SU1686424A2 - Capacitor bank controller - Google Patents

Abstract

The invention relates to electric power industry and can be used in all national enterprises for the automatic control of capacitor installations. The purpose of the invention is to increase the efficiency of controlling D compensating devices by reducing the electric power losses from reactive power flows, taking into account the direction of this power flows in the power grids of an enterprise. This goal is achieved using a reactive power flow direction metering unit 9, the inputs of which are connected to reactive power sensors 7 and a quad block 8. Signals from the reactive power flow unit outputs, proportional to the squares of reactive powers in the nodes, go to the scale amplifier unit 10, outputs which is connected to the inputs of the loss analysis and location detection unit 6, which enables the switching of sections of a capacitor battery at one of the distributor nodes Noah network. 2 Il. Ё О 00 О ю N)

Description

The invention relates to electric power industry, can be used in all national enterprises for the automatic control of capacitor installations and is an improvement of the device according to the author. No. 1416961.

The aim of the invention is to increase the efficiency of controlling compensating devices by reducing the electric power losses from reactive power flows, taking into account the direction of flows of this power in the enterprise power grids.

FIG. 1 is a block diagram of an automatic capacitor bank regulator; in fig. 2 is a schematic diagram of a unit for accounting for the direction of reactive power flows.

The output of the sensor 1 input reactive power (Fig. 1) is connected to the input of the reacting body 2, the second input of which is connected to the output of the setpoint adjuster 3, to the input of which the output of the automatic switching unit 4 is connected. The outputs of the reacting organ 2 are connected to the inputs of the time-delaying organ 5, the outputs of which are connected to the control inputs of the loss analysis and switching point determination units 6. Sensors 7.1, 7.2 7, p of reactive power, installed at the locations of capacitor batteries, are connected to block 8 quadrants and block 9 taking into account the direction of reactive power flows (BUNP), consisting of n devices, and the corresponding outputs of block quadrants are connected to the corresponding inputs of BUNP The outputs of which are connected to the inputs of the block 10 of large-scale amplifiers, the outputs of which are connected to the inputs of the Loss Analysis Unit (BAP) and Switching Location Determination (OMC), the outputs of which are connected to the inputs of the corresponding actuators x bodies 11.1, 11.2 11.p.

The output from the quad (Fig. 2) is connected to the electronic key 12 and through an inverter consisting of an operational amplifier 13 and resistors 14 and 15, to an electronic key 16. The keys 12 and 16 are controlled from the output of the reactive power sensor via a comparator 17 and inverter 18.

The device works as follows.

When the input reactive power changes, when the readings of the sensor 1 of the input reactive power are less than the voltage values of the setpoint 3, the reacting authority 2 sends a Disable signal to the BAS and the OMC 6 through time delay 5.

With sensors 7.1. 7.27, p reactive

power is removed voltage proportional to the reactive power consumed in the nodes of the power supply system. These voltages are applied to

inputs of quadrators 8.1, 8.28.p and block 9.1,

9.2, ..., 9.p take into account the direction of flow

0 reactive power. With each output of the quad, the voltage is taken proportional to the square of the reactive power in this node and fed to the input of the electronic switch 12, and through the inverter 18

5, a voltage proportional to minus the square of the reactive power at the node is applied to the input of the electronic switch 6.

Electronic key management 12

0 and 16 is carried out depending on the sign of the voltage of the reactive power sensor. If the voltage is positive, the comparator 17 is triggered and sends a signal to turn on the electronic key 12, and with a negative voltage, the inverter 18 sends a signal to turn on the electronic key 16. From the BUNP outputs, depending on the direction of the reactive power flow, the nodes are supplied with voltage proportional to square reactive power in these nodes, if the direction of flow of reactive power is positive, and minus the squares of reactive power in these nodes, if the direction is negative in the BMU 10. from which Signals, proportional to the losses in nodes, are received at the information inputs of BAP and OMK 6.

When the Disconnect command is supplied to the BAS and the OMC, a generator of linearly increasing voltage is started, the output voltage of which starts to increase from the value corresponding to the largest active loss from the flows of negative reactive power in the network of this enterprise, and as a result, the OMC signal is generated which is permitting the shutdown of the compensating device, in which the maximum re-compensation is the highest. If in all nodes the active losses from reactive power flows are positive or equal to zero, then the compensating device will be switched off, at the node of which these losses are minimal.

5The introduction of a new unit and communications increases the management efficiency by additionally reducing the power losses from reactive power flows. This is achieved by introducing a unit for taking into account the direction of the flow of reactive power, which eliminates the backflow of reactive power in the distribution network of the enterprise.

Claims (1)

Claims of automatic capacitor battery regulator aut. Ev ISb 1416961, characterized in that, in order to increase management efficiency, it is equipped with a unit for recording the direction of flow of reactive power and controlled keys The reactive power sensors are connected to the inputs of the metering block of reactive power flow directions. The direct and inverse quad block block outputs are connected to the power inputs of the controlled switches. The corresponding power outputs of the meter block of the reactive power flow metering module are connected to the control inputs of controlled keys, the power outputs of which are connected to the block of large-scale amplifiers. Coadratoro block exit Input from the sensor reactive ®UZ 2 tidyy power