RU96119989A - ELECTRONIC CIRCUIT FOR CONVERSION OF ELECTRIC POWER AND INSTALLATION OF POWER SUPPLIES IN WHICH IT IS USED - Google Patents

Claims (9)

1. A multilevel converter comprising, between a voltage source (SE) and a current source (C), serially connected controlled switching cells (CL1, CL2, ..., CLn), each of which has two switches (T1, T'1, T2 , T'2, ..., Tn, T'n), with one pole of each of the two switches forming part of a pair of upstream poles, and the other pole of each of the switches forming part of a pair of downstream poles, pairs below upstream of the poles of the cell located upstream, connected to a pair of upstream e downstream of the poles of the cell located downstream, a pair of upstream poles of the first cell (CL1) is connected to said current source (C), and a pair of downstream poles of the last cell (CLn) is connected to said voltage source (SE ), and the converter additionally contains a capacitor (C1, C2, ..., Cn) for each cell, while the capacitor of the last cell can be omitted, when the voltage source (SE) performs the same function, each capacitor is connected between two poles constitutinga pair of poles of the corresponding cell located downstream, the converter also contains means for controlling the operation of the converter by acting on the switches of subsequent cells in such a way that two switches of any given cell always appear in opposite states of electrical conductivity and in response to the cell control signal (CT1, CT2,. .., CTn), coming from the control means, one of the two switches in this cell is sequentially in the first state of electrical conductivity, and then in the second state conductivity during a cyclically repeated period, and in response to the control signals of the cell, which are identical, but shifted in time by a part of the said period, the switches of the subsequent cells operate, respectively, in the same way, but with a time offset by the said part of the period, and series capacitors (C1, C2, ..., Cn) have correspondingly increasing nominal average charge voltages, while the nominal average charge voltage of the capacitor in each of these cells is the product of voltage (VE) from the voltage source (SE) by the reciprocal of the number of cells and by the cell serial number, characterized in that it contains means (VMO1, VMO2, ..., VMOn) for estimating the average voltage at the terminals of each capacitor (C1, C2 ,. . ., Cn), a means of measuring any difference on each of the capacitors (C1, C2, ..., Cn) between the estimated average charge voltage and the rated average charge voltage of the capacitor and for the corresponding difference signals (VEC1, VEC2, .. ., VECn), and correction control means (BT, EC1, EC2, ..., ECn) receiving said difference signals and designed to control at least one temporary connection between two capacitors to correct said difference.  2. The multilevel converter according to claim 1, characterized in that the correction means comprises one correction circuit (EC1, EC2, .., ECn) for each capacitor in the converter, each circuit receiving one of the difference signals (VEC1, VEC2 ,. .., VECn) together with the enable signal for the sweep generator (BT) and responds to it by supplying one of two charge transfer control signals (CR1, CR1 ', CR2, CR2', ..., CRn, CRn ') designed for controlling the connection of the capacitor (C1, C2, ..., Cn), respectively, with an upstream circuit for th digit and the downstream circuit for recharging it.  3. The multilevel converter according to claim 2, characterized in that the circuit located upstream includes a capacitor directly of a lower serial number, if any.  4. A multilevel converter according to claim 2, characterized in that the circuit located downstream includes a capacitor with a directly higher serial number, if any.  5. A multilevel converter according to any one of the preceding claims, characterized in that the presence of at least one of the difference signals causes a correction cycle, during which the sweep generator sequentially unlocks the correction schemes (EC1, EC2, ..., ECn).  6. A multilevel converter according to any preceding paragraph, characterized in that the differences create a difference signal only if they exceed a predetermined threshold value.  7. A multilevel converter according to any preceding paragraph, characterized in that the amplitude of one of the difference signals characterizes the difference and determines the duration of the correction signal.  8. A multilevel converter according to any one of paragraphs. 1-6, characterized in that the correction signal has a predetermined constant duration corresponding to the increment of the correction.  9. A power supply installation comprising a multilevel converter according to any preceding paragraph.