DE2916279C2 - - Google Patents

Description

The invention relates to an electrical snap switch, consisting of a jump provided with a contact carrier member, a push pin to actuate the jump member a movement from an unactuated to an actuated End position, a holding device that the jump member in holds its unactuated end position, and from one the spring acting spring.

Such electrical Jump switches are already known (DE-OS 19 11 104); there is this Jump member within a recess of the pressure pin longitudinally guided in its direction of displacement, being as a holding device device for the jumping link in the unactuated end position in addition to a magnet, and supported on the housing on the pressure pin, the magnetic force in the same direction Tete return spring is provided. The return spring restoring force acting on the pressure pin is determined by a additional spring supported on the pressure pin on the jump member transferred. Relaxed when the pressure pin is actuated gradually the the jump link in the same direction like the additional spring moving the magnetic force, while a attacking on the opposite side of the phalanx  second additional spring is biased until finally the pressure pin when it contacts the spring element of the magnet solves. This is before during the push pin movement tensioned second additional spring effective to make the jump to release the member with bounce from the magnet. Disadvantageous is in this known relatively complex construction form that the operating force for the switch on the Path length of the pressure pin increases because of that for the jump the spring of the spring link must first be tensioned got to. To achieve the required clamping force, is a comparatively large actuation path absolutely necessary Lich. Another disadvantage is that the jump of the Spring causing spring element at all times Force of the return spring works in the opposite direction and can only be effective to a limited extent.

A snap switch is also already known, in which the contact carrier should be opened as quickly as possible and thus the smallest possible contact erosion should be ensured by a sudden movement of the contact carrier (DE-PS 24 45 957). There two contact bridges are provided, one of which is assigned a break contact and the other a break contact. In order to achieve the jumping behavior of the contact bridges, at least one slide is provided, which is provided with a holding device and with a spring arrangement. When the pressure bolt is actuated, two return springs arranged next to each other in the switch housing and in addition the springs for the sudden slide movement must be tensioned. These springs must be tensioned even further after the shift jump to ensure the opposite shift jump even when moving back.

The invention has for its object an electrical Snap switch of the type specified at the beginning as a break contact and / or make NO so that the switching process with a high switching reliability already after an extremely short actuation stroke and preferably less Actuating force is triggered. This object is achieved according to the invention solved in that the pressure pin and the snap link by the on the pressure pin side supported on the switch housing together in Are biased towards the actuated end position, and that the holding device in a manner known per se in Relationship to the jump member is arranged so that their stroke-dependent holding force in the non-actuated end position of the jump member near a maximum value located.

This is advantageous the demand for as little actuation as possible power fulfilled because already in the not actuated end position of the pressure pin and the jump link by the spring supported on the switch housing too far in the direction of the actuated end position can be excited, so that from the outset possibly a large proportion of the force of the holding device is no longer effective. The size of the from the holding device force available with which the jump member in the is not actuated end position can be used moderate from the necessary vibration resistance of the jump determine switch. Even with high vibration resistance a very small, barely noticeable switch actuation Stroke necessary. This is in contrast to that of the Known switches necessary advance path for tensioning  of the different feathers. This will be a surprise short stroke possible, which may be shorter than at So-called microswitches can be where to initiate the Shifting a few millimeters stroke are necessary. In the design described here, the needs to Pushbutton therefore only exerted actuation impulse the holding force of the holding device on the way to so-called jump point to be overcome, whereupon the pressure pin with the jump member carrying the contacts alone in the actuated end position arrives. Are expedient Push pin and spring link firmly connected.

In a preferred embodiment, are as retainers direction a fixed in the switch housing Magnet and one associated with the magnet, with the jump link related anchor plate or vice versa intended. In a further embodiment of the described The snap switch can be arranged in the switch housing Magnet from an open one towards the anchor plate pot-shaped shielding casing that likes the netic lines of force. Because of the lines of force Bundling can be done on the one hand the holding force and size of the magnet more precisely and to the desired one Lay out the smallest value. On the other hand, it results in a magnet size that was just sufficiently chosen sought-after keeping the actuation stroke small until it triggers the jump switch to a few tenths of a millimeter.  

The open end face of the shield housing can be the armature plate adjacent side surfaces of the magnet project for the purpose of gap formation. While with the Force line bundling in the shielding housing the holding force of the magnet and its size more precisely determined and fixed can be placed in the area of the bundled Force line arranged gap between anchor plate and mag net that on Manufacturing tolerances due to variations in the Release force remain low and thus a more precise shift force adjustment is made possible.  

If in a further embodiment of the jump switch described the spring from at least one with both Ends fixed in the switch housing and between their Leaf spring acting on the ends of the spring link, those in the non-actuated end position of the jump member takes a state in which she jumps in Biased towards the actuated end position size and dimensions of the magnet advantageous keep low. In another embodiment, can the spring from at least one Leaf spring exist, one end of which is on the housing and the other end of it on the jump link supports the jump in the non-actuated end position link in the direction of the actuated end position. If the spring is designed as a leaf spring, it is conveniently located in the not actuated end position of the jump member near its unstable Dead center position.

The feather can advantageously also as a coil spring be trained in the unactuated End position is most excited.

According to a second basic embodiment of the snap switch described the holding device consists of at least instead of a magnet a sheet clamped or supported at the ends in the switch housing feather that jumps between their ends like that limb connected that they are not in use End position close to and towards the unstable dead center biased. In this part can be selected by selecting a suitable spring Characteristic the intended effect of the smallest possible Achieve actuation force, which is why the characteristic curve in particular to the one causing the jumping behavior of the jumping link Spring is tuned.  

The holding device expediently consists of at least a leaf spring, the one end is on the housing and the other end is on Lunger supports and which is in non-actuated end location of the jump member near and towards the biased dead center. In their means position between the actuated and unactuated end positions the leaf spring only as a shear force on the jump limb while the spring force in the longitudinal direction of the jump link from the middle position to one or the other Direction increases. This in the longitudinal direction of the jump member force-neutral middle dead center area of the leaf spring exploited for the short switching path sought.

Hereinafter are embodiments of the invention with reference to the drawings explained in more detail. It shows

Fig. 1 shows a schematic section through a snap-action switch of the type described,

Fig. 2 in the same representation, a variant of the switch of FIG. 1, and

Fig. 3 is a stop and switch operations of the jump switch explanatory force / displacement diagram.

According to Fig. 1 is axially displaceably in a switch housing 10 an elongated jump member 12 in not shown guides. The jump member 12 includes a recess 14 in which a contact bridge 16 with a guide pin 18 and symmetrically arranged contacts is provided.

In the non-actuated end position of the jump member 12 shown , the contact bridge 16 is biased by means of a spring 22 against contacts 26 attached to the housing 10 on a switch 24 . The spring 22 is supported with its end facing away from the contact bridge on the wall of the recess 14 .

Two with their outer ends on the housing 10 fixed (z. B. each stored in a notch) leaf springs 28 grasp with their inner ends in a tapered section or a circumferential groove 30 of the spring link. The leaf springs 28 are biased in the not shown end position of the spring element 12 in the direction of an end position in FIG. 1 to the left of the position shown. The switching stroke of the jump member 12 extends from a not shown, in Fig. 1 further left actuated end position, in which the springs 28 are tensioned, to the drawn, unactuated end position, in which the springs have been gradually tensioned from the initially relaxed state are, but have not yet reached their unstable dead center position.

The jump member 12 carries a magnetically conductive anchor plate 32 which is fixed on a bolt 34 inserted. The bolt 34 extends through a central opening of a fixed in a front side of the housing 10 permanent magnet 36th This permanent magnet is surrounded by a cup-shaped shield 38 that the anchor plate 32 is open. The shielding housing 38, which is made of particularly magnetically conductive material, bundles the magnetic lines of force, so that these pass essentially only in the area of the annular contact surface on the anchor plate, so as to close the magnetic circuit.

Between the body of the permanent magnet 36 and the armature plate, a gap 40 is provided, which reduces the dispersion of the adhesive force and thus enables a uniform switching force.

If the snap switch, for example as a safety switch, is actuated by a moving stop (not shown) or the like, by touching the bolt 34 , which can be fastened in a sealed manner by an elastic hood 42 to the housing, the anchor plate 32 moves away From the end of the screen housing 38 , so that after a few tenths of a millimeter stroke the magnetic holding force has been overcome so far that the force of the leaf spring 28 overcomes the remaining magnetic holding force on its own and now the spring element 12 is immediately transferred to its actuated position. In this Schaltvor gear relaxes the spring 22 , which normally biases the contact bridge 16 against the stationary contacts 26 . The side face of the recess 14 which is opposite the contact bridge 16 at a short distance now moves or presses the contact bridge 16 away from the contacts 26 , so that the previously closed circuit is broken.

In the embodiment according to FIG. 2, instead of a leaf spring 28, a helical spring 50 is provided, which is clamped between the fixed housing 10 and a support plate 52 fixed on the snap member 12 .

In addition, two contact bridges 16, 17 fixed contacts 26 and 26 are arranged in the housing opposite in the recess 14 of the switching pin, so that a circuit is opened and the other closed when the switch is actuated.

Accordingly, Fig. 3 is the zero point of the force / displacement chart image in the unactuated end position of the jump member (switching path = 0). At this point, the maximum holding force acting on the jump member of the magnet corresponding to the curve 36 a and in the vicinity of the unstable dead center T small drive force of the leaf spring (s) toward the actuated end position accordingly the curve 28 a. The broken dotted ge drawn curve shows the reflection of 36 a on the abscissa and allows a better illustration of the holding force of the magnet available for the vibration resistance of the switch corresponding to the distance R.

Claims (11)

1.Electrical snap switch, consisting of a snap member provided with a contact carrier, a pressure bolt for actuating the snap member to move from a non-actuate, into an actuated end position, a holding device which holds the jump member in its non-actuated end position, and from one spring acting on the snap link, characterized in that the pressure pin ( 34 ) and the snap link ( 12 ) are jointly biased towards the actuated end position by the spring ( 28, 50 ) supported on the pressure pin side on the switch housing ( 10 ), and in that the holding device (z. B. 36 ) is arranged in a manner known per se in relation to the jump member ( 12 ) so that its stroke-dependent holding force is in the non-actuated end position of the jump member ( 12 ) near a maximum value. 2. Electrical snap switch according to claim 1, characterized in that the pressure pin ( 34 ) and the snap member ( 12 ) are firmly connected. 3. Electrical snap switch according to claim 1 or 2, characterized in that the spring consists of at least one with both ends in the switch housing ( 10 ) and between its ends on the snap member ( 12 ) engaging leaf spring, which in the non-actuated end position of the snap member Condition takes one, in which it prestresses the jump member ( 12 ) towards its actuated end position. 4. Electrical snap switch according to claim 1 or 2, characterized in that the spring ( 28 ) consists of at least one leaf spring, one end of which is supported on the housing ( 10 ) and the other end of which is supported on the snap member ( 12 ) and which in the unactuated end position of the jump member assumes a state in which it prestresses the jump member in the direction of its actuated end position. 5. Electrical snap switch according to claim 1 or 2, characterized in that the spring ( 50 ) is a coil spring which is in the non-actuated end position is most excited. 6. Electrical snap switch according to claim 3, characterized in that the leaf spring in the non-actuated end position of the snap member ( 12 ) is in the vicinity of their unstable dead center position. 7. Electrical snap switch according to one of claims 1 to 6, characterized in that as a holding device in the switch housing ( 10 ) fixed magnet ( 36 ) and a magnet associated with the snap element ( 12 ) in connection with the anchor plate ( 32 ) or reversed are provided. 8. Electrical snap switch according to claim 7, characterized in that the arranged in the switch housing ( 10 ) magnet ( 36 ) is surrounded by an in the direction of the anchor plate ( 32 ) open cup-shaped shielding housing ( 38 ) which bundles the magnetic lines of force. 9. Electrical switch according to claim 8, characterized in that the open end of the shielding housing ( 38 ) on the armature plate ( 32 ) adjacent side surface of the magnet ( 36 ) for the purpose of gap formation. 10. Electrical snap switch according to one of claims 1 to 6, characterized in that the holding device consists of at least one at the ends in the switch housing ( 10 ) is clamped or mounted leaf spring, which is connected between its ends in such a way with the snap element ( 12 ) that it is in its unactuated end position near and biased towards the unstable dead center. 11. Electrical snap switch according to one of claims 1 to 6, characterized in that the holding device consists of at least one leaf spring, one end of which is supported on the switch housing ( 10 ) and the other end of which is supported on the snap member ( 12 ) and which is not in be active end position of the jump member is close to and biased towards the unstable dead center.