FR2709864A1 - Electric circuit breaker with sudden tilting mechanism. - Google Patents

Abstract

Electrical circuit breaker comprising a sudden tilting mechanism (1, 3, 4, 8) with a tensioning lever (1) by which a detent element (4) can be moved by a coupling member (3) between two rest positions , a force accumulating spring (8) being tensioned during movement between one rest position and the other until the tilted position of the detent member (4) is reached, and when the tilted position is exceeded , the spring (8) continuing to move the trigger element in the same direction until the second rest position of the trigger element (4) is reached, a transmission lever (11) movable by the trigger element being coupled with the movable contact of the circuit breaker, this trigger element (4) comprising a support element (roller) (12) for moving the transmission lever (11), and moving by sliding or by rolling against the transmission lever (11) over a determined stroke length.

Description

Electric circuit breaker with sudden tilting mechanism The invention

  relates to an electric circuit breaker with a sudden tilting mechanism, which comprises a tensioning lever (drive lever) which can be actuated directly or indirectly by hand, by which an expansion element can be moved into two rest positions by means of '' a coupling member, a force accumulator spring being tensioned during the movement between one rest position and the other until the tilted position of the detent element is reached, and after passing the tilted position , the force accumulator spring continues to move the trigger in the same direction until the second rest position of the trigger is reached, and a transmission lever that can be moved by the relaxation,

  lever which is coupled to the movable electrical contact of the circuit breaker.

  A wide variety of electrical circuit breakers are known, including a sudden tilting mechanism. Their switching mechanism is generally of complicated construction and has relatively large dimensions. It has also been found that when the electrical contacts are soldered to each other, the elastic force of the force accumulator spring is often not sufficient to

  separate the soldered contacts from one another in an emergency.

  The object of the invention is to improve an electrical circuit breaker of the type mentioned in the preamble so that the contacts can be reliably separated from one another although the device is of simple construction and of small dimensions, when these contacts resist opening force because

  that they are welded to each other.

  According to the invention, this object is achieved because the detent element comprises, to move the transmission lever, a support element (roller) which slides or rolls along the transmission lever over a determined length of stroke. , while the support element, in the open position of the circuit breaker, rests against a projecting stop (nose, hook) of the transmission lever

  and limits the travel of the transmission lever on one side.

  Thanks to such a construction, it is possible, by means of the handle or the tensioning lever, to transmit directly to the electrical contact a sufficiently large force by the various elements of the switching mechanism for this contact to be released. This force which is exerted by hand can be greater than the force of the force accumulator spring, which however

  still assisting the opening movement.

  It is particularly advantageous that during a movement of the tensioning lever from the closed position to the open position the support element comes to bear on the stop after a first partial movement, and that during the remaining movement and all by maintaining the support element on the stop of the transmission lever, it can be brought via the support element in the

  position in which the circuit breaker contact is open.

  A relatively simple switching mechanism can be obtained, comprising only a few movable elements and whose dimensions are reduced when the stroke length of the support element is shorter between the two rest positions of the trigger element. as the length of travel of the articulation element between the transmission element leading to the electrical contact and the transmission lever. The force accumulator spring exerts a high force over a short stroke length, while being able to determine a long switching stroke length. It is particularly advantageous that the stroke length of the support element is between one third and half the stroke length of the articulation element of the transmission lever. It is also very advantageous that the force accumulator spring is not moved

  only on a very limited stroke length.

  Advantageously, it is proposed that the force accumulator spring be constituted by a strong helical pressure spring, an annular tension spring, a disc spring or a spring in

tubular blade shape.

  An embodiment is shown in the drawing and will now be described in detail. In the drawing: FIG. 1 represents the switching mechanism of the electric circuit breaker in the open position, the switching shaft and the electrical contacts not being shown, FIG. 2 represents the switching mechanism of FIG. 1 in the closed position, and Figure 3 is a sectional view along line AA of Figure 1. The operating element (handle) of the electric circuit breaker will be called in the following tensioning lever I and can pivot on 60 around d 'an axis 2 from the open position shown in Figure 1 to the closed position shown in Figure 2. The tensioning lever 1 is constituted by a lever with two arms whose arm which is clearly the most important form the handle while to its short arm is connected a coupling member 3, the other end of which is

  hingedly attached to a trigger 4.

  The detent element 4 comprises at one end an articulation element 5 to which the coupling member 3 is fixed, and at its opposite end an axial slot 6 into which a fixed stud 7 penetrates. The detent element 4 can thus pivot not only around the axis 7 but can also move longitudinally there in a limited manner. On the expansion element is coaxially mounted a force accumulator spring 8 having the form of a helical pressure spring, which is supported by one end on a shoulder 9 of the expansion element 4 which is close to the articulation element 5, and by its other end on a fixed support 10. The expansion element 4 can therefore only move longitudinally against

spring force 8.

  Elements 1, 3 and 8 thus form a sudden tilting mechanism in which, after pivoting of the tensioning lever 1 over a little more than half of its maximum pivoting angle, the trigger element suddenly passes from the stable position shown at FIG. 1 at the stable position shown in FIG. 2. The articulation element 5 then moves over the relatively limited stroke length W1. If the tensioning lever is moved in the opposite direction, the trigger 4 suddenly returns from the position shown in FIG. 2 to

  the position shown in Figure 1.

  The dimensions are selected so that the stroke length W1 between the two stable rest positions is shorter than the stroke length W2 of the articulation element of a transmission lever 11 which is actuated and which will be described in what follows. The line of action 4a of the trigger 4 is located in the open position outside the axis 13, so that the point of intersection of the line of action 4a with the axis longitudinal of the transmission lever 11 is at a distance b from the axis 13, and in the closed position at a distance a (Figure 2). In the present embodiment, the distance a is shorter than the distance b. The fact that the extension of the line of action 4a in the first stable position is located on one side of the axis 13 and on the other side in the second stable position has the consequence that the transmission lever 11 pivots around the roller 12 when closing in a different direction of rotation than in the case of opening, and this over a very limited stroke length of the roller 12 with significant pivoting movements of the lever

transmission 11.

  The force accumulator spring 8 exerts a high force over a very short stroke length, so that the spring 8 as well as the detent element 4 can be of very short length when the spring 8 is sufficiently powerful. This allows with a short stroke length W1 to produce a long switching stroke W2, so that the spring does not relax too strongly and that it still has sufficient force at the end of its movement to move the switching shaft not shown of the circuit breaker. In particular, the stroke length W1 of the articulation element 5 is between one third and half of the stroke length W2. The force accumulator spring 8 can also consist of an annular tension spring, a disc spring or a tubular leaf spring, which are all characterized by the fact that they produce a high force over a short stroke length of 0lo spring, which remains essentially the same over the short length of

spring stroke.

  A roller is rotatably attached to the articulation element 5 to constitute the support element 12, as shown in section in FIG. 3. This roller 12 moves by turning on the straight edge of the transmission lever 11 which can pivot around a fixed axis 13 which is located near the articulation element 5 and the coupling member 3. At its other end, the transmission lever 11 comprises an elongated slot 14 oriented in the longitudinal direction of the lever 11, into which penetrates a connecting element 15 which is fixed to one end of an element

  bar-shaped coupling 16.

  When the trigger 4 pivots from the first position shown in Figure 1 to the second position shown in Figure 2, the roller 12 rolls along the side edge 17 of the transmission lever 11 and thus rotates the transmission lever with two arms, the roller 12 being, in the first position, in the region of the upper part of the lever arm which is close to the coupling member 3, and in the second position in the second part of the arm of the sink. The expansion element 4 determines a relatively large stroke length W2

of the articulation element 15.

  In the first position of the articulation element 5, the roller 12 is applied against a stop (nose, hook) 18 projecting from the edge 17 at the end of its stroke. This stop 18 makes that during a movement of the tensioning lever 1 from the closed position to the open position, the roller 12 comes to bear on the stop 18 and also pivots the transmission lever 11 in

  the open position when the force of the spring 8 is not enough.

  This is particularly important when the electrical contacts of the circuit breaker have soldered to each other following a

  high stress caused by an electric arc.

  The coupling element 16 is articulated at its end opposite to the connection element 15 on a switching shaft not shown from which protrudes the movable electrical contact which comes to rest against a fixed electrical contact after a movement of

  the switching shaft in the closed position.

Claims (6)

  1. Electric circuit breaker comprising a sudden tilting mechanism (1, 3, 4, 8) which comprises a tensioning lever (driving lever) (1) which can be actuated directly or indirectly by hand, by which an expansion element ( 4) can be moved via a coupling member (3) between two rest positions, a force accumulator spring (8) being tensioned during this movement between one rest position and the other until until the tilted position of the detent element (4) is reached, and the 0lo force accumulator spring (8) continues to move the detent element (4) in the same direction after having exceeded the tilted position until that the second rest position of the expansion element (4) is reached, and a transmission lever (11) which is coupled with the movable electrical contact of the circuit breaker can be moved by the expansion element, characterized in what - the element d he trigger (4) comprises, in order to obtain the movement of the transmission lever (11), a support element (roller) (12) which moves by sliding or rolling over a determined stroke length along the transmission lever (11 ), and - the support element (12), in the open position of the circuit breaker, is applied against a projecting stop (nose, ratchet) (18) of the transmission lever (11) which limits on a side the race of transmission lever.   2. Circuit breaker according to claim 1, characterized in that in the case of a movement of the tensioning lever (1) from the closed position to the open position, the support element (12) bears against the stop (18) after a first partial movement, and in that during the remaining movement and while the support element (12) remains in abutment against the stop (18) of the transmission lever (11), it can be moved by the support element (12) in the position   in which the circuit breaker contact is open.   3. Circuit breaker according to claim 1 or 2, characterized in that the stroke length (Wil) of the support element (12) between the two rest positions of the expansion element (4) is shorter than the stroke length (W2) of the articulation element (15) between the transmission element which goes into electrical contact and the lever transmission (11).   4. Circuit breaker according to claim 3, characterized in that the stroke length (W1) of the support element (12) is between one third and half the stroke length (W2) of the element   hinge (15) of the transmission lever (11).   5. Circuit breaker according to any one of claims   previous, characterized in that the force accumulator spring   (8) is only moved over a stroke of very short length.   6. A circuit breaker according to claim 5, characterized in that the force accumulator spring (8) is a powerful helical pressure spring, an annular tension spring, a spring with   disc or tubular leaf spring.