DE10027484C1 - Combined tipping and sliding switch for automobile sunroof operating device has sliding and pivoted switch operating element with 2 parallel switch pieces acting on respective operating bridges - Google Patents

Abstract

The switch has a switch housing (1) containing a number of electrical switch contacts (4), controlling electrical circuits for different functions of the sunroof operating device and a cooperating switch operating element (2) which slides in the direction of its longitudinal axis and which pivots about a transverse axis. The operating element has 2 spaced parallel switch pieces (16) on its underside, each provided with 2 control noses (18) on either side of the pivot axis, for cooperating with a linear operating bridge (20) having at least 2 movable switch contacts.

Description

The present invention is based on one according to the preamble of The main claim was designed from toggle-slide switches.

Such tilt-slide switches 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. This enables the user to operate the actuator by switching the connected electrical on, off and on Circuits a variety of functions in a convenient way a single actuator on or off. Often times the various functions via such electrical toggle-slide switches of a sunroof of a motor vehicle affected.

DE 37 06 681 A1 describes a preferred embodiment of an electrical Switch discloses a toggle switch, in which an actuation handle is slidably and pivotably guided in a housing. there grip on the one hand on the operating handle of this known switch molded axle pieces in assigned elongated holes in the housing and on the other hand engage from the axle pieces in the direction of displacement  spaced, molded cams on the actuating handle in assigned, in the housing, cross-shaped backdrop tracks. The Pivotal movement of the actuating handle is vertical Slidable, provided with a catch, perpendicular to the shift direction arranged vertical switching element assigned by a lever is firmly connected to the operating handle. The Sliding movement of the actuating handle is also an in Movement direction movable, with its own detent assigned horizontal switching element, which by a rotatable on Actuating handle piece attached lever in the horizontal direction is controlled. The vertical or horizontal switching element cooperate with assigned, vertically or horizontally arranged contact elements.

Furthermore, the DE 44 31 061 A1 discloses a tilt-slide Switch became known, in which also an operating handle in a housing with the help of elongated holes and cross-shaped backdrops is displaceable and pivotable. That the operating handle orderly actuator is designed in two parts with this switch, the part associated with the pivoting movement being rotatable in the part of the actuating element associated with the displacement movement is stored. This rotatable part is firmly attached to the Actuator handle connected lever controlled. The other part of the Actuator, which is assigned to the displacement movement by means of a strap coupled to the actuating handle piece direction driven. This tab is in the actuating handle for decoupling plung the sliding from the pivoting movement rotatably supported. Both parts of the actuating element act on horizontally arranged cones clock springs.

The actuating element stands over an attached, spring-loaded locking bolts with molded in the housing walls, pyramid-shaped depressions ("resetting pyramids") in operative connection, whereby the return of the actuator - starting from the individual actuation positions - in the neutral position.  

In addition, in US Pat. No. 5,623,134 there is an electrical switch in particular a door lock switch. This previously known Switch contains an operating handle, which starts from a middle neutral position, in which the switch cannot be operated, in one of two possible end positions can be moved. In the End positions, on the other hand, is a pivoting movement of the actuation handle possible. An in is firmly connected to the operating handle a sliding carriage rotatably mounted actuation element on which two spaced transversely to the direction of displacement Switch pieces are formed, which are two parallel on their foot surfaces to control direction spaced control lugs, which on two interlocking actuating bridges act, which in turn with Contact elements are in operative connection.

Finally, DE 197 26 149 C2 is a generic term for Main claim corresponding electrical tilt-slide switch for a Lift / sunroof became known. This toggle switch has a the electrical switch contacts housing on which a only actuating element that can be brought into several switching positions is. The actuating element is for guidance and limitation of the adjustment path two bolt-like approaches 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 from the two approaches on the actuator Guide cams each in an existing, also in the housing cross-shaped backdrop a pivotable and slidable. The Actuator is therefore analogous to the functions of a Adjustable sunroof. In addition, the tilt-slide Switch for generating defined actuation and restoring forces of the Actuator on a control device, which consists essentially of a molded onto the actuating element receiving sleeve in which two pressure pieces are slidably received. The two spring-loaded thrust pieces in turn engage in one on the housing existing cross-shaped control curve. The bottom of the Actuator are assigned two contact pieces, which over their  Foot surfaces directly with the movable electrical switch contacts in Active connection. For functional control of the electrical Switch contacts is the first contact on the bottom of the Actuator molded and the second contact piece as separate mounting individual part. The second contact piece is a pivotally coupled to the bottom of the actuator and on the other hand pivotable in a separate bearing arrangement of the Housing added. Such training is dependent on Assembly of such a tilt and slide switch is comparatively complex or complicated.

According to the predicted, there are a number of constructive solutions known to perform a toggle switch, but they have the disadvantage that a comparatively large number of complicated Individual parts to be produced, some of which are also required must be movably stored in the housing. A reason for the existence such comparatively complex solutions is that a mechanical decoupling of the pivotal movement Actuators required by those associated with the displacement movement becomes.

The present invention is therefore based on the object electric toggle switch of the type mentioned above to further develop that with a high functional density from as few as possible Individual parts exist and in a particularly simple and inexpensive way and Can be mounted in a manner that is particularly simple has mechanical decoupling of the pivoting and displacement movement.

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

It is advantageous with such a configuration of a tilt and slide switch that that the tilt and slide switch altogether consists of only a few, robustly designed and easy to manufacture individual parts. Consequently is a particularly inexpensive manufacture and assembly of such  Toggle-slide switch with high functional reliability given.

Further advantageous configurations of such an electrical tilt-slide Switch are specified in the subclaims.

Based on an embodiment shown in the drawings The subject of the invention explained in more detail and show

Fig. 1 shows in principle an toggle slide switch in an exploded view

Fig. 2 shows a full section of a tilt and slide switch with a more detailed representation of the first contact piece and the first actuating bridge

Fig. 3 shows a full section of a tilt and slide switch with a more detailed representation of the second switching element and the second actuating bridge.

As can be seen from the figures, such a toggle-slide switch essentially consists of a housing 1 , an actuating element 2 mounted on the housing 1 and which can be brought into several switching positions, and the single element required for realizing the various switching functions arranged in the housing 1 Switch mat 3 associated movable electrical switch contacts 4 , as well as the fixed switch contacts 6 located on a single circuit board 5 . The actuating element 2 has a correspondingly shaped actuating handle 7 for its comfortable handling.

As can furthermore be seen from the figures, the actuating grip piece 7 can be fixed securely on the actuating element 2 by means of appropriately designed clip elements. Starting from its basic position shown in FIGS. 2 and 3, the actuating element 2 or the actuating handle 7 can be displaced 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. For this purpose, an elongated hole 8 is formed in each of the two longitudinal walls of the housing 1 running parallel to the sliding direction and a cross-shaped link 9 spaced apart in the sliding direction. Both the two elongated holes 8 and the two cross-shaped backdrops 9 are designed as window-like slots. Correspondingly, two stub axles 10 and two guide cams 11 are integrally formed on the actuating handle 7 for storage. The two stub axles 10 each represent an extension of the transverse axis of the actuating element 2 and each engage rotatably and displaceably in one of the two elongated holes 8 . At the same time, the guide cams 11 also each pivot and slide into one of the two cross-shaped links 9 . The actuating element 2 is accordingly z. B. to adjust according to the function of a sunroof and defined starting from its basic position in four different positions. Two functional positions are achieved by moving in opposite directions and two further functional positions by pivoting the actuating element 2 in opposite directions. The possible applications of such tilt-slide switches are in no way limited to a device designed as a sliding / lifting roof. Rather, use with other devices with similar adjustment options is readily possible. In this context, for example, reference is made to the power-operated adjustment of vehicle seats, the vehicle steering wheel, etc.

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, automatic return of the actuating element 2 from its four different functional positions to the basic position, the actuating element 2 is provided with a control device which has two control cams on the housing 1 12 cooperates. The control device consists of a receiving sleeve 13 which is formed parallel to the transverse axis on the actuating element 2 and which in addition to a helical compression spring 14 slidably receives two pressure pieces 15 . The receiving sleeve 13 is integrally formed on one of the two end regions of the first switching element 16 and the second switching element 17 . The two contact pieces 16 , 17 are in turn formed in one piece with the actuating element 2 , the receiving sleeve 13 connecting the two contact pieces 16 , 17 in a bridge-like manner at one of their two end regions. One of the two control cams 12 is molded into one of the two longitudinal walls of the housing 1 . The two control cams 12 are also present, like the two elongated holes 8 and the two cross-shaped scenes 9 , directly opposite in the two longitudinal walls. The cross-shaped control cams 12 and the cross-shaped cams 9 are in pairs in the sliding direction, each spaced apart in the longitudinal walls, so that the elongated hole 8 is arranged approximately centrally between them.

Each of the two cross-shaped control cams 12 has four control tracks which, starting from a central locking recess which represents the low point, are designed to be as inclining resetting slopes. Thus, on the one hand ensures a simple and effective manner that the actuator 2 remains securely on the two engaging in the locking recesses under spring tension pressing pieces 15 in its basic position, ie that the actuating element 2 is not unintentionally, z. B. can be moved from the basic position by vibrations. On the other hand, it is ensured by the control tracks of the two control cams 12 designed as reset bevels that the helical compression spring 14 is tensioned more and more into its functional positions when the actuating element 2 is adjusted. After the end of the actuation, the helical compression spring 14 strives to relax again, as a result of which the two pressure pieces 15 are each returned along the assigned control path to the central latching recess, which represents the low point of the corresponding control curve 12 . After the end of the adjustment, it is thus ensured that the actuating element 2 is automatically returned to its basic position. Depending on the application, however, the control tracks can also be provided with a further locking recess at their end remote from the central locking recess. The associated functional position is then designed to rest, ie the actuating element 2 remains in this functional position until it is consciously actuated again in the opposite direction.

As can further be seen in particular from the figures, a first contact piece 16 and a second contact piece 17 are integrally formed on the underside of the actuating element 2 , as already described. Both the first and the second switching piece 16 , 17 are continuously molded onto the underside of the actuating element 2 and each aligned with their main surfaces parallel to the sliding direction of the actuating element 2 . The integrally formed receiving sleeve 13 extends transversely to the sliding direction and forms a bridge-like one free end region of the two switching elements 16 , 17 . Each change in position of the actuating element 2 inevitably results in a corresponding change in position of the two switching elements 16 , 17 and the receiving sleeve 13 .

The first switching element 16 is provided for realizing those functions which are triggered by the pivoting movements of the actuating element 2 . As is apparent in particular from FIG. 2, for this purpose on the base surface of the first contact piece 16 in the sliding direction two spaced-apart first control tabs 18 integrally formed. The two first control lugs 18 are each in operative connection with a first control surface 19 of a first actuating bridge 20 . To implement the associated switching functions, the first actuating bridge 20 with the two free end faces facing away from the actuating element 2 lies directly on the top faces of the associated movable electrical switching contacts 4 . The distance between the associated movable electrical switching contacts 4 is slightly larger than the distance between the two first control lugs 18 of the first switching element 16 . Because of the redundant design, each free end face of the first actuating bridge 20 is assigned a pair of movable electrical switch contacts 4 , so that it rests on four movable electrical switch contacts 4 . The first actuating bridge 20 extends with its two main surfaces or with its first control surfaces 19 parallel to the main surface of the printed circuit board 5 which has the fixed electrical switching contacts 6 and is completely covered by the dome switching mat 3 . If the actuator 2 starting from the position shown in Fig. 2 basic position pivoted in the one or in the other operating position, this movement is transmitted via the respective first control nose 18 of the first contact piece 16 on the respective first cam surfaces 19, thereby ultimately because of the pivotal movement of the first switching element 16, the associated electrical switching contacts 4 are depressed by the corresponding end face of the first actuating bridge 20 . To bad contact of the respective doses not to be controlled switching contacts 4 to avoid the first actuation bridge 20 is formed a tilting web 27 on the underside by which it is pivoted with appropriate adjustment of the actuating element. 2 The desired function is ultimately triggered or carried out by contacting the movable electrical switch contacts 4 with their associated stationary switch contacts 6 . The second actuating bridge 25 is not influenced by the pivoting movement of the actuating element 2 , as described in more detail below.

The second switching element 17 is provided for realizing those functions which are triggered by the sliding movements of the actuating element 2 . 3 as is apparent especially from FIG., Are for this purpose on the base surface of the second contact piece 17, two in the sliding direction spaced-apart second control tabs 23 integrally formed. One of the two second control lugs 23 is formed by a section of the receiving sleeve 13 . The two second control lugs 23 and the corresponding section of the receiving sleeve 13 are each in operative connection with a second control surface 24 of a second actuating bridge 25 . To implement the associated switching functions, the second actuating bridge 25 likewise lies directly on the top surfaces of the associated movable electrical switching contacts 4 with the two free end faces facing away from the actuating element 2 . The distance between the associated movable electrical switching contacts 4 is also slightly larger than the distance that is present between the two second control lugs 23 of the second switching element 17 . Because of the redundant design, each free end face of the second actuating bridge 25 is assigned a pair of movable electrical switch contacts 4 , so that it rests on a total of four movable electrical switch contacts 4 . The second actuating bridge 25 extends with its two main surfaces essentially parallel to the main surface of the printed circuit board 5 which has the fixed electrical switching contacts 6 and is completely covered by the dome switching mat 3 . If the actuating element 2 is shifted from one of the basic positions shown in FIG. 3 to one or the other functional position, this movement is transmitted via the respective second control lug 23 of the second switching element 17 to the respective second control surface 24 which is designed like a ramp, which ultimately results in the associated movable electrical switch contacts 4 are depressed by the associated end region of the second actuating bridge 25 . This is the case because the second ramp-like control surfaces 24 have an angle of inclination of approximately 45 °, and the second control lugs 23 are pressed more and more against the second control surfaces 24 due to the displacement of the second switching element 17 and thereby the associated end regions of the second Press down the actuating bridge 25 in the direction of the printed circuit board 5 . The desired function is ultimately triggered or carried out by contacting the movable electrical switching contacts 4 on their associated stationary switching contacts 6 . The first actuating bridge 20 is not influenced by the sliding movement of the actuating element 2 , as described in more detail below.

So that when the actuating element 2 is pivoted - as already described - only the first actuating bridge 20 is adjusted, the first control lugs 18 of the first switching element 16 are made somewhat longer in the direction of the circuit board 5 than the second control lugs 23 of the second switching element 17 . When pivoting the actuating element 2 , the foot surfaces of the two switching pieces 16 , 17 pivot about the imaginary transverse axis or about the two stub axles 10 , which are rotatably mounted in the two elongated holes 8 . Because of the shorter design of the second control lugs 23 and the swiveling circle of the two switching elements 16 , 17 determined by the mounting of the axle stub 10 and the design of the ramp-like second control surfaces 24 , the second switching element 17 works in freewheeling fashion. There is thus no influence on the second actuating bridge 25 or the movable electrical switching contacts 4 assigned to it , because the second control lugs 23 can not exert any effect on the second ramp-like control surfaces 24 of the second actuating bridge 25 when the actuating element 2 is pivoted. The tilting web 27 acts like an end stop, ie when the actuating element 2 is pivoted in one direction it is prevented that the switching contact 4 assigned to the other actuating direction is influenced.

So that only the second actuating bridge 25 is adjusted when the actuating element 2 is displaced, as already described, the first control surfaces 19 of the first actuating bridge 20 are arranged parallel to the sliding direction of the actuating element 2 . Only the second control surfaces 24 of the second actuating bridge 25 are designed like ramps and each have an inclination angle of 45 °. When moving the actuating element 2 , the foot surfaces and thus the control lugs 18 , 23 of the two switching elements 16 , 17 are necessarily moved parallel to the direction of displacement of the actuating element 2 . Because of the first control surface 19 running parallel to the sliding direction, the first switching element 16 works in freewheeling fashion. There is therefore no influence on the first actuating bridge 20 or the movable electrical switching contacts 4 assigned to it , because the first control lugs 18 can not exert any effect on the first control surfaces 19 of the first actuating bridge 20 when the actuating element 2 is pivoted.

Two spaced apart parallel to the sliding direction of the actuating member 2 extending guide ribs 26 are respectively formed on the two actuating links 20, 25th The two first control lugs 18 of the first contact piece 16 are slidably received between the two guide webs 26 of the first actuating bridge 20 . Between the two guide webs 26 of the second actuating bridge 25 , however, only the one second control lug 23 of the second switching element 17 is slidably received. In addition, the two guide webs 26 contribute to the stiffening of the two actuating bridges 20 , 25.

For the functional design of the tilt and slide switch, both the printed circuit board 5 and the dome switching mat 3 are held in place on a base part 21 , which in turn is provided with a plug connection area 22 for connecting corresponding electrical lines. The plug pins belonging to the plug connection area 22 protrude perpendicularly from the main surface of the electrical circuit board 5 , which comes to rest on the base part 21 . To protect against damage, the plug pins led out of the housing 1 are surrounded by a protective collar molded onto the underside of the base part 21 .

Claims (8)

1. Tilt-slide switch for a power-operated adjustable device of a motor vehicle, in particular a sliding sunroof, with a housing ( 1 ) in which the movable and stationary electrical switching contacts ( 4 ) necessary for realizing the various switching functions are located and on which an actuating element ( 2 ) Starting from its basic position, it can be moved in the direction of an imaginary longitudinal axis and is pivotably mounted about a transverse transverse axis that perpendicularly intersects the imaginary longitudinal axis, the actuating element ( 2 ) for guiding and limiting the adjustment path via two axis elements ( 10 ) each in one Housing ( 1 ) existing, in the sliding direction elongated hole ( 8 ) rotatable and displaceable and at the same time via two spaced in the sliding direction to the two axis elements ( 10 ) existing guide cams ( 11 ) each in a, also in the housing ( 1 ), cross-shaped ete backdrop ( 9 ) pivotally and displaceably engage and the actuating element ( 2 ) is assigned a receiving sleeve ( 13 ), which runs parallel to the transverse axis and is intended for receiving two pressure pieces ( 15 ), the control device with its two spring-loaded pressure pieces ( 15 ) each engages in a cross-shaped control cam ( 12 ) provided in the housing ( 1 ), and the underside of the actuating element ( 2 ) is in operative connection with a first switching element ( 16 ) which, via its foot surface, is provided for realizing the lifting movements of the device Movable electrical switch contacts ( 4 ) is assigned influencing and wherein the underside of the actuating element ( 2 ) is operatively connected to a second switching piece ( 17 ), which influences the movable electrical switch contacts ( 4 ) provided for realizing the sliding movements of the device via its foot surface dnet, characterized in that both the first switching element ( 16 ) and the second switching element ( 17 ) are continuously molded onto the underside of the actuating element ( 2 ) and that the foot surfaces of the two switching elements ( 16 , 17 ) each have two control lugs ( 18 , 23 ) arranged one behind the other in the sliding direction at a distance on both sides of the transverse axis, and that the two first control lugs ( 18 ) of the first switching element ( 16 ) with a first control surfaces ( 19 ) extending parallel to the sliding direction extend a substantially linear one designed actuating bridge ( 20 ) and the two second control lugs ( 23 ) of the second switching element ( 17 ) with second ramp-like control surfaces ( 24 ) of a second substantially linearly elongated actuating bridge ( 25 ) are in operative connection and that the two are at least almost constant distance to each other Actuating bridges ( 20 , 25 ) arranged essentially in parallel, with their end faces facing away from the control lugs ( 18 , 23 ), each come into direct contact with at least two movable electrical switching contacts ( 4 ) which are spaced apart in the sliding direction. 2. Tilt and slide switch according to claim 1, characterized in that at least one of the two actuating bridges ( 20 , 25 ) has a parallel to the transverse axis, with the actuating element ( 2 ) facing the main surface of the switch mat ( 3 ) coming into contact with the tilting web ( 27 ). 3. Tilt-slide switch according to one of claims 1 or 2, characterized in that the main surfaces of the two switching elements ( 16 , 17 ) are aligned parallel to the sliding direction of the actuating element ( 2 ), and that the receiving sleeve ( 13 ) is transverse to Sliding direction of the actuating element ( 2 ) is integrally formed as a bridge-like connection to the two switching elements ( 16 , 17 ). 4. Tilt and slide switch according to one of claims 1 to 3, characterized in that at least a portion of the receiving sleeve ( 13 ) as the second control lug ( 23 ) is assigned to one of the two second control surfaces ( 24 ) of the second actuating bridge ( 25 ). 5. Tilt and slide switch according to one of claims 1 to 4, characterized in that on at least one of the two actuating bridges ( 20 , 25 ) two mutually parallel guide webs ( 26 ) are formed at a distance parallel to the sliding direction of the actuating element ( 2 ) and that at least one of the control lugs ( 18 , 23 ) is slidably received between the two guide webs ( 26 ). 6. Tilt and slide switch according to one of claims 1 to 5, characterized in that all movable electrical switch contacts ( 4 ) are functional components of a single dome switch mat ( 3 ). 7. Tilt-slide switch according to one of claims 1 to 6, characterized in that all fixed electrical switch contacts ( 6 ) are present on a single electrical circuit board ( 5 ). 8. Tilt and slide switch according to one of claims 1 to 7, characterized characterized in that the two actuating bridges (20, 25) over a elastically formed connecting element in one piece in Connect.