SU1658135A1 - Power supply system - Google Patents

Abstract

The invention relates to electrical engineering and can be used to power automation devices and computer equipment. The goal is to expand the functionality by disconnecting all power sources when the voltage at the output of any of them disappears. The device contains several power sources, each of which includes a disconnecting unit and an optocoupler, as well as a starting unit and two isolating diodes. The execution of the disconnecting unit in the form of a controlled rectifier, as well as the definite switching on of the decoupling diodes and optocouplers, ensures the protection of the load by disconnecting the power supply from it during the disappearance of the voltage at the output of any power source regardless of the cause of this disappearance. In addition, in the device, if necessary, can be used simple integral stabilizers, with input, output and general conclusions. 1 il. Yo

Description

The invention relates to electrical engineering and can be used to supply power to automation devices and computer technology where a certain sequence of supplying power is required at the moment of switching on the mains voltage.

The purpose of the invention is to expand the functionality by disconnecting all power sources in the event of the disappearance of the voltage at the output of any of them.

The drawing shows a power supply system diagram.

The power supply system contains sources 1. 1-1.p power supply, each of which has a shutdown unit, made in the form of a controlled rectifier 2 with control input 3, a photodetector 4 and a light emitter 5 optocoupler 6 with pins

7.i, 8.i 0 - 1-p), as well as, if necessary, voltage regulator 9. At the same time, the photodetector 4 of the optocoupler 6 of each source 1.1-1. A power supply input is connected to one of the output terminals of the controlled rectifier 2 of its power supply, and the output - to its control input 3. The light emitter 5 optocoupler 6 of each source 1.2-1. The power supply terminals 7. 2-7.p and 8.2-8.P is connected between the output terminals of the corresponding previous power source. In addition, the power supply system comprises a start-up unit 10, made in the form of a single pulse generator, the first output terminal 11 connected to the first terminal of the first decoupling diode 12, the second terminal of which is connected to the same terminal of the second decoupling diode 13 and the first

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output 7.1 of the light emitter 5 optocoupler of the first 1.1 start-up power supply source. The second terminal of the second isolation diode 13 is connected to the first output terminal 14 of the last starting source 1. R, the second output terminal 15 of which is connected to the second output terminal of the starting unit 10 and the second terminal 8.1 of the optical emitter 5 of the optocoupler of the first starting source 1.1. The first 12 and second 13 isolating diodes are included in the forward current direction, respectively, from the starting unit 10 and the output terminals 14 and 15 of the latter for starting the power supply 1.p.

The power supply system operates as follows.

At the moment the input voltages Uex are supplied 1 l, and without, for example, when the mains voltage is switched on, the starting unit 10 produces a single trigger pulse, the duration of which is chosen to be greater than or equal to the total start time of all sources of the power supply system and its polarity on the first output terminal 11 The starting block 10 corresponds to the polarity of the first output terminal 14 of the last one by the start of the power supply source 1. From the output of the trigger unit 10, the trigger pulse through the first decoupling diode 12 connected forwards in the forward direction arrives at the light emitter 5 of the optocoupler 6 of the first starting source 1.1 power supply and ignites it, while the decoupling second diode 13 protects the last ho start source 1. A power supply from hitting the start pulse on its output terminals 14 and 15. The photodetector 4 of the optocoupler 6 of the first starting source 1.1 is opened, and the controlled rectifier 2 of the source

1.1 the power supply is turned on, rectifying the input voltage UBX.L At the output of the first starting source 1.1 power supply, the output voltage Uv1 output stabilized by voltage stabilizer 9 appears.

Voltage 1) Output 1 is supplied to the light emitter 5 (pins 7.2, 8.2) of the optocoupler 6 of the second start source 1.2 power supply, this opens the photodetector 4 of the optocoupler 6 and turns on the controlled rectifier 2 of the source

1.2 power supply. At the output of the second starting source 1.2 of the power supply, the output voltage Kwx.2 appears.

Similarly, all other power supplies entering the system are started up in a predetermined order. When the voltage Ovyh.p on

the output of the last one by starting up the power supply 1.l, the uncoupling second diode 13 opens, and the uncoupling first diode 12 closes, protecting the output of the starting block 10 from falling

on his weekends conclusions voltage Uvyh. Through the open second decoupling diode 13, the voltage UBbix.n enters the light emitter 5 (terminals 7.1, 8.1) of the optocoupler 6 of the first starting source 1.1 power supply, maintaining the light emitter 5 in the lit state and, thus, blocking the receiving receiver 4 optocoupler b in the open state, and the power supply source 1.1. At the same

time block 10 run finishes the formation of a triggering pulse.

If at the time of input voltages supply l / vout 1 freshwater at the output

any of the sources 1.1-1. The power supply of the system is short-circuited, then during the trigger pulse only those power sources are started, the start of which precedes the start of this emergency source and, therefore, the voltage of the last source 1, there will be no power supply and the open state of the photodetector 4 will not be blocked by the optocoupler 6 of the first power supply source 1.1. Therefore, at the end of the triggering pulse, the photodetector 4 of the optocoupler 6 of the first

0 the start of the power supply 1.1, the controlled rectifier 2 of the power supply 1.1 is turned off and the output voltage UBUX.I is turned off, and this leads to the shutdown of all other start-ups

power sources.

Similarly, all power supplies are disconnected when the output voltage disappears.

Any one of them during the operation of the power supply system occurs regardless of what caused the voltage to disappear.

Assume that the voltage disappeared on

5 output of the latter by starting the source 1. Power supply, for example, as a result of an accident that occurred in the power supply source itself. This leads to the closing of the photodetector 4 of the optocoupler 6 of the first power supply source 1.1, the shutdown of its controlled rectifier 2, and the removal of the voltage UvykhL from its output, which, in turn, closes the photodetector 4 of the optocoupler 6 of the second starting source 1.2 the power supply, turning off its controlled rectifier 2 and relieving the voltage of the Quyh 2 from its output. Similarly, all other power sources included in the power supply system are turned off.

In order to restart the system after eliminating the cause that caused the voltage to disappear at the output of the power supply, it is necessary for the starting unit 10 to form a trigger pulse. In order to do this, it is enough to remove and then re-apply to the starting unit 10 the input supply voltage UecnoM.

The proposed power supply system provides protection for the powered load by disconnecting all power sources of the system in the event of the disappearance of the voltage at the output of any one of them, regardless of what caused the disappearance of the voltage, which extends its functionality. The use of controlled rectifiers as switch-off units makes it possible to efficiently use integral voltage stabilizers in the power supply sources of the system, in particular, stabilizers having only input, output, and common leads, and also eliminates voltage stabilizers from power supplies in when there is no need for them.

Claims (1)

A power supply system comprising at least two power sources, each of which includes a shutdown unit, an optocoupler, a photodetector of which with an output connected to the control input of the shutdown unit, and a light emitter connected between the output terminals of the previous power source start up unit trigger, one of the output pins of which is connected to the first output of the first decoupling diode, characterized in that, in order to extend the functionality by turning off all power sources at disappearance of the voltage at the output of any of them. each power supply disconnection unit is designed as a controlled rectifier, one of the output pins of which is connected to an input of an optocoupler photodetector; the second terminal of the second isolation diode is connected to the first output terminal of the last one to start up the power supply, the second output terminal of which connected to the second output terminal of the startup unit and the second output of the optocoupler optocoupler of the first to start up power source; in addition, the first and second isolating diodes are connected in the forward direction for current flow from the start up unit and from the output terminals of the last to start up power source.