RU2680147C1 - Generator with the shaft rotation changing frequency and combined excitation voltage stabilization method - Google Patents

Abstract

FIELD: electrical equipment.SUBSTANCE: invention relates to the field of electrical equipment and can be used in the aircrafts power supply systems. Generator voltage stabilization method consists in the exciter excitation current value changing in the second range and its direction changing. Implementing the method device contains main inductor, including a permanent magnet (1), a non-magnetic material bushing (2), a shaft (3), retaining ring (4), composed of the magnetically conductive and magnetically non-conductive material parts, additional inductor made in the form of a magnetic conductor (5), a pole tip (6), an excitation winding (7), contact rings (8), bushings (9) from insulating material, contact brushes (10) with the corresponding terminals (10and 10), separated by the gap stator magnetic circuit the main (13) and the additional (14) parts. In the stator magnetic circuit the main (13) and additional (14) parts slots an armature winding (15) is laid. All of the said elements are located in the housing (16). Combined excitation electric machine (CEEM) contains its output voltage stabilization unit (19) (VSU) as a function of the shaft 1 rotational speed changing, which includes the power part (20) (VSU PP) and the VSU PP (20) control system (21) (CS). Units (20, 21) required power supply is provided the in-house needs power supply unit (INPSU) (22). At the ƒ>ƒfrequency the control system (21) (VSU CS), using information from the armature winding (15), generates control signals for the VSU (19) power part (PP) (21) key elements, which provides a in the applied by the brushes (10) to the contact rings (8) voltage polarity change, therefore, the current in the excitation winding (7) changes its direction to the opposite one, induced by an additional inductor, voltage in the armature winding (15) changes its sign to the opposite, and the induced by the inducers in the winding (15) voltages are not added but subtracted.EFFECT: increase in the stabilization process energy efficiency.1 cl, 2 dwg

Description

The invention relates to the field of electrical engineering, namely to electric generators with variable shaft speed and is intended for use in the construction of alternating current and direct current generators for power supply systems of autonomous objects, primarily for aircraft (where the minimum possible weight and dimensions and contactlessness are required) as well as in wind energy.

A known method of stabilizing the voltage of a generator with a varying frequency of rotation of the shaft and combined excitation, described in p. 292 fig. 9.28 Power supply for aircraft / V.A. Balagurov, I.M. Besedin, F.F.Galteev, N.T. Koroban, N.Z. Mastiaev. - M.: Mechanical Engineering, 1975 .-- 536 p.). This method is implemented in a generator made in the form of a synchronous electric machine with excitation from permanent magnets, on the stator magnetic circuit of which there is an anchor winding and a magnetization winding connected to the output of the voltage regulator. The method of regulating the voltage in the direction of its reduction is provided by increasing the degree of saturation of the stator magnetic circuit by reducing the value of its induction. As a result of magnetization of the magnetic circuit, the magnetic flux and the working induction in it decrease, therefore, the generator voltage also decreases.

The disadvantage of this solution is the reduced energy efficiency.

Closest to the technical nature of the invention is a method of stabilizing the voltage of the generator (with a variable shaft speed and combined excitation - KMEG), described, for example, on page 183 fig. 6.19 Electrical equipment of aircraft: a textbook for high schools. In two volumes / ed. S.A. Gruzkova. - M .: MEI Publishing House, 2005 - Volume 1. Aircraft power supply systems. - 568 p.). This method is implemented in an alternating voltage generator (CMEG), in which the first (main) part of the inductor is based on permanent magnets, and the second (additional) part of the inductor is based on electromagnetic excitation. The field winding of the additional inductor is connected to the output of the voltage regulation unit (BRN). The stabilization of the output voltage of KMEG when changing the shaft speed is carried out by the BRN control system, which includes a negative feedback loop (COOS) on the voltage of the KMEG. The BRN power input is connected to the KMEG anchor winding, and its output is connected to the excitation winding of the additional inductor. When changing the shaft speed in the range from n _min to n _max , the excitation current changes from the maximum value to zero. When the rate of change of the shaft rotation speed K _n = n _max / n _min = 1,5 is the power of the additional part of the SG (additional anchor winding and inductor) S _add has 30% of the total power of the SG - S _SG .

The disadvantage of this method is to increase energy consumption, which increases in proportion to the frequency of rotation of the generator shaft: when K _n = n _max / n _min = 2 S _add = 0,5S _SG . The BRN power is in the same dependence on the parameter K _n .

The technical result of the method is to increase the energy efficiency of the stabilization process.

его изменяют от максимального значения до нуля при одном направлении тока в обмотке возбуждения регулируемого индуктора, во втором диапазоне изменения частоты от ƒ_ном до ƒ_max его значение изменяют от нуля до максимального значения, а направление тока в обмотке возбуждения меняют на обратное.This is achieved by the fact that the known method of stabilizing the voltage of a generator with a varying frequency of rotation of the shaft and combined excitation, containing the main inductor with excitation from permanent magnets and an additional adjustable inductor, including the excitation winding, and summing the induced voltage of these inductors in the common for two inductors winding, consisting in appropriate regulation of the current in the excitation winding of the additional inductor in one direction of its flow in the range the number of changes in shaft speed from the minimum - ƒ _min to the maximum value - ƒ _max , characterized in that in the first range of shaft speed from f _min to

it is changed from the maximum value to zero with one direction of the current in the excitation winding of the adjustable inductor, in the second frequency range from ƒ _nom to ƒ _max its value is changed from zero to the maximum value, and the direction of the current in the excitation winding is reversed.

The method consists not only in the nature of the change in the value of the excitation current of the pathogen in the second range, but also in a change in its direction.

The invention is illustrated by drawings, where in FIG. 1 shows a structural diagram of a device that implements the method, FIG. 2 graphs explaining the logic of the operation of KMEG when changing the shaft speed - n.

The circuit that implements a method of controlling the excitation by a combined magnetoelectric generator (KMEG), contains a main inductor including a permanent magnet 1, a sleeve of non-magnetic material 2, shaft 3, a combined ring-band 4, made by welding from parts of a magnetically conductive and magnetically non-conductive material, additional the inductor is made in the form of a magnetic circuit 5, a pole piece 6, field windings 7, contact rings 8, bushings 9 of insulating material, contact brushes 10 with the corresponding with leads 10 ₊ and 10 _- , bearings 11 and 12, the main 13 and additional 14 parts of the stator magnetic circuit, which are separated by a gap or non-magnetic material, the anchor winding 15 is laid in the slots of the main 13 and additional 14 parts of the stator magnetic circuit. All of these elements are located in the housing 16, which is connected to the bearings 11,12 by covers 17, 18. In addition, the electric machine (KMEG) contains a block 19 (BSN) for stabilizing its output voltage as a function of changing the speed of the shaft 1, which includes the power part 20 (MF BSN) 21 (SU) BSN MF control system 20. The required power supply nodes 20, 21 internally provides a power unit (BPVN) 22.

The above graphs explain the logic of the operation of CMEG when changing the frequency n rotation of the shaft 3. It shows the voltage dependence in that part of the armature winding 15, which is located in the main part of the magnetic circuit 13 and the voltage U _meg (n) induced by the first inductor, as well as the dependence of the adjustable part voltage in the armature winding 15, which is located in an additional part of the magnetic circuit, and the voltage U _emv (n) induced by the second inductor. The graphs are given for the range of variation of the shaft speed from "n _min = 6000 rpm to n _max = 9000 rpm and for the range from" n _min = 6000 rpm to n _max = 12000 rpm.

и

соответственно для 1-го и 2-го диапазонов изменения частоты вращения вала. В области частот от ƒ_min до ƒ_ном напряжение, наведенное в якорной обмотке индукторами имеют одинаковые знаки. Дополнительный индуктор совместно якорной обмоткой 15, расположенной под дополнительным индуктором, работает здесь в генераторном режиме.In the first frequency range of the rotation of the shaft 3 from the minimum value - f _min to the nominal value - f _{nom, the} adjacent poles of the main and additional inductors have the same polarity (for example, N _о and N _д ), and in the armature winding 15 from the main and additional inductors .ds E ₁ and emf E _{2 of the} same polarity, and the resulting emf E _Σ in the armature winding 15 is determined by their sum: E _Σ = E ₁ + E ₂ . Here, in the armature winding 15, the boost mode is realized, and the current in the field winding 7 has the same direction, and with increasing frequency of ƒ _min to ƒ _prefecture it through BSN 19 is automatically changed from the I _max to zero. This change in current is illustrated by the lines.

and

respectively for the 1st and 2nd ranges of variation of the shaft speed. In the frequency range from ƒ _min to ƒ _{nom, the} voltage induced in the armature winding by the inductors have the same signs. The additional inductor jointly with the armature winding 15 located under the additional inductor, operates here in a generator mode.

ток в обмотке возбуждения 7 дополнительного индуктора равен 0.At rated shaft speed

the current in the field winding 7 of the additional inductor is 0.

At a frequency ƒ> ƒ _nom , the control system 21 (SU BSN), using information from the anchor winding 15, generates control signals for key elements of the power part (MF) 21 of the BSN 19, which provides a change in the polarity of the voltage supplied through the contact brushes 10 and terminals 10 ₊ and 10 _- of the contact ring 8, whereby the current in the field winding 7 changes its direction and the voltage in the armature winding 15, induced an additional inductor changes its sign. In this case, the voltages induced in the armature winding 15 by the main and additional inductors are not summed, but subtracted. Ultimately, using information about the voltage of an electric machine (KMEG), stabilization of its voltage is provided when changing the frequency of rotation of the shaft 3.

и

(для 2-х диапазонов изменения частоты вращения вала). Здесь дополнительный индуктор с расположенной под ним частью якорной обмотки 15 работает уже не в генераторном, а в двигательном режиме. При этом к валу 3 прикладывается положительный момент, обеспечивающий снижение мощности, потребляемой от первичного источника механической энергии, обратно пропорциональное повышению частоты вращения вала.In the second range of variation of the shaft 3 speed from the nominal value - - _nom to the maximum ƒ _max - the adjacent poles of the main and additional inductors acquire different polarity (for example, N _о and S _д ), and in the anchor winding 15 from the main and additional inductors .ds E ₀ and emf E _d different polarity, and the resulting emf E _Σ in the armature winding 15 is determined by their difference: E _Σ = E ₀ -E _d . Here the voltage subtraction mode is implemented. The current in the excitation winding 7 changes its direction in the opposite direction, and with increasing frequency from ƒ _nom to посредством _max it automatically changes from zero to I _max by means of BSN 19. This change in current is illustrated by the lines.

and

(for 2 ranges of change of frequency of rotation of a shaft). Here, an additional inductor with a part of the armature winding 15 located below it is no longer operating in the generator mode, but in the motor mode. At the same time, a positive moment is applied to the shaft 3, which ensures a decrease in the power consumed from the primary source of mechanical energy, inversely proportional to the increase in the shaft speed.

Thus, in the full frequency range with a change in the rotational speed of the shaft 3 and at a given load, the CMEG automatically stabilizes the output voltage of the CMEG and the constancy of the power consumed from the source of mechanical energy.

The use of reverse excitation in a contactless combined magnetoelectric generator (KMEG) for a given range of changes in the shaft speed allows using the negative feedback loop - COOS on the output voltage of the KMEG to stabilize the output voltage as a function of the shaft speed. In this case, the required rigidity of the external characteristics of the CMEG is ensured even with disturbing influences on the load current.

The use of the invention allows to halve the power of the additional inductor and half the power of the BSN and, accordingly, significantly improve the electromagnetic compatibility as a whole. This is achieved in a special way of changing the excitation current of a generator with a variable shaft speed, which consists in a corresponding (according to a special law as a function of shaft speed) change not only the value of the excitation current of the pathogen, but also under certain conditions and its direction.

Claims (1)

A method of stabilizing the voltage of a generator with a varying shaft speed and combined excitation, comprising a main inductor with excitation from permanent magnets and an additional adjustable inductor including an excitation winding, and summing the voltage induced by these inductors in the armature winding common to the two inductors, which consists in appropriate regulation current in the excitation winding of the additional inductor in one direction of its flow in the range of rotation frequency ala from the minimum - ƒ _min to the maximum values - ƒ _max , characterized in that in the range of shaft speed from ƒ _min to

it is changed from the maximum value to zero for one current direction in the excitation winding of an additional adjustable inductor, in a different frequency range from ƒ _nom to ƒ _max its value is changed from zero to the maximum value, and the current direction in the excitation winding is reversed.

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