RU2421838C1 - Electric high-frequency transformer - Google Patents

Abstract

FIELD: electricity. ^ SUBSTANCE: in electric high-frequency transformer, which contains low-voltage winding connected through capacitor to high-frequency generator and high-voltage winding performed in a form of spiral coil with winding length equal to quarter of current wave and voltage wave length, electric voltage and thickness of conductor electrical insulation is different for each section and increases while section is receding from beginning of spiral winding according to the formula: where cosåi; - specified current value of i section; where Vi, - voltage at the end of i section; V0 - voltage at the end of spiral winding; i - thickness of electrical insulation in i section, ^ EFFECT: increase of insulation strength of high-voltage winding. ^ 3 cl, 2 dwg

Description

The invention relates to the field of electrical engineering, in particular to the design of electrical high-frequency transformers for electric power transmission devices.

Known voltage transformer is an electromagnetic static converter of electrical energy containing primary and secondary windings. Power is transferred from one winding to another by an electromagnetic field. To enhance communication, the windings are placed on a ferromagnetic core - a magnetic circuit. In transformers there is a high coefficient of electromagnetic coupling C = 0.93-0.999.

,

,

where M is the mutual inductance between the primary and secondary winding,

L ₁ , L ₂ - inductance of the primary and secondary windings.

To create a magnetic field in the transformer, reactive power is used, which is spent on creating a mutual induction field and scattering fields of the primary and secondary windings. Part of the active power is spent on copper losses in the primary and secondary windings (IP Kopylov, Electric machines. M: Logos, 2002, pp. 131-239).

A disadvantage of the known device is the symmetry of the voltage at the terminals of the secondary winding, which does not allow the use of an electric transformer to transfer electrical energy through a single-conductor line.

Known electrical transformer, which has a primary winding connected to an electric generator of high frequency. The primary winding is wound on a secondary high-voltage winding, the wire length of which is much greater than the length of the primary winding and approximately equal to a quarter of the wavelength of the electromagnetic field in the line. In this case, the potential of one internal output of the high voltage winding is zero, and the potential of the other external output will be maximum. The inner end of the high-voltage secondary winding is connected to the electric power transmission line, and the outer end of the secondary winding and the adjacent terminal of the primary winding for electrical safety are connected to the ground (N. Tesla. Electrical transformer. US Pat. No. 593138, 02.11.1897).

A disadvantage of the known device is the loss of power at a high frequency due to losses on the resistance of the high voltage winding.

Known high-voltage high-frequency transformer containing a single-layer spiral coil, which is made single-layer with an electric length equal to a quarter of the wavelength, and is connected to the generator and the load asymmetrically (Pat. RF 2033651 from 04/22/1988).

A disadvantage of the known device is the use to obtain resonant oscillations of the own capacitance of the spiral winding.

Known electric high-frequency transformer containing a low-voltage and a high-voltage winding, made in the form of a spiral coil with a length of a high-voltage winding equal to a quarter of the wavelength of current and voltage, the spiral winding consists of several series-connected sections of an insulated conductor, the cross-sectional area of which is different for each section and decreases in as the section is removed from the beginning of the spiral winding according to the equation:

where cosφ _i is the normalized current value of the i-th section;

,

,

, а начало спиральной обмотки соединено с концом низковольтной обмотки и через емкость - с одним из выводов высокочастотного генератора (патент РФ №2337423. Бюл. №30, опубл. 27. 10.2008).where I _i is the current in the i-th section, I ₀ is the current at the beginning of the first section, S _i is the conductor cross section in the i-th section;

and the beginning of the spiral winding is connected to the end of the low-voltage winding and through the capacitance to one of the terminals of the high-frequency generator (RF patent No. 2337423. Bull. No. 30, publ. 27. 10.2008).

A disadvantage of the known device is the decrease in reliability due to an increase in voltage along the length of the spiral winding and the possibility of breakdown of insulation at the end of the spiral winding.

The objective of the invention is to increase the reliability and service life of a high-frequency transformer. The technical result is to increase the dielectric strength of the insulation of the high voltage winding.

The technical result is achieved in that in an electric high-frequency transformer containing a low-voltage winding connected through a container to a high-frequency generator, and a high-voltage winding made in the form of a spiral coil with a winding length equal to a quarter of the wavelength of current and voltage, the spiral winding consists of several sections of an insulated a conductor, the cross-sectional area of which is different for each section and decreases as the section moves away from the beginning of the spiral winding according to the equation:

where cosφ _i is the normalized current value of the i-th section;

,

,

, а начало спиральной обмотки соединено с концом низковольтной обмотки и через емкость с одним из выводов высокочастотного генератора, электрическое напряжение и толщина электрической изоляции проводника различна для каждой секции и увеличивается по мере удаления секции от начала спиральной обмотки согласно уравнениюwhere I _i is the current in the i-th section, I ₀ is the current at the beginning of the first section, S _i is the conductor cross section in the i-th section;

and the beginning of the spiral winding is connected to the end of the low-voltage winding and through the capacitance with one of the terminals of the high-frequency generator, the electric voltage and thickness of the electrical insulation of the conductor are different for each section and increases as the section moves away from the beginning of the spiral winding according to the equation

where sinψ _i is the normalized voltage value at the end of the i-th section.

,

,

where V _i is the voltage at the end of the i-th section;

V ₀ is the voltage at the end of the spiral winding;

δ _i is the thickness of the electrical insulation in the i-th section.

.

.

In an embodiment of an electric high-frequency transformer, it is made without a core.

In another embodiment of an electric high-frequency transformer, it comprises an open core.

The invention is illustrated in figure 1, 2. Figure 1 shows the electrical circuit of the device and figure 2 shows the distribution of current and voltage in sections of the high-voltage winding of a high-frequency transformer.

длины волны тока и напряжения.According to figure 1, the high-frequency generator 1 is connected through capacitance 2 to the low-voltage winding 3 of the high-frequency transformer 4. The high-voltage winding 5 is made in the form of a spiral coil with a conductor length l _B equal to

current and voltage wavelengths.

, где C - скорость электромагнитной волны.

where C is the speed of the electromagnetic wave.

At a generator frequency f ₀ = 50 kHz

High-voltage winding 5 consists of sections C ₁ , C ₂ , C ₃ with different cross-sections of the conductor and different thicknesses of insulation.

Figure 2 shows the distribution of the current wave 6 and voltage 7 in the quarter-wave spiral high-voltage winding 5.

The maximum value of the electric field in the insulation in section C _i is

,

,

where V _i = V ₀ sinφ _i is the voltage at the end of the i-th section;

V ₀ - the maximum voltage at the end of the spiral winding, equal to the rated voltage of the high voltage winding of the high-frequency transformer 4;

δ _i - insulation thickness of the i-th section.

Assuming the electric field is constant along the length of the spiral winding, we obtain the equation

where A ₁ is a constant value;

V ₀ is the rated voltage of the high-voltage winding 5 of the high-frequency transformer 4 and is a constant value. Divide both sides of the equation by V ₀ . We get

where A ₂ is another constant, a sinψ _i is the normalized value of the voltage in the i-th section of the spiral winding

.

.

Figure 2 high-voltage spiral winding 5 of a quarter-wave resonant transformer 4 with a length of 1500 m at a frequency of 50 kHz contains three sections of 500 m each. Taking the maximum value of the normalized voltage for the section C ₁ ψ ₁ = 30 °, sinψ ₁ = 0.5; for section C ₂ ψ ₂ = 60 °, sinψ ₂ = 0.815; for section C ₃ ψ ₃ = 90 °, sinψ ₃ = 1.

To fulfill the condition of the same magnitude of the electric field in the insulation of the conductor, we obtain the ratio for the insulation thickness in sections

;

;

.

;

;

.

;

;

.

;

;

.

Choosing the voltage V ₀ = 100 kV, insulation thickness 15 mm for the end of the third section C ₃ , we obtain δ ₁ = 7.5 mm, δ ₂ = 0.815 · 15 = 12 mm, δ ₃ = 15 mm.

The implementation of the high-frequency transformer 4 without a core provides potential asymmetry at the terminals of the high-voltage winding 5 with zero potential at the terminal of section C ₁ connected to the low-voltage winding 3 and the full potential equal to the rated voltage V _{0 of the} high-voltage winding 5 at the end of section C ₃ . The use of an open core with an air gap of 1-100 mm, depending on the size of the transformer, allows you to reduce the size of the high-frequency transformer by increasing the coefficient of electromagnetic coupling while maintaining the asymmetry of the potentials at the terminals of the high-voltage winding 5.

An example of a high-frequency transformer.

The high-frequency transformer is made without a core.

The number of turns in the low-voltage winding 3 is 4. The high-voltage winding 5 has a total length of 1500 m. The winding has three sections of 500 m. The first section C ₁ has a conductor cross section of 15 mm ² , the insulation thickness is 7.5 mm, the second section C ₂ has a cross section the conductor is 6 mm ² , the insulation thickness is 12 mm, the third section C ₃ has a conductor cross section of 4 mm ² , the insulation thickness is 15 mm.

Thus, in comparison with the known transformer, in which the high-voltage winding is made of a conductor with insulation that is the same along the entire length of the high-voltage winding, the execution of a high-voltage spiral coil from several sections in which the insulation thickness increases in accordance with relation (1) increases the electric strength isolation, reliability and service life of a high-frequency transformer.

Claims (3)

1. An electric high-frequency transformer containing a low-voltage winding connected through a container to a high-frequency generator, and a high-voltage winding made in the form of a spiral coil with a winding length equal to a quarter of the wavelength of current and voltage, the spiral winding consists of several sections of an insulated conductor, the cross-sectional area of which different for each section and decreases with the distance of the section from the beginning of the spiral winding according to the equation

where cosφ _i is the normalized current value of the i-th section;

,
where I _i is the current in the i-th section, I ₀ is the current at the beginning of the first section, S _i is the conductor cross section in the i-th section;

and the beginning of the spiral winding is connected to the end of the low-voltage winding and through the capacitance to one of the terminals of the high-frequency generator, characterized in that the voltage and thickness of the electrical insulation of the conductor are different for each section and increases as the section moves away from the beginning of the spiral winding according to the equation

where sinψ _i is the normalized voltage value at the end of the i-th section.

,
where V _i is the voltage at the end of the i-th section;
V ₀ is the voltage at the end of the spiral winding;
δ _i is the thickness of the electrical insulation in the i-th section,

2. Electric high-frequency transformer according to claim 1, characterized in that it is made without a core. 3. The electric high-frequency transformer according to claim 1, characterized in that it contains an open core.

Images