SU838891A1 - Device for multisted capacitive compensation - Google Patents

Description

The invention relates to the electric power industry, in particular to devices for lateral compensation of reactive power.

Known multistage adjustable capacitor unit (KU), in which each stage contains a series-connected capacitor bank with a reactor and a main vacuum switch, which is shunted by a resistive chain of two series-connected resistors. In the resistive circuit there are two additional auxiliary switches: the first is connected in series with the resistive circuit, and the second shunts one of the resistors. The KU is turned on first by the first auxiliary switch of the resistive circuit. Through both resistors, then one of them is bypassed by the second switch, and the last step is to turn on the main vacuum switch that shunts the resistive circuit. By such a three-stage switching on of the switchgear, a substantial damping of current and voltage is achieved, the inrush of which does not exceed the permissible p ^5. The disadvantage of this circuit is the presence of a large number of switching devices (three switches for one stage) and two resistors. Also known is the installation of capacitive lateral compensation, when turned on, the reactor is shunted by a protective device consisting of a resistor and a spark gap SI

However, when KU is switched on, an increased voltage is created at the reactor inductance, which causes the arrester of the protective device to operate. In this case, the reactor is shunted, and the resistor is introduced into the circuit KU, which dampens the current and voltage. With frequent KU switching, the arrester is replaced by a switch,

838891 4

Which turns on before turning on ^: KU, and then turns off. The disadvantage of this device is that in multi-stage switchgears, when the next stage is connected in parallel with the previous surge voltage and current, they reach 1.3-1.5 and 1.7-2.1, respectively, which is unacceptable. For KU with frequent switching of steps, these throws lead to an increased 'I' znozoukondensator .; and, therefore, to reduce the reliability of the KU.

The purpose of the invention is to limit overvoltage and inrush currents. This goal is achieved by the fact that in the device multi-stage capacitive compensation, containing. of each stage, a capacitor bank connected to the ground, a reactor and a resistor connected in parallel and connected between the capacitor bank to the high-voltage bus through individual circuit breakers with block contacts and a control unit for circuit breakers with separate on and off circuits due to the fact that the resistor circuit breaker is turned on the opening contact block of the reactor switch is included, the closing circuit of the resistor switch is inserted into the circuit of its inclusion, and the circuit is connected to the circuit of breaking of which controlling unit switch-contact reactor,

The drawing shows a diagram of the device.

The device consists of a main switch 1 and several stages 2 connected to a high-voltage bus 3 and ground 4. A capacitor bank 5 is included in the stage, the reactor and resistor 7 are connected through their switches 8 and 9 to the bus 3. The control unit 10 for connecting the stage is connected with the circuit And turning on the resistor switch 9 through the opening block contact 12 of the switch 8 of the reactor 6. In addition, the control unit 10 is connected to the circuit 13 of turning on the switch 8 through the closing block contact 14 of the resistor switch 9 and with the switching circuit 15 of the switch 9 re the resistor 7 through the closing block contact 16 of the switch 8 of the reactor 6.

The device operates as follows.

When the next stage is turned on, the control unit 10 at the first stage gives a command to turn on the switch 9 of the resistor 7, and after ₅ closing the contact block 14, the second step is turned on by the circuit 13 of the switch 8 of the reactor 6, thereby connecting the resistor 7 in parallel Then, at the third stage Yu, after the block contact 16 is closed, the switch 9 of the resistor 7 is turned off. Thus, a three-stage switching on of each stage occurs, which increases the efficiency of reducing the inrush and current surges 15 '. Since at each stage the transition process ends in 2-3 periods, then by the time the switches 8 and 9 are turned on, the transition processes end.

In terms of efficiency, this device is similar to a device with three-stage switching on, but compared with the last one, each stage has only one resistor (instead of two) and 25 two switches (instead of three). With the optimal value of the resistance of the resistor 7 (calculations were done on a computer), the surges of voltage and current in the circuit are within acceptable limits.

Claims (4)

The invention relates to electric power industry, in particular to devices for lateral compensation of reactive masses. A well-known multistage adjustable condenser unit (KU), in which each stage contains a series-connected capacitor bank with a reactor and a main vacuum switch, which is shunted by a resistive chain of two series-connected resistors. In the resistive chain there are two more auxiliary switches: the first is connected in series with the resistive circuit and the second shunts one of the resistors. The switching on of the control unit is performed first by the first auxiliary switch. The body of the resistive circuit. Through both resistors, then one of them is shunted by a second switch, and the last stage - the inclusion of the main vacuum switch, shunt the resistive circuit. Such a three-stage switching on of the capacitor unit achieves a substantial damping of the current and voltage, the surges of which do not exceed the limits of admissible I J. The disadvantage of this circuit is the presence of a large number of switching devices (for one stage three switches) and two resistors. Also known is the installation of capacitive transverse compensation, when switched on, the reactor is shunted by a protective device consisting of a resistor and a spark gap. 2. However, when switching on the capacitor on the inductance of the reactor, an overvoltage is created, which triggers the protection device. In this case, the reactor is shunted, and the resistor is introduced into the capacitor circuit, which damps the current and voltage. In case of frequent switching, the DL is replaced by a switch. Which is turned on before switching on KU, and then disconnecting. The disadvantage of this device is that in multistage KU, when connecting the next stage parallel to the previous surge voltage and current, reach respectively 1.3 1.5 and 1.7-2 , 1 which is unacceptable. For QA with frequent switchings, the above throws lead to increased wear and tear on the capacitors, HS therefore, to a reduced reliability of the KU. The purpose of the invention is to limit overvoltages and inrush currents. The goal is achieved by the fact that in a multi-stage capacitive compensation device, containing. each stage is a capacitor battery connected to ground, a reactor and a resistor connected in parallel and connected between, a capacitor battery and a high-voltage bus through individual switches with auxiliary contacts and a control unit with switches with separate / de-energized on / off switches due to that in the switch-on circuit of the switch of the resistor the breaker contact contact of the reactor switch is turned on, the closing circuit contact of the switch of the resistor is inserted in the switch-on circuit, and the switch-on circuit of which is switched on abutting contact switch block reactor. The drawing shows a diagram of the device. The device consists of a main switch 1 and several stages 2 connected to a high-voltage busbar not 3 and to earth 4. The stage includes a capacitor battery 5, the reactor 6 and the resistor 7 are connected through the switches 8 and 9 to the bus 3. A control unit 10 for switching on a stage is connected to an on circuit 11 for switching off the resistor body 9 through the disconnecting block-contact 12 of the reactor's switch 8 6. In addition to the control unit 10, the control unit 10 is connected to the activating circuit of the 8-switch 8 through the closing block of the resistor 9 7, and with circuit 15 disconnecting the switch 9 of the resistor 7 through the closing block terminal 16 of the switch 8 of the reactor 6. The device operates as follows. 14 . When the next stage is turned on, the control unit 10 at the first stage issues a command to turn on the circuit 11 of the switch 9 of the resistor 7, and after closing the block of the contact 14 at the second stage turns on the circuit 13 of the switch 8 of the reactor 6, thereby the latter is connected in parallel to the resistor 7. in the third stage, after the closure of the block-contact 16, the switch 9 of the resistor 7 is turned off. Thus, a three-stage connection of each stage occurs, which increases the efficiency of reducing the voltage and current surges. Since at each stage the transient process ends in 2–3 periods, by the time the switches 8 and 9 are turned on, the transients end. In terms of efficiency, this device is similar to a device with three-stage switching, but compared to the last, there is only one resistor in each stage (instead of two) and two switches (instead of three). At an optimal value of the resistance of the resistor 7 (calculations are made on a computer) voltage surges and the current in the circuit is within the allowable limits. Invention A multistage capacitive compensation device containing in each stage a capacitor battery connected to earth, a reactor and a resistor connected in parallel and connected between a capacitor battery and a high voltage bus through individual switches with auxiliary contacts and a switch control unit with separate switching circuits and tripping, characterized in that, in order to limit overvoltages and inrush currents, a disconnecting contact is switched off in the resistor switch on circuit ents reactor in which the circuit incorporating entered closing the auxiliary contact switch resistor and a shutoff circuit of which includes a normally open switch contact block reactor. Sources of information taken into account during the examination 1. Mamoshin P.P., Zabelova L.F. Resistive start-up scheme of adjustable transverse capacitive compensation for posts for sectioning roads electrified on alternating current. Sat Improving the quality of electric energy, h. 4., Kiev, Institute of Electrodynamics, Academy of Sciences of the Ukrainian SSR, 1978, p. 59-61. 2, Borodulin BM, German L.A. Condenser installation of electrified AC railways. M., Transport, 1976, p. 94. 14 Wed / 1G No. f " lit L