SU43071A1 - Device for protecting electrical installations from reverse current - Google Patents

Description

The present invention relates to the protection of electrical installations against reverse current, and consists in the fact that, in order to apply a maximum relay as an organ that reacts to reverse current, the electrical resistance or differential transformer is specifically included in the protected line.

FIG. 1 of the drawing shows a diagram of the inclusion of the proposed device; FIG. 2-modifying it.

Parallel to a certain section of the protected line, an auxiliary branch is switched on, as shown in FIG. 1, with load concentrated at point C. 3. This branch can be considered as a line fed from two sides, i.e. from the switching points of the branch. Due to a drop in the voltage Tia of the section AB of the line, the auxiliary branch will have different voltages EI and E ъ points A and B, and the voltage at the branch point closest to the power source, for example, at point A-will be greater than the voltage in point B, further away from the power source.

The value of currents i-i and 4 in the sections of the AU and CB of the auxiliary branch will be equal, respectively:

, I Ha, E - Et

. . . . (one)

 G1 .- {- G2

P ,

Jei-e

Jn

(2)

; -r

g I -) - "n -} - gz n -j- ri gy + n

where TI and Gz are the resistances of the wires / k 2 in the sections AC and CB (both ways), and / is the current flowing through the resistance 3.

From equations (1) and (2), it appears that with small values of r and g, the insignificant difference between the voltages E - and, significantly affects the distribution of currents ii and / 2. moreover, for practical implementation of protection, it will be sufficient to have a voltage difference of the order of tenths of a volt, which always takes place within the switchgear on the bus connections of the latter. In this case, the protection is carried out by switching on the conventional maximum MR relay on the auxiliary branch EC portion.

The relay is adjusted to a current slightly higher than 4, obtained by calculating the idle mode of the AB line, i.e., under the condition E-EZ.

During normal operation of the line under load, i.e., when the line is powered from the A side, the value of the 4. current flowing through the relay decreases as the load increases; on the contrary, when the reverse power is insignificant, ie, the line is powered from the B side, the relay current increases significantly and, when the relay is tuned, as mentioned above, to a current, without having to pick up a greater current of the hollow mode of the line, it leads to the operation of the relay and the line to shut down. The scheme described can be applied without changes to low voltage networks. The magnitude of the constant load while applying a sensitive induction counter (Ferraris motor) may be small — on the order of 50-100 watts.

It should be noted that the values of the load / and the ratios f and g must be chosen taking into account the insensitivity of the circuit to the through short circuits m.

The application of the described circuit in high voltage networks can only take place through transformers. This limits the range of application of the circuit, since slight changes in voltage on the primary high voltage side of the transformers will not reflect on the parallel operation of the low voltage side. However, the presence in modern networks of a whole range of reactors (reactors, partitioning, tires, power transformers) allows the use of the described scheme in high voltage networks. In the event that a voltage drop is used in a transformer for auxiliary branch transformers, the transformation coefficient must be taken into account.

In this case, the circuit can be implemented using a single differential transformer.

Transformer 4 is performed on the core of a normal three-phase transformer; the cross section of the iron of the middle rod may be smaller than that of the extreme rods. The transformer switching circuit is shown in FIG. 2

Extreme windings (high voltage windings) are calculated for the protection voltage of the network section, and the winding connected behind reactors 5, calculated from the power supply (point B), has a slightly lower inductive resistance than the winding connected before the reactor (point A) , is proportional to the voltage drop in the section AB.

b The secondary circuit, located on the middle rod, directly activates the maximum relay.

The primary windings A and B are included in the LINE in such a way that their magnetic fluxes on average of the core are subtracted.

In the idle mode of the line, the magnetic flux of the middle core will have maximum values when the line is powered from the A side. Do the SRI load, and therefore the decrease of E with respect to E, similarly to the first case, will decrease the magnetic flux of the average rod and relay current. On the contrary, the current flowing along the line from the B side, i.e. the condition ECH EI, will cause an increase in the magnetic flux of the middle rod above the flow when the line is idle, to which the relay can be adjusted, which will lead to the latter's operation.

The latter circuit has an advantage over the first one due to the absence of a dead zone of the relay.

The subject matter of the invention.

Claims (2)

1. A device for protecting electrical installations from reverse current, characterized in that, in order to apply a maximum relay as an organ responsive to reverse current, between two conductors 7 and 2 connected in parallel to the wires of the section AB of the protected line, electrical resistance 3 is turned on, and the specified maximum relay is included in one of the wires 7, 2 between resistance 3 and the load. 2. A device change according to claim 1, characterized in that, in order to apply it to protect high voltage AC installations, a differential transformer 4 with two primary windings, of which a winding with a large number of turns is connected to the line, is used to power the maximum relay between the linear reactors 5 and the current source, and the winding with a smaller number of turns between the reactors 5 and the load. YOU aBTopCKOsty certificate A.A. No. 43071 Resurrection Fig1 -VWVVAWWVA