SU1734085A1 - Multichannel device to stabilize dc voltage - Google Patents

Abstract

The invention relates to electrical engineering, in particular, to sources of secondary power supply for electronic equipment. The goal is to improve the quality of stabilization. The device contains a pulse generator 11, an information storage control unit 12, switches 13, 14, a comparison pulse width modulation unit 15, a distribution unit 16, keys 1-3, storage elements 4-6, voltage scaling parts 17-19 . The device has several channels with pulse voltage stabilization, which is carried out by changing

Description

FIG.

the duration of the pulses at the output of node 15 when the voltage changes at the output of a channel. As a control unit 12, a random access memory is used. At that time, when a width-modulated pulse arrives at the corresponding input of node 12 via switch 13,

the remaining inputs are supplied with pulses from the outputs of node 12. Therefore, at each moment of time one of the keys is controlled in accordance with the current deviation of the channel output voltage, and the other keys in accordance with the information previously entered in node 12. 3 hp . f-ly, 4il.

The invention relates to electrical engineering, in particular to secondary power sources, and can be used to power various radio equipment.

A stabilized multichannel power supply unit is known, which contains a voltage converter consisting of a power transformer with primary and output windings, key transistors, a control circuit connected to the winding of the power transformer, rectifiers, power cables including inductance and capacitance, linear stabilizers made with separate power supply to the regulating and pre-regulating transistors, an additional circuit of diodes in series, droplets and a capacitor.

The disadvantage of this device is the low quality of stabilization.

Closest to the proposed device is a multichannel device for stabilizing DC voltage, containing p power channels, in each of which a key and a power cell are connected in series between the terminals, for connecting a primary power source and an individual load, a feedback channel with the switch, the signal inputs of which are connected through the scaling voltage dividers to the outputs of the accumulative elements of the corresponding supply channels, the eye, whose input is connected to the output of the pulse generator, and the first output is connected to the switch input, a comparison node that has an output connected to a key element, a reference input connected to the pulse generator and a signal input connected to the switch, a node control having a signal input connected to the output of the key element; an address input connected to the second output of the distribution block and n outputs connected to the control inputs of the keys of the corresponding supply channels.

The disadvantage of this device is the low quality of stabilization.

The purpose of the invention is to improve the quality of stabilization.

This goal is achieved by the fact that in a multichannel device for stabilizing DC voltage, containing n power channels, each of which a key and a cumulative element are connected in series between the terminals for connecting the primary power source and the individual load, the feedback channel to the first switch The n signal inputs of which are connected via n scaling voltage dividers to the outputs of the storage elements of the corresponding supply channels, the distribution block, the input which is connected to the output of the pulse generator, and the first output to the address input of the first switch, the comparison node. having an output, a reference input and a signal input connected to the output of the first switch, a control node having a signal input, an address input connected to the second output of the distribution unit, and n outputs connected to the control inputs of the keys of the corresponding supply channels to the return link The second switch is entered, the comparison node is made with pulse-width modulation of signals, and equipped with n - 1 additional signal inputs and the input of the write command, the control node - with information storage, and the address input of the second switch is connected to the first output of the distribution block, one of the signal inputs to the output of the comparison node, n other signal inputs to the outputs of the control node, and n outputs to the signal inputs of the latter, the reference input of the comparison node is connected to the third output of the distribution block and the command input to the recording of the control unit is connected to the output of the pulse generator.

The second switch consists of a decoder and three multiplexers, the group of address inputs of the decoder is used as the address input of the second switch, the address inputs of the multiplexers are connected to the corresponding outputs of the decoder, the first information inputs are combined with each other and used as the first signal input of the second switch, and the second information inputs as its remaining signal inputs.

The distribution block consists of two binary counters, the transfer output of the first counter is connected to the counting input of the second counter, the counting input of the first counter is used as the input of the distribution block, and the output group of the second counter, the output group of the first counter and the output of its high bit are respectively as the first, second and third outputs of the distribution unit.

The control node with information storage is made in the form of a random access memory, the data inputs of which are used as signal inputs of the control node, the group of address inputs as its address input and the read-write input as the write command input.

FIG. 1 shows a functional diagram of the device; in fig. 2 - the second switch; in fig. 3 - distribution block; in fig. 4 - control unit with information storage.

The device (Fig. 1) contains n power channels, each with a key 1-3 and a storage element 4-6, with the first inputs of the keys 1-3 of each channel connected to each other and the input terminal 7, and the outputs to the inputs of the storage elements 4-6, the outputs of which are connected to the output terminals of 8-10 channels, a feedback channel comprising a pulse generator 11, an information storage control unit 12, switches 13 and 14, a comparison node 15 configured for pulse-width modulation. signals, distribution block 16, n scaling dividers on the number of which depends on the number of supply channels (17-19), while the input of the distribution unit 6 is connected to the output of the generator 11 pulses, the first output to the address inputs of the switches 13 and 14, the second output to the address input of the control unit 12, and the third output is with the reference input of the comparison node 15, the signal input of which is connected to the output of the switch 14, the signal inputs of which through the voltage scaling voltage dividers 17-19 are connected to the outputs of the accumulation elements 4-6 of the corresponding supply channels, the rotary inputs of the switch 13 are connected to the output of the comparison node 15, its remaining signal inputs to the outputs of the control unit 12, and n outputs to the signal inputs of the latter, the command input for recording the control unit 12 is connected to the output of the pulse generator 11, n outputs of the node 12 Controls are connected to the control inputs of the keys 1-3 of the respective supply channels.

Switch 3 (Fig. 2) contains a decoder 20 and multiplexers 21, 22 and 23, the group of address inputs of the decoder 20 used as the address input of the second switch, the address inputs of the multiplexers 21, 22 and 23 are connected to the corresponding outputs of the decoder 20, the signal input of which connected to ground, the first information inputs of multiplexers 21, 22 and 23 are combined with each other and used as the first signal input of the second switch, and the second information inputs as its other signal inputs, output The multiplexers 21, 22 and 23 are the corresponding outputs of the second switch.

Distribution unit 6 (Fig. 3) contains binary counters 24 and 25, with the transfer output of the counter 24 connected to the counting input of the counter 25, the counting input of the counter 24 is used as the input of the distribution unit, and the group of outputs of the counter 24, the output group of the counter 25 and the output its most significant bit is, respectively, as the first, second and third outputs of the distribution unit.

The control unit 2 with information storage (FIG. 4) is made in the form of a random access memory RAM 26, whose data inputs are used as signal inputs of the control unit, a group of address inputs as its address input and a read-write input as command input on the record.

The device works as follows.

Unstabilized voltage from an external power source (not shown) is supplied to the input terminal 7, and the control inputs of keys 1-3 from the control unit 12 are pulses that open them for a time equal to their duration. Consider the operation of a single feed channel, for example, the first.

The pulses from the control unit 12 will cause a pulse 1 at the output of the key 1 with an amplitude equal to the input voltage, a duration equal to the duration of the control pulses and the frequency

f fr / 2 where fr is the generator frequency of 11 pulses;

k is the number of address bits of the random access memory (RAM).

These pulses are fed to the input of the storage element 4 and are converted into a constant voltage proportional to the input voltage and the fill factor of the control pulses, which arrive at the output terminal 8 of the first channel, and from there through the scaling voltage divider 19 to the corresponding input of the switch 14.

At the first output of the distribution unit 16, the address of the first supply channel is formed, which enters the switch 13 and 14. As a result, the signal input of the comparison node 15 will be connected through the switch 14 to the voltage scaling divider 19, and its output through the switch 13 to the corresponding input of the node 12 management A reference is received at the reference input of the comparison node 15 from the third output of the distribution unit 16, which will be converted into a triangular voltage compared with a constant voltage received at the signal input of the comparison node 15.

As a result, the comparison at the output of the comparison node 15 is vits a rectangular pulse, the duration of which is proportional to the voltage at its signal input. This pulse will go through the switch 13 to the corresponding signal input of the control unit 2. The remaining signal inputs of the control unit 12 receive pulses from its output.

At the second output of the distribution unit 16, under the influence of pulses arriving at its input from the pulse generator 11, immediately after setting the supply channel address, the RAM addresses of the control unit 2 are started to be sequentially generated at its address input. From each pulse that enters the input command to write control unit 2 from the pulse generator 11, a write pulse is generated in the RAM. Since the key management signal 1-3 can take only two values: log. Oh and log. 1, it is possible to take samples of it and store them in RAM, and then reproduce it as many times as necessary. The accuracy of the playback depends on the capacity of the RAM. Since the information recorded in the RAM immediately appears at the output, then the control input of the key 1 will receive a pulse from the output of the comparison node 15, the control inputs of the other keys 23

impulses previously stored in control unit 12 are received.

The same pulses come from its output through the switch 13 to the corresponding

the signal inputs of the control unit 12 will be overwritten,

After the last output of the RAM is formed at the second output of the distribution block 16, at its first

0 output by Vits is the address of the second supply channel and the operation is repeated in the described manner. The switch 13 operates as follows.

The address inputs of the decoder 20 through 5 step channel address, formed at the first output of the distribution unit 16. As a result, at the corresponding output of the decoder 20 on Vits signal log. Oh that will go to the address input of one

0 from multiplexers 21, 22 and 23 and connects its output to the first signal input of the switch 13. The outputs of the remaining multiplexers will be connected to the other signal inputs of the switch 13. Thus

5, the address arriving at switch 13 will determine which of its outputs will be connected to the first signal input. Since the latter is connected to the output of the comparison node 15, and the remaining inputs

0 is connected to the output of control node 2, the address received at the address input of the switch 13 will determine which output it will be connected to the output of the comparison node 15 and which outputs to the outputs of the node

5 12 controls,

Distribution unit 16 operates as follows.

At its entrance there are counting pulses from the generator 11 pulses. These signals

0 is fed to the counting input of the binary counter 24, the conversion factor of which is determined by the number of addressable RAM buses in the control unit 12, while the pulses from the high bit output of the counter 24 are fed to the second input of the comparison node 15, and from the transfer output of the counter 24 pulses arrive to the counting input of the binary counter 25, the conversion factor of which is determined by the number of channels. At the exit

0, the counter 25 generates the channel address after polling all the RAM cells in the control unit 12.

The control storage unit 12 operates as follows.

5 The address formed at the second output of the distribution unit 16 is fed to the address input of the RAM 26. The next pulse from the pulse generator 11, which enters the read / write input of the control unit 12, is written to the RAM 26

information on shinadannyh. At the same time, depending on the state of the switch 13, one of the data inputs of the RAM 26 will be connected to the output of the comparison node 15, and the rest to the corresponding inputs of the RAM,

Thus, after on dew of all the addresses of the RAM 26, samples of the output signal of the distribution block 16 will be recorded on one data input, and on the remaining outputs the information will be overwritten from the corresponding inputs.

Claims (4)

1. A multichannel device for stabilizing DC voltage, containing n power supply channels, in each of which a key and a cumulative element are connected in series between the terminals for connecting the primary power source and the individual load, the feedback channel to the first switch, whose signal inputs through n scaling voltage dividers are connected to the outputs of the cumulative elements of the corresponding supply channels, with the distribution block, the input of which is connected to the output of the generator and pulses, and the first output is with the address input of the first switch, with a comparison node having an output, a reference input and a signal input connected to the output of the first switch, with a control node having a signal input, an address input connected to the second output of the distribution unit, and n outputs connected to the control inputs of the keys of the corresponding supply channels, characterized in that, in order to improve the quality of stabilization, a second switch is introduced into the feedback channel, the comparison node is made with a pulse-width mod by signals, and supplied with n - 1 additional signal inputs and command input recording a control unit with information storage, with the address input of the second switch connected to the first output of the distribution unit, one of the signal inputs to the output of the comparison node, n other signal inputs to the outputs of the control node, and n outputs to the signal inputs of the latter, the reference input of the comparison node is connected to the third output of the distribution unit, and the input of the command to record the control node is connected to the output of the pulse generator. 2. Device pop. 1, characterized in that the second switch consists of the decoder and three multiplexers, the group of address inputs of the decoder is used as the address input of the second switch, the address inputs of the multiplexers are connected to the corresponding outputs of the decoder, the first information inputs are combined with each other and used as the first signal input of the second switch, and the second information inputs are quality its remaining signal inputs. 3. The device according to claim 1, characterized in that the distribution unit consists of two binary counters, and the transfer output of the first counter is connected to the counting input of the second counter, the counting input of the first counter is used as the input of the distribution unit, and the group of outputs of the second counter, the group of outputs of the first counter and the output of its most significant bit, respectively, as the first - third outputs of the distribution unit. 4. Pop.1 device, characterized in that the control node with storage information is made in the form of a random access memory, the data inputs of which are used as signal inputs of the control node, the group of address inputs as its address input and the read-write input as the write command input. FIG. 2 Editor A.Dolinich Compiled by V. Belov Tehred M. Morgental fig.Z Rie.4 Proofreader O. Kravtsov