SU600462A2 - Arrangement for comparison of two ac voltages - Google Patents

Description

one

The invention is adapted to relay protection devices, in particular, to maximum current protection, and can be used to protect electric motors, power lines, geyoretors, and transformers with a K / A- | winding circuit.

According to the main author. St. No. 542143, a device for comparing two alternating voltages is known, comprising a bridge circuit, which is powered by one of the compared voltages and two diode comparison circuits, each of which forms two adjacent arms of a bridge circuit, the number of diode circuits being compared to doubled the number of phases, each additional diode comparison circuit forms an additional bridge circuit, to the input of which one of the compared values is fed, and the output diagonals of all bridge donolitelio circuits include Gotka Polisovaya Relay.

The disadvantage of the known device is that it can not work irn damage to the transformer I / A-

The aim of the invention is to expand the scope of application by providing protection against damage behind a power transformer ./A-j |. The goal is achieved by the fact that the cathodes of bridge diodes

circuits included in adjacent phases are interconnected and connected to resistors, and a polarized relay is connected via a rectifier to the secondary windings of intermediate transformers, and the nerves of the intermediate transformers are included in the adjacent arms of the MOCTOBI IX circuits.

Pa figs. 1 shows prpntspppal diagram of the device of the irppeppepp; pas figs. 2- circuit connected 1 winding of the relay relay.

Pa figs. 1 primary windings of intermediate traps-reactors A, B, C flow around the corresponding tocamp / l; /at - (); fc, and the secondary nx windings are distributed to the supplying diagonal and bridge circuits. In the first nanoliod circuit, each bridge consists of two diode comparison circuits. The bridge of phase L 1 has a bottom circuit that is similar, contains 1, dpod 2 and resistor 3, and the second, containing resistor 4, diode 5 and resistor 6. To balance the bridge circuit, the resistors 1 and 4 must be equal if the resistances of the resistors 3 are equal and 6.

The phase B washes also has a first DND 30 comparison mode, containing a resistor 7, a diode 8 and a resistor 9, and a second one - containing a resistor 10, a diode 11 and a resistor 3 (common with the phase A bridge).

The phase C bridge likewise has a first diode comparison circuit containing a resistor 12, a diode 13 and a resistor 6 (common with a phase A bridge), and the second one containing a resistor 14, a diode 15 and a resistor 9 (common with a phase B bridge).

Thus, each bridge circuit has two common resistors with other bridge circuits. In the scheme of the second half-period, the bridge circuits are made similarly, but in each phase, the bridge circuits have two common points (resistors 1 and 4; 7 and 10; 12 and 14) and the output diagonal. In the scheme of the second noluperida, the individual legs of the bridge circuits consist of: in phase L - a nara from diode 16 and resistor 17, and also a nara from diode 18 and resistor 19; in phase B - a pair of diode 20 and resistor 19 (common with phase L), as well as a bunker of diode 21 and resistor 22; in phase C, a nara from diode 23 and resistor 22 (common with phase B), as well as a pair from diode 24 and resistor 17 (common with phase L). To the output diagonal of the bridges, the primary windings of the intermediate transformers 25 are connected to each other (see Fig. 2). The secondary windings of transformers 25 are connected via a rectifier 26 to a polarized relay 27 winding, through whose closing contact (see Fig. 1) a resistor 28 is connected in parallel with the outermost terminals of the winding 29 of the main electromagnetic relay. Resistor 30 may be useful for adjusting the set point and for smoothing.

The device works as follows.

Under the conditions of a three-phase current in the interval of the angle @ (from O to 30 °, the instantaneous value of phase C voltage exceeds the voltage of phase L. As a result, diode 13 will pass current to resistor 6 and diode 5 will be locked. This will cause unbalance in the output diagonal bridge L, and the current pulse will be negative, as it enters the end of the winding of the transformer 25.

In the interval of angle from 30 to 60 °, the voltage of phase L exceeds the voltage of phase C. Therefore, the tenant will pass current to resistor 6 to be diode 5, and diode 13 will turn out to be locked, which will cause an imbalance in the output diagonal of the phase C bridge, and the current impulse will be positive , since it enters the beginning of the transformer 25 winding. In the interval of the angle from 60 ° to 120 °, the instantaneous values of the voltages (-B) and (-C) in the second zero-voltage circuit on the resistor 22 through diodes 21 and 23 will be compared in the same way causing unbalances in the output diagonal of the bridges of phase C and then the phases . Thus, for neriod voltage network pas secondary windings of transformer 25 receives a total voltage in the form schesti periods schestoy harmonic. When the three-phase current rises to the desired value, the polarized relay 27 will also trip with its closing contact.

connect the resistor 28 in parallel to the winding 29 of the main electric helix generator), and the cause of which is worse is shortened.

Under the conditions of a pure two-phase and current at the output diagonals of the bridge circuits, nanr / kenya pulses are not, since there is no third current, and the two curvatures and phases created by them of the secondary windings of the transreactors left by the other cannot disturb the unbalance of the bridge circuits. Thus, in this device, a polarized relay 27 and. Has a different sensitivity at three-phase and two-phase currents. Similarly, it has a different sensitivity at three-phase and single-phase currents.

If on one side of a power transformer with a winding connection circuit l / A- | | if there are two-phase short-circuit currents, they are transformed to the other side in the form of three currents, of which two (half magnitude) are in phase, and the third (full magnitude) is shifted by 180 °. The voltage on the secondary windings of the intermediate transformers of the B and C phases of the half value coincides in phase, while the voltage of the phase L full value is shifted by 180 °. In a phase L bridge, an unbalance of voltage does not occur on the output diagonal, since there is no other voltage that could cause a violation of the balance of the bridge. Bridges of phase B and phase C will produce unbalances of output on the output diagonal x, as the threading voltages of these bridges disturb one another of the balance of the bridge, but the current impulses from the output diagonals of these bridges will be opposite to the sign: one - at the beginning of the primary winding transformer 25, and the other - to the end of a similar winding. If the bridges are sufficiently identical, then the current impulses will also be equal in magnitude. As a consequence of this pas secondary windings

5 transformers 25 total voltage will be practically zero.

Thus, a polarized relay 27 has a different sensitivity at three-phase and two-phase currents also in cases

0 damage to power transformer

VA-II.

In addition to the exemplary embodiment shown in FIG. 1 and 2 may be the following.

Intermediate transreactors A, B, C are replaced by intermediate current transformers, showing switches transferred from horizontal to vertical position. In this case, the resistors (I, 4, 7, 10, 12, 14) are excluded from the circuit, and the primary windings of the intermediate transformers 25 are included in the adjacent bridge circuits. Thanks to this, the device is installed.