SU395950A1 - CONVERTER WITH STABLE OUTPUT VOLTAGE - Google Patents

Description

one

The invention relates to the field of training technology and can be used in power supply systems and automatics.

Known converters with a stable output voltage consist of several cells, the outputs of which are connected in series and closed on the load. The output voltage in such converters is usually regulated in a static system.

In order to obtain an astatic voltage stabilization system and an increase in stabilization point to stabilize, the generator generators of the following system are preconditioned: the converter is connected in a circular cxeiMe mutual synchronic mode. These generators are powered through a voltage divider consisting of series-connected resistors and an aporio element and P1P) switch to the output of the L1M converter terminals.

FIG. 1 shows the scheme of the proposed converter, where / is the master oscillator of the main converter cell; 2 - the main converter cell amplifier; 3 - additional converter cells; 4 - voltage divider; 5-7 - master generators, respectively, of the first, second and third additional cells; S-amplifiers additional cells; 9 - amplifier output winding; 10 - straightener; // - synchronizing capacitors; 12, 13 are the connection points of the master oscillators, respectively, of the second and third additional cells to the voltage divider. On f “g. Figure 2 shows timing diagrams of the output voltage of the amplifiers.

The output windings 9 of the amplifiers are connected in series with each other and connected to the rectifier 10. The collectors of the transistors of the main master oscillator are connected, for example, through the synchronizing capacitors 11 to the bases of the transistors of the first additional cell, the collectors of the transistors of the first additional cell, to the bases of the transistors of the second, second headers - with bases of the third, collectors of the third - with bases of transistors of the main master oscillator. To the input of the master oscillator, under 1 “1”, a starting circuit of a resistor and a power supply source E, ensures a stable start of the circuit.

Consider a stabilization process, for example, as the input voltage increases.

With a low voltage of the power source E, the frequency of self-oscillations of each previous generator number in the order of the numbering of the additional cells of the frequency of the next and below the frequency of the main generator.

The main master oscillator synchronizes the temperature of additional cells, and the amplifiers operate synchronously. The output voltage is equal to the voltages on the windings of 9 amplifiers. With an increase in the voltage of the Istoch and ka power supply of the converter, the tests on the generators 5–7 grow. The frequency of self-oscillations of the generator 7 stays higher than the frequency of the generator /, and it switches from the synchronization mode to the self-oscillation mode.

Since the 3 rd sdvig phase is equal to the integral of the frequency difference between the oscillators / and 7, then the output voltage will change until the oscillator frequency does not match. With a subsequent increase in the input voltage or a decrease in the load, the phase shift between the generator voltages / and 7 ranges from 0 to 180 °. In this case, the width of the third additional step (Fig. 2, a) of the output voltage decreases so that the average value of the output voltage is constant.

With a further increase in the supply voltage E, the phase shift of the generator voltages / and 7 remains constant, the output voltage of the converter changes somewhat, and the generator / is synchronized by it / pulse generator 7.

Since with increasing voltage the potential of point 12 changes more dynamically than potential 13 (Fig. 1), the frequency of self-oscillations of generator 6 becomes less than greater than the frequency of generator 7, generator 6 switches from synchronization mode to self-oscillation mode. Processes flow like described. This changes the width of the second incremental stage:

output voltage (Fig. 2.6). A further increase in the input voltage changes the width of the first (Fig. 2, e) additional step of the output voltage. In this case, the generators Y and 7 are synchronized by the pulses of the generator 6, and in the a1 mode of oscillations there is a generator 5.

 Thus, the output voltage is regulated in amplitude by steps, and within the limits of each step in the width of the additional I1M pulse. This extends the operating voltage range of the converter power supply and reduces the ripple of the output voltage and current consumption. When the astatic nature of the stabilization of the output voltage is maintained.

Subject invention

A converter with a stable output voltage, consisting of several converter circuits, the outputs of which are connected in series and closed via a load cell, differing in that, in order to increase the voltage stabilization accuracy, the reference generators of the cells are connected to each other via synchronizing Circuit | Circuit Circular Circuit, some of the power supply terminals of these generators are combined, while others are connected to the corresponding output, a voltage divider consisting of series-connected pesHiCTopOB and about ornogo element and connected to vyhodnyl1 zazhemam converter.

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