RU2103699C1 - Device for measurement of grounding parameters - Google Patents

Abstract

FIELD: electric power engineering. SUBSTANCE: device has signal former the frequency of which is lower than frequency of first harmonic of supply mains. Device has also frequency-selective measuring circuit with synchronous detector and analog-to-digital converter connected between device potential input and digital indicator. Signal former output is connected to current output of device through current pickup. Reference input of analog-to-digital converter is connected to current pickup output through reference-voltage forming unit. Control input of synchronous detector is connected to current pickup output via phase-shifting circuit. Signal former is provided with synchronous input which is connected to external lead of device, for example to potential input lead. In this case, interference across external lead of device caused by extraneous currents of mains frequency synchronizes signal former. EFFECT: extended dynamic range of output current. 3 cl, 2 dwg

Description

 The invention relates to the field of electrical measurements in the electric power industry and is intended to indirectly determine the touch voltage (step) that occurs in emergency modes of electrical installations by measuring the contact resistance.

 The prior art.

 Devices for measuring the grounding parameters, as a rule, are performed according to the scheme of a four-output alternating current ohmmeter with a current output and a potential input.

 It is known, for example, a device for measuring touch voltage and ground resistance [1], in which the power source is connected to the current output of the device through a switching unit. A block measuring current and voltage is connected to the potential input. This device allows measurements under the influence of interference from extraneous currents flowing in the ground near existing electrical equipment. However, for detuning from such interference in the device [1], relatively large output currents and voltages are required, which increases the power consumption, the mass, the overall dimensions of the device, and worsens the electrical safety conditions when performing measurements.

 Known devices for measuring grounding parameters [2, 3], containing a signal conditioner, the output of which is connected to the terminals of the current output of the device, and a frequency-selective measuring circuit with a synchronous detector, connected between the terminals of the potential input of the device and the indicator input. In devices [2, 3], measurements are performed at a frequency different from the industrial frequency of 50 Hz, and the noise is suppressed due to the frequency selectivity of the measuring circuit with a synchronous detector. These devices are more noise-resistant and require lower output currents, however, their common drawback is the need for strict stabilization of the output current of the device to obtain reliable values of the measured parameters. In this case, the value of the stabilized output current should be sufficient to neglect the influence of extraneous currents in the ground on the measurement results.

 The closest in technical essence to the claimed device - its prototype is a device for measuring grounding parameters [4], containing a signal shaper with a frequency lower than the frequency of the main harmonic of the network, the output of which through a current sensor is connected to the terminals of the current output of the device, a frequency-selective measuring circuit with a synchronous detector, connected between the potential input of the device and the input of the indicator, and the control circuit of the synchronous detector. The measuring circuit of the device [4] is equipped with another input designed to be connected to a remote additional electrode, clogged outside the spreading zone of the output current of the device, but in the area of the extraneous current flow of interference acting on the potential electrode. In addition, a dividing unit is included in the measuring circuit, normalizing the indicator readings when the output current changes.

 This technical solution contributes to the expansion of the dynamic range of the output current of the device, however, it does not achieve this result when performing measurements near operating electrical equipment, where extraneous currents in the ground, as a rule, significantly exceed the output current of the device in the lower part of the extended dynamic range. This is due to the fact that compensation of interference from an extraneous current in the measuring circuit of the device [4] requires identical amplitude and phase interference voltages at the potential and remote electrodes, which is rarely performed in practice. As a result, in the prototype device, the dynamic range of the output current is limited from below due to the need to provide the signal-to-noise ratio required for measurement.

 The objective of the present invention is to provide a device characterized by an extended dynamic range of permissible output currents of the device under conditions of significant interference from extraneous currents in the ground.

 Disclosure of the invention.

 The subject of the invention is a device for measuring grounding parameters, comprising a signal shaper with a frequency lower than the frequency of the main harmonic of the network, the output of which through a current sensor is connected to the terminals of the current output of the device, a frequency-selective measuring circuit with a synchronous detector, connected between the potential input of the device and the indicator input , and a control circuit of a synchronous detector, characterized, according to the invention, in that the signal conditioner with a frequency lower than the frequency of the main harmony and the network is equipped with a clock input that is connected to the external output of the device, the frequency-selective measuring circuit contains an analog-to-digital converter included at its output, and a reference voltage generating unit is introduced, while the output of the current sensor is connected to the input of the control circuit of the synchronous detector and through the reference voltage generating unit is connected to the reference input of the analog-to-digital converter.

 The specified set of features allows you to provide a temporary reference control voltage of the synchronous detector to the main harmonic of the interference voltage in combination with automatic normalization of the measurement results when the output current changes and, thereby, expand the dynamic range of the output current of the device under the action of significant interference from extraneous currents in the ground near the working electrical equipment.

 The invention has a development consisting in the fact that the output of the potential input of the device is used as the external output to which the sync input of the signal conditioner is connected with a frequency lower than the frequency of the main harmonic of the network.

 This allows you to provide a solution to the problem when powering the device from an autonomous source.

Another development of the proposed solution relates to the internal execution of the control circuit of a synchronous detector, namely, its implementation in the form of a phase-shifting circuit with the ability to switch the phase shift by 90 ^o .

 This allows you to separately measure the active and reactive components of the integrated contact resistance.

 In FIG. 1 shows a block diagram of a device, taking into account its development in p.p. 2 and 3 of the claims and the most preferred embodiment of a frequency selective measuring circuit; in FIG. 2 is a timing diagram of signals explaining the operation of the device.

 Description of the invention.

 The device (Fig. 1) contains a signal shaper 1 with a frequency lower than the main harmonic frequency of the network, the output 2 of which is connected through the current sensor 3 to the terminals 4, 5 of the two-wire current output of the device, a frequency-selective measuring circuit 6 with a synchronous detector 7, connected between the potential input 8 of the device and the input of the indicator 9, and the control circuit 10 of the synchronous detector 7. The driver 1 is equipped with a synchro input 11, which is connected to the external output 12 of the device. The external terminal 12 may in particular be one of the terminals of the two-wire potential input 8, as shown in FIG. one.

 The measuring circuit 6 contains an analog-to-digital Converter (ADC) 13, included at its output.

 A block 14 for generating a reference voltage is introduced into the device, while the output 15 of the current sensor 3 is connected to the input of the circuit 10 and, through block 14, is connected to the reference input 16 of the ADC 13.

The control circuit 10 of the synchronous detector 7 can be made in the form of a phase-shifting circuit with the ability to switch the phase shift by 90 ^o .

 The circuit 6 of the device may include a selective amplifier 17 and a low-pass filter 18, as shown in FIG. one.

In the timing diagram of FIG. 2 are given:
u ₁ - voltage at the output 2 of the shaper 1;
i ₁ - current output 2 of the driver 1, flowing through the sensor 3 current and conclusions 4 and 5;
u ₂ - the main harmonic of the touch voltage at the measuring input 19 of the detector 7;
u 'and u''are the voltages at the control input 20 of the synchronous detector 7 with phase shifts in circuit 10, respectively, 0 ^o and 90 ^o ;
u _R and u _L - voltage at the output 21 of the synchronous detector 7 with phase shifts in circuit 10, respectively 0 ^o and 90 ^o ; the dashed line shows the constant components of these voltages;
u _C is the mains voltage.

 The device operates as follows.

Shaper 1 at the output 2 generates a voltage u ₁ , which creates a current i ₁ in the external circuit. The magnitude of this current depends on the resistance between the current electrodes connected to pins 4 and 5.

The voltage at the potential input 8, arising from the flow of current i ₁ through the complex touch resistance, is supplied to a selective amplifier 17, which selects and amplifies the main harmonic u ₂ of the touch voltage and supplies it to the input 19 of the synchronous detector 7.

When conducting measurements near a working electrical installation at potential input 8, in addition to the useful signal from current i _1, there is interference voltage from extraneous currents flowing in the ground due to leaks through the insulation of electrical equipment or due to corona, often significantly exceeding the measured potential difference. Extraneous currents, the main harmonic of which is equal to the network frequency of the electrical installation, create additional voltages between the external terminals of the device and the common point of its circuit (usually this is pin 4). Such voltage is supplied to the sync input 11 of the driver 1, for example, as shown in FIG. 1, output 12, provides a temporary reference voltage u ₂ to the voltage u _C , which significantly increases the degree of suppression of interference in the measuring circuit of the device.

The frequency of the signal u ₁ is an integer number of times less than the frequency of the fundamental harmonic of the voltage supplied to the synchro input 11 of the shaper 1.

The control input 20 of the synchronous detector 7 through the circuit 10 with a switched phase shift receives a signal from the current sensor 3. Depending on the phase shift in the circuit 10 set by the operator, either the voltage u ', which coincides in phase with the current i ₁ flowing through the contact resistance, or the voltage u''shifted by 90 ^° relative to the current phase, is input to the input 20 of the synchronous detector 7 u ₁ .

At the output 21 of the detector 7, when the indicated phases coincide, a voltage u _R corresponding to the active component of the contact resistance is formed, and with a phase shift of 90 ^o , a voltage u _L corresponding to the reactive component of the contact resistance is formed.

The filter 18 selects a constant component of the signal at the output 21 of the detector 7, which is proportional to the measured resistance and is fed to the measurement input 22 of the ADC 13. The constant voltage components u _R and u _L are shown in FIG. 2 dotted lines.

The ADC 13 converts the voltage at input 22 into a digital code, the value of which depends on the reference voltage at input 16. The reference voltage allocated by unit 14 from the voltage at output 15 is proportional to the current of sensor 3, which ensures that the readings of indicator 9 are independent of the current value i ₁ .

 It should be noted that in some cases, the sync input 11 can be connected differently than in FIG. 1. For example, it is possible to connect the synchro input 11 with an external terminal (terminal), designed to be connected to a separate movable electrode installed in the area of interference of industrial frequency. When powered from the mains, the synchro input 11 can be connected to an external output of the device’s mains supply, for example, via a transformer or a voltage divider.

 However, shown in FIG. 1, connecting the sync input 11 to the output of the potential input 8 is most preferable, since it does not require the introduction of additional external outputs (terminals) and allows you to solve the problem when powered by an autonomous source.

 Thus, the proposed technical solution provides a temporary reference of the control voltage of the synchronous detector to the main harmonic of the interference voltage, which, in combination with automatic normalization of the measurement results when the output current changes, expands the dynamic range of the output current of the device under conditions of significant interference from extraneous currents in the ground near the working electrical equipment .

 Industrial applicability.

 The structure of FIG. 1 prototype was tested in an open switchgear of a working substation with a voltage of 220 kV.

 Grounding parameters were measured when the current electrode was driven into various points of the ground. The results obtained were compared with the results of measurements performed with the de-energized electrical equipment of the substation.

 When the resistance of the current electrode circuit is less than 3000 ohms, the measurement error did not exceed 5%, and with an increase in the resistance of the same circuit to 7000 ohms, the error was 10%.

 Sources of information.

 1. Auth. St. THE USSR. 1026064, IPC G 01 R 27/20, 1981.

 2. Auth. St. THE USSR. 826844, IPC G 01 R 27/20, 1978.

 3. Auth. St. THE USSR. 1023253, IPC G 01 R 27/20, 1981.

 4. Auth. St. THE USSR. 828119, IPC G 01 R 27/20, 1979.

Claims (3)

 1. A device for measuring grounding parameters, comprising a signal shaper with a frequency lower than the frequency of the main harmonic of the network, the output of which through a current sensor is connected to the terminals of the current output of the device, a frequency-selective measuring circuit with a synchronous detector, connected between the potential input of the device and the indicator input, and a control circuit of a synchronous detector, characterized in that the driver of the signal with a frequency lower than the frequency of the main harmonic of the network is equipped with a sync input that is connected to the outside to the device’s output, the frequency-selective measuring circuit contains an analog-to-digital converter connected at its output, and a reference voltage generating unit is introduced, while the output of the current sensor is connected to the input of the control circuit of the synchronous detector and is connected to the analog reference input via the reference voltage generating unit -digital converter.  2. The device according to claim 1, characterized in that the output of the potential input of the device is used as the external output to which the sync input of the signal conditioner is connected with a frequency lower than the frequency of the main harmonic of the network. 3. The device according to claim 1, characterized in that the control circuit of the synchronous detector is made in the form of a phase-shifting circuit with the ability to switch the phase shift by 90 ^o .

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