DE19858118C1 - Electrical switch for electrical systems, has rocker with mechanism that defines switch operating positions - Google Patents

Abstract

The electrical switch has a rocker (2) that is pivot mounted (9) on a pair of coupled contact arms (14,18). These have a lower pivot point (13) that locate in holes in posts (16) in a base (15) and operate against contact pads (3) on a plate. The rocker has a projecting pin (6) that locates in a slot in a cover, that determines the switch positions.

Description

The present invention is based on one according to the preamble of Main claim designed switch arrangement.

Such switch arrangements are intended for one or more electrical circuit (s) by influencing the stationary in the housing and to interrupt or close movably arranged electrical switching contacts conclude. So it is possible for the user to go through the actuator Switching the electrical circuits on, off and on A multitude of functions in a convenient way using just one Switch actuator on or off. Often over such electrical switch assemblies the various functions of a sliding Sunroof of a motor vehicle affected.

DE 39 31 722 C2 is one of the preamble of the main claim corresponding electrical switch arrangement has become known. This Electrical switch arrangement has the electrical switch contacts housing on which a single in several  Switch positions bringable actuator is stored. The Actuating element is for guiding and limiting the adjustment path via two molded axle stub each in an existing in the housing, in Elongated slot rotatable and slidably mounted. At the same time, the actuating element engages two in the sliding direction spaced apart from the two integrally formed stub axles on Actuator existing cam each in a likewise in Housing existing, cross-shaped backdrop swivel and slidable one. The actuating element is accordingly analogous the functions of a sunroof. The Actuator are assigned to several contact pieces, which for Realization of the various switching functions the movements of the Actuator on the movable electrical switch contacts transfer. In addition, the switch arrangement has several spring-loaded control devices, which ensure that the Actuator not inadvertently moved out of its basic position is automatically in or out of its various switching positions his basic position returns. One constructed in this way However, the switch arrangement is not just made up of a considerable number of complicated parts to assemble, which is significant Causes costs, but also burdens the movable electrical Switch contacts, through the pronounced pivoting movements of the Switch elements when they are actuated. So the movable electrical Switch contacts with correspondingly high lateral forces.

In addition, DE 34 15 997 C2 has a switch arrangement become known, the actuating element also in the sense of Functional movements of a sunroof starting from its Basic position can be brought into several switch positions. The storage of the  Actuating element also takes place via two stub axles, which and slidable in each case in an elongated hole in the housing and at the same time over two Guide cams, which can be pivoted and slid into a cross-shaped Intervene the backdrop of the housing.

The present invention is therefore based on the object electrical switch arrangement of the type mentioned above to further develop so that the directions of movement of the contact pieces as possible exactly the adjustment directions of the associated movable corresponds to or correspond to electrical switching contacts, i.e. transverse forces, practically does not occur due to the actuation.

According to the invention, the task is performed in the characterizing part of Main claim specified features solved.

Advantageous in such an embodiment of an electrical Switch arrangement is that from an operation made movable electrical switch contacts resulting, latently stored Forces almost in full to reset the actuating element come into effect. A reliable reset of the Actuator is therefore without the use of additional Reset means realized.

Further advantageous configurations of such an electrical Switch arrangement are specified in the subclaims.

Based on two embodiments shown in the drawings, the The subject of the invention explained in more detail and show

Fig. 1 shows in principle a side view of a first switch arrangement

Fig. 2 in principle a first switch arrangement in an exploded view without a housing

Fig. 3 shows in principle a side view of a first switch arrangement without housing in the basic position

Fig. 4 shows in principle a side view according to Fig. 3, wherein a switching position is achieved by a pivoting movement

FIG. 5 shows, in principle, a side view according to FIG. 3, a switching position achieved by a sliding movement being reached

Fig. 6 in principle, a second switch arrangement in an exploded view without a housing

Fig. 7 shows in principle a side view of a second switch arrangement without a housing in the basic position

Fig. 8 in principle a rear side view of a second switch arrangement without housing in the basic position

FIG. 9 shows, in principle, a spatial representation of the switch arrangement according to FIG. 7, a first switching position that can be achieved by a pivoting movement being achieved

Wherein a realizable by a sliding movement of first shift position is reached Fig. 10 by way of principle a perspective view of the switch assembly of FIG. 8,

Fig. 11 by way of principle a perspective view of the switch assembly of FIG. 8, wherein a realizable by a sliding movement of second switching position is reached.

As can be seen from the figures, such a switch arrangement essentially consists of a housing 1 , an actuating element 2 mounted on the housing 1 , which can be brought into several switching positions, and the movable electrical switching contacts 3 arranged in the housing 1 and necessary for realizing the various switching positions the associated stationary electrical switch contacts 4 .

As can further be seen from the figures, the actuating element 2 can be displaced from its basic position in the direction of an imaginary longitudinal axis and is mounted on the housing 1 so as to be pivotable about a transverse axis running perpendicular thereto. In order to limit the adjustment path and to precisely guide the actuating element 2 , a cross-shaped link 5 is formed in each of the two longitudinal walls of the housing 1 running parallel to the sliding direction. The two cross-shaped backdrops 5 are designed as window-like slots. On the two side walls of the actuating element 2 extending in the sliding direction, two guide cams 6, each engaging in one of the two scenes 5 , are formed. The two guide cams 6 thus each pivot and slidably engage in one of the two cross-shaped scenes 5 , so that the actuating element 2 analogously, for. B. is to be adjusted according to the function of a sliding / lifting roof. The possible applications of such switch arrangements are in no way limited to devices designed as sliding / lifting roofs. Rather, the application for other devices with similar adjustment options can be easily implemented. Only in this context, for example, is to be adjusted to power-operated devices, such as. B. vehicle seats, the vehicle steering wheel, etc. pointed out.

As shown particularly in Fig. 1 to Fig. 5 is apparent, for realizing the various adjustment movements on the underside of the operating element 2 is attached a hinge mechanism. A first bearing block 7 for the articulated mechanism formed on the underside of the actuating element 2 has a first bearing point 8 and a second bearing point 9 one behind the other in the sliding direction. The first bearing point 8 and the second bearing point 9 are each classically formed from a bearing eye and bearing journal. A first contact piece 14 , which comes to bear against a first and a second movable switching contact 3 under pretension, is connected to a second bearing block 10 , which is arranged opposite the first bearing block 7 . The second bearing block 10 is integrally formed on the essentially rocker-like first switching piece 14 via a rod-shaped arm. The second bearing block 10 also has a third bearing point 11 and a fourth bearing point 12 arranged one behind the other in the sliding direction of the actuating element 2 . The third bearing 11 and the fourth bearing 12 are integrally formed as film hinges. In addition, a fifth bearing point 13 is formed centrally between the third bearing point 11 and the fourth bearing point 12 on the second bearing block 10 and on the first contact piece 14 . The fifth bearing 13 is formed by two stub axles, each of which represents an extension of the rod-shaped arm. The first contact piece 14 or the second bearing block 10 is pivotably held on a third bearing block 16 on the base part 15 of the housing 1 via the fifth bearing point 13 . The integrally formed third bearing block 16 consists of two bearing arms projecting perpendicularly from the main surface of the base part 15 and receiving the first switching element 14 and the second bearing block 10 between them . Between the first bearing point 8 and the third bearing point 11 designed as a film hinge, a second contact piece 17, which is assigned to a third movable electrical switching contact 3 , is movably mounted. In addition, a third contact piece 18, which is assigned to a fourth switching contact 3 , is arranged in an articulated manner between the second bearing point 9 and the fourth bearing point 12 designed as a film hinge. Both the second contact piece 17 and the third contact piece 18 are essentially L-shaped. The joint mechanism thus has three one-piece switching elements 14 , 17 , 18 which can be actuated independently of one another and which have five bearing points 8 , 9 ; 11 , 12 ; 13 are kept movable. The joint mechanism itself is in turn articulated between the first bearing block 7 and the third bearing block 16 .

Starting from its basic position shown in FIG. 3, the actuating element 2 can be brought into four different switching positions. Two switching positions can be reached by moving in opposite directions and two further switching positions can be reached by pivoting the actuating element 2 in opposite directions. In order to ensure precise positioning of the actuating element 2 in its basic position and, at the same time, reliable return of the actuating element 2 from its four different switching positions to the basic position, the three switching elements 14 , 17 , 18 come under tension with their undersides facing away from the actuating element 2 assigned movable electrical switch contacts 3 to the system. The four movable electrical switching contacts 3 are integral with a dome switching mat 19 . The dome switching mat 19 in turn rests on the base part 15 of the housing 1 which has the four fixed electrical switching contacts 4 . The four fixed electrical switch contacts 4 and the associated conductor track structure, which is not shown for the sake of simplicity, are applied as metallizations directly on the main surface of the base part 15 facing the actuating element 2 .

As can be seen in particular from FIG. 4, the switch arrangement is in one of its two switch positions which can be reached by pivoting the actuating element 2 . By pivoting the actuating element 2 in one actuation direction, the articulation mechanism was deflected such that the first contact piece 14 and the second bearing block 10 were pivoted about the fifth bearing point 13 . The second contact piece 17 and the third contact piece 18 remain essentially in the basic position due to their connection via the third bearing point 11 and fourth bearing point 12 designed as film hinges. By pivoting the rocker-like switching element 14 , the associated movable electrical switching contact 3 was depressed and brought into contact with the associated stationary electrical switching contact 4 . The associated switching function is thus implemented. The force latently stored in the movable electrical switching contact 3 by the depression comes into effect almost completely when the actuating force is removed to reset the joint mechanism or the actuating element 2 . This is the case because the direction of movement of the first switching element 14 essentially corresponds to the direction of adjustment of the movable associated electrical switching contact 3 and thus no transverse forces arise.

As can be seen in particular from FIG. 5, the switch arrangement is in one of its two switching positions which can be reached by moving the actuating element 2 . By moving the actuating element 2 in one actuating direction, the articulation mechanism was deflected such that the second switching element 17 was pivoted about the third bearing point 11 , which was designed as a film hinge. The first contact piece 14 remains unaffected by its articulated connection, ie in the basic position. By pivoting the L-shaped second contact 17 , the associated movable electrical switch contact 3 was depressed and brought into contact with the associated stationary electrical switch contact 4 . The associated switching function is thus implemented. The force latently stored in the movable electrical switching contact 3 by the depression comes into effect almost completely when the actuating force is removed to reset the joint mechanism or the actuating element 2 . This is the case because the direction of movement of the second switching element 17 corresponds essentially to the direction of adjustment of the associated electrical switching contact 3 and thus no transverse forces arise.

The same applies mutatis mutandis to the functional sequence, the actuating element 2 is adjusted by pivoting or shifting in the other direction of actuation and thereby brought into the other switching position.

As shown particularly in Fig. 6 to Fig. 9 is apparent, for realizing the various adjustment movements is attached to the underside of the operating element 2, a wrist mechanism. A first bearing block 7 for the articulated mechanism formed on the underside of the actuating element 2 has a first bearing point 8 , an intermediate bearing point 20 and a second bearing point 9 lying one behind the other in the sliding direction. A second bearing block 10 is arranged opposite the first bearing block 7 at a distance. The second bearing block 10 also has a third bearing point 11 , a fourth bearing point 12 and a fifth bearing point 13 arranged one behind the other in the sliding direction of the actuating element 2 . The four bearings 8 , 9 ; 11 , 12 and the fifth bearing point 13 and the intermediate bearing point 20 are each classically formed from a bearing eye and bearing journal.

A first articulated arm 22 is movably received by the first bearing point 8 and the third bearing point 11 and a second articulated arm 23 is movably received by the second bearing point 9 and the fourth bearing point 12 . A fork-like intermediate member 24 is received on the one hand by the intermediate bearing point 20 of the first bearing block 7 , and on the other hand the intermediate member 24 has three prongs 25 , 26 , 27 . The middle tine 26 is received by the fifth bearing 13 of the second bracket 10 . The two outer tines 25 , 27 are arranged laterally outwardly from the middle tine 26 . The second bearing block 10 is in turn held via the fifth bearing point 13 so as to be pivotable by a third bearing block 16 present on the base part 15 of the housing 1 . The second bearing block 10 has, at its third bearing point 11 and at its fourth bearing point 12 , a rod-shaped extension 28 , 29 which projects laterally outwards and forms an extension of the bearing pins. The third bearing block 16, which is integrally formed on the base part 15, consists of two bearing arms projecting perpendicularly from the main surface of the base part 15 and receiving the second bearing block 10 so that it can pivot between them. The first articulated arm 22 , the second articulated arm 23 and the intermediate member 24 are movably received between the first bearing block 7 and the second bearing block 10 . The entire joint mechanism is in turn received in a pivotable manner via the second bearing block 10 through the fifth bearing point 13 on the third bearing block 16 .

Via the two rod-shaped projections 28 , 29 , a first contact piece 14 is assigned to bridge two movable electrical switching contacts 3 under pretension. The first contact piece 14 is formed like a rocker, and the two rod-shaped projections 28, 29 come in the middle region of the the actuating member 2 facing main surface of the first contact piece 14 to the plant. The two end regions of the first contact piece 14 rest with their main surface facing away from the actuating element 2 on the two associated movable electrical switch contacts 3 . Via the two outer tines 25 , 27 , a second contact piece 17 is assigned to bridge two other movable electrical switch contacts 3 under pretension. The second switching element 17 is also rocker-like, the two outer prongs 25 , 27 also coming to rest in the central region on the main surface of the second switching element 17 facing the actuating element 2 . The two end regions of the main surface facing away from the actuating element 2 thus rest on the two further associated electrical switching contacts 3 .

The four movable electrical switching contacts 3 are integral with a dome switching mat 19 and are assigned in pairs to the first switching element 14 and the second switching element 17 . The dome switching mat 19 itself lies on the base parts 15 of the housing 1 which has the four fixed electrical switching contacts 4 . The four stationary electrical switch contacts 4 , which are also arranged in pairs, and the conductor track structure (not shown for the sake of simplicity) are applied as metallizations directly on the main surface of the base part 15 facing the actuating element 2 .

The operating member 2 is brought from its starting in Fig. 7 and 8, basic position into eight different switching positions. Four switching positions can be achieved by moving in opposite directions and four further switching positions by pivoting the actuating element 2 in opposite directions. Each switching position is marked with a clearly noticeable pressure point for the user. By shifting in two stages and by pivoting the actuator 2 in two stages in one and the same direction of actuation, two switching positions can be achieved. In order to ensure a positionally accurate, secure mounting of the actuating element 2 in its basic position and at the same time a reliable return of the actuating element 2 from its eight different switching positions, the two switching elements 14 , 17 come under tension with their undersides facing away from the actuating element 2 each on their assigned pair of movable electrical switch contacts 3 to the system.

As can be seen in particular from FIG. 9, the switch arrangement is in one of its four switching positions that can be reached by pivoting the actuating element 2 . By pivoting the actuating element 2 in one actuating direction, the articulation mechanism was deflected by a first step such that the second bearing block 10 was pivoted about the fifth bearing point 13 . As a result, the first contact piece 14 is simultaneously pivoted about the operative connection point formed by the rod-shaped extension 29 . The second contact piece 17 remains in the basic position due to the articulated connection of the intermediate member 24 via the intermediate bearing point 20 and the fifth bearing point 13 . By pivoting the rocker-like first contact piece 14 , the first associated electrical switching contact 3 , which is assigned to the rod-shaped extension 29 , was depressed and brought into contact with the associated stationary electrical switching contact 4 . The first associated switching function is thus implemented. The adjustment of the first switching element 14 is therefore only carried out via one of the two outwardly projecting rod-shaped projections 29 , the user having to overcome a clearly perceptible pressure point.

If, starting from the switching position shown in FIG. 9, the actuating element 2 is pivoted further in the same actuation direction in a second stage, then the first switching element 14 is further adjusted via the rod-shaped extension 29 until, ultimately, the movable electrical switching contact located away from the rod-shaped extension 29 3 of this switch contact pair is depressed. Both movable switching contacts 3 assigned to the first switching element 14 are thus assigned to their fixed electrical switching contacts 4 so that the second associated switching function is realized for this actuation direction. Two pressure points clearly perceptible to the user have to be overcome.

As can be seen in particular from FIG. 10, the switch arrangement is in one of its four switch positions that can be reached by shifting the actuating element 2 . By moving the actuating element 2 in one actuation direction, the articulation mechanism was deflected by a first step such that the intermediate member 24 was pivoted about the fifth bearing point 13 . Thereby also the second contact piece 17 is pivoted about the through one of the two outer prongs 27 operative connection point formed simultaneously. The first contact piece 14 and the second bearing block 10 remain in the basic position due to their articulated connections. By pivoting the rocker-like second contact piece 17 , the first associated electrical switching contact 3 , which is assigned to the outer prongs 27 , has been depressed and brought into contact with the associated stationary electrical switching contact 4 . The associated switching function is thus implemented. The adjustment of the second switching element 17 is therefore only carried out via one of the two outer prongs 27 of the intermediate member 24 , the user having to overcome a clearly noticeable pressure point.

As can be seen in particular from FIG. 11, the switch arrangement is in the second of its four switching positions that can be reached by displacing the actuating element 2 . By moving the actuating element 2 in one and the same actuation direction, the joint mechanism was first deflected by a first step, as can be seen in FIG. 10. Starting from the first switching position shown in FIG. 10, the joint mechanism was deflected by a second step in this actuation direction, so that the intermediate member 24 was pivoted by a further amount around the fifth bearing point 13 . Thereby also the second contact piece 17 is pivoted by a further amount to the through one of the two outer prongs 27 operatively connected dots formed simultaneously. The first contact piece 14 and the second bearing block 10 remain in the basic position due to their articulated connections. By pivoting the rocker-like second switching element 17 , in addition to the first electrical switching contact 3 , the second associated switching contact 3 of this pair of switching contacts, which is distant from the outer prongs 27 , was also depressed and brought into contact with the associated stationary electrical switching contact 4 . Both movable switching contacts 3 assigned to the second switching element 17 are thus assigned to their fixed electrical switching contacts 4 in a contact-making manner. The second associated switching function is thus implemented. The adjustment of the second switching element 17 thus takes place only via one of the two outer prongs 27 of the intermediate member 24 , two pressure points clearly perceptible to the user to be overcome.

The force stored latently in the or in the relevant, movable electrical switching contact (s) 3 when the actuating force is removed comes to a quasi full effect to reset the joint mechanism or the actuating element 2 . This is the case because the actuation direction of the first switching element 14 and the second switching element 17 essentially corresponds to the adjustment direction of the associated movable electrical switching contacts 3 and thus no transverse forces arise.

The same applies mutatis mutandis to the functional sequence, the actuating element 2 is adjusted by swiveling or shifting in two stages in the other - not shown - actuation direction and thereby brought into the other switching positions.

Claims (19)

1. Switch arrangement for a power-operated adjustable device of a motor vehicle, in particular a sliding / sunroof, with a housing in which the movable and fixed electrical switching contacts required for implementing the various switching functions are located and on which an actuating element can be displaced from its basic position in the direction of an imaginary longitudinal axis and is mounted so as to be pivotable about a transverse transverse axis that perpendicularly intersects the imaginary longitudinal axis, the actuating element for guiding and limiting the adjustment path engaging pivotably and displaceably in at least two guide cams in a cross-shaped link provided in the housing, and wherein several actuating elements are assigned to the actuating element are, which carry out the movements of the actuating element on the movable electrical switch contacts to implement the various switching functions s, characterized in that for influencing a joint mechanism on the underside of the actuating element ( 2 ) there is a first bearing block ( 7 ) which is arranged in the sliding direction of the actuating element ( 2 ) at a distance one behind the other at least a first bearing point ( 8 ) and a second bearing point ( 9 ), and that a first contact piece ( 14 ) assigned to at least a first and a second movable switching contact ( 3 ) is assigned to a second bearing block ( 10 ) of the joint mechanism which is arranged opposite the first bearing block ( 7 ) and which in the sliding direction of the actuating element ( 2 ) arranged at a distance one behind the other, has at least a third bearing point ( 11 ) and a fourth bearing point ( 12 ), and in that the second bearing block ( 10 ) is provided by means of a fifth bearing point ( 13 ) located centrally between the third and fourth bearing points ( 11 , 12 ). from one on the base part ( 15 ) of the housing ( 1 ) the third bearing block ( 16 ) is pivotally received, and that between the first bearing point ( 8 ) of the first bearing block ( 7 ) and the third bearing point ( 11 ) of the second bearing block ( 10 ) there is an L- associated with at least one third movable switching contact ( 3 ). second switching piece ( 17 ) in the form of a L, and an L-shaped third switching piece associated with at least one fourth movable switching contact ( 3 ) between the second bearing ( 9 ) of the first bearing block ( 7 ) and the fourth bearing ( 12 ) of the second bearing block ( 10 ) ( 18 ) is articulated. 2. Switch arrangement for a power-operated adjustable device of a motor vehicle, in particular a sliding sunroof, with a housing in which the movable and fixed electrical switching contacts necessary for implementing the various switching functions are located and on which an actuating element can be displaced from its basic position in the direction of an imaginary longitudinal axis and is mounted so as to be pivotable about a transverse transverse axis that perpendicularly intersects the imaginary longitudinal axis, the actuating element for guiding and limiting the adjustment path engaging pivotably and displaceably in at least two guide cams in a cross-shaped link provided in the housing, and wherein several actuating elements are assigned to the actuating element are, which carry out the movements of the actuating element on the movable electrical switch contacts to implement the various switching functions s, characterized in that for influencing a joint mechanism on the underside of the actuating element ( 2 ) there is a first bearing block ( 7 ) which is arranged in the sliding direction of the actuating element ( 2 ) at a distance one behind the other at least a first bearing point ( 8 ) and a second bearing point ( 9 ), and that a first contact piece ( 14 ) assigned to at least a first and a second movable switching contact ( 3 ) is assigned to a second bearing block ( 10 ) of the joint mechanism which is arranged opposite the first bearing block ( 7 ) and which in the sliding direction of the actuating element ( 2 ) arranged at a distance one behind the other, has at least a third bearing point ( 11 ) and a fourth bearing point ( 12 ), and in that the second bearing block ( 10 ) is provided by means of a fifth bearing point ( 13 ) located centrally between the third and fourth bearing points ( 11 , 12 ). from one on the base part ( 15 ) of the housing ( 1 ) Ndenen third bearing block ( 16 ) is pivotally received, and that the first bearing block ( 7 ) has an intermediate bearing point ( 20 ) and that between the first bearing point ( 8 ) of the first bearing block ( 7 ) and the third bearing point ( 11 ) of the second bearing block ( 10 ) a first articulated arm ( 22 ) and between the second bearing point ( 9 ) of the first bearing block ( 7 ) and the fourth bearing point ( 12 ) of the second bearing block ( 10 ) a second articulated arm ( 23 ) and between the intermediate bearing point ( 20 ) and the fifth bearing point ( 13 ) of the second bearing block ( 10 ) an intermediate member ( 24 ) is arranged in an articulated manner and that the intermediate member ( 24 ) has at least two spaced-apart teeth ( 25 , 27 ) interacting with the second contact piece ( 17 ), and that the second bearing block ( 10 ) has two rod-shaped projections ( 28 , 29 ) spaced apart from one another, each of which is designed to interact with the first contact piece ( 14 ). 3. Switch arrangement according to one of claims 1 or 2, characterized in that the first bearing block ( 7 ) is integrally formed with the actuating element ( 2 ). 4. Switch arrangement according to one of claims 1 to 3, characterized in that the third bearing block ( 16 ) is integrally formed with the base part ( 15 ) of the housing ( 1 ). 5. Switch arrangement according to one of claims 1 to 4, characterized in that at least the first contact piece ( 14 ) extends with its main surfaces substantially parallel to the base part ( 15 ) of the housing ( 1 ). 6. Switch arrangement according to one of claims 1 to 5, characterized in that at least one of the switching pieces ( 14 , 17 , 18 ) has an integrally formed, with a movable switching contact ( 3 ) which can be brought into contact with an actuating projection, the main surface of which is parallel to the base part ( 15 ) extends. 7. Switch arrangement according to one of claims 1 to 6, characterized in that at least one of the movable switch contacts ( 3 ) is part of a dome switch mat ( 19 ). 8. Switch arrangement according to one of claims 1 to 7, characterized in that at least one of the movable switching contacts ( 3 ) is designed as a snap-action switching disk. 9. Switch arrangement according to one of claims 1 to 8, characterized in that the fixed switching contacts ( 4 ) are part of a printed circuit board. 10. Switch arrangement according to one of claims 1 to 8, characterized in that the fixed switching contacts ( 4 ) are part of a conductor foil. 11. Switch arrangement according to one of claims 1 to 8, characterized in that the base part ( 15 ) of the housing ( 1 ) has a metallization, the stationary electrical switching contacts ( 4 ) comprising conductor structure. 12. Switch arrangement according to one of claims 1 to 11, characterized in that at least two of the movable switch contacts ( 3 ) are bridged by a bar-like bridge member which is directly in contact with one of the switching pieces ( 14 , 17 , 18 ). 13. Switch arrangement according to claim 12, characterized in that the bridge member has an eccentrically arranged actuating bead which is in direct contact with one of the switching pieces ( 14 , 17 , 18 ). 14. Switch arrangement according to one of claims 1 or 3 to 13, characterized in that at least one bearing journal is integrally formed on at least one of the three switching elements ( 14 , 17 , 18 ), and that in at least one of the three bearing blocks ( 7 , 10 , 16 ) at least one correspondingly designed bearing eye is molded in for the rotatable reception of a bearing journal. 15. Switch arrangement according to one of claims 1 or 3 to 14, characterized in that for the one-piece articulated coupling at least one of the three switching pieces ( 14 , 17 , 18 ) via at least one bearing formed in one piece as a film hinge with at least one of the three bearing blocks ( 7 , 10 , 16 ) is articulated. 16. Switch arrangement according to one of claims 1 or 3 to 15, characterized in that the first switching piece ( 14 ) for pivotable mounting on the third bearing block ( 16 ) has an integrally formed bearing journal which is integral with the second bearing block ( 10 ) and that the second switching element ( 17 ) is coupled in one piece to the second bearing block ( 10 ) in an articulated manner via a first film hinge, and the third switching element ( 18 ) is articulated in one piece via a second film hinge. 17. Switch arrangement according to one of claims 2 to 13, characterized in that at least one bearing pin is formed on the intermediate member ( 24 ) and on at least one of the two articulated arms ( 22 , 23 ) 18. Switch arrangement according to one of claims 2 to 13 or 17, characterized in that at least one bearing eye is introduced into the intermediate member ( 24 ) and in at least one of the two articulated arms ( 22 , 23 ). 19. Switch arrangement according to one of claims 2 to 13 or 17 to 18, characterized in that both the first contact piece ( 14 ) and the second contact piece ( 17 ) each extend with their main surfaces substantially parallel to the base part ( 15 ) and on the one hand, two movable switch contacts ( 3 ) are assigned in a bridge-like manner and, on the other hand, they are in contact with the second bearing block ( 10 ) or with the intermediate member ( 24 ) to create an operative connection.