SU1387058A1 - Winding for high-voltage inductive device - Google Patents

Abstract

This invention relates to electrical engineering, in particular to power transformers and reactors. The aim of the invention is to reduce material. winding capacitances by weakening the electric field in the oil channels between the pairs of coils during overvoltage of the winding. The winding contains coils connected in series and placed one under another. Each coil is made up of continuously wound working turns 1-8, 9-16, 17-24, 25-32 and idle turns W - 8, 9-12, 25- 28, 24-2l, having a smaller width than the working coils. The idle coils have an outer end at the outermost working coil and the inner end is no deeper than the middle of the coil. A jumper connecting the idle coils in one pair of coils is located between the outer ends of the idle coils, and in the adjacent coil pair the jumper connects the inner ends of the idle coils. 3 il. "(L

Description

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113

The invention relates to electrical engineering and can be used in power transformers and reactors, subjected to operation and during tests to overvoltages.

The purpose of the invention is to reduce the material intensity of a winding by weakening the electric field in the oil channels between the pairs of coils during overvoltages.

Figure 1 shows a portion of the proposed winding; figure 2 - picture of the electric field in the oil cana

The winding has a jumper between the outer ends 24-25 of the single spirals of the upper pair of coils and the jumper between the internal ends 9 and 8 of the single spirals of the lower pair of coils. The pairs of coils are separated by an oil channel 33, a coil insulation is applied on the coils.

The combination of a pair of coils with a jumper between the inner ends of the idler spirals and a pair of coils with a bridge between the outer ends of the idler spirals and the ratio of the large

le between adjacent pairs of coils about 15 width of the working coil with a small width

hanks; FIG. 3 is a schematic of a portion of a winding with impulse currents during overvoltages.

The winding contains four coils connected in series and placed one under the other. Each katugika has a working spiral of continuously wound working turns. In cross section, the working turns have a large width. In the first one, when counting from the bottom of the coil, the working turns are indicated by but-measures 1–8 in the order of their sequential inclusion in the working helix, the same numbers also indicate the value of the electric potential of the coil.

The second, third and fourth coils are working spirals from turns 9-16, 17-24 and 25-32, respectively. To each working helix to pieces

The length of the fit is shorter and tone-. 9 and working turns 24 and 9 can be seen.

A single spiral of single turns with an external end near the outermost working coil and an internal end no deeper than the middle intermediate working coil. In the cross section, idle Q and 9 have a voltage of 2.5 N, the coils have a smaller width, in the cervix, second, third and fourth coils the idle coils are indicated by the numbers

that the field in them is the same - the equipotentials 20 and 13 are the same in the compared areas. In the area between the idle coils 28

is distributed in such a way that a voltage (20-13) acts on the oil channels, and the remaining voltage acts on a stronger, coil insulation, on which

respectively, the outer ends 5., 2 last calculated, i.e. oily

channel not loaded larger than 2ht

5–8, 9–12, 25–28 and 24–21

25 and 24 are located near the extreme working turns, and the inner ends at, 9, 28, and 2l are located near the intermediate working turns, not deeper than the average working turn.

The numbers of idle coils are determined in accordance with the rule: in a pair of coils, the potential of the midpoint (jumper) of the connected spirals connected to each other is equal to the potential of the middle point of the working spirals connected to each other.

50

55

voltage

Serial connection and placement of coils with external and internal bridges one after the other leads to a significant weakening of the electric field in the oil channel between them: alternation of bridges forms a layout of idle coils with a reduced voltage of 2.5 N between the pairs, reduction of the coil voltage H is due to mutual quenching of the magnetic pulsed flows of the indicated pairs of coils.

The idle revolution results in a qualitative improvement in the electric field in the oil channel 33 between the combined pairs of coils: the highest voltage between the pairs of coats is 2.5 N, (2.5 N, less than 2E ,.

The isolation gap between the pairs of coils is shown in FIG. The working turns have a greater, for example, 4 times the width than the idle, and the same (or greater) thickness of the winding insulation, the numbers on them indicate the potentials, 33 - the oil channel between the coil pairs, 34 qi on workers and idle coils, equipotentials with potentials 20 and 13 are shown by dotted lines. From a comparison of the sections of the oil channel between the idle coils 2B and

0

five

voltage

Serial connection and placement of coils with external and internal bridges one after the other leads to a significant weakening of the electric field in the oil channel between them: alternation of bridges forms a layout of idle coils with a reduced voltage of 2.5 N between the pairs, reduction of the coil voltage H is due to mutual quenching of the magnetic pulsed flows of the indicated pairs of coils.

The mutual damping of the pulsed flows is explained by the obtained distribution of the pulsed currents (Fig. 3). Segments 1–8, 9–16, 17–24, and 25–32 are the working helix of the coils, the 5 –V, 9–12, 21–24 –– 28 – idle helix segments (digits indicate the numbers of the extreme coils of the spirals), 35 between the working and idler coils form paths for the pulsed current 36 during overvoltages (for introducing the capacitor 35 and forming the pulsed current 36 idle coils are wound). In the upper pair of coils, the pulsed currents 36 flow counter to the working idle spirals, in the lower pair of coils the pulsed current flows in accordance with the working and idling spirals; a strong mutually inductive coupling of both pairs leads to a reduced total magnetic flux (the counterbalance of the uncompensated flux of external idle coils 24 and 25 and the flux of the lower pair of coils is important), which therefore induces a reduced voltage H ,. in the coil.

An additional effect — a decrease in the tension in the oil channel — is due to the placement of narrow idle coils 28 and 9 (between them the highest voltage of 2.5N 28-9 19 2.5 X 8 acts between the wide working coils: wide coils 13 , 14, 19 and 20 screen

J- J

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387058

narrow coils 28 and 9 with the greatest potential difference.

With an increase of 1.5 times or more of the insulation thickness of the idle coils compared with the insulation thickness of the working coils, the effect of non-idle turns on the oil channel field is enhanced.

1Q The calculation of the proposed winding for a transformer with a capacity of 630 mVA with a voltage of 500 kV shows that its weight is reduced by 20 tons, and the laboriousness of its manufacture is

15 780 people h

Claims (1)

Invention Formula  The winding of the high-voltage induction apparatus of high voltage, containing pairs of series-connected coils, where each has a working spiral of continuously wound working turns and a single spiral of single turns of 5 with an external end at the extreme working coil and an internal end not deeper than the middle of the coil, and a jumper connecting the inner cones of the idle spirals of one pair of coils, 0 characterized in that, in order to reduce the material consumption of the winding by weakening the electric field in the oil channels between the pairs of coils during overvoltages, the adjacent pair of coils is made with a bridge between the outer ends of the blank spirals. , (Reg. 2 F1 / .3