WO2002103850A2

WO2002103850A2 - Multi-position switch comprising a progressively displaceable contact

Info

Publication number: WO2002103850A2
Application number: PCT/DE2002/002138
Authority: WO
Inventors: Roland Ruegenberg
Original assignee: Methode Electronics Inc.
Priority date: 2001-06-15
Filing date: 2002-06-12
Publication date: 2002-12-27
Also published as: WO2002103850A3

Abstract

The invention relates to a switch comprising a slider (3) carrying contacts (4) and provided with a saw-like drive gearing (7) extending in the sliding direction. Said drive gearing comprises drive teeth (9) which rise towards an actuator (2). The actuator (2), which can be displaced perpendicularly in relation to the direction of displacement, is provided with an actuating cam (10) which can be slid along the drive teeth (9). When the actuator is pressed in, said actuating cam displaces the slider (3) along the slide path of a drive tooth (9). A stop gearing (11) which is formed on the slider (3) and extends in the sliding direction, and a stationary cam-like stop element (13) which can be elastically displaced, move the slider (3), by means of their catch action, along a residual height into a defined catch position in which the contacts (4) can be brought into contact with stationary corresponding contacts (6) of the switch. The invention enables the handling and production of one such switch to be improved.

Description

description

Multi-stage switch with a contact that can be shifted gradually

The invention relates to a multi-stage switch with at least one step-wise displaceable contact, with a plurality of stationary counter-contacts distributed along a displacement distance of the contact, with at least one movable essentially perpendicular to the direction of displacement

Actuator, with a slide which supports the contact and which is adjustable in the direction of displacement, with a link-like drive for the gradual conversion of an actuator stroke into an adjustment stroke of the slide, and with fixing means for temporarily fixing the slide in the respective switching position.

Such a switch is e.g. made known by US4318221 A. In this case, a tappet actuates a rotary valve step by step via a circular link drive, with a return stroke rotating the rotary valve further by one switching division. In such a position, the rotary valve is fixed in a form-fitting manner. Due to the fixed direction of rotation, the switch can only be cyclically operated. In the case of a multi-stage switch with a small step angle, the plunger has to be actuated correspondingly frequently for a large actuating travel, which is particularly annoying if one wishes to return to the respective preliminary stage from a rotary position. Such rotary links also require link elements that are difficult to produce on the inside of a cylinder.

The invention has for its object to improve the handling and manufacture of such a switch.

This object is achieved by the invention according to claim 1. The drive toothing and the locking toothing can be molded, for example, on the outer edge of an elongated slide with little outlay on the device. Such a slide can be inserted into a linear or circular guideway of a switch housing in a technically simple manner. The actuator engages with its drive element in a simple stroke curve in the drive toothing. The stroke direction oriented in the mounting direction enables a one-piece arrangement on an operating element which can be mounted on the switch housing by simply snapping on.

Part of the feed movement is here by the

Snap movement of the locking means achieved. This makes it possible to keep the feed generated by pressing in the actuator smaller than the feed division, which means that complex drive means can be dispensed with. The drive gearing is then removed after the e.g. resiliently deflected actuator by the locking action pulled a short distance, which already allows the drive element to reach the engagement area of the next locking slope. Another advantage is the temporary functional separation of the drive means from the locking means. As a result, the drive element completely disengages during its return stroke into its starting position and cannot hinder the centering process of the latching means. The locking teeth can advantageously be formed on the elongated slide and the locking element can be attached to the switch housing.

Another advantage is that the actuator, which is disengaged in its starting position, releases the slide completely and that the slide can then be moved in a simple manner in the opposite direction, in particular into an immediately preceding switching position, by additional restoring means.

The actuator can e.g. as sloping, on

Actuator pivotally mounted pawl, which remains, for example by a pivot stop in the starting position above the drive teeth. When the actuator is lowered, it engages in the drive teeth, is in the Direction of displacement deflected and takes the slider with it.

Advantageous further developments of the invention result from the features characterized in claims 2 to 12.

The drive means according to claim 2 form an easy to manufacture and functionally reliable mechanism.

The development according to claim 3 enables a maximum drive feed.

Through the developments according to claims 4 to 6, the slide can be moved back and forth with similar means, the arrangement according to claim 5 allowing a slim structure and clearly separated actuating elements.

The control rocker according to claim 7 enables operation on both sides with a stable mounted component in a simple and logical manner.

Through the development according to claim 8, the pivot axis of the operating rocker is so far above the slide that a movement component in the displacement direction can be derived from the pivoting movement, which supports the slide movement.

In the arrangement according to claim 9, this component forms directly on the drive cam and is thus transmitted directly to the slide.

In the switch according to claim 10, the latching element is first pivoted against the direction of displacement and thus already reaches the engagement area of the next latching recess after a small useful stroke of the slide. When the control rocker is released, the locking element swings back into its starting position and takes the slide with it. In this way, the entire shifting stroke can take place on both phases of the actuation cycle can be divided so that the actuation stroke of the drive cam can be reduced.

The contact spring according to claim 11 can be mounted in a simple manner and enables the slide to be supported and guided in the housing without play. The arrangement of the mating contacts in one plane can be easily realized on a circuit board.

The development according to claim 12 enables additional center support of the slide against the force of the actuator.

An embodiment of the invention is shown in the drawing and is explained in more detail below. Show it:

1 shows a schematic side view of a switch according to the invention, FIG. 2 shows a top view of parts of the switch according to FIG. 1,

Figure 3 is a schematic side view of a modified switch similar to Figure 1, Figure 4 is a plan view of parts of the switch of Figure 3.

According to Figures 1 and 2 has a multi-stage switch z. B. for the adjustable current supply to a seat heater, a housing, not shown, a rocker arm 1 pivotally mounted in the housing about a pivot axis 19, attached to this downward protruding actuator 2, a parallel to the rocker switch 1 and in this direction A sliding slide 3 with Contacts 4 and a circuit board 5 with mating contacts 6. The relation referred to below as “top / top / over” stands for a direction pointing to the operating side of the switch, “bottom / bottom” for the opposite direction.

The slide has on its upper side facing the operating rocker 1 with two in the direction of displacement extending drive toothing 7, which is provided with upwardly facing saw-like teeth 8. These have a ramp-like profile, each with a drive bevel 9, the drive bevels 9 of the two mutually mirror-image drive teeth 7 being inclined in opposite directions and arranged on the outer sides of the teeth 8 facing away from one another. Intermediate bevels 18 of the teeth 8 arranged between the successive drive bevels 9 are perpendicular to the displacement direction A.

The actuators 2 are designed at their ends facing the drive teeth as drive cams 10 adapted to the tooth profile. They are arranged in a contact position of the slide 3 so that they slightly overlap the associated drive slope 9. When pressing on one end of the rocker switch 1, the drive cam 10 first reaches the intermediate position shown in broken lines, in which it just touches the drive slope 9. When the actuator 2 is pressed further into the end position indicated by double-dashed lines, the slide 3 is displaced in the indicated arrow direction by the wedge effect of the drive bevels 9 and reaches the intermediate line-dashed position. Pressing the other end of the rocker switch 1 results in an opposite direction of displacement.

The slide 3 has on another longitudinal side of a locking toothing 11 with recesses 12 which are uniformly chamfered on both sides and have the same spacing as in the drive toothing. A cam-like, resiliently deflectable stationary latching element 13 made of spring plate engages in one of the recesses and is fastened to the printed circuit board 5. The bevels of the recesses 12 are designed such that when the latching tips 14 lying between the recesses 12 are exceeded, a snap effect occurs, which causes the slide 3 to move into a defined latching position of the adjacent recess, as is indicated by the latching element 13 and the dash-dot line Locking toothing is indicated. The slider ^■ can be shifted forwards or backwards from switch position to switch position step by step. The number of switch positions can be changed to a large extent, for example, by adjusting the slide length or the spacing.

The contacts 4 are formed at the ends of a bow-shaped contact spring 15, which is fixed in a recess in the bridge-like slide 3 by means of a central position-securing holding pin 16. This is supported with its underside on a slideway of the slide, so that the bending load on the slide 3 resulting from the actuating forces is reduced. The counter contacts 6 are distributed in two groups linearly aligned in the direction of displacement, their pitch division corresponding to the drive teeth 7. In each case a pair of the counter contacts from both groups is contacted with the contacts 4 of the contact spring 15 and is thus electrically connected.

The switch according to FIGS. 3 and 4 differs from the switch according to FIGS. 1 and 2 essentially in that the drive bevels 9 are formed on the inside of the teeth 8 and in that another locking element 17 made of spring plate is attached to the operating rocker 1 , In this switch, the direction of displacement A is reversed and the locking element 17 projecting radially from the pivot axis 19 is first pivoted against the direction of displacement. Thus, after a small useful stroke of a modified slide 3a, it reaches the engagement area of the next recess 12 of the latching toothing 11. This phase is indicated by the dot-dash position of the latching element 17. When the control rocker 1 is released, the locking element 17 pivots back into its starting position and takes the slide 3a with it. In this way, the entire displacement stroke can be divided into two phases of the actuation cycle, so that the actuation stroke of the correspondingly modified drive cam 10a can be reduced. reference numeral

1 operating rocker

2 actuators

3, 3a slider

4 contact

5 circuit board

6 counter contact

7 Drive telling

8 tooth

9 drive bevel

10, 10a drive cams

11 locking teeth

12 recess 13 locking element

14 locking tip

15 contact spring

16 holding pins

17 locking element 18 intermediate flank

19 swivel axis

A direction of displacement

Claims

claims

1. Multi-stage switch, in particular for vehicles with at least one step-wise displaceable contact (4), with several stationary counter-contacts (6) distributed along a displacement distance of the contact (4), with at least one actuator (2) that can be moved essentially perpendicular to the displacement direction, with one by means of this slide (3), which is adjustable in the direction of displacement and carries the contact (4), with a link drive for the gradual conversion of an actuator stroke into an adjustment stroke of the slide (3), and with fixing means for temporarily fixing the slide (3) in the respective switching position characterized in that the slide (3, 3a) is provided with a saw-like drive toothing (7) which extends in the sliding direction and faces the actuator (2), that the actuator (2) has a drive element (e.g., engaging in the drive toothing (7)) 10), which converts the actuator stroke into the actuator stroke and which is in one Starting position is outside the drive toothing (7) and that the fixing means from one in the

Latching toothing (11) extending in the sliding direction and a cam-like latching element (13, 17) which can be deflected perpendicularly resiliently there.

2. Switch according to claim 1, characterized in that the drive toothing (7) with in the sliding direction to the actuator (2) towards the drive bevels (9) is provided that the drive element is designed as a drive cam (10, 10a), which in its Starting position of the locking position slightly overlaps the outer end of the drive slope (9) and that the actuator (2) one along the drive slope (9) has slidable drive cams (10, 10a).

Switch according to Claim 2, characterized in that an intermediate flank (18) which is approximately perpendicular to the direction of displacement is formed between the successive drive slopes (9) and, together with the drive slope (9), delimits a tooth (8) of the drive toothing.

4. Switch according to claim 1, 2 or 3, characterized in that the slide (3) has two of the drive teeth (7), each with oppositely inclined drive slopes (9) and two of the actuators (2) assigned to them.

5. Switch according to claim 4, characterized in that the two drive teeth (7) are arranged in two mutually parallel tracks and that the actuators are correspondingly next to each other.

6. Switch according to claim 4, characterized in that the two drive teeth (7) are arranged one behind the other in the direction of displacement and that the two actuators (2) are arranged one behind the other in the direction of displacement.

7. Switch according to claim 6, characterized in that the actuators (2) are attached to an operating rocker (1) of the switch and that this can be fixed in a central angular position by means of a centering device.

Switch according to Claim 7, characterized in that a pivot axis (19) of the operating rocker (1) is arranged at a clear distance above the drive toothing (9), and that the drive cams (10, 10a) of the actuators (2) are arranged in the rest position at a short distance above the drive teeth (9).

9. Switch according to claim 6, 7 or 8, characterized in that the drive bevels (9) of the drive toothing on the other drive toothing (9) facing away from the teeth (8) are arranged and that the locking element (13) stationary in the direction of displacement is anchored in the switch.

10. Switch according to claim 6, 7 or 8, characterized in that the drive bevels (9) of the drive toothing are arranged on the side of the teeth (8) facing the other drive toothing (9) and that the latching element (17) on the operating rocker (1) is attached.

11. Switch according to one of the preceding claims, characterized in that the displaceable

Contact (4) at one end of a bow-shaped

Contact spring (15) is designed so that to form a bridge contact at its other end carries a second contact (4) which cooperates with at least one further stationary counter-contact (6), that the counter-contacts (6) are arranged in one plane and that the contact spring (15) is arranged on the underside of the slide (3. 3a) facing away from the actuator (2).

12. Switch according to claim 11, characterized in that the bridge-like slide (3) has a recess for receiving the contact spring (15) with a central holding pin (16) for this and that the underside of the holding pin (16) on a Slider of the slide (3, 3a) is supported.