SU688957A1 - Device for compensating for reactive power - Google Patents

Description

The invention relates to electrical engineering, in particular, to devices for compensating reactive power in alternating current power transmissions. A device for reactive power P is known, containing a cap1, its reactor with a winding located on a magnetic conductor having air gaps 1. When connecting such a reactor to two-price AC transmission with close-coupled phases, but where the conditions for ensuring maximum transmission capacity of the electrical transmission are it is necessary to control the angle between the approaching phases from 0 to 180 °, and when the angle of 120 ° is reached, the reactors i.-, tori connected between opposite phases, are completely removed from operation. Moreover, at values of phase angles greater than 120 °, they require significant reactive power and, thus, 20 thereby prevent an increase in the transmission capacity of the electron transfer. The closest technical solution to the invention is a device for compensating reactive power with a shunt-2.5 reactor containing a winding located on a three-core magnetic core, the middle rod of which is made with a non-magnetic gap 2. This reactor has a linear magnetization characteristic, however all of these drawbacks when using it to compensate for reactive power in two-circuit power transmissions and current with approximate phases. The purpose of the invention is the application of a device on two-price transmission lines with approached phases and an extension of the range of control of reactive power compensation. The goal is achieved in a device to compensate reactive power, which contains a shunt reactor, having a winding located on a three-rod magnetic circuit, the middle rod of which is made with a magnetic non-magnetic gap, the stanchion reactor additionally contains a second winding, on each side of the conductor pipe. winding, the beginning of each of which is for the connection to the corresponding of the two contiguous phases of the double-circuit line, and the ends of the union are intended for grounding. In addition, it contains two additional series n according to the connected windings of the bypass reactor, located one on each of the outermost cores of the magnetic circuit,

to which a capacitor is connected through a switching apiarat.

The drawing shows a diagram of the shunt reactor.

It has a three-core magnetic conductor 1, on which windings 2 and 3 are located, intended for connection to the adjacent phases A and A of double-circuit transmission and windings 4 and 5, which are connected according to and in the circuit of their connection, a capacitor 6 and a switching apiarat 7 are connected.

The operation of such a reactor when connecting it to a double-circuit AC power with close phases will be considered for the two extreme modes of power transmission.

When the power is in idle, the loads applied to terminals A and A of the reactor are identical in phase. Due to this, the currents generated by the currents flowing through the windings 2 and 3 in the same relatively similarly-shaped terminals of the voltage are also directed in the same way and are closed through the middle core of the magnetic circuit 1, which has a non-magnetic gap (flat arrows in the drawing). The magnetic resistance in this case is large. To conduct a magnetic flux, a large magnetizing current is required, therefore windings 2 and 3 from the network consume the maximum reactive current, i.e., the reactor operates in the mode of maximum compensation of the reactive power of the line. In this case, the EMF induced in the windings 4 and 5, to which the capacitor 6 is connected, have the same magnitude, but the opposite direction, as a result of which} the a voltage on the capacitor 6 is zero,

When the transmission operates at full load, the phase shift angle between the adjacent phase lines is maintained at 180 °. Since the voltages applied to terminals A and A of the reactor are in antiphase, the currents in windings 2 and 3 have different directions with respect to the like terminals, the fluxes in the rods also change direction relative to each other and are closed in the magnetic conductor 1, as shown. in the drawing are dotted arrows. The resistance to the magnetic flux is small, so the inductive magnetizing current consumed from the network is small. However, the EMF induced in windings 4 and 5 coincide in phase and

the voltage on the capacitor 6 reaches its maximum value, and the reactor consumes a capacitive current from the line. Consequently, the mode of least inductive compensation of the line charge power and the maximum additional reactive power generation by the capacitors 6 are provided.

Power line modes are possible when it is not required that a capacitor be in operation. A switch is provided in the circuit to disconnect the capacitor. Thus, the device made

According to the invention, it increases the capacity of double-circuit transmissions with close phases and increases the control range of the transmitted power.

Claims (2)

1. A device for controlling reactive power, containing a shunt reactor, or winding, located on a three-core magnetic core, whose middle rod is made with a nonmagnetic gap, characterized in that, in order to use on double-circuit power lines with close phases, the shunt reactor also contains a winding, in this case on each of the extreme rods of the magnetic conductor, one winding is located, the beginning of each of which is intended to be connected to the corresponding of two sat. the two phases of the double-lined line, and the ends are connected and ground to ground. 2. The device according to claim 1, characterized in that, with the purpose of extending the range regulating reactive power compensation, it contains two additional series and according to the connected windings of the shunt reactor, located one on each of the outermost cores of the magnetic circuit, to which a capacitor is connected through a switching device. Sources 1P1formatsii, Irish Ty in attention prp examination 1. Wilhelm R., Waters M. Neutral Grounding in High Voltage Systems. M, SEI, 1959, p. 345. 2. Petrov G. P., Electric Machines, Part 1. M., GEI, 1956, p. 175 (prototype). PS