DE1665193B1 - Electric snap switch for pressure actuation - Google Patents

Description

The invention relates to an electrical snap-action switch for pressure actuation with a control lever, one end of which can be pivoted about a fixed pivot point and the one about a snap spring with one roughly parallel to and below it arranged, pivotably mounted in an opposing, stationary pivot point, snap-on contact arm is clamped, which has two contact pieces at its free end one with a fixed contact and the other with a Opening fixed contact can be brought into contact, and the free end of the Return spring acting on the control lever.

In the known snap switches of this type, the strength of the snap spring is determining the level of the contact pressure. To ensure one with a high Contact pressure to be equated, high performance must therefore with these switches a relatively strong snap spring is used in such constructions has its opposite pole in the return spring, which is then equally strong is to be interpreted like the snap spring. Since now the restoring force of this return spring goes directly into the information required to operate such a snap switch Force required - when the pressure is actuated, the force of the return spring is immediate to overcome - is the provision of a high contact pressure in these known Snap switches equate with the requirement of a high expenditure of force to Pressing the pressure member. Relevant for this is the fact that with the known Snap switches the pivot points for the control lever and the snap-on contact arm in connection with the points of application of the snap spring are placed on these in such a way that that snap spring and return spring are the same up to the time of the snap action Take effect, but the snap action is accompanied by a reversal of direction the line of action of the snap spring, so that the snap spring after the snap action has taken place and return spring act in different directions. The powers of the two Springs are therefore not constantly in balance over a full switching cycle, and the return spring only takes on the function of one in these known switches automatic return of the contact arm to its starting position.

The relationships discussed above for electrical snap-action switches of the type mentioned at the beginning are also present in a German utility model 1899 866 known snap switch, with its development the present Invention essentially on the basis of the object is concerned with an electrical To provide snap switches for pressure actuation of this type available on the one hand the provision of high contact pressure to ensure high performance allowed and the other hand while maintaining the smallest dimensions with minimal Force can be actuated. With the snap switch according to this utility model are the fixed pivot points for the control lever and for the contact arm on the provided on the same side, and the return spring and the snap spring are up at the time of the snap action upwards, i.e. in the same direction Compression springs, the spring constants of which are thus reciprocal until the snap action add, on the other hand subtract each other after the snap action has taken place, because then the snap spring acts in a different direction than the return spring.

The above-noted object is according to the invention in a electrical snap-action switch for pressure actuation of the type mentioned the union of the following features, some of which are known per se, solved: a) the Fixed pivot point of the control lever is when one contact piece is touched with the Schheß fixed contact above the connecting line of the stationary pivot point of the contact arm with the point of application of the snap spring on the contact arm; b) the Return spring loads the free end of the control lever from below; c) the pressure member comes with the free end of the control lever from above for immediate application; d) the return spring is an upwardly acting compression or tension spring, and the Snap spring is a downward acting tension spring, and e) the one on the control lever acting tensile force of the snap spring is constantly acting in the opposite direction to the compressive or tensile force of the return spring and is smaller than this.

With these measures, for the entirety of the invention, its patent protection desired, one achieves independence of the pressure actuation of the switch The force to be applied depends on the level of the contact pressure determined by the snap spring, which is decisive for the performance of such a switch. Even if this contact pressure is chosen to be very high by appropriate design of the snap spring only a minimal actuation force is required to press the switch required because both springs are constantly in different positions for a full switching cycle Directions act and their spring constants are constantly in balance.

In accordance with further partial features of the invention one can the level of this operating force can easily be changed by choosing the fixed one The pivot point of the control lever can be arranged in different ways Provides high altitudes or that one trains the return spring adjustable. on the other hand can- a possibility of changing the displacement path of the pressure member thereby are provided that different fixing options for the snap spring be provided on the control lever.

The snap switch according to the invention is below using a In the drawing illustrated embodiment explained in more detail. It shows F i g. 1 the snap switch in a longitudinal section, F i g. 2 the snap switch in Top view along line II-11 of FIG. 1, Fig. 3 a schematic representation in reduced scale to illustrate the different pivot positions of the control lever and contact arm for one switching cycle, FIG. 4 a further schematic illustration for Illustration of the distribution of forces and F i g. 5 a diagram to explain the moments of force that act on the control lever.

In the F i g. 1 and 2, 1 denotes the pressure member of the snap-action switch which is displaceable in an opening 3 of the housing 2 and which, by means of an insulating piece test, comes from above with the free end of a control lever 4 for direct application. The housing 2 has a removable cover 2 'and is lined with an insulator 2 ″ on its upper inner wall forms this control lever 4. The insulating body 5 has further notches 52 'and 53' at different heights, which can be used to support the control lever 4 in order to increase the actuating force to be exerted via the pressure member 1.

At the free end of the control lever 4 engages an upwardly acting compression spring 6, which acts as a return spring of the switch. This return spring 6 is supported on an adjusting screw 8 which is screwed into a threaded hole 7 of the insulating body 5 and which has a slot 8 'for inserting a screwdriver when the housing cover 2' is removed. By screwing in or unscrewing the adjusting screw 8, the biasing force of the return spring 6 fixed by means of a projection 4 ″ on the control lever 4 can be changed; an increase in this biasing force by screwing in the adjusting screw 8 results in an increase in the force to be exerted on the pressure member 1 to operate the switch In addition to the approach 4 ″ at the free end of the control lever 4 there is a somewhat longer extension 9, which is provided with openings 91 ', 92 and 93' for hanging one end of a snap spring 10, the other end of which into an opening 11 ' Contact arm 11 is hooked. The snap spring 10 is a downwardly acting tension spring whose tensile force acting on the control lever 4 constantly acts in a direction opposite to the compressive force of the return spring 6 and is smaller than this. Relevant for this is the fact that the contact arm 11 has a stationary pivot point opposite the stationary pivot point .des control lever 4, which is formed by a notch 12 'in the upright web of a body 12 fixed to the housing for receiving the knife-shaped end 11 "of the contact arm 11. In relation to this stationary pivot point of the contact arm 11 equipped with two contact pieces 13 at its free end, the stationary pivot point of the control lever 4 lies above the connecting line of the stationary pivot point of the contact arm with the point of application 11 'when the one contact piece 13 comes into contact with a fixed contact 16. the snap spring 10 on the contact arm. The terminal for the closing fixed contact 14 is denoted by 14 ″ and the opening fixed contact cooperating with the other contact piece of the contact arm 11 is denoted by 15. Finally, 15 "denotes the connection terminal for this opening fixed contact, and 12" denotes a third connection terminal. If the snap spring 10 is hooked into one of the other two openings 92 and 92 of the projection 9 of the control lever 4, the displacement path of the pressure member 1 can thereby be increased. With reference to the further Fi g. 3 to 5 it is to be assumed for the operation of the snap switch described above that the snap spring 10 exerts opposing tensile forces F1 and F2 on the control lever 4 or the contact arm 11 via its two ends. The tensile force F1 can be divided vectorially into the forces F * and F1 ", that is, into a partial force acting in the direction of the control lever 4 and a partial force acting perpendicular thereto. The partial force Ft 'acts in a direction opposite to the line of action R of the return spring 6. How Fig. 3 indicate that for touching the contact pieces of the contact arm 11 on the closing fixed contact (Fig. 3 A) or on the opening fixed contact (Fig. 3 C) or for a point in time shortly before When the snap action occurs (Fig. 3 B), this division of forces almost always prevails for a switching cycle that is initiated by depressing the pressure member 1.This means that the control lever 4 is pivoted in the counterclockwise direction, which means that its item 9 This downward movement of the projection 9 also causes a downward movement of the snap spring 10 to trigger the snapping process, that is, the waste of the contact arm 11 in a clockwise direction has the consequence, whereby one of the contact pieces comes into contact with the opening fixed contact 15 and remains in this contact position until the force on the pressure member 1 is canceled. This then has the consequence that the return spring 6 pushes the free end of the control lever 4 upwards, causing it to pivot clockwise, thereby moving the projection 9 upwards and thus also pulling the snap spring 10 upwards, so that the other contact piece of the Contact arm 11 comes into contact again with the closing fixed contact.

With regard to the distribution of forces and moments of force, referring in particular to FIG. 4 and 5 assume the following requirements. Without taking into account the actuating force acting in the direction of the vector line W, the contact between the one contact piece 13 of the contact arm 11 and the closing fixed contact 14 is assumed to be in a state of equilibrium. This state of equilibrium or equilibrium is also present in any swivel position of the control lever 4 because the torque applied by the return spring 6 on the one hand is directed in the opposite direction to the torque applied by the snap spring 10 on the other hand. The level of the contact pressure is now determined by the strength of the snap spring 10, which thus finds its opposite pole in the return spring 6, compared to which it is made somewhat weaker. This state of equilibrium or equilibrium is only disturbed if an actuating force is exerted on the pressure member 1 in the direction of the vector line W; this actuating force can thus be applied with a minimum value. It is irrelevant for the switching characteristics of the switch where the pressure element is applied to the control lever 4 , if the action occurs in the LA ae shown in dashed lines in FIG influenced.

In the diagram of FIG. 5, the clockwise torques acting on the positive branch of the Y-axis are mapped as a function of the displacement path of the pressure member plotted on the X-axis, while the counterclockwise torques acting in the counterclockwise direction are plotted on its negative branch. The line from stands for the change in the torque exerted by the return spring 6 on the control lever 4; its pitch angle corresponds to the spring constant k of this return spring. The line cdejghc stands for the change in the torque exerted by the snap spring 10 on the control lever 4, while the line ijklmni stands for the change in the resultant of these two torques. Of course, these lines are only ideally straight lines, usually curves are to be brought to the beginning, which can, however, be viewed approximately as straight. The line drawn for the resultant of the two torques thus determines the level of the force to be exerted on the tension member in order to operate the switch. The displacement path O-qu corresponds to the displacement path x in FIG. 4, which is therefore required in order to lift one contact piece 13 of the contact arm from the closing fixed contact 14. For this lifting, on the other hand, a torque of the size qu-j is required, which is absolutely smaller than the torque qu-e, from which the conclusion that the force for pressing down the pressure member 1 can be set relatively low even when the snap spring 10 is designed to provide a high contact pressure relatively strong. From this diagram it can also be deduced that by screwing in the adjusting screw 8, i.e. a resulting increase in the biasing force of the return spring 6, the line from is shifted upwards parallel to itself and thus also the line i jklmni, without it becoming a Change of the line line cdefghc is coming.

Instead of the push button designed as a push button as described above Embodiment can also be a split on a shaft cam as an actuator come to the actuation of the control lever. The return spring 6, which is described in the above Embodiment is designed as an upwardly acting compression spring, can also as upward acting tension spring be formed without thereby the described Conditions would experience a change.

Claims (5)

Claims: 1. Electrical snap-action switch for pressure actuation with a control lever, one end of which can be pivoted about a stationary pivot point and which is braced via a snap spring with a contact arm which is arranged approximately parallel to and below it, pivotably mounted in an opposing stationary pivot point and which can be snapped around carries at its free end two contact pieces, one of which can be brought into contact with a closing fixed contact and the other with an opening fixed contact, and with a return spring acting on the free end of the control lever, characterized by the combination of the partially known Features: a) the fixed pivot point (4 ', 5') of the control lever (4) is above the connecting line of the fixed pivot point (12, 12 ') of the contact arm when one contact piece (13) touches the closing fixed contact (14) (11) with the point of application (11 ') of the snap spring (10) on the contact arm; b) the return spring (6) loads the free end of the control lever (4) from below; c) the pressure member (1) comes with the free end of the control lever (4) from above to act directly; d) the return spring (6) is an upwardly acting compression or tension spring, and the snap spring (10) is a downwardly acting tension spring, and e) the tensile force of the snap spring (10) acting on the control lever (4) acts continuously opposite direction to the pressure or. Tensile force of the return spring (6) and is smaller than this. 2. Snap switch according to claim 1, characterized in that the fixed pivot point (4 ', 5') of the control lever (4) Can be placed at different altitudes. 3. Snap switch after Claim 1 or 2, characterized in that the at the free end of the control lever (4) acting return spring (6) is adjustable in its preload. 4. Snap switch according to claim 3, characterized in that the return spring (6) is an adjusting screw (8) is assigned. 5. Snap switch according to one of claims 1 to 4, characterized characterized in that the snap spring (10) in different positions on the control lever (4) can be determined.