DE3524439C2 - - Google Patents

Description

The invention relates to a switch, in particular for setting of at least two mirrors of a motor vehicle, the one with two degrees of freedom of movement provided each of the mirror discs are adjustable via two reversible electric motors, with a cross articulated and additionally rotatable in its central basic position mounted shift lever, which can be locked in a switch position Rotary switching element and one automatically returning to a basic position Sliding switching element is connected, between which one Printed circuit board is arranged.

By the applicant is a switch for adjusting a motor vehicle mirror using two reversible electric motors on the market, which has a universal joint shift lever with a resilient locking element, that works with a fixed cruciform curve, owns. The cam track defines the switch-off state in the middle assigned basic position and in the end points an unlocked Switch position of the shift lever, in which a movable by the shift lever Sliding switching element on a circuit board, the corresponding, connection contact belonging to the electric motors of the mirror disk carrier acted upon. So there is a separate one for each mirror  To provide switches.

To eliminate this disadvantage, is already from US-PS 42 45 137 Known switch of the type mentioned, with which several mirrors adjusted can be. With this switch, however, the slide switching element acts and the rotary switching element each with the top of different PCB together. The arrangement of two circuit boards is disadvantageous in that they have a relatively large installation space and secondly requires complex electrical connections. Furthermore is the oval rotary switching element of the known switch a stop in the form of a fixed web and a U-shaped plate spring, both require a separate installation space.

The invention has for its object a switch of the beginning mentioned type both in terms of size and in terms of to make the electrical connections compact.

This object is achieved in that the sliding switching element the side of the circuit board opposite the rotary switching element contacted, resilient locking means in the rotary switching element are used with a fixed, concentric to the gear lever arranged shift gate interact.

The measures according to the invention both result in a proportionate small construction volume as well as a simple construction of the electrical Connections of the switch. Applying to the top of the circuit board by the rotary switching element and the loading on the underside enable this circuit board by the sliding switching element in particular a low height of the switch, while the space-saving arrangement the locking means of the rotary switching element directly between them and the switch lever ensures a slight lateral extension of the switch.  

For easy determination of the positions of the shift lever has in configuration the invention of the shift lever an lying in its axis, spring-loaded locking element in a blind hole, which with a the central axis of the switch arranged in the housing base cruciform Curve interacts, which in the middle corresponds to the switch-off state Basic position and an unlocked switch position in the end points of the shift lever determined.

To a blocked zero position in a trained according to the invention To obtain switches for controlling two mirrors of a motor vehicle, in which the shift lever can only be rotated and not pivoted is in a preferred development of the subject of the invention into the underside of a switch button attached to the gear lever a groove extending over 180 ° is inserted into the basic position the switch button engages a stop attached to the housing, being on the stop as well as on the opposite side of the Each case has a wide, short bridge and opposite at right angles to it each a wide, short web and opposite at right angles to it each have a narrow, long web attached to the housing is, and being in the basic position and simultaneous blocking position the pivotal movement of the switch button corresponding to the narrow, long bars trained recesses in the underside of the switch button stand over the wide, short bars on the housing, while the wide, short ridges on the housing, while the wide, short ridges accordingly trained recesses in the underside of the switch button are located above the narrow, long webs on the housing. If the Switch knob rotated 90 ° to the right or left from the zero position is blocked in each case, so that one or the other Mirror adjusted by appropriate swiveling movements of the switch button can be.

To achieve a compensation of the switching forces when turning the Shift lever when transitioning from a locked switch position in the other locked switch position exist in a further embodiment the invention, the locking means of the rotary switching element from two opposite,  locking levers mounted on one side in the rotary switching element, which a compression spring is assigned in each case in the region of the free end, or of two opposite, spring-loaded arranged in the rotary switching element Locking bolt. Appropriately, each compression spring is on one End through a recess in the rotary switching element and at the other end held a pin on the locking lever in position.

In a further embodiment of the invention, the locking levers are in the area their storage in the rotary switching element by a film hinge with each other connected. As a result, the two locking levers form a component that is quick can be assembled.

The shifting gate is expediently on a housing attachment or on molded onto the side walls of the housing. The shift gate is preferred cross-sectionally square and each outside centered a notch, in the correspondingly molded on opposite Engage the locking lugs on the locking levers. As a result, the are locked Switch positions of the shift lever are precisely determined.

At the dead center between the individual switching positions when turning To keep the shift lever as small as possible form in a further embodiment of the invention, the legs of the corner angle of the shift gate each an obtuse angle. The angle is expediently here between the bevels of each notch of the shift gate 150 ° and each Corner angle of the shift gate 120 °. This ensures that the shift lever always jumps into a locked switch position. Because if the Shift lever when turning before reaching the dead center due to Angled arrangement in the switching link is designed as a tip, released, so the switching element and thus the shift lever jumps to the original latched switch position automatically back. However, if the Release lever after passing dead center, then jumps the rotary switching element and thus the shift lever automatically in the next switch position.  

To achieve a simple turning and swiveling movement of the shift lever is according to a further preferred embodiment of the subject matter of the invention the shift lever by a conical, the pivoting movement of the Shift lever adapted center bore of the rotary switching element, wherein the shift lever via a ball joint in one on the rotary switching element molded neck that extends from the narrow side of the center hole a dome-like housing curvature extends, is mounted, and two opposite pins of the ball joint in associated vertical grooves of the neck of the rotary switching element are guided.

The idea underlying the invention is described in the following Description explained in more detail using several exemplary embodiments. It shows:  

Fig. 1 a longitudinal section through a vehicle switch according to the invention with a defined zero position for the adjustment of two mirrors of a motor,

Fig. 2, where, however, the shift lever is a cross section through the switch of FIG. 1 according to the line II-II in slightly enlarged representation, in its basic position,

Fig. 3, the rotary switch member of FIG. 2 shortly before he rich the dead center of the shift gate,

Fig. 4, the switching member of Fig. 3 shortly after the short of the dead point of the control grid,

Fig. 5 shows an alternative embodiment of the switching member of Fig. 2,

FIG. 6a is a detail view of the upper part of the formwork ters of FIG. 1, but in the blocked-zero position,

Fig. 6b shows a section through the representation of Fig. 6a, however, button along the line VIb-VIb without switching,

Fig. 6c is a view of the representation according to FIG. 6b in the direction of arrow Fig. 6c,

Fig. 6d is a section through the representation of Fig. 6a along the line VId-VId,

Fig. 7a is a detail view of the upper part of the formwork ters of FIG. 1, but in the basic position, the first functional position,

Fig. 7b shows a section through the representation of Fig. 7 taken along the line VIIb-VIIb, and

Fig. 8 shows a cross section through an alternative switch of FIG. 1 along the line II-II in a somewhat enlarged representation ver, but with the shift lever in its basic position.

The housing 1 of the switch, which is square in cross section, has projections 2 on two opposite outer sides, behind which the clip lugs 3 of a holding part 4 for the switch interpose spring elements to compensate for tolerances. The housing 1 is connected via snap connections 5 with a connection contacts 6 supporting base 7 . Since the switch for the adjustment of two exterior mirrors of a motor vehicle is laid out, a total of four reversible electric motors are required, namely two electric motors for each mirror, one of which is the vertical pivoting movement of the mirror disk carrier to the left or right and the other the horizontal Swiveling movement of the mirror disc carrier causes up or down. A total of nine connection contacts 6 are required to act on the four electric motors, of which only four are shown.

The base 7 carries, on an edge 8 encircling the housing 1, a printed circuit board 9 printed on both sides, to which the connection contacts 6 are connected. Between the printed circuit board 9 and a cross-shaped curved path 10 formed in the center of the base of the base 7 there is a sliding switching element 11 , which has a switching lever 12 inserted into it, the switching element 11 projecting beyond the underside of the sliding element, in a blind bore 13 of the Switch lever 12 guided and acted upon by a compression spring 14 locking element 15 with the cross-sections in their cross-section V-shaped course venbahn 10 , is movable. The circuit board 9 has a central opening 16 for the pivoting movement of the shift lever 12 .

In the sliding switching member 11 there are spring-loaded con tact elements 17 which cooperate with the contact tracks of the circuit board 9 such that when the shift lever 12 or its locking element 15 is in the basic position 18 , ie the Schalthe bel 12 is in the middle the cruciform cam 10 , all the electric motors for adjusting the mirror disk carrier are switched out, and that when the shift lever 12 or its locking element 15 is in one of the four non-locked switching positions 19 , ie the switching lever 12 is in one of the four end points of the cross-shaped cam track 10 , the corresponding electric motor for the pivoting movement of the mirror disk carrier of one or the other mirror is driven in the vertical direction to the left or right or in the horizontal direction upwards or downwards, until the switching lever 12 is released again, since the shift lever 12 due to the interaction of its springs the locking elements s 15 always returns automatically to its basic position with the cross-shaped cam track 10 . Which of the two mirrors is controlled is determined by the position of one of the upper side of the circuit board 9 and also by the shift lever 12 adjustable rotary switching element 20 , the structure and mode of operation of which will be explained in more detail below.

The equipped with resilient, the contact tracks on the top of the printed circuit board 9 associated contact elements 21 rotary switching member 20 has a conical, the pivoting movement of the shift lever 12 adapted and thus serving as a stop center bore 22 . From the narrow side of this central bore 22 , a neck 23 formed on the rotary switching element 20 extends into a dome-like housing bulge 24 of the drawn-in upper side 25 of the housing 1 , the housing bulge 24 having a conical central bore 26 adapted to the pivoting movement of the switching lever 12 is provided. In the neck 23 of the rotary switching element 20 , the switching lever 12 is pivotally mounted by means of a ball joint 27 . Two opposing pins 28 of the ball joint 27 engage in associated vertical grooves 29 of the neck 23 of the rotary switching element 20 , the upper region of the ball joint 27 resting on the inside of the housing bulge 24 . When the shift lever is in its basic position, 18 12, lever 12, the rotary switching member concomitantly at the same time at a Drehwegung the switching 20th Is, in contrast, the control lever 12 in one of its unlatched switching positions 19, the scarf lever 12 and thus the rotary switching member are not twisted 20 because one of the webs 50, 51 at the top 25 of the housing 1 with one of the recesses 52, 53 is engaged in the underside of the switch button 45 . Another, at right angles to the two pins 28 on the ball joint 27 is attached pin 30 which engages in an associated vertical groove in the neck 23 of the rotary switching element 20 , serves only as protection against rotation during assembly.

The rotary switching element 20 has on its side facing the printed circuit board 9 from an annular recess 31 into which a switching link 33 with a square cross section formed on a housing projection 32 opposite the housing bulge 24 engages. Each outside of the switching link 33 is provided in the center with a notch 34 , the bevels of which enclose an angle α of 150 °. The size of each corner angle β of the shift gate 33 is 120 °. In opposite, circular segment-shaped Ausneh lines 35 of the rotary switching member 20 is a single-sided locking lever 36 , the protruding locking lugs 37, the Einker exercises 34 of the shift gate 33 are adapted. Each locking lever 36 is assigned a compression spring 38 in the region of its free end, which is held in position on the one hand in a recess 39 in the rotary switching element 20 and on the other hand by a pin 40 on the rear of the locking lever 36 . The eccentric arrangement of the opposing compression springs 38 compensates for the switching forces when the rotary switching element is rotated from one detent position to the other detent position. Now, the rotary switching element 20 from its shown in Fig. 2 Verraste th switching position with the help of be in a basic position switch lever 12 rotated counterclockwise until the detents 37 of the detent lever 36 together pressing the compression springs 38 just before the as peaks trained, diagonal dead centers 41 and now the shift lever 12 is released, then the restoring force of the Druckfe countries 38 in conjunction with the interplay between the locking lugs 37 of the locking lever 36 and the bevels of the corner angles and the notch 34 of the shift link 33 cause an automatic reset of the rotary switching element 20 in its locked starting position (see FIG. 3). In contrast, in the process described above, the diagonal dead centers 41 are exceeded by the locking lugs 37 of the locking lever 36 , and only now the switching lever 12 is released, then the restoring force of the compression springs 38 in conjunction with the interaction with the locking lugs 37 of the locking lever 36 and Slanting the corner angle and the notches of the switching link 33 an automatic turning of the rotary switching element of the 20 into the next locked switching position of the rotary switching element of the 20 (see. Fig. 4). The same circuitry processes are achieved with the rotary switching element 20 shown in FIG. 5, in which only the latching levers 36 are connected to one another in the region of their bearing 42 by a film hinge 43 . As a result, the two latching elements 36 form a single, easy-to-assemble component with the film hinge 43 .

The shift lever 12 projects with a diametrically flattened end piece 44 over the housing bulge 24 . On this end piece 44 is a one of the housing bulge 24 correspondingly adapted inner curvature having switch button 45 , with a molded on a flat side of the end piece 44 web 46 serves as an assembly aid. In the top of the switch button 45 is a translucent, with a symbol provided on the end face of the end piece 44 of the shift lever 12 plastic insert 47 is inserted. The symbol can be illuminated via a light bulb arranged in the housing 1 , not shown, and via the switching lever 12 made of translucent material.

In the underside of the switch button 45 , a groove 48 extending over 180 ° is inserted into which a stop 49 attached to the housing 1 engages in the basic position of the switch button 45 . At the ends of the groove 48 there is a depression 54 corresponding to the size of the stop 49 , in order to enable the pivoting movement of the switch button 45 .

On the stop 49 and on the opposite side of the housing 1 there is in each case a wide, short web 50 , while at right angles to these two webs 50 two opposite, long webs 51 are attached to the housing. In a corresponding arrangement to the webs 50, 51 on Gehäu se 1 45 recesses 52, 53 are embedded in the underside of the switch button, being in the basic position of the switch button 45 and simultaneous blocking position of the switch button 45 in the pivoting directions that the zero position of the switch button 45 , in which the switch button 45 can only be turned, corresponds to the wide, short recesses 52 over the narrow, long webs 51 and the narrow, long recesses 53 over the wide, short webs 50 , so that the switch button 45 and thus also the Shift lever 12 can not be pivoted, with the result that the sliding switching element 11 can also not be moved and consequently neither of the two mirrors is controllable.

If the switching button 45 shown in its Fig. 6d neutral position in the counterclockwise direction by 90 ° in the in Figure 7b. Illustrated first operating position twisted, so at the same time through the shift lever 12 with its integrally formed on the ball joint 27 pin 28, the rotary switch member 20 in moves its control function for the first mirror, and the wide, short recesses 52 of the switch button 45 are over the wide, short webs 50 on the housing 1 , while the narrow, long recesses 53 of the switch button 45 over the narrow, long webs 51 on the housing 1 lie. Here, the associated end of the groove 48 of the shift lever 45 abuts the stop 49 on the housing side, whereby the pins 28 on the ball joint 27 of the shift lever 12 are relieved. It is thus possible in this first functional position of the switching button 45 to pivot it into its four working positions, in which the sliding switching element 11 which is moved via the switching lever 12 has the two electric motors belonging to the first mirror for the desired horizontal or vertical pivoting adjustment of the mirror accordingly acted upon. The adjustment of the second mirror takes place in an analogous manner. In this case, the switch knob shown in the zero position in FIG. 6d must be turned clockwise by 90 °.

In the alternative embodiment of the switch according to FIG. 8, the switching link 33 is located on the inside of the side walls 55 of the housing 1 , which are assigned two spring-loaded latching bolts 56 which are arranged opposite each other in the rotary switching element 20 . In this case too, only the defined latching positions in the notches 34 occur due to the formation of the latching link 33 with its dead points 41 designed as tips.

Claims (11)

1.Switch, in particular for the adjustment of at least two mirrors of a motor vehicle, the supports of the mirror panes provided with two degrees of freedom of pivoting are each adjustable via two reversible electric motors, articulated with a cross and, in its central basic position, additionally rotatably mounted shift lever, which with a in a Switching position lockable rotary switching element and a sliding switching element automatically returning to a basic position, between which a circuit board is arranged, characterized in that the sliding switching element ( 11 ) is the side of the circuit board opposite the rotary switching element ( 20 ) ( 9 ) contacted, resilient latching means being inserted in the rotary switching element ( 20 ) and interacting with a stationary shifting link ( 33 ) arranged concentrically with the shift lever ( 12 ). 2. Switch according to claim 1, characterized in that the switching lever ( 12 ) has an axially lying, spring-loaded latching element ( 15 ) in a blind hole ( 13 ) which is arranged with a cross-shaped on the central axis of the switch in the housing base ( 7 ) Curved track ( 10 ) cooperates, which determines the basic position ( 18 ) assigned to the switch-off state and, in the end products, an unlocked switching position of the shift lever ( 12 ). 3. Switch according to claims 1 or 2, characterized in that in the underside of a on the shift lever ( 12 ) attached switch button ( 45 ) is a 180 ° extending groove ( 48 ) is inserted into which in the basic position of the switch button ( 45 ) on the housing ( 1 ) attached stop ( 49 ) engages that on the stop ( 49 ) and on the opposite side of the housing ( 1 ) each have a wide, short web ( 50 ) and at right angles to each other a narrow, long web ( 51 ) is attached to the housing, and that in the basic position and simultaneous blocking position of the pivoting movement of the switching button ( 45 ) the narrow, long webs ( 51 ) have correspondingly designed recesses ( 53 ) in the underside of the switching button ( 45 ) over the wide, short webs ( 50 ) are on the housing ( 1 ), while the wide, short webs ( 50 ) have correspondingly designed recesses ( 52 ) in the underside of the switch button ( 45 ) are located above the narrow, long webs ( 51 ) on the housing ( 1 ). 4. Switch according to one of claims 1 to 3, characterized in that the latching means of the rotary switching element ( 20 ) from two opposite, one-sided in the rotary switching element ( 20 ) mounted locking levers ( 36 ), each in the region of the free end Compression spring ( 38 ) is assigned, or consist of two opposite locking bolts ( 56 ) arranged spring-loaded in the rotary switching element ( 20 ). 5. Switch according to claims 1 to 4, characterized in that each compression spring ( 38 ) at one end by a recess ( 39 ) in the rotary switching element ( 20 ) and at the other end by a pin ( 40 ) on the locking lever ( 36 ) is held in position. 6. Switch according to one of claims 1 to 5, characterized in that the latching levers ( 36 ) in the region of their storage ( 42 ) in the rotary switching element ( 20 ) are connected to one another by a film hinge ( 43 ). 7. Switch according to one of claims 1 to 5, characterized in that the switching link ( 33 ) on a housing extension ( 32 ) or on the side walls ( 55 ) of the housing ( 1 ) is integrally formed. 8. Switch according to one of claims 1 to 7, characterized in that the switching link ( 33 ) made square in cross section and each outside centrally with a notch ( 34 ), in the opposite, correspondingly formed locking lugs ( 37 ) of the locking lever ( 36 ) intervene, is provided. 9. Switch according to one of claims 1 to 8, characterized in that the legs of the corner angle (β) of the switching link ( 33 ) each form an obtuse angle. 10. Switch according to claim 9, characterized in that the angle (α) between the bevels of each notch ( 34 ) of the shift gate ( 33 ) is 150 ° and each corner angle (β) of the shift gate ( 33 ) is 120 °. 11. Switch according to one of claims 1 to 10, characterized in that the switching lever ( 12 ) through a conical, the pivoting movement of the switching lever ( 12 ) adapted center bore ( 22 ) of the rotary switching element ( 20 ) is guided in that the switching lever ( 12 ) is mounted on a ball joint ( 27 ) in a neck ( 23 ) formed on the rotary switching element ( 20 ), which extends from the narrow side of the center bore ( 22 ) into a dome-like housing bulge ( 24 ), and that two opposite pins ( 28 ) of the ball joint ( 27 ) are guided in associated vertical grooves ( 29 ) of the neck ( 23 ) of the rotary switching element ( 20 ).