FR2499307A1 - CONTROL MECHANISM WITH OSCILLATING PART AND ELASTIC RETURN MEANS FOR ELECTRICAL APPARATUS WITH TWO STABLE POSITIONS AND ELECTRICAL APPARATUS COMPRISING SUCH A MECHANISM - Google Patents

Abstract

A push rod (3) which can move in a reciprocating manner and is pressed to the lower end whenever it is operated supports a finger (4) which is connected to a cam profile (7) which is arranged in a rocker (5) which is coupled to an electrical contact device (6) in two stable positions. A telescopic element (16), which is provided with a compression spring (9), is supported at one end (at 30) in the push rod (3) and at the other end (at 27) in the rocker (5) in such a manner that, in each quiescent position, the finger (4) is arranged opposite one or the other of the two control switch positions (10, 11) which admits the cam profile (7).

Description

 The invention relates to a control mechanism for electrical devices such as switches, reversers, switches, remote switches and the like, comprising: a connecting rod on which intermittent longitudinal control thrusts are exerted, always directed in the same direction, and which carries an operating finger an oscillating part which is coupled to at least one electrical contact member with two stable alternative positions and which is provided with a cam profile with which the operating finger of the connecting rod cooperates, this oscillating part being mounted so that it can rotate around a fixed axis; and elastic return means working in compression and arranged so as to give way to the abovementioned longitudinal control thrusts and to urge the oscillating part alternately towards two angular end-of-travel positions which correspond respectively to the two stable positions of the electrical contact, prof.

cam having two symmetrically or substantially symmetrical control notches intended to alternately receive the operating finger when the abovementioned longitudinal thrusts are exerted.

 The object of the invention is to arrange the above-mentioned mechanism in such a way that, when it is at rest in one or other of the end-of-travel positions of the oscillating part, the operating finger is necessarily placed , relative to the cam profile, at the desired position for the next operation of the mechanism.

To achieve this goal, the control mechanism according to the invention is essentially characterized in that the elastic return means are incorporated in a telescopic element which is articulated by one end to the connecting rod and by the other end to a zone of the oscillating part which is situated between the fixed axis of this and the articulation of the telescopic element to the connecting rod, in that the cam profile has two lateral retaining notches, opposite respectively to the two control notches, and in that the telescopic element is arranged in such a way that its longitudinal axis passes from one side to the other of the geometric pivot axis of the oscillating part each
Once this rod is subjected to a longitudinal maneuvering thrust.

 A toggle mechanism is thus obtained which, as will be explained in more detail below, engages and maintains the operating finger alternately in the two lateral retaining notches, at the end of each operation, that is to say say opposite that of the two control notches with which this finger must cooperate during the next maneuver.

 Preferably, the electrical contact member consists of a contact-carrying part which is guided parallel or roughly parallel to the telescopic mean direction of the longitudinal axis of the element / and of at least one movable contact. which is carried by the contact-carrying part and which cooperates with two fixed contacts as well as with a spring normally bearing at one of its ends on the contact-carrying part and urging the movable contact towards the fixed contacts. To balance the maneuvering forces in both directions, it is advantageous to place a fixed abutment element on the path of the contact piece so as to immobilize the said end of the spring during the movement of the piece. contact which moves the movable contact away from the fixed contacts.

 Finally, in order to provide a self-cleaning of the contact grains by lateral displacement, the contact-carrying part is preferably connected to the oscillating part by means of an articulation axis as far as possible from the axis of this oscillating part. .

 The invention will now be described in more detail with the aid of the accompanying drawings which illustrate a preferred embodiment.

 Figures 1 and 2 partially show an electrical device according to the invention, the front part of the housing is removed, respectively in the two stable positions of its electrical contact member.

 Figure 3 is a cross section along line III - III of Figure 1.

 FIGS. 4 to 11 are diagrams illustrating the operation of the same device, the positions of FIGS. 4 and 8 being identical to those of FIGS. 1 and 2 respectively.

The electrical appliance shown in the figures
1, 2 and 3, has, inside a housing formed by two adjoining shells 1 and 2, a control mechanism comprising - a connecting rod 3 on which intermittently act longitudinal control thrusts, always directed from top to bottom, and which carries an operating finger 4 - an oscillating part 5 which is coupled to at least one electrical contact member 6 and which is provided with a cam profile 7 with which the operating finger 4 of the connecting rod 3, this oscillating part 5 being mounted so as to be able to rotate by a limited angle around a fixed pivot axis 23, generally materialized by pivots or trunnions 8, and - elastic return means 9 working at the compression and arranged so as to yield to the abovementioned longitudinal control thrusts and to urge the oscillating part 5 alternately towards two angular end-of-travel positions (FIGS. 1 and 4 and FIGS. 2 and 8) which correspond respectively to the two stable positions of the o electrical contact member 6, the cam profile 7 having two symmetrical or practically symmetrical control notches 10 and 11 intended to alternately receive the operating finger 4 when the above-mentioned longitudinal thrusts are exerted.

 According to the embodiment shown, these longitudinal thrusts are exerted by a pallet 12 which is mounted on the housing 1, 2 by means of a pivot axis 13 and which can be lowered against the action of the elastic return means 9 under the effect either of the attraction of an electromagnet 14, or of a thrust exerted manually by means of an oscillating pusher 15.

 In this type of device, it is essential that at each rest position, the operating finger 4 is opposite that of the notches 10 and 11 which corresponds to the tilting of the oscillating part 5 towards the other rest position , so that the next longitudinal operating thrust (due to the momentary excitation of the electromagnet 14 or the depression of the oscillating plunger 15) is effective. The object of the invention is in particular to solve this problem while using a space-saving oscillating part 5.

 To this end, the elastic return means 9 are incorporated in a telescopic element 16) which is articulated by one end to the connecting rod 3 and-by the other end to an area of the oscillating part 5 which is located between the axis of fixed pivoting 23 thereof and the articulation of the telescopic element 16 to the connecting rod 3. In addition, the cam profile 7 has two lateral retaining notches 20 and 21, opposite respectively to the two control notches 10 and 11 Finally, the telescopic element 16 is arranged in such a way that its longitudinal axis 22 passes from one side to the other of the geometric pivot axis 23 of the oscillating part 5, each time that the connecting rod 3 undergoes a thrust. longitudinal maneuver.

 In the cam profile 7, the retaining notches 20 and 21 are interconnected by a smooth and flat surface 41 (FIG. 10), the control notch 10-is connected to the opposite retaining notch 20 by a smooth surface and flat 42 while the control notch 11 is connected to the opposite retaining notch 21 by a smooth and flat surface 43.

 According to a particularly advantageous construction, the telescopic element 16 consists of a cage 24 inside which is guided, along the axis 22, a slide 25, the elastic return means 9 being constituted by a compressed spring between the slide 25 and one of the transverse walls 26 of the cage 24.

On the side of this transverse wall 26, the cage 24 comprises a seat 27 which receives the end 28, in the form of a ball joint, of an arm 29 which projects radially from the oscillating part 5 and relative to which the control notches 10 and 11 are placed symmetrically or approximately symmetrically. In the slide 25 is engaged an axis 30 which is part of the connecting rod 3.

 Opposite its transverse wall 26, the cage 24 carries an indicator finger 31 which, depending on the rest position of the mechanism, is placed (Figures 1 and 4) or not (Figures 2 and 8) behind a transparent element 32 housing 1, 2 which, for the rest, is opaque.

 Stops 33 and 34, fixed relative to the housing 1, 2, cooperate with the oscillating part 5 so as to define its two stable end-of-travel positions.

 A mechanism is thus obtained, the operation of which will be described with the aid of FIGS. 4 to 11.

 In the rest position of Figure 4 (or Figure 1), the spring 9 pushes down the cage 24 and its seat 27. As the longitudinal axis 22 of the telescopic element 16 passes to the right of the axis 23 of the oscillating part 5, the thrust of the spring 9 tends to rotate this part 5 clockwise and thus keeps it against its stop 34. By reacting on the cage 24, the spring 9 tends to lift the slide 25 and, via the axis 30, the connecting rod 3.

Ultimately, the indirect action of the spring 9 on the connecting rod 3 has the effect of urging the finger 4 of the latter towards the lateral retaining notch 20.

 Starting from this rest position, if a longitudinal maneuvering thrust is exerted from top to bottom on the connecting rod 3, the mechanism first passes through the position of FIG. 5 where the finger 4, after having left the retaining notch 20 , was forced by the spring 9 to follow the flat and smooth surface 42, then to enter the control notch 10, located just opposite the retaining notch 20, the oscillating part 5 remaining in contact with its stop 34. continuing to move downwards, the connecting rod 3, whose finger 4 remains engaged in the control notch 10, rotates the oscillating part 5 anticlockwise, this movement first compressing further the spring 9, as it emerges from FIG. 6, then passing the axis 22 of the telescopic element / from one side to the other of the pivot axis 23 of the oscillating part 5, as it emerges of Figure 7. The spring 9 can relax by continuing to rotate the oscillating part S in the ns counter-clockwise, until it meets the stop 33 (Figure 8). As soon as the longitudinal thrust ceases to act on the connecting rod 3, the spring 9 pushes the slide 25 upwards by bringing the pallet 12 back to its initial position and bringing the finger 4 up along the flat and smooth surface 43 as far as the retaining notch 21.

 The position of Figure 8 (and Figure 2) is a stable position, symmetrical to the position of Figure 4 (and Figure 1). In this case also, the operating finger 4 is engaged in the retaining notch 21, opposite the control notch 11. When the next operating thrust is exerted on the connecting rod 3, the finger 4 is necessarily engaged in this notch 11 (as described with reference to FIG. X, without going astray towards the control notch 10, as illustrated in FIG. 9, then passes the elements of the mechanism successively to the positions of FIGS. 10 and II which are symmetrical respectively from those of Figures 6 and 7. As soon as the maneuvering thrust ceases, the elements again reach the stable position of Figure 4, and so on.

 Depending on whether the indicator finger 31 appears (FIGS. 1 and 4) or not (FIGS. 2 and 8) behind the transparent element of the case 32g the user can check from the outside what is the end position of travel occupied by the electrical contact member 6.

 As can be seen from the drawings, this electrical contact member 6 consists of a contact-carrying part 35 which is guided in translation (or approximately in translation) parallel to the mean direction of the longitudinal axis 22 of the telescopic element 16 , and a movable contact 36 which is carried by the part 35 and which cooperates with two fixed contacts 37. The movable contact 36 has a certain clearance a (FIG. 9) relative to the part 35, parallel to the direction of translation of the latter, and a spring 38, placed between the part 35 and the movable contact 36, biases the latter towards the fixed contacts 37. It was assumed that these fixed contacts were located above the movable contact 36 (the device being shouted so that the pallet 12 is placed at its upper part) but the reverse arrangement can also be adopted. In addition, there can be not just one, but two electrical contact members 6-actuated by the mechanism conforming to the invention, these two organ es of contact being arranged respectively on the left and on the right of figure 3 and being in general reversed one compared to the other.

Before reaching the end position of FIG. 4 where the movable contact 36 is in contact with the fixed contacts 37, this movable contact 36 has moved by
on the one hand with respect to the contact-carrying part 35, which / has enabled the oscillating part 5 to reach its stop 34 and on the other hand ensures the necessary pressure between the movable contact 36 and the fixed contacts 37 by compression of the spring 38. The spring 38 tends, by lowering the part 35, to rotate the oscillating part anticlockwise, that is to say to oppose the action of the spring 9 On the contrary, in the end position of FIG. 8 where the movable contact 36 is spaced from the fixed contacts 37, the spring 38 exerts no return action on the contact-carrying part 35 and on the oscillating part 5 , at least according to the usual solution where this spring 38 is constantly supported on the contact piece 35. The elastic return forces which are exerted on the control mechanism are therefore unbalanced at the two end positions of the figures 4 and 8. In other words, to operate the apparatus from the position of FIG. 8 , it is necessary to overcome a greater restoring force than from the position of FIG. 4, which has significant drawbacks, in particular when this force is due to the attraction of the electromagnet 14.

 To eliminate this drawback, according to an improvement of the invention, a fixed stop element 39 is placed on the trajectory of the contact-carrying part 35 so as to immobilize that of the ends of the spring 38 which normally rests on this part 35, during the movement of the latter which moves the movable contact 36 away from the fixed contacts 35. In this way and as shown in FIG. 8, the spring 38, bearing on the stop element 39, comes to exert in the in another end-of-travel position, a return action on the oscillating part 5, by urging the movable contact 36 and consequently the contact-carrying part 35 upwards. This return action tends to rotate the oscillating part 5 in this case. clockwise, so that the forces required to operate the device are practically the same in both directions.

 Finally, it is advantageous to connect the contact-carrying part 35 to the oscillating part 5 by means of a hinge pin 40 as far as possible from the axis 23 of this oscillating part 5, so as to that the rotation thereof causes a certain lateral displacement of the contact-carrying part. This lateral displacement which is indicated by two neighboring mixed lines, roughly vertical, in FIG. 6, is transmitted to the movable contact 36 and provides it with a self-cleaning effect relative to the fixed contacts 37.

 It is possible to actuate by the oscillating part 5 one or more electrical contact members such as 6, placed in adjacent housings. It suffices for this purpose to provide the pivots 8 with a coupling element for the piyot-of a neighboring oscillating part and to provide in the housing 1, 2 a window for the passage of a connecting element between these two. pivots.

Claims (8)

 1. Control mechanism, for electrical devices such as switches, reversers, commu  tutors, remote control switches and the like, comprising: a connecting rod on which intermittent longitudinal thrusts of control, always directed in the same direction and which carries an operating finger; an oscillating part which is coupled to at least one electrical contact member with two stable alternative positions and which is provided with a cam profile with which the operating finger of the connecting rod cooperates, this oscillating part being mounted so as to be able to rotate around a fixed axis; and elastic return means working under compression and arranged so as to yield to the abovementioned longitudinal control thrusts and to urge the oscillating part alternately towards two angular end-of-travel positions which correspond respectively to the two stable positions of the contact member electric, the cam profile having two symmetrical or practically symmetrical control notches intended to receive alternately the operating finger when the abovementioned longitudinal thrusts are exerted, characterized in that the elastic return means (9) are incorporated in a telescopic element (16) which is articulated by one end to the connecting rod (3). And by the other end to an area of the oscillating part (5) which is located between the fixed axis (23) thereof and the articulation of the telescopic element (16) to the connecting rod (3); in that the cam profile (7) has two lateral retaining notches (20, 21), respectively opposite to the two control notches (10, 11), and in that the telescopic element (16) is arranged so such that its longitudinal axis (22) passes from one side to the other of the geometric pivot axis (23) of the oscillating part (5) each time this connecting rod (3) undergoes a longitudinal actuating thrust.  2. control mechanism according to claim 1, characterized in that the telescopic element (16) consists of a cage (24) inside which is guided, along the longitudinal axis (22) of this element  telescopic (16), a slide (25) and in that the elastic return means (9) consist of a spring compressed between this slide (25) and one of the transverse walls (26) of the cage (24) .  3. Control mechanism according to claim 2, characterized in that, on the side of the said transverse wall (26), the cage (24) comprises a seat (27) which receives the end (28), in the form of a ball joint , an arm (29) which projects radially from the oscillating part (S) and with respect to which the control notches (10, 11) are placed symmetrically.  4. Control mechanism according to one of claims 2 and 3, characterized in that an axis (30), forming part of the rod (3), is engaged in the slide. (24).  5. Control mechanism according to any one of claims 2 to 4, characterized in that, opposite the aforesaid transverse wall (26), the cage (24) carries an indicator finger (31) which, according to the rest position of the mechanism, is placed or not behind a transparent element (32) of the housing (1, 2) which, for the rest, is opaque.  6. Control mechanism according to any one of claims 1 to 5, characterized in that stops (33, 34) cooperate with the oscillating part (5) so as to define its two stable end-of-travel positions.  7. Control mechanism according to any one of claims 1 to 6, the electrical contact member of which consists of a contact-holding part which is guided parallel or roughly parallel to the mean direction of the longitudinal axis of the connecting rod and at least one movable contact which is carried by the contact-carrying part and which cooperates with two fixed contacts as well as a spring normally bearing at one of its ends on the contact-carrying part and urging the movable contact to the fixed contacts, characterized in that a fixed stop element (39) is placed on the path of the contact-carrying part (35) so as to immobilize the said end of the spring (36) during movement contact-piece (35) which moves the movable contact (36) away from the fixed contacts (35).  8. Control mechanism according to any one of claims 1 to 7, characterized in that the contact-carrying part (35) is connected to the oscillating part (5) via a hinge pin (40 ) as far as possible from the pivot axis (23) of this oscillating part (5).