RU2251777C2 - Redundant dc power supply - Google Patents

Abstract

FIELD: electrical engineering; secondary power supplies for home-made radio-electronic equipment.

SUBSTANCE: proposed redundant dc power supply has input terminals 1, 2 connected to ac power supply and used as channel inputs of regulated voltage converters; each channel incorporates power amplifier 3 whose inputs are connected to channel inputs and output, to primary winding of transformer 4 whose secondary winding extreme leads are connected to input of power rectifier 5; ripple filter 6 has its inputs connected to output of power rectifier 5 and to center tap of secondary winding of transformer 4; first lead is connected to first lead of voltage divided built around resistors 7, 8 and to anode of decoupling diode 9; second lead is connected to second lead of voltage divider and to second output of channel; cathode of decoupling diode 9 is connected to first output of channel and central lead of voltage divider, to first control input of control unit 10 whose first output is connected to first control input of power amplifier 3 and second output, to second control input of power rectifier 3; each channel also has rectifier diode 11, filtering circuit 12, error amplifier, and cutoff diode 14; input of rectifier diode 11 of each channel is connected to one of extreme leads of transformer secondary winding; output of rectifier diode 11 is connected to input of filtering circuit 12; output of filtering circuit of each channel is connected to first input of error amplifier 13 of first channel and to second input of error amplifier of second channel; output of filtering circuit 12 of second channel is connected to first input of error amplifier 13 of second channel and to second input of error amplifier 13 of first channel; output of error amplifier of each channel is connected through cutoff diode 14 to second control input of control unit 10 of respective channel.

EFFECT: enhanced quality of supply voltage.

4 cl, 1 dwg

Description

The invention relates to electrical engineering, in particular to sources of secondary power supply of critical electronic equipment.

Known stabilized DC voltage Converter containing a master oscillator, sawtooth generator, a comparator, a power amplifier, a rectifier, a filter, a feedback circuit, a frequency divider and two selectors, and the input of the divider is connected to the master generator, the inputs of the selectors to the outputs of the divider and the output of the comparator , and the outputs of the selectors to the input of the power amplifier [1].

Known stabilized DC-DC Converter allows you to get high quality output voltage and has reliability sufficient for a wide range of electronic equipment. A disadvantage of the known stabilized converter is that for particularly demanding consumers, for example, ground-based power supplies of on-board radio equipment of missile systems, the reliability of the known device is insufficient, which necessitates the reservation of stabilized DC-DC converters.

Closest to the proposed in its technical essence is a redundant DC power supply containing N parallel-connected converter cells, the control inputs of which are connected to the output of the control unit, the integrity control unit of the converter cells, made using AND, NOT, OR-NOT and peak elements detector, and the inputs of the AND element are connected to the in-phase intermediate outputs of the converter cells, and the input of the element is NOT connected to the output of the control unit, the inputs of the element are NOT connected to the outputs of AND and NOT, and the output - to the input of the peak detector. [2]

Known redundant DC power supply has a reliability sufficient to power especially critical consumers. A disadvantage of the known redundant power supply is that, due to the variation in the settings of the channel settings of the redundant power supply, one of the channels whose output voltage, albeit slightly exceeds the voltage of other channels, becomes the leading one and locks the control circuits of the remaining channels with its output voltage. During normal operation of the redundant power supply, i.e. if all channels are in good working order, as well as in the case of failure of any channel except the master, this drawback does not affect the quality of the output voltage of the power source and can be neglected. However, in case of failure of the lead channel due to the inertia of the backup channel control circuit and due to the presence of reactive elements in its power circuit for the duration of transients, a voltage drop occurs at the output of the redundant power source, which is unacceptable for electronic equipment.

The essence of the invention lies in the fact that the redundant DC power supply containing the first and second channels of stabilized voltage converters, the inputs of which are connected in parallel and connected to the primary power source, the outputs are connected in parallel and connected to the load, each channel includes a power amplifier the inputs of which are connected to the inputs of the channel, and the output is connected to the primary winding of the transformer, the extreme terminals of the secondary winding of which are connected to the input of the power rectifier, a smoothing filter, the inputs of which are connected to the output of the power rectifier and to the midpoint of the secondary winding of the transformer, the first output is connected to the first output of the voltage divider and the anode of the decoupling diode, and the second output is connected to the second output of the voltage divider and the second output of the channel, the cathode of the decoupling diode is connected to the first output of the channel, and the middle output of the voltage divider is connected to the first control input of the control unit, the first output of which is connected to the first unit with the input of the power amplifier, and the second output with the second control input of the power amplifier, a rectifier diode, a filter circuit, a mismatch amplifier and a cut-off diode are introduced into each channel, and in each channel the input of the rectifier diode is connected to one of the extreme terminals of the transformer secondary winding, the output of the rectifier diode is connected to the input of the filter circuit, the output of the filter circuit of the first channel is connected to the first input of the mismatch amplifier of the first channel and to the second input of the amplifier popping a second channel, the second channel output of the filter circuit is connected to the first input of the error amplifier of the second channel and the second input of the error amplifier of the first channel, and outputs the error amplifiers of each channel through clipping diode connected to the second control channel corresponding to the management node entry.

The power amplifier of the redundant DC power supply includes a bridge voltage transistor, the first diagonal of the bridge converter is connected to the inputs of the power amplifier, the second diagonal of the bridge converter is connected to the outputs of the power amplifier through an isolation capacitor, and the control inputs of the transistors of the bridge converter are connected to the drivers control inputs of the power amplifier.

The control unit includes a master oscillator, the output of which is connected to the input of the sawtooth voltage generator and the trigger input, the outputs of which are connected to the first inputs of two selectors, the second inputs of which are connected to the output of the comparator, the first input of which is connected to the output of the sawtooth voltage generator, and the second input connected to the output of the amplifier of the error signal, the inputs of which are the control inputs of the control unit, the second input of the amplifier of the error signal through the resistor n with the reference voltage output, and the selector control unit outputs are the outputs.

The filter circuit includes a resistor and a capacitor, the first output of the resistor is the input of the filter circuit, and the second is connected to the first output of the capacitor, and the terminals of the capacitor are the outputs of the filter circuit.

The proposed technical solution allows loading the backup channel of the DC voltage power supply, which allows in the event of a failure of the main channel to eliminate output voltage dips, thereby ensuring high voltage quality even in emergency conditions.

The drawing shows a functional diagram of a redundant DC power supply, consisting of two channels.

The redundant DC power supply contains input terminals 1 and 2 connected to the primary power source and which are the channel inputs of stabilized voltage converters, each channel includes a power amplifier 3, the inputs of which are connected to the channel inputs, and the output is connected to the primary winding of transformer 4, the extreme terminals of the secondary winding of which are connected to the input of the power rectifier 5, a smoothing filter 6, the inputs of which are connected to the output of the power rectifier 5 and to the midpoint a secondary winding of the transformer 4, the first terminal is connected to the first terminal of the voltage divider on resistors 7 and 8 and the anode of the decoupling diode 9, and the second terminal is connected to the second terminal of the voltage divider and the second output of the channel, and the cathode of the decoupling diode 9 is connected to the first output of the channel, and the middle terminal of the voltage divider is connected to the first control input of the control unit 10, the first output of which is connected to the first control input of the power amplifier 3, and the second output is connected to the second control input of the amplifier 3 a rectifier diode 11, a filter circuit 12, a mismatch amplifier 13 and a cut-off diode 14, and in each channel the input of the rectifier diode 11 is connected to one of the extreme terminals of the secondary winding of the transformer, the output of the rectifier diode 11 is connected to the input of the filter circuit 12, the output of the filter circuit 12 of the first channel is connected to the first input of the mismatch amplifier 13 of the first channel and to the second input of the mismatch amplifier 13 of the second channel, the output of the filter circuit 12 of the second channel is connected to the first input of the amplifier 13 the second channel and the second input of the mismatch amplifier 13 of the first channel, and the outputs of the mismatch amplifiers of each channel through the cut-off diode 14 are connected to the second control input of the control unit 10 of the corresponding channel. The output terminals 15 and 16 of the power source are connected to the load.

The power amplifier 3 of the channel of the redundant DC power supply includes a bridge voltage converter on transistors 17 ... 20, the first diagonal of the bridge converter is connected to the inputs of the power amplifier, the second diagonal of the bridge converter is connected through the decoupling capacitor 21 to the outputs of the power amplifier, and the control inputs bridge transistors through control drivers 22 and 23 are connected to the control inputs of the power amplifier.

The control unit 10 includes a master oscillator 24, the output of which is connected to the input of the sawtooth generator 25 and the input of the trigger 26, the outputs of which are connected to the first inputs of the selectors 27 and 28, the second inputs of which are connected to the output of the comparator 29, the first input of which is connected to the output generator 25 sawtooth voltage, and the second input is connected to the output of the amplifier 30 of the error signal, the inputs of which are the control inputs of the control unit, and the second input of the amplifier of the error signal through the rubber Torr 31 connected to the output of reference voltage source 32, and the selector control unit outputs are the outputs.

The filter circuit 12 includes a resistor 33 and a capacitor 34, the first output of the resistor 33 is the input of the filter circuit, and the second is connected to the first output of the capacitor 34, and the terminals of the capacitor 34 are the outputs of the filter circuit 12.

Since the redundant power supply consists of two identical channels, we will consider the principle of its operation using the example of one channel. The device operates as follows. When primary power is supplied to the input terminals 1 and 2 of the redundant source, the supply voltage is supplied to the inputs of the power amplifier 3 and to the control unit 10. The master oscillator 24 of the control unit 10 starts to generate rectangular pulses of positive polarity, the frequency of which is equal to twice the conversion frequency of the power amplifier 3. Pulses of positive polarity from the output of the master oscillator 24 are fed to the input of the counting trigger 26 and the input of the sawtooth voltage generator 25. At the output of the generator 25, unipolar pulses of a sawtooth shape with the frequency of the master oscillator 24 are formed, and rectangular pulses of the meander type appear at the outputs of the trigger 26, the frequency of which is equal to the frequency of conversion of the power amplifier 3. The phase of the pulses at the first output of the trigger 26 is 0 degrees, the phase of the pulses at the second output of the trigger 26 is 180 degrees. The sawtooth pulses generated by the sawtooth voltage generator 25 are compared at the input of the comparator 29 with a mismatch signal of the mismatch signal amplifier 30, as a result of which rectangular pulses of positive polarity are generated at the output of the comparator 29, the duration of which is determined by comparing the reference voltage of the reference voltage source 32 and the feedback voltage taken from the midpoint of the voltage divider on the resistors 7 and 8. The output pulses of the comparator 29 are divided into two to anal with phases 0 and 180 degrees selectors 27 and 28, controlled by a trigger 26, and are fed to the control inputs of the power amplifier 3. Further conversion of the control pulses in the power amplifier 3 is carried out by the control drivers 22 and 23. Control drivers 22 and 23 are designed to convert low-power input pulses of a power amplifier into powerful control signals of transistors 17 ... 20 and transfer these signals to the inputs of weighted transistors 17 and 19. Such control drivers are typical and are issued as finished devices by well-known companies, for example . Motorola, International Rectifier, SGS Thomson. An example is the chip IR2110, IR2113, HCPL315, HCPL316J. The signals converted by the control drivers 22 and 23 alternately open either transistors 17 and 20, or transistors 18 and 19. At the same time, an alternating square voltage with an amplitude of the supply voltage and a duty cycle of rectangular pulses determined by the control unit 10 is induced on the primary winding of the transformer 4. The rectangular voltage of the required amplitude, determined by the transformation coefficient of the transformer 4, is rectified by a power rectifier 5 and filtered by a smoothing filter 6. A constant stabilized voltage from the output of the smoothing filter 6 through the decoupling diode 9 is fed to the output of the channel, where it is combined with the voltage of another channel. The function of the decoupling diode 9 is to cut off the faulty channel, in case of failure of its output elements, to maintain the functioning of the working channel.

Consider the operation of the channel redundant power supply in dynamic mode. Suppose the output voltage of the channel decreased as a result of external factors, resulting in a decrease in the voltage taken from the midpoint of the voltage divider on resistors 7 and 8, i.e. has become lower than the voltage of the reference voltage source 32. A mismatch signal appears at the inputs of amplifier 30, as a result of which its output voltage increases, which leads to an increase in the duration of rectangular pulses at the output of comparator 29, and therefore at the control inputs of power amplifier 3. The output voltage of the channel increases and becomes equal to the nominal. Similarly, the channel stabilization system operates in dynamic mode and with increasing output voltage.

Consider the collaboration of both channels. Suppose the voltage at the input of the decoupling diode 9 of the first (upper in the drawing) channel as a result of technological variation or exposure to external factors has become higher than the same voltage of the second channel. In this case, the decoupling diode 9 of the second channel is locked, the second channel goes into idle mode and its output voltage stabilization system, working out the intermittent current mode arising from this, starts to reduce the duration of the control pulses to almost zero. Such an imbalance in the distribution of channel loads is dangerous in that a failure of the loaded channel leads to transients in the output voltage during the transition of the backup channel to the loaded state due to the presence of reactive elements in the smoothing filter and the control unit. To eliminate such a regime, the following measures have been taken. Pulses from the secondary windings of transformers 4 are rectified by rectifier diodes 11 and filtered by filter circuits 12. If the first channel is loaded, its pulse duration is longer and the output voltage of the filter circuit 12 of the first channel is greater than the output voltage of the filter circuit 12 of the second channel. As a result, a positive voltage appears at the output of the second channel mismatch amplifier 13, which increases the setpoint voltage of the second channel through the cut-off diode 14, which leads to the loading of the second channel. In this case, the failure of the first (loaded) channel does not lead to catastrophic drops in the output voltage of the redundant power source, which allows the proposed source to be used to power especially critical radio equipment.

Sources of information

1. USSR copyright certificate No. 479101, cl. G 05 f 1/64, 1973.

2. USSR copyright certificate No. 1312678, cl. H 02 j 9/00, 1985.

Claims (4)

1. A redundant DC power supply containing the first and second channels of stabilized voltage converters, the inputs of which are connected in parallel and connected to the primary power source, the outputs are connected in parallel and connected to the load, each channel includes a power amplifier, the inputs of which are connected to the channel inputs and the output is connected to the primary winding of the transformer, the extreme terminals of the secondary winding of which are connected to the input of the power rectifier, a smoothing filter, the inputs to which are connected to the output of the power rectifier and to the midpoint of the secondary winding of the transformer, the first output of the output of the smoothing filter is connected to the first output of the voltage divider and the anode of the isolation diode, and the second output of the output of the smoothing filter is connected to the second output of the voltage divider and the second output of the channel, and the isolation cathode the diode is connected to the first output of the channel, and the middle output of the voltage divider is connected to the first control input of the control unit, the first output of which is connected to the first the power amplifier’s input input, and the second output with the second power amplifier control input, characterized in that a rectifier diode, a filter circuit, a mismatch amplifier, and a cut-off diode are introduced into each channel of the redundant DC power supply, and in each channel the input of the rectifier diode is connected to one of the extreme conclusions of the secondary winding of the transformer, the output of the rectifier diode is connected to the input of the filter circuit, the output of the filter circuit of the first channel is connected to the first input the mismatch amplifier of the first channel and with the second input of the mismatch amplifier of the second channel, the output of the filter circuit of the second channel is connected to the first input of the mismatch amplifier of the second channel and the second input of the mismatch amplifier of the first channel, and the outputs of the mismatch amplifiers of each channel through the cut-off diode are connected to the second control input of the control unit corresponding channel. 2. The redundant DC power supply according to claim 1, characterized in that the power amplifier includes a bridge voltage transistor with transistors, the first diagonal of the bridge converter is connected to the inputs of the power amplifier, the second diagonal of the bridge converter is connected through the decoupling capacitor to the outputs of the power amplifier, and the control inputs of the transistors of the bridge converter through the control drivers are connected to the control inputs of the power amplifier. 3. The redundant DC power supply according to claim 1, characterized in that the control unit includes a master oscillator, the output of which is connected to the input of the sawtooth voltage generator and the trigger input, the outputs of which are connected to the first inputs of two selectors, the second inputs of which are connected to the output of the comparator, the first input of which is connected to the output of the sawtooth voltage generator, and the second input is connected to the output of the error signal amplifier, the inputs of which are the control inputs of the node board, and the second input of the amplifier of the error signal through a resistor is connected to the output of the reference voltage source, and the outputs of the selectors are outputs of the control unit. 4. The redundant DC power supply according to claim 1, characterized in that the filter circuit includes a resistor and a capacitor, the first output of the resistor is the input of the filter circuit, and the second is connected to the first output of the capacitor, and the terminals of the capacitor are the outputs of the filter circuit.