EP0309741A1 - Push-button electrical switch - Google Patents

Abstract

In order to achieve precise linear guiding and rotational positioning of the push-button part on both parts, the push-button switch with a housing part (10) and linearly moving push-button part (30) has guide columns (20 or 40) which grip over one another and are connected to one another in a multiple line contact (24) running in the movement direction (25). The length of the line guide is variable between the rest position and the operating position of the push-button part (30), and is at its greatest in the latter. The contact surface (19) of the fixed mating contacts (18) is designed as a flat sliding surface for the sprung contact arms (37). The friction which is connected with the inevitable sliding movement when the contacts close results in self-cleaning of the contacts and damping of bouncing movements. As a result of precise guiding and damping of the movement, the contact bouncing time is decisively reduced (even when the push-button is operated eccentrically). …<??>A snapping mechanism, which has to be overcome on operation, advantageously consists of a permanent-magnet cover plate (15) on the housing part and an anchor plate (35) on the push-button part. For use in individual switches or those which form a component of a push-button panel with a common housing part (10). …<IMAGE>…

Description

The invention relates to an electrical key switch with a housing part, which contains fixed mating contacts, and a key part, which can be moved linearly to the housing part between a rest position and a working position by overcoming a snap mechanism, and a contact bridge with resilient contact arms inclined to the direction of movement for interacting with the counter contacts having.

In a known key switch of this type, unsafe contacting sometimes made itself felt, but above all a bounce time that was too long after the switch was actuated, which is very undesirable, especially in conjunction with electronic circuits. In addition, it turned out that the bounce time was strongly dependent on whether the plunger on the button part was actuated in the center or eccentrically. A closer analysis showed that the deficiencies found were partly due to a non-optimal contact design, but above all to an insufficient guidance of the movable button part, by not only bouncing the resilient contact arms alone, but also uncontrolled vibrations of the entire button part, superimposed on the actuation path were found.

The object of the invention is to achieve the shortest possible contact bounce time in a switch of the type mentioned in connection with a safe and flawless contact. This is achieved according to the invention in that, for the purpose of linear guidance and rotational positioning of the key part, the housing part and the key part are provided with overlapping guide columns which are in multiple, linear contact with one another in the direction of movement, the length of which is variable during the movement and is greatest in the working position.

With such a configuration of the key switch, the contact bounce time can be drastically shortened, and in fact far below a value of 5 ms, as is required for numerous applications. With only slight friction (thanks to line contact), an effective linear guidance and alignment of the rotary position of the button part is achieved, which achieves the best effect at the moment of contact with the contact and in the area of a subsequent overrun in which the contact pressure is built up. This prevents the button part from "fluttering", largely regardless of whether the button plunger is actuated in the middle or on the edge.

With a contact training according to claim 2 in conjunction with the effective key guide, additional damping of the contact bouncing movements and self-cleaning of the contacts can be achieved. Further expedient refinements are specified in claims 3 to 6. The idea of the invention can be realized with particular advantage in combination with a permanent magnetic snap mechanism according to claim 6, in which the actuating force is greatest at the beginning of the actuation ("tearing off" of the magnetically held anchor plate) and then falling steeply; this very favorable force / displacement characteristic is hardly noticeably impaired by the linear guidance of the button part according to the invention.

• Fig. 1 ist die Draufsicht auf einen Tastenschalter, welcher Teil eines Tastenfeldes bildet,
• Fig. 2 ist ein Schnitt entlang der Linie II - II in Fig. 1 in einem grösseren Massstab, wobei der Tastenteil links in der Arbeitslage und rechts in der Ruhelage gezeichnet ist,
• Fig. 3 ist eine Ansicht der Kontaktbrücke, der festen Gegenkon­takte und der Führungssäulen,
• Fig. 4 zeigt die zentrale Schalterpartie perspektivisch und teilweise aufgeschnitten,
• Fig. 5 veranschaulicht in grösserem Massstab die Kontaktausbil­dung und -Wirkungsweise beim Schalter nach Fig. 1 bis 4, und
• Fig. 6 und 7 zeigen schematisch im Schnitt weitere Möglichkei­ten der Querschnittgestaltung von übereinandergreifenden Führungssäulen.

The invention is explained in more detail below on the basis of exemplary embodiments in conjunction with the drawing.

• Fig. 1 is a plan view of a key switch, which part a keypad,
• 2 is a section along the line II - II in FIG. 1 on a larger scale, the key part being drawn on the left in the working position and on the right in the rest position,
• 3 is a view of the contact bridge, the fixed mating contacts and the guide columns,
• 4 shows the central switch section in perspective and partially cut open,
• Fig. 5 illustrates on a larger scale the contact formation and mode of operation in the switch of Fig. 1 to 4, and
• 6 and 7 schematically show in section further possibilities for the cross-sectional design of overlapping guide columns.

The electrical key switch shown in FIGS. 1 to 5 is composed of a housing part 10 and a key part 30 (FIG. 2). As is known per se, several identical switches - e.g. four rows to four switches - to be combined into a so-called keypad, in that the housing part is made in one piece and is common to all switches of the keypad.

Side walls 13 and intermediate walls 14 extend from the continuous, flat bottom 12 of the housing. For each switch, two fixed mating contacts 18 with connecting pins led out of the rear of the base are preferably embedded in the base 12. In parallel and at a distance from the floor 12 are two "plates" 15, 16, each with a rectangular opening for the button part of each switch; the plates 15 and 16 are after the assembly of the keypad connected to the floor 12 in a manner not shown. The plate 15 is permanently magnetic and is preferably made from a mixture of plastic and magnetizable metal powder. The plate 16 is made of steel and serves as a magnetic shield.

In the middle of the housing base 12, between the counter contacts 18 located approximately in a diagonal of the rectangular base, a guide column 20 with an extension 21 for guiding the button part 30 is formed. The button part 30 has an actuating plunger 31 projecting beyond the plates 15, 16 and a rectangular flange 32 connected to the plunger. A flat, rectangular anchor plate 35 made of steel and a contact bridge 36 are held between the plunger 31 and the flange 32. The shape of the contact bridge 36 can be seen in particular from FIG. 3. It has two resilient contact arms 37 pointing obliquely downwards, each of which ends in double contacts 38 which cooperate with the fixed counter-contacts 18.

In the rest position of the plate part 30 (on the right in FIG. 2), the anchor plate 35 bears against the underside of the plate 15 and is held by this magnet permanently. The plates 15 and 35 thus form a snap mechanism, which is overcome by depressing the plunger (arrow 25 in Fig. 2). After the armature plate 35 has “torn off” from the magnetic plate 15, the magnetic attraction quickly decreases with increasing distance, so that the button part 30 moves suddenly into the working position and the contact between the two counter-contacts 18 is established. In the working position (left in Fig. 2), the magnetic force is still so great that after releasing the plunger 31, the button part is raised again to the rest position.

When the button part 30 moves between the rest position and the working position in the direction of arrow 25, the button part is loosely guided by the column extension 21, which engages in a corresponding recess 33 on the plunger 31. For exact linear guidance of the However, part of the button as well as its positioning in the rotational position serves the following arrangement: The guide column 20 of the housing part has two opposite, V-shaped guide grooves 22, and on the button part on the underside of the plunger 31 two cylindrical guide columns 40 are formed, each in a V Engage the groove 22 so that there is a line contact 24 in the direction of the linear movement 25 at a total of four locations. By overlapping the guide columns 40 of the button part and the guide column 20 of the housing part in this way, the length of these line contacts increases when the button is pressed from the rest position to the working position and is therefore the largest in the working position. The working or lower end position of the key part is determined by a stop surface 23 of the guide column 20 at the transition to the column extension 21, on which surface the underside 34 of the key tappet 31 comes to rest (see FIG. 4).

The described arrangement of the overlapping guide columns 20 and 40, connected to the end stop 23, 34, enables an effective and precise movement guidance and positioning of the key part, especially in the end region of the movement when the contact closure takes place, which significantly reduces the contact bounce time. Compared to the guide through the column extension 21 alone, the guide length is almost doubled in the working position of the button part. For the effectiveness of the guide, it has proven to be expedient if, as shown, the guide columns 20 and 40 (seen in the direction of movement) are located in an area lying between the counter-contacts 18, and it is also advantageous if the stop surface 23 for the Key part is provided on the centrally arranged guide column of the housing part. The linear guidance achieved is also effective when the key is pressed on the edge of the plunger 31 instead of in the middle.

As can be seen above all from FIG. 2, in the rest position the distance between the contact arms 37 and the mating contacts 18 is less than the key path to the working position. This means, that after the first contact touch, the key part continues to run into the end position, in which the contact arms 37 are resiliently bent, as a result of which the required contact pressure is achieved. 5, the position of a contact arm end at the moment of first contact of the mating contact is shown in dash-dotted lines and in the end position in solid lines. The contact surface 19 facing the contact arms 37 is expediently designed to be flat on the mating contacts. Thanks to the precise longitudinal guidance with little rotational play of the button part, each contact arm 37 performs an inevitable sliding movement s on the flat contact surface 19 during the run-on according to FIG. 5 (in contrast to a rolling movement with a curved contact surface). The mentioned sliding movement is accompanied by an effective self-cleaning of the contacts, and the associated sliding friction causes additional damping of bouncing movements of the contact arms. The formation of double contacts 38 at the ends of the contact arms also contributes to the reliable contact closure.

The illustrated configuration of the guide columns 20 and 40, with a central, opposite V-groove guide column on the housing part, has proven to be advantageous for spatial reasons in the given contact arrangement. Of course, there are numerous other options for the design of overlapping guide pillars with multiple line contact. Two such variants are shown schematically as examples in FIGS. 6 and 7: According to FIG. 6, a pair of cylindrical guide columns 20a and 40a are present on both the housing part and the button part, with a line contact 24 for longitudinal guidance and rotational positioning at four points . In the example according to FIG. 7, four angular columns 20b form crossed guide slots on the housing part, in each of whose arms a cylindrical column 40b of the key part engages with line contact 24.

Claims (6)

1. Electric key switch with a housing part (10), which contains fixed mating contacts (18), and a key part (30), which can be moved linearly to the housing part between a rest position and a working position while overcoming a snap mechanism (15, 35) and a contact bridge (36) with resilient contact arms (37) inclined to the direction of movement for interacting with the mating contacts, characterized in that for the purpose of linear guidance and rotational positioning of the key part (30) the housing part (10) and the key part (30) with overlapping guide columns (20, 40) are provided which are in multiple line contact (24) running in the direction of movement (25), the length of which is variable during the movement and is greatest in the working position. 2. Key switch according to claim 1, characterized in that the counter contacts (18) have a flat, with the double contacts (38) formed contact arms (37) facing sliding surface (19). 3. Key switch according to claim 1 or 2, characterized in that the guide columns (20, 40), seen in the direction of movement (25), are arranged in an area lying between the counter-contacts (18). 4. Key switch according to claim 3, characterized in that a centrally arranged guide column (20) of the housing part has a stop surface (23) determining the working position for the Has button part (30). 5. Key switch according to one of the preceding claims, characterized in that it forms part of a keypad with a plurality of switches common housing part (10). 6. Key switch according to one of the preceding claims, characterized in that the snap mechanism is formed by a permanent magnetic plate (15) on the housing part and an anchor plate (35) connected to the key part.

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