SI24729A - A mechanism for speed independent switching on contacts - Google Patents

Abstract

The mechanism according to the invention is arranged in such a way that the spring (5) is fixed to the lever (2) and to the lever (6) in such a way that, when the activation force (1) is applied to the lever (2), the feeding of the energy immediately before closing the contact (8) which is movably mounted in the pole (7), releases the contact with the contact (9) and ensures contact of the contacts and the contact of the contact spring (14) independently of the activation force (1). This movement provides a bearing roller (3), which travels along the backbone of the half-bridge (7).

Description

MECHANISM FOR SPEED INDEPENDENT CONTACT SWITCHING

The subject of the invention is a mechanism for speed-independent switching of contacts for switching on electrical loads in protective switchgear, in which the mechanism and implementation of the contacts enable the basic function, that is, switching on and off the contacts, by means of a manually operated lever. The present invention belongs to Class H01H71 / 10, H01H71 / 52, H01H5 / 06 of the International Patent Classification.

The technical problem that is satisfactorily solved by the proposed embodiment of the mechanism is a construction that allows a repetitive and button-independent speed at the moment of contact contact.

Known solutions use different techniques or techniques. the physical operating principles of the switch mechanism. Switch mechanism according to patents FR2717617,

W02005069335 and EP2061059 provide a solution by holding the moving contacts a short distance from the fixed contacts, squeezing the contact springs during switching on, this energy being released in the last phase of switching on when the contacts of the moving contacts move away and hit the fixed contacts at high speed. , which results in bouncing contacts, and the overall contact squeeze is subsequently performed slowly with the continued movement of the used bridge where the moving contacts are engaged. However, if we stop switching on when the contacts are touched, the whole squeeze is not executed.

The switch mechanism according to the patent WO2013003057 provides a solution by holding the moving contacts a short distance from the fixed contacts, during which the spring attached to the button and the moving contact extends during switching on, thus the stored energy is released by moving the recess which moves into the rear the switching stage is executed in an instant and the contacts are hit with the highest contact force. Weakness is a great release of energy at the moment of a collision that cannot be mitigated, which can result in contact rejection.

The mechanism according to the invention solves the requirements for the speed of manual switch-on by independently switching on the contacts with a soaked contact material collision, ensuring an immediate switch-off in the event of a fault in the electrical circuit upon contact contact (free actuation).

The invention is described on the basis of an embodiment and figures showing: FIG. 1 is the on-state mechanism of the invention in axonometric projection on one side; Fig. 2 is an on-state mechanism of the invention in axonometric projection on the other hand; Figure 3 shows the mechanism in the off state from the cross-section; Fig. 4 mechanism just before switching on from the side in cross section; 5 is a cross-sectional view of the mechanism in the engaged state;

Fig. 6 the mechanism in the off state from the side;

Fig. 7 mechanism just before switching on from the side;

Fig. 8 mechanism in on state from the side.

• ·

The mechanism according to the invention is formed by a lever 2, which is centrally mounted in the housing of the mechanism and has a cylindrical attachment, to which a tensile spring 5 is mounted, and a second wheel 3 is attached to the second cylindrical extension. The lower end of the spring 5 is fixed to the piercing axis 19. a rotatable lever 6, which is connected to the lever 11 and a lever 12, is engaged in the housing. The lever 12 is supported by a lever 10 which is engaged in a fixed lever 17 which is attached to the housing of the mechanism. All levers are pivotally connected. The used jumper 7 is housed in the housing of the mechanism and serves as a carrier for contacts 8, which can be any number io up to two or four at most. Contact 8 is pivotally mounted on the half-bridge 7 and supported by the contact spring 14. The spring 14 serves as a shock absorber upon contact collision.

8, 9 and provides the necessary pinching of contacts 8, 9 in the on state.

The spring 5 serves as an energy reservoir and extends from the start of the actuation to the moment of escape of the lever 2, that is, when the actuation of the contacts is made independently of the thrust force 1. The bearing wheel 3 serves to prevent the actuation of the contacts from the desired point and a force of 16 at used bridge 7, which causes rolling, but also serves as part of the shut-off mechanism when complete start-up.

In the off state, the return spring force 13 acts on the half-bridge

7, which is connected to the levers 12, 11 and 6, this causes the spring 5 to be stretched which, by force 4, holds the lever 2 in the off state. The bearing wheel 3 is offset from the half-bridge 7. The contact spring 14 is partially • compressed and pushes the contact 8 by force 15 against the wall of the used bridge 7, the contacts 8 and 9 are open.

Activation takes place in two stages; in the first phase we store the energy in the spring 5 and bring the contact 8 closer to the contact 9, and in the second phase release the stored energy in the spring 5 and use it to close the contacts 8, 9 and to compress the contact spring 14, which provides sufficient contact pressure.

The transfer of the actuating force 1 is carried out via the lever 2, which is moved from the off to the on state. A spring 5 is attached to the lever 2, which begins to extend when the roller 3, which is mounted on the lever 2, rests on the io pole 7. The roller 3 prevents uncontrolled rotation of the pole 7, which causes the spring 5 to stretch slowly and slowly. approaching contact 8 to contact 9. Thus, the actuating force 1 is used to stretch the spring 5 to the point where the roller 3 allows the half-bridge 7 to rotate and to push the contact independent of the speed 2

8 against pin 9 and, after contacting contacts 8 and 9, compresses the contact spring 14.

The spring 5 is fixed at one end to the lever 2 and at the other to the axis 19, which pierces the lever 6, which is pivotally pivoted to the housing in the middle and pivotally coupled to the other end by the lever 11, which is pivotally coupled to the lever 12, which is pivotally engaged in the half-bridge 7. Thus force 4 generates force through the arms 6, 11, 12

18, which generates a torque acting on the half-bridge 7. The lever 12 is supported by a lever 10, which is clamped to a fixed lever 17. All the levers are pivotally connected. The arms 6, 11, 12 are positioned to form a small force 18 in the initial start-up phase, but in the final phase, despite a smaller force 4, they form a large force 18 in the spring 5, because then a large torque is required which compresses the contact spring 14 so force 15 is increasing. The suspension of the spring 5, which is made between the lever 2 and the lever 6, serves as an energy storage device, in that the rotation of the used bridge 7 during the tensioning of the spring 5 prevents the roller 3 from rolling over the used bridge 7.

In the case of slight welding of contacts 8, 9, it is possible to break the weld with lever 2 through the roller 3, which pulls off the half-bridge 7, thereby moving the contact 8 from the contact 9.

Claims (6)

PATENT APPLICATIONS 1. A mechanism for speed-independent switching of contacts for switching on electrical loads in protective switching devices, wherein the mechanism The mechanism according to claim 1, characterized in that all the arms (6, 10, 11, 12, 17) are pivotally connected. The mechanism according to claim 1, characterized in that the bearing roller (3) 20 prevents the second bridge (7) from rotating uncontrollably, causing the spring (5) to stretch and the contact (8) to move slowly to the point (9) to the point where the roller (3) allows the second bridge (7) to rotate and from the lever (2) pushes the contact (8) towards the contact (9) at an independent speed and compresses the contact spring (14) after touching the contact (8) and (9). The mechanism according to claim 1, characterized in that the spring (14) serves as a shock absorber in the event of contact collision (8, 9) and provides the necessary contact compression (8, The mechanism according to claim 1, characterized in that the spring (5) is engaged between the lever (2) and the lever (6) and serves as an energy storage device by rotating the used bridge (7) while tensioning the spring (5) prevents the roller bearing (3) from rolling over the half-bridge io (7). 5 9) in the on state. 5 and the arrangement of contacts allow the contacts to be switched on and off by means of a manually driven lever, characterized in that the mechanism forms a lever (2) which is centrally mounted in the housing of the mechanism and has a cylindrical attachment to which a tensile spring (5) is attached. on the second cylindrical extension, the roller bearing (3) is clamped and the lower end of the spring (5) is fixed to the axis (19), which pierces the crank (6) connected to the crank (11) in the housing, which is connected to the crank (11). (12), the lever (12) being supported by a lever (10) which is clamped into a fixed lever (17) that is attached to the housing of the mechanism; the second bridge (7) is mounted in the housing of the mechanism and serves as a support for contacts (8), which can be any number, 15 preferably two or four, the contact (8) being movably clamped into the half-bridge (7) and supported by the contact spring (14). 6. Mechanism according to claim 1, characterized in that in the case of slight welding of the contact (8, 9) it is possible to tear the weld with the lever (2) over the bearing roller (3), which pulls away the half-bridge (7), thereby moving the contact away. (8) from contact (9).