SU993402A1 - Device for compensating higher harmonics - Google Patents

Description

(54) DEVICE FOR COMPENSATION OF HIGHER HARMONICS

Claims (2)

The invention relates to a device for the compensation of the conductors of a voltage voltage, and can be used to power the thyristor converters from a synchronous generator. A device for compensating higher-order harmonics on the buses of a synchronous generator is known, comprising a static converter connected to a synchronous generator and an additional power source connected to each zero point of the generator and the converter outputs. The additional source is a triple frequency harmonic generator that compensates for harmonics, due to & data from the work of the thyristor transform of the bodies Cl. However, this device requires a significant triple frequency source. So, for example, to compensate for the fifth harmonic down to zero, the input current to the rectified voltage is 0.5. In addition, the introduction of a third-harmonic current creates a flux of induced magnetization; the magnetizing current increases significantly, in which abnormal harmonics appear. The closest in technical essence to the present invention is a device for compensating higher harmonics, containing a three-phase synchronous generator, to the stator windings of which a static converter is connected, and the CS-type 2. However, the known device has the disadvantages of having an additional voltage harmonic generator, which complicates the device. In addition, the harmonic generator generates unnecessary harmonics in the network, which are absent in the spectrum of the converter, in order to compensate for the need to install passive UC filters. The purpose of the invention is to simplify the device, adjusting the level of high-harmonic compensation. The goal is achieved by the fact that in a device for compensating higher harmonics containing a three-phase synchronous generator, to the stator windings of which a static converter is connected, and L, C-filters, in each phase the stator winding of the synchronous generator is equipped with an additional winding connected to the parallel HC circuit. having a transformer connection with a stator winding. The drawing shows an electrical circuit of a device for compensating higher harmonics. A device for compensating higher harmonics of voltage on buses of a synchronous generator contains a synchronous generator 1, a converter 2 connected to it and a load 3. Each phase of the stator winding 4 is superimposed aonon bearing punching 5, the ends of which are connected to two parallel branches consisting of a capacitor 6 and inductance 7 of the resonant L, C-circuit. The device works as follows. When connected to the terminals of generator 1 of converter 2, higher harmonics of current appear in the network. The presence of higher current harmonics in the generator leads to a voltage distortion at the generator terminals due to the voltage drop at the super-intermediate inductive resistance. The flow of higher harmonics is induced by the EMF on the additional winding 5. The inductive resistance of the additional winding 5 is chosen to be equal to the average inductive resistance of the generator in super-inter-x mode, i.e. d 2 is the resistance of the reverse sequence, is the super transition resistance of the generator. When the additional winding is closed to the resistance, which is used by the CS circuit, a current flows in the additional winding and a magnetic flux appears that is directed opposite to the magnetic flux of the higher harmonics of the stator winding of the generator. The parameters of the second winding are selected in such a way as to ensure the equality of magnetic fluxes from higher harmonics in the generator's winding and in the additional winding 5. Under this condition, the coefficient of the magnetic connection between the stator winding of the generator and the additional winding equal to one will be assumed compensation of magnetic fluxes of higher harmonics and inductor impedance of the generator in the supertransient mode. Since the excitation controller of a synchronous generator responds to the average or effective value of the voltage deviation, the instantaneous change in the magnetic flux from higher harmonics is not restored by the controller. Simultaneously with the higher harmonics, the 1st harmonic emf is induced in the additional winding and there is a first harmonic flux directed against the magnetic flux of the first harmonic of the stator winding. To eliminate this drawback, the additional winding is reduced to two parallel branches of the resonant L C-circuit. When tuning in the resonance of parallel 1, C-circuit at a frequency of 5O Hz, the current of the first harmonic from the EMF of the additional winding will close inside the L-C circuit. In the additional winding, the current of the first harmonic and, accordingly, the flow will be minimal. Thus, at the super-transient inductive impedance of the generator, only the flux from higher harmonics will be compensated, the first harmonic remains unchanged. Physically, this means a reduction in the super-interme- diate resistance of the generator to second harmonics. Thus, the present invention allows, at a relatively small capacitance and inductance, to achieve a significant decrease in the voltage drop across the higher harmonics on the internal resistance of the generator, which ultimately simplifies the device, increases the compensation level of the higher voltage harmonics, and ensures sinusoidal voltage on the press of the generator. Apparatus of the invention for compensating higher harmonics, containing a three-phase synchronous generator, to the stator windings of which a static converter is connected, and L, C-filters, characterized in that, in order to simplify and increase the level of compensation of higher harmonics, the stator winding in each phase synchronous generator equipped with a 5 & 934026 Connected to a parallel IC-contour l-Tlie Protodint rs of ttie Jnsiitu with an additional winding having a transmission of Eeectricae En ineer5. Formatorno connection with the stator winding T-7, 1972, p. 357. Sources of information taken into account in the examination 2. US patent Me 3825814, cl. H O2M 1/12, 1974.