RU145993U1 - DRY HIGH VOLTAGE TRANSFORMER (OPTIONS) - Google Patents

Abstract

1. A dry high-voltage transformer containing a magnetic circuit with at least one rod, on which at least two windings are concentrically located, one of which is an internal higher voltage with a linear tap in the middle of the height, and the other is an external adjustment winding made with a coil-free zone for the passage of the linear tap of the internal winding of the higher voltage, and at least one high-voltage input, while the linear tap of the internal winding of the higher voltage has an electrostatic screen, The fact that each high-voltage input is installed at an angle to a plane perpendicular to the axis of the core of the magnetic circuit, the lower part of the high-voltage input is placed at a level free from the turns of the zone of the external control winding, while the electrostatic shield covers the place of electrical connection of the linear tap of the internal winding of the higher voltage to the lower parts of the high voltage input. 2. A high-voltage dry transformer containing a magnetic circuit with at least one rod on which at least two windings are concentrically located, one of which is an internal higher voltage with a linear tap in the middle of the height, and the other is an external adjustment winding made with a passage-free passage area a linear tap of the internal winding of a higher voltage, and at least one end cable sleeve with a tip, while a linear tap of the internal winding of a higher voltage I have an electrostatic screen, characterized in that each end cable sleeve is installed at an angle to a flat

Description

The utility model relates to the field of electrical engineering, in particular, to transformer construction, and can find application in dry transformers of voltage class PO kV and higher with voltage regulation.

A technical solution for a voltage-controlled transformer is known, which is used for a voltage class of 110 kV and higher (P. Tikhomirov. Calculation of transformers: Textbook. A manual for universities. - 5th ed., Revised and additional - M: Energoatomizdat, 1986 , p. 528) - [1], in which the transformer contains a magnetic circuit and at least three windings concentrically located on the core of the magnetic circuit, the first of which is the lower voltage winding (LV), the second is the higher voltage winding (VN) with a linear tap into mid-height, the third - adjusting winding (RO), having schaya in its middle part is free from windings zone for passage of the linear retraction voltage winding; the HV winding of a three-phase transformer is connected to a star with a neutral output, voltage regulation is performed in the neutral of the HV winding. In this technical solution, the lower part of the linear high-voltage input of the HV winding, as a rule, is located outside the HV and PO windings - in the gap between the RO winding and the grounded tank wall (casing). When the transformer is operating, the voltage of the PO winding, as well as the voltage between the PO windings of the adjacent phases (in the case of a three-phase transformer), is small (corresponds to the voltage regulation range). With regard to a three-phase transformer, this allows you to make the insulation gaps between the outer winding of the RO and the grounded wall of the tank (casing), as well as between the windings of the neighboring phases, relatively small, which is the advantage of this technical solution.

The disadvantage of the technical solution [1] is that during operation of the transformer between the parts of the RO winding and the linear tap of the HV winding at the point of its passage through the RO winding, between the RO winding and the lower part of the linear high-voltage input of the HV winding, and also between the lower part of the linear high-voltage input the HV windings and the grounded wall of the tank (casing) the voltage is close to the phase voltage of the HV side, which requires appropriate insulation distances that increase the overall dimensions of the transformer.

Known technical solution for a transformer with voltage regulation (RU 106436 U1, IPC: H01F 29/02, H01F 27/32, publ. 07/10/2011) - [2], intended, inter alia, for use in dry transformers of voltage class 110 kV, in which the regulating winding concentrate is located closest to the low voltage (LV) winding concentrate and one of these two concentrates is located closest to the core of the magnetic circuit. Thus, the HV winding is external in location, and in this case there is no insulation gap mentioned above between the linear end (tap) of the HV winding and the PO winding, as well as the gap between the RO winding and the lower part of the high-voltage input, designed for phase voltage.

The disadvantage of the arrangement of the windings according to [2] in a three-phase transformer is that the voltage between the windings of adjacent phases (external windings of the HV) during its operation is equal to the linear voltage of the side of the HV, which requires the use of sufficiently large insulation gaps between the windings of these neighboring phases. In addition, in this technical solution, it is necessary to provide isolation of the taps of the RO winding relative to the magnetic circuit and the LV winding.

Closest to the proposed utility model is a technical solution (SU 890456 A1, IPC: H01F 27/28, publ. 15.12.1981) - [3], in which the transformer contains a magnetic circuit, on the rod of which there are concentrically placed windings, at least two, one of which the inner one with a linear tap in the middle of the axial size, and the other one, which has a coil-free zone for the linear tap of the inner winding to pass, in which there is an electrostatic screen with a rounded surface facing the linear tap, and barrier insulation between windings, consisting of cylinders of insulating elements on a linear tap and barriers on the screen, characterized in that in order to reduce material consumption, labor and energy losses in the area free of turns of the external winding, an electrostatic screen is made in the form of a ring located concentrically on the linear tap of the inner windings.

The disadvantage of solution [3] is that in it, as in the other technical solutions discussed above, the place of electrical connection of the linear tap of the HV winding and the high-voltage input or cable termination is located outside the windings, therefore, it is necessary to provide insulation gaps from the outer winding and the wall tank (casing) to the bottom of the high-voltage input or the tip of the cable termination, which must be performed on phase voltage. With regard to dry transformers of voltage class 110 kV with air-barrier insulation, the use of such a technical solution leads to significant dimensions of the transformer as a whole and a decrease in its technical and economic indicators.

The technical task of the utility model is to design a dry high-voltage transformer that eliminates the insulation gap from the outer surface of the outer winding to the lower part of the high-voltage input or cable terminal end and reduces the insulation gap from the grounded tank wall (casing) to the lower part of the high-voltage cable input or terminal cable box.

The technical result achieved in the utility model consists in reducing the overall dimensions of a dry high voltage transformer without reducing the electric strength of its internal insulation.

The problem is solved due to the fact that:

- in a dry high-voltage transformer according to option 1, comprising a magnetic circuit with at least one rod on which at least two windings are concentrically located, one of which is an internal higher voltage with a linear tap in the middle of the height, and the other is an external adjustment winding made with free from the turns, the zone for the passage of the linear tap of the internal winding of the higher voltage, and at least one high-voltage input, while the linear tap of the internal winding of the higher voltage is electrostatically according to this utility model, it is proposed to install the high voltage input at an angle to the plane perpendicular to the axis of the core of the magnetic circuit, place the lower part of the high voltage input at the level of the external adjustment winding free from the turns and cover the place of electrical connection of the linear tap of the internal winding of the higher voltage to the lower parts of high voltage input;

- in a dry high-voltage transformer according to option 2, containing a magnetic circuit with at least one rod on which at least two windings are concentrically located, one of which is an internal higher voltage with a linear tap in the middle of the height, and the other is an external adjustment winding made with free from the turns by the zone for the passage of the linear tap of the internal winding of the higher voltage, and at least one end cable sleeve of the high voltage with a tip, while the linear tap of the internal winding in An electrostatic shield has a higher voltage, it is proposed according to this utility model to install an end cable sleeve at an angle to a plane perpendicular to the axis of the core of the magnetic circuit, place the tip of the end cable sleeve at the level of the external adjustment winding free from turns and cover the place of electrical connection of the linear tap of the internal winding with an electrostatic screen high voltage to the end of the cable end sleeve.

The technical result of the proposed device is determined as follows. In traditional transformers of voltage class ON kV and higher, in contrast to the proposed solution, the lower parts of high-voltage bushings or the terminals of high-voltage cable terminations are placed outside of all windings. With the traditional arrangement of the windings on the magnetic rod in the NN-VN-RO order, in this case, it is necessary to provide the necessary insulation distances outside from the RO winding to the lower part of the high-voltage input or the terminal end of the cable sleeve, as well as to the linear tap of the VN winding connected to the lower part of the high-voltage the input or the tip of the cable sleeve, as well as from the bottom of the high voltage input or the tip of the end cable sleeve to the grounded tank wall (casing).

The installation of a high-voltage input (end cable sleeve) at an angle to the plane perpendicular to the axis of the core of the magnetic circuit, and the placement of the lower part of the high-voltage input (tip of the cable end sleeve) at the level of the outer winding-free zone, eliminates the insulation gap between the outer surface of the outer winding and the lower part high-voltage input (terminal end of cable gland) and reduce the insulation gap between the lower part of the high-voltage input (terminal end cable coupling) and a grounded wall of the tank (casing), which can significantly reduce the dimensions of the transformer as a whole and increase the technical and economic indicators of dry transformers of voltage class 110 kV and higher.

To further reduce the insulation gaps without reducing the electrical strength of the insulation, the place of electrical connection of the lower part of the high-voltage input or the tip of the cable end sleeve and the linear tap of the internal winding of the higher voltage is covered by an electrostatic screen.

A comparative analysis of the proposed options for a dry high-voltage transformer with known devices of similar purpose and the lack of descriptions of such in known sources of information allows us to conclude that the proposed utility model meets the criterion of "novelty."

In FIG. 1 and 2 schematically shows a variant of the proposed design of a dry high-voltage transformer made according to claim 1 of the utility model formula; in FIG. 1 shows a side view, the cross section is made along the axis of the core of the magnetic circuit in a plane perpendicular to the longitudinal axis of the magnetic circuit; in FIG. 2 shows a top view and a section in the plane “AA”, perpendicular to the axis of the core of the magnetic circuit.

In FIG. Figure 3 schematically shows a variant of the proposed design of a high-voltage dry transformer made according to claim 2 of the utility model formula — side view, section taken along the axis of the core of the magnetic circuit in a plane perpendicular to the longitudinal axis of the magnetic circuit.

In the dry high voltage transformer of Embodiment 1 shown in FIG. 1 and 2, structural elements are designated as follows:

1 - magnetic circuit;

2 - the core of the magnetic circuit 1;

3 - winding low voltage LV;

4 - winding high voltage VN;

5 - adjusting winding RO;

6 - grounded casing;

7 - high voltage input;

8 - a plane perpendicular to the axis of the rod 2 of the magnetic circuit 1;

9 - the lower part of the high-voltage input 7;

10 - linear tap winding VN;

11 - electrostatic screen.

The dry high voltage transformer of FIG. 1 and 2 has a magnetic circuit 1 with at least one rod 2 and at least one high-voltage input 7, while the number of high-voltage inputs 7 corresponds to the number of linear taps 10 of the high-voltage windings BH4. At least on the part of the rods 2 of the magnetic circuit 1, the windings are concentrically located - the low voltage winding HH 3, the high voltage winding BH4 and the adjustment winding RO 5. In the adjustment winding RO 5 there is a zone free from turns (“gap”). The high-voltage input 7 is installed at an angle α to the plane 8, perpendicular to the axis of the rod 2 of the magnetic circuit 1, so that the end of its lower part 9 is located in the “gap” zone of the PO 5 winding free of turns at the level of the linear tap 10 of the VN 4 winding, electrically connected to the lower part 9 of the high-voltage input 7. To equalize the electric field and ensure high electric strength, an electrostatic screen 11 with a large radius of curvature is installed in the lower part 9 of the high-voltage input 7, which shields the place of the electric rhichny connection of the linear tap 10 of the winding VN 4 and the lower part 9 of the high voltage input 7.

Another embodiment of the design of the dry high voltage transformer, made according to claim 2 of the utility model formula (Fig. 3), is characterized in that the connection of the dry transformer to the high voltage network may include at least one high voltage power cable 12 terminating from the transformer side at least one end cable sleeve 13. In this case, the end cable sleeve 13 is installed at an angle α to the plane 8, perpendicular to the axis of the rod 2 of the magnetic circuit 1, so that its tip 14 is located in the free zone (“gap”) of the RO 5 winding at the level of the linear tap 10 of the BH 4 winding, electrically connected to the tip 14 of the cable sleeve 13. To equalize the electric field and ensure high electric strength in the location of the tip 14 of the cable sleeve 13 of the high voltage cable 12, an electrostatic screen 11 is installed with a large radius of curvature, which at the same time shields the place of electrical connection of the linear branch 10 of the BH 4 winding and the cable end sleeve 13.

The installation angle α of the high-voltage input 7 or terminal cable sleeve 13 relative to plane 8 depends on the particular design of the control winding RO 5, is determined based on the conditions for ensuring the required insulation distances from the lower part 9 of the high-voltage input 7 or tip 14 of the cable end sleeve 13 to the control winding RO 5 and the grounded wall of the tank (casing) 6. The optimal values of the angle α are in the range from 0 to 60 °. The implementation examples shown in FIG. 1 and 3 (design options) are characterized by an angle α = 35 °.

When using a dry high voltage transformer according to paragraphs 1 and 2 of the utility model, the voltage at the linear tap 10 of the BH 4 winding and the lower part 9 of the high voltage input 7 or the tip 14 of the cable end sleeve 13 electrically connected to it is equal to the phase voltage of the high voltage side of the transformer. Since the BH 4 winding is usually connected to the star with the neutral output, and voltage regulation is performed in the neutral of the BH 4 winding, the voltage across the PO 5 winding is small and is determined by the voltage control range on the higher voltage side. Thus, the potential difference between the lower part 9 of the high-voltage input 7 or the tip 14 of the cable termination 13 and the winding PO 5 is almost equal to the phase voltage of the higher voltage side, which requires the use of appropriate insulation distances. By positioning the lower part 9 of the high-voltage input 7 or the tip 14 of the cable termination 13 in the “gap” of the RO 5 winding, it is possible to significantly reduce the length of the linear tap 10 of the BH 4 winding and exclude the presence of live parts that are under phase voltage and are located outside the RO 5 winding. As a result , this arrangement reduces the overall dimensions of the dry high-voltage transformer as a whole without reducing the electrical strength of its internal insulation.

During the operation of the transformer, the presence of metal parts with sharp edges in the place of electrical connection of the linear tap 10 of the BH 4 winding and the lower part 9 of the high-voltage input 7 or the tip 14 of the cable end sleeve 13 can lead to an increase in the electric field strength and the occurrence of local corona foci. By placing at least part of the linear branch 10 of the BH 4 winding and the place of electrical connection of the linear branch 10 of the BH 4 winding with the lower part 9 of the high-voltage input 7 or the tip 14 of the cable end sleeve 13 inside the electrostatic shield 11 with a large radius of curvature, it is possible to significantly reduce the tension and equalization of the electric field, to eliminate the appearance of local foci of corona discharge and to increase the electric strength of the internal insulation of the proposed dry transformer.

Claims (2)

1. A dry high-voltage transformer containing a magnetic circuit with at least one rod, on which at least two windings are concentrically located, one of which is an internal higher voltage with a linear tap in the middle of the height, and the other is an external adjustment winding made with a coil-free zone for the passage of the linear tap of the internal winding of the higher voltage, and at least one high-voltage input, while the linear tap of the internal winding of the higher voltage has an electrostatic screen, The fact that each high-voltage input is installed at an angle to a plane perpendicular to the axis of the core of the magnetic circuit, the lower part of the high-voltage input is placed at a level free from the turns of the zone of the external control winding, while the electrostatic shield covers the place of electrical connection of the linear tap of the internal winding of the higher voltage to the lower parts of high voltage input. 2. A dry high-voltage transformer containing a magnetic circuit with at least one rod on which at least two windings are concentrically located, one of which is an internal higher voltage with a linear tap in the middle of the height, and the other is an external adjustment winding made with a coil-free zone for the passage of the linear tap of the internal winding of the higher voltage, and at least one end cable sleeve with a tip, while the linear tap of the internal winding of a higher voltage It has an electrostatic shield, characterized in that each end cable sleeve is installed at an angle to a plane perpendicular to the axis of the core of the magnetic circuit, and the tip of the end cable sleeve is placed at a level free from the turns of the external adjustment winding zone, while the electrostatic screen covers the place of electrical connection of the linear tap internal winding of high voltage to the end of the cable end sleeve.