RU2305292C1 - METHOD OF DETECTING FAULT IN 6( 10 )-35 kV ELECTRIC CIRCUIT WITH ISOLATED OR COMPENSATED NEUTRAL POINT - Google Patents

Abstract

FIELD: electric measuring technique.

SUBSTANCE: method can be used at exploitation of three-phase electric circuit with isolated or compensated neutral point for quick detection of faults without switching consumers off. Meaning of constant parameter, namely inductivity of line, is preset. Damaged line is revealed. Parameters of transient process in damaged line are measured: instant value of voltage at moment of fault, instant value of current at moment of fault, voltage in neutral point, amplitude values of current in damaged line in time. Distance from substation to fault point is calculated on base of constant and measured parameters.

EFFECT: improved precision; higher speed of operation.

2 cl, 2 dwg

Description

The invention relates to electrical engineering and can be used in the operation of three-phase electrical networks with isolated or compensated neutral to quickly determine the place of their damage, without disconnecting consumers.

There is a method of determining to the point of phase to ground fault in networks with isolated neutral (AS USSR No. 1559318), according to which, when a source of non-industrial frequency is turned on through a compensating device, a voltage resonance is established on the circuit consisting of the capacity of the network wires with an additional adjustable inductance during normal operation of the network, a stabilized current of non-industrial frequency is obtained, flowing through a wire closed to ground, the voltage between the points is fixed oh connection of the resonant inductance to the mains and ground, measure the angle between the measured voltage and the known voltage of the non-industrial frequency source, and the distance to the point of phase to earth fault is determined by the formula, based on the values of the resonant inductance of the selected circuit, the inductance of one kilometer of the line, the voltage between the point of attachment of the resonant inductance to the electrical network and ground, the angle between the measured voltage and the voltage of the non-industrial frequency source . The disadvantage of this method is the complexity of its implementation, which requires, in particular, the availability of a non-industrial frequency source, additional adjustable inductance and the establishment of a resonant mode with subsequent measurement of parameters. In addition, it requires a sufficiently long time, which makes this method ineffective.

There is a method of determining the location of a single-phase earth fault in a branched overhead power line with an isolated neutral (RF Patent No. 2285883), according to which they move under its power lines along its branches and take measurements as an alarm signal of the electric and magnetic fields, convert them into harmonic components proportional to them voltage and current signals, and the earth fault location is determined by changing the sign of the phase angle between the harmonic components of the voltage and current signals of the selected i-th harmonic nicks. The disadvantage of this method is its complexity and lack of accuracy, in addition, it cannot be carried out by hardware at the substation, and the brigade needs to go to the line.

A known method for determining the distance of a single-phase circuit in a three-phase power line [RF patent No. 2186404], in which the following sequence of operations is carried out: determine the first phase of the power line with damaged insulation, closed to the ground; disconnect the power line from the power source; short-circuit the wires of the first phase with damaged insulation and the second phase with intact insulation at the end of the power line at a known distance L from the power source with a jumper; open the supply end of the third phase wire with intact insulation using, for example, a switching device; connect to the ground a third-phase wire with intact insulation at the beginning and end of the power line with jumpers; connect to the ground a zero point or terminal of the second phase with intact insulation of the power source using a switching device; connect the first phase with damaged insulation and the second phase with intact insulation to a power source; measure the voltage U ₁₂ at the terminals of the power source between the first phase with damaged insulation and the second phase with undamaged insulation, as well as the values of currents I ₁ and I _{2 of} these phases; determine the distance l _k to the place of a single-phase circuit according to the formula

where L is the distance from the power source to the opposite end of the line.

The main disadvantage of this method is the need to disconnect the damaged line from the power source, which will inevitably cause a malfunction of consumers. In addition, this method gives errors due to the fact that the currents I ₁ and I ₂ retain components due to single-phase loads connected between the first phase with damaged insulation and the second phase with undamaged insulation, as well as due to the presence of transverse capacitive conductivity between the first and second phases, and also between the second phase and the ground.

The closest in technical essence is a method for determining the distance of a single-phase circuit in three-phase power lines with isolated or compensated neutral [RF patent No. 2249226], which is selected as the prototype. The prototype method is as follows: determine the first phase of the power line with damaged insulation, closed to the ground, in a known manner, for example using three voltmeters; disconnect the power line from the power source in a known manner, for example using a three-phase switch or disconnector; short circuits phases 2 and 3 with intact insulation at the beginning and end of the power line with jumpers; include at the beginning of the power line between the first phase with damaged insulation and ground a single-phase AC voltage source; measure the voltage between the first phase with damaged insulation and ground at the beginning of the power line, the current in the first phase and the phase angle between these voltages and current; set the values of constant coefficients depending on the specific parameters and the length of the power line according to the formulas:

determine the distance to the place of a single-phase earth fault by the formula

The main disadvantage of the prototype method is that to determine the place of damage, disconnect from the power source not only the phases with damaged insulation, but also the undamaged phases, and all consumers. Meanwhile, it is known (see Electrical Installation Rules. - M.: Energoatomizdat, 2003, p. 316) that protection against single-phase earth faults must be made in the form of selective protection acting on the signal, since the consumer has a certain period of time does not feel damage on the line and, if you reduce the time to eliminate such damage, you can turn off consumers, which is very important for all consumers, and for consumers with a continuous production cycle, (for example, chemical production) in particular Nost.

The task to which the claimed invention is directed is to eliminate these drawbacks, namely, to create a method that allows, while at the substation, to quickly and accurately determine the location of the damage by analyzing the parameters of the transient process of emergency operation, so that the repair team is directed exactly to the place of damage and at the same time, consumers were not disconnected from the power supply.

The problem is solved by the method according to which the values of the constant parameters of the power line are established, the damaged line is detected, the transient process parameters are taken on the damaged line, and based on the constant and measured parameters, the distance from the substation to the place of damage is calculated, in which, unlike the prototype, as constant parameters of the monitored line remember the linear inductance of the line, as the parameters of the transient process measure the instantaneous value on voltage at the time of damage, the instantaneous value of the current at the time of damage, voltage on the neutral, the amplitude values of the current on the damaged line sequentially in time, and the distance from the substation to the place of damage is determined from the ratio

where L ₀ - linear inductance of the damaged line is a constant value, depending on the material of the line;

u is the instantaneous voltage value;

i is the instantaneous current value at the time of damage;

U is the neutral voltage;

I _m1 , I _m2 - maximum successive amplitude values of the current on the damaged line.

The problem is solved in that the determination of the distance to the place of damage is carried out using a personal computer.

The dependence of the distance to the place of damage was determined by calculation from the following considerations.

Line inductance

where ω is the angular frequency, s ^-1 ;

L = (L _NL + L _K ) - line inductance equal to the sum of the inductances of the undamaged lines L _NL and the inductance from the beginning of the damaged line to the place of damage L _K , GN;

U is the neutral voltage, V;

I _m1 is the maximum amplitude value of the current.

The ratio of successive maximum amplitude current values on the damaged line

where R is the line resistance, Ohm.

Logarithm the left and right sides of the expression

from here

Express R

Instead of ωL, we substitute the formula for the line inductance

For the discharge of capacities when the line is damaged, an equivalent phase replacement circuit is drawn up (Fig. 2), in which the inductances of the damaged phase of the undamaged lines are replaced by the equivalent L _NL , the capacitances between the phase and ground are replaced by the equivalent C, the inductance from the beginning of the damaged line to the place of damage L _K , for the right side, according to the second law of Kirchhoff, we compose the differential equation:

Where from

If we substitute the expression for the linear inductance

and the previously derived value for R:

we get the final formula

The prior art does not know solutions that allow the hardware, without going to the line and the use of additional devices, to determine the distance to the place of damage. This determines the compliance of the proposed method with the criterion of "novelty."

The inventive method does not follow with obviousness from the prior art, since it was traditionally believed that the distance to the place of a single-phase earth fault in 6-35 kV networks cannot be determined from the records of current and voltage of the emergency mode, because the value of the earth fault current of any phase on any of the network lines extending from the power source does not depend on the location of the fault location along the line length and is determined by the total length of all connected network lines (see A. Kuznetsov. Determination of damage points on overhead lines power transmission. - M.: Energoatomizdat, 1989, p. 94). The inventive method refutes this statement, which allows us to consider it consistent with the criterion of "inventive step"

An experimental verification of the claimed device in real conditions showed that from the moment the first signal about the presence of damage arrives before the repairmen left for the place, taking into account organizational measures, it takes no more than 10-15 minutes, of which determining the distance to the place of damage takes no more than a few seconds. In this case, control and measuring devices made on the basis of a commercially available element base are used, which allows us to conclude that the proposed method meets the criteria of "industrial applicability".

Figure 1 shows a diagram of a device for implementing the inventive method, figure 2 - equivalent circuit to illustrate the calculations.

A device for implementing the method of determining the place of damage to the electric network of voltage 6 (10) - 35 kV with isolated or compensated neutral consists of phase A, phase B and phase C current sensors, the outputs of which are connected to the input of the zero-sequence current filter 1, voltage sensor, output which is connected to the input of the filter of the voltage circuit 2. The output of the zero-sequence current filter 1 is connected to the input of the filter of the current circuit 3, the first output of which is connected to the input of the inverter 4, and the second output is connected to the input of the comparator 5. The output of the fil Three voltage circuits 2 are connected to the first input of the adder 6, and the output of the inverter 4 is connected to its second input, the output of the adder 6 is connected to the first input of the analyzer 7, which can be used as a computer, the second input of which is connected to the output of the comparator 5.

The inventive device operates as follows. With a working network there is no signal on the sensors, the device is in standby mode. In the event of a phase to earth fault, signals other than 0 are sent from the sensors to the transducers 1 and 2. The device then processes the received information in order to determine the distance to the fault location from the above dependence.

Claims (2)

1. A method for determining the place of damage to an electric network of voltage 6 (10) - 35 kV with an isolated or compensated neutral, according to which the values of the constant parameters of the power line are established, the damaged line is detected, the parameters of the transient process on the damaged line are removed and based on the constant and measured parameters calculate the distance from the substation to the place of damage, characterized in that the linear inductance of the line is stored as a constant parameter, as a parameter in transient measured instantaneous voltage value at the time of injury, the instantaneous value of the current at the time of injury, the voltage at the neutral current amplitude values over the damaged line consecutively in time, and the distance from the substation to the fault is determined from the relation

where L ₀ - linear inductance of the damaged line; u is the instantaneous voltage value; i is the instantaneous current value at the time of damage; U is the neutral voltage; I _m1 , I _m2 - maximum successive amplitude values of the current on the damaged line. 2. The method according to claim 1, characterized in that the determination of the distance to the place of damage is carried out using a personal computer.

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