FR3104807A1 - Switch / circuit breaker-disconnector for electrical distribution networks greater than 3.6KV, with cutting and closing of currents in a vacuum interrupter and insulation without SF6. - Google Patents

Abstract

Electrical switchgear device for electrical distribution networks greater than 3.6KV, with cutting and closing of currents in a vacuum interrupter and insulation without SF6. The invention applies to the production of electrical distribution equipment, in particular secondary, switch-disconnector and circuit breaker-disconnector without SF6, using a low-power insulating fluid with a greenhouse effect for the insulation and a vacuum interrupter used. transiently for the interrupting and switching on currents function. The invention consists, during the change of state of the position of the disconnector, in temporarily inserting a vacuum interrupter external to the disconnector device through a switching electrode, and excluding it from the circuit in the two stable positions of the switch. 'apparatus. The disconnector function is performed by solutions based on conductive knives movable in rotation or by a movable tube in translation in air or any other dielectric in a sealed enclosure. Figure for the abstract: Fig 2

Description

Switch/circuit breaker-disconnector for electrical distribution networks above 3.6KV, with breaking and closing of currents in a vacuum interrupter and insulation without SF6.

As part of the reduction in the use of greenhouse gases, electrical distribution equipment, which overwhelmingly uses SF6 gas as an insulating and arc extinguishing agent, will in the near future have to be replaced by new solutions without SF6.

The object of the invention is to provide a solution to this problem by means of circuit breaker electrical equipment, generally three-phase switches, the breaking and closing of short-circuit and permanent currents of which are carried out by a vacuum interrupter and the passage of the permanent current. and isolation between input and output by a disconnector, the vacuum interrupter being temporarily inserted during the change of state of the disconnector and isolated from the circuit in the two stable open/closed positions of the circuit breaker-disconnector. All the power arcs are confined in the vacuum interrupter, the switchings in the insulation fluid are carried out at iso-potential or without current, do not influence the quality of the insulation solutions either of the materials or of the fluid used .

In the following, we will denote circuit breaker-disconnector for all the different functions that can be performed circuit breaker, circuit breaker-disconnector, switch, switch-disconnector. The descriptions are limited to one phase of the device which may be multipolar.

State of the art
Current vacuum circuit breakers are poorly suited to these architectures because they require the addition of a disconnector in series requiring two mechanisms and their safety interlocking to ensure the input-output isolation function, an electrical function which cannot be ensured by a solution. continuity in vacuum according to IEC or other standards.

Solutions have already been the subject of patent filings in particular for circuit breaker applications (patents DE1265815B and JPS54183671) or such as the French patent FR 2980632 adapted only to switch functions, but limiting the use of the vacuum bulb only to breaking currents and leaving power arcs in the insulating fluid and the associated environmental constraints.

The invention, adapted for primary and secondary electrical distribution circuit breaker-disconnector, supplements and enriches that of French patent FR 3077921 based on a rectilinear movement of the cylindrical mobile assembly of the disconnector function, which can concentrically integrate the vacuum interrupter solution suitable for high intensity devices such as generator or very high voltage circuit breakers.

Exposed
The invention relates to circuit breaker-disconnectors whose disconnector function is performed by a rotary movement of the movable assembly (11) of the disconnector function. and [Fig 2], and for applications where the vacuum interrupter (5) is placed outside the disconnector function, in particular in the case of a rectilinear movement of the movable assembly of the disconnector function [Fig 3] .

The invention uses a conventional disconnector function in the field of the art with conductive blades making up the mobile assembly (11) of the disconnector function. The conductive blades making up the mobile assembly (11) rotate around a fixed point linked to the current inlet (4) ensuring, in the open position, a solution of continuity in the insulating fluid between the current inlet (3) and the blades (11) to ensure the isolation function of the disconnector and in the closed position, the electrical connection between the two current inputs (3) and (4) through their sliding contacts (6) and (12 ) with the conductor blades of the moving assembly (11) ensuring the transport of electrical energy.

During the transitory period of passing from one state to the other during an opening or closing operation, the conductive blades of the movable assembly (11) will connect to the switching electrode (9) allowing to insert the vacuum interrupter (5) into the circuit and produce the electrical diagrams with the moving contact of the vacuum interrupter, (Vacuum interrupter open) and (Vacuum interrupter closed) of the . The profile of the cam (16) makes it possible to ensure synchronism between the opening and closing of the contacts of the vacuum interrupter (5) with the position of the movable assembly (11) of the disconnector function as described by the 2 space-time curves of [Fig 4].

The fixed switching electrode (9) has a specific crescent profile to ensure the dielectric strengths during the transient period of insertion of the vacuum interrupter between the switching electrode (9) and the current input (3) and sections determined to ensure the various electrical current flow constraints. In [Fig 2], the switching electrode (9) has variable sections making it possible to ensure the electrical contacts between the mobile assembly (11) and the electrode in its zone (9a) and to be disconnected in the zone (9b) making it possible to reduce the mechanical forces and ensure only electrical contact between the conductive blades of the moving assembly (11) with the current input (3).

The drive of the cam (16) operating the moving contact of the vacuum interrupter and that of the moving assembly (11) is achieved by a single motor shaft (20) connected to the operating member, but it is conceivable to use a secondary shaft to operate the cam (16) connected to the motor shaft (20) by a conventional crank rod system or a gear system.

The invention makes it possible to ensure the containment of the power arcs both on closing and on opening of the circuit breaker-disconnector in the vacuum interrupter, all the phases of switching from the disconnector function to the circuit breaker function are carried out at same potential or no current in the insulating fluid.

The figures represent the diagram of one phase of each type of circuit breaker-disconnector.

There represents a circuit breaker-disconnector with rotary movement of the disconnector with a one-piece insulating shaft (20) supporting and driving in rotation the conductor blades of the movable assembly (11) of the disconnector function and integrating the cam (16) which through the insulating rod (13) actuates the moving contact of the vacuum interrupter (5).

There represents, a circuit breaker-disconnector with rotary movement of the disconnector, the mobile blades of the disconnector (11) are operated by a crank rod system (18) and (19) mounted on the motor shaft (20) which supports and drives the cam ( 16).

There represents a solution with rectilinear movement of the movable assembly (11) of the disconnector function and the vacuum interrupter (5) external to the disconnector function with a switching electrode (9) concentric externally to the movable assembly (11) , fixed on the insulating support (8) and connected to the movable contact of the vacuum interrupter (5) by the movable contact (7).

The active chamber according to the invention can operate in an insulating dielectric such as air or any other insulating fluid (gas or liquid) in a tight closed envelope.

detailed description
With reference to the drawings of & [Fig 2], the invention comprises a first device which provides the disconnector function, consisting of current inputs (3) and (4) isolated from the frame by insulating supports (1) and (2), a crew mobile (11) in rotation around a fixed point linked to the current input (4), driven by a one-piece shaft (20) in the case of [Fig 1] or by a lever (18) and connecting rod (19 ) Insulators in the case of [Fig 2], connected to a motor shaft (20) connected to the actuator not shown.

A second device performing the circuit breaker function, comprising a vacuum interrupter (5) mechanically supported by an insulating device (8) connected to the insulating support (1), connected to the current input (3) for its fixed contact, and for its moving contact through the moving contact (7) to a switching electrode (9) fixed to the insulating support (8), this switching electrode (9) performs several functions, depending on the position of the moving assembly (11):

1. Switching the current from the current input (3) to the vacuum interrupter (5)
2. Passage of the current from the vacuum interrupter (5) into the moving assembly (11) through sliding contacts (9a)
3. Short-circuiting of the vacuum interrupter (5) in the circuit breaker-disconnector closed position

The two devices are operated by a single motor shaft (20) which drives the mobile assembly (11) and a cam (16) whose adapted profile makes it possible to synchronize the movement of the mobile contact of the vacuum interrupter (5) with the positions of the mobile assembly (11) to obtain the electrical diagrams of the , thanks to the linear displacement of the insulating rod (13) connecting this cam (16) to the movable contact of the vacuum interrupter (5) guided in translation by the support (8).

There shows the closed and open positions of the circuit breaker, as well as the transient positions of the mobile assembly (11) during a change of state operation to ensure the transfer of current in the vacuum interrupter (5) through the switching electrode (9)

In the open position, the disconnector function and the insulation are ensured by a solution of continuity of the insulating fluid across the distance between the parts (11), (9), (3). It should be noted that the switching electrode (9) may be at a floating potential or at the potential of the current outlet (3) depending on the chosen space/time curve of the vacuum interrupter.

In the closed position, the moving assembly (11) connects the inputs-outputs (3) and (4) through the sliding contacts (6) and (12). The vacuum interrupter is totally short-circuited by the mobile assembly (11) by the electrical connection between the contacts (6) and the switching electrode (9), and supports no electrical and mechanical stress in normal operation.

In transient positions, on a closing operation, the mobile assembly is connected to the switching electrode (9), the profile of the cam (16) will allow, at this moment, to close the contacts of the bulb at (5), switching on the current in the vacuum interrupter, the moving assembly continuing its course until it comes into contact with the current input (3), the current is switched to the disconnector function, the interrupter vacuum (5) is short-circuited by the conductive blades of the moving assembly (11) in the stable circuit breaker-disconnector closed position.

In the , the switching electrode (9) has variable cross-sections to make it possible to reduce the friction forces by eliminating the contact between the switching electrode (9) and the conductive blades of the movable assembly (11) at the end of travel closure, making it possible to disconnect the vacuum interrupter from the circuit and to ensure the contact pressures of the sliding contacts (6) between the conductive blades of the mobile assembly and the current input (3).

The shape of the crescent-shaped switching electrode is defined to maintain an electric field between the current input (3) and the contour of the switching electrode (9) making it possible to ensure the dielectric withstand of transient restoration voltages (TTR) of the standards of the electrical equipment between the current input (3) and the switching electrode (9) as a function of the position of the mobile assembly (11).

There gives a representation of the invention on a disconnector base with a rectilinear movement of the movable assembly (11), the vacuum interrupter (5) external to the disconnector device is integral with an insulating support (8) which ensures the same functions as previously described, same for the cam (16), the motor shaft (20) and the switching electrode (9).

The cam (16) also makes it possible, thanks to a suitable profile, to integrate an earthing switch function into the disconnector function, by increasing the rotation of the disconnector function without involving the vacuum interrupter.

One quickly sees the interest of such a solution, it makes it possible to produce circuit breakers-disconnectors using any insulating fluid without electronegative power by confining the functions of switching on and breaking of the currents in a vacuum interrupter defined only by the transient conditions and not by the power rating and insulation conditions, limiting the number of bulb types which maximizes production volume and optimizes cost.

The invention makes it possible to carry out switch and circuit breaker-disconnector functions with the same dimensioning, the only variant of which will be the vacuum interrupter, the disconnector function remaining an invariant both in terms of components and dimensioning, simplifying the architecture of the substations and the use of a single operating device to design the circuit breaker-disconnector function.

Claims (5)

A circuit breaker-disconnector for breaking and closing currents in a vacuum interrupter operating in air or any other insulating fluid (gas or liquid) in a sealed enclosure, characterized
-by a first device providing the disconnector function comprising a single moving element (11) electrically linked to the current input (4) of the disconnector, which in the circuit breaker-disconnector closed position, connects the two current inputs of the disconnector function ( 3) and (4); which, in the circuit breaker-disconnector open position, ensures the dielectric withstand thanks to a solution of continuity in the insulating fluid used, between the mobile assembly (11) and the current input (3) of the disconnector function; which in transient position will be connected to a fixed switching electrode (9).
-by a second device providing the switch/circuit breaker function, external to the disconnector function, consisting of a vacuum interrupter (5) whose fixed contact is electrically connected to the current input (3) of the disconnector function, and by an insulating support (8) ensuring the positioning and the insulation of the vacuum interrupter (5) with respect to the elements of the disconnector and the mechanical positioning of the switching electrode (9) electrically linked to the movable contact (7) of the vacuum interrupter (5).
-by a fixed switching electrode (9) which temporarily provides the mechanical and electrical connection between the first device and the second device as a function of the relative position of the movable assembly (11).
-by a mechanical system for synchronizing the movements of the movable assembly (11) of the disconnector function and of the movable contact of the vacuum interrupter (5) by means of a cam (16) linked to the motor shaft (20) of the disconnector. A circuit breaker-disconnector according to claim 1 characterized by the mechanical synchronization system, which is linked to an operating member, consisting of a motor shaft (20), one-piece or equipped with a crank rod system (18) (19) , rotating the movable assembly (11) of the disconnector function and the cam (16) whose adapted profile makes it possible to maneuver, by the linear movement of an insulating rod (13), the movable contact of the bulb with vacuum (5) depending on the position of the moving assembly (11). A circuit-breaker-disconnector according to Claims 1 to 2, characterized in that the switching electrode (9) is crescent-shaped, determined to ensure a minimum electrical withstand field between the current input (3) and the switching electrode (9) making it possible to withstand the transient recovery voltage when the currents are cut. A circuit-breaker-disconnector device according to one of Claims 1 to 3, characterized in that the switching electrode (9) has variable cross-sections to make it possible to ensure, for a first zone (9a), contact between the switching electrode switching (9) and the conductor blades of the mobile assembly (11) and a disconnection of these same conductor blades in the second zone (9b) to ensure the quality of their electrical contacts with the current input (3). A circuit breaker-disconnector device according to one of Claims 1 to 4, characterized by a first motor shaft linked to the maneuvering member which drives the moving assembly (11) of the disconnector function and a secondary shaft linked to this motor shaft by a crank rod or gear system which rotates the cam (16).