RU2285968C2 - Method for manufacturing high-voltage bushing insulator - Google Patents

Abstract

FIELD: manufacture of column-shaped high-voltage bushing insulators.

SUBSTANCE: proposed bushing insulator has symmetrical hollow cylindrical external insulator 1 with lead-through head 2 supported by one of its butt-ends and designed for connection to high-voltage supply. Resting on opposite end of insulator is lead-through base 3 designed for connection to ground potential. Proposed method involves sequential fitting of lead-through base 3, external insulator 1, and lead-through head 2 on drawing frame 5; lead-through base 3 rests in this case on insulating case 6. Lead-through base 3 and lead-through head 2 are tightly fitted to one another through drawing frame 5 that mounts insulating case 6. Clamping member 21 made for shifting in axial direction is installed on flange 22 of lead-through head 2 prior to fitting the latter on drawing frame 5; head flange 22 and clamping member 21 are pressed against one another to produce pre-tensioning force. During next fitting of pre-tensioned lead-through head 2 clamping member 21 is secured on end of drawing frame 5 passed through insulator 1, and then clamping member 21 is taken off head flange 22 to form negative allowance.

EFFECT: enhanced economic efficiency in manufacturing high-voltage bushing insulator.

7 cl, 2 dwg

Description

FIELD OF THE INVENTION

The invention is based on a method for manufacturing a high voltage bushing according to the preamble of claim 1. Using this method, insulators made in the form of a column are made, which serve to pass a high-voltage conductor through the grounded wall of the housing, for example, a transformer. Such bushing insulators have a hollow cylindrical symmetrical external insulator, on one end side of which there is a bushing head adapted to be connected to the high voltage potential, and on the opposite end side there is a bushing base that is connected to earth potential. In addition, the bushing contains an extension tube passing along the axis of the cylinder through the outer insulator and mounted on the extension tube, the insulating casing controlling the field.

State of the art

In the restrictive part of paragraph 1 of the claims, reference is made to the method of manufacturing high voltage bushings, which has been used by the applicant for many years. At the same time, a passage base made in the form of a mounting flange, made of porcelain or an external shape-preserving plastic made of porcelain, and a passage head with a compression spring are mounted on the drawing tube in order. This lingering tube carries a field-insulating enclosure on which the passage base rests. Using a clamping tool, the pre-tensioned feed-through head is held against the external insulator. A nut is screwed onto the end of the lug tube passing through the bushing head and externally threaded to the stop in the bushing head. After removing the clamping tool, the lead-in head and the lead-through base are connected to each other with a power circuit through the lug tube and the insulating body and with the pre-tension determined by the compression spring, rest on the end faces of the outer insulator, so that the hollow space inside the outer insulator is sealed relative to the outer space and can be filled with insulating agent.

SUMMARY OF THE INVENTION

The invention, as defined in the claims, solves the problem of creating a method of the type indicated at the beginning, which provides a particularly cost-effective way of manufacturing high-voltage bushings with different sizes and characteristics.

In the method according to the invention, before fitting the feed-through head onto the lug tube, a clamping element is mounted on the flange of the feed-through head, the head flange and the clamping element are pressed against each other with the formation of a pre-tensioning force, with subsequent mounting of the pre-compressed feed-through head the clamping element is fixed to the broaching housing at the end of the broaching housing passing through the external insulator, and then the clamping element is removed from the head flange and with the formation of interference. These process steps provide a quick and economical manufacture of a high voltage bushing. There is no need to use an additional clamping device, as well as to prepare the passage heads that are relatively difficult and depend on the size and performed by the bushing insulators.

For technological reasons, it is advisable to install the clamping element on the head flange using a screw passing through the threaded hole in the head plate. In this case, you can very easily actuate the screw when installing the bushing. At the same time, in this case, the clamping element does not depend widely on the size of the bushing and can be used in the manufacture of bushing with any size.

By turning the screw while moving the clamping plate lying on the spring in the direction of the head flange, it is possible to quickly and reliably create the pre-tension required for installation with a screwdriver.

It is recommended that the previously threaded bore head provided on the clamping plate with an internal thread be screwed onto the external thread of the broaching housing as far as it will go into the external insulator. Due to this, it is possible, on the one hand, to use the external thread that is necessary for conventional manufacturing and therefore already existing, and at the same time there is no need for tools necessary otherwise for the manufacture of a preassembled passage head.

Then very simply you can finally mount the bushing. Using a screwdriver, loosen the screw and thereby automatically install on the external insulator the head flange and the passage through a pre-compressed spring, a pressure plate, a lug housing and an insulating housing fixed to the lug housing, controlling the field.

Since the mating thread for the screw is made in the form of a through threaded hole, the internal space of the bushing after removal of the screw can be filled through this hole with insulating means. Thus, there is no need to make an additional filling hole for the insulating means.

Reliable closing of the internal space of the bushing is ensured by closing the threaded through hole after filling the insulating material with a suitable sealed screw.

Brief Description of the Drawings

The following is a detailed description of the invention based on exemplary embodiments with reference to the drawings, in which:

figure 1 - manufactured using the method according to the invention, a high-voltage bushing with an axial section to the right of the longitudinal axis, side view and

figure 2 is a section of a pre-tightened feed-through head before installation in a high-voltage feed-through insulator according to figure 1.

Ways to implement the invention

In both figures, identical positions denote identically acting elements. The high voltage bushing shown in FIG. 1 is a column type and has a hollow cylindrical symmetrical external insulator 1. This insulator is made of a weather-resistant material, preferably plastic, based on a pipe made of fiber-reinforced multilayer material with silicone shielding or porcelain. On its upward facing end side, it carries a metal bushing 2 configured to be connected to a high voltage voltage. On its opposite downward facing end side, the external insulator rests on a metal bushing 3, which is adapted to connect to earth potential.

Along the vertically extending axis 4 of the outer insulator 1 is a cylindrical symmetrical metal broaching body 5, which, as shown, can be made in the form of a tube 5 or in the form of a massive pin. When it is made into a broaching housing in the form of a broaching tube 5, the latter serves to accommodate the high-voltage end of the cable, which is screwed electrically conductively to the upper end of the broaching tube. If the broaching housing is made in the form of a pin, then this pin can conduct current passing through the end of the cable.

On the outer surface of the broaching tube 5, a control field is fixed, preferably made in the form of a capacitor-type input, an insulating casing 6. The insulating casing 6 has an upper, made essentially cylindrical and a lower, made essentially conical section. The cylindrical section is located inside the external insulator 1 and serves to control the electric field of the passage insulator during operation through the lug tube 5 of the high-voltage conductor in the zone of the outer insulator 1 and the passage base 3. The conical section during operation of the passage insulator is located in the case of, for example, a transformer connected electrically in a conductive manner with the passage base 3, and controls the electric field of the conductor inside the housing, not shown in figure 1 and finding schegosya high voltage. Between the two sections, the field-controlling insulating body 6 comprises a step 7, on which the passage base 3 rests. Both ends of the broaching tube 5 are brought out of the inner space of the passage insulator. An external thread 51 is made at the upper end of the broaching tube 5, which interacts with two internal threads of the clamping element 21 of the passage head 2 and mounting device 8 for holding the end screw clamp of the passage insulator, which runs during operation, through the broaching tube, which is under high voltage of the conductor. At the lower end of the broaching tube 5, a spherical control electrode is fixed, which serves to align the electric field of the current path extended through the broaching tube 5.

For the manufacture of bushing, the bushing 3 and the outer insulator 1 are mounted in order on a lingering tube. In this case, the passage base 3 rests on the stop 7 of the control field of the insulating casing 6 and on the lower end side of the external insulator 1. Then, the passage head 2 is mounted on the drawing tube 5. When fitting the passage head 2 on the flange 22, the clamping element 21 is fixed so that between the clamping member 21 and the head flange 22 have a certain pre-tension force.

Figure 2 shows the design of the pre-tightened feed-through head 2. It is shown that in the flange 22 of the feed-through head there are two through threaded holes through which one of the two mounting screws 23 passes, and the clamping element 21 has a disk spring 24 adjacent to the head flange, and also compressing a disk spring 24, the pressure plate 25. The pressure plate 25 contains two unmarked, oriented in the direction of the axis 4 of the bearing shell, on which one of the two mounting screws 2 is supported 3. In addition, an internal thread 26 is provided in the pressure plate 25.

Before mounting the feed-through head 2 onto the lug tube 5, both mounting screws are screwed into the head flange 22. In this case, the pressure plate 25 moves downward and thereby compresses the cup spring 24 lying on the head flange 22.

The same action can be achieved with a single mounting screw or with more than two mounting screws. First of all, it is important that the pressure plate is movable in the direction of the axis 4. If only one screw 23 is provided, then the unilaterally acting pre-tension force must be compensated with the help of a guide pin, which is used instead of the second mounting screw 23.

The lead-in head 2 pretensioned in this way with a predetermined force is then also fitted onto the draw tube 5. In this case, the internal thread 26 of the pressure plate 25 is screwed onto the external thread 51 of the draw tube 5 all the way into the external insulator 1. When the screw connection is loosened, the pre-compressed disc spring 24 stretches in the axial direction and directs the pressure plate 25 up. During this movement, the pulling tube 5 fixedly connected to the clamping plate 25 through the thread 26, 51 and the control field immovably connected in turn with the pulling tube, the insulating body 6 are moved upward. Thus, the flange 22 of the passage head 2 and the passage base 3 relative to each other are fastened through a disk spring 24, the pressure plate 25, the lug tube 5 and the insulating housing 6 and are mounted on the end faces of the outer insulator 1.

The hollow space 9 remaining inside the passageway insulator, delimited by the substantially insulating body 6 and the inner walls of the outer insulator 1, the head flange 22 and the passageway 3, is filled with dielectric considerations by an insulating agent, for example silicone oil. This insulating means can be filled in a simple manner through the threaded holes after the complete removal of both mounting screws 23. To ensure sealing of the hollow space 9, sealing rings not shown in FIG. 2 between the lug tube and the head flange 22, as well as sealing rings not shown in the figures, are used between the external insulator 1, respectively, the insulating body 6 and the head flange 22 and the passage base 3. In this case, the air in the hollow space 9 can be removed through another from both through threaded holes. After filling the hollow space 9, the through threaded holes can be closed using sealed screws.

Claims (7)

1. A method of manufacturing a column-shaped high-voltage bushing, comprising a hollow cylindrical symmetrical external insulator (1), resting on one end side of the external insulator, configured to connect a bushing head (2) to the high-voltage voltage, resting on the opposite end side of the insulator ( 1), made with the possibility of connecting to the ground potential, the passage base (3) passing along the axis (4) of the cylinder through the external insulator (1), made with the possibility of Connections to high voltage voltage, the broaching housing (5) and the insulating housing (6) mounted on the broaching housing, controlling the field, while in the method, the passage base (3), the external insulator (1) and the passage head are inserted in order (2), the passage base (3) is supported by an insulating body (6) and the passage head (2) and the passage base (3) are pressed against each other through the broaching housing (5), characterized in that before mounting the passage head (2) on the broaching housing (5) on the flange (22) of the passage head (2) axially movable clamping element (21) is pressed, the head flange (22) and the clamping element (21) are pressed against each other with the formation of a pre-tension force, with the subsequent compression of the pre-compressed passage head (2) on the broaching housing (5 ) fix the clamping element (21) at the end of the broaching housing (5) passing through the insulator (1) and then remove the clamping element (21) from the head flange (22) with the formation of an interference fit. 2. The method according to claim 1, characterized in that the clamping element (21) is mounted on the head flange (22) with a screw (23) passing through the threaded through hole of the head flange (22). 3. The method according to claim 2, characterized in that the preliminary tension is created by turning the screw (23) while simultaneously moving the clamping plate (21) lying on the spring (24) of the clamping element (21) in the direction of the head flange (22). 4. The method according to claim 3, characterized in that the pre-threaded through-head (2) provided on the pressure plate (25) with an internal thread (26) is screwed onto the external thread (51) of the extension housing (5) until it stops in the external insulator (1) ) 5. The method according to claim 4, characterized in that the head flange (22) and the passage base (3) are tightened together by loosening the screws (23) through a pre-compressed spring (24), a pressure plate (25), a long the housing (5) and the insulating housing (6) are mounted on the external insulator (1). 6. The method according to claim 5, characterized in that the screws (23) are removed and the inside of the bushing is filled through the threaded hole with an insulating means. 7. The method according to claim 6, characterized in that the threaded through hole after filling the insulating material is closed with a sealed screw.

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