RU114377U1 - DAMAGE DETECTION DEVICE - Google Patents

Abstract

1. A device for determining the location of a fault in a power line, containing a series-connected generator of probing pulses, an amplifier, a phase wire of the overhead line is connected to the output of the amplifier, a computing unit connected to the phase wire of the overhead line to measure the voltage across it, characterized in that it is equipped with a current transformer installed at the output of the amplifier, and a measuring winding connected to the computing unit. ! 2. The device according to claim 1, characterized in that it is additionally equipped with a voltage transformer connected to the phase wire, the measuring winding is connected to the amplifier output. ! 3. The device according to claim 1, characterized in that it is additionally equipped with a coupling capacitor connected to the phase wire, the high-frequency output is connected to the amplifier output.

Description

The proposed technical solution relates to electrical engineering and is intended to determine the location of damage to sections of overhead lines.

A known method for determining the location of damage to power lines and communications and a device for its implementation, comprising a probe pulse generator, consisting of a controlled output impedance unit, a memory unit, a digital-to-analog converter and a power amplifier, a receiver, a computing unit, an indication unit. (Pat. RF №2269789, publ. 02/10/2006).

The disadvantage of this system is the work at frequencies close to the frequencies of the HF communication in the line, in addition, a wire break is not detected.

The technical problem solved by the utility model is to determine the location of damage (short circuit and open circuit) of the wire by determining the input impedance of the overhead line, depending on the frequency of the probing signal, and the displacement of the probing signal in the region of sound frequencies.

The technical result that arises when solving the problem is expressed in determining the place of a break and in reducing the influence of the device on the communication line and is achieved by the fact that the known device for determining the location of damage in the power line, containing series-connected probe pulse generator, amplifier, computing unit, according to the utility model equipped with a current transformer installed at the output of the amplifier, and a measuring winding connected to the computing unit.

In addition, the device is additionally equipped with a voltage transformer connected to the phase wire, the measuring winding is connected to the output of the amplifier.

In addition, the device is additionally equipped with a coupling capacitor connected to the phase wire, a high-frequency output is connected to the output of the amplifier.

Figure 1 presents the structural diagram of the proposed device.

Figure 2 shows the dependence of the input resistance on the frequency of the probing signal.

Figure 3 presents the structural diagram of the proposed device, additionally equipped with a voltage transformer.

Figure 4 presents the structural diagram of the proposed device, additionally equipped with a coupling capacitor.

The proposed device for determining the location of damage in the power line (Fig. 1) contains a generator 1, the output of which is connected to an amplifier 2. A phase wire of an overhead line (OHL) 3 is connected to the output of the amplifier 2. Computing unit 4 is connected to the measuring winding of the current transformer 5, which installed at the output of amplifier 2.

The proposed device for determining the location of damage works as follows.

Generator 1 supplies a sinusoidal signal to the input of amplifier 2, which amplifies the signal and supplies a sinusoidal voltage to the beginning of the phase wire of OHL 3. Generator 1 gradually increases the frequency of the signal.

The computing unit 4 is connected to the phase wire of the overhead line 3 to measure the voltage on it. In relation to the current value of the voltage on the phase wire of the overhead line to the current flowing through the phase wire of the overhead line 3, we determine the input resistance of the phase wire of the overhead line, which varies from the signal frequency.

The computing unit 4 through a current transformer 5 measures the current value in the phase wire of the overhead line 3.

In case of damage to the overhead line (short circuit or open circuit) with an increase in the frequency of the probing signal, minimums Z _in (in the case of short circuit) and maximums Z _in (at break) _arise . Knowing the frequency at which the first minimum or maximum is detected, it is possible to determine the distance l to the damage site, which is equal to a quarter of the wavelength of the signal of this frequency λ [Electricity No. 5/2009 Normal waves in phase lines, pp. 51-54]:

When using amplifier 2, the amplitude of the voltage at the output of the amplifier does not significantly depend on the current and frequency, therefore, the form of the dependence I (f) will approach Z _in (f), while the frequency f is _cut at which a minimum of current I _{min occurs} (at short circuit) and the maximum current I _max (at break) will coincide with the frequency at which there will be a minimum of Z _{in min} (at short circuit) and a maximum of current Z _{in max} (at break).

In the case of supplying the device with an additional voltage transformer (Fig. 3) connected to the phase wire 3, the measuring winding is connected to the output of the amplifier. The device operates as follows.

The generator 1 supplies a sinusoidal signal to the input of amplifier 2, which amplifies the signal and supplies a sinusoidal voltage to the measuring winding of voltage transformer 6, which increases and is fed to the phase wires of VL 3.

The computing unit 4 is connected to the measuring winding of the voltage transformer 6 to measure the voltage on it. In relation to the current value of the voltage on the measuring winding of the voltage transformer 6 to the current flowing through the measuring winding of the voltage transformer 6, we determine the input resistance of the phase wire of the overhead line 3, which varies from the signal frequency.

The computing unit 4 through the current transformer 5 measures the current value in the measuring winding of the voltage transformer 6.

The distance to the place of damage is determined by the change in Z _in from the signal frequency:

In the case of supplying the device with an additional coupling capacitor (Fig. 4), the device operates as follows.

The proposed device is additionally equipped with a coupling capacitor 6 connected to the phase wire of the overhead line 3, the high-frequency output of which is connected to the output of the amplifier 2.

The generator 1 supplies a sinusoidal signal to the input of amplifier 2, which amplifies the signal and supplies a sinusoidal voltage to the high-frequency output of the coupling capacitor 6, which is fed through it to the phase wires of the overhead line 3.

The computing unit 4 is connected to a high-frequency output of the coupling capacitor 6 to measure the voltage across it. In relation to the current voltage value at the high-frequency output of the communication capacitor 6 to the current flowing through the high-frequency output of the communication capacitor 6, we determine the input resistance of the phase wire of the overhead line 3, which varies from the signal frequency.

The computing unit 4 through a current transformer 5 measures the effective value of the current flowing through the high-frequency output of the coupling capacitor 6.

In the proposed device, a sound frequency generator (100 Hz-100 kHz) can be used, which is lower than the frequencies of the RF communication.

When using a voltage transformer or a coupling capacitor, it is not necessary to unscrew the overhead line from the side of the switchgear, which simplifies the use of this device. In addition, it becomes possible to continuously monitor the status of the overhead line.

Thus, an open circuit is detected and the device operates at frequencies below the frequencies of the RF communication.

Claims (3)

1. The device for determining the location of damage in the power line, containing a series-connected probe pulse generator, an amplifier, an overhead phase wire connected to an amplifier output, a computing unit connected to a overhead phase wire for measuring voltage across it, characterized in that it is equipped with a current transformer installed at the output of the amplifier, and a measuring winding connected to the computing unit. 2. The device according to claim 1, characterized in that it is additionally equipped with a voltage transformer connected to the phase wire, the measuring winding is connected to the output of the amplifier. 3. The device according to claim 1, characterized in that it is additionally equipped with a coupling capacitor connected to a phase wire, a high-frequency output connected to the output of the amplifier.