CN112230100A - Slow-development permanent fault early warning method and system - Google Patents

Abstract

The invention discloses a slowly developing permanent fault early warning method and a system, comprising the following steps: acquiring a recording waveform of each instantaneous fault before a permanent fault occurs on a line; judging a fault section through a recording waveform, and extracting key characteristic quantity; calculating an insulation degradation value during each transient fault according to the key characteristic quantity; accumulating the insulation degradation values obtained for multiple times in the same fault section to obtain an accumulated insulation degradation value; and when the accumulated insulation degradation value exceeds an insulation degradation threshold value, giving an early warning. Acquiring each instantaneous fault recording waveform before a permanent fault occurs, extracting fault key characteristic quantity, judging the insulation degradation degree of the circuit according to the extracted key characteristic quantity, and then sending out early warning according to the insulation degradation degree.

Description

Slow-development permanent fault early warning method and system

Technical Field

The disclosure relates to a slowly developing permanent fault early warning method and system.

Background

The statements in this section merely provide background information related to the present disclosure and may not necessarily constitute prior art.

Distribution lines are directly connected with users, the aspects of life and production are directly influenced, the distribution network has an extremely important role in an electric power system, the distribution network has a large coverage area due to the responsibility of distributing electric energy, has the characteristics of multiple feeders, multiple branches, changeable topology, multiple points, wide range and the like, is relatively severe in operating environment and very easy to break down, and statistical data shows that most line faults belong to instantaneous faults.

For a distribution line, when a single-phase instantaneous earth fault occurs at the same position for many times, each fault releases energy at the earth point, and the line insulation at the earth point is damaged. Although the fault is temporary and the fault duration is mostly from several milliseconds to several minutes, the insulation of the line is degraded to different degrees after each fault occurs, so that the insulation degradation of the line reaches the limit due to the accumulation of multiple faults, and finally permanent faults are formed by concentrated explosion after a certain grounding.

How to early warn about a slowly developing permanent fault so as to avoid the permanent fault is extremely important.

Disclosure of Invention

In order to solve the above problems, the present disclosure provides a slowly developing permanent fault early warning method and system, which acquire each instantaneous fault recording waveform before a permanent fault occurs, extract fault key feature quantities, determine an insulation degradation degree of a line according to the extracted key feature quantities, and then send out an early warning according to the insulation degradation degree.

The first purpose of the present disclosure is to provide a slow-developing permanent fault early warning method, which includes:

acquiring a recording waveform of each instantaneous fault before a permanent fault occurs on a line;

judging a fault section through a recording waveform, and extracting key characteristic quantity;

calculating an insulation degradation value during each transient fault according to the key characteristic quantity;

accumulating the insulation degradation values obtained for multiple times in the same fault section to obtain an accumulated insulation degradation value;

and when the accumulated insulation degradation value exceeds an insulation degradation threshold value, giving an early warning.

Further, the key characteristic quantities comprise the number of times of occurrence of transient faults in a period of time, the interval between two transient faults, the amplitude of the transient zero-mode current, the fault duration and the low-frequency-band energy factor of the zero-sequence current.

Furthermore, the occurrence frequency of transient faults in a period of time is positively correlated with the insulation degradation degree; the interval between two transient faults is in negative correlation with the insulation degradation degree; the transient zero-mode current amplitude is in positive correlation with the insulation degradation degree; the fault duration is positively correlated with the degree of insulation degradation; the zero sequence current low-frequency band energy factor is in negative correlation with the insulation degradation degree.

Furthermore, the occurrence frequency of transient faults, the interval between two transient faults, the transient zero-mode current amplitude and the fault duration in a period of time are directly obtained from the obtained recording waveform.

Further, performing frequency band decomposition on the obtained wave recording waveform to obtain energy of each sub-frequency band, and obtaining a zero-sequence current low-frequency band energy factor according to a ratio of the energy of the first sub-frequency band to the sum of the energy of each sub-frequency band.

Further, when calculating the insulation degradation value of each transient fault, the correlation between the key characteristic quantity and the insulation degradation degree is considered.

Further, a larger insulation degradation value indicates a larger degree of insulation degradation.

Further, the insulation degradation threshold is determined according to actual operation experience of a specific power distribution network.

The second purpose of the disclosure is to provide a slowly developing permanent fault early warning system, which includes a detection module, a controller and an alarm model, wherein a wave recording waveform of a transient fault is acquired through the detection module, the controller extracts a key characteristic quantity of the wave recording waveform after receiving the wave recording waveform acquired by the detection module, calculates an insulation degradation value during each transient fault according to the key characteristic quantity, accumulates insulation degradation values acquired for multiple times, acquires an accumulated insulation degradation value, and sends alarm information to the alarm module to give an alarm when the accumulated insulation degradation value exceeds an insulation degradation threshold value.

Further, the controller extracts key characteristic quantities from the recording waveform, including the number of times of transient faults occurring in a period of time, the interval between two transient faults, the transient zero-mode current amplitude, the fault duration and the zero-sequence current low-frequency band energy factor.

Compared with the prior art, the beneficial effect of this disclosure is:

1. the method and the device utilize each instantaneous fault recording waveform before the permanent fault occurs to obtain the key characteristic quantity of the fault, calculate the accumulated insulation degradation value of the line through the extracted key characteristic quantity, judge the insulation degradation degree according to the accumulated insulation degradation value, and send out early warning, thereby realizing the early warning of the slowly-developing permanent fault.

2. According to the method, only the transient fault recording waveform is obtained, early warning of the slowly-developing permanent fault can be completed, other fault characteristics do not need to be additionally detected, and an additional other fault characteristic detection and processing device does not need to be installed in a large quantity, so that the operation cost is reduced, and the method is more suitable for the requirements of practical application.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the application and, together with the description, serve to explain the application and are not intended to limit the application in a limiting sense.

Fig. 1 is a fault early warning process of a slowly evolving permanent fault early warning method of the present disclosure;

FIG. 2 is a graph illustrating cumulative insulation degradation value variation according to the present disclosure;

FIG. 3(a) is a spectrum energy distribution diagram of a slow-developing permanent fault transient fault 1 in example 1;

FIG. 3(b) is a spectrum energy distribution diagram of a slow-developing permanent fault transient fault 2 in example 1;

FIG. 3(c) is a spectrum energy distribution diagram of a slow developing permanent fault transient fault 3 in example 1;

FIG. 4 is a single phase ground fault component mode network diagram;

FIG. 5 is a transient single-phase earth fault equivalent circuit;

fig. 6 is a graph showing the variation of the line parameters at different times of insulation degradation.

The specific implementation mode is as follows:

the present disclosure is further described with reference to the following drawings and examples.

It should be noted that the following detailed description is exemplary and is intended to provide further explanation of the disclosure. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular forms "a", "an", and/or "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of the features, steps, operations, devices, components, and/or combinations thereof.

Example 1

For an overhead line, a large number of devices are arranged on the overhead line, instantaneous ground faults occur with a high probability, for example, lightning strikes, flashover of insulating parts, instantaneous discharge, short-time contact of foreign matters such as branches and the like can cause the instantaneous ground faults of a distribution line, according to actual fault statistics, in a power distribution network with a certain overhead line as a main part, 7 instantaneous faults with different degrees occur before the faults in 20 times of permanent ground faults, wherein 2 instantaneous grounds with 15 times and 16 times respectively occur in three days before the permanent faults, 1 instantaneous ground occurs with 7 times in one hour before the permanent faults, like a certain transformer substation, an instantaneous ground phenomenon occurs in 72 hours before the 6 permanent ground faults, and the maximum 16 instantaneous faults occur. For a cable line, an insulating layer of a modern cable is mainly crosslinked polyethylene, the insulating layer is generally considered to be high in insulating level and irreversible in insulation breakdown, once the insulating layer is broken down, the insulating layer cannot be recovered, in the practical statistics of cable faults, a considerable part of transient faults such as faults of a cable middle joint and a terminal and transient breakdown phenomena of a cable body are also found, and in a certain cable fault case, before a permanent ground fault which lasts for 100 minutes in the interior of the cable occurs, 8 transient ground faults are detected.

It can be seen that for a distribution line, when a single-phase instantaneous ground fault occurs at the same location multiple times, each fault will discharge energy at the ground point, destroying the line insulation at the ground point. Although such a fault is temporary, the fault duration is mostly from several milliseconds to several minutes, and mostly less than 1s, the insulation of the line is degraded to different degrees after each fault occurs, so that the insulation degradation of the line is limited by the accumulation of multiple times, and finally permanent faults are formed by concentrated explosion after a certain grounding, and the fault mode can be summarized as a slowly-developing permanent grounding fault, and the fault mode also conforms to many fault scenarios in practice.

With the development of a power grid synchronous measurement system and a dispatching automation system based on modern information technology, high-precision synchronous measurement devices such as a fault recording device and a distribution network side PMU further cover all important nodes of a power distribution network, more and more accurate information with unified synchronous time scales can be acquired by a dispatching center, and the actual change waveforms of all electrical quantities of early insulation discharge can be recorded in a time sequence form, wherein rich information reflecting the running state of the system is contained.

Therefore, the method is extremely important for analyzing the transient fault recording data of each time before the permanent fault occurs, finding out the early-stage fault characteristics, obtaining the fault characteristics-space-time distribution response characteristics, further analyzing and judging the insulation level of the circuit, giving out alarm signals timely, and providing an early warning method for the slowly-developing permanent grounding fault so as to avoid the permanent fault.

The overall development law of the permanent fault is analyzed, so that the formation of the permanent fault is a slowly-developing process, before the permanent fault occurs, transient fault grounding often occurs, and at the moment, the element has a physical evolution process of intermittent discharge-breakdown. The overall development law of the permanent faults of the power distribution line is obtained by analyzing the insulation aging and fault formation of main equipment such as cables, overhead lines, insulators and the like.

Under the long-term action of operating voltage, thermal stress, external mechanical force, moisture and other environmental conditions, the insulation of the power distribution network power equipment presents a slow degradation process. For solid insulation such as inside cables and insulators, the insulation generally cannot be broken down under the operation voltage, and it is considered that the insulation may be broken down under the action of transient overvoltage, but the transient overvoltage is not long in duration and disappears after a few seconds, and then the power grid returns to normal operation. For the external insulation, oil insulation and gas insulation of power equipment, the medium-low voltage distribution network is a low-current grounding system, the fault current is small, the arc suppression coil can suppress instantaneous arcs, even if instantaneous breakdown possibly occurs under the operating voltage, the arcs can be extinguished when the fault current crosses zero at a high frequency, and then considering that impurities and water at fault points are heated by the arcs to be burnt and dried, the arcs can be naturally extinguished and can not be reignited. In the initial stage of degradation, the single-phase earth fault has obvious arc grounding characteristics, when overvoltage and various severe operating conditions occur again, the insulation weak point can be continuously broken down and further damages the insulation, unstable arc grounding also gradually develops towards metallic grounding, and finally permanent single-phase grounding occurs. In the process, the instantaneous insulation breakdown times are in an ascending state on the whole, and the time interval between two instantaneous faults is also in a shortening trend.

In the related work of the rule research on the change of the insulation resistance and the distributed capacitance caused by the electrical branch formed by the insulation deterioration, it is also found that the distributed capacitance fluctuates and increases in the early period of the deterioration, the equivalent resistance gradually decreases in the middle and later periods of the deterioration, the decrease of the resistance and the increase of the capacitance are consistent with the degree of the electrical branch formed by the insulation deterioration, and the relative dielectric constant and the insulation resistance of the insulation both show nonlinear changes, as shown in fig. 6. It can be seen that in the process of degradation of line insulation, there are generally an increase in equivalent distributed capacitance and a decrease in insulation resistance, i.e., the transition resistance tends to decrease in the transient fault development stage of a slowly-developing permanent ground fault.

Other various faults in the power distribution network are mostly developed by single-phase earth faults, after the single-phase earth faults occur, firstly, non-fault phase voltage is increased to line voltage, the single-phase faults are likely to be developed into two-phase or even three-phase faults at insulation weak points, particularly, the intermittent arc earthing enables the non-fault phases to generate arc earthing overvoltage which is up to 3.5p.u. to cause tripping, and secondly, for switch equipment such as circuit breakers and the like, the two-phase or three-phase short circuit is caused because the earthing arc is in contact with the non-fault, and the line tripping is caused to enlarge the fault range.

The analysis of the transient grounding fault principle shows that most of the operation modes of the power distribution network in China are that a neutral point is grounded through an arc suppression coil, when the transient single-phase earth fault occurs, the transition process of the system can be equivalent by adding a zero-sequence voltage source at the fault point, the actual data shows the damping rate of the line network in the resonance earth distribution network, namely, the ratio of the active current of the fault grounding point to the capacitive current is very small, and neglecting the active current of the grounding point will not affect the analysis result, so as to be used as the simplified condition for the next analysis, the equivalent circuit of the instantaneous single-phase grounding fault obtained on the basis of the single-phase grounding fault component mode network diagram of figure 4 is shown in figure 5, where L is the sum of the two-wire mode loop inductances, which is approximately equal to twice the line positive sequence inductance value, and R is the sum of the two-wire mode loop resistances, which is approximately twice the line positive sequence resistance value, R._trRepresenting zero sequence equivalent resistance, equivalent transition resistance in the arc path formed by the fault ground points, C₀Is zero mode capacitance, 3L_LIndicating arc-suppression coil inductance value, u_kIndicating an additional zero sequence supply voltage at the fault point, the closing of switch S corresponds to an instantaneous earth fault occurrence. According to the dynamic circuit analysis theory, the capacitance and the inductive current of the equivalent circuit are deduced by means of Laplace transformation and inverse transformation, and the equations (1) and (2) are shown.

In the formula I_CmAmplitude of capacitive current flowing through a single-phase earth fault, I_Cm＝U_mωC₀； ω_f-transient current free oscillation angular frequency; delta-transient capacitance current decay factor; omega-supply voltage angular frequency; i is_Lm-the magnitude of the inductor current in the loop;

-a fault phase voltage initial phase angle; tau is_L-an inductive loop time constant.

Wherein i_CFor the capacitance loop current, the first term in the formula (1) is a transient capacitance current component, has a high-frequency free oscillation property, is generated due to the fact that the loop contains inductance and capacitance, and is a resistor at the same time in the loop, the first term is gradually attenuated, and finally only a steady-state capacitance current component is in the loop, namely the second term in the formula (1). i.e. i_LSince the loop does not have a capacitor and only includes an inductor and a resistor, the transient inductor current in the first term in equation (2) is a decaying dc component, and the steady inductor current component in the second term.

The two components are superposed to obtain the total current of the grounding point fault, as shown in formula (3):

the first term in the formula (3) is a steady-state component of the total current, and the first term is observed to show that the steady-state current is the difference between the steady-state components of the capacitance and the inductance current, the angular frequencies of the capacitance and the inductance current are the same and are power supply voltage angular frequencies, so the steady-state component of the total current is single in component, the property of the steady-state component is related to the compensation degree of the arc suppression coil, and when the compensation degree is more than 1, a small inductive fundamental current can flow through the head end and the grounding point of the fault line; when the compensation degree is less than 1, the fault line and the grounding point flow smaller capacitive fundamental current; when the compensation degree is equal to 1, the fundamental wave current of the fault line and the grounding point is zero. The compensation effect of the crowbar coil therefore makes the steady-state component very weak, from which no further information about the momentary fault can be derived.

The second term is total current transient component, which is formed by superposing transient components of capacitance current and inductance current, the two components have different frequencies and even have larger difference, so that the two components can not be mutually cancelled but are more likely to become larger, the transient property of zero mode current, the transition impedance of a grounding point and the line parameters are mutually influenced and closely linked, although the insulation state of the distribution line cannot be directly evaluated according to the relationship, the relationship can find that the transient property of the zero mode current after the transient fault is extracted to be associated with the insulation state of the line, and the transient zero mode current is selected as a characteristic quantity extraction source for researching the insulation state of the distribution line.

Then, the transient zero-mode current is specifically analyzed, and the expression of the transient zero-mode current is

1) Initial phase angle of fault

In most cases, a transient ground fault caused by insulation breakdown at a certain position of a line in a power distribution network often occurs at the moment when a phase voltage is close to a maximum value, that is, at the moment when a fault initial phase angle phi is pi/2, a transient zero-mode current component can be expressed as follows:

that is, when a transient earth fault occurs, the transient zero-mode current component does not contain an inductive component, but only a capacitive component of oscillation attenuation.

2) Transition resistance and transient current oscillation frequency

Transient current free oscillation angular frequency omega_fThe method is determined by the oscillation frequency of the capacitive component, and after the parameters of the actual power distribution network are considered, the calculation formula is as follows:

distribution line parameter R, L, C for a resonant grounded distribution network₀The transient current free oscillation angular frequency is mainly determined by the transitional impedance, and the change of the transitional resistance causes the change of the transient current oscillation frequency.Considering the actual parameters of power distribution, the increase of the transition resistance can shift the spectral energy distribution of the fault signal to the low frequency band direction, i.e. the transition resistance becomes large, and the content of the high frequency band of the transient zero-mode current becomes small.

3) Transition resistance and transient zero-mode current amplitude

When single phase ground fault occurs in actual power distribution network, fault transient state zero mode current oscillation frequency omega of overhead line_fIn the range of 300 Hz-1500 Hz, the distributed capacitance of the cable line is larger than that of the overhead line because the inductance of the cable line is far smaller than that of the overhead line, and the oscillation frequency omega of the fault transient zero-mode current_fThe range is 1500 Hz-3000 Hz, so the fault transient zero-mode current oscillation frequency omega_fIs much larger than the power frequency omega. The amplitude of the fault transient zero-mode current mainly consists of omega_fThe ratio of/ω is determined and the amplitude is proportional to the oscillation frequency, the oscillation frequency ω_fThe transient zero-mode current is related to the transition resistance, so that the amplitude of the transient zero-mode current is changed while the oscillation characteristic of the transition resistance is changed, and the larger the transition resistance is, the smaller the amplitude of the transient zero-mode current is.

Based on the analysis of the permanent earth fault rule and the transient earth fault principle, the characteristics of the slowly-developing permanent earth fault are summarized:

1) transient earth faults are typically single-phase earth faults

In an actual power distribution network, the insulation degradation degree of a three-phase line is not completely consistent, so that transient faults always occur at the weakest point of insulation to form single-phase grounding, and therefore the transient faults are generally single-phase grounding faults.

2) When the permanent faults are close to occurring, the frequency and the duration time of the transient faults are in an ascending trend

When the deterioration of the insulation of the line is aggravated, the insulation strength becomes less easily restored, the duration of arc burning becomes longer in the event of a transient fault, and the line becomes more likely to establish an arc, which in turn further aggravates the insulation deterioration, which progresses to the end of complete insulation failure. The frequency and duration of transient faults are on the rise near the occurrence of permanent faults.

3) Abundant instantaneous grounding related information is contained in fault transient zero-mode current

Transient earth faults caused by insulation degradation often occur at the initial phase angle

In the vicinity, the transient component in the zero-mode current mainly contains the oscillation attenuation capacitive component and is much larger than the steady-state component, and the zero-mode current is suitable for being used as a data source for researching the insulation state of the line.

4) Transient zero-mode current frequency spectrum change and amplitude change caused by transition resistance

The transient zero-mode current amplitude value is changed while the oscillation characteristic of the transient resistance is changed, so that the transient zero-mode current amplitude value is increased.

Based on the above research, in this embodiment, a slow-developing permanent fault early warning method is provided, including:

acquiring a recording waveform of each instantaneous fault before a permanent fault;

secondly, positioning a fault section from the obtained wave recording waveform, and extracting key characteristic quantities, wherein the key characteristic quantities comprise the number of times of transient faults in a period of time, the interval between two transient faults, the transient zero-mode current amplitude, the fault duration and the zero-sequence current low-frequency band energy factor;

a. number of transient faults occurring N within a period of time_k

Setting a window with a fixed time length, and observing the occurrence frequency of transient faults in the time window in the process that the window slides along a time track, wherein the more frequent the transient faults occur, the more serious the damage to the line insulation is, the closer the permanent ground fault occurs, and the positive correlation is formed between the damage degree and the insulation degradation degree.

b. Interval between two faults T_kit

The time interval between the current transient fault and the last transient fault of the kth line is considered to be in negative correlation with the insulation degradation degree, and the time interval is shorter and shorter in the process that the frequency of the insulation ground fault rises and the insulation damage of the line is aggravated.

c. Transient zero-mode current amplitude I_k

The transient zero-mode current amplitude reflects the size of the grounding impedance of a fault point to a certain extent, and also indirectly reflects the degree of insulation degradation, and is positively correlated with the degree of insulation degradation, and the larger the transient zero-mode current amplitude is, the higher the degree of insulation degradation is, and the more serious the transient fault is.

d. Duration of failure T_kdt

The longer the fault duration, the greater the intensity of this instantaneous ground fault, the more severe the insulation breakdown, and the greater the degree of reduction in the line insulation level, which positively correlates with the degree of insulation degradation.

e. Zero sequence current low frequency band energy factor E_Lk

The proportion of low-frequency-band energy in the total energy is defined as a low-frequency-band energy factor of zero-sequence current, and the energy distribution of the zero-sequence current in each frequency band is related to the intensity of instantaneous fault along with the reduction of insulation resistance and the increase of equivalent distribution capacitance in the process of line insulation deterioration, and the smaller the low-frequency-band energy factor of the zero-sequence current is, the smaller the transition resistance is, the more serious the insulation deterioration is, and the negative correlation is formed with the insulation deterioration degree.

Except the zero sequence current low-frequency band energy factor, other four characteristics can be directly calculated according to instantaneous fault recording data, and the zero sequence current low-frequency band energy factor needs to be calculated after the recording waveform is subjected to frequency band decomposition. The zero sequence current is decomposed in an equal-bandwidth frequency band by utilizing wavelet packet transformation, namely, the signals pass through a conjugate orthogonal filter bank formed by high-low pass combination, the signals of the upper layer are continuously subdivided into different frequency bands, the sampling interval is doubled and the data points are halved when the filter acts on the signals once. If the sampling frequency of the signal is f_sThen, by the sampling theorem, the Nyquist frequency isf _s2, the bandwidth of the frequency band after n layers of decomposition is f_s/2/2ⁿ＝f_s/2ⁿ⁺¹The frequency range of the jth sub-band may be expressed as:

recording signal x_kThe coefficient of the j sub-band after n-layer decomposition is

m is the number of coefficients in each sub-band, and the energy of each sub-band is:

by reasonably setting the number n of decomposition layers, the power frequency 50Hz appears in the frequency band j equal to 1, and the third harmonic, the fifth harmonic and the power frequency aliasing are avoided, so that the low-frequency band energy factor E of the zero-sequence current can be obtained_LkComprises the following steps:

thirdly, calculating an insulation degradation value during each transient fault according to the key characteristic quantity, and accumulating insulation degradation values obtained for multiple times in the same fault section to obtain an accumulated insulation degradation value;

each key characteristic quantity is constructed as an insulation degradation value function D according to the correlation between the key characteristic quantity and the insulation degradation degree, wherein the larger D is, the more serious the insulation degradation degree is. Cumulative degradation value of line k

Defined as historical degradation value

And a degradation value D 'caused by the current transient fault'_jAnd, as shown in formula (10):

fig. 2 shows an accumulated insulation degradation value change curve obtained by calculating each characteristic amount using a waveform of a transient fault and then updating the insulation degradation value function.

According to the method, besides constructing the function through the correlation relationship between the key characteristic quantity and the insulation degradation degree, the mapping relationship between the key characteristic quantity and the insulation degradation degree can be obtained based on a neural network method of sample training, and the contribution of different key characteristic quantities to the insulation degradation degree can be distinguished through introducing weights.

And fourthly, when the accumulated insulation degradation value exceeds an insulation degradation threshold value, giving out an early warning, wherein the insulation degradation threshold value is determined according to actual operation experience of the specific power distribution network.

The spectral energy distribution of each transient fault in a slowly evolving permanent fault case is shown in fig. 3(a) -3(c), where three transient faults occurred before the permanent fault.

On the basis of analyzing the development rule of the permanent fault and the transient earth fault principle and summarizing the characteristics of the slowly-developing permanent earth fault, the key characteristic set of the early transient fault discharge waveform is extracted from the two aspects of the transient fault generation frequency and the transient fault intensity, and the extracted key characteristic set is used for well reflecting the insulation degradation process in the slowly-developing permanent earth fault, so that the slowly-developing permanent fault is predicted.

The early warning method is designed based on a signal processing mechanism of the power distribution network fault recording device, the problem that the operation cost is excessively increased due to the fact that a large number of additional fault characteristic detection and processing devices need to be installed is solved, and the requirements of practical application are met.

Example 2

In the embodiment, a slowly-developing permanent fault early warning system is provided, and the system comprises a detection module, a controller and an alarm model, wherein the detection module acquires a wave recording waveform of a transient fault, the controller extracts a key characteristic quantity of the wave recording waveform after receiving the wave recording waveform acquired by the detection module, calculates an insulation degradation value during each transient fault according to the key characteristic quantity, accumulates insulation degradation values acquired for multiple times to acquire an accumulated insulation degradation value, and sends alarm information to the alarm module to give an alarm when the accumulated insulation degradation value exceeds an insulation degradation threshold value.

The controller extracts key characteristic quantities from the recording waveform, wherein the key characteristic quantities comprise the occurrence frequency of transient faults in a period of time, the interval between two transient faults, the amplitude of transient zero-mode current, the fault duration and the low-frequency-band energy factor of zero-sequence current.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Although the present disclosure has been described with reference to specific embodiments, it should be understood that the scope of the present disclosure is not limited thereto, and those skilled in the art will appreciate that various modifications and changes can be made without departing from the spirit and scope of the present disclosure.

Claims (10)

1. A slow-developing permanent fault early warning method is characterized by comprising the following steps:

acquiring a recording waveform of each instantaneous fault before a permanent fault occurs on a line;

judging a fault section through a recording waveform, and extracting key characteristic quantity;

calculating an insulation degradation value during each transient fault according to the key characteristic quantity;

accumulating the insulation degradation values obtained for multiple times in the same fault section to obtain an accumulated insulation degradation value;

and when the accumulated insulation degradation value exceeds an insulation degradation threshold value, giving an early warning.

2. A slow-developing permanent fault pre-warning method as claimed in claim 1, wherein the key characteristic quantities include the number of transient faults occurring within a period of time, the interval between two transient faults, the transient zero-mode current amplitude, the fault duration and the zero-sequence current low-band energy factor.

3. The method of claim 2, wherein the number of transient faults occurring within a period of time is positively correlated to the degree of insulation degradation; the interval between two transient faults is in negative correlation with the insulation degradation degree; the transient zero-mode current amplitude is in positive correlation with the insulation degradation degree; the fault duration is positively correlated with the degree of insulation degradation; the zero sequence current low-frequency band energy factor is in negative correlation with the insulation degradation degree.

4. The method of claim 2, wherein the number of transient faults occurring within a period of time, the interval between two transient faults, the transient zero mode current amplitude and the fault duration are directly obtained from the obtained recording waveform.

5. The slow-developing permanent fault pre-warning method as claimed in claim 2, wherein the obtained recording waveform is subjected to band decomposition to obtain energy of each sub-band, and a zero-sequence current low-band energy factor is obtained according to a ratio of the energy of the first sub-band to the sum of the energy of each sub-band.

6. The slow-developing permanent fault early warning method as claimed in claim 1, wherein the correlation between the key characteristic quantity and the insulation degradation degree is considered when calculating the insulation degradation value of each transient fault.

7. The slow-developing permanent fault warning method as claimed in claim 1, wherein a larger insulation degradation value indicates a more serious insulation degradation.

8. The slow-developing permanent fault pre-warning method as claimed in claim 1, wherein the insulation degradation threshold is determined according to actual operation experience of a specific distribution network.

9. The slow-developing permanent fault early warning system is characterized by comprising a detection module, a controller and an alarm model, wherein a wave recording waveform of a transient fault is obtained through the detection module, the controller extracts key characteristic quantities of the wave recording waveform after receiving the wave recording waveform obtained by the detection module, an insulation degradation value during each transient fault is calculated according to the key characteristic quantities, the insulation degradation values obtained for multiple times are accumulated to obtain an accumulated insulation degradation value, and when the accumulated insulation degradation value exceeds an insulation degradation threshold value, alarm information is sent to the alarm module to give an alarm.

10. A slowly evolving permanent fault pre-warning system as claimed in claim 9, wherein the key features extracted by the controller from the recorded waveform include the number of transient faults occurring over a period of time, the interval between two transient faults, the transient zero mode current amplitude, the fault duration and the zero sequence current low band energy factor.

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