FR2733086A1 - HIGH VOLTAGE HYBRID CUTTING DEVICE - Google Patents

Abstract

High-voltage hybrid cut-off device, comprising in a single enclosure (12) filled with gas, a first vacuum switch (14), connected in series with a second gas switch (16). Between the two switches (14, 16) is disposed an actuating rod (28) having a support end of the first movable arcing contact (26) of the first switch (16), and an opposite support end of the contact d semi-fixed arc (38) of the second switch (16), said rod being made of conductive material to ensure the placing in series of the two switches, and passing tightly through the bulb (22) of the first vacuum switch (14) . Elastic means are associated with the actuating rod (28) to ensure the opening of the first switch (14) and to follow the movement in translation of the second movable arcing contact (48) in the direction of opening, ensuring the closure of the second switch (16) to a predetermined intermediate position of the second movable arcing contact (48). Stop means stop the movement of the rod (28) beyond the intermediate axial position so as to open the second switch (16) during the continued opening stroke of the second movable contact (48).

Description

HIGH VOLTAGE HYBRID CUTTING DEVICE

  The invention relates to a high-voltage hybrid switching device, comprising: -a first vacuum switch having a sealed bulb containing a first pair of separable arcing contacts, - a second gas switch comprising a second pair of contacts separable arc, and electrically connected in series with the first switch, - control means for opening and closing said switches according to a predetermined operating sequence, - and a common sealed enclosure for housing the two switches, said enclosure

  being filled with a gas of high dielectric strength.

  Such a breaking device is known from document US-A 4,434,332. Each switch is provided with its own control mechanism intended to move the corresponding movable contact. The two mechanisms are mechanically interconnected by means of cranks wedged on a common shaft controlled from a pressurized pneumatic system. Such a control device is complicated, and requires considerable space. The object of the invention is to provide a high voltage hybrid switching device for

  simple and space-saving construction.

  The device according to the invention is characterized in that the breaking device further comprises: - an actuating rod having a support end of the first movable arcing contact of the first switch, and an opposite end of support for the contact d semi-fixed arc of the second switch, said rod being made of conductive material to ensure the placing in series of the two switches, and passing through the bulb of the first vacuum interrupter in a sealed manner, - elastic means associated with the rod actuation to ensure the opening of the first switch and to follow the translational movement of the second movable arcing contact in the opening direction, ensuring the closing of the second switch to a predetermined intermediate position of the second contact movable arc, - and stop means able to stop the displacement of the rod beyond the intermediate axial position, so as to open the second switch during the race

  continued opening of the second mobile contact.

  Main contacts are also provided inside the envelope by surrounding o10 coaxially the first and the second switch. The main contacts for

  open before the first pair of arcing contacts of the first vacuum interrupter.

  According to a preferred embodiment, the second gas switch comprises a self-expanding cut-off chamber, which communicates with the volume of the envelope by the second hollow movable arcing contact. The semi-fixed arcing contact is arranged on the

  front face of an arc rotation coil.

  According to an alternative embodiment, the second gas switch comprises a device

  self-blowing by gas piston.

  Other advantages and characteristics of the invention will emerge more clearly from the

  description which follows, of two embodiments given as examples not

  limiting, and shown in the accompanying drawings, in which: - Figure 1 is a sectional view of a pole of the hybrid switching device according to the invention, the pole being shown in the closed position, - Figures 2 to 4 show identical views of the device in FIG. 1, respectively when the main contacts are separated, then when the first switch is opened, and finally at the end of the opening stroke,

  FIG. 5 represents a view identical to FIG. 4 of an alternative embodiment.

  In FIGS. 1 to 4, a pole of a hybrid high-voltage cut-off device 10 is housed in a sealed envelope 12 containing a first vacuum switch 14, electrically connected in series with a second gas-insulated switch 16. The casing 12 has a cylindrical side wall made of electrically insulating material, and is closed at its opposite ends by a cover 18 and a bottom 20, which are made of material

  conductor and connected respectively to the input and output terminals of the pole.

  The envelope 12 is filled with gas of high dielectric strength, which may be, for example, sulfur hexafluoride or nitrogen, or a mixture of the two. Other

  gas can of course be used.

  The first vacuum switch 14 is formed by a sealed bulb 22, secured to the inner wall of the cover 18. Inside the bulb 22 is a fixed arcing contact 24 carried by a conductive stud 25 connected to the cover 18. The fixed arcing contact 24 cooperates by abutment with a first movable arcing contact 26, which is secured to a] o end of a movable and conductive actuating rod 28. The rod 28 extends in the longitudinal direction of the pole 10, and passes axially through an orifice 30 in the bulb 22

  with interposition of a sealing bellows 32.

  A first compression spring 34 is interposed opposite the cover 18, between an intermediate shoulder 36 of the rod 28, and the base of the bulb 22. The spring 34 surrounds

coaxially the rod 28.

  The other end of the rod 28 serves as a support for the semi-fixed arcing contact 38 of the second switch 16, having a breaking chamber 40, with self-expansion. The chamber 40 is fixed to the bulb 22 by fixing members 42, 44, and contains a coil 46 for rotating the arc. The front front face of the coil carries the semi-fixed arcing contact 38, which cooperates with a second movable arcing contact 48 of tubular shape, and mounted

  in axial alignment with the actuating rod 28.

  The second movable arcing contact 48 passes tightly through the chamber 40, and is driven in translation by a control socket 50 associated with a mechanism 52 of

  maneuver (shown schematically in Figure 1).

  The control socket 50 is made of a conductive material, and is in electrical connection with the bottom 20. A movable main contact 54 is subject to the control socket 50, and cooperates with a fixed main contact 56 secured to the cover 18. Inside the sleeve 50 is a second spring 58 urging the second contact

  movable arc 48 abutting against the semi-fixed arc contact 38.

  The internal wall of the sleeve 50 is equipped with a drive member 60 intended to cooperate with a radial shoulder 62 of the second movable arcing contact 48 after

  catching up with a dead stroke 64 (see FIG. 1).

  The main contacts 54, 56 are arranged coaxially inside the assembly 12 in

  surrounding the vacuum bulb 22, and the switching chamber 40.

  The interior of the breaking chamber 40 of the second autoexpansion switch 16 communicates with the casing 12 through the second hollow movable arcing contact 48, and

  orifices 66 formed in the socket 50.

  A sliding contact 68 is arranged between the sleeve 50 and the second movable arcing contact 48.

  The operation of the hybrid breaking device 10 according to the invention is as follows: In FIG. 1, all the main and arcing contacts are closed, and the nominal current passes mainly through the main contacts 54, 56 because of the low main circuit impedance. In the event of a short circuit fault detected by the circuit breaker sensors, the mechanism 52 drives the control sleeve 50 in translation in the direction of arrow A (FIG. 2) to interrupt the main circuit following the separation of the main contacts 54 , 56. The short-circuit current switches in the arcing circuit, first passing through the arcing contacts 24, 26 of the first vacuum switch 14, then flows successively in the rod 28, the arcing contacts 38, 48 of the second autoexpansion switch 16, the socket 50, and finally the bottom 20 arranged as an output terminal. During this first phase, all

  arcing contacts 24, 26; 38, 48 remain closed, but the coil 46 is not energized.

  In FIG. 3, the continued opening stroke of the control sleeve 50 drives the second movable arcing contact 48 downward. The semi-mobile assembly formed by the arcing contact 38, the coil 46 the rod 28, and the first movable arcing contact 26 follows the downward movement of the second movable arcing contact 48 thanks to the elastic action of the first spring 34. The arcing contacts 38, 48 of the second autoexpansion switch 16 remain closed, while the arcing contacts 24, 26 of the first vacuum switch 14 open during this second operating phase. The race of the semi-mobile crew stops when the shoulder 36 abuts against the upper wall of the

cutoff 40.

  During the third operating phase which ends at the end of the opening stroke of the sleeve 50 (FIG. 4), the semi-mobile assembly remains immobilized in the position of the

  FIG. 3, and the second movable arcing contact 48 separates from the arcing contact 38.

  The first arc established between the arcing contacts 24, 26 is quickly interrupted by the vacuum bulb 22, which is adapted to large voltage gradients dv / dt, during the period from zero current to increased recovery voltage. The second gas switch 16 intervenes later, and withstands the recovery voltage well. The appearance of a second arc between the arcing contacts 38, 48 causes the excitation of the coil 46, causing the rotation of the arc and a rapid increase in the pressure inside the breaking chamber 40 The flow of gas to the expansion chamber of the envelope 12, via the hollow arc contact 48, allows rapid extinction of the second arc. Such a pole operating sequence avoids all

  re-striking of the arc, and guarantees good dielectric strength of the circuit breaker.

  In the cut-off device 100 illustrated in FIG. 5, the second gas switch 16 is not of the autoexpansion type, but includes a device for self-blowing the arc by piston. The same reference numbers will be used to designate parts identical to those in Figures 1-4. The self-blowing device 70 is provided with a blowing nozzle 72, of insulating material, coaxially surrounding the arcing contacts 38, 48, and integral with a movable cylinder 74 cooperating with a fixed piston 76 so as to delimit a volume 78 pistonnable. The cylinder 74 is made of conductive material, and advantageously comprises at its upper end the movable main contact 54. The lower end of the cylinder 74 is connected to the control sleeve 50 and to the sliding contact 68. The operating sequence of the breaking device 100 of Figure 5 is identical to that described above. The second arc is extinguished by a jet of gas from the

  volume 78 pistonnable, and channeled in the convergent of the nozzle 72.

  it is clear that any other type of cut-off device can be used to constitute the

second gas switch 16.

  According to a variant (not shown), it is possible to reverse the opening phases of the

  switches, by opening the second switch 16 before the first.

Claims (8)

  1. High-voltage hybrid switching device, comprising: -a first vacuum switch (14) having a sealed bulb (22) containing a first pair of separable arcing contacts (24, 26), - a second switch (16 ) gas comprising a second pair of separable arcing contacts (38, 48), and electrically connected in series with the first switch (14), - control means for opening and closing said switches (14, 16) according to a predetermined operating sequence, - and a common sealed enclosure (12) for housing the two switches (14, 16), said enclosure being filled with a gas of high dielectric strength, characterized in that the cut-off device (10, 100 ) further comprises: - an actuating rod (28) having a support end of the first movable arcing contact (26) of the first switch (16), and an opposite end of support for the semi-fixed arcing contact (38) of the second switch (16), the said rod being made of conductive material to ensure that the two switches are placed in series, and passing through the bulb (22) of the first vacuum interrupter (14) in a leaktight manner, - elastic means associated with the actuating rod (28 ) to ensure the opening of the first switch (14) and to follow the movement in translation of the second movable arcing contact (48) in the opening direction, ensuring the closing of the second switch (16) until a predetermined intermediate position of the second movable arcing contact (48), and abutment means capable of stopping the movement of the rod (28) beyond the intermediate axial position, so as to open the second interrupter (16 ) when   continued opening stroke of the second movable contact (48).   2. Hybrid switching device according to claim 1, characterized in that the device comprises main contacts (54, 56) intended to open before the first pair of   arcing contacts (24, 26) of the first vacuum switch (14).   3. Hybrid switching device according to claim 1 or 2, characterized in that the movable main contact (54) is connected to a control socket 50, which is electrically connected to the second movable arcing contact (48) by l 'through a sliding contact (68), and mechanically secured to the control means. 4. Hybrid switching device according to claim 3, characterized in that the control means comprise a drive member (60) fixed to the socket (70), and capable of cooperating with a shoulder (62) of the second contact d 'movable arc (48) after making up for a dead race (64).   5. Hybrid switching device according to claim 2, characterized in that the main contacts (54, 56) are arranged coaxially inside the envelope (12) in   surrounding the first and second switches (14, 16).   6. Hybrid switching device according to one of claims 1 to 5, characterized in that   the second gas switch (16) has a self-expanding breaking chamber (40), which communicates with the volume of the envelope (12) via the second hollow movable arcing contact (48), and that the contact semi-fixed arc (38) is arranged on the   front face of a coil (46) for rotating the arc.   7. Hybrid switching device according to one of claims 1 to 5, characterized in that   the second gas switch (16) includes a self-blowing device (70) by gas boosting.   8. Hybrid switching device according to one of claims 1 to 7, characterized in that   the elastic means comprise a first compression spring (34) arranged between a shoulder (36) of the actuating rod (28), and the base of the bulb (22), and a second spring (58) biasing the second movable arcing contact (48) against the contact   semi-fixed arc (38) of the second switch (16).