SU1097991A1 - Automatic controller for compensating reactive power - Google Patents

Abstract

AUTOMATIC REGULATOR FOR COMPENSATION OF REACTIVE POWER, containing current transformer and voltage transformer, connected to the input of a phase-sensitive unit, the outputs of which through the Enable, Disconnect control module are connected to the logic control unit of the static capacitor battery, characterized in that, in order to expand the functional capabilities , it is equipped with current transformers according to the number of additionally monitored electrical networks, a switching unit, a unit for selecting the voltage of the network and the program a mm unit made in the form of a pulse generator connected to a counter connected to the input of the decoder, the number of outputs of which is equal to the number of batteries of static capacitors and connected to two encoders, the number of outputs of the first of which is equal to the number of monitored electrical networks, and the number of outputs of the second encoder is equal to the number the network phases, the static capacitor battery logic control unit consists of cells, the number of which is equal to the number of static capacitor batteries, each of which contains two logical elements IS-NOT connected to the RS-flip-flop, the voltage transformer with% (/ phase of the phase selector, and the current transformers are connected to the phase-sensitive unit through the switching unit, the outputs of the first encoder of the program block are connected to the switching unit, From the outputs of the second encoder of the software block, they are connected to the phase selector unit, the second output of the phase selector unit is connected to the On and Off control unit, the outputs of which are connected to the first inputs of the logical AND elements of the IS-NOT to the second kotoso ryh inputs connected decoder outputs. with

Description

The invention relates to power engineering and can be used as an automatic controller to compensate for reactive power. Devices are known for automatically compensating for the reactive power of industrial plants using a capacitor battery, operating as a function of the phase angle between the current and the voltage of the network Art. The closest to the proposed technical entity is an automatic regulator containing a current transformer and a voltage transformer connected to the input of a phase-sensitive unit, the outputs of which are connected via the Enable and Disable control units to the static battery capacitor control unit 12. A disadvantage of the known automatic regulators is a low value of the utilization rate of equipment regulators. Operating experience and technical requirements for disconnecting static capacitors show that there is no need for continuous monitoring of current and voltage. This operation can be done periodically for short periods of time. The remaining free time can be used to monitor current and voltage in other electrical networks. Thus, in known regulators, it is possible to increase equipment utilization. The purpose of the invention is to expand the functionality. The goal is achieved by the fact that the automatic regulator to compensate for reactive power, which contains a current transformer and a voltage transformer, is connected to the input of the phase-sensitive unit, the outputs of which are connected through the control modules of the battery of static capacitors, current transformers were introduced according to the number of additionally monitored electrical networks, a switching unit, a network voltage phase selection unit, and a software unit made in the form of an imp pulses connected to a counter connected to the input of the decoder, the number of outputs of which is equal to the number of batteries of practical capacitors and connected to two encoders, the number of outputs of the first of which is different to the number of monitored electrical networks, and the number of outputs of the second of which is equal to the number of phases network, and the static battery capacitor control logic unit consists of cells, the number of which is equal to the number of static capacitor batteries, each of which contains two NAND logic elements, with connected to the RS flip-flop, the voltage transformer through the phase picker, and the current transformer through the switching unit are connected to the phase-sensitive unit, the outputs of the first encoder of the program block are connected to the switching unit, the outputs of the second encoder of the program block are connected to the phase selector, the second output of the selector The phases are connected to the Enable and Disable control unit, the outputs of which are connected to the first inputs of the NAND logic elements, to the second inputs of which the decoder outputs are connected. The drawing shows an automatic controller for compensating reactive power, a block diagram. The automatic regulator contains current transformers 1.1, 1.2, ... 1.k, where k is the number of monitored circuits, voltage transformer 2, phase-sensitive unit 3, control units Enable, Disconnect 4, logic control unit 5 with batteries of static capacitors, memory cells of 6.1, 6.2 ... 6.P, each of which in turn contains a RS-flip-flop and two NAND logic gates (n number of batteries of static capacitors), switching unit 7 current transformers, Bt i6opa unit network voltage phases 8, software block 9, with holding pulse generator 10, counter 11, decoder 12, encoders 1 3 and 1 4. The number of current transformers 1 included in the controller is equal to the number of monitored electrical networks. The number of batteries of static capacitors is greater or, in extreme cases, equal to the number of controlled electrical networks. Thus, for each electrical network, if necessary, one, two or more batteries of static capacitors can be attached. The number of outputs of block 5 is equal to p. The operation of the automatic controller consists in that it alternately determines the required state of each static capacitor battery connected to it and stores the received state until the next time interval of operation with this static capacitor battery. The pulse generator 10 sets the time required for using the proposed automatic controller to determine the state in which the battery of static capacitors with which the current moment of time does work, as well as set and remember the found state. The generator 10 starts the counter 11, which, together with the decoder 12, determines the sequence of correction of the states of the batteries of static capacitors. The encoders 13 and 14 connected to the output of the decoder 12 set the connection programs to the phase-sensitive unit 3 using blocks 7 and 8, respectively, of current transformers 1 of other electrical networks, and the voltage transformer of phase transformer 2. The encoders are made on logical elements OR. The number of inputs of each encoder is equal to the number of batteries of static capacitors connected to the automatic controller. The number of encoders of the encoder 13 is equal to the number of electrical networks in which the batteries of the static capacitor controlled by the automatic controller are installed. The encoder has three outputs in accordance with the number of phases of the network, which need to be synchronized. The test of the automatic control program starts with the determination of the state of the battery of static capacitors. For this purpose, the encoders 13 and 14 block 10 use blocks 7 and 8 to connect the required current transformer 1 and through the voltage transformer 2 the necessary phase of the network voltage (set by the program) and the phase sensitive unit 3. In addition, using the output signals of the decoder 12 selection of a memory cell 6.1 of block 5 attached to a battery. The choice is made by applying a logical unit to the general view of the AND logic elements included in cell 6.1, and the logical inputs of the remaining cells of the memory at this time are given. The output signal of the phase-sensitive unit 3 actuates the control units 4, which, depending on the signals of blocks 3, 8, produce either the Enable command or the Disable command, which is a short single. impulses. One of the commands of block 4 is fed to the inputs of memory cells 6.1, 6.2, ... 6.p of logic unit 5 for controlling a battery of static capacitors. The output signals of the decoder 13 contribute to the fact that the command of block 4 will be fixed only by element 6.1 and, accordingly, will remain the same or the state of the battery will change. Then, the automatic controller in a similar way alternately identifies and stores the state of the batteries of static capacitors. After the batteries have determined the status of static capacitors, the controller starts up again with the first battery, etc. Thus, the proposed automatic regulator for compensation of reactive power has more extensive functionality than the known ones.

Claims (1)

AUTOMATIC REGULATOR FOR COMPENSATION OF REACTIVE POWER, containing a current transformer and a voltage transformer connected to the input of the phase-sensitive unit, the outputs of which are turned on via the control unit; it is equipped with current transformers according to the number of additionally controlled electric networks, a switching unit, a phase voltage phase selection unit and software a lock made in the form of a pulse generator, connected to a counter connected to the decoder input, the number of outputs of which is equal to the number of static capacitor batteries and connected to two encoders, the number of outputs of the first of which is equal to the number of monitored electrical networks, and the number of outputs of the second encoder is equal to the number of phases networks, the static control unit of the battery of static capacitors consists of cells, the number of which is equal to the number of batteries of static capacitors, each of which contains there are two NAND gates connected to the RS-flip-flop, with the voltage transformer through the phase selection unit, and the current transformers through the switching unit connected to a phase-sensitive unit, the outputs of the first encoder of the software unit are connected to the switching unit, the outputs of the second encoder of the software unit are connected with a phase selection unit, the second output of the phase selection unit is connected to the Enable and Disable control unit, the outputs of which are connected to the first inputs of the NAND gates, to the second inputs of which the output is connected s decoder.