SU1576898A1 - Secondary power supply system - Google Patents

Abstract

The invention relates to electrical engineering, in particular, to sources of secondary power supply for electronic equipment. The purpose of the invention is to simplify and improve reliability. The system consists of parallel-connected stabilizing sources 2 1-2 3 DC voltages. The regulator 3, the current sensor 4, the measuring amplifier unit 5, the control unit 15, the auxiliary operational amplifier 18, the reference source 19 and the resistor divider voltage 20, 21 are the inputs to each of the stabilizing sources; 23, the separation diode 24, the shunt diode 25. The distribution and equalization of the current through the load 1 between the N stabilizing sources is ensured by the fact that, as the load current N-1 of the stabilizing sources increases, the current stabilizes alternately and ization output voltage of the system is provided by other stabilizing sources operating in stabilizing mode voltage. When the system is overloaded, all stabilizing sources go into current stabilization mode, and after a time determined by the time delay capacitor 23, the regulators 3 of all stabilizing sources are closed, the circuit “tilts”, the output voltage and the load current of the system become zero. . 1 hp f-ly, 1 ill.

Description

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The distribution and equalization of the current through the load, 1 between N stabilizing sources, is ensured by the fact that, with an increase in the load current N-1, the stabilizing sources alternately switch to the current stabilization mode, and the output voltage of the system is stabilized by the other stabilizing sources operating in voltage stabilization. Overload

the current system all stabilizing sources go into current stabilization mode and after a time determined by the time delay capacitor 23, the regulators 3 of all stabilizing sources close, turn off the circuit, the output voltage and the load current of the system become zero. 1 z.p, f-ly, 1 ill.

The invention relates to electrical engineering and is intended for use in the implementation of power supply of electronic equipment.

The purpose of the invention is to simplify and improve reliability.

The drawing shows a functional diagram of a secondary power system.

The system contains parallel-connected to the load 1 sources 21 - 2 DC voltages. Regulator 3, resistor current sensor 4, measuring amplifier unit 5 with resistors 6–9, resistor divider voltage 10, capacitor 11, zener diodes 12, 13 and operating amplifier 14, control unit 15 with master oscillator 16 and pulse-width modulator 17, auxiliary operational amplifier 18, auxiliary source

19 support voltage, auxiliary voltage divider with resistors

20 and 21, the time setting RC element with a resistor 22 and a capacitor 23, a separating diode 24, a shunt diode 25, current-limiting resistors 26

27. The diagram also shows outlines 28.1-28.3 and 29.1-29.3 for connecting a common or individual primary power sources, terminals 30.1-30.3 and 31.1-31.3 for connecting additional power sources, terminals 32 and 33 for connecting a load 1. In each of the stabilizing sources 2. - 2 DC voltages supplying the input of the regulator 3 is connected to the terminals for connecting the primary power source, for example, to the terminals 28.1 - 29.1, and the output through the resistor 4 of the current - to the terminals 32 and 33 for

connecting the load 1. The output of the control unit 15 (output of the pulse-width modulator 17) is connected to the control input of the regulator 3. The input of the measuring-amplifier unit 5 is connected to the terminals 32 and 33 to connect the load 1, and the output to the input control unit 15 (with a signal input of a pulse-width modulator 17). The shunt diode 25 is connected between the outputs of the measuring and amplifier unit 5 and the auxiliary operational amplifier 18 with the bypassing of the signal opening by the regulator 3. The first (non-inverting) input of the auxiliary operational amplifier 18, prohibiting the opening of the shunt diode 25, is connected to the output of the auxiliary source 19 of the reference voltage and the second (inverting) input allowing the opening of the shunt diode 25 to the output circuit of the resistor current sensor 4 (via resistor 26). The input of the auxiliary resistor divider 20, 21 is the DC voltage, and the output through the series-connected time setting RC-link 22, 23 and the separation diode 24 - to the second (inverting) input of the auxiliary operational amplifier 18. In each of the stabilizing sources 2.J - 2 g of DC voltage; auxiliary source 19 of the voltage can be made in the form of a scaling resistive voltage divider connected by an input to the corresponding intermediate terminals of the measuring and amplifying node 5 (to the conclusions of the Zener diode 12).

The system works as follows. The output voltage of each of the stabilizing sources, for example

source 21 is fed to the input of the measuring and amplifying unit 5. Part of this voltage from the lower arm of the divider 10 is fed to the non-inverting input of the operational amplifier 14, performing a comparison operation with the reference voltage at the Zener diode 12. The error signal from the output of the operational amplifier 14 is supplied the output of the measuring and amplifier node 5, i.e. to the pulse-width modulator 17 of the control unit 15, to which the clock pulses from the master oscillator 16 are also supplied.

From the output of the pulse-width modulator 17, the control pulses of the required duration arrive at the control input of the regulator 3, which maintains the output voltage of the stabilizing source at a predetermined level.

If the load current of the stabilizing source is less than the specified maximum value, the voltage on the current sensor 4, i.e. at the inverting input of the operational amplifier 18, less than the reference voltage supplied to its non-inverting input from the output of the source 19. The resistance of the resistors 20 and 21 of the auxiliary booster voltage divider is chosen such that at the nominal output voltage of the stabilizing source the voltage the anode of the separation diode 24 was lower than the voltage at its cathode. Therefore, in this mode, the diode 24 is locked and does not affect the state of the operational amplifier 18. As a result, the operational amplifier 18 is in the first steady state, the voltage at its output has a positive value relative to pin 32. The shunt diode 25 turns out to be locked by the reverse field voltage and the operational amplifier 18 does not affect the performance of the stabilizing source. The capacitor 23 of the delay while charging up to a certain voltage.

As the load current of the stabilizing source increases, the voltage on the current sensor 4 increases, the output voltage of the operational amplifier 18 decreases, and the shunt diode 25 opens. The resulting voltage at the signal input of the pulse-width modulator 17

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decreases the width of the governing im-. The pulses at the control input of the regulator 3 are changed accordingly, and this stabilizing source switches to the current stabilization mode.

When all stabilizing sources 21 - e of the DC voltage are operated in parallel to the total load 1, the output voltage of one stabilizing source operating in the current stabilization mode is maintained at the level of the nominal value at the expense of other stabilizing sources. When a stabilizing source operates in a current stabilization mode, separately from other stabilizing sources or when

When all stabilizing sources go into current stabilization mode, their output voltage decreases.

When the output voltage of the stabilizing source decreases, the voltage on the auxiliary drive of the mountain divider 20, 21 and voltage on its output terminal relative to the output 32 rises, the time delay capacitor 23 starts to charge, the voltage on the anode of the separation diode 24 rises and it opens. The voltage at the inverting input of opamp 18 rises, while the voltage at its non-inverting input remains constant. The operational amplifier 18, at the time determined by the time by the driver of the CS link 22, 23, passes to the second steady state, at which the voltage at its output has a minimum negative value. As a result, the shunt diode 25 opens, the voltage at the signal input of the pulse-width modulator 17 decreases, and the width of the control pulses at the output of the latter decreases. The regulator 3 is plugged in, the output voltage of the stabilizing source decreases and the circuit breaks down. In this mode, the voltage on the inverting input of opamp 18 is higher than the voltage on its non-inverting input, and opamp 18 is in a second stable state where the voltage on its output is minimal and has a negative value relative to pin 32. Regulating

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organ 3 is completely closed, the output voltage and load current of the stabilizing source are zero.

A time delay capacitor 23 serves to prevent the circuit from tipping over when the stabilizing source is turned on and during its short-term current overload.

The described algorithm of operation of each of the stabilizing sources 2-2e of the direct current voltage provides the following algorithm for the operation of the secondary power supply system as a whole. When the system load current is less than the specified maximum value of any stabilizing source, this current is randomly distributed between all stabilizing sources that operate in voltage stabilization mode and stabilize the output voltage of the system. In the particular case, the entire load current is provided with one stabilizing source.

When the load current increases above the specified maximum value of the most loaded stabilizing source, which has the highest output voltage at a given load current compared to other stabilizing sources, it switches to the current stabilization mode, and the remaining stabilizing sources continue to operate in the voltage stabilizing mode. With a further increase in the load current, the next stabilizing source goes into the current stabilization mode, while the rest work in the voltage stabilization mode, etc.

With a load current greater than the maximum allowable load current of the entire system, all stabilizing sources go into current stabilization mode, the output voltage of the system decreases, and all stabilizing sources tip over. The output voltage and load current of the system become zero. To return the circuit to its original state, it is necessary to eliminate the fault, turn off and then re-turn on all stabilizing sources.

The maximum permissible current of the system, which is the current of operation of the protection, is equal to the sum of the maximum currents of all the stabilizing needles entering the system.

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Thus, in this secondary power supply system, the work on the common load of stabilizing sources of direct current voltage without additional leveling elements, as well as the protection of elements of stabilizing sources against current overloads and short circuits, is ensured in parallel.

The distribution and equalization of the load current between N stabilizing sources operating on a common load is achieved by increasing the load current N-1 stabilizing sources to alternately switching to current stabilization mode, and stabilizing the output voltage of the system working in voltage stabilization mode. When the system is overloaded, all stabilizing sources go into current stabilization mode and after a time determined by the time delay capacitor 23, the regulators 3 of all stabilizing sources are closed, the circuit is turned off, the output voltage and the load current of the system become zero.

The proposed technical solution allows to simplify the secondary power supply system and increase its operational reliability due to the fact that the alignment of currents of parallel operating stabilizing sources 21-23 is provided without cross-links and additional elements, and the protection of current stabilizing sources is realized by introducing links 22, 23.

Claims (2)

1. A secondary power supply system comprising a series of parallel-connected stabilizing DC voltage sources, each of which includes a regulating organ, the feed input of which is connected to the terminals for connecting the primary power supply. And, the output through the resistor current sensor - with the terminals for connecting the load, the control unit, the output of which is connected to the control input of the regulator, measure the voltage and the coupling, the input of which is connected to. terminals for connecting the load, and the output with the input of the control unit, characterized in that, in order to simplify and increase the reliability of operation, auxiliary operational amplifier, reference source and resistor are introduced into each of the stabilizing DC voltage sources the voltage divider, which time sets the KC link, separates and shunt the diodes, the latter being connected between the outputs of the measuring amplifier unit and the auxiliary operational amplifier with the opening bypass signal s body, a first auxiliary input of the operational amplifier, prohibits the opening of the bypass diode connected to the output vspomogatap- Nogo reference voltage source, and the second input allowing the opening of the shunt diode - with the output circuit of the rectifier current sensor, the input of the auxiliary resistor voltage divider is connected to the output circuit of this stabilizing DC voltage source, and the output through the serially connected time setting RC link and the separation diode to the second input of the auxiliary op amp, 2. The system according to claim 1, wherein in each of the stabilizing DC voltage sources, the auxiliary reference voltage source is made in the form of a scaling resistor voltage divider connected by an input to the corresponding intermediate terminals of the measuring amplifier unit.