RU94054U1 - DISCONNECTOR - Google Patents

Abstract

 1. The disconnector containing the frame, the insulators and mounted on top of at least one insulator contact knife, including a holder with holes for mounting to the insulator, the axis of the contact output, current-carrying knife, contact elements, characterized in that the current-carrying knife of the disconnector made integral with at least the holder in the form of a single monolithic structure. ! 2. The disconnector according to claim 1, characterized in that the current-carrying knife with a holder is made integral with the axis of the contact output. ! 3. The disconnector according to claim 2, characterized in that the axis of the contact terminal is reinforced in a holder. ! 4. The disconnector according to claim 1, characterized in that at least part of the contact elements is made integral with the current-carrying knife and holder. ! 5. The disconnector according to claim 1, characterized in that the current-carrying knife is made in the form of a spatial structure of two vertical plates with jumpers between them. ! 6. The disconnector according to claim 1, characterized in that in the current-carrying knife made places for attaching at least part of the contact elements. ! 7. The disconnector according to claim 1, characterized in that the holes in the holder for attachment to the insulator are oblong in the direction of the axis of the contact terminal. ! 8. The disconnector according to claim 1, characterized in that the current-carrying knife with a holder is made of current-carrying material, for example, aluminum alloy.

Description

The utility model relates to electrical engineering and can be used in high voltage disconnectors.

Known disconnectors containing a frame, a base with rotary shafts and plates, on which are mounted rotary support insulators. A contact knife with contact fingers on the free end of the contact knife is fixed on one insulator, a contact knife with an incoming contact is fixed on the other insulator, while the contact fingers and the incoming contact form a detachable disconnector contact. Each contact knife is a prefabricated structure and consists of a current-carrying knife mounted on a holder, an axis on which a movable contact terminal is mounted, and various contact elements: flexible electrical connection for connecting a current-carrying knife to a contact terminal, contact fingers or an incoming contact, as well as a fixed the earthing switch when making the disconnector with the earthing switch. The contact knife is attached to the upper flange of the insulator with bolts passing through the holes in the holder. The axis of the contact terminal is fixed motionless on the holder coaxially with the longitudinal geometric axis of the insulator. The current-carrying knife, depending on the current and voltage of the disconnector, can be made in the form of one plate installed flat, in the form of two plates installed on the "edge", in the form of a pipe, etc. (V.V. Afanasyev, E.K. Yakunin "Disconnectors", L., "Energy", 1979, fig. 1-14, 1-15, 3-10, p.130-133).

The disadvantage of such disconnectors is that they have a large number of parts and sufficient complexity, due to the fact that their production requires various technologies and assembly by mechanical assembly with the appropriate adjustment of various elements and, as a result, increased consumption of materials and labor costs. A large number of parts from various materials with different coatings also objectively reduce the reliability of the disconnectors.

The objective of this utility model is to create a disconnector, structurally less complex and more technological in manufacturing, reduced labor and material consumption, increased reliability in operation.

The solution to this problem is achieved by the fact that in a known disconnector containing a frame, insulators and mounted on top of at least one insulator contact knife, including a holder with holes for mounting to the insulator, the axis of the contact output, the current-carrying knife, and contact elements , according to the utility model, the current-carrying knife of the disconnector is made integral with at least the holder in the form of one monolithic structure. In the disconnector, the current-carrying knife with the holder can be made integral with the axis of the contact output. In addition, the axis of the pin can be reinforced into a holder. In the disconnector, at least part of the contact elements can be made integral with the current-carrying knife and holder. The current-carrying knife can be made in the form of a spatial structure of two vertical plates with jumpers between them. In addition, in the current-carrying knife can be made places for mounting at least part of the contact elements. The holes in the holder for mounting to the insulator can be made oblong in the direction of the axis of the contact output. The current-carrying knife with a holder can be made of current-carrying material, for example, aluminum alloy.

Figure 1 shows the disconnector, General view; figure 2 - contact knife with contact fingers; figure 3 is the same as in figure 2, a top view.

The disconnector comprises a frame 1, on which bases 2 are fixed, in which rotary shafts with plates 3 are mounted. Two support-rotary insulators 4 are attached to the plates 3 (as a special case, the disconnector for small voltages up to 110 kV can have only one support-rotary insulator )

On the insulators 4, a contact knife 5 with contact fingers 6 and a contact knife 7 with an incoming contact 8, forming a detachable contact of the disconnector, are installed.

Contact knife 5 consists of a current-carrying knife 9 and a holder 10, made at the same time in the form of a single monolithic structure, for example, from an aluminum alloy, which is a good current-carrying material with high mechanical strength. In the holder 10 there are holes 11 for attaching the entire contact knife 5 to the insulator 4. To be able to use the contact knife 5 on various insulators 4, the holes 11 in the holder 10 can be oblong in the direction of the axis 12 of the contact terminal 13, which increases the versatility of this design contact knives. In this case, the current-carrying knife 9 with the holder 10 can be made integral with the axis 12 in the form of a single monolithic structure, for example, by casting from an aluminum alloy. The axis 12 can be made of steel or other material and reinforced in the holder 10 when casting parts.

On the current-carrying knife, contact points 14 and 15 (surfaces) are made for various contact elements: at one end of the current-carrying knife 9 for installing contact fingers 6, at the other end, for attaching a flexible electrical connection 16, which serves for electric connection of the current-carrying knife 9 with the contact output 13. On the current-carrying knife 9, places 17 can also be made for the fixed contact of the ground electrode in the case of a disconnector with ground electrodes.

An input contact 8 is installed on the current-carrying knife 9 of the contact knife 7 at its free end. In this case, the incoming contact 8 itself can be made of aluminum alloy, like the entire current-carrying knife 9, with the exception of contact surfaces, which can be additional coated with copper, tin, nickel or silver, etc.

The current-carrying knife 9 can be made of various shapes: for small currents and voltages in the form of a plate (plate knife), for currents of 1000 A and above - of a spatial structure of two vertical plates 18 with jumpers 19 between them, in the form of a channel, etc. with a good heat sink. Such knives can be made for disconnectors for rated currents up to 4000 A and voltages up to 220 kV. Current-carrying knife 9 can be made of aluminum alloy having good electrical and mechanical, as well as casting properties. For small currents (up to 800 A) it can be made of brass.

At the same time, brackets, protrusions, etc. can be made with a current-carrying knife during casting. for fastening other elements of the disconnector: deicing casings, screens, etc.

The disconnector operates as follows. Electric current flows from the power line to terminal 13, via flexible electrical connection 16 to current-carrying knife 9, to contact fingers 6 of contact knife 5, then to incoming contact 8 of contact knife 7, via current-carrying knife 9, flexible electrical connection 16, to contact pin 13, then to the power line. In order to prevent the occurrence of parasitic parallel currents along axis 12 (especially during short circuits to prevent welding of terminal 13 to axis 12), a rotation along the insulating and anti-friction coating, or a special insulating sleeve, can be arranged in the contact terminal-axis connection, which will increase the reliability of the node.

The manufacture of a disconnector with a current-carrying knife, made integral with the holder and contact elements in the form of a single monolithic design by casting in a mold (fixture), in particular, of aluminum alloy, automatically eliminates the curvature of the current-carrying knife, allows for the necessary parallelism of surfaces, eliminates many parts and, accordingly, mechanical, stamping and assembly operations, their coatings and part of the adjustments. This allows to reduce the consumption of materials and labor costs in the manufacture of the disconnector. The above circumstances can improve the reliability of contact knives and, as a consequence, the entire disconnector.

ZETO CJSC tested a sample of a 110 kV, 1600 A disconnector according to this utility model, which yielded positive results.

Claims (8)

1. The disconnector containing the frame, the insulators and mounted on top of at least one insulator contact knife, including a holder with holes for mounting to the insulator, the axis of the contact output, the current-carrying knife, contact elements, characterized in that the current-carrying knife of the disconnector made integral with at least the holder in the form of a single monolithic structure. 2. The disconnector according to claim 1, characterized in that the current-carrying knife with a holder is made integral with the axis of the contact output. 3. The disconnector according to claim 2, characterized in that the axis of the contact terminal is reinforced in a holder. 4. The disconnector according to claim 1, characterized in that at least part of the contact elements is made integral with the current-carrying knife and holder. 5. The disconnector according to claim 1, characterized in that the current-carrying knife is made in the form of a spatial structure of two vertical plates with jumpers between them. 6. The disconnector according to claim 1, characterized in that in the current-carrying knife made places for attaching at least part of the contact elements. 7. The disconnector according to claim 1, characterized in that the holes in the holder for mounting to the insulator are oblong in the direction of the axis of the contact terminal. 8. The disconnector according to claim 1, characterized in that the current-carrying knife with a holder is made of current-carrying material, for example, aluminum alloy.