SU1513586A1 - Method of controlling voltage regulator - Google Patents

Abstract

This invention relates to electrical engineering and can be used in variable voltage regulators. The purpose of the invention is to expand the range of regulation. For a voltage regulator containing an inverter with two branches and a demodulator on AC switches connected first in parallel to the load, the second in series with the first, two reference pulse sequences and two main adjustable high frequency pulse sequences are set, the reference sequences are fed to pairs of diagonal keys of the demodulator, changing the phase of the adjustable sequences, and applying them to two keys of the first branch of the inverter, and also carried out pulse-width modulation of the reference sequences of pulses and forming two additional pulse sequences with varying relative emoy main phase, which is supplied to the second inverter branch keys provide output voltage regulation over a wide range. 5 il.

Description

The invention relates to electrotechnical and can be used in variable voltage regulators.

The aim of the invention is to expand the range of regulation.

FIG. 1 shows a functional diagram of an apparatus for implementing a method for controlling a voltage regulator; in fig. 2 shows an embodiment of a pulse distributor; in fig. 3 shows the implementation of a pulse width modulator; in fig. 4 shows an exemplary embodiment of a bypass device; on

FIG. 5 - timing charts, explaining the operation of the voltage regulator.

The voltage regulator contains input 1 and output 2 filters with a common car 3, bridge inverter 4 and demodulator 5, made on alternating current keys 6-13. The primary winding of the high-frequency boost transformer 14 is connected to the inverter 15 and 16 terminals, and the input terminals 17 and 1B connected in parallel with the output filter 2. The secondary winding of the transformer

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pa 14 is connected to the terminals 19 and 20 of the demodulator 5, which is connected by the terminals 21 and 22 between the input and output 2 filters. The key control unit 23 comprises a master oscillator 24, the output of which is connected to the first input of the distributor 25 pulses, the clock input 26 of the pulse-width modulator 27 and the control inputs 28 of the phase-shifting devices 29-32. pulse modulator 27 is connected to the second input of the distributor 25 pulses. The control inputs 33 of the phase-shifting devices 29 - 32 are combined with the control input 34 of the pulse-width modulator 27 and connected to the control input 35 of the controller. The control inputs of keys 6–9 of demodulator 5 are connected in pairs to outputs 36 and 37 of a distributor 25 pulses, and the control inputs of non-adjacent opposite keys 6 and 9 of bridge demodulator 5 are connected to output 36 of a distributor 25 pulses, and the control inputs of keys 7 and 8 to the output 37. The control inputs of the keys 10-13 of the inverter 4 are connected to the outputs of the phase-shifting devices 29–32, respectively.

The pulse distributor 25 contains, for example, two elements 2И 38 and 39, one of the inputs is combined and forms the first input of the distributor 25 pulses, and an inverter 40, the output of which is connected to the second input of one of the elements 2И 38. The input of the inverter 40 is connected to the second input of the element 2I 39 and forms the second input of the distributor 25 pulses, and the output of the elements 2I 38 and 39 form the outputs 36 and 37.

The pulse width modulator 27 can be implemented as follows. The sawtooth voltage generator 41, whose input forms the clock input 26 of the pulse-width modulator 27, the output is connected to the first input of the comparator 42, one input of which is connected to the output of the amplifier 43, one input of which is connected to the output of the bias voltage source and the other input forms the information input 34 of the pulse-width modulator 27.

Each of the phase-shifting units 29–32 contains a sawing voltage generator 44 and two comparators

45 and 46. The first inputs of which are connected to the output of the generator 44 of the saw-tooth voltage, and the second inputs are connected to the outputs of the amplifiers 47 and 48, respectively. The output of each comparator 45 and 46 is connected to one of the inputs of element 2I-NOT 49, the output connected to one of the inputs of the EXCLUSIVE OR element 50, the second input of which is connected to the synchronizing input 28 of the phase-shifting unit 29 ..

FIG. 5 denotes the voltage 51 at the output of the master oscillator 24, the voltage 52 at the output of the sawtooth generator, the voltage

53 to control input 35, at the output of amplifiers 47 phase shifters 29 and 30, and at the output of amplifier 48 phase shifters 30, voltage

54 on the output of the amplifier 47 phase-shifting units 31 and 32 and at the output of the amplifier 48 phase-shifting unit-. 31, the voltage 55 at the output of the amplifier 43 and at the output of the amplifier 48 of the phase-shifting unit 29, 32, the voltage 56 at the output of the comparator 45 of the phase-shifting blocks 29, 30 and the comparator 46, the voltage 57 at the output of the comparator 45 of the phase-shifting blocks 31, 32, and the comparator 46 of the phase-shifting unit 31, the voltage 58 at the output of the comparator 42 and the comparator 46 of the phase-shifting units 29, 32, the voltage 59 at the output 36, the voltage 60 at the output 37, the voltage 61-64 at the outputs of the phase-shifting units 29 - 32, supply voltage 65 and voltage 66 at the output of the output filter 2.

The voltage regulator operates as follows.

The pulse sequence voltage 5 from the output of the master oscillator 24 is fed to the first input of the distributor 25 pulses and the clock inputs 28 of the phase-shifting blocks 29–32 and the pulse-width modulator 27. At the outputs of the generators, linearly varying voltage is generated at the outputs of the generators 52, arriving at the input of the comparators. At the same time, the control input 34 of the pulse-width modulator 27 and the control inputs 33 of the phase-shifting units 29–32 come from the control input 35 of the voltage regulator 53. The amplifiers 47 of the phase-shifting; blocks 29, 30 and the amplifier 48 of the phase-shifting unit 30 pa515

It works in repeater mode and a similar voltage 53 is formed at their inputs. The amplifiers 47 phase-shifting blocks 31, 32 and the amplifiers 48 of the 30- and 30-shift blocks 29, 31 and 32, as well as the amplifier 43 of the pulse-width modulator 27 work in the subtractor mode, the voltage 53 is applied to one of the inputs, and the other input is a constant bias voltage equal to the amplitude of the sawtooth voltage 52. At the outputs of the amplifiers 47 phase-shifting blocks 31, 32 and the amplifier 48 of the phase-shifting unit 31 voltage is 54 and the output of the amplifier is 43 and the amplifiers 48 of the phase shifting units 29, 32, a voltage 55 is generated. As a result of comparison of the sawtooth voltage 52 and the voltage 53, the output of the comparators 45 of the phase shifting units 29, 30 and the comparator 46 of the phase shifting unit 30 forms a voltage 56. On the comparators 45 of the phase shifting units 31, 32, and the comparator 46 of the phase-shifting unit 31, sawtooth voltage 52 and voltage 54 are compared, and voltage 57 is formed at their outputs. Voltage 58 is obtained by comparing saw voltage 52 and voltage 55 at comparator 42 and the comparators 46 phase-shifting units 29 and 32.

The pulse distributor 25 distributes the pulses 58 to the control inputs of the keys 6-9 of the demodulator 5 in accordance with the voltage 51 at its first input, so that the keys 6 and 9 on one conversion frequency and the keys on the other input 7 and 8. From the output 36 of the distributor 25 pulses, the control inputs of the keys 6 and 9 receive voltage 59, and from the output 37 to the control inputs of the keys 7 and 8 - voltage 60.

The voltage 61 formed at the output of the phase-shifting unit 29 is fed to the control input of the key 10 of the inverter 4, respectively, the voltage 62 - 64 - to the control inputs of the keys 11-13.

In the time interval t, -to, in accordance with voltages 62, 63, 59, the keys 11 and 12 of the inverter 4 and the keys 6 and 9 of the demodulator 5 are closed. The primary winding of the additional transformer 14 is shorted by the switches 11 and 12 of the inverter 4 and the supply voltage nets

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through the closed keys 6 and 9 enters the load in undistorted form. In the time interval, the keys 10, 12 and the keys 6, 9 are closed in accordance with the voltages 61, 63, 59 at their control inputs. The keys of the demodulator 5 connect the secondary winding of an add-on transformer to the CMM so that the voltage on it is added to the supply voltage 65 and the sum of these voltages is applied to the output filter 2. The change in time intervals and

5 2 in this case ensures the regulation of the voltage applied to the load upwards from the nominal value of the supply voltage. In this case, a controlled voltage boost mode is implemented.

In the time interval t.-t, the keys II, 13 and the keys 6, 9 are closed in accordance with the voltages 62, 64, 59 at their control inputs. The voltage

5 of the secondary winding of the booster transformer 14 is subtracted from the supply voltage 65 and their difference is applied to the output filter 2. In the interval t, ..- t, 0 undistorted voltage is applied to the output voltage of the power line 2, since the primary winding The add-on transformer 14 is shorted by the switched on keys 10 and 13, and the keys of demodulator 5 are closed according to the algorithm 6.9 - 7.8 (digits separated by a comma indicate the simultaneously switched state of the keys). Relative change in the duration of the intervals

.Q time and tg-t allow adjustment of the average value of the voltage across the load down from the nominal mains voltage to the maximum voltage boost. , In the interval, the demodulator keys are open, and the keys 10 and 11 are switched on in accordance with voltages 6 1, 62 at their control inputs. In this case, the supply network is

fj disconnected from the load and voltage 66 at the output of the output filter is zero, the switched on keys 10, 11 close the reactive load current. In the interval tg-t, the keys 1, 6, 9, and the keys 11, 13, in accordance with the voltages 59, 62, 64, and the output filter, are applied a voltage difference 65 and the voltage across the secondary winding of the additional transformer5

torus 14. In the alternation of such intervals, the pulse-width regulation of the output bore is in the range from the maximum additive to zero. When the voltage 53 at the control input 35 varies from zero to a voltage equal to the amplitude of the sawtooth voltage changes from zero to iT pa-) Q cyan, the phase if of the pulse sequences 61, 62 applied to the control inputs of the keys 10 and 11, and from zero to IT radians in the direction of the advance of the phase 15 behind adjustable sequences of pulses 63 and 64 supplied to the control inputs of the keys 12 and 13. The reference sequences of pulses 59 and 60 formed at the outputs 36 20 and 37 are fed to the control inputs of the keys 6. -9. The algorithm for switching the keys of the inverter 4 and demodulator 5, which is determined by the reference and adjustable pulse sequences, supplied to their control inputs, allows the output voltage to be controlled by an additional voltage transformer 14, i.e. . Output voltage control 30 is made by varying the average value of the secondary voltage of the transformer 14, which is summable or subtracted from the network voltage. In this case, the following operating modes are implemented: the maximum voltage boost mode, the undistorted power supply voltage transfer mode to the load, the variable voltage boost mode, and the maximum power boost mode.

A further increase in the voltage at the control input 35 provides pulse width control of the reference sequences of pulses supplied to the control inputs of the gateway 6 to 9, and synchronous change of the phase of the adjustable sequences of pulses fed to the control inputs of the keys 10 and 13, In this case, the phase of the pulse sequences supplied to the control inputs of the keys 11 and 12 remains fixed. In the time interval, all the keys of demodulator 5 are turned off, the network is disconnected from the load, and the voltage 66 at the output of the output filter 2 is zero. The keys 10 and 11 are closed at this time and provide a flow

reactive load current and throttles of the output filter 2. At the time interval tg-t, the network is connected to the load by keys of demodulator 5, and the difference between the network voltage and the secondary winding of the transformer 14 is applied to the output filter 2.

In this way, the output voltage in the zone from the maximum voltage boost mode to zero is controlled. Regulation in this zone is also possible when applying adjustable sequences of pulses, the phase of which changes synchronously with the pulse-width modulation of the reference sequences of pulses applied to the control inputs of keys 1 and 12, while simultaneously fixing the phase of the sequences of pulses fed to the control inputs of keys 10 and 13,

Thus, the application of the proposed method of controlling the voltage regulator allows adjusting the output voltage from zero to maximum voltage mode, which expands the range of output voltage regulation while maintaining high technical and energy indicators.

Claims (1)

Formula isobuty The method of controlling a voltage regulator containing an inverter with two branches and a demodulator on AC switches connected to the first parallel to the load, the second in series with the parallel connected load and the inverter, consisting in that the control signal is set, two reference pulses are set and two main adjustable sequences, high frequency pulses, feed the reference pulse sequences to the corresponding pairs of diagonal keys of the demodulators, change the registration phase liruemyh pulse sequences in the range of + 1G ... radians relative to the reference pulse sequences is proportional signal control fed adjustable basic pulse sequence into two branches corresponding to the first inverter switch, characterized in that, with a view to controlling the spreading range. pulse width modulation of the reference pulse sequences is proportional to the control signal; two additional variable pulse sequences are formed, the phase of which changes with respect to the main adjustable pulse sequences in proportion to the control signal, additional adjustable pulse sequences are applied to the corresponding keys of the second inverter branch. 36 37 Z5 38 39 0 1 / 7 26 four-/ zi / 4J Fig.z sunncmI1 I-P I 5f i 1sty X 55 jj 57 jziHz ± 59 Srig. i 1sty : l E ± l