RU96119946A - ELECTRONIC CIRCUIT FOR ELECTRIC POWER TRANSFORMATION - Google Patents

Claims (5)

1. A multi-level converter containing, in particular, between a voltage source (SE) and a current source (C) a sequence of controlled switching elements (CL1, CL2, ..., CLn), each of which has two keys (T1, T'1 ; T2, T'2; ...; Tn, T'n), moreover, one pole of each of the two keys forms part of a pair of ascending poles, and the other pole of each of the keys forms one of a pair of descending poles, a pair of descending poles of the ascending element is connected with a pair of ascending poles of the descending element, and a pair of ascending poles of the first element (CL1) with dinene with a current source (C), while the pair of downward poles of the last element (CLn) is connected to a voltage source (SE), and the converter additionally contains a capacitor (C1, C2, ..., Cn) for each element, except that the capacitor of the last element may be absent when the voltage source (SE) is suitable for the same role, each capacitor is connected between two poles making up a pair of downward poles of the corresponding element, and the converter also contains control means that controls the operation of the converter in the nominal mode by acting on the keys of consecutive elements in such a way that the two keys of any given element are always in the corresponding opposite states of conductivity, so that in response to the control signal (CT1, CT2, ..., CTn) supplied by the means control, one of the two keys in this element is sequentially in the first conduction state, and then in the second conduction state for a cyclically repeating period, and so that in response to control signals I am an element that are identical, but offset in time by a fraction of a specified period, the keys of consecutive elements work accordingly the same, but with a shift in time by a specified fraction of a period, sequential capacitors (C1, C2, ..., Cn) have correspondingly increasing nominal averages charge voltage, and the average charge voltage of the capacitor in each of the elements is equal to the product of the voltage (VE) from the voltage source (SE) by the reciprocal of the number of elements and the element rank, characterized in that contains a filter chain (CF) parallel to the current source (C) for preferred dissipation, at least in part, of the energy of any component having a frequency lying in a frequency band extending from the main frequency of the voltage supplied to the current source to a frequency of n times the frequency of the converter, also called the frequency of the chopper, where n is the number of stages in the converter, while these two frequencies are absent in the specified frequency band.  2. The multilevel converter according to claim 1, characterized in that the filter chain (CF) comprises at least one series circuit type RLC containing a resistor (Ra) and a series resonant circuit (La, Ca).  3. The multilevel converter according to claim 2, characterized in that the filter chain (CF) comprises a common resistor (Rax) connected in series with a plurality of series resonant circuits (La1, Ca1, La2, Ca2).  4. A multilevel converter according to claim 2 or 3, characterized in that the filter chain (CF) comprises a series resonant circuit for the frequency of the converter (Fd) and at least for some of its harmonics present with relatively higher amplitudes.  5. A multilevel converter according to claim 2 or 3, characterized in that any of the RLC series in question is resistor small enough to dissipate as quickly as possible the energy supplied by the converter at a frequency corresponding to the resonance frequency of any resonant circuit connected in series with the resistor, but at the same time large enough to avoid excess current damaging the converter keys.