CN109616296B - Capacity-regulating transformer adopting three-phase linear arrangement Dy (Dy) connection method - Google Patents

Abstract

The invention belongs to the technical field of electricity, and discloses a three-phase linear arrangement type capacity-regulating transformer adopting a Dy (Dy) connection method, which comprises an iron core, a three-phase capacity-regulating winding and three capacity-regulating switches; each phase of the capacity-regulating winding comprises a high-voltage winding I section coil and a high-voltage winding II section coil which are axially arranged; and the low-voltage winding I section coil and the low-voltage winding II section coil are arranged in a radial direction. The low voltage coil is wound with an electrically conductive foil. The low-voltage winding I section coil and the low-voltage winding II section coil form a radial spiral lamination structure, and are rotationally symmetrical along the axis by 180 degrees; the high-voltage wiring terminals and the low-voltage wiring terminals of the capacity-regulating switches are respectively arranged at two sides, and the outgoing lines of the high-voltage winding I section coil, the high-voltage winding II section coil and the low-voltage winding I section coil and the outgoing lines of the low-voltage winding II section coil are upwards connected with the capacity-regulating switches from two sides. The outgoing lines of the capacity-regulating transformer are all arranged at the upper part, the connection distance between the outgoing lines and the capacity-regulating switch is short, the length is similar, the three-phase resistance is balanced, the structure is compact, the volume is small, and the manufacturing is simple.

Description

Capacity-regulating transformer adopting three-phase linear arrangement Dy (Dy) connection method

Technical Field

The invention belongs to the technical field of electricity, relates to a capacity-regulating transformer, and particularly relates to a low-voltage side winding wire outlet mode and a capacity-regulating switch placement mode of the capacity-regulating transformer.

Background

The capacity-regulating transformer is a multi-capacity distribution transformer, and mainly utilizes the capacity-regulating switch mounted on the transformer, when the load is light, at the same time, the connection mode of high-voltage winding and low-voltage winding can be changed, and the magnetic flux density in the core of the transformer can be reduced so as to attain the goal of reducing no-load loss of the transformer under the condition of light load.

The high-capacity coupling group is marked as Dy 11, the low-capacity coupling group is marked as Dy 11, the principle is that each phase of low-voltage winding of the transformer consists of two sections of coils I and II, the number of turns of the coils I and II is equal and the size of the coils I and II is the same, the high-voltage winding consists of two sections of coils I and II, the number of turns of the coils I and II of each phase of the high-voltage winding is equal and the size of the coils I and II is the same.

The distribution modes of the low-voltage winding I-section coil and the low-voltage winding II-section coil of the existing capacity-regulating transformer are three, wherein one is radial splitting, the other is axial splitting, and the third is a wire mixed winding mode. The radial split has the advantages that the lengths of the outgoing lines of the two sections of coils are equivalent, and the defects that the radial positions of the two sections of coils are different, the magnetic field environments are greatly different, the total lengths of the two sections of coils are different, the voltages at the two ends of the two coils are different, and when the two coils are connected in parallel, circulation loss can be generated. The axial splitting has the advantages that the radial positions of the two sections of coils are the same, and the two sections of coils can have the same total circumference, conductive section, resistance and magnetic field environment; the length of the outgoing line of the section of coil far away from the capacity-regulating switch is obviously longer than that of the outgoing line of the section of coil close to the capacity-regulating switch, which is unfavorable for the resistance balance of the two sections of coils. In addition, the two coils need to be separated by a distance in the axial direction. The wire-type mixed winding mode is that the wires of two sections of coils are respectively overlapped, and then the two stacks of wires are adjacent axially and are wound on the iron core. The method has the advantages of transposition width and helix angle, low window filling coefficient, unbalanced ampere turn distribution and poor short circuit resistance.

Disclosure of Invention

In order to solve the problem of the winding structure of the I-section coil and the II-section coil of the low-voltage winding in the existing capacity-regulating transformer adopting the Dy (Dy) connection method, the invention selects a foil type mixed winding scheme to wind the low-voltage winding, in the scheme, the I-section coil and the II-section coil are axially overlapped, radially overlapped and mixed, and the I-section coil and the II-section coil are rotationally symmetrical along the axis of 180 degrees.

The foil type mixed winding scheme is characterized in that: the outgoing lines of the low-voltage I-section coil and the low-voltage II-section coil are not on the same side of the winding, namely the outgoing line of one section of coil is on the same side as the outgoing line of the high-voltage winding coil. The three-phase linear arrangement type capacity-regulating transformer based on the foil type mixed winding scheme is adopted, if the existing three-phase integrated capacity-regulating switch is adopted, the length direction of the capacity-regulating switch is arranged along the upper yoke of the iron core, and the high-voltage wiring terminal and the low-voltage wiring terminal of the capacity-regulating switch are respectively arranged at two sides in the width direction, and then the outgoing line of the low-voltage winding I-section coil of the capacity-regulating winding is positioned at one side of the outgoing line of the high-voltage winding coil, so that the outgoing line of the low-voltage winding I-section coil needs to penetrate from one side to the other side above the upper yoke of the iron core and then is connected with the capacity-regulating switch. On one hand, enough wiring space is reserved between the capacity-adjusting switch and the upper yoke of the iron core, so that the volume of the transformer is enlarged; on the other hand, the wiring processing procedure and the wiring difficulty of the outgoing line are increased; in a third aspect, more material costs of the pinout are required; in the fourth aspect, the outgoing line of the coil of the section I of the low-voltage winding is obviously longer than the outgoing line of the coil of the section II which can be directly connected with the capacity-regulating switch upwards, so that the unbalanced resistance rate of the coils of the two sections is increased.

In contrast, the invention provides a three-phase linear arrangement type capacity-regulating transformer specially designed for the foil-type mixed winding capacity-regulating winding, which adopts a Dy (Dy) conversion capacity-regulating method, and is characterized by comprising an iron core, three-phase capacity-regulating windings and three relatively independent capacity-regulating switches respectively used for controlling the conversion of the coil connection structure of the three-phase capacity-regulating windings, wherein three-phase iron core columns of the iron core are arranged in a linear side-by-side manner, the three-phase capacity-regulating windings are respectively sleeved on the three-phase iron core columns,

Each phase of the capacity-regulating winding comprises a high-voltage winding consisting of two sections of coils I and II which have the same number of turns and the same size, and a low-voltage winding consisting of two sections of coils I and II which have the same number of turns and the same size; the high-voltage winding and the low-voltage winding are axially overlapped. The low-voltage winding I-section coil and the low-voltage winding II-section coil are wound by metal foils with the same size; and the high-voltage winding I section coil and the high-voltage winding II section coil are wound by wires with the same size. The I-section coil and the II-section coil of the high-voltage winding are axially split and distributed; the lead-out wires of all coils extend out in the same axial direction; the outgoing line of the low-voltage winding I section coil is positioned on a first side of the winding, the outgoing line of the low-voltage winding II section coil is positioned on a second side of the winding opposite to the first side, and the outgoing line of the high-voltage winding coil can be positioned on the first side or the second side; the low-voltage winding I-section coil and the low-voltage winding II-section coil form a spiral laminated structure in the radial direction, and are rotationally symmetrical along the axis by 180 degrees;

the three capacity-regulating switches are respectively arranged above the iron core upper yoke and correspond to the positions of the three-phase capacity-regulating windings, the high-voltage wiring terminal and the low-voltage wiring terminal of each capacity-regulating switch are respectively arranged at two sides of the width direction of the capacity-regulating switch, and the length direction of each capacity-regulating switch is perpendicular to the arrangement direction of the three-phase capacity-regulating windings;

The first side and the second side of the capacity-regulating winding respectively correspond to the two sides of the upper yoke of the iron core; and the outgoing line which is required to be connected with the capacity-regulating switch in the low-voltage winding I section coil positioned at the first side of the capacity-regulating winding, the outgoing line which is required to be connected with the capacity-regulating switch in the low-voltage winding II section coil positioned at the second side, and the outgoing line which is required to be connected with the capacity-regulating switch in the high-voltage winding coil positioned at the first side or the second side are respectively upwards connected with the capacity-regulating switch from two sides of the upper yoke of the iron core.

Further, the high-voltage winding coil, the low-voltage winding coil I section and the low-voltage winding coil II section are sequentially arranged from outside to inside in radial direction.

Further, the lead-out wire of the low-voltage winding includes a welded segment welded to the metal foil and a lead-out wire segment protruding from the coil.

And the two outgoing lines of the low-voltage winding I-section coil and the two outgoing lines of the low-voltage winding II-section coil are rotationally symmetrical along the axis of the winding by 180 degrees.

The first side of the regulator Rong Kaiguan comprises a vacuum arc-extinguishing chamber Kd1, a vacuum arc-extinguishing chamber Kdc, a vacuum arc-extinguishing chamber Kdg, a vacuum arc-extinguishing chamber Kd2, a first wiring pin, a second wiring pin and a third wiring pin; the first wiring pin links to each other with the first wiring end of vacuum interrupter Kd1, the first wiring end of vacuum interrupter Kdc respectively, and the second wiring pin links to each other with the first wiring end of vacuum interrupter Kdg, and the third wiring end links to each other with the first wiring end of vacuum interrupter Kd 2.

A first outgoing line of the further low-voltage winding I-section coil is connected with a first wiring pin, and a second outgoing line of the low-voltage winding I-section coil is connected with a zero line; the first outgoing line of the low-voltage winding II-section coil is connected with the low-voltage output end of the capacity-regulating transformer, and the second outgoing line of the low-voltage winding II-section coil is connected with the third wiring pin; the first wiring end of the vacuum arc-extinguishing chamber Kd1 is connected with the first wiring end of the vacuum arc-extinguishing chamber Kdc, and the second wiring end of the vacuum arc-extinguishing chamber Kd1 is connected with the low-voltage output end of the capacity-regulating transformer; the second wiring end of the vacuum arc-extinguishing chamber Kdc is connected with the second wiring end of the vacuum arc-extinguishing chamber Kdg; the first wiring of vacuum interrupter Kd2 is connected to the first wiring of vacuum interrupter Kdg, and the second wiring of vacuum interrupter Kd2 is connected to the zero line.

The second side of the capacity-regulating switch comprises a vacuum arc-extinguishing chamber Kg1, a vacuum arc-extinguishing chamber Kgc, a vacuum arc-extinguishing chamber Kgg, a vacuum arc-extinguishing chamber Kg2, a fourth wiring pin, a fifth wiring pin and a sixth wiring pin, wherein the fourth wiring pin is connected with a first wiring end of the vacuum arc-extinguishing chamber Kg1 and a first wiring end of the vacuum arc-extinguishing chamber Kgc, the fifth wiring pin is connected with a first wiring end of the vacuum arc-extinguishing chamber Kgg, and the sixth wiring pin is connected with a first wiring end of the vacuum arc-extinguishing chamber Kg 2.

Further, a first outgoing line of the first-section coil of the high-voltage winding is connected with a fourth wiring pin, and a second outgoing line of the first-section coil of the high-voltage winding is connected with a high-voltage output end of an adjacent phase; the first outgoing line of the second-section coil of the high-voltage winding is connected with the high-voltage output end of the capacity-regulating transformer, and the second outgoing line of the second-section coil of the high-voltage winding is connected with the sixth wiring pin; the first wiring end of the vacuum arc-extinguishing chamber Kg1 is connected with the first wiring end of the vacuum arc-extinguishing chamber Kgc, and the second wiring end of the vacuum arc-extinguishing chamber Kd1 is connected with the high-voltage output end of the capacity-regulating transformer; the second wiring end of the vacuum interrupter Kgc is connected with the second wiring end of the vacuum interrupter Kgg; the first wiring of the vacuum arc-extinguishing chamber Kg2 is connected with the first wiring of the vacuum arc-extinguishing chamber Kgg, and the second wiring of the vacuum arc-extinguishing chamber Kg2 is connected with the high-voltage output end of the adjacent phase;

Finally, through the capacity-regulating switch, the serial connection and parallel connection conversion of two sections of coils of each phase of high-voltage winding I and II and two sections of coils of low-voltage winding I and II are realized, the three-phase high-voltage winding forms D connection, and the three-phase low-voltage winding forms yn connection.

The invention has the beneficial effects that: 1. through designing the I section coil of the low-voltage winding and the II section coil of the low-voltage winding into 180-degree rotationally symmetrical structures, the lengths of outgoing lines of the two coils are kept consistent, the geometric parameters of the two coils are guaranteed to be completely consistent, the magnetic field environment is the same, the structure is compact, the volume is small, the manufacture is simple, the short circuit resistance of the transformer is effectively improved, the generation of circular current in the two coils is avoided, and the unbalance rate of the three-phase resistor is effectively reduced to the minimum. 2. The single-phase independent capacity-regulating switch is adopted, the arrangement mode that the length direction of the capacity-regulating switch is perpendicular to the arrangement direction of the three-phase capacity-regulating winding is adopted, and the structure of double-side outgoing lines of the low-voltage copper bar is matched, so that the length and redundant bending and bending of outgoing lines are effectively reduced, the processing technology of the outgoing lines is simplified, the materials required by the outgoing lines are saved, the production cost is saved, and the volume of the capacity-regulating transformer is reduced.

Drawings

Fig. 1 is a schematic diagram of a phase-modulating winding of a capacity-modulating transformer according to the present invention;

FIG. 2 is a schematic illustration of the axial split of the high voltage winding coil of the present invention;

FIG. 3 is a schematic diagram of a capacity-adjusting switch according to the present invention;

Fig. 4 is a schematic diagram of a wiring scheme of a first group of vacuum interrupters in the present invention;

fig. 5 is a circuit diagram of the low voltage side of the regulating transformer at low capacity;

Fig. 6 is a circuit diagram of the low voltage side of the capacity regulating transformer at high capacity;

FIG. 7 is a schematic diagram of a wiring scheme of a second group of vacuum interrupters in the present invention

Fig. 8 is a circuit diagram of the high voltage side of the regulating transformer at low capacity;

Fig. 9 is a circuit diagram of the high voltage side of the capacity regulating transformer at high capacity;

in the figure: the symbol 'day' indicates that the vacuum arc-extinguishing chamber is in a closing state, and the symbol 'mesh' indicates that the vacuum arc-extinguishing chamber is in a separating state; rd represents the transition resistance at the low voltage side, and Rg represents the transition resistance at the high voltage side.

Detailed Description

The technical solutions of the present invention will be clearly and completely described below by means of specific embodiments in conjunction with the accompanying drawings.

In order to enable those skilled in the art to better understand the present invention, the following description will make clear and complete descriptions of the technical solutions in the embodiments of the present invention with reference to the accompanying drawings in the embodiments of the present invention. It will be apparent that the embodiments described below are only some, but not all, embodiments of the invention.

Referring to fig. 1, the one-phase capacity-regulating winding structure of the three-phase capacity-regulating transformer shown in the present embodiment includes a high-voltage winding coil, a low-voltage winding i-section coil, and a low-voltage winding ii-section coil sequentially arranged from outside to inside in radial direction; the low-voltage winding I section coil and the low-voltage winding II section coil are formed by winding metal foils, and the high-voltage winding coil is formed by winding metal wires.

Specifically, the coil I and the coil II in the low-voltage winding form a spiral laminated structure, the spiral laminated structure is rotationally symmetrical along the center 180 degrees of the iron core, the winding comprises a first metal foil 2 for winding the coil I, a first insulating layer 20, a first outgoing line 21 of the coil I in low voltage, a second outgoing line 22 of the coil I in low voltage, a second metal foil 3 for winding the coil II in low voltage, a second insulating layer 30, a first outgoing line 31 of the coil II in low voltage and a second outgoing line 32 of the coil II in low voltage.

The specific winding mode of the low-voltage winding is as follows:

Sleeving a low-voltage winding insulating paperboard cylinder on a winding die, and respectively pulling the end part of a first metal foil for winding a low-voltage I-section coil and the end part of a second metal foil for winding a low-voltage II-section coil to the winding die from two opposite directions; the end part of the first metal foil is welded with a first outgoing line 21 of the low-voltage I-section coil, a first insulating layer 20 is attached to the inner side of the first metal foil, the end part of the second metal foil is welded with a first outgoing line 31 of the low-voltage II-section coil, and a second insulating layer 30 is attached to the inner side of the second metal foil; the end part of the first metal foil is fixed on the first side of the winding mould through a low-voltage I-section coil first outgoing line 21, and the end part of the second metal foil is fixed on the second side of the winding mould opposite to the first side through a low-voltage II-section coil first outgoing line 31;

And secondly, rotating the winding die, synchronously winding the first metal foil and the second metal foil with equal length on an insulating paperboard cylinder to form a section I coil and a section II coil which are mutually in a spiral laminated structure, cutting the first metal foil and the second metal foil on the first side and the second side of the winding die respectively when the target turns are met, and welding a low-voltage section I coil second outgoing line 22 and a low-voltage section II coil second outgoing line 32 on new ends of the first metal foil and the second metal foil respectively. And obtaining a spiral mixed coil formed by combining a low-voltage I-section coil and a low-voltage II-section coil, and obtaining the low-voltage winding of the capacity-regulating transformer.

The outgoing line of the low-voltage winding I section coil is positioned on a first side of the winding, and the outgoing line of the low-voltage winding II section coil is positioned on a second side of the winding opposite to the first side. The high-voltage winding coil is wound by a metal wire 200, and is provided with a first outgoing line 201 of a high-voltage I-section coil, a second outgoing line 203 of the high-voltage I-section coil, a first outgoing line 202 of a high-voltage II-section coil, a second outgoing line of the high-voltage II-section coil and a high-voltage insulating layer 205. The outgoing line of the high-voltage winding coil and the outgoing line of the low-voltage winding I-section coil are positioned on the first side of the winding.

As shown in fig. 2, the high voltage i-stage coil 601 and the ii-stage coil 602 are axially split distributed around the periphery of the overall low voltage winding coil 600.

As shown in fig. 3, the connection terminals of the capacity-adjusting switch are respectively arranged at two sides of the width direction of the capacity-adjusting switch, and the length direction of the capacity-adjusting switch is perpendicular to the arrangement direction of the three-phase capacity-adjusting windings;

As shown in fig. 4, in the first group of connection modes of the vacuum arc-extinguishing chambers, the vacuum arc-extinguishing chambers Kd1 are shown, the lower end is provided with a first connection pin 40 and a first connection terminal 41, and the upper end is provided with a second connection terminal 42; the vacuum interrupter Kdc has a first wiring terminal 51 at the lower end and a second wiring terminal 52 at the upper end, a second wiring pin 60 and a first wiring terminal 61 at the lower end and a second wiring terminal 62 at the upper end; the vacuum interrupter Kd2 has a third terminal pin 70 and a first terminal 71 at the lower end and a second terminal 72 at the upper end.

The low-voltage side circuit diagrams shown in fig. 5 and 6 show a low-voltage i-stage winding at the upper left side and a low-voltage ii-stage winding at the upper right side.

The wiring of the outgoing line and the vacuum arc-extinguishing chamber in the capacity-regulating switch is as follows:

As shown in fig. 5 and 6, a first outgoing line of the low-voltage winding I-section coil is connected with a first wiring pin, and a second outgoing line of the low-voltage winding I-section coil is connected with a zero line; the first outgoing line of the low-voltage winding II-section coil is connected with the low-voltage output end of the capacity-regulating transformer, and the second outgoing line of the low-voltage winding II-section coil is connected with the third wiring pin; the first wiring end of the vacuum arc-extinguishing chamber Kd1 is connected with the first wiring end of the vacuum arc-extinguishing chamber Kdc, and the second wiring end of the vacuum arc-extinguishing chamber Kd1 is connected with the low-voltage output end of the capacity-regulating transformer; the second wiring end of the vacuum arc-extinguishing chamber Kdc is connected with the second wiring end of the vacuum arc-extinguishing chamber Kdg; the first wiring of vacuum interrupter Kd2 is connected to the first wiring of vacuum interrupter Kdg, and the second wiring of vacuum interrupter Kd2 is connected to the zero line.

Referring to fig. 7, a second group of vacuum interrupters is shown in a wiring mode of the vacuum interrupter Kg1, wherein the lower end of the vacuum interrupter Kg1 is provided with a fourth wiring pin 80 and a first wiring terminal 81, and the upper end of the vacuum interrupter Kg1 is provided with a second wiring terminal 82; the vacuum arc-extinguishing chamber Kgc has a first wiring terminal 91 at the lower end and a second wiring terminal 92 at the upper end; the vacuum arc-extinguishing chamber Kgg has a fifth wiring pin 100 and a first wiring terminal 101 at the lower end and a second wiring terminal 102 at the upper end; the vacuum arc extinguishing chamber Kg2 has a sixth wiring pin 74 and a first wiring terminal 73 at the lower end and a second wiring terminal at the upper end;

As shown in fig. 8 and 9, a first outgoing line of the section i coil of the high-voltage winding is connected with a fourth wiring pin, and a second outgoing line of the section i coil of the high-voltage winding is connected with a high-voltage output end of an adjacent phase; the first outgoing line of the second-section coil of the high-voltage winding is connected with the high-voltage output end of the capacity-regulating transformer, and the second outgoing line of the second-section coil of the high-voltage winding is connected with the sixth wiring pin; the first wiring end of the vacuum arc-extinguishing chamber Kg1 is connected with the first wiring end of the vacuum arc-extinguishing chamber Kgc, and the second wiring end of the vacuum arc-extinguishing chamber Kd1 is connected with the high-voltage output end of the capacity-regulating transformer; the second wiring end of the vacuum interrupter Kgc is connected with the second wiring end of the vacuum interrupter Kgg; the first wiring of the vacuum interrupter Kg2 is connected with the first wiring of the vacuum interrupter Kgg, and the second wiring of the vacuum interrupter Kg2 is connected with the high-voltage output end of the adjacent phase.

In order to realize capacity adjustment of the capacity-adjusting transformer, as shown in fig. 5, vacuum arc-extinguishing chambers Kd1 and Kd2 are opened, and vacuum arc-extinguishing chambers Kd g and qdc are closed, and are in a low-capacity state at the moment; as shown in fig. 6, the vacuum arc-extinguishing chambers Kd1 and Kd2 are changed from open to closed, the vacuum arc-extinguishing chambers Kd g and Kdc are changed from closed to open, and at the same time, as shown in fig. 8 and 9, the serial-parallel conversion is also completed at the high voltage side, so that the capacity-regulating transformer is changed from a low capacity state to a high capacity state.

Claims (6)

1. The capacity-regulating transformer is characterized by comprising an iron core, three-phase capacity-regulating windings and three relatively independent capacity-regulating switches respectively used for controlling the conversion of the coil connection structure of the three-phase capacity-regulating windings, wherein three-phase iron core columns of the iron core are arranged in parallel in a straight line, and the three-phase capacity-regulating windings are respectively sleeved on the three-phase iron core columns;

Each phase of capacity-regulating winding comprises a high-voltage winding I section coil, a high-voltage winding II section coil, a low-voltage winding I section coil and a low-voltage winding II section coil which are arranged in a radial direction; the high-voltage winding I-section coil, the high-voltage winding II-section coil, the low-voltage winding I-section coil and the low-voltage winding II-section coil are axially overlapped, the high-voltage winding I-section coil and the high-voltage winding II-section coil are axially split and distributed, and the low-voltage winding I-section coil and the low-voltage winding II-section coil are wound by metal foils with the same width; two ends of each coil are respectively connected with an outgoing line, and the outgoing lines of all coils extend out in the same axial direction; the outgoing line of the low-voltage winding I section coil is positioned at a first side of the winding, the outgoing line of the low-voltage winding II section coil is positioned at a second side of the winding opposite to the first side, and the outgoing line of the high-voltage winding I section coil and the outgoing line of the high-voltage winding II section coil can be positioned at the first side or the second side; the turns of the low-voltage winding I section coil and the low-voltage winding II section coil are equal, and the low-voltage winding I section coil and the low-voltage winding II section coil realize serial and parallel structure conversion through a capacity-regulating switch; the low-voltage winding I-section coil and the low-voltage winding II-section coil form a spiral laminated structure, and the two coils are rotationally symmetrical along the axis by 180 degrees;

the three capacity-regulating switches are respectively arranged above the iron core upper yoke and correspond to the positions of the three-phase capacity-regulating windings, the high-voltage wiring terminal and the low-voltage wiring terminal of each capacity-regulating switch are respectively arranged at two sides of the width direction of the capacity-regulating switch, and the length direction of each capacity-regulating switch is perpendicular to the arrangement direction of the three-phase capacity-regulating windings;

The first side and the second side of the capacity-regulating winding respectively correspond to the two sides of the upper yoke of the iron core; the lead-out wire which is needed to be connected with the capacity-regulating switch in the low-voltage winding I section coil positioned at the first side of the capacity-regulating winding, the lead-out wire which is needed to be connected with the capacity-regulating switch in the low-voltage winding II section coil positioned at the second side, and the lead-out wire which can be positioned at the first side or the second side of the high-voltage winding I section coil and the high-voltage winding II section coil and is needed to be connected with the capacity-regulating switch are respectively upwards connected with the capacity-regulating switch from two sides of the upper yoke of the iron core;

The high-voltage winding I-section coil, the high-voltage winding II-section coil, the low-voltage winding I-section coil and the low-voltage winding II-section coil are sequentially arranged from outside to inside in radial direction, and the high-voltage winding I-section coil and the high-voltage winding II-section coil are axially split and distributed;

The lead-out wire of the low-voltage winding comprises a welded section welded with the metal foil and a lead-out wire section extending from the coil.

2. The three-phase in-line Dy (Dy) connected capacity regulating transformer of claim 1, wherein the two outgoing lines of the low-voltage winding i-section coil and the two outgoing lines of the low-voltage winding ii-section coil are rotationally symmetric about a winding axis by 180 degrees.

3. The three-phase in-line Dy (Dy) connected capacity regulating transformer of claim 1, wherein the first side of the regulator Rong Kaiguan comprises a vacuum interrupter Kd1, a vacuum interrupter Kdc, a vacuum interrupter Kdg, a vacuum interrupter Kd2, and first, second, and third wire pins; the first wiring pin links to each other with the first wiring end of vacuum interrupter Kd1, the first wiring end of vacuum interrupter Kdc, and the second wiring pin links to each other with the first wiring end of vacuum interrupter Kdg, and the third wiring end links to each other with the first wiring end of vacuum interrupter Kd 2.

4. A three-phase in-line Dy (Dy) connected capacity regulating transformer as claimed in claim 3, wherein a first lead wire of the low voltage winding i-section coil is connected to the first connection pin, and a second lead wire of the low voltage winding i-section coil is connected to the zero line; the first outgoing line of the low-voltage winding II-section coil is connected with the low-voltage output end of the capacity-regulating transformer, and the second outgoing line of the low-voltage winding II-section coil is connected with the third wiring pin; the first wiring end of the vacuum arc-extinguishing chamber Kd1 is connected with the first wiring end of the vacuum arc-extinguishing chamber Kdc, and the second wiring end of the vacuum arc-extinguishing chamber Kd1 is connected with the low-voltage output end of the capacity-regulating transformer; the second wiring end of the vacuum arc-extinguishing chamber Kdc is connected with the second wiring end of the vacuum arc-extinguishing chamber Kdg; the first wiring of vacuum interrupter Kd2 is connected to the first wiring of vacuum interrupter Kdg, and the second wiring of vacuum interrupter Kd2 is connected to the zero line.

5. The capacity modulation transformer of the three-phase in-line Dy (Dy) connection method of claim 1, wherein the capacity modulation switch second side includes a vacuum interrupter Kg1, a vacuum interrupter Kgc, a vacuum interrupter Kgg, a vacuum interrupter Kg2, and a fourth wiring pin, a fifth wiring pin, and a sixth wiring pin, the fourth wiring pin being connected to a first terminal of the vacuum interrupter Kg1 and a first terminal of the vacuum interrupter Kgc, the fifth wiring pin being connected to a first terminal of the vacuum interrupter Kgg, and the sixth wiring pin being connected to a first terminal of the vacuum interrupter Kg 2.

6. The three-phase in-line Dy (Dy) connected capacity regulating transformer of claim 5, wherein a first lead of the high voltage winding i-section coil is connected to a fourth lead, and a second lead of the high voltage winding i-section coil is connected to a high voltage output terminal of an adjacent phase; the first outgoing line of the second-section coil of the high-voltage winding is connected with the high-voltage output end of the capacity-regulating transformer, and the second outgoing line of the second-section coil of the high-voltage winding is connected with the sixth wiring pin; the first wiring end of the vacuum arc-extinguishing chamber Kg1 is connected with the first wiring end of the vacuum arc-extinguishing chamber Kgc, and the second wiring end of the vacuum arc-extinguishing chamber Kd1 is connected with the high-voltage output end of the capacity-regulating transformer; the second wiring end of the vacuum interrupter Kgc is connected with the second wiring end of the vacuum interrupter Kgg; the first wiring of the vacuum interrupter Kg2 is connected with the first wiring of the vacuum interrupter Kgg, and the second wiring of the vacuum interrupter Kg2 is connected with the high-voltage output end of the adjacent phase.