FR2737937A1 - High tension circuit breaker with double movement within reduced volume - Google Patents

Abstract

The circuit breaker with a double movement comprises an insulating envelope filled with gas, and insertion resistance (5) and two mobile contact assemblies (14,15-15A,20;29,11-11A). The two contact assemblies are arranged to move in opposite directions. One of the contact assemblies comprises a conducting cylinder (22) containing a contact rod (33) cooperating with a first set (35) of contacts in series with a first end of the resistance (5). This is surrounded by a conducting slide (45) carrying a second set (50) of contacts cooperating with a third set (52) of fixed contacts. The fixed contacts are carried by conducting arms (54) connected to the second end of the resistance (5).

Description

DOUBLE MOTION CIRCUIT BREAKER WITH CLOSING RESISTANCE
The present invention relates to a high voltage circuit breaker with double movement, provided with a closing resistor in each of the chambers, arranged coaxially inside the breaking chamber.

 A double-circuit breaker is a circuit-breaker in which the contacts are moved, in an opening (or tripping) movement, in opposite directions, so that the relative speed of contact separation is increased relative to the separation speed of single movement circuit breakers.

 A double movement circuit breaker has been described in French patent application No. 95 00114. It is a circuit breaker with two breaking chambers per pole, but it should be understood that the present invention also applies to circuit breakers n 'having only one room per pole.

 It has been described, in French patent n079 05478, a circuit breaker comprising a resistor intended to be momentarily inserted in series in the circuit of the circuit breaker, when the latter is closed. Such an insertion is intended to limit the overvoltages which occur in particular when the long empty lines are closed.

 In the aforementioned document, the resistor is arranged inside the interrupting chamber and is associated with an insertion mechanism also placed inside the interrupting chamber.

The latter comprises an insertion contact linked to the moving part of the circuit breaker, consisting of a tungsten cylinder and cooperating with a contact linked to the fixed assembly of the circuit breaker and also consisting of a tungsten cylinder. The electrical contact is made at the end and is made suddenly, which explains the choice of tungsten as the contact material. These cylinders are expensive. The cylinder linked to the moving part is heavy; its rapid movement requires significant energy so that the power of the circuit breaker control must take this into account, which strikes its cost price. The shock of the two cylinders produces shock effects and risks of rebounding so that the mechanism must include damping elements which also increase the cost of the circuit breaker. The size and in particular the diameter of the tungsten cylinders is important , so that the diameter of the porcelain delimiting the cutting chamber is important
An object of the present invention is to provide a double movement circuit breaker, with a resistance insertion mechanism comprising no heavy parts, so that the power of the control can be reduced and its cost lowered.

Another object of the present invention is to provide a double movement circuit breaker, with a resistance insertion mechanism that does not require a damping device when contacting the insertion contacts
Another object of the invention is to provide a double movement circuit breaker with a resistance insertion mechanism of reduced diameter, which makes it possible to reduce the diameter of the porcelain shell and reduce its cost.

 All of these objects are achieved in the circuit breaker described in the claim.

The invention is explained in detail by the description of an exemplary embodiment, with reference to the appended drawing, in which:
FIG. 1 is a perspective view of a circuit breaker breaking chamber, provided with a closing resistor,
FIG. 2 is a partial view in axial section of a breaking chamber according to the invention shown in the engaged position,
FIGS. 3 to 6 are partial views in axial section of the same breaking chamber, illustrating the various stages of a tripping operation of the circuit breaker,
- Figures 7 to 9 are partial views in axial section of the same breaking chamber, illustrating the various stages of a circuit breaker switching operation.

 Figure 1 shows a breaking chamber of a circuit breaker with closing resistance. The breaking chamber comprises a sealed insulating envelope, generally made of porcelain, closed by two end flanges 2 and 3 provided with a first 2A and a second 3A. The interior of the envelope is filled with insulating gas (preferably sulfur hexafluoride SF6 under a pressure of a few hundred hectopascals). A closing resistor is arranged coaxially with the casing 1, inside a metal cover 4 which is in communication with the interior of the casing and which provides the electrical connection between one end of the resistor and the socket. current 4.The mobile assemblies of the breaking chamber are operated respectively by two sets of insulating rods 4A and 30, connected to a control not shown and operating in opposite directions.

 It is noted that the same circuit breaker can comprise, for each phase, several breaking chambers of the aforementioned type, connected in series.

 Furthermore, the invention which is the subject of this patent application applies to installations of the type with a metal shell to the ground, called armored installations. In this case the porcelain casing 1 is replaced by a metallic casing, for example aluminum, grounded, and the sockets are insulated.

 Figure 2 shows, on a larger scale but partially and in axial section, a breaking chamber of a circuit breaker according to the invention.

 There is a ceramic envelope 1 and a first end of the resistor 5, formed of stacked pellets. The second end of the resistor, not visible in FIG. 2, is electrically connected to the second socket 3A, not visible in FIG. 2. The resistor is placed inside an insulating envelope 5A; the stacking of the pellets ends in a metal end piece 5B.

The breaking chamber comprises a first movable assembly comprising a metal cylinder 13 mechanically connected to the operating rod 4A and electrically to the first socket 2A, not visible in the
Fig. 2. The operating rod 4A is arranged to communicate to the cylinder 13 a movement to the right of the figure during a tripping operation of the circuit breaker.

 At one end of the cylinder 13 is disposed a ring of contact fingers 14 constituting the permanent contact of the first movable assembly.

 Coaxial with the cylinder 13 is placed a metal tube 15, a first end of which, not visible in FIG. 2, is electrically connected to the first socket 2A and the second end of which 15A consists of a ring of contact fingers made of material resistant to the effects of the arc. This ring of fingers 15A constitutes the arcing contact of the mobile assembly of the circuit breaker.

 The cylinder 13 and the tube 15 define an annular blowing volume 16 closed on one side by a disc 17 integral with the cylinder 13 and the tube 15 and on the other side by a fixed blowing piston 18 of annular section. The disc 17 is pierced with holes 19 for the passage of the blowing gas which escapes through a blowing nozzle 20.

The piston 18 comprises at least one unidirectional valve 18A intended to supply gas to the volume 16 when the circuit breaker is turned on.

The breaking chamber comprises a second movable assembly, the centerpiece of which is a conductive metal cylinder 22 having first and second closed ends, referenced 22A and 22B respectively; at the end 22A and in the extension of the cylinder 22 is fixed a hollow metal rod 11, for example of copper-based alloy, provided with an end 11A made of a material resistant to the effects of the electric arc. This material can be a tungsten-based alloy. This rod constitutes the arcing contact of the second movable assembly and is intended to come into contact with the 1SA fingers when the circuit breaker is in the engaged position.
The metal cylinder 22 carries a crown 25 to which a metal tube 26 is fixed at the end of which is placed a crown 28 carrying contacts 29.

These contacts 29 are intended to be in contact with the contacts 14 of the first movable assembly, for the passage of the permanent current. The crown 25 is provided with orifices 25A for the passage of gas.

 To the crown 28 are attached the ends of insulating operating rods 30, ensuring the movement of the second movable assembly. It will be noted that these operating rods, connected to a control mechanism not shown, perform a movement to the left of the figure when the circuit breaker opens, in the opposite direction to the movement of the operating rod 4A ensuring the movement of the contacts 14 and 15A.

 Inside the cylinder 22 is arranged a conductive rod 33, one end of which ends in a disc 33A sliding with gentle friction inside the cylinder, and the other end 33B of which passes through the end 22B of the cylinder 22, extends outside of it and engages in the fingers of a first set of contacts 35 secured to the end piece 5B.

 The rod 33 is subjected to the action of a first spring 41, disposed between the disc 33A and the end 22B of the cylinder 22.

 Sliding contacts 43 ensure the passage of current between the conductive rod 33 and the cylinder 22.

 The insertion assembly is completed by a conductive cylindrical slide 45, which can slide around the tube 22, and in electrical contact with the latter by sliding contacts 47. The slide 45 comprises at one end a metal ring 48 carrying a second set contacts 50. The metal ring 48 has orifices 48A for the passage of gas. The contact 50 cooperates with a third set of fixed contacts 52 carried by conductive arms 54 (as a variant by a tube), the first ends of which, not visible in the figure, are connected to the second socket 3A. At the second ends of the arms 54 is optionally fixed a conical insulating part 56 serving to guide the tube 26. The part 56 is pierced with holes 56A for the free circulation of the gas in the envelope.

 A spring 60, having a force lower than that of the spring 41, is placed between the crown 25 and the crown 48.

 The slide 45, when the circuit breaker is in the engaged position as shown in Fig.2, comes, under the action of the spring 60, to bear by a shoulder 45A against the projecting bottom 22B of the cylinder 22. The dimensions of the various components the insertion assembly are chosen so that, in the configuration of FIG. 2 (circuit breaker closed), the contacts 50 and 52 are in contact.

 The end 33B of the rod 33 is provided with a groove 63 in which, for a certain position of the part 33, can engage the ends of the contacts 35 which are secured to this piece 33, this attachment ceasing when the force exerted on the rod 33 exceeds a given value.

 The circuit breaker works as follows.

CIRCUIT BREAKER OPENING
When the circuit breaker is closed, the breaking chamber is in the configuration of Fig. 2.

 The current flows from the second socket to the first socket passing successively: the arms 54, the contacts 52 and 50, the slide 45, the contacts 47, the tube 22, the crown 25, the tube 26, the contacts 29, contact 14 and tube 13.

 At the time of opening, the operating rod 4A pulls the tube 13 to the right of the figure while the rods 30 push the tube 22 to the left of the figure.

 The permanent contacts 14 and 29 separate and the current flows through the arcing contacts 11A and 15A.

 When the arcing contacts are separated (Fig. 3), an arc Al spurts between these contacts.

 It is noted that the spring 60 is slightly compressed but that the contacts 50 and 52 have not moved appreciably relative to one another due to the weakness of the spring 60 and the inertia of the slide 45.

The operating rods continuing their travel, the movable arcing contact 11A leaves the neck of the nozzle 20 (FIG. 4); the gas compressed by the piston 18 escapes through the neck of the nozzle and the orifices 25A and 48A. The arc
Al, stretched, is blown away by the gas.

 It is observed that the contacts 50 and 52 have moved slightly relative to each other, while remaining in electrical contact with each other.

 Fig.5 shows the breaking chamber in the configuration corresponding to an instant before the end of the opening operation. Under the action of the spring 60, the contacts 50 and 52 move relative to each other and will soon separate.

 Fig.6 shows the circuit breaker at the end of the opening operation.

 The ends of the contacts 35 are engaged in the groove 63. The contacts 50 and 52 are completely separate.

 The dimensions of the parts have been chosen so that the respective distances dl and d2, between the contacts 11A and 15A on the one hand, and 50 and 52 on the other hand, are greater than the insulation distance at the nominal voltage of the breaking chamber.

CLOSING THE CIRCUIT BREAKER
A closing operation (switching on) of the circuit breaker is now described and we will show how the resistor 5 is inserted into the circuit, for a limited time.

 When the circuit breaker is closed, the rods are operated in the opposite direction to that with which they were operated when the circuit breaker was opened. The rods 30 drive the second movable assembly to the right of the figure, while the rod 4A pushes the first movable assembly to the left of the figure.

 After a short stroke (Fig. 7), the distance dl becomes less than the isolation distance and an arc A2 erupts between the contacts 11A and 15A. The distance d2 remains constant because the contact 35 remains hooked in the groove 63, despite the compression of the spring 41. The resistor 5 is inserted into the circuit of the circuit breaker which includes the socket 2A, the resistor 5, the end piece 5B, contact 35, rod 33, contact 11-IIA, arc A2, contact 15A, tube 15 and socket 3A.

 The race continues (Fig.8) during which the rod 32 remains attached to the contact 35, ensuring the insertion of the resistance.

When the force exerted by the spring 41 reaches the threshold mentioned above, the rod 33 is suddenly driven to the right; the distance d2 decreases and, as soon as it becomes less than the isolation distance, an arc
A3 springs up between contacts 50 and 52, which short-circuits the resistor (Fig. 9).

 The gripping force of the contact 35 in the groove 63, the force of the spring 41 and the length of the rod 33 are chosen as a function of the relative speed of movement of the mobile assemblies to ensure a suitable duration of insertion of the resistance, for example between 8 and 12 milliseconds.

 The operating rods continue their race until the end of the engagement and we find the configuration of Fig. 2.

 The circuit breaker of the invention responds to the technical problems posed. The insertion is carried out by means of light devices not requiring damping means and authorizing reduced power commands. The diameter of the mobile assemblies is reduced, which allows the use of reduced diameter casings.

 The invention applies to circuit breakers with one or more breaking chambers per pole, of the conventional or shielded type.

Claims (3)

1 / High voltage circuit breaker with double movement comprising, for each phase, at least one breaking chamber delimited by an insulating casing (1) substantially cylindrical, filled with dielectric gas under pressure and inside which are arranged, so coaxial, a first movable assembly comprising in particular a main contact (14), an arcing contact (1515A) and a blowing cylinder terminated by a blowing nozzle (20) cooperating with a piston (18), said contacts (14, 15-15A) being connected to a first socket (2A), said first mobile assembly being mechanically connected to a first set of operating rods (4A), a second mobile assembly comprising a main contact (29) intended to cooperate with the main contact (14) of the first mobile assembly, an arcing contact (11-llA) intended to cooperate with the arcing contact (15-15A) of the first mobile assembly, said second mobile assembly being connected to a second setof operating rods (30) moving in the opposite direction to the first set of rods (4A), a resistor (5) arranged coaxially and of which a first end is electrically connected to the second socket (3A), characterized in that the contacts of the second mobile assembly are carried by a cylinder (22) at a first end (22A) from which the arcing contact (11-llA) of the second mobile assembly is fixed, said cylinder (22) internally containing a contact rod (33) sliding inside the cylinder, in electrical contact with the latter by first sliding contacts (43), opening at a second end (22B) of the cylinder and subjected to the action of a first spring (41) tending to bring it inside the cylinder, the outer end (33B) of the rod being able to cooperate electrically with a first set of contacts (35), fixed, electrically connected to the end of the resistance (5) opposite by the second socket (3A), said rod (33) comprising a means (63) for locking the end of said first set of contacts (35), this blocking ceasing when the force exerted by said first spring (41) on the rod (33 ) exceeds a given threshold, said cylinder (22) being in electrical contact by second sliding contacts (47) with a conductive slide (45) disposed externally and coaxially with said cylinder (22), said slide being subjected to the action of a second spring (60) tending to eject it from the cylinder, said slide being provided with means (45A, 25) for limiting its travel along the cylinder, said slide carrying a second set of contacts (50) cooperating with a third set of contacts (52) fixed to fixed conductive arms (54) connected to the second socket (3A), the dimensions of the various components being chosen so that the second (50) and third (52) sets of contacts are, when the circuit breaker is in the tripped position, sep arés a distance (d2) at least equal to the isolation distance corresponding to the voltage of the chamber, the aforementioned force being chosen according to the speed of movement of the movable assemblies so that the rod (33) is maintained by the first contact (35), against the action of the first spring (41), during a closing circuit breaker maneuver, during the chosen duration of insertion of the resistor (5). 2 / A circuit breaker according to claim 1, characterized in that said locking means is constituted by a groove (63) formed in the contact rod (33) and cooperating with the contact end of said first set of contacts (35). 3 / Circuit breaker according to claims 1 and 2, characterized in that the second movable assembly is guided by an insulating cone (56) fixed to the end of the arms (54).