DE1092095B - Switching mechanism for toggle switch - Google Patents

Description

GERMAN

The subject of the main patent application is an electrical toggle switch with Pressure contact, in which the reaction force of the toggle spring, which is used in particular to generate the contact pressure, in the end positions exceeds the contact pressure via a pressure acting on the moving contact Increased deflection device. This switch is a one on a rotatable lever movable switching contact leading lever articulated, so that the reaction force deflected by the switching lever the toggle spring on approaches of the shift lever with a power-boosting translation affects the contact.

The switch according to the main patent application achieves the contact pressure increase by means of leverage, which inevitably takes up a relatively large amount of space. For the normal toggle switches, how they are applied in almost all fields of electrical engineering is therefore the device not usable after the main patent application, because there is generally only one for this switch relatively little space available. On the other hand, these switches are subject to high demands made with respect to the switching capacity, so that there is a need for a device that although the Increased contact pressure, but not significantly increased the size of the switch.

In addition to the switch according to the main patent application, there are already other toggle switches with pressure contacts known, in which the reaction force of the toggle spring is used to increase the contact pressure will. However, these known switches are due to their structural design for the mentioned Purpose not fully suitable, because firstly they only provide a relatively small increase in contact pressure and also require a considerable amount of space to accommodate the deflection device. So is for example in the case of switches with a compression spring member actuated by a rocker arm, one supported on the rocker arm Contact pressure spring is provided, which acts on the contact carrier via the rocker arm with its reaction force acts back. The lever ratios are so unfavorable with this switch that the contact pressure increases is hardly noticeable. In one of these switches is also provided as a result of the resilient Contact carrier flanks a relaxation of the contact compression spring and thus a further reduction contact pressure possible. In another switch, the toggle spring engages two levers, the on the one hand are pivotally mounted on a common rotary lever and on the other hand by the spring against a lens-shaped, pivotable contact carrier provided with a contact lever can be pressed. In this switch, although the reaction force is switching mechanism for toggle switches

Addition to patent application L 22218 VIIIb / 21 c
(Exhibition guide 1 087 213)

Applicant:

LICENTIA Patent-Verwaltungs-GmbH _r Frankfurt / M., Theodor-Stern-Kai 1

Helmut Brand, Hamelin,
has been named as the inventor

the toggle spring is also used for the contact pressure, but the contact lever is in its end positions blocked by stops, so that a substantial part of the spring force is lost here.

It is the object of the invention, the principle of the contact pressure increase according to the main patent application can also be used for ordinary small toggle switches. This becomes according to the invention achieved that the end of the switching lever directly or via deflection elements so on the contact guide lever acts that the toggle spring reaction force transmitted to the lever meets at an acute angle on the respective transfer surface, so that the thereby generated wedge effect amplifies the toggle spring reaction force in the sense of an increase in contact pressure.

The drawing shows three application examples of the invention on known toggle switch mechanisms., where in the

Fig. 1 and 2 toggle switches with roller contact bridge and in the

Fig. 3 shows a toggle switch with terminal contact bridge.

In the embodiment of FIG. 1, 1 denotes a part of the switch housing, in which Interior on a curved track 2 two fixed contacts 3 are arranged. With the permanent contacts a contact roller 7 interacts, which can be pivoted about an axis 12 via a toggle spring 8 Shift lever 10 is in connection. The toggle spring is on a telescopic, not shown Attached intermediate member and is supported on the one hand on the end 9 of the shift lever and on the other hand on a Axis 6 of the contact roller. The increase in contact pressure is brought about by a contact guide lever 5 which can be pivoted about a fixed axis 4. The shift lever is in one with a pin 11

009 630/310

Slit 14 of the lever 5 is mounted displaceably, and the lever 5 acts with lugs 16, 16 'on the axis of the contact roller. In the position shown, the lug 16 of the lever presses against the axis 6 of the contact roller 7 and presses it against the fixed contacts 3. The increase in contact pressure is brought about by the inclined surface 13 on which the pin 11 of the shift lever rests. The reaction force of the toggle spring causes the pin 11 to shift on the inclined surface 13 when it is switched on, ie the pin moves on a wedge surface that forms a very acute angle with the tangent to the circular path of the pin determined by the lever movement . The balance of forces can be seen from the drawn arrows of forces. The contact roller is first pressed against the fixed contacts with a force F. This force comes from the toggle spring and acts in its longitudinal direction. The equally large toggle spring reaction force R acts in the opposite direction on the pin 11. The pin 11 acts in the direction of the tangent of its movement path on the inclined surface of the lever 5, that is, the pin exerts a force P on the inclined surface, the magnitude of which is determined by the triangle of forces to

P = R-cos β

where β is the angle between the directions of P and R. According to the laws of mechanics, the force G perpendicular to P is related to P.

30th

tg (α + ρ)

The angle α results from the direction of the force G to the perpendicular to the inclined surface 13. The friction angle ρ is a material constant. The force G _{1, which} is decisive for the increase in contact pressure, acts in the direction of the vertical on the inclined surface and results from the triangle of forces

G ₁ = G * cos α

If the values for G and P are inserted into the formula for G ₁ , one obtains

_ R * cos β * cos α
tg (α + ρ)

45

Since the point _{of application of the force G 1 is} about the same distance from the pivot point of the lever 5 as the point of application of the Heliel 5 on the roller _{contact, the force G 1} also acts on the contact and combines with the force F to form a resulting force that determines the contact pressure . In order to be able to show the relationships particularly clearly, the angles α and β are chosen to be relatively large. A more favorable increase in contact pressure naturally results when the wedge angle is smaller. For example, the force G _{1 is} calculated on the assumption that the friction angle ρ is 6 °, the angle β = 10 ° and the angle α = 5 °, to a value 5 times the spring force F. The switch is switched off by pivoting of the switching lever 10. The pin 11 takes the auxiliary lever 5 with it during this pivoting movement and pivots it about its axis 4 into the position shown in dash-dotted lines. The contact is opened after the toggle lever system, which consists of the switching lever and the toggle spring, has been pushed through the dead center position. The approach 16 'ensures a compulsory separation of contacts if the contact role should not itself pass into the exhibition for any reason. In the embodiment of FIG. 2, a toggle switch is shown which has essentially the same basic construction as the switch of FIG. Corresponding parts are therefore provided with the same reference symbols. In this embodiment, the lever 5 is provided with a triangular recess 14 into which the pin 11 engages. The axis of the contact roller is mounted in a slot in the auxiliary lever. The switch is shown in the closed state. In the switched-on position shown, the toggle spring 8 exerts a force on the end 9 of the shift lever arm 10 so that it would pivot about its axis 12 if its pin 11 were not in contact with one of the inclined surfaces 13 of the triangular recess 14. The shift lever is therefore limited in movement by this contact surface. The toggle spring reaction force is transmitted to the inclined surface 13 via the pin 11, the direction of the force being at an acute angle to the support surface. A wedge effect is created so that the force exerted on the auxiliary lever in the pivoting direction is greater than the toggle spring reaction force. With this arrangement, force diagrams similar to those in the exemplary embodiment according to FIG. 1 can be set up. The switch is switched off by actuating the switch lever, which pivots into the position shown in dash-dotted lines. The shift lever can be pivoted beyond the dead center position without touching one of the inner surfaces of the auxiliary lever with the pin 11. This free path is chosen to be so large that the force component of the toggle spring is able to initiate the change in position of the contact bridge into the dot-dash position. Do mechanical obstacles such as B. contact welds and the like., The switching process, the auxiliary lever is inevitably taken along by the pin 11 of the switching lever in the course of its pivoting movement. The obstacles are overcome and the switching process is ended by the toggle spring.

Fig. 3 shows a further example of construction, which is particularly suitable for such switches, at where a contact bridge is clamped between two resilient contacts in the switch-on position will.

The switching lever 10 and the lever 5 carrying a contact bridge correspond to a known switch design. The function is essentially similar to the function of the mechanisms according to FIGS. 1 and 2. Here, however, the toggle spring reaction force is applied to the contact lever with the aid of reversing levers 18 and 18 ' transmitted, the power transmission from the shift lever 10 to the inclined surface 19 again of the pivotable about the axis 20 transmission lever 18 is increased by the wedge effect. In the The position shown in dashed lines is the shift lever 10 on the inclined surface 19 'of the second transmission lever 18 'and swivels it around its fixed bearing 20' so that the other lever arm of lever 18 ' strikes against the contact carrier 17 and this forcibly out of the switching position shown in the other switch position breaks. The gear ratios of the levers can vary according to the Purposes.

Claims (10)

Patent claims: 1. Electrical toggle switch with pressure contact, in which a toggle spring and the movable switch contact leading lever with is hinged at one end to a shift lever rotatable about a fixed shaft so that the through the shift lever deflected reaction force of the toggle spring via lugs on the shift lever with a force-amplifying translation increases the contact pressure exerted on the contact, according to patent application L 22218 VIIIb / 21c, characterized in that that the end of the switching lever (10) directly or via deflection elements so on the contact guide lever (5) acts that the toggle spring reaction force transmitted to the lever (5) in a sharp Angle impinges on the respective transfer surface, so that the wedge effect generated thereby Toggle spring reaction force increased in the sense of an increase in contact pressure. 2. Toggle switch according to claim 1, characterized in that the lugs (11) of the shift lever (10) are guided in a slot (14) of the approximately centrally mounted contact guide lever (5) and that at the widened other end of the lever (5) two lugs (16 and 16 ') are arranged which in the switching end positions act on the contact bridge or roller (7) in the sense of an increase in contact pressure, while they are above the dead center position pivoted switching lever bring about a forced contact opening (Fig. 1). 3. Toggle switch according to claim 1, characterized in that the approximately centrally mounted contact lever (5) at its one free end carries a roller contact (7), while its other free end is widened and an approximately triangular cutout (14) with stops for the forcibly has contact opening into which a projection or a pin (11) of the switching lever (10) engages (Fig. 2). 4. Toggle switch according to claim 1 and 3, characterized in that the sides of the approximately isosceles Triangular section (14) in the Konr clock lever (5) are inclined so that the approach (11) of the shift lever (10) transmitted toggle spring reaction force in the shift end positions in their direction of force impinges at an acute angle on the corresponding transfer surface and through Wedge effect exerts an increased force component in the pivoting direction of the contact lever (5) (Fig. 2). 5. Toggle switch according to claim 1, 3 and 4, characterized in that the base angle of the Triangle (14) are rounded so that the pin (11) of the switching lever (10) one of its shape in the event of a forced contact separation adapted stop surface finds (Fig. 2). 6. Toggle switch according to claim 1 and 3 to 5, characterized in that the movable contact (7) is mounted in slots of the two-part contact lever (5) so that the toggle spring (8) acts simultaneously as a contact spring in a manner known per se (Fig. 2). 7. Toggle switch according to claim 1, characterized in that a known contact lever (5) Way, approximately one-sided mounted, pear-shaped lever is provided, which is of two curved, fixed transmission levers (18 and 18 ') is enclosed by which in each case one of the toggle spring reaction force on the shift lever end (10) by means of inclined surfaces (19) with wedge effect on the contact lever (5) transmits, while the other lever at over Dead center pivoted shift lever (10) the reaction forces and the actuation forces in the The sense of a compulsory contact separation transmits (Fig. 3). 8. Toggle switch according to claim 1 and 7, characterized in that the switching lever (10), the Contact lever (5) and the two reversing levers (18 and 18 ') are mounted on fixed points (12, 4, 20, 20') are, these parts are only in positive connection with each other (Fig. 3). 9. Toggle switch according to claim 1, 7 and 8, characterized in that the fixed bearing points (12, 20, 20 ') of the shift lever and the two reversing levers are the corner points of an approximately isosceles Form a triangle and the fixed bearing point (4) of the auxiliary lever approximately in the center of this triangle, is arranged. 10. Toggle switch according to claim 1, 7 and 9, characterized in that in the switching end positions the rounded end of the switching lever (10) on a beveled end face (19) one of the two reversing levers (18 and 18 ') acts to produce the wedge effect (Fig. 3). Considered publications:
German Patent Nos. 420765, 491 798;
British Patent No. 660,338. Legacy Patents Considered:
German Patent No. 1 001 741. 1 sheet of drawings © 009 630/310 10.60