SU1529197A1 - Multichannel power supply source - Google Patents

Abstract

The invention relates to electrical engineering and can be used in multichannel / multiphase / power supply systems. The purpose of the invention is to provide control over the distribution of currents between the channels. A block for setting the current load rate of the channels and a control unit for the current distribution are introduced into the multichannel system. This makes it possible to quickly evenly distribute the currents between the channels when the current changes in at least one of the channels. 1 il.

Description

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The invention relates to electrical engineering, in particular to converter equipment, and can be used in multi-channel (multi-phase) power supply systems (BOT).

The aim of the invention is to provide control. 1 the distribution of the load current between the channel.

The drawing shows a functional diagram of the BOT.

The power supply system contains N identical channels 1 connected to the outputs via the sensor 2 of the load current and the load 3 to the bus 4 of the SEC. Each channel 1 consists of a series-connected primary source 5, a regulating element 6, a current sensor 7 of the regulating element, the output of which is the output of channel 1, and a control unit 8 connected by an output to the control input of the regulating element 6, the first input of the sensor connected to the output 7 current regulating element. Amplifier-meter 9 of the error signal by the first input is connected to the output of the source 10 of the reference ({apr. Second vomo.ms with the outputs of all channels 1, and the output is connected to the second inputs of the control nodes 8 of all channels 1. In addition, the BOT contains unit 11 specifies the channel loading degree by (BESZ), which has N output (c, and current distribution control unit (CUT). BUT 12 includes .N controllable resistances (CI) 13 and N differential amplifiers 14. Controlled resistances 13 are connected in series with each other between the information The output of the load current sensor 2 and the common voltage of 4 CEP. The control inputs of each of the N US 13 are connected to the corresponding BESZ II outputs. Each of the N differential amplifiers 14 is connected to the direct and inverse inputs parallel to the respective controlled resistance 13. And the output connected to the third input of the control node 8 of the corresponding channel 1.

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The system works as follows.

The BESZ 11 generates signals at each of its N outputs that determine the load of each channel 1 depending on the target of the control, for example, when batteries are used as primary sources in the EPS, as a function of the degree of charge of the batteries (capacitor batteries. Signals Each of the N BESZ 11 outputs is connected to the control inputs of the corresponding DC 13 by varying the value of their ohmic resistance. The chain of the DC 13 connected in series is a controlled dividing voltage from the information of the output current of the load current sensor 2. The drop in voltage on the controllable voltage divider is proportional to the load current (equal to the load current multiplied by the gain of the current sensor). The voltage drop is 1 and on the i-th DC 13 is proportional to the KL part of the current the load. currents pet ularukn The number of elements and the load current sensor are the coefficient (}) of the amplifiers of the di (5 effective amplifiers 14 are equal to one, and the signal of the i-ro differential amplifier 12 is equal to Ki. load current parts. When the i-ro transmission coefficient of the regulating element current sensor 7 differs from that of the load current sensor, the i-ro di ratio (() of ferential: 1n amplifier 14 R; is defined as the ratio of the transmission coefficient of the i-ro current sensor 7 to regulate the 1st element to the coefficient transmitting the load current sensor 2, which is necessary to bring the signal, proportional to the load current portion (voltage on the i-th MS 13), to the current i-ro of the regulating element 6.

The output from the i-ro differential amplifier 14 is fed to the third input of the control unit M of the i-ro channel, the first input of which receives a signal from the current sensor 7 of the regulating element 6. At the control unit 8, the signal from the output of the i-ro differential amplifier 14 is compared (signal proportional to K; part of the load current) and the signal of sensor 7 of the current of the scanning element (signal proportional to the current of the regulating element 6). The received current error signal in total with the voltage error signal is supplied to the control input of the regulating element 6. At the same time, voltage stabilization at the output of the EPS and the required load on current 1 ka0 is achieved.

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1. When the signal changes at least at one output, the BESZ 1 1 causes a redistribution of the voltage drops (signals) on each US 13 and, accordingly, the redistribution of the currents of each of the N channels. At the same time, the sum of the currents of all channels remains equal to the load current, since the voltage drop across the controlled voltage divider does not change.

Claims (1)

Invention Formula A multichannel power supply system containing N channels connected by outputs through a load current sensor, converting the measured current into a proportional voltage to the output for connecting the load, the reference voltage source, the error signal measuring amplifier, connected to the output source of the reference voltage. voltage, the second input to the outputs of the channels, each of the channels comprising a primary source, a regulating element and a current sensor of the regulating element, connected to a successor but also connected to the output of the channel, the control unit of the regulating element is scoop by inputs and one output, connected by the first input to the current sensor of the regulating echement, the second input to the output of the error signal amplifier, and the output to the regulating input of the regulating e .1, characterized in that, in order to control the distribution of the load current between the channels, a block for specifying the load level of the canal is introduced into it. a current profile with N outputs, and a current distribution control unit having an information input connected to the information output of a load current sensor, N control inputs and N outputs, the current distribution control unit consisting of N controlled resistances connected in series between the information input of the block control of current distribution and common busin and connected by its own control inputs, which are the control inputs of the current control distribution unit, with the corresponding outputs of the rear unit The extent of channel loading but current, and N differential amplifiers having a gain Ri, connected by direct and inverse inputs parallel to the corresponding controlled resistance and outputs that are the outputs of the current distribution control unit, to the third inputs of the control nodes of the corresponding channels, and The coefficient R is equal to the ratio of the current sensor transmission coefficient i-ro of the regulating element to the coefficient of transmission of the load current sensor, where i 1.2 N.