RU2479881C2 - Disconnector for switching device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to a switching device, comprising a disconnecting mechanism (10) for detachable connection of the first (12) and second (14) movable tube of current flow path and control of transfer of electric current between them. The switching device comprises a system (26) of transmitting contacts for transfer of electric current from a rotary end rod (30) into the first movable tube (12) of the current flow path. The system (26) of transmitting contacts comprises at least one flexible woven conductor (36), rigidly fixed on both ends on the first tube (12) of the current flow path. The flexible woven conductor (36) is additionally in rigid contact with the specified end rod (30) in the intermediate point along the length of the flexible woven conductor (36) between its ends.

EFFECT: simplified design and assembly of components, increased throughout capacity by current of a system of transmitting contacts due to provision of maximum surface scattering of heat.

6 cl, 4 dwg

Description

This invention relates to switchgears, in particular to a horizontal disconnecting central opening mechanism for a switching device.

The disconnector is a node that, when installed in a switchboard box, has the function of breaking the voltage supply line to the switchboard when the disconnector is open, thereby isolating the switchboard from power supply. A conventional known type of disconnector comprises a horizontal system having a detachable current path including a pair of movable tubes or knives. Two movable knives are detachably connected to each other and can take two positions, namely, a closed position in which the knives are in electrical contact with each other through the main contact system, and an open position in which two knives are rotated around an axis perpendicular to their length so that the electrical contact between them is broken. The disconnector assembly also includes a pair of switching contact systems for connecting movable knives at each end, for supplying electricity and for distributing busbars of the switchboard.

In the conventional conventional horizontal central opening disconnecting mechanism, the main contact system consists of socket contacts provided on one of the movable blades containing coil springs (usually made of stainless steel) to provide positive contact pressure for current transfer, as well as to ensure proper contact for perception electrodynamic forces during the passage of the emergency current flow in the system. Socket contacts are located in a movable knife, which is made mainly of aluminum alloy. The pin contact is provided on another movable knife and is formed of two copper sheets and coated with a layer of silver to improve the conductivity and thermal resistance of the contacts. However, this existing design of the main contact system has several drawbacks. During the operation of opening and closing the disconnector, the contacts rub against each other during the movement of the contacts and require lubrication to withstand friction. If lubrication is not carried out at frequent intervals, the silver layer erodes, causing contact damage. In addition, the stainless steel coil springs used in the system also adversely affect the operation of the main contact system, because if the springs are constantly engaged for some reason for a certain period of time, then the contact pressure disappears, causing a temperature rise, which leads to to burning the contact system itself.

In the case of a switching contact system, the existing design provides a rotatable end contact plug with a flat spring that exerts pressure on the end pin (usually made of copper) to ensure proper contact for current transfer. In this case, the contacts are usually coated with silver and during the pivoting movement during the opening and closing operations of the disconnector, the silver surface rubs against the end rod. Therefore, it is necessary to maintain the correct pressure of the contacts on the end rod, in the absence of which the silver layer existing on the end rod, as well as on the end plug, erodes, which reduces the thermal stability of the contacts and increases the temperature rise above the specified limits at the transfer point. Therefore, in the absence of lubrication of the switching contacts at frequent intervals, the contact surface is subjected to severe friction, causing damage to the silver coating of the contacts, which reduces the ability to work and the service life of the contacts.

An object of the present invention is to provide a switching device having an improved disconnecting mechanism.

This goal is achieved using a switching device having a disconnecting mechanism for detachable connection of the first and second tube of the current path for a controlled switching of electric current between them, while the specified switching device contains:

- a system of switching contacts for switching an electric current from a rotary end rod to a first movable tube of a current path, wherein said system of switching contacts further comprises at least one flexible braided conductor rigidly fixed at both ends on said tube of a current path, wherein said at least one flexible braided conductor is additionally in fixed contact with said terminal rod at a point along its length, intermediate th between the indicated ends.

The idea underlying the invention is to provide a switching device having a horizontal central opening disconnecting mechanism in which the switching contact system does not have a relative pivoting movement between the switching contacts. According to this invention, the current is transmitted through at least one flexible braided conductor, which is rigidly fixed to the movable tube of the current path and to the end rod.

In one embodiment, said at least one flexible braided conductor is made of copper and comprises a tin coating. This provides, in particular, improved conductivity of the flexible braided conductor.

In another embodiment, the switching device comprises several flexible braided conductors rigidly fixed at both ends on said first movable tube of the current path using tin-coated eyes. This improves the current carrying capacity of the switching contact system.

In a preferred embodiment, said end shaft is made of aluminum alloy. This preferably ensures that silver coating is not required on the end rod and the movable tube of the current path, and therefore the cost of the material and coating is reduced.

In a particularly preferred embodiment, the switching device comprises a main contact system for electrically connecting said first and second tubes of the current path, the main contact system further comprising:

- socket contact interface connected to the first movable tube of the current path and containing a pair of contact fingers, and

- a pin contact interface connected to the second movable tube of the current path and containing a contact block having a circumferential groove around its surface, designed to provide two contact points for transmitting electric current to the socket contact interface.

This design eliminates the need for coil springs, and thereby prevents damage due to improper operation of the springs.

In another embodiment, said contact fingers and contact block are made of copper and coated with a material containing silver or graphite, or combinations thereof. Silver and graphite coating improves the conductivity and lubrication of the contacts themselves, respectively.

The following is a detailed description of embodiments of the present invention with reference to the accompanying drawings, which are schematically depicted:

FIG. 1 is a switching device having a horizontal disconnecting central opening mechanism in a front view;

FIG. 2 is a section through a system of switching contacts of said horizontal disconnecting central opening mechanism;

FIG. 3 is a socket contact interface of a main contact system of said horizontal disconnecting central opening mechanism, in a plan view;

FIG. 4 is a socket interface of a main contact system of said horizontal disconnecting central opening mechanism, in a front view.

As shown in FIG. 1, the disconnector 10 for the switching device has tubes 12 and 14 of the current path. In the shown example, the tubes 12 and 14 of the current path are made of aluminum alloy and have a rectangular cross-sectional profile. In an alternative embodiment, the movable knives 12 and 14 may also be made of copper alloy. The movable knives 12 and 14 are detachably connected to each other and are able to rotate around the axes 19 and 20, respectively, to occupy two positions, namely a closed position and an open position. In FIG. 1 shows a closed position in which the movable knives 12 and 14 are in electrical contact with each other through the main contact system 16. In the open position, the movable knives 12 and 14 are rotated around the axes 19 and 21, respectively, in the direction shown, so that the electrical contact between them is broken. The main contact system 16 comprises a female contact interface 18 mounted on the movable knife 12 with pins 24, and a pin contact interface 20 mounted on the movable knife 14 with pins 22. Each of the movable knives 12 and 14 is connected to the electrical network and to the distribution buses via contact switching systems 26 and 28 having pivoting end rods 30 and 32, respectively. In the shown embodiment, the end rods 30 and 32 extend upward from the movable knives 12 and 14 and are each additionally connected to a rotary block (not shown) designed to rotate the end rods 30 and 32 around the axes 19 and 21, respectively. Each pivot unit (not shown) includes a pivot mechanism, typically comprising two ball bearings, designed for high mechanical loads.

In FIG. 2 is a cross-sectional view of a switch contact system 26 to illustrate its components. It will be appreciated that a similar description applies to the system 28 switching contacts. As shown in FIG. 4, the switching contact system 26 is partially enclosed in a housing 42, which is fixed to the movable knife 12 with pins 43 and 45. The end rod 30 is insulated with bushings 39, typically made of nylon. In the switching contact system 26, current is transmitted from the pivoting end bar 30 to the movable knife 12 using one or more flexible braided conductors 36. In the shown embodiment, the flexible braided conductor 36 is made of copper and contains a tin coating. Unlike existing designs, silver plating is not required in this embodiment. Silver plating in existing structures is associated with the additional cost of the material. Therefore, in this embodiment, there is no erosion, which usually occurs in a silver coating. In addition, the end shaft 30 in the shown example is made of aluminum alloy, therefore, a silver coating is not required, which further reduces the cost of the material.

A single or multiple flexible braided conductors may be provided depending on the required current strength. Flexible braided conductors 36 are rigidly fixed at both ends to the movable knife 12 using tin-coated eyes 38 and 40. Flexible braided conductors 36 extend mainly with a horizontal orientation, extending upward to form hard contact with the end shaft 30 through the washer 41. In the shown embodiment the point of hard contact of the flexible braided conductor 36 with the end rod 30 is approximately in the middle of the length of the flexible braided conductor 36. This provides two parallel paths for transmitting current between the end th rod 30 and the movable knife 12, which improves the ability of the current transmission system 26, the switching contacts. This design using flexible braided conductors ensures that the switching contact system 26 does not have a relative pivoting movement between the switching contacts (between the end shaft 30 and the conductors 36, and between the conductors 36 and the movable knife 12). The above design preferably allows for easy assembly of components and cheaper manufacturing, eliminating the need for CNC machines. In addition, the design provides maximum surface heat dissipation. Unlike existing designs, in the shown embodiment, there is no need for end plugs or other contact pressure, since both ends of the flexible braided conductors 36 are rigidly fixed. In addition, the conductors 36 are flexible, spiral springs are not required, which eliminates manufacturing inconsistency or damage to the switching contacts.

The components of the main contact system 16 are shown in FIG. 3 and 4. As shown in a plan view in FIG. 3, the socket contact interface 18 comprises fingers 50 and 52 inserted into finger blocks 53. Contact fingers 50 and 52 are typically made of copper. As shown in a front view in FIG. 4, the pin contact interface 20 includes a contact block 54, which is inserted between the contact fingers 50 and 52 during the operation of closing the disconnector. The pin contact unit 54 has a V-shaped groove in its circumference, so that the contact unit 54 has two contact points 56 and 58 for transmitting current to each finger when the disconnector is in the closed position. The pin contact block 54 may also be made of copper. The contact fingers 50 and 52 and the pin contact block 54 can be coated with silver and graphite to improve the conductivity and lubrication of the contacts themselves, respectively. The foregoing preferably reduces the maintenance costs of the main contact system. In addition, in the shown embodiment, stainless steel coil springs are not required, and therefore damage due to improper operation of the springs is excluded.

As a conclusion, it should be noted that this invention relates to a switching device having a disconnecting mechanism for releasably connecting the first and second movable tube of the current path to control the transmission of electric current between them. The switching device comprises a system of switching contacts for transmitting electric current from the rotary end rod to the first movable tube of the current path. The switching contact system comprises at least one flexible braided conductor rigidly fixed at both ends on the first tube of the current path. The flexible braided conductor is additionally in hard contact with the end rod at a point along its length intermediate between the ends.

Although a description of the invention has been made with reference to specific embodiments, this description should not be construed as limiting. Various modifications of the disclosed embodiments, as well as alternative embodiments, will become apparent to those skilled in the art after reading the description of the invention. Therefore, such modifications should be considered as included in the idea and scope of the invention defined by the claims.

Claims (6)

1. A switching device having a disconnecting mechanism (10) for detachably connecting the first (12) and second (14) movable tube of the current path to control the transmission of electric current between them, wherein said switching device comprises:
a system of transmitting contacts (26) for transmitting electric current from the rotary end rod (30) to the first movable tube (12) of the current path, said system of transmitting contacts (26) additionally containing at least one flexible braided conductor (36) rigidly fixed at both ends on the first tube (12) of the current path, wherein said flexible braided conductor (36) is further in hard contact with said end rod (30) at a point along its length, in the middle between said ends . 2. The switching device according to claim 1, wherein said at least one flexible braided conductor (36) is made of copper and contains a tin coating. 3. A switching device according to any one of claims 1 or 2, containing several flexible braided conductors (36), rigidly fixed at both ends to the indicated first movable tube (12) of the current path using tin-coated eyes (38, 40). 4. The switching device according to claim 1, wherein said end rod (30) is made of aluminum alloy. 5. The switching device according to claim 1, further comprising a main contact system (16) for electrically connecting said first (12) and second (14) movable tubes of the current path, said main contact system (16) further comprising:
the socket contact interface (18) connected to the first movable tube (12) of the current path and containing a pair of contact fingers (50, 52), and
a pin contact interface (20) connected to the second movable tube (14) of the current path and containing a contact block (54) having a circumferential groove around its surface, designed to provide two contact points for transmitting electric current to the socket contact interface (18) . 6. The switching device according to claim 5, wherein said contact fingers (50, 52) and contact block (54) are made of copper and coated with a material containing silver or graphite, or combinations thereof.

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