NO317117B1 - An extinguishing chamber for a self-extinguishing circuit breaker with rotating arc - Google Patents

Description

The invention relates to an extinguishing chamber for a high-voltage circuit breaker insulated with a gas of high dielectric strength, equipped with a device for extinguishing an electric arc by self-expansion of the gas, which chamber comprises: - an enclosure made of insulating material, containing a stationary contact device that cooperates with a movable contact arranged at the end of a conductive tube, which passes by sliding through one of the panels of the enclosure and which moves between a closed position and an open position for the contacts, - an electromagnetic coil for rotation of the arc on the contact track located on the front face of the coil, said coil being securely fixed to the stationary contact means to form an overhanging module on the opposite panel of the enclosure, - means for connecting the chamber to the outer volume of the enclosure when the self-expansion of gas takes place after the contact is been separated, - where the stationary contact device is coax generally surrounded by the cylindrical coil, and comprising a plurality of contact fingers arranged along the circumference to define a cavity for receiving the movable contact, each contact finger in the stationary contact device comprising a composite metallic structure having: - a main part of copper, shaped as a cylinder sector, for the flow of the permanent current in the closed position of the movable contact, - an electrode made of a resistant conductive material, brazed on the front end of the main part to form a stationary arc contact arranged near the arc rotation track, - and a segment made of a ferromagnetic material brazed to the periphery of the electrode and of part of the main part, which segment is placed inside the coil to achieve optimal guidance of the arc along the track.

In known extinguishing chambers of the above type, flow of the nominal current generally takes place in a main circuit equipped with stationary and movable main contacts which are separated before the arc contacts open, and which close after the arc contacts have closed. The main circuit is formed by a circuit independent of the arc circuit and is arranged either coaxially around the coil or offset laterally in relation to the arc circuit (particularly described in document EP-A-768,692). The complex architecture of such an extinguishing chamber for the circuit breaker is not suitable for a substation that requires small dimensions.

In the circuit breaker of document US-A-4,431,886, the coil is permanently excited by the rated current when the contacts are closed.

The purpose of the invention is to produce an improved closing chamber for a self-extinguishing expansion circuit breaker that can be contained in a compact sub-station. The extinguishing chamber according to the invention is characterized in that the electrode and the segment for each contact finger are separated from the contact track by an axial space of small thickness, to enable the connection of the arc for excitation of the coil when the movable contact is separated from the electrode. Each contact finger is provided with a trailing edge latched onto a centering portion of a live pin.

The combined operation of the composite structure of the stationary contact device as main contact and arc contact, in the internal dimensions of the coil, enables the achievement of a very compact extinguishing chamber.

According to a preferred embodiment, the electrode is made of a copper-tungsten alloy base, and the segment is made of steel.

According to one feature of the invention, the coil is connected to the pin with support arms made of copper which form spacers, separated from the contact fingers by an insulating substrate. A spring in the form of a curved blade is inserted between each insulating substrate and the corresponding contact finger.

Other advantages and features will appear more clearly from the following description of an embodiment of the invention, given only as a non-limiting example and shown in the attached drawings, where: fig. 1 is a cross-sectional view of the extinguishing chamber according to the invention, shown in the closed position of the contacts;

fig. 2 is a view identical to Fig. 1 in the open position;

fig. 3 is a perspective view of the pre-assembled coil and stationary contactor module;

fig. 4 shows an elevational view of fig. 3;

fig. 5 is a cross-sectional view along the line 5-5 in fig. 4;

fig. 6 shows a perspective view of an elementary contact finger for the stationary contact device;

fig. 7 is a top view of a contact finger;

fig. 8 shows a cross-sectional view along the line 8-8 in Fig. 7;

fig. 9 is a cross-sectional view along line 9-9 in FIG. 7.

In fig. 1 and 2 comprises an extinguishing chamber 10 for one pole of a high-voltage circuit breaker of the self-extinguishing expansion type with an enclosure 12 made of insulating material and filled with a gas of high dielectric strength, in particular sulfur hexafluoride SF6. The inner volume of the extinguishing chamber 10 contains a tubular movable contact 14 which cooperates with a stationary contact device 16 associated with an electromagnetic coil 18 for rotation of the arc. The movable contact 14 is located at the end of an elongated tube 20 made of conductive material, which is able to slide tightly through one of the panels 22 of the insulating enclosure 12. The outer end of the tube 20 is connected to a drive mechanism (not shown) designed to move the movable contact 14 between a closed position (Fig. 1) and an open position (Fig. 2).

The stationary contact device 16 is extended by a conductive pin 24 of cylindrical shape passing through the opposite panel 26 in the longitudinal direction of the enclosure 12, and connected to the outside with the terminal strip 28 for the pole. The hollow tube 20 allows the extinguishing chamber 10 to communicate with the outer volume of the enclosure 12 as soon as the contacts 14, 16 are separated thereby allowing self-expansion of the gas.

The insulating enclosure 12 is formed by joining two half-shells 12A, 12B, both produced by molding a polymer-plastic material which has good mechanical strength and thermal resistance.

With reference to fig. 3-5, the electromagnetic coil 18 used to extinguish the arc comprises an axial stacking of conductive copper windings 18A which are adjacent to each other, and which are electrically connected in series by means of fixing screws 30 with intermediate cut-in parts 18B made of insulating material. The front surface 31 of the coil 18 is equipped with an arc-conducting groove 32 of ring shape, and which has an inner diameter slightly larger than the diameter of the movable contact 14. The rear winding 33 on the opposite side of the front surface 31 is connected to the conducting pin 24 with support arms 34 which constitute spacers of copper, which are separated from the inner stationary contact device 16 by insulating base 36. Two steel discs 38, 40 are fixed with screws 30 to the rear surface of the coil 18, with insulating discs 41 placed between them.

The stationary contact device 16 for the self-extinguishing expansion circuit breaker comprises three contact fingers 42 in the form of circular sectors, circumferentially arranged to form a cylindrical hollow contact. The inner diameter of this hollow contact substantially corresponds to the outer diameter of the movable contact 14, to allow telescopic sliding, respectively at the beginning of the opening movement and at the end of the closing movement of the movable contact 14.

Each contact finger 42 has associated with it a spring 44 in the form of a curved blade, the convex surface of which is associated with the insulating substrate for the corresponding support arm 34. Centering of the three contact fingers 42 in relation to the longitudinal axis of the stationary contact device 16 is carried out by by means of edges 46 provided at the back of the contact fingers 42 and secured with locking on a centering shoulder 48 for the pin 24.

The coil 18 surrounds the stationary contact device 16 coaxially with a small annular clearance, the pre-assembled assembly forming an overhanging module attached to the panel 26 by means of a nut 50 which is accessible from the outside of the enclosure 12.

The structure of the stationary contact device 16 inside the coil 18 is arranged to give it a double function, as a stationary main contact for the flow of the permanent current, and as a stationary arc contact in the separation and current breaking phase in the coil 18.1 fig. 6-9, each contact finger is made of a composite metallic structure formed from different materials assembled by brazing. The main part 52 of the contact finger 42 is made of copper and is formed as a cylinder sector for the flow of the permanent current when the movable contact 14 is in the closed position. A copper-tungsten electrode 54 is brazed to the rear end of the main part 52 located on the opposite side of the locking edge 46. This electrode 54 performs the function of a stationary arc contact to protect the stationary contact device 16 against the effects of the arc.

The inner cylindrical part of the main part 52 is connected to the electrode 54 by a curved, intermediate part 56 which serves to facilitate the insertion of the movable contact 14 in the closing phase of the circuit breaker. A segment 58 made of steel or other ferromagnetic material is brazed on the periphery of the electrode 54 of the main part 52 to effect guidance of the arc and good distribution of the magnetic field generated by the coil 18 when the arc is connected on the track 32. The axial length of the segment 58 is larger than the equivalent for the electrode 54, and extends up to the vicinity of the cylindrical part of the main part 52.

The operation of the extinguishing chamber 10 according to the invention is as follows: 1 the closed position (fig. 1) the movable contact 14 is inserted into the stationary contact device 16 and is engaged with the copper main part 52 for the flow of the permanent current, which may have a nominal value of 630A. The contact pressure is applied by the springs 44 to the contact fingers 42, and the coil 18 is out of action, since all the current flows through the pin 24, the contact fingers 42, and the movable contact 14 in the tube 20. The constriction forces enable a compensating effect on the contacts to keep them closed.

Should a short-circuit current occur, the operating mechanism causes the tube 20 to slide upwards and the movable contact 14 to be withdrawn in the direction of the electrode 54. An arc occurs as soon as the movable contact 14 is separated from the electrode 54, which is separated from the groove 32 by a small axial space. The movement of the arc on the track 32 then causes the current to flow in the coil 18 and the support arms 34, with the formation of a magnetic field which causes rapid rotation of the arc around the track 32. Then there is no current flowing in the contact fingers 42.

The arc temperature increase causes a pressure increase in the SF6 gas inside the enclosure 12, followed by a gas flow via the tube 20 to the expansion volume of the tank (not shown). Extinguishing the arc takes place as soon as the arc is sufficiently cooled by the gas flow (Fig. 2).

The combined operation of the stationary contact device 16 as main contact and arc contact, within the internal dimensions of the coil 18, makes it possible to provide a very compact extinguishing chamber at a low initial cost.

Claims (8)

1. Extinguishing chamber for a high-voltage circuit breaker insulated with a gas of high dielectric strength, equipped with a device for extinguishing an arc by self-expansion of the gas, which chamber comprises: - an enclosure (12) made of insulating material, containing a stationary contact device (16) which cooperates with a movable contact (14) arranged at the end of a conductive tube (20), which passes by sliding through one of the panels (22) of the enclosure and which moves between a closed position and an open position for the contacts , - an electromagnetic coil (18) for rotation of the arc on the contact track (32) located on the front surface of the coil (18), said coil being securely fixed on the stationary contact device to form an overhanging module on the opposite panel (26 ) in the enclosure (12), - means for connecting the chamber (10) with the outer volume of the enclosure (12) when the self-expansion of gas takes place after the contact has been separated, - where the n the stationary contact device is coaxially surrounded by the cylindrical coil (18), and comprises a plurality of contact fingers (42) arranged along the circumference to define a cavity for receiving the movable contact (14), each contact finger (42) in the stationary the contact device (16) comprises a composite metallic structure which has: - a main part (52) of copper, shaped like a cylinder sector, for the flow of the permanent current in the closed position of the movable contact (14), - an electrode (54) made of a heavy fusible conductive material brazed to the front end of the main part (52) to form a stationary arc contact arranged near the arc rotation track, - and a segment (58) made of a ferromagnetic material brazed to the periphery of the electrode (54 ) and of part of the main part (52), which segment is placed inside the coil (18) to achieve optimal guidance of the arc along the track (32), characterized in that the electrode (54) and the segment (58) for each contact finger (52) is separated from the contact groove (32) by an axial space of small thickness, to enable connection of the arc for excitation of the coil (18) when the movable contact (14) is separated from the electrode (54). 2. Extinguishing chamber as stated in claim 1, characterized in that the electrode (54) is made of a copper-tungsten alloy base. 3. Extinguishing chamber as stated in claim 1 or 2, characterized in that the segment (58) is made of steel. 4. Extinguishing chamber as stated in claim 1, characterized in that each contact finger (42) is equipped with a rear edge (46) fixed with locking on a centering part (48) of a current-conducting pin (24). 5. Extinguishing chamber as stated in claim 4, characterized in that the coil (18) is connected to the pin (24) with copper support arms (34) which form spacers separated from the contact fingers (42) with an insulating substrate (36). 6. Extinguishing chamber as stated in claim 5, characterized in that a spring (44) in the form of a curved blade is inserted between each insulating substrate (36) and the associated contact finger (42). 7. Extinguishing chamber as specified in claim 5, characterized in that the coil (18) is formed by axial stacking of conductive windings (18A) isolated from each other with insulating cut-in parts (18B), and that the rear surface of the coil (18) on the opposite side of the slot (32) is equipped with steel washers (38, 40), where the assembly is fixed with fixing screws (30). 8. Extinguishing chamber as stated in claim 1, characterized in that the connecting means are formed by the hollow tube (20) in the movable contact (14).