DE10134895C1 - Electrical push-button switch has cylindrical switch rod provided with guide sleeve for fixing in switch dome - Google Patents

Abstract

The push-button switch has a housing (1) enclosing a switch part (2) with a heart-shaped ratchet cam, displaced against a spring bias by operation of the switch push-button (5) for closure of switch contacts, the ratchet cam engaged by a ratchet lever (7), released by subsequent operation of the push-button. The spring bias is provided by a spring elastic switch mat (6) with a switch dome (6A) containing a movable switch contact operated by a cylindrical switch rod (2B) of the switch part, having a guide sleeve for fixing the switch rod in the switch dome.

Description

The invention relates to a push button switch with a latching position. On Generic push button switch consists of a housing in which a switching part is arranged, which can be moved against a spring force by pressing a push button is. The switching part acts on a contact element, which due to the displacement of the Switching part for effecting an electrical switching contact pressed against a circuit board becomes. The locking mechanism consists of a heart-shaped molded on the switching part Locking curve, in which a housing-mounted, pivotable locking lever is guided. When you press the pushbutton (i.e. press and then releasing) the switching part from an initial switching position in the the contact element is spaced from the circuit board, in a latched position in which the Presses contact element against the circuit board, spent. The is in the resting position Locking lever in the locking position of the heart-shaped locking curve. In the rest position, it will Contact element is pressed resiliently against the circuit board via the spring force. At a Pressing the push button again will then switch the switching part from the rest position into the Starting position spent, with the contact element again lifting off the circuit board.

Such a push button switch is known for example from DE 198 39 602 A1. A compression spring is provided there to generate the spring force. The use of a Compression spring and its assembly is complex and correspondingly expensive. From FR 2 584 528 A1 a generic push button switch according to the The preamble of the claim is known, which is a safety mat in the form of a snap-back reset membrane used and therefore no compression spring required.

The object of the invention is to that effect the generic push button switch further develop that the plunger of the switching part against the switching dome of the switching mat is better fixed.  

This object is achieved in that the plunger is designed as a cylinder is on the front side also a hollow cylindrical guide sleeve with a smaller one Is molded onto the diameter, the guide sleeve for fixing the plunger in the Switch dome engages.

The invention will be explained in more detail below with the aid of the accompanying drawings. It shows:

Fig. 1 is an exploded view of a switching device with three pushbutton switches,

Fig. 2 shows a section through the switching part with switching mat,

Fig. 3 is a perspective view of the shifting member with a heart-shaped locking cam,

Fig. 4 is an illustration of the heart-shaped latching curve with the trajectory of the latch lever,

Fig. 5 shows the force-displacement curve of the keypad corresponding to the position of the latching lever in the locking curve,

Fig. 6, the height profile within the detent curve,

Fig. 7 is a section through the switching mat in the initial position,

Fig. 8 shows a section through the switch mat at the end of the switching stroke area, where the contact pill contacts the circuit board.

Fig. 1 shows a switching device with three push button switches ( 3 , 5 ) in an exploded view, wherein all push button switches are housed in a common housing ( 1 ). Two of the push button switches ( 3 ) integrated in the switching device do not have a latching position. With these pushbutton switches ( 3 ), the switching stroke of the pushbuttons ( 3 ) is only transferred to a switch mat ( 6 ) via plunger ( 4 ) - without a switching part with a locking curve - whereby contact pills ( 6 B) are pressed against the circuit board ( 8 ).

The push button switch ( 5 ) according to the invention with a latching position is located in the switching device shown in the middle between the two push button switches ( 3 ) without a latching position. The push button switch according to the invention (5) has a switching part (2) having a heart-shaped latching curve (2 A). When pressing the push button ( 5 ) as the control element of the switch, the switching part ( 2 ) is moved linearly relative to the housing ( 1 ) and at the same time a locking lever ( 7 ) mounted on the housing is guided in the locking curve ( 2 A). The switching part (2) now in turn pushes a plunger (2 B) on an integrally formed on the switching mat (6) switching dome (6 A). On the side of the switch mat ( 6 ) facing the printed circuit board ( 8 ) there is a contact pill ( 6 B), which is pressed against the printed circuit board ( 8 ) when the switching dome ( 6 A) is pressurized and there are two conductive tracks for switching a switching state connects with each other.

The plunger, the switching dome and the to reduce the pressure force to be applied Contact pill available twice. In addition, this redundancy also increased switching reliability in the event that, for example, a contact pill is defective or the conductor tracks in the area of a contact pill are dirty.

When the pushbutton ( 5 ) is actuated (pressed and then released), the switching part ( 2 ) is moved from an initial switching position, in which the contact pill ( 6 B) is spaced from the printed circuit board ( 8 ), into a detent position, in which then press the contact pill ( 6 B) against the circuit board ( 8 ). In the locked position, the pushbutton ( 5 ) is arranged slightly recessed in the switching device so that the operator can visually perceive the switching position.

When the pushbutton ( 5 ) is actuated again, the switching part ( 2 ) is brought back from the locked position to the starting position.

The sequence when the push button ( 5 ) is actuated is to be illustrated with reference to FIGS. 4 to 6. Fig. 4 shows the heart-shaped locking curve ( 2 A), which is preferably formed in one piece with the switching part ( 2 ) made of plastic. In the latching curve (2 A) of the guide pin (7 A) of the detent lever is to detect (7) which is guided in the detent curve (2 A). Since the locking lever ( 7 ) is pivotally mounted in the housing ( 1 ), the guide pin ( 7 A) can not only be moved linearly along the travel path relative to the switching part ( 2 ) / locking curve ( 2 A), but also perpendicular to the travel path. In addition, the guide pin ( 7 A) can be pivoted elastically out of the plane of the drawing, which enables the traversing of a height profile along the locking cam track.

When the push button ( 5 ) is actuated, the guide pin ( 7 A) is guided into the locking cam path starting from an initial position - just below the heart-shaped locking curve ( 2 A). The guide pin ( 7 A) is guided in the illustrated embodiment on the right around the heart-shaped center of the locking curve ( 2 A) counterclockwise. The other direction is blocked by a step (S6) as a deflecting surface in the detent curve (2 A). On its way from the starting position (A) to the position (P1), the guide pin ( 7 A) passes a first step (S1) which converts the locking cam track into an inclined plane. When the guide pin ( 7 A) in the locking curve ( 2 A) has reached position (P1), the contact pill ( 6 B) presses on the circuit board ( 8 ). The corresponding stroke range which the switching part ( 2 ) has covered up to here against the spring force of the switching mat ( 6 ) is referred to as the switching stroke range (h). The spring constant of the switch mat ( 6 ) arranged on the printed circuit board ( 8 ) is smaller in this stroke range than in the adjoining stroke range, the switch mat ( 6 ) being elastically deformed in this switch stroke range so that the contact pill ( 6 B) in Direction on the circuit board ( 8 ) is moved.

Once the contact pellet (6 B) presses against the circuit board (8) (see FIG. Position (P1) in the detent curve) is followed by a overstroke in which the guide pin (7 A) is brought of the detent lever (7) in its locking position. In this overstroke range, there is only an elastic deformation of the switch mat ( 6 ) without a displacement of the contact pill ( 6 B). The spring constant of the switching mat ( 6 ) in this overtravel area is greater than in the switching stroke area. This ensures that the initial deformation always causes a shift of the contact pill ( 6 B) in the direction of the circuit board ( 8 ).

On its way within the overstroke range from the contact position (P1) to a reversing position (P3), the guide pin passes another steep step (S2) as a deflecting surface, which prevents the guide pin ( 7 A) from being released after the push button ( 5 ) is released the reverse position (P2) can reach the starting position (A). Instead, the guide pin ( 7 A) moves after releasing the push button due to the spring force of the switching mat ( 6 ) into the locking position (P3), where the guide pin ( 7 A) is held in a trough of the heart-shaped center of the locking curve ( 2 A). When step (S2) is exceeded, the guide pin ( 7 A) jumps in the height profile of the locking curve ( 2 A) and generates a switching sound which signals to the operator that the locking position is ensured after the pressure switch ( 5 ) is released. When walking from the reverse position (P2) to the locking position (P3), the guide pin ( 7 A) passes another step (S3), which serves as a deflecting surface when the push button ( 5 ) is pressed again.

To unlock the button ( 5 ) is pressed again. This causes the guide pin ( 7 A) to move from the locking position (P3) to a further reversing position (P4). Hiking from the locking position (P3) in the reverse position (P4) of the guide pin (7 A) passes through a further step (S4) as a deflecting surface, which is a migrating back of the guide pin (7 A) while releasing the push-button (S) to the latching position ( P3) should prevent. Instead, the guide pin ( 7 A) moves back to its starting position (A) after releasing the push button ( 5 ).

The force-displacement curve of the safety mat ( 6 ) shows a steep rise in the reversal points (P2, P4), so that further deformation is hardly possible and the operator perceives an end position that prompts him to release the push button ( 5 ) ,

FIGS. 7 and 8 show the switching mat (6) in the region of the contact pellet (6 B) in detail. Here, FIG. 7 shows the switching mat (6) in the output switching position (cf. FIG. Point A in the detent curve), that is at the beginning of Schalthubbereiches where the contact pellet (6 B) spaced apart from the printed circuit board (8). Fig. 8 shows the switch mat ( 6 ) at the end of the switching stroke area (see point P2 in the locking curve), where the contact pill ( 6 B) already presses on the conductor track ( 8 ).

The switching mat ( 6 ) is specially designed to effect the switching stroke and the overstroke in the relevant area around the contact pill ( 2 B). The description refers to the relaxed starting switch position of the safety mat. This has a circumferential contact surface ( 6 C) with which it rests on the printed circuit board ( 8 ). A circumferential, cylindrical wall ( 6 D) extends in one piece from the support surface ( 6 C) and is closed off by an integrally molded base ( 6 E). A cylindrical block ( 6 F) carrying the contact pill ( 6 B) is integrally formed in the center of the base ( 6 E). A switching dome ( 6 A) is integrally formed as a hollow cylinder on the side of the base ( 6 E) facing away from the contact pill ( 6 B). The switch mat is made of a rubber-elastic material, e.g. B. silicone rubber.

The plunger ( 2 B) of the switching part ( 2 ) presses against the end face of the hollow cylindrical switching dome ( 6 A). The plunger ( 2 B) is also designed as a hollow cylinder on which a hollow cylindrical guide sleeve ( 2 C) with a smaller diameter is integrally formed, which engages in the switching dome ( 6 A) for fixing the plunger ( 2 B). In the overstroke area, the cylindrical block ( 6 F), which carries the contact pill ( 6 B), can then advantageously be immersed in the hollow cylindrical guide sleeve ( 2 C).

During the switching stroke, the wall ( 6 D) of the switching mat ( 6 ) and the base ( 6 E) are arched inwards, the force-displacement curve being essentially constant and linear in this area. At the end of the switching stroke area, when the contact pill ( 6 B) presses on the printed circuit board ( 8 ), two curved chambers have formed on average, which form a circumferential arch over the printed circuit board ( 8 ). In the event of a further elastic deformation of the switch mat ( 6 ) in the overstroke area, this arch must be pressed in. This deformation then corresponds to a larger spring constant than in the switching stroke area.

The spring constants can be set, for example, via the wall thicknesses in the area of the wall ( 6 D) and the bottom ( 6 E).

LIST OF REFERENCE NUMBERS

1

casing

2

switching part

2

A Heart-shaped locking curve on the switching part

2

B Tappet on the switching part

2

C Hollow cylindrical guide sleeve on the ram

3

Push buttons for push button switches without rest position

4

Tappet for pushbutton switches without rest position

5

Pushbutton for pushbutton switches with rest position

6

Safety mat

6

A switch dome

6

B contact pill

6

C contact surface

6

D All-round cylindrical wall

6

E floor

6

F Cylindrical block with contact pill

7

locking lever

7

A Guide pin of the locking lever

8th

circuit board
A starting position
P1 contact position
P2 reverse position
P3 rest position
P4 reverse position
h switching stroke

Claims (1)

1. Push button switch with latching position consisting of
a housing (1), in which a a heart-shaped latching curve (2 A) exhibiting switching part (2) is arranged, which is displaceable by pressing a push button (5) against a spring force,
a housing side mounted, pivotable detent lever (7) which is passed during a displacement of the switching part (2) in the latching curve (2 A),
a printed circuit board ( 8 ) against which at least one movable contact element ( 6 B) is pressed due to the displacement of the switching part ( 2 ) to effect an electrical switching contact, wherein
the switching part ( 2 )

• a) upon actuation of the push button (press and then release) from an initial switching position in which the contact element ( 6 B) is spaced from the circuit board ( 8 ), in a latching position in which the contact element ( 6 B) against the PCB ( 8 ) presses, can be moved,
• b) can be moved from the rest position into the starting position when the pushbutton ( 5 ) is pressed again, wherein

the push button switch ( 5 ) has a spring-elastic switching mat ( 6 ) arranged on the circuit board ( 8 ) for effecting the spring force, the switching mat ( 6 ) having a switching dome ( 6 A) acted upon by the switching part ( 2 ) and one facing the conductor track ( 8 ) Has contact pill ( 6 B) as a contact element,
the switching mat ( 6 ) has a switching stroke area (h) with a first spring constant, in which the contact pill ( 6 B) is pressed against the printed circuit board ( 8 ) before reaching the locking position,
the switching mat (6) has an overstroke having a second spring constant, in which the switching mat (6) (6 B) elastically deformed in already oppressive against the circuit board (8) contact pill, wherein the detent lever (7) within the Überhubbereiches its locking position in the locking curve ( 2 A)
the spring constant in the overstroke range is greater than the spring constant in the switching stroke range,
the switching part ( 2 ) has a plunger ( 2 B) which presses against the end face of a hollow cylindrical switching dome ( 6 A),
characterized in that
the plunger ( 2 B) is designed as a cylinder, on the end of which a hollow cylindrical guide sleeve ( 2 C) with a smaller diameter is molded, the guide sleeve ( 2 C) for fixing the plunger ( 2 B) in the switching dome ( 6 A) intervenes.