FR2766959A1 - Fast control device for high voltage isolating switch - Google Patents

Abstract

The device includes a spring and a loading mechanism with an electrical motor actuating a shaft and a toothed wheel. The mechanism actuates a rotating arm coupled to the spring. An additional mechanism coupled to the rotating arm actuates a mobile contact.

Description

QUICK CONTROL DEVICE FOR AN APPARATUS
HIGH VOLTAGE CONNECTION, ESPECIALLY A
EARTH
The present invention relates to a rapid control device for a high-voltage connection device, in particular an earthing switch, equipped with a movable contact, this device comprising a mechanical energy storage spring, an arming mechanism for this spring comprising an electric motor arranged to drive a first rotary part, a pivoting arm, a second rotary part, locking means arranged to cooperate with said second rotary part to define two stable positions, said pivoting arm carrying a first pin arranged for cooperate with two bearing surfaces of said first rotary part and a second pin arranged to cooperate with two bearing surfaces of said second rotary part, and a mechanism for driving the movable contact.

Devices of this type are already known, in particular the mechanism described by US Pat. No. 4,681,993 which includes a spring whose rod is articulated on a fork-shaped link, secured to an axis which can, depending on the shape embodiment, be distinct from the respective axes of a disc for tensioning the spring and a drive disc. According to one of the embodiments, the tensioning disc and the drive disc are mounted on the same axis which therefore requires only two bearings provided in the housing.

The drawback of this mechanism is notably due to the fact that the working angle, namely the angle at which the link coupled to the spring rod is clearly less than 1800.

Another device of this type is illustrated by Swiss patent 594 279 and comprises two opposite mechanical energy storage springs and several other members associated with these springs, so that the construction of this device turns out to be complicated. Furthermore, it is only by actuating a ratchet, manually or by means of a magnet or following the release of a security system, that the ordering process can be completed. As a result, this process is complicated and awkward, especially in the case of remote control.

The present invention provides a rapid control device as defined in the preamble, comprising a single lock arranged to ensure locking of the device in two distinct positions.

This device is characterized in that said locking means comprise a movable lock housed in a housing and urged by a thrust spring which defines two dead center stops, these dead center stops being arranged to cooperate respectively with the bearing surfaces of the second rotary part to define said stable positions.

According to a preferred embodiment, said second pin is arranged to push said movable lock by opposing the thrust of the spring just before said second rotating part reaches one of the stable positions.

In a particularly advantageous manner, said movable lock comprises a central protuberance carrying said dead center stops which are mutually parallel and parallel to said bearing surfaces of the second rotary part.

Preferably the central protuberance has a rectangular section, and the dead center stops are planar.

Advantageously, the movable lock is a slide arranged to move parallel to itself in the housing subjected to the stress of the spring.

The present invention will be better understood with reference to the description of a preferred embodiment and the accompanying drawings given without limitation and in which: FIG. 1 represents a first state of the device according to the invention, in which the movable contact is closed and the spring disarmed, FIG. 2 represents a second state of the device according to the invention, in which the movable contact is closed and the spring armed, FIG. 3 represents a third state of the device according to the invention, in which the movable contact is open and the spring disarmed, FIG. 4 represents a fourth state of the device according to the invention, in which the movable contact is open and the spring armed, and FIGS. 5A, 5B, 5C and 5D represent the relative positions of the second rotary part and the movable lock in the different phases of changes of state of the movable contact.

The rapid control device 10 for a gas insulated earthing switch as shown in FIGS. 1 to 4, mainly comprises the following components: - a mechanical energy storage spring II, - an arming mechanism 12 of this spring comprising an electric motor 13 and a reduction gear 14 consisting, in
The example shown of a drive pinion 15, mounted on the shaft 16 of the electric motor 13 and of a toothed wheel 17 which meshes with the drive pinion 15, - a first rotary part 18 driven by the mechanism d armament 12 and coupled to a pivoting arm 19 connected to said spring 11, - a coupling member 20, in particular consisting of a chain, which couples the pivoting arm 19 to the spring 11 for the accumulation of mechanical energy, passing through a return pulley 20a, - a second rotary part 21 driven by said pivoting arm 19, this part being arranged to cooperate with dead center stops 22 and 23 associated with a movable contact 24, - a contact drive mechanism 25 mobile 24.

The first rotary part 18 is mounted on the shaft 26 of the toothed wheel 17 and has two bearing surfaces 18a and 18b, radial and diametrically opposite, which are arranged to cooperate, as stops, with a pin 27 mounted in parallel to the shaft 26 on a part 28 articulated on the pivoting arm 19, and to which is fixed the free end of the chain 20. The pin 27 cooperates respectively with the bearing surface 1 8a when the first part 18 is in a first position illustrated in particular in Figure 1 and with the bearing surface 18b when this first rotary part 18 is in a second position illustrated in particular in Figure 3, said rotary part 18 having undergone a rotation of 1800 between the two positions.

The pin 27 is preferably formed by the end of an axis passing through the pivoting arm 19 and which extends on the other side of this arm, in the form of a pin 27a arranged to cooperate with two bearing surfaces 21a and 21b of the second rotary part 21 which is integral with a hollow axis 29 on which the pivoting arm 19 can rotate.

This hollow axis 29 is in the form of a cylindrical part coaxial with a solid axis 29a. The pivoting arm 19 can rotate freely around the hollow axis 29, and the assembly formed by the hollow axis 29 and the second rotary part 21 is freely rotatable around the solid axis 29a which is fixed.

In one of the positions of the pivoting arm 19, as represented for example by FIG. 1, and which corresponds to a first position of the second rotary part 21, the pin 27a is in abutment against the bearing surface 21 a of this second rotary part 21.

In a second position of the pivoting arm 19, reached after a tilting of 1800 and represented for example by FIG. 2, which always corresponds to the initial position of the second rotary part 21, the pin 27a is in abutment against the bearing surface 21 b, of this second rotary part 21.

The drive mechanism 25 of the movable contact 24 comprises an axis 30 carrying a rocking lever 31 on which is fixed a fixed pivot axis 32 which is connected by a link 33 to a pivot axis 34 fixed eccentrically on the second rotary part 21 The bearing surfaces 21a and 21b of this second rotary part 21 are arranged to cooperate respectively with a movable lock 35 carrying the dead center stops 22 and 23 and which is housed inside a housing 36. A thrust spring 37 is disposed in this housing and tends to push the movable lock 35 forward in a position where the bearing surfaces 21 b and 21 a are respectively supported against the dead center stops 22 and 23 (see respectively Figures 1 and 3).

According to the arrangement illustrated in FIG. 1, the movable contact 24 is closed and the mechanical energy accumulation spring II is defused. In this state, the rapid control device is inoperative. To make it operational, it is necessary to arm the spring 11, which has been achieved on the device as shown in FIG. 2.

To achieve this arrangement, the motor 13 was activated so as to drive the toothed wheel 17 in the direction of the arrow A by an angle of 1800.

Following this rotation, the first rotary part 18 carried out a rotation of 1800 by driving the swivel arm 19 by means of the pin 27 and by arming the spring II by means of the part 28 and the chain 20 .

As a result, the pin 27a switches from 1800 to come to bear on the bearing surface 21b of the second rotary part 21 after having pushed the movable lock 35 towards the interior of the housing 36, against the action of the spring of thrust 37.

The movable contact 24 remains closed and the drive mechanism 25 remains in the same position as in FIG. 1. However, the spring II is armed and the rapid control device is operational. In order for this command to take place, the motor 13 must drive the toothed wheel 17 in the direction of the arrow A until the first rotary part 18 and consequently the pivoting arm 19 have passed their neutral position. At this moment, the force of the spring 11, transmitted by the chain 20, exerts a very powerful traction on the part 28 and drives the pivoting arm 19 in rotation at an angle of 1800, as far as the position represented by FIG. 3. The rotation of the pivoting arm 19 causes the rotation of the second rotary part 21 driven by the pin 27a, also integral with the pivoting arm 19.

During this movement, or more exactly in its initial phase, the pin 27a releases the movable lock 35, which is pushed back in front of the housing 36 by the push spring 37. In the final phase of this movement, the surface of support 21a of the second rotary part 21 comes to bear against the dead center stop 23 of the movable lock 35, which has been pushed into position by the push spring 37 in the initial phase of the movement.

The 1800 rotation of the second moving part 21 caused the rod 33 to move. the direction of arrow B by causing the rocking lever 31 to tilt and the axis 30 to rotate, which causes the movable contact 24 to open.

At the end of this procedure, the movable contact 24 is open and the mechanical energy accumulation spring It is disarmed. To make the device operational, it is necessary to re-arm the spring 11. This is done during an approach, the result of which is illustrated in FIG. 4.

The motor 13 is controlled to drive the toothed wheel 17 in the direction indicated by the arrow C, that is to say in the opposite direction to that indicated by the arrow A in FIG. 2. This rotation of the wheel generates the rotation of 1800 of the first rotary part 18, which has the effect of tilting of 1800 the pivoting arm 19 actuated by the pin 27.

The movement of the part 28 articulated on the rocking arm 19 causes the tension of the spring II for the accumulation of mechanical energy. The pin 27a causes the movable latch 35 to be withdrawn inside the housing 36, against the pushing force of the spring 37. The other components of the device do not undergo displacement during this phase.

To ensure the closure of the movable contact 24, it suffices to control the motor 13 in such a way that the first rotary part 18 and the pivoting arm 19 exceed their neutral point, which instantly causes the release of the force of the spring II and the rotation of the second rotary part 21, with the consequence of closing the movable contact 24.

The cycle can be repeated indefinitely by an alternating drive of the motor 13 in one direction or the other.

FIG. 5A shows in more detail the relative position of the lock 35, of the second rotary part 21, of the pivoting arm 19 and of the pin 27a when the device 10 occupies the position illustrated in FIG. 1. It will be noted that the lock is provided a central protuberance 35a which defines the two dead center stops 22 and 23. parallel to each other. In this position, the bearing surface 21b of the second rotary part 21 is in contact with the dead center stop 22. The bearing surface 21b constitutes one of the faces of a stud 40 of rectangular profile with which the second is provided. rotating part 21 and which carries, on one of its sides, said bearing surface 21b. This pin 40 is in fact engaged in a notch 41 of equivalent profile which is formed in the latch 35, between the central protuberance 35a and a projection 42 parallel to this central protuberance 35a and disposed at the lower end of the latch 35. This engagement is made possible by the fact that the latch 35 is pushed forward by the thrust spring 37. The second rotary part 21 is therefore locked in position, the stud 40 being engaged in the notch 41.

FIG. 5B represents a later phase which is illustrated by FIG. 2 and which corresponds to the unlocking of the second rotary part 21. The pivoting arm 19 has rotated by 1800 and the pin 27a has come to be interposed between the oblique flank 43 of the second rotary part 21 and the front face of the central protuberance 35a, thus pushing the lock 35 while counteracting the pushing force exerted by the spring 37. The second rotary part 21 is unlocked.

FIG. 5C represents a state of the device after a further rotation of 1800 of the pivoting arm 19 having caused a rotation of the second rotary part 21. This state corresponds to FIG. 3. In this state the bearing surface 21 a is in contact with the neutral stop 23. In addition, the latch 35 has returned to its advanced position pushed by the spring 37. As a result, the stud 44 of the second rotary part 21, carrying the bearing surface 21 a, is engaged in the notch 45 of the lock 35 delimited by the central protuberance 35a and a projection 46 arranged parallel to the central protuberance 35a at the end of the lock 35 opposite to the projection 42. The second rotary part 21 is well locked.

FIG. 5D represents the state of the device corresponding to FIG. 4. A rotation of 1800 of the pivoting arm 19 has displaced the pin 27a to interpose it between the second oblique flank 47 of the second rotary part 21 and the central protuberance 35a, by pushing the lock 35 against the action of the spring 37. The second rotary part is unlocked.

This device is particularly advantageous in that one and the same lock can ensure locking in two stable positions of the second rotary part and consequently of the entire device.

The present invention is not limited to the embodiment described, but extends to any variant obvious to a person skilled in the art.

Claims (5)

1. Quick control device for a high-voltage connection device, in particular an earthing switch, equipped with a movable contact, this device comprising a spring (11) for accumulating mechanical energy, an arming mechanism ( 12) of this spring comprising an electric motor (13) arranged to drive a first rotary part (18), a pivoting arm (19), a second rotary part (21), locking means arranged to cooperate with said second rotary part (21) to define two stable positions, said pivoting arm carrying a first pin (27) arranged to cooperate with two bearing surfaces (18a, 18b) of said first rotary part (18) and a second pin (27a) arranged to cooperate with two bearing surfaces (21a, 21b) of said second rotary part (21), and a mechanism for driving the movable contact, characterized in that said locking means comprise a movable latch (35) housed in ans a housing (36) and biased by a thrust spring (37) which defines two dead center stops (22, 23), these dead center stops being arranged to cooperate respectively with the bearing surfaces (21b, 21a) of the second rotary part (21) to define said stable positions. 2. Device according to claim 1, characterized in that said second pin (27a) is arranged to push said movable lock (35) by opposing the thrust of the spring (37) just before said second rotary part (21) reaches one of the stable positions. 3. Device according to claim 1, characterized in that said movable lock (35) comprises a central protuberance (35a) carrying said dead center stops (22, 23) which are parallel to each other and parallel to said bearing surfaces (21 b, 21a) of the second rotary part (21). 4. Device according to claim 3, characterized in that the central protuberance (35a) has a rectangular section, and in that the dead center stops (22, 23) are planar. 5. Device according to claim 3, characterized in that the movable lock (35) is a slide arranged to move parallel to itself in the housing (36) subjected to the stress of the spring (37).