NO314327B1 - Connection device for electrical connection of two gas insulated high voltage chambers - Google Patents

Abstract

A coupling device for electrically connecting two gas-insulated switch mechanism chambers intended for high voltage comprises an insulating sleeve (24), which coaxially surrounds a coupling contact (16), which is formed by a rigid, central pin (18), on which it is hinged two retractable tulip fingers (20,22). The length of the pin (18) corresponds to the distance between the two chambers, and each retraction tulip finger (20,22) extends over the entire distance of the blunt cone-shaped contact portions of the sleeve (24) inside sockets (26,28) with corresponding shapes. The flexible insulating material of the sleeve (24) is at the level of the coupling area of the coupling contact (16), reinforced with inserts (34, 36) by reinforcing means formed either by an inner core with a larger hardness than the hardness of the sleeve (24). or by placing the indentation tulip fingers (20,22) without radial clearance in the cylindrical inner surface of the sleeve (24), or by covering or molded tubes (54,56) made of an insulating or conductive material.

Description

The invention relates to a coupling device for the electrical interconnection of two chambers which contains an electrical high-voltage switch mechanism which is the chamber in two tight metal capsules which are filled with an insulating gas, in particular sulfur hexafluoride, and comprising: - a coupling contact which at its opposite ends interacts with a pair of inserts made of a conductive material, which are covered by insulating bushings which are fixed leak-tight in two adjacent openings in metal partitions of the two capsules, - an insulating sleeve made of elastomeric material, and which surrounds the coupling contact and the coupling inserts and has two truncated cone-shaped contact parts, which abut against the correspondingly shaped inner surface of the bushings, - and means for strengthening the insulating sleeve at the level of the area for the connection of the coupling contact with the inserts for counteracting internal electrical flashovers.

A known device of this type is described in FR-A-I 362 997, EP-A 199 249, EP-A 199 208 and EP-A 520 933. The coupling contact is formed either by an elongated, tubular element which is connected to the coupling inserts or by a set of male and female connectors arranged in the middle area. The sleeve, which is made of a flexible elastomer, can be reinforced by a conductive metal tube that runs coaxially around the coupling contact. A known device of this type is suitable for two capsules that have well-aligned coupling inserts, which necessitates very small manufacturing tolerances. If the axial alignment of the mellon inserts and bushings is poor, the electrical coupling is exposed to mechanical stresses with a risk of premature wear of the coupling device.

The purpose of the invention is to achieve a reliable connection device between two high-voltage capsules with high dielectric resistance.

The coupling device according to the invention is characterized in that the coupling contact is composed of a rigid, central pin which is made of a conductive material with an axial length that approximately corresponds to the separation distance between the two chambers, and two retracting tulip fingers which are articulated at opposite ends of the central pin and extends over the entire length of the frustoconical contact parts of the sleeve and of the reinforcement means.

According to a particular embodiment, the reinforcing means comprise an inner core covered by the insulating sleeve made of a flexible elastomeric material, the material of the core being conductive and having a hardness greater than the hardness of the material of the sleeve. The thickness of the core is less in the central portion surrounding the pin of the coupling contact to preserve the flexibility of the sleeve should an error occur regarding the axial alignment of the inserts.

According to a preferred, alternative embodiment, the reinforcement means are formed by fitting or placing the cylindrical retracting tulip fingers without radial clearance in the inner surface of the sleeve, which is covered by a coating of a conductive paint to achieve a uniform distribution of the electric field . The two retracting tulip fingers are hinged on ball joints which are provided at the ends of the central pin of the coupling connector.

Other advantages and features will appear more clearly from the following description of three design examples with reference to the drawing. Fig. 1 shows a schematic cross-section through a coupling device according to the invention. Fig. 2 shows a cross-section similar to that shown in fig. 1, through an alternative embodiment example.

Fig. 3 shows a cross-section through an alternative design example.

As shown in fig. 1 is a switching device 10 with a full insulation and a rectified field placed between two high-voltage chambers for switch mechanisms. The active part of each chamber is the space in a sealed metal capsule containing an insulating gas, particularly air or sulfur hexafluoride SF6. A connection is made on the side of the capsules through two metal partitions 12, 14 and must be leak-proof to prevent leaks. The coupling device 10 comprises a movable coupling contact 16 which is divided into three parts and comprises a conductive and rigid central pin 18 which carries two retracting tulip fingers 20, 22 at their opposite ends. The movable contact 16 is arranged in a sleeve 24 which is made of a flexible elastomeric material which is placed in hollow bushings 26, 28 which are made of epoxy resin and which are of the one-pole or three-pole type. The sleeve 24, which is made of an elastomeric material, is provided with two truncated cone-shaped contact parts which are brought into contact with the bushings 26, 28, and an intermediate connection part with a reduced cross-section.

The bushings 26, 28 are attached to the partitions 12, 14 of corresponding capsules either by means of a number of screws or a nut 30. The tightness at the level of each capsule is obtained by means of an o-ring 32 which is pressed onto the capsule. A conductive insert 34, 36 is molded into or covered by each bushing 26, 28 and provides the connection between the movable contact 16 and the busbar of the adjacent chambers, the nominal current flowing through this insert. Each insert 34, 36 is provided with a contact with a chamfered or conical entrance to facilitate plugging in, even if the alignment of the two chambers is not perfect.

The bushings 26, 28 may comprise metal shields which are covered with resin to improve the distribution of the electric field when a current flows.

In order to prevent electrical flashovers at the level of the coupling device 10, the frustoconical portions of the sleeve 24 are compressed by the bushings 26, 28 at the level of the mutual connection or engagement 38. For this purpose, the sleeve 24 must be reinforced by means of reinforcements that affect the internal diameter and the length that is inserted into the bushings 26, 28.

In the embodiment shown in fig. 1, the mechanical strength is obtained by placing or molding the sleeve 24 of a flexible elastomeric material on a core 40 which is made of a harder elastomeric material. The core 40 has a smaller thickness at the middle part to maintain the flexibility of the whole assembly.

The elastomer material of the sleeve 24 is insulating, while the elastomer material of the core 40 is conductive. The conductive pin 18 of the coupling contact 16 is set to the potential of the core 40 by means of an annular projection 42 which is brought into contact with the cylindrical side surface of the central pin 18.

The length of this central part 18 mainly corresponds to the length of the intermediate connecting part of the sleeve 24.

A grounded, semi-conductive layer 44 is deposited or cast on the outside of the intermediate portion of the sleeve 24, thus forming a rectified-field assembly which is insensitive to external contamination.

The two retracting tulip fingers 20, 22 of the movable contact 16 are hinged on the ends of the pin 18, so that they can move if the two chambers are badly aligned.

As shown in fig. 2, the reinforcement means of the sleeve 24 are formed by the cylindrical retracting tulip fingers 20, 22 which are arranged without radial clearance in the inner diameter of the sleeve 24 to secure it. The two retracting tulip fingers 20, 22 are preferably mounted on ball joints 46, 48 which are arranged on opposite ends of the conductive pin 18 of the movable contact 16.

The inner surface of the sleeve 24 according to the embodiment shown in fig. 2, is covered by a coating of a conductive paint 50 to achieve a uniform distribution of the electric field when a current flows in the movable coupling contact 16.

In the two design examples according to fig. 1 and 2, the rigid, central part 18 of the coupling contact 16 extends substantially over a length corresponding to the separation distance between the two chambers.

According to fig. 3, the sleeve is stiffened by means of a tube 54, 56 which is made of an insulating or conductive material, and which is connected to the phase potential, the tube being covered by or embedded or glued in the elastomer material on each side of the sleeve 24.

Claims (6)

1. Coupling device for the electrical interconnection of two chambers which contains an electrical high-voltage switch mechanism which is the chamber in two tight metal capsules which are filled with an insulating gas, in particular sulfur hexafluoride, and comprising: - a coupling contact (16) which at its opposite ends interacts with a pair of inserts (34,36) made of a conductive material, which are covered by insulating bushings (26,28) which are fixed leak-tight in two adjacent openings in metal partitions (12,14) of the two capsules, - a insulating sleeve (24) which is made of elastomeric material, and which surrounds the coupling contact (16) and the coupling inserts (34,36) and has two truncated cone-shaped contact parts, which rest against the correspondingly shaped inner surface of the bushings (26,28), - and means for strengthening the insulating sleeve (24) at the level of the area for the connection of the coupling contact (16) with the inserts (34,36) for counteracting the effect of internal electrical flashovers, characterized in that the coupling contact (16) is composed of a rigid, central pin (18) which is made of a conductive material with an axial length which approximately corresponds to the separation distance between the two chambers, and two retracting tulip fingers (20,22) which are the joint on opposite ends of the central pin (18) and extends over the entire length of the frustoconical contact parts of the sleeve (24) and of the reinforcement means. 2. Coupling device according to claim 1, characterized in that the reinforcing means comprise an inner core (40) which is covered by the insulating sleeve (24) which is made of a flexible elastomeric material, the material of the core (40) being conductive and having a hardness that is greater than the hardness of the material of the sleeve (24). 3. Coupling device according to claim 2, characterized in that the thickness of the core (40) is smaller in the central part surrounding the pin (18) of the coupling contact (16) in order to preserve the flexibility of the sleeve (24) should an error occur regarding the axial alignment of the inserts (34, 36). 4. Connecting device according to claim 1, characterized in that the reinforcement means are formed by fitting or placing the cylindrical retracting tulip fingers (20,22) without radial clearance in the inner surface of the sleeve (24), which is covered by a coating of a conductive paint (50) to achieve a uniform distribution of the electric field. 5. Connecting device according to claim 1, characterized in that the two retracting tulip fingers (20,22) are hinged on ball joints (46,48) which are arranged at the ends of the central pin (18) of the coupling contact (16). 6. Connection device according to claim 1, characterized in that the reinforcement means comprise a tube (54,56) which is made of an insulating or conductive material, which is covered by or embedded or glued in the elastomer material on each side of the sleeve (24).