RU2794411C1 - Combined high voltage test transformer - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention can be used to test high-voltage electrical equipment, in particular power transformers, as well as current and voltage transformers. A combined high voltage test transformer contains a cylindrical body with a base filled with an insulating medium, inside of which a magnetic circuit with primary and secondary windings and a capacitor are placed. The capacitor is made of three electrodes. The primary low-voltage and secondary high-voltage windings of the transformer are located on a rectangular magnetic circuit, fixed to the base with a bracket and covered by electrostatic screens covering the side and end surfaces of the high voltage windings wound over the low voltage windings. In the upper part of the housing, a cover is hermetically fixed, on which the insulator is attached. Inside the insulator, one of the plates of a three-electrode capacitor is installed, made in the form of a high-voltage rod, which is attached to the high-voltage screen with bolts by the upper part. The other capacitor plate is a grounded input screen connected to the cover by welding. The third capacitor plate is an additional screen, consisting of a cylindrical and flanged part, fixed on an insulating washer, which is screwed to the cover. There is a sealed connector for taking measurements from the additional screen and a contact that provides connection between the sealed connector and the additional screen.

EFFECT: increased reliability of operation by reducing the influence of external electromagnetic fields and reduced weight and size characteristics.

1 cl, 3 dwg

Description

The technical solution claimed as an invention relates to the field of electrical engineering and can be used to test high-voltage electrical equipment, in particular power transformers, as well as current and voltage transformers.

It is known that the use of high-voltage electrical equipment in power circuits places high demands on them in terms of reliability of operation and accuracy of measuring high voltage, therefore, before commissioning such equipment, it is necessary to carry out tests that are carried out using high-voltage test transformers with significant weight and size characteristics, as well as those affected by external factors that reduce reliability.

Known patent of the Russian Federation No. 2046427, IPC H01F38 / 34, priority dated November 9, 1987 for the invention: “High-voltage voltage measuring transformer”, in particular, a combined high-voltage current and voltage measuring transformer, under pressure of insulating gas, made in the form of a head with a core , which is under high voltage, which is coaxially surrounded by a high-voltage winding with a connecting terminal, equipped with a metal screen with a cut and also coaxially surrounding it with a low-voltage winding, with a supporting frame, as well as with a grounded coaxial shielding electrode surrounding the high-voltage and low-voltage windings. The transformer has two metal coatings located isolated from each other and concentric to each other with a distance of maximum 5 mm, forming a capacitance; additional metal screen, metal covers are located between the high-voltage and low-voltage windings, one of them, located on the high voltage side, is connected by a lead to the connecting terminal for the high-voltage winding. The metal coating located on the low voltage side is electrically conductively connected by connecting wires in the shortest way to the shielding electrode, to which an additional metal shield is connected. The metal screen of the high-voltage winding is used as a metal coating. The metal coating located on the high voltage side is located on the carrier frame of the low voltage winding and is electrically conductively connected to the metal screen of the high voltage winding through a connecting element.

The transformer has several layers of insulating material in the form of a tape or film, located between the metal coatings on the high voltage and low voltage side, forming a distance between them. Metal coatings are made in the form of a conductive layer deposited on the insulating frame, divided in the direction of the winding axis. The metal coatings are made in the form of a metal cylinder pushed over the insulating material, cut in the direction of the winding axis. The metal cylinder is glued on the insulating material and/or reinforced by means of an external insulating bandage winding on the insulating material of the metal coatings. The output for the connecting terminal of the high-voltage winding is insulated relative to the body and the outputs of the low-voltage winding and is brought out to a common terminal block.

Known patent of the Russian Federation No. 139737, IPC H01F38 / 26 priority dated June 28, 2013 for a utility model: “High-voltage gas-filled voltage transformer”, containing an insulating porcelain case installed on a metal base and filled with insulating gas, inside which an insulating cylinder made of high-strength insulating material is installed with a magnetic circuit placed inside it with screens and a metal current outlet tube, with at least one main and additional low voltage windings wound on a rod, and with a high voltage winding wound over the main winding and closed by an electrostatic screen connected to its linear end, and is connected to the upper metal cover tightly closing the insulating cylinder made of high-strength insulating material, by means of a metal current outlet pipe fixed in a cylindrical electrostatic screen. At least one through hole is made in the walls of the insulating cylinder made of high-strength insulating material.

Known patent of the Russian Federation No. 2150762, IPC H01F38 / 26, priority dated October 14, 1998 for the invention: “High-voltage voltage transformer”, containing a metal case filled with an insulating medium, inside which a rectangular magnetic core with electrostatic screens covering two side and one bottom yoke is installed magnetic circuit, with the main and additional low voltage windings wound over the core of the magnetic circuit, and the higher voltage winding wound over the main low voltage winding and closed by an electrostatic screen connected to its linear end and a metal current outlet tube fixed in the electrostatic screen. The electrostatic screen covering the higher voltage winding is made with two or more through cuts along its generatrix, while the connection of the screen parts in one cut is made by means of an insulating screed, and in the rest of the others - by means of a metal screed.

Known patent of the Russian Federation No. 130132, IPC H01F38 / 34, priority dated January 21, 2013 for a utility model: “Device for measuring currents, voltages and data transmission via a digital communication channel”, containing a housing made of insulating material with a high-voltage capacitor, a high-voltage unit with the main current transformer, transmitter and high-voltage bushing, which is under high voltage potential, the base unit with the receiver, which is under zero potential, while the high-voltage unit is fixed on the body of insulating material. The transmitter of the high-voltage unit is connected to the receiver of the base unit, and the power supply of the transmitter is configured to transmit power from the base unit. The main current transformer is attached to the high-voltage input and, along with the low-voltage output of the high-voltage capacitor, is connected to the transmitter inputs. The device is equipped with a protective current transformer, a power supply module, a temperature sensor located in the high-voltage block, optical power and information channels located in an insulating case, as well as an optical pumping module and a low-potential power supply module fixed in the base block. The protective current transformer is installed similarly to the main current transformer at the high-voltage input and is connected with the transmitter by its outputs, and the power inputs of the transmitter are connected to the output of the power supply module, the inputs of which are connected to the optical pumping module via an optical power channel and are connected to the high-voltage arm of the high-voltage capacitor via conductive channels. The power supply module is configured to switch power supply, wherein the temperature sensor is connected to the transmitter input, and the transmitter output is connected to the receiver via an optical information channel, while the power inputs of the optical pumping module and the receiver are connected to a low-potential power supply module, configured to be powered from the mains 220 V. The high-voltage capacitor is made on the basis of oil-impregnated film capacitors, and the main and protective current transformers are made in the form of Rogowski coils. The high-voltage block is made with the possibility of electromagnetic shielding of the transmitter.

Known patent of the Russian Federation No. 182715, IPC G01R15 / 00, H01F38 / 20, H01F38 / 34, priority dated February 1, 6, 2018, for a utility model: “Combined voltage and current transformer”, containing a high-voltage support tubular insulator with a voltage divider, a current transformer , measuring and converting module, fiber-optic communication line with the base unit. The current transformer is made in the form of a fiber circuit of a magnetically sensitive optical fiber, covering the current bus, and the fiber-optic communication line is laid in a tube located inside the high-voltage support tubular insulator, the ends of which are hermetically sealed into the upper and lower flanges of the high-voltage support tubular insulator.

The closest analogue of the technical solution claimed as an invention is the patent of the Russian Federation No. 2297063, IPC H01F38 / 00, H01F38 / 36, priority dated October 19, 2004, for the invention: “A current transformer combined with a capacitor of the high-voltage arm of a capacitive voltage divider”, containing an insulating cylindrical casing hermetically fixed on a metal base, filled with an insulating medium, with an insulating cylindrical column made of high-strength material, hermetically fixed inside it, filled with an insulating medium, and a metal case made in the form of a cylinder and filled with an insulating medium, in which the primary and secondary windings are placed, moreover, the primary winding is made in the form of a rectilinear conductor installed along the axis of the secondary winding and fixed with its ends on the side walls of the metal case, and the secondary winding is made on toroidal magnetic cores covered by a toroidal metal screen fixed at the upper end of the support tube, and the support tube is installed inside an insulating cylindrical column made of high-strength material coaxially with it and the lower end is fixed on a metal base. The support pipe consists of segments of metal pipes and a segment of a pipe made of insulating material rigidly connecting them, and in the cavity of the support pipe there is a tap from the toroidal metal electrostatic screen and taps from the secondary windings led out through bushings installed on the base of the device.

The disadvantage of the known technical solution lies in the impossibility of using it for testing high-voltage electrical equipment, in particular power transformers, as well as current and voltage transformers due to the influence of electromagnetic fields arising from the interaction of a high voltage test transformer and a two-electrode capacitor in one housing.

The objective of the technical solution claimed as an invention is to create a combined high voltage test transformer that provides high reliability by reducing the influence of external electromagnetic fields while reducing weight and size characteristics.

The problem is solved by the fact that in a combined high-voltage test transformer containing a cylindrical body with a base filled with an insulating medium, inside which a magnetic circuit with primary and secondary windings is placed and a capacitor according to the invention, the capacitor is made three-electrode, and the primary low-voltage and secondary high-voltage windings of the transformer are located on a rectangular magnetic circuit fixed to the base with a bracket and covered by electrostatic screens covering the side and end surfaces of the high voltage windings wound over the low voltage windings, a cover is hermetically fixed in the upper part of the housing, on which an insulator is fixed, inside which one of the plates is installed three-electrode capacitor, made in the form of a high-voltage a rod, which is attached to the high-voltage screen with bolts by the upper part, the other capacitor plate is a grounded input screen connected by welding to the cover, the third capacitor plate is an additional screen, consisting of a cylindrical and flanged part, fixed on an insulating washer, which is fastened with screws to the lid in addition, there is a sealed connector for taking measurements from the additional screen and a contact that provides connection between the sealed connector and the additional screen.

The essence of the invention is illustrated by drawings, where figure 1 shows a combined high voltage test transformer in section, figure 2 shows a fragment of a combined high voltage test transformer with an additional screen 13, figure 3 shows an active part of a combined high voltage test transformer.

In accordance with the drawings (figure 1-3) high voltage test transformer combined contains sealed on an aluminum base 4 cylindrical housing 5 filled with an insulating medium (SF6), which houses the magnetic core 1 with primary and secondary windings 2. Primary low-voltage and secondary high-voltage windings 2 are located on a rectangular magnetic circuit 1, fixed on the base 4 with a bracket 9 and covered by electrostatic screens 11, 12, covering the side and end surfaces of the high voltage windings wound on the magnetic circuit over the low voltage windings. In the upper part of the housing 5, a cover 3 is hermetically fixed, on which an insulator 8 is fixed, inside which one of the plates of a three-electrode capacitor is installed, made in the form of a high-voltage rod 6, which is attached to the high-voltage screen 10 with the help of bolts. The other plate of the three-electrode capacitor is a grounded input screen 7, connected by welding to the cover 3. The third plate of the capacitor is an additional screen 13, consisting of a cylindrical part and a flange part, fixed on an insulating washer 14, which is attached to the cover 3 with screws Additional screen 13, which is the third plate of the capacitor, is isolated from cover 3 and a grounded input shield 7, which is the second capacitor plate, an insulating washer 14. The ends of all transformer windings are brought out to the base 4 of the housing, and the capacitor plates are brought out to the cover 3. The electrostatic screen 11 is made in the shape of a torus and is designed to shield high-voltage turns of the transformer winding. The electrostatic screen 12 serves to shield the winding leads and sharp edges of the magnetic circuit 1. The grounded input screen 7, which is the first plate of the capacitor, is connected by welding to the cover 3 and is designed to exclude external interference from the additional screen 13 from the bracket 9. In addition, there is a sealed connector 15, which serves to take measurements from the additional screen 13, which is the third plate of the three-electrode capacitor, and contact 16, which connects the sealed connector 15 and the additional screen 13.

The advantage of the technical solution claimed as an invention is that it provides high reliability by reducing the influence of external electromagnetic fields, since in the proposed design solution, the grounded electrode, made in the form of an additional screen 13, ensures the stability of the electric capacitance between the high-voltage rod 6 and additional screen 13, since it is shielded by a grounded screen from the body and therefore it is not affected by external electromagnetic pickups.

In addition, the claimed design, which ensures the stability of the electrical capacitance, allows the use of capacitors with small weight and size characteristics, which in general also reduces the weight and size characteristics of the device, which allows it to be made in a compact package.

Claims (1)

Combined high-voltage test transformer, containing a cylindrical body 5 with a base 4, filled with an insulating medium, inside which there is a magnetic circuit with primary and secondary windings and a capacitor, characterized in that the capacitor is made of three-electrode, and the primary low-voltage and secondary high-voltage windings 2 of the transformer are located on a rectangular magnetic core 1, fixed on base 4 with bracket 9 and covered by electrostatic screens 11, 12, covering the side and end surfaces of high voltage windings wound over low voltage windings, cover 3 is hermetically fixed in the upper part of housing 5, on which insulator 8 is fixed, inside which one of the plates of a three-electrode capacitor is installed, made in the form of a high-voltage rod 6, which is attached to the high-voltage screen 10 with bolts by the upper part, the other capacitor plate is a grounded input screen 7, connected by welding to the cover 3, the third capacitor plate is an additional screen 13, consisting of a cylindrical and flanged part, fixed on an insulating washer 14, which is screwed to cover 3, in addition, there is a sealed connector 15 for taking measurements from an additional screen 13 and a contact 16 that provides connection of a sealed connector 15 and an additional screen 13 .

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