SU1026261A1 - D.c. voltage-to-stepped voltage static converter - Google Patents

Abstract

STATIC DC converter into a stepped variable, comprising a first inverter, whose output is connected to the primary winding of the intermediate transformer, the secondary windings of which: through the rectifiers are connected to the transducer cells of the second inverter kotoryhvklyucheny outputs sequentially gripping load about Whitlock ich and w u and u so that, in order to improve the quality of the output transducer output, by additionally excluding from it the highest harmonic component of the Mth order, This intermediate transformer is provided with an additional winding, connected in a counter-sequential manner to the load circuit, the first inverter being made with an operating frequency of the output voltage more than once the working frequency of the output voltage of the inverter. V) with S

Description

The invention relates to electrical engineering and can be used in power supply and electric drive systems of industrial plants and vehicles for converting a constant voltage into a stepwise, close to sinusoidal alternating voltage. Known static converters of direct voltage into step-alternating voltage are known, containing several klevevy bridge amplifiers with output transformers, the secondary windings of which are connected in series and form a load circuit 1. The closest technical solution to the proposed is a static converter of constant voltage to step-like variable, containing the first inverter, the output of which is connected to the primary winding of the intermediate transformer, the secondary windings of which you have p DC converter connected to the transducer cells of the second inverter, the outputs of which are connected in series in the load circuit 2 A disadvantage of such transducers is a considerable weight and dimensions of the output transformers, especially at relatively low output frequencies (Hz). The purpose of the invention is to increase the quality of the output voltage by additionally excluding the highest harmonic component of the C-th order from it. The goal is achieved by the fact that in a static converter containing the first inverter, the output of which is connected to the primary winding of an intermediate transformer, the secondary windings of which through rectifiers are connected to the npeoiSpao cells of the second inverter whose outputs are connected in series to the load circuit, the intermediate transformer is provided with an additional winding, back-to-back in the circuit, the load, the first inverter being performed with the operating frequency of the output voltage .v times the operating frequency of the output voltage of the second inverter. The drawing shows a diagram of the converter. The converter contains the first high-frequency inverter on transistors 1 and 2, the output of which is connected to the primary winding Wf of the intermediate transformer 3. The secondary windings of the transformer 3 (W2 and rectifier C and 5 are connected to converter cells of the second inverter, for example , on transistors shunted by opposite-connected diodes. The output circuits of the cells are connected in series and closed through the additional winding 8 (9 Udp) of the transformer 3 and the load 9 The control circuits of the transistors 1 and 2 are connected to the control unit 10, and the control circuits of the transistors-inverters 6, and 7 with the control unit 11, the filter 12-13 is turned on to the output of the converter. The converter operates as follows. Transistors 1 and 2 switchable through the high frequency half-period generate the voltage that, after rectification, is supplied to power the cells 6 and 7, the block 11 controls the transistors of the cells 6 and 7 in such a sequence so as to form a step voltage U with a minimum of the highest order harmonics. . . For example, if a pair of transistors of one cell is switched with a shift of 60 (in output frequency) relative to the other pair of transistors of a given cell, then the output terminal of the cell does not contain the third harmonic. If two such cells 6 and 7 are controlled with a mutual shift at (at the output frequency), then the voltage U will not contain the third and fifth harmonics. ; To improve the spectral composition of the output voltage of the converter, the winding 8 () is turned on counter to the output of the second inverter cells, and the switching frequency of transistors 1 and 2 is chosen greater than the output frequency by a number equal to the number of excluded harmonics, for example, 7 times. In this case, the output voltage of the converter. 310 (Uabij (U + U) does not contain 3, 5 and harmonics.,. Thus, the quality of the output voltage of the converter applied to the load 9 is increased, i.e. it contains less. High order harmonics, which have a detrimental effect on some types of loads 261 (selsins, rotary transformers, etc.). Given the quality of the output voltage, the proposed scheme allows us to simplify the device, since in a known scheme, instead of windings 8, we would have to introduce an additional bridge cell of cell type 6 and

Claims (1)

DC STATIC CONVERTER TO STAGE VARIABLE, containing the first inverter, the output of which is connected to the primary winding of the intermediate transformer, the secondary windings of which through rectifiers are connected to the converter cells of the second inverter, the outputs of which are connected in series to the load circuit, which is connected to I mean, in order to improve the quality of the output voltage. converter by additional exclusion from it of the highest harmonic component of the Nth order, the specified intermediate transformer is equipped with an additional winding included in the opposite sequence in the load circuit, moreover. the first inverter is made with an operating frequency of the output voltage N times greater than the operating frequency output! voltage of the second inverter.