SU765972A1 - Method and device for shaping wide pulses for control of power-diode converters - Google Patents

Description

The invention relates to electrical engineering and can be applied in DC and AC converter valves, as well as in electric drives.

There is a known method of forming wide control pulses by converting them into packets of short pulses. The generation of short pulses is provided when a negative voltage half-wave is applied, and the generation failure is caused by the application of a blocking pulse into which the positive half-wave voltage l is converted. However, the wide pulses for control, obtained after straightening a packet of short pulses, are characterized by significant pulses.

The closest in technical essence and the achieved result to the invention is a method of forming wide pulses for controlling valve converters, which means that wide pulses transform into packets of short bipolar pulses by separately transmitting paraphase signals through information and energy channels, the formed packets transform

to another potential level, followed by rectification 2.

This method is implemented by a wide pulse shaping device for controlling power gate converters, which contains information and power channels, an isolation pulse transformer and a rectifier. With this device, wide pulses are converted into bipolar rectangular-shaped pulses of increased frequency and of the same duration, which transform to another potential level. The first half-wave of the transformed alternating voltage is used to store energy in the capacitor, and the second half-wave to control the process of transferring the stored energy (discharging the capacitor through the thyristor) to the control electrode of the power valve.

Claims (2)

The disadvantage of this method, as well as all known ones, is that it does not ensure high reliability of power valve transducers, especially high-frequency alternating current, since its use does not exclude the effect of short pulse frequency switching on the leading edge of a wide 1 U1 pulse. and it does not ensure the required slope of the falling edge, since the discharge of the capacitor takes a long time to stop the effect of the transformed alternating voltage. The aim of the invention is to increase the reliability of the converter by eliminating the effect of commutation of the frequency of the following bipolar pulses on the leading edge of a broad pulse and forming its trailing edge at zero magnetization current. This is achieved by the fact that in the method of forming wide pulses for controlling power valve converters, which means that wide pulses transform into packets of short bipolar pulses by separately transmitting paraphase signals through information and energy channels. the level followed by the rectification of one of the paraphase signals is converted into a sequence of gating pulses, selected in the order of the distribution in the times and wide pulses are detected, and an information signal is received, and the second paraphase signal is divided in two by the following frequency, and a pulse selection of the received sequence of energy pulses by the information signal is performed. FIG. Figure 3 shows the oscillogram of the paraphase signal of the reference follow frequency; in fig. 4 - oscillogram frame of the gating pulse sequence; in fig. 5 is an oscillogram of a sequence of pulses after dividing the original signal by frequency in half; in fig. b - oscillogram of the formed front edge of a wide pulse for control; in fig. 7 is an oscillogram of a molded trailing edge of a wide pulse for controlling -, fi, g. 8 Oscillogram of magnetizing current. FIG. Figure 1 shows the functional scheme of the device in which the proposed method is implemented; in fig. 2 timing diagrams explaining the operation of the device. The formation of wide pulses to control the valve transducers is carried out on the basis of paraphase signals of the reference frequency following (see Fig. 3) through two channels: information and energy. One of the paraphase signals is fed to the input of the information channel and converted into a sequence of gating pulses (see Fig. 4). Pulse selection of this sequence is performed in the order of time distribution of wide pulses. Packets of gating pulses are detected and, at the output of the specified channel, an information signal is received on the distribution in time of the front and rear edges of wide pulses. The second paraphase signal is fed to the input of the energy channel. This signal is divided in half by the following frequency. The resulting sequence of energy pulses, shown in FIG. 3, is selected according to the information signal. The result is a series of packets of short energy pulses. The leading edge of each packet shown in FIG. 4, corresponds to the instant of coincidence of the leading edge of the information signal with the middle of the next subsequent energy pulse, and thus eliminates the effect of commutations of the bipolar pulse frequency. The falling edge of each packet, shown in FIG. 5 corresponds to the instant of coincidence of the wide-pulse trailing edge with the middle of the nearest subsequent energy pulse, i.e. the zero magnetization current shown in FIG. 6. Thus, guarantee the steepness of the back front. Formed packets of energy pulses enhance. Paraphase energy pulses are converted into short bipolar pulses of equal duration and frequency. The bipolar short impulse packets are transformed to a potential level, rectified, and wide impulses with guaranteed steepness of the front and rear fronts are sent to the control electrodes of the power gates. The device for forming wide pulses of control of converter converters has two channels: information and energy. Information channel contains one-shot. 1, the input of which is connected to one of the outputs of the generator 2 paraphase signals of the reference frequency, and the output from the inputs of elements 3 and 4 of the delay, made according to the coincidence circuit, the output of the wide pulse generator (not shown) is connected to one of the delay elements directly and to the second, via inverter 5. In addition, the information channel contains an RS flip-flop b, acting as a detector, which with its inputs is connected to the outputs of elements 3 and 4 of the delay, and the output to the input of the distributors 7 and 8 paraphase signals, nnyh by the coincidence circuit. The energy channel contains a discrete frequency divider 9, the input of which is connected to the output of the generator 2, and the output is connected to the second inputs of the distributors 7 and 8 paraphase signals, the outputs of which through the power amplifiers 10 and 11 are connected to the primary winding of the pulse transformer 12, Outgoing device 13 performed by a push-pull scheme. The generator 2 generates paraphase signals of the reference frequency (see Fig. 8). From one of the outputs of the generator 2, the paraphase signal is fed to the one-oscillator 1, which differentiates them along the leading edge into the gating pulses cf. The C signal from the wide pulse generator through the information channel is fed to the input of delay element 3, and the inverted one to the input of element 4. Thus, gating pulses appear in relation to the first of which the front edge of the information signal C is held by the value of T. The falling edge of the information signal C is delayed until the next gate pulse by the value T. The RS flip-flop remembers the levels of the information signal along the leading and trailing edges. From the second output of the generator 2 through the energy channel, the paraphase signal of the reference frequency is fed to a discrete frequency divider 9, during which you receive paraphase signals f and (see Fig. 8), the frequency of which is half the reference frequency while their midpoints coincide with the moment the appearance at the output of the one-shot 1 strobe pulse. The pairs of phase signals f and are fed to the first inputs of the valves 7 and 8 of the paraphase signals, to the second inputs of which an information signal is fed from the RS flip-flop 6. By supplying the phase signals alternately through the power amplifiers 10 and 11 to the beginning and the end of the primary windings of the primary winding of the JI power transformer 12, the power supply source EP is connected. In this case, a wide pulse and a bi-polar filling of the pulse are generated. From the output device 13, the signal Ug is captured. It contains information and energy of a wide control pulse with steep fronts and back edges. Claim 1. A method of forming wide pulses for controlling power valve converters, which consists in converting wide pulses into packets of short bipolar pulses with separate transmission of paraphase signals through information and energy channels, transforming the packets into another potential level with subsequent rectifying It is characterized in that, in order to increase the reliability of the operation of valve converters by eliminating the effect of frequency commutation Studying bipolar pulses on the leading edge of a wide pulse and forming its trailing edge at zero magnetization current; one of the paraphase signals is converted into a sequence of gating pulses, selected in the order of time distribution of wide pulses, detected, and an information signal is received, and the second paraphase signal divided by frequency in half, and pulsed selection of the sequence of energy pulses received by the information signal is made. 2. An apparatus for carrying out the method of forming wide pulses for controlling power valve converters according to claim 1, comprising information and power channels, a switching pulse transformer and a rectifier, which is only because the information channel contains an RS-flip-flop, an inverter, a single-oscillator and delay elements, the energy channel contains a discrete divider, and in the information channel the first inputs of the delay elements are connected via a one-shot to the output of a paraphase signal generator frequency, and the second inputs - to the output of the wide pulse generator, so that one of them is connected to the last directly, and the other through an inverter, their outputs are connected to the RS-flip-flop inputs, the output of which is connected to the first of two inputs of paraphase distributors, the second inputs of which are connected to the corresponding outputs of the discrete frequency divider of the energy channel, the input of which is connected to the output of the paraphase signal generator. Sources of information taken into account during the examination 1. USSR author's certificate number 424280, cl. H 02 R 13/16, 1974. 2. Published for the Federal Republic of Germany No. 2436282, cl. H 02 M 1/04, 1976. 1