding of the switching rocker and which lie opposite the folding region 21 are, as shown in FIG. 1, angled at an acute angle. At their free end they run together in a wedge shape and form cutting edges 25 which carry the pivot axes 26, 27 at their free end. The cutting edges 25 of the free ends 23, 24 engage in notch-like depressions 28 of the holding bearing 17. It remains to be added that the rocker arm carries an opening 29. One end 55 of a switching spring 30 is hooked into this opening. Furthermore, it should also be mentioned that the rocker arm 20 has a U-shaped cutout 31 in plan view, which is open towards the side of the cutting edges 25. This U-shaped cutout takes up an area of the switching spring 30.

Likewise, the holding bearing 17 is forked. Here, the fork space 32 receives areas of the switch spring 30.

The other end 54 of the switch spring 30 is fixedly mounted on the inner housing. For this purpose, a cross pin 33 is provided, on which the second end of the switching spring is suspended.

Between the cross pin 33 and the holding bearing 17, a link-like actuating member 34 is provided, which receives 35 areas of the switching spring 30 in a recess. The actuator 34 is essentially Movable perpendicular to the longitudinal axis of the switching spring 30 and guided in the housing 11. It should already be stated here that regions of the switching spring 30 are also moved when the actuator is moved. For this purpose, two opposite edge regions of the recess 35 form projections 56, which engage the switching spring 30 when the actuating member 34 moves, and move regions of the switching spring 30.

The actuator 34 is further provided with an opening 36. An arm 37 of an angular pivot lever 38 engages in this opening 36. The second arm 39 of the pivot lever 38 is designed as a handle 13 and, as already mentioned, protrudes from the outer housing 10. The swivel lever itself is mounted on the housing. 1, the actuating member 34 moves upward, while in the case of a pivoting movement counterclockwise the actuating member 34 is moved downward in its guide 40. During this upward and downward movement of the actuating member, as already mentioned, part of the spring 30 is taken along. As a result, the line of action 52 of the spring changes with respect to the switching rocker 20. When the actuating member moves downward, the switching rocker receives a downward force component due to a downward moving spring area, so that the contact 22 can come into contact with the stationary contact 18. At the same time, however, the shift rocker is also pulled against the holding bearing 17 via a further force component of the shift spring.

As can be seen from the drawing, the deflected switching spring also acts as a force component on the actuator 34, namely in the upward direction, so that when the handle is released, the actuator 34 moves into its position shown in FIG. 1. As a result of this movement, the line of action 52 of the spring changes with respect to the switching rocker, namely the line of action now lies between the two pivot axes 26 and 27 of the switching spring. This causes the switching rocker to pivot back so that the contact 22 is released from the connection contact 18.

When the handle is moved clockwise, the actuating member 34 is moved upward, as already mentioned. As a result, the spring force line 52 of the switching spring 30 is moved beyond the pivot axis 27, so that the switching rocker also receives an upward switching component and thus can pivot with its contact 22 against the stationary contact 19.

When the handle 13 is released, the actuating member 34 is moved back by the spring via the tensioned switching spring, so that the switching spring comes to rest again between the two pivot axes of the switching rocker and thus the switching rocker is pivoted into its position shown in FIG. 1.

It should be added here that with a clockwise movement, as can be seen from FIG. 1, the shift rocker swivels about the pivot axis 27 against the stationary contact 19, while with a clockwise movement the shift rocker pivots about the pivot axis 26 and then in Contact with the fixed contact 18 occurs.

Furthermore, it should be added that if the spring force line comes to lie outside of the pivot axes due to the movement of the actuating element, the switching rocker arm is switched over abruptly in a manner known per se, since the spring will then automatically attempt to switch the rocker arm about the respective pivot axis 26 to move around.

Instead of the pivot lever 38, the actuator 34 could be provided with an extension protruding from the housing, which serves as a handle. By pushing in or pulling out the handle, the shift rocker could then be pivoted, as described, the resetting is then carried out again by the shift spring. It would also be possible to extend the actuator on both sides, so that there are handles protruding from the housing at both ends, which then cause a switchover by pushing in and / or pulling out.

In the exemplary embodiment according to FIG. 2, a structure similar to that in FIG. 1 is given. In this embodiment, however, the switch is designed as a pressure switch.

The actuator 34 has an extension 41 which protrudes through an opening 42 in the housing and forms the handle 13 there outside the housing. The actuator is loaded at the end opposite the handle with a compression spring 43 which tries to always move the actuator 34 to its upper position.

When the actuator 34 moves then again the pivoting of the rocker arm 20 about its pivot axes 26 and 27. Furthermore, it should also be mentioned in this embodiment that the rocker arm is approximately triangular in side view and in the manner of an isosceles triangle. Here, the main tip 44 of the isosceles triangle carries the contact 22, while the other two tips 45, 46 are assigned to the pivot axes 26 and 27. When the spring is deflected by the actuator, the switching rocker is then pivoted again. In this exemplary embodiment, the two pivot axes 26, 27 of the switching rocker 20 engage in a channel-like recess 53 of the holding bearing 17 for mounting purposes.

In the embodiment of FIGS. 4 and 5, the shift rocker is made of a plate-shaped material. It has the U-shaped cutout 31 at its lower end, the two U-legs 47 and 48 in turn having a longitudinal section 49 which divides the two U-legs into regions 50 and 51. The area 50 of both U-legs 47, 48 is angled in one direction, while the area 51 of the two U-legs 48, 49 is angled to the other side at an acute angle: (FIG. 4).

The free ends of the areas 50 of the U-legs 47 and 48 then take up the pivot axis 27 of the shift rocker, while the two areas 51 carry the pivot axis 26.

In Fig. 6 the backdrop-like actuator is shown in more detail. The recess 35 is C-shaped, so that the spring 30 from the side into the Recess 35 can be inserted. The boundaries of the recess 35 form projections 56 with which the switching spring is moved. The opening 36, however, is closed on all sides. As already mentioned, the arm 37 of the swivel lever 38 engages in it.

It remains to be added that the U-shaped shift rocker and the forked holding bearing can be seen in Fig. 3 in plan view. It should also be mentioned here that the area between the U-shaped cutout 31 and the opening 29 has a somewhat smaller thickness, see FIG. 1, so that the switching spring 30 suspended there has an almost point-shaped point of application.

The snap switch shown in FIGS. 7 to 9 is constructed as a built-in switch. It is installed in a device wall 112.

The housing of the switch consists of two parts, namely an outer housing part 110 and a withdrawable housing part 111. The two housing parts are fastened to one another by a latching connection (not described further).

The actuator 113 of the switch is constructed angularly and consists of two parts, a handle part 114 and a switching part 115. The two leg-like parts are connected in that the handle part 114 is assigned a shoulder 138 which engages in a receptacle 116 of the switching part, whereby this recording has undercuts, which is engaged by projections, so that the two parts of the angular actuator 13 is attached to each other by a locking connection 117. The handle part 114 and the switching part 115 are non-rotatably connected to one another by the non-circular cross section of shoulder 138 and receptacle 116, the axis of rotation 137 of the actuating member leading through the shoulder and seat.

In order to reliably protect the inside of the switch against the ingress of moisture and impurities, a sealing ring 118 is provided around the insert 111, the sealing ring 118 taking up its function when the two housing parts 110 and 111 are fastened to one another, and the sealing ring 119 is also used arranged around the shoulder 138 of the handle part 114 and seals its inlet opening into the interior of the housing.

The insert 111 carries the various fixed contacts 120 and 121, these contacts being cast in some areas with the insert itself.

The fixed contact 121 carries a holding bearing 123 on the inside of the housing, on which a rocker arm 122 is supported. The fixed contacts 120 have mating contacts. Depending on the switching position, they alternately make an electrically conductive connection with one end of the rocker arm 122.

The rocker arm 122 is associated with two pivot axes 124, 125, here the rocker arm pivots about the pivot axis 124 when it is pivoted clockwise in Fig. 7, while it moves about the pivot axis 125 when it is from that shown in Fig. 1 Middle position of the rocker arm is moved from counterclockwise.

The shift rocker 122 has an opening, not designated in any more detail, in which a switch spring 126 is suspended with its spring end 130. The other spring end 129 of the switching spring 126 is mounted on the insert 111. For this purpose, it engages around a pin 127 provided on the insert.

The arrangement of the pin 127 of the two pivot axes 124, 125 and the fastening end 130 of the spring is designed such that the spring line of action 136 extends between the two pivot axes 124, 125 in the central position.

The switching part 115 is provided with projections 128 at its end facing away from the connection point with the handling part 114, in this case the two projections, see FIG. 7, encompass the switching spring directly behind the holding bearing 123 for the switching rocker 122.

If the actuating member is now pivoted in regions clockwise, a spring region of the switching spring 126 is pivoted downward, as seen in FIG. 7. As a result, the spring action line 136 comes to lie below the pivot axis 125, so that the switching rocker swings suddenly against the lower fixed contact 120, in this case the switching spring 126 lies on the upper of the two projections 128. If the handling part is now released, then due to the spring tension in the Switch spring 126, the rocker arm pivoted back so that it returns to its position shown in Fig. 7. The switching part turns counterclockwise moves, the rocker arm 122 pivots clockwise and the rocker arm is moved against the upper fixed contact 120. The spring 126 is also slightly tensioned here, this time the spring resiliently loading the lower projection 128 of the two projections of the switching part. When the handle part is released, the shift rocker automatically swings into its central position. In this middle position there is no electrically conductive connection between the fixed contacts 120 on the one hand and the fixed contact 121 on the other hand.

The three positions of the actuator and their projections 128 are shown in Fig. 7, here the middle position is shown fully drawn, while when pivoting the actuator in the counterclockwise direction this end position is shown dotted. The end position when the actuator is moved in the clockwise direction is shown in dash-dot lines, as can be seen from FIG. 7.

As can be seen in particular from FIG. 9, the switching part is provided with an extension 131 at its free end. A compression spring 132 is supported on this extension in such a way that the actuator is resiliently loaded in the clockwise direction.

This makes it possible for the free end 133 of the handle part 114 to connect to switching cams 134 which are provided on a roller section 135, the switching actuation of the actuating member then taking place by rotation of the roller section.

It remains to be added that the rocker arm is U-shaped, here is the central opening of the fastening opening for the switching spring, while the two side legs together have both pivot axes 124, 125, the two pivot axes engaging in unspecified recesses of the holding bearing 123.

It must also be added that the insert 111 is fully assembled before it is inserted into the outer housing part 110, i. is provided with the rocker arm and the switching spring, in addition, the switching part 115 of the actuator with the compression spring 132 is arranged in a receptacle of the insert. After insertion, as already mentioned, there is a latching between the two housing parts 110 and 111, and the handle part 114 can then also be fastened to the switching part.

As already mentioned, the illustrated embodiments are only examples of realizations of the invention. This is not limited to this, but many other changes and applications are still possible. For example, the actuator could also be formed in one piece, the switching part with the projections being designed as a rotating link instead of the pivotable mounting shown. The pivoting movement of the actuator then takes place through a positive guidance in the insert. One end of the rotating link would then protrude from the housing and could in turn be operated by switching cams or by hand. The rotating link could also be equipped with an extension, at the end of which the compression spring 132 would be arranged. Could continue if there is little space is given for the movement of the actuator, this can be arranged even closer to the holding bearing. It should also be mentioned that the snap switch can not only be constructed as a microswitch. For example, it could also be used as a push button or even a push button switch in the house installation. Furthermore, several switching rockers could be arranged next to one another in order to enable multi-pole switching, or to be able to open or close further switching circuits.

Claims (18)

1. An electric snap-action switch, in particular a microswitch, comprising

   a housing (10, 11; 110, 111)
      which has stationary (17, 18, 19; 120, 121) and movable contacts (20, 22; 122),

   a switching rocker member (20; 122) which is in the form of a movable contact and which assumes the individual switching positions and
      which at its one end carries two spaced-apart pivot axes (26, 27; 124, 125) about which the switching rocker member (20; 122) is mounted pivotably on a holding mounting (17; 123),

   a switching spring (30; 126) which with its one end (55; 130) engages the switching rocker member (20; 122) and
      which is fixed with its second end (54; 129) to the housing (11; 111) and which pulls the switching rocker member (20; 122) with its two pivot axes (26, 27; 124, 125) against the holding mounting (17; 123), and

   a movable actuating member (34, 13; 113, 114, 115) which is mounted in the housing (10, 11; 110, 111) and which projects region-wise out of the housing,

   wherein a region of the switching spring (30; 126) is arranged between two projections (56; 128) of the actuating member (34; 113) and upon movement thereof transfers the switching rocker member (20; 122) into its switching positions,

   in which case the switching rocker member (20; 122) is pivotable from a central switching position in the one pivotal direction about the pivot axis (26; 125) and in the other pivotal direction about the other pivot axis (27; 124),

   characterised in that

   the holding mounting (17; 13) is in the form of a stationary contact (17; 121), that the projections (56; 128) engage the switching spring (30; 126) upon a movement of the actuating member (34; 113) and that upon a movement of the actuating member (34; 113) said projections (56; 128) move regions of the switching spring (30, 126) out of the central position thereof,

   in which case the switching spring (30; 126) loads the actuating member (34; 113) by way of the projections (56; 128) in the resetting direction for setting the central switching position of the switching rocker member (20; 122).
2. An electric snap-action switch according to claim 1 characterised in that the actuating member (34) which moves the switching spring (30) is in the form of a slider-type sliding actuating member which projects with one or its two ends as a handle out of the housing (10, 11).
3. An electric snap-action switch according to claim 1 characterised in that the actuating member (113) which moves the switching spring (130) is in the form of an actuating member which is rotatable between the switching positions and which is mounted on the housing (110, 111) and which projects at least with its handle (114) out of the housing (110, 111).
4. An electric snap-action switch according to one of claim 1 to 3 characterised in that the switching rocker member is constructed as a folded contact which in the fold region (21) has contacts (22) and whose fold ends (23, 24) which form the pivot axes (26, 27) are angled through an acute angle in opposite directions.
5. An electric snap-action switch according to one of claims 1 to 4 characterised in that in transverse view the switching rocker member (20) is in the form of an isosceles triangle, in that case the main tip (44) of the isosceles triangle carries the contacts (22) while the other two tips (45, 46) each form a respective pivot axis (26, 27).
6. An electric snap-action switch according to one of claims 1 to 4 characterised in that the switching rocker member (20) which is made from material in sheet form is of a U-shaped configuration, in this case its two limbs (47, 48) which form the pivot axes (26, 27) are each subdivided by a slot (49) into two regions (50, 51) which are angled towards different sides.
7. An electric snap-action switch according to one of claims 1 to 5 characterised in that provided in the region of the two pivot axes (26, 27) of the switching rocker member (20) on the holding mounting (17) is a channel-like depression (53), in this case the channel width corresponds to the spacing of the two pivot axes (26, 27).
8. An electric snap-action switch according to one of claims 1 to 7 characterised in that the projections (56), for also moving the switching spring (30), are formed as boundaries of an opening (35) in the actuating member (34).
9. An electric snap-action switch according to one of claims 1 to 8 characterised in that, when the switch is in the form of a pressure switch, the actuating member (34) projects with its one end (41) as a handle (13) out of the housing (10) while a compression spring (43) acts on its other end.
10. An electric snap-action switch according to one of claims 1 to 8 characterised in that, when the switch is in the form of a pivot switch, the one arm (37) of a pivotable angle lever (38) engages into a receiving means (36) in the slider-type actuating member (34), the other arm (39) of the angle lever (38) projecting as a handle (13) out of the housing (10).
11. An electric snap-action switch according to one of claims 1 to 10 characterised in that the two projections (56; 128) of the actuating member (34; 113), as viewed in the longitudinal direction of the switching spring (26), act on the switching spring (30; 126) between the holding mounting (17; 123) and the second fixing location (54; 129) of the switching spring (30; 126), which is provided on the housing (11; 111).
12. An electric snap-action switch according to one of claims 1 to 11 characterised in that the pivot axis (137) of the actuating member (113) is arranged on the side of the holding mounting (123) which is remote from the projections (128).
13. An electric snap-action switch according to one of claims 1 to 12 characterised in that the switch housing (10, 11; 110, 113) is of a two-part construction, in this case the switching rocker member (20; 122), the stationary contacts (17, 18, 19; 120, 121) and the switching spring (30; 126) are arranged on the first housing portion (11; 111) which is in the form of an insert (11; 111) into the second housing portion (10; l10).
14. An electric snap-action switch according to one of claims 1 to 13 characterised in that the rotary actuating member (113) is mounted on the second housing portion (110).
15. An electric snap-action switch according to one of claims 1 to 14 characterised in that the rotary actuating member (113) is made up in two parts from a handle portion (114) and a switching portion (115), in this case the two portions (114) and (115) are non-rotatably connected together in the region of the axis of rotation (137) of the actuating member (113), wherein to make the connection the handle portion (114) is arranged engageably with a step portion (138) which extends through the outer housing (110) in a receiving means (116) in the switching portion (115).
16. An electric snap-action switch according to one of claims 1 to 15 characterised in that the insertion opening in the second housing portion (10; 110) in respect of the housing insert (11; 111) and the handle portion (114) can be sealed off by a sealing ring (118, 119).
17. An electric snap-action switch according to one of claims 1 to 16 characterised in that at its end remote from the axis of rotation (137) the switching portion (115) of the actuating member (113) is loaded by a compression spring (132) which biases the rotary actuating member (113) in a direction of rotation.
18. An electric snap-action switch according to one of claims 1 to 17 characterised in that the rotatable actuating member (113) bears resiliently with the free end (133) of its handle portion (114) against a roller portion (135) provided with switching cams (134).

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