The invention relates to a switch, particularly a window lifter switch.
A known switch has a housing, a switching rocker which is mounted in the housing and is associated with electrical contacts, and a button which is likewise mounted in the housing.
By actuating the button, the switching rocker is moved which, in turn, then actuates one of the electrical contacts. The actuation of the button can usually take place in two directions, for example pushing and pulling, whereby different contacts are connected. Each of the contacts can generally be switched in two stages, for example in a first stage with a light actuating force and in a second stage with a greater actuating force or a greater stroke of the button. In this way, for example, a window lifter motor can be actuated in the desired direction, i.e. opening or closing of the window pane, and in the desired type of operation, in order for example to be actuated manually, as long as the corresponding button is held or complete opening or closing of the window pane, even after the button as been released.
A problem in such switches is that the button basically tends to rattle. In particular owing to the unavoidable vibrations in a motor vehicle, an undesired noise is then generated in the interior of the vehicle.
It is an object of the invention to further develop a switch of the type initially mentioned to the effect that rattling noises are avoided.
To achieve this object, in a switch, particularly a window lifter switch, with a housing, a switching rocker which is mounted in the housing and is associated with electrical contacts, and with a button which is likewise mounted in the housing, the button is acted upon elastically so that it is mounted free from play in the housing. In this way, the undesired vibrations are reliably prevented.
A switching mat is preferably provided, which is provided with the electrical contacts and with which the switching rocker cooperates, the switching mat acting upon the rocker elastically against the button. In this embodiment, no additional structural element is necessary in order to act upon the button elastically so that it is free of play. Owing to its characteristics, the switching mat is readily able to permanently provide the necessary elastic pre-stressing.
“Free of play” is understood here to mean a state in which the button has no play relative to the housing in the case of the vibrations which usually occur. It stands to reason that when greater stresses occur, the button can definitely have a play in the housing, for example when it is moved by a user in opposition to the elastic application force.
The rocker is preferably mounted in the housing so that it is displaceable towards the button. In this way, it can transfer the elastic application force provided from the switching mat directly onto the button.
According to the preferred embodiment of the invention, provision is made that the button is mounted in the housing by means of a two-point bearing. “Two-point bearing” is understood here to mean a bearing which has two bearing points or bearing surfaces which are separated from each other spatially, in which with a relative movement between the button and the housing in one direction, a movement takes place about the one bearing point or the one bearing surface, whereas with a relative movement in the opposite direction, a movement takes place about the other bearing point or the other bearing surface. Unlike a conventional swivel bearing, in which the relative movement between two components always takes place about the same swivel axis, in a two-point bearing there are two different movement axes depending on the direction of movement. This can be seen in the example of a cube which stands on a flat base. If the cube is to be tilted in one direction, it tilts over the corresponding outer edge of its underside, which touches the base. With a movement in the opposite direction, the cube tilts about the opposite outer edge of the underside, i.e. about a spatially distanced axis. The use of a two-point axis offers the critical advantage that it automatically forms a precise defined middle position into which the button is acted upon. In a comparable manner to the cube which has been discussed, which due to its weight experiences a force bringing it into a position in which it rests with its entire underside on the base, the elastic pre-stressing acting upon the button to bring it into a position in which the two bearing points or bearing surfaces are uniformly stressed. This is particularly advantageous when two switches are arranged adjacent to each other or the switch is constructed as a double switch. A slight malposition of the button in the neutral position would in this case already be negatively noticed. The neutral position precisely defined by the two-point bearing ensures that the buttons assume exactly the same position in the unactuated position.
A further advantage which is connected with the use of the two-point bearing consists in that comparatively high elastic pre-stressing forces can be applied by the switching mat, without the risk occurring that the button is deflected in an undesired manner out from its neutral position. Owing to unavoidable manufacturing tolerances, the risk occurs in every switch that the elastic pre-stressing force applied by the switching mat does not act exactly on a line which runs through the mid-point of the connection between the switching rocker and the button on the one hand and the bearing between button and housing on the other hand. If a conventional journal bearing were used for the bearing of the button in the housing, a slight deviation of the direction of action of the elastic pre-stressing force from the ideal path would generate a torque which attempts to deflect the button out from its neutral position. This torque is determined by the lever arm, i.e. the shorter distance between the direction of action of the elastic pre-stressing force and the mid-point of the journal bearing, multiplied by the pre-stressing force. However, the two-point bearing has two bearing points or bearing surfaces which lie at a distance from each other on one side or the other of the middle line and theoretical line of action of the elastic pre-stressing force. As long as the actual direction of action of the elastic pre-stressing force runs anywhere between the two bearing points or bearing surfaces, no torque is produced which attempts to move the button out from its neutral position. The two-point bearing in fact ensures that the button remains in a stable manner in its neutral position.
Such a two-point bearing can preferably be formed by a journal pin and a bearing surface, in which the journal pin has on its side facing the switching mat a geometry which deviates from the circular shape, when viewed in cross-section, and in particular has a generally rectangular cross-section. This ensures that the two edges lying on the one and the other side of the middle line act as swivel axes of the two-point bearing. Preferably bearing surfaces which are arranged in a V-shape and receive the journal pin between them cooperate with the two edges of the journal pin.
To improve the centering of the switching rocker relative to the button, a play-free abutment is preferably formed between the switching rocker and the button. This can be realized by an abutment pin which engages into an abutment fork which is provided with two abutment surfaces arranged in a V-shape. Advantageous embodiments of the invention will be apparent from the sub-claims.
In
The switching mat 12 is associated with a metal plate 14 which can be pressed downwards by an actuating striker 16. The actuating striker 16 is arranged in the ratio 1/3 to 2/3 eccentrically on the metal plate, so that two contacts can be actuated in two stages. The contacts are arranged one behind the other with respect to
The switching rocker 20 has an oblong hole 22 into which a bearing pin 24 engages which is mounted on the housing 10 or part of the housing. The switching rocker has, in addition, an abutment pin 26 which has a circular cross-section and cooperates with the button 30.
For this purpose, the button 30 is provided with an abutment fork which has two abutment surfaces 34 which are aligned in a V-shape (see also
The button 30 is mounted in the housing 10 by a journal pin 36 which is mounted on the housing or part of the housing. The button 30 has an opening 38 into which the journal pin 36 engages. On its side facing the switching mat 12, the opening 38 is provided with two bearing surfaces 40 (see also
Through the cross-sectional shape of the journal pin 36, a two-point bearing is provided between the button 30 and the housing 10, because the button 30 rests on the journal pin 36 in two points P (see
When the button 30 is actuated, it swivels in accordance with the actuating direction about the journal pin 36. The abutment fork 32 is thereby swiveled, whereby the abutment pin 26 is entrained. This leads to a tilting movement of the switching rocker 20 about the bearing pin 24, so that the switching rocker presses onto one or other contact of the switching mat 12.
An essential feature of the switch is that the button 30 is acted upon by an elastic pre-stressing force, so that it is free of play. This pre-stressing force is produced through the switching mat 12 which, in the initial state, is held in a compressed state in the vertical direction in relation to
The theoretical path of force is shown in
Number | Date | Country | Kind |
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10 2007 052 655.7 | Nov 2007 | DE | national |