RU2611554C1 - Method of monitoring technical condition of electric power facilities - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to the diagnosis of electric power facilities. Essence: everything is measured in equivalent conditions for a controlled and a one-type reference objects, the energy spectra of electromagnetic radiation of horizontal polarization of all the objects' equipment on joint action frequencies of white noise and quasi-harmonic oscillations with resonance frequencies of good-quality oscillatory circuit equipment of these facilities. It is allocated and fixed in the measured spectra of the intensity of white noises. The complete deficiency of the controlled object is determined by comparing the intensities of fixed white noises in the energy spectra of the horizontally polarized radiation for the controlled and the reference objects. The defectiveness of the object is defined as a weak, moderate, severe or dangerous, if the intensity of white noises in the energy spectra of the horizontally polarized radiation for the controlled object exceeds this figure in the reference object by an amount respectively to 15, 15 to 30, 30 to 45 and more than 45 dB . The energy spectra of electromagnetic radiation of horizontal polarization was measured by a standard industrial equipment. The measuring devices are placed in the middle of the controlled or reference object directly above or below the high-voltage input (BB) transmission line near the BB OPY. The main recommended frequency measurement range is in the low part of the scope of the white noise at the frequencies f = 3-300 MHz or alternate embodiment of frequency f = 3-3000 MHz.

EFFECT: invention provides simplification, improving the reliability and efficiency of diagnosing of electric power facilities.

3 cl, 2 dwg

Description

The invention relates to methods for diagnosing the defectiveness of electric power (EE) objects, and in the first place, large objects over the occupied area of EE, such as a power plant, distribution substation, power supply network for a particular settlement, enterprise, cosmodrome, airfield, railway junction, and other similar objects, including extended sections of high voltage (BB) power lines (power lines) and discrete EE equipment connected to these lines (voltage transformers voltage transformers, CT current transformers, AT power autotransformers, UShR controlled shunt reactors, outdoor switchgear and other switchgears), and is intended for the creation of industrial information-measuring complexes for monitoring the technical condition of such objects, providing reliable express diagnostics of their complete defectiveness.

A known method of monitoring the technical condition of EE equipment based on the use of thermal imagers to record the temperature distribution on the surfaces of individual units of equipment of a controlled object under voltage (see A. Khrennikov et al. Power plants, No. 8, 2001).

The known method relates to methods for the built-in diagnostics of the technical state of EE objects, and with it you can determine the defectiveness of individual pieces of equipment of the controlled EE object, and then, using the data obtained, establish the complete defectiveness of the controlled object.

The main disadvantages of the analogue are that it has a low diagnostic sensitivity, does not allow to detect defects associated with electric discharges in the internal parts of the equipment of a controlled EE facility and requires cumbersome processing of experimental data (a detailed analysis of thermal imaging maps of individual pieces of equipment of an EE facility), the complexity of execution which increases with the increase in the area occupied by the controlled object, and with the increase in the number of energy efficiency equipment located at this object.

Therefore, the known method is complex, does not provide the required speed, sensitivity and reliability of diagnosis, and therefore is not suitable for performing reliable express diagnostics of the complete defects of controlled EE objects, and especially large-area EE objects.

There is also a method for monitoring the technical state of EE of objects (equipment), in which the complete defectiveness of a controlled object under voltage is determined by the electromagnetic radiation (EMR) of the equipment of this object (see Glukhov O.A., Korovkin N.V., Balagula Yu .M. Methodology for estimating the parameters of partial discharges in high-voltage insulation during relative measurements of their pulsed electromagnetic fields. Proceedings of the IV international symposium on electromagnetic compatibility, St. Petersburg, 2001, prototype). This method is remote, and with its help it is possible, as in the analogue method, to first determine the defectiveness of individual pieces of equipment of a controlled energy-efficient object, and then, using the data obtained, establish the complete defectiveness of this object.

The method is based on measurements of average intensities of flows of electromagnetic pulses of arbitrary polarization emitted by individual pieces of equipment of a controlled object at frequencies of white noise in the working frequency band of the measuring equipment. Therefore, in the prototype, essentially the integrated power of the EMP of arbitrary polarization, generated by electric discharges in the external and internal parts of individual pieces of equipment of the controlled EE object, is measured.

Measurements in the prototype method are performed using a broadband receiving antenna of arbitrary polarization connected to the input of a specially manufactured recorder of average intensity of the flow of electromagnetic pulses emitted by the equipment of a controlled EE object. Recommended measurement frequencies exceed f = 150-200 MHz and lie in the high-frequency part of the white noise area.

According to the measurement results, the dependences for the average intensities of the pulse flows emitted by individual equipment samples of the controlled EE of the object on the detection threshold are used, and the diagnostic parameters for determining the defects of specific equipment samples are used: the slope of the slopes of the lines approximating the sections of these dependencies, the number of intervals required for such an approximation, and the values of the coordinates of the inflection points in the indicated dependencies. In this case, the defectiveness of individual samples of equipment of the controlled EE facility (and then the complete defectiveness of this facility) is established by the dynamics of changes in the above diagnostic parameters when performing series of periodic measurements at time intervals separated by months and years of operation of the equipment of the controlled facility.

The prototype belongs to the category of noise and quasi-noise methods and therefore has an increased, in comparison with the analogue, sensitivity and reliability of diagnosing the complete defectiveness of the controlled equipment, determined by electric discharges not only in its external, but also in its internal structural elements (which is not in the analogue).

The main disadvantages of the prototype are due to the use of non-standard, specially manufactured measuring equipment (which leads to a decrease in the reliability of diagnosing defects in individual pieces of equipment and complete defective EE of the object) and a cumbersome procedure for processing measurement results, which requires a significant investment of time, which increases with the growth of the area of the controlled EE of the object and with an increase in the number of equipment of this facility (which leads to a decrease in the efficiency of diagnosing complete defectiveness EE object). In addition, when diagnosing a complete defect in the EE of an object using the prototype method without additional measurements of the EMR energy spectra of individual equipment samples of this object, it cannot be unambiguously asserted that the average flux intensity of which pulses is recorded by measuring equipment: chaotic, generated by white noise (as the authors believe), or more intense deterministic associated with the filtering and regeneration of white noise at the resonant frequencies of high-quality vibrational circuits of the equipment of the energy efficiency of the object also emitted at the recommended frequency measurement. The latter circumstance leads to an additional decrease in the reliability of diagnosing the defects of individual units of equipment of a controlled energy efficiency facility and, accordingly, the complete failure of this facility.

From this it follows that the prototype method is quite complex, does not have the required efficiency and reliability of diagnosis, and therefore is not suitable for performing reliable express diagnostics of the complete defects of these objects and, first of all, large objects in terms of energy efficiency.

The problem to which the invention is directed is to create a method for monitoring the technical condition of EE objects suitable for reliable express diagnostics of the complete defects of controlled EE objects, especially large ones over the occupied area of EE objects).

The technical result obtained by solving the problem is expressed in the creation of a method for monitoring the technical condition of EE equipment (and, first of all, large objects by the occupied area), simple enough, with increased efficiency and increased reliability of diagnosis, and therefore suitable for performing reliable express -diagnostics of complete defects of controlled energy objects.

To solve this problem, a method for monitoring the technical condition of electric power facilities, in which the complete defectiveness of a controlled object that is energized, is determined by the electromagnetic radiation of the equipment of this object, characterized in that they measure under equivalent conditions for a controlled and standard object of the same type the energy spectra of electromagnetic radiation horizontal polarization of all the equipment of these objects at once at the frequencies of joint action of white noise and quasi-harmonic vibrations with resonant frequencies of high-quality vibrational circuits of the equipment of these objects are isolated and recorded in the measured spectra of white noise intensities, and the total defectiveness of the controlled object is determined by comparing the fixed intensities of white noises in the energy spectra of horizontal polarized radiation for the controlled and reference objects, and the defectiveness an object is defined as weak, moderate, strong or dangerous if the intensity of white noise in The spectrum of horizontal polarized radiation for a controlled object exceeds this indicator in the reference object by up to 15, 15 to 30, 30 to 45, and more than 45 dB, respectively. In addition, the energy spectra of electromagnetic radiation of horizontal polarization are measured using standard industrial equipment. In addition, the measuring equipment is placed in the middle part of the controlled or reference object, directly above or below the high-voltage input (BB) of the power transmission line next to the BB of the switchgear, and the main recommended measurement frequency range is in the low-frequency part of the white noise area at frequencies f = 3-300 MHz or in the reserve version at frequencies f = 3-3000 MHz.

In the claimed method of monitoring the technical state of the energy efficiency of the objects common with the prototype is that it "the complete defectiveness of the controlled object, which is energized, is determined by the electromagnetic radiation of the equipment of this object."

Therefore, the proposed method, as well as the prototype method, relates to remote methods of noise and quasi-noise diagnostics, and in it, as in the prototype, the complete defectiveness of a controlled EE of a live object (i.e. connected to an explosive power transmission line and under voltages of these power lines), determined by the electromagnetic radiation of the equipment of this object.

A comparative analysis of the essential features of the proposed method and prototype shows the presence of the following distinctive features:

1) “they measure under equivalent conditions for controlled and homogeneous reference objects with the energy spectra of electromagnetic radiation of horizontal polarization of all the equipment of these objects at once at the frequencies of joint action of white noise and quasi-harmonic vibrations with resonant frequencies of high-quality vibrational circuits of the equipment of these objects”;

2) “isolate and fix in the measured spectra the intensity of white noise”;

3) “the complete defectiveness of the controlled object is determined by comparing the fixed intensities of white noise in the energy spectra of horizontal polarized radiation for the controlled and reference objects”.

A sign indicating that the measurements are carried out “using standard industrial equipment, the energy spectra of the electromagnetic radiation of horizontal polarization of all the equipment of the specified objects at the frequencies of the combined action of white noise and quasi-harmonic vibrations with resonant frequencies of sound vibrational are measured under equivalent conditions for a controlled and homogeneous reference object equipment circuits of these objects ... "indicates that the claimed method uses standard industrial equipment (rather than specialized equipment containing a broadband antenna of arbitrary polarization and a specially made meter of the average intensity of the emitted pulse flux, as is the case in the prototype) and under equivalent conditions (i.e., under the same operating conditions for a controlled and similar to it reference EE objects and using uniform metric means different from those used in the prototype) measure the energy spectra of the EMP of horizontal polarization at once of all the equipment of these objects at frequencies of the combined action of white noise and quasi-harmonic vibrations with resonant frequencies of high-quality oscillating circuits of equipment of these objects, and not the average intensities of flows of noise and deterministic pulses of arbitrary polarization emitted by individual equipment units of these EE objects in the entire operating frequency band of measuring equipment, as in the method prototype.

In this case, the main recommended measurement range in the present method is located in the low-frequency part of the field of action of white noise, i.e. at frequencies of 3-300 MHz (a fallback in the high-frequency part of this region at frequencies of 0.3-3.0 GHz), and differs from that in the prototype.

Preference in the proposed method is given to measuring the energy spectra of EMP of precisely horizontal polarization (rather than the integrated power of EMP of arbitrary polarization in the operating frequency band of the measuring equipment, as in the prototype), since in EE objects with a large occupied area there is always a large amount of equipment whose voltage inputs are supplied through explosives Outdoor switchgear connected to the explosive power line. The latter ones (VV ORU and VV power transmission lines) contain in their currents information about the defectiveness of all equipment of the EE facility and are effective emitting antennas of exactly horizontal polarization at the main measurement frequencies recommended by the proposed method f = 3-300 MHz (and at the frequencies of the fallback version f = 3-3000 MHz) and when using a broadband measuring antenna of the same horizontal polarization, connected to the input of an industrial spectrum analyzer with a specified frequency range, it is possible to measure and analyze energy horizontal polarization radiation spectra created by the equipment of the entire EE of the object (controlled or reference) at once, and it is quite simple, with increased efficiency and increased reliability, in comparison with the prototype method, reliable express diagnostics of the complete defects of controlled EE objects and first of all large facilities. Moreover, when using the spare recommended frequency range of measurements in the proposed method, the accuracy is further increased, and, accordingly, the reliability of diagnosing the complete defectiveness of the controlled EE of the object is increased (this possibility is not provided for in the prototype method).

The distinguishing feature “isolate and fix in the measured spectra of white noise intensities” refers to the diagnostic parameter used in the proposed method (white noise intensities in the EMR energy spectra of horizontal polarization from controlled and similar reference objects), offers simple mathematical methods, for example, the linear approximation method ( with subsequent extrapolation of the approximation result to the entire frequency range of the spectra measurement) of the set of experimental points, numerical ohms of 10–20 or more, with the minimum local spectral densities within the range of values equal to twice the statistical measurement error, select the white noise components (the spectral densities of which are independent of analysis frequency) and recommends fixing the intensities of these components in the above spectra, i.e. to fix the intensities (spectral densities) of precisely white noise (due to which the proposed method improves the reliability of diagnosing the total defects of these objects), and not the total intensities of white noise and quasi-harmonic components with resonant frequencies of sound vibrational circuits of EE objects in the entire working band of the measuring equipment, as this is done in the prototype.

The distinguishing feature “the complete defectiveness of the controlled object is determined by comparing the fixed intensities of white noise in the energy spectra of horizontal polarized radiation for the controlled and reference objects” indicates the path to the development of criteria and the determination (using these criteria) of the complete defectiveness of the controlled EE of the object.

These criteria are formed in such a way as to distinguish between several gradations (levels) of total defects of controlled energy objects, for example gradations: weak, moderate, severe and dangerous defects. At the same time, the controlled EE object itself at the initial stage of its operation (i.e., a new EE object or an object that has fully restored its working capacity after performing preventive and repair work) and any other object of the same type with a controlled one can be used as a reference the minimum (among the examined objects) intensity of white noise in the energy spectrum of its EMP of horizontal polarization.

In the course of the experiments, we found that immediately before the failure of a controlled EE object, the white noise intensity in the energy spectrum of the horizontal polarization EMR of this object increases by 50-60 dB. Therefore, we can propose the following simple and universal criteria for determining the complete defectiveness of a controlled EE object by the intensity of white noise in its energy spectrum of horizontal polarized electromagnetic radiation.

The weak complete defectiveness of the object being monitored by the EE corresponds to the intensity of white noise in its energy spectrum of the horizontal polarization EMR that exceeds that of the reference object by up to 15 dB. (one)

The moderate total defectiveness of the object being monitored by the EE corresponds to the intensity of white noise in its energy spectrum of the horizontal polarization EMR that exceeds that of the reference object by 15 to 30 dB. (2)

The strong complete defectiveness of the object being monitored by the EE corresponds to the intensity of white noise in its energy spectrum of the EMR of horizontal polarization, which exceeds that of the reference object by 30 to 45 dB. (3)

The dangerous complete defectiveness of the object being monitored by the EE corresponds to the intensity of white noise in its energy spectrum of the horizontal polarization EMR that exceeds that of the reference object by more than 45 dB. (four)

Due to measurements of the EMR energy spectra of horizontal polarization and comparison with the standard, the criteria proposed in the claimed method (1-4) and obtained using these criteria for assessing the total defects of controlled EE objects exhibit low sensitivity to external interference, less than in the prototype method, because most of the third-party broadcast and service radio and television stations work with vertical polarized EMP, which are suppressed in the proposed method by a horizontal polarization measuring receiving antenna. The noted circumstance contributes to the proposed method an additional increase, in comparison with the prototype method, the reliability of diagnosing the complete defectiveness of a controlled EE object.

Therefore, in the inventive method of monitoring the technical condition of EE objects, all the advantages of the prototype are preserved and multiplied. Moreover, due to measurements in the inventive method using standard industrial equipment of EMR energy spectra of horizontal polarization of the entire equipment of EE objects at once (bypassing the cumbersome preliminary steps of measuring energy spectra for individual equipment units of these objects and determining the defects of these units of equipment, as is done in the prototype method ) in the specific recommended frequency range (and not the average flow intensity of noise and determinate pulses arbitrary polarization in a frequency range above uncertain values f = 150-200 MHz, in the prior art), the method is quite simple and enables reliable rapid diagnostic full defectiveness EE objects with increased speed and greater reliability than with the prior art.

From the foregoing, it follows that the proposed combination of common and distinctive essential features of the proposed method for monitoring the technical condition of EE objects (and especially large objects in terms of area) provides a solution to the problem and the achievement of the desired technical result.

It is this combination of essential features of the proposed method for monitoring the technical condition of EE objects that has provided its simplicity, made it possible to increase the efficiency and reliability of diagnosing the complete defects of monitored objects, and therefore has made the claimed method suitable for performing reliable express diagnostics of the complete defects of EE objects, and especially large ones occupied area of objects. Moreover, the diagnosis in the proposed method can be performed both on the object under the explosive power transmission line near the explosive switchgear, and from a helicopter hovering above the object at an altitude of 50-100 in close proximity to the explosive power transmission line and explosive switchgear.

Based on the foregoing, we can conclude that the set of essential features of the claimed invention has a causal relationship with the achieved technical result, i.e. thanks to this combination of essential features, the invention solved the problem.

Moreover, the claimed invention is new and has an inventive step, because it does not follow explicitly from known technical solutions and is suitable for practical use.

The practical implementation of the proposed method for monitoring the technical state of EE facilities will be demonstrated by diagnosing the complete defectiveness of one of the distribution electrical substations (PS) of the Primorsky Territory of Russia.

The structure of this substation includes: extended sections of explosive power lines with voltages of 500 kV, 220 kV, 11 kV and more than a dozen units of EE equipment, including AT, TT, VT, CSR, ORU-500, ORU-220 and others.

The essence of the invention is illustrated by drawings.

In FIG. Figure 1 shows (on a logarithmic scale on both axes) the energy spectrum of the EMP of horizontal polarization of the reference EE of the object, measured for the above substation on 06.03.2010 directly under the explosive power line with a voltage of 500 kV (next to ORU-500). The weak complete defectiveness of the reference object was established by the methods by which then, on 03.06.2010, the defectiveness of all the main pieces of equipment of this substation, which turned out to be weak, was checked.

In FIG. Figure 2 presents (on a logarithmic scale on both axes) the energy spectrum of horizontal polarized EMR, measured on July 23, 2014 for the same EE of an object (PS), after 4 years of its continuous operation.

Both spectra were recorded in nominal PS operating modes in the frequency range f = 3-300 MHz using unified metric means: a horizontal polarization measuring antenna and a NS-30A computer-controlled industrial spectrum analyzer.

In FIG. 1, 2 the following notation is used: S _G1 , S _G2 - energy spectra of horizontal polarized radiation for the reference (first) and controlled (second) objects in dB (W) / Hz; f is the analysis frequency in Hz; (S _G1 ) _W , (S _G2 ) _W - intensities of white noise components in the emission spectra of the reference and controlled objects in dB (W) / Hz (dashed lines).

In the EMP spectrum of the horizontal polarization of the reference EE object (Fig. 1), intense peaks of quasi-harmonic components are visible at the resonant frequencies of high-quality vibrational circuits of the equipment of this object. Approximation by a straight dashed line parallel to the frequency axis f of the set of experimental points A, B, C, ..., Z corresponding to the minimum local radiation intensities in the range of spectral densities equal to twice the statistical measurement error 2β (in our case 2β = 2 dB), made it possible to isolate the white noise component in the radiation spectrum of the reference EE of the object and determine its intensity (spectral density), which was (S _G1 ) _W = -177 dB (W) / Hz.

In the EMP spectrum of horizontal polarization of the controlled EE object (Fig. 2), peaks of quasi-harmonic components at the resonant frequencies of high-quality oscillatory circuits of the equipment of this object are increased in magnitude. Approximation by a straight dashed line parallel to the frequency axis f (with subsequent extrapolation of the approximation result to the entire frequency range of measurements), a set of experimental points A, B, C, ..., Z corresponding to the minimum local radiation intensities in the range of spectral densities equal to twice the statistical error measurements 2β = 2 dB, made it possible to isolate the white noise component in the radiation spectrum of the object being monitored by EE and determine its intensity (spectral density), which turned out to be equal to _{(S G2) W = -156 dB} (W) / Hz, i.e. 21 dB higher than that of the reference EE object.

At the same time, it is guaranteed that the obtained 21 dB readout corresponds to the difference in intensities (spectral densities) of precisely white noises, and not peaks of quasi-harmonic vibrations in the EMR of the considered EE objects. In the prototype method there is no such guarantee.

Now, using the criteria (1-4), it is possible to evaluate the proposed method quite simply and with increased reliability (in comparison with the prototype and analogue) the complete defectiveness of the object being monitored by EE as moderate, which was also confirmed by known methods described in RU No. 2311652, and in the “Guidelines for the diagnosis of developing defects in transformer equipment based on the results of chromatographic analysis of gases dissolved in oil. RD 153-34.0-46.302-00, RAO "UES of Russia", Department of Scientific and Technical Policy and Development of the Russian Federation, M., 2001, i.e. It was found that weak and moderate defectiveness on 07/23/2014 in the controlled object has all the main EE equipment.

It should be noted that it is enough for a qualified specialist to take a quick look at the spectra shown in FIG. 1, 2, so that without special processing of experimental results, up to a statistical measurement error β, determine the difference in white noise intensities in the emission spectra of the reference and controlled objects and, applying criteria (1-4), quickly certify the complete defectiveness of the controlled EE of the object.

Therefore, the inventive method for monitoring the technical state of EE objects not only provides increased reliability of diagnosing the complete defectiveness of the controlled object, but is also quite simple, in comparison with the prototype, as in terms of performing measurements of the energy spectra of EMR of all equipment of the EE object at once (using standard industrial equipment ), and in terms of processing and interpretation of the measurement results. This allows the specialist, using the proposed method, with increased speed and reliability to carry out reliable rapid diagnostics of the complete defectiveness of EE objects (and especially large ones in the occupied area of EE objects) directly at the measurement site, without any additional time spent on processing the obtained experimental data, which is not in the prototype and in the analogue.

The noted advantages of the proposed method, its sufficient simplicity, increased reliability and increased efficiency of forming a conclusion are especially important when performing express diagnostics of EE of objects with strong and dangerous defects, when it is urgent to solve the issue of stress relief from an emergency object.

The given example of the implementation of the proposed method for monitoring the technical condition of EE objects convincingly demonstrates the advantages of this method in comparison with the prototype and analogue.

The practical application of the proposed method for monitoring the technical condition of EE facilities for attesting the defectiveness of a particular industrial facility (one of the distribution substations in Russia) demonstrated the simplicity of this method, increased reliability and increased efficiency in assessing the complete defectiveness of a controlled EE facility and confirmed the feasibility, using the proposed method, of reliable rapid diagnostics of energy efficiency of objects and, first of all, large objects on the occupied area, including they include the extended parts of the explosive power lines and the numerous equipment connected to these explosive power lines.

From the foregoing, it follows that the claimed method of monitoring the technical condition of the energy efficiency of objects has, in comparison with the prototype and analogue, sufficient novelty, simplicity, increased reliability and increased efficiency in determining the defects of controlled objects and allows the successful rapid diagnosis of complete defects of these objects in the first queue of large energy-efficient objects.

Claims (3)

1. A method for monitoring the technical condition of electric power facilities, in which the complete defectiveness of a controlled object that is energized is determined by the electromagnetic radiation of the equipment of this object, characterized in that the energy spectra of horizontal polarized electromagnetic radiation are measured under equivalent conditions for a controlled and homogeneous reference object immediately all the equipment of these objects at frequencies of joint action of white noise and quasi-harmonic oscillations with resonant frequencies of sound-oscillating circuits of the equipment of these objects are isolated and recorded in the measured spectra of white noise intensities, and the complete defectiveness of the controlled object is determined by comparing the fixed white noise intensities in the energy spectra of horizontal polarized radiation for the controlled and reference objects, and the defectiveness of the object is determined as weak, moderate, strong or dangerous if the intensity of white noise in the energy spectra of mountain emissions the polarization polarization for the controlled object exceeds this indicator in the reference object by up to 15, 15 to 30, 30 to 45, and more than 45 dB, respectively. 2. The method according to p. 1, characterized in that the energy spectra of electromagnetic radiation of horizontal polarization are measured using standard industrial equipment. 3. The method according to p. 1, characterized in that the measuring equipment is placed in the middle of the controlled or reference object, directly above or below the high voltage input (BB) of the power transmission line next to the BB of the open switchgear (outdoor switchgear), and the main recommended frequency measurement range is in the low-frequency part of the range of white noise at frequencies f = 3-300 MHz or in the backup version at frequencies f = 3-3000 MHz.

Images