CN101782621A - Method and device for judging fault point locations in cable protective layer fault detection - Google Patents

Method and device for judging fault point locations in cable protective layer fault detection Download PDF

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Publication number
CN101782621A
CN101782621A CN201010130453A CN201010130453A CN101782621A CN 101782621 A CN101782621 A CN 101782621A CN 201010130453 A CN201010130453 A CN 201010130453A CN 201010130453 A CN201010130453 A CN 201010130453A CN 101782621 A CN101782621 A CN 101782621A
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signal
voltage
cable
probe
acquisition
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CN101782621B (en
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李桂义
李卒祥
陈宗军
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ZIBO WEITE ELECTRIC CO Ltd
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ZIBO WEITE ELECTRIC CO Ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y04INFORMATION OR COMMUNICATION TECHNOLOGIES HAVING AN IMPACT ON OTHER TECHNOLOGY AREAS
    • Y04SSYSTEMS INTEGRATING TECHNOLOGIES RELATED TO POWER NETWORK OPERATION, COMMUNICATION OR INFORMATION TECHNOLOGIES FOR IMPROVING THE ELECTRICAL POWER GENERATION, TRANSMISSION, DISTRIBUTION, MANAGEMENT OR USAGE, i.e. SMART GRIDS
    • Y04S10/00Systems supporting electrical power generation, transmission or distribution
    • Y04S10/50Systems or methods supporting the power network operation or management, involving a certain degree of interaction with the load-side end user applications
    • Y04S10/52Outage or fault management, e.g. fault detection or location

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Abstract

The invention relates to a method and a device for judging fault point locations in cable protective layer fault detection, which belong to the technical field of cable sheath fault detection. A stable current rectangular wave signal is applied to a fault cable sheath through a controllable high-voltage DC constant current power supply, and the cable sheath directly flows into the ground through fault points or through a semi-conductor layer through the fault points; the signal is detected on the ground or on the surface of the cable sheath; and the locations of the fault points are judged by analyzing the duty cycle of the rectangular wave signal, and an indicator is used to display the wave form of the signal and clearly indicates the locations of the fault points. The device comprises the controllable high-voltage DC constant current power supply, a signal detector and a probe, can automatically track the changes to the ground potential with the judgment method, has the advantages of strong anti-interference capability, high detection flexibility and large scope of response, so as to improve the cable sheath fault defection efficiency, reduce the working strength, and reduce the requirements on the experience of a user.

Description

A kind of in the cable sheath fault finding method and apparatus in failure judgement point orientation
Technical field
Invention relate to a kind of in the cable sheath fault finding method and apparatus in failure judgement point orientation, belong to cable sheath Fault Defection Technology field.
Background technology
Present traditional cable sheath Fault Defection Technology, one working voltage ratio or resistance ratio method are found range, but these distance-finding methods can only be effective at Single Point of Faliure, then can't accurately find range for the multiple spot fault.Therefore can carry out on a large scale the direct localization of faults particularly the high resistive fault point become extremely important.
At present, the fault localization of power cable and location mainly contain following several method:
1, bridge method: this method is to utilize electrical bridge principle, carries out fault localization by the resistance that calculates earthing cable.But this method is not suitable for the sheath fault localization because of poor anti jamming capability.
2, sound magnetic-synchro method: this method uses high-tension apparatus to make Method of Cable Trouble Point disruptive discharge, utilizes receiver record discharge sound, and with field signal it is carried out synchronously, by analyzing sound waveform or earphone fault is found range and is fixed a point.But the voice signal that this method needs detection failure point to produce, and most trouble spots of sheath fault do not produce voice signal, so incompatibility sheath position determination of fault.
Traditional fix-point method " step voltage method ", as Chinese patent 200410035595.0 disclosed " orientation of direct application type cable sheath fault and locating measurement method and measurement mechanism thereof ", one is the surge voltage signal that applies a Millisecond by the impacting with high pressure signal generator between the metal sheath of cable and the earth, or the injection one-period is tens seconds a direct current discontinuous signal, at this signal of ground location, by the polarity and the amplitude of direct judgement signal voltage, determine direction of current and particular location.This surge voltage method is to be applied directly on the cable by behind the capacitance energy storage, when fault resstance is smaller, can produce the dash current signal of very big Millisecond.When fault resstance was bigger, dash current was little, and the faint signal of Millisecond can be flooded by neighbourhood noise easily, and the probe response scope is little.Macrocyclic direct current signal injection method is subjected to the influence of earth potential drift easily, the zeroing difficulty, and the probe response scope is little.
Summary of the invention
According to above deficiency of the prior art, the object of the present invention is to provide a kind of antijamming capability strong, that surveys is highly sensitive, responding range is big, thereby improve the efficient of cable sheath fault finding, reduce working strength, the method in failure judgement point orientation in the cable sheath fault finding that reduces that experience to the user requires.
Another object of the present invention is to provide a kind of device that can be implemented in the method in failure judgement point orientation in the cable sheath fault finding.
The present invention is achieved in that the method in failure judgement point orientation in the cable sheath fault finding, it is characterized in that, may further comprise the steps:
(1) apply stable electric current square-wave signal by the controllable high-voltage dc constant flowing power in failure cable sheath to be measured, the dutycycle of this electric current square-wave signal is 1%-99%, but does not comprise 50%;
(2) the electric current square-wave signal flows directly into the earth or flows into the earth by the trouble spot through semiconductor layer by the trouble spot of cable sheath, utilize an acquisition of signal instrument sensing point to be set, survey the voltage signal that this electric current square-wave signal forms on ground or on the cable sheath surface;
(3) by the analytical voltage signal, change from the earthy drift of motion tracking, by computed duty cycle, judge sense of current, and by indicator for displaying waveform voltage signal and trouble spot direction;
(4) along the sensing point of the trouble spot direction movable signal detection instrument of indicator for displaying, repeating step (3), the trouble spot direction that sight indicator shows is up to showing that the trouble spot direction changes the localization of faults.
Its preferred version is anodal probe and negative pole probe continuously detectable voltage signals and the earth potential drift variation of described acquisition of signal instrument by being provided with at interval.The setting that one in front and one in back keeps at a certain distance away of two probes, the big I of distance is adjusted according to the detectable signal size, forms sensing point.
Its principle can adopt the phase place determining method: when injecting the electric current square-wave signal of positive polarity, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, the direction that anodal probe is arranged on the cable other end is surveyed, the voltage signal that analyze the acquisition of signal instrument anodal probe and negative pole probe in detecting arrive, and carry out bit comparison mutually with the electric current square-wave signal of injecting, both homophases, be judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying waveform and directional arrow; Otherwise, voltage signal carries out bit comparison mutually with the electric current square-wave signal of injection, both are anti-phase, are judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction, and indicator for displaying voltage waveform and directional arrow are expressed.
Perhaps, when injecting the electric current square-wave signal of negative polarity, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, the direction that anodal probe is arranged on the cable other end is surveyed, the voltage signal that analyze the acquisition of signal instrument anodal probe and negative pole probe in detecting arrive, and carry out bit comparison mutually with the electric current square-wave signal of injecting, both are anti-phase, be judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying waveform and directional arrow; Otherwise, voltage signal carries out bit comparison mutually with the electric current square-wave signal of injection, both homophases are judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction, and indicator for displaying voltage waveform and directional arrow are expressed.
For simplifying the phase bit comparison of two signals, adopt and inject the unequal square-wave signal of high-low level.
Described electric current square-wave signal is the continuous signal of frequency stabilization, and its frequency is between 0.5Hz-2Hz, and dutycycle is 1%-99%, but does not comprise 50%.
It judges that principle can also adopt the dutycycle determining method:
A), when injecting positive polarity and dutycycle less than 50% current signal, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, anodal probe is surveyed in the direction of the cable other end, the dutycycle of acquisition of signal instrument analytical voltage signal, the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is less than 50%, be judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying waveform voltage signal and directional arrow; Otherwise, the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is greater than 50%, be judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction, indicator for displaying waveform voltage signal and directional arrow are expressed.
B), when injecting positive polarity and dutycycle greater than 50% current signal, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, anodal probe is surveyed in the direction of the cable other end, the dutycycle of acquisition of signal instrument analytical voltage signal, the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is greater than 50%, be judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying waveform voltage signal dutycycle and directional arrow; Otherwise, the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is less than 50%, be judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction, indicator for displaying waveform voltage signal and directional arrow are expressed.
C), when injecting negative polarity and dutycycle less than 50% current signal, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, anodal probe is surveyed in the direction of the cable other end, the dutycycle of acquisition of signal instrument analytical voltage signal, the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is greater than 50%, be judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying waveform voltage signal and directional arrow; Otherwise, the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is less than 50%, be judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction, indicator for displaying waveform voltage signal and directional arrow are expressed.
D), when injecting negative polarity and dutycycle greater than 50% current signal, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, anodal probe is surveyed in the direction of the cable other end, the dutycycle of acquisition of signal instrument analytical voltage signal, the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is less than 50%, be judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying waveform voltage signal and directional arrow; Otherwise, the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is greater than 50%, be judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction, indicator for displaying waveform voltage signal and directional arrow are expressed.
According to above method; the device in failure judgement point orientation in the cable sheath fault finding; comprise failure cable and probe; it is characterized in that also comprising controllable high-voltage dc constant flowing power and acquisition of signal instrument; the output terminal of described controllable high-voltage dc constant flowing power connects an end of failure cable; probe connects the input end of acquisition of signal instrument; described acquisition of signal instrument comprises the input protection unit; magnification processing; computer processing unit; indicator and signal trace zeroing unit; probe connects the input end of magnification processing by the input protection unit; the output terminal of magnification processing connects the input end of computer processing unit; the output terminal of computer processing unit is by the input end of signal trace zeroing unit connection magnification processing, and the output terminal of computer processing unit is link indicator also.
The controllable high-voltage dc constant flowing power applies stable electric current square-wave signal in the sheath of failure cable, the acquisition of signal instrument is obtained this signal by probe, and carries out Treatment Analysis, display result.
Described controllable high-voltage dc constant flowing power comprises square-wave signal generation circuit, feedback control circuit, power supply input rectifying filtering circuit, inverter circuit, high-frequency transformer, high-voltage rectifier and isolation feedback circuit, the input end of power supply input rectifying filtering circuit connects civil power, its output terminal connects the input end of inverter circuit, the output terminal of inverter circuit connects the high-voltage rectifier input end by high-frequency transformer, the output terminal of high-voltage rectifier is connected inverter circuit by isolation feedback circuit with feedback control circuit, the output terminal of square-wave signal generation circuit connects feedback control circuit, and the output terminal of high-voltage rectifier is the output terminal of controllable high-voltage dc constant flowing power.Square-wave signal generation circuit provides given signal, and the output terminal of high-voltage rectifier applies power supply and this signal to the sheath of failure cable.
Its prioritization scheme is that the output terminal of described computer processing unit connects the input end of signal trace zeroing unit by digital to analog converter.
The beneficial effect that method and apparatus had in the present invention failure judgement point orientation in the cable sheath fault finding is: this method is injected the method for continuous signal and waveform duty cycle analysis by using the controllable high-voltage dc constant flowing power, failure judgement point direction, can be directly by the indicator for displaying signal waveform and clearly indicate fault direction; This device can change from the motion tracking earth potential, and antijamming capability is strong, detection highly sensitive, and responding range is big, thereby improves the efficient of cable sheath fault finding, reduces working strength, reduces the experience requirement to the user.
Description of drawings
Fig. 1 is a working state schematic representation of the present invention;
Fig. 2 is a decision flow chart of the present invention;
Fig. 3 is the functional-block diagram of controllable high-voltage dc constant flowing power of the present invention;
Fig. 4 is an electrical principle block scheme of the present invention;
Wherein: 1; controllable high-voltage dc constant flowing power 2; semiconductor layer 3; trouble spot 4; acquisition of signal instrument 5; 16; probe 6; aluminium sheath 7; main insulating layer 8; heart yearn 9; square-wave signal generation circuit 10; feedback control circuit 11; power supply input rectifying filtering circuit 12; inverter circuit 13; high-frequency transformer 14; high-voltage rectifier 15; isolation feedback circuit 16; input protection unit 17; magnification processing 18; signal trace zeroing unit 19; magnification processing 20; computer processing unit 21; indicator.
Embodiment
Come process in detail below in conjunction with accompanying drawing.
As shown in Figure 1, buried cable is made up of heart yearn 8, main insulating layer 7, aluminium sheath 6 and semiconductor layer 2, and when cable sheath broke down, aluminium sheath 6 formed short circuit at 3 places, trouble spot and the earth of semiconductor layer 2.
During detection, apply stable electric current square-wave signal by controllable high-voltage dc constant flowing power 1 in failure cable aluminium sheath 6 to be measured, the dutycycle of this electric current square-wave signal is 1%-99%, but does not comprise 50%; The electric current square-wave signal flows directly into the earth or flows into the earth by trouble spot 3 through semiconductor layer 2 by the trouble spot 3 of cable sheath, and forming with trouble spot 3 is the voltage drop that reduces successively outward in the center of circle.The variation of this voltage drop is relevant with amplitude size, the frequency of electric current square-wave signal.Utilize two probes 5 (forming) setting that one in front and one in back keeps at a certain distance away of acquisition of signal instrument 4, form sensing point, survey the voltage signal that this electric current square-wave signal forms by A pin, B pin; Acquisition of signal instrument 4 changes from the earthy drift of motion tracking by the analytical voltage signal, by computed duty cycle, judges sense of current, and by indicator 4 display voltage signal waveforms and trouble spot direction; At last, along the sensing point of the trouble spot direction movable signal detection instrument 4 of indicator for displaying, the trouble spot direction that sight indicator shows is up to showing that the trouble spot direction changes the localization of faults.
The electric current square-wave signal is preferably the continuous signal of frequency stabilization, and its frequency is between 0.5Hz-2Hz, and dutycycle is 5%-95%, but does not comprise 50%.
The dutycycle of acquisition of signal instrument analytical voltage signal, and compare with the electric current square-wave signal, both are identical, are judged to be the trouble spot on the cable of the sensing point other end, indicator for displaying voltage waveform and directional arrow; Otherwise the dutycycle of voltage signal is compared with the electric current square-wave signal, and both are opposite, is judged to be the trouble spot on the cable between sensing point and the controllable high-voltage dc constant flowing power, and indicator for displaying waveform voltage signal and directional arrow are expressed.
As shown in Figure 2, during acquisition of signal instrument 4 analytic signals, the signal of probe in detecting carries out the A/D data sampling by computer processing unit, signal calculated dc shift amount then, return to zero by zeroing circuit, calculate the dutycycle of input signal, judge at last: if dutycycle greater than 50%, shows direction of arrow A-B; If dutycycle less than 50%, shows direction of arrow B-A.
Specific embodiment:
Embodiment 1:
The electric current square-wave signal is a positive polarity, dutycycle is 1% o'clock, when two probes 5 contact 2 of acquisition of signal instrument 4 left side (on the cable between trouble spot 3 and the controllable high-voltage dc constant flowing power) in Method of Cable Trouble Point 3, the square wave dutycycle of its indicator for displaying is less than 50%, the A probe that shows arrow points probe 5, traveling probe 5 continues sight indicator, until showing the trouble spot.When right side in Method of Cable Trouble Point 3 of two probes 5 contact 2 of signal receiver 4 (trouble spot opposite side cable), the square wave dutycycle of its indicator for displaying shows the B probe of arrow points probe 5 greater than 50%.
Embodiment 2:
The electric current square-wave signal is a positive polarity, dutycycle is 49% o'clock, when two probes 5 contact 2 of acquisition of signal instrument 4 left side (on the cable between trouble spot 3 and the controllable high-voltage dc constant flowing power) in Method of Cable Trouble Point 3, the square wave dutycycle of its indicator for displaying shows the A probe of arrow points probe 5 less than 50%.When right side in Method of Cable Trouble Point 3 of two probes 5 contact 2 of signal receiver 4 (trouble spot opposite side cable), the square wave dutycycle of its indicator for displaying shows the B probe of arrow points probe 5 greater than 50%.
Embodiment 3:
The electric current square-wave signal is a positive polarity, dutycycle is 30% o'clock, when two probes 5 contact 2 of acquisition of signal instrument 4 left side (on the cable between trouble spot 3 and the controllable high-voltage dc constant flowing power) in Method of Cable Trouble Point 3, the square wave dutycycle of its indicator for displaying shows the A probe of arrow points probe 5 less than 50%.When right side in Method of Cable Trouble Point 3 of two probes 5 contact 2 of signal receiver 4 (trouble spot opposite side cable), the square wave dutycycle of its indicator for displaying shows the B probe of arrow points probe 5 greater than 50%.
Embodiment 4:
The electric current square-wave signal is a positive polarity, dutycycle is 51% o'clock, when two probes 5 contact 2 of acquisition of signal instrument 4 left side (on the cable between trouble spot 3 and the controllable high-voltage dc constant flowing power) in Method of Cable Trouble Point 3, the square wave dutycycle of its indicator for displaying shows the B probe of arrow points probe 5 greater than 50%.When right side in Method of Cable Trouble Point 3 of two probes 5 contact 2 of signal receiver 4 (trouble spot opposite side cable), the square wave dutycycle of its indicator for displaying shows the A probe of arrow points probe 5 less than 50%.
Embodiment 5:
The electric current square-wave signal is a positive polarity, dutycycle is 99% o'clock, when two probes 5 contact 2 of acquisition of signal instrument 4 left side (on the cable between trouble spot 3 and the controllable high-voltage dc constant flowing power) in Method of Cable Trouble Point 3, the square wave dutycycle of its indicator for displaying shows the B probe of arrow points probe 5 greater than 50%.When right side in Method of Cable Trouble Point 3 of two probes 5 contact 2 of signal receiver 4 (trouble spot opposite side cable), the square wave dutycycle of its indicator for displaying shows the A probe of arrow points probe 5 less than 50%.
Embodiment 6:
The electric current square-wave signal is a positive polarity, dutycycle is 70% o'clock, when two probes 5 contact 2 of acquisition of signal instrument 4 left side (on the cable between trouble spot 3 and the controllable high-voltage dc constant flowing power) in Method of Cable Trouble Point 3, the square wave dutycycle of its indicator for displaying shows the B probe of arrow points probe 5 greater than 50%.When right side in Method of Cable Trouble Point 3 of two probes 5 contact 2 of signal receiver 4 (trouble spot opposite side cable), the square wave dutycycle of its indicator for displaying shows the A probe of arrow points probe 5 less than 50%.
Embodiment 7-embodiment 12:
The electric current square-wave signal is a negative polarity, and dutycycle adopts 1%, 30%, 49%, 51%, 70% and respectively at 99% o'clock, and after the test, the square wave of indicator for displaying is identical with embodiment 1-embodiment 6, can clearly indicate the trouble spot direction.
Embodiment 13:
When injecting the electric current square-wave signal of positive polarity, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, the direction that anodal probe is arranged on the cable other end is surveyed, the voltage signal that analyze the acquisition of signal instrument anodal probe and negative pole probe in detecting arrive, and carry out bit comparison mutually with the electric current square-wave signal of injecting, both homophases are judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying waveform and directional arrow; Otherwise, voltage signal carries out bit comparison mutually with the electric current square-wave signal of injection, both are anti-phase, are judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction, and indicator for displaying voltage waveform and directional arrow are expressed.
Embodiment 14:
When injecting the electric current square-wave signal of negative polarity, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, the direction that anodal probe is arranged on the cable other end is surveyed, the voltage signal that analyze the acquisition of signal instrument anodal probe and negative pole probe in detecting arrive, and carry out bit comparison mutually with the electric current square-wave signal of injecting, both are anti-phase, are judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying waveform and directional arrow; Otherwise, voltage signal carries out bit comparison mutually with the electric current square-wave signal of injection, both homophases are judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction, and indicator for displaying voltage waveform and directional arrow are expressed.
As Fig. 3; shown in Figure 4; for realizing a kind of device of this method: comprise failure cable; probe 16; controllable high-voltage dc constant flowing power 1 and acquisition of signal instrument 4; the output terminal of controllable high-voltage dc constant flowing power connects an end of failure cable; probe 16 connects the input end of acquisition of signal instrument; described acquisition of signal instrument comprises input protection unit 17; magnification processing 19; computer processing unit 20; indicator 21 and signal trace zeroing unit 18; probe 16 connects the input end of magnification processing 19 by input protection unit 17; the output terminal of magnification processing 19 connects the input end of computer processing unit 20; the output terminal of computer processing unit 20 is by the input end of signal trace zeroing unit 18 connection magnification processing 19, and the output terminal of computer processing unit 20 is link indicator 21 also.The output terminal of computer processing unit 20 connects the input end of signal trace zeroing unit 18 by digital to analog converter.
Controllable high-voltage dc constant flowing power 1 comprises square-wave signal generation circuit 9, feedback control circuit 10, power supply input rectifying filtering circuit 11, inverter circuit 12, high-frequency transformer 13, high-voltage rectifier 14 and isolation feedback circuit 15, the input end of power supply input rectifying filtering circuit 11 connects civil power, its output terminal connects the input end of inverter circuit 12, the output terminal of inverter circuit 12 connects high-voltage rectifier 14 input ends by high-frequency transformer 13, the output terminal of high-voltage rectifier 14 is connected inverter circuit 12 by isolation feedback circuit 15 with feedback control circuit 15, the output terminal of square-wave signal generation circuit 9 connects feedback control circuit 15, and the output terminal of high-voltage rectifier 14 is the output terminal of controllable high-voltage dc constant flowing power 1.
Two probes 16 are surveyed input voltage signal, through input protection unit 17, and signal trace zeroing unit 18; magnification processing 19; by computer processing unit 20 calculating of returning to zero, judge the dutycycle of calculating input signal, by the direction of indicator 21 shows signal waveforms and indication fault point.
Above-described indicator 21 can be the LCD LCD, also can be the indicating device of other types, and waveform shows and clear and definite direction prompting all can as long as can carry out.Computer processing unit 20 adopts can single-chip microcomputer, also can adopt micro computer PC, and input protection unit 17 adopts the normal signal holding circuits.Signal trace zeroing unit 18 is an operational amplifier.Power supply input rectifying filtering circuit 11, inverter circuit 12, high-frequency transformer 13 and high-voltage rectifier 14 are common existing product, can buy from the market.
Principle of work and process:
Square-wave signal generation circuit 1 provides given signal, and the output terminal of high-voltage rectifier 14 applies power supply and this signal to the sheath of failure cable.Two probes 16 are surveyed input voltage signal; through input protection unit 17; signal trace zeroing unit 18; magnification processing 19; by computer processing unit 20 calculating of returning to zero; judge and calculate phase of input signals or dutycycle, by the direction of indicator 17 shows signal waveforms and indication fault point.

Claims (9)

1. the method in a failure judgement point orientation in the cable sheath fault finding is characterized in that: may further comprise the steps:
(1) apply stable electric current square-wave signal by the controllable high-voltage dc constant flowing power in failure cable sheath to be measured, the dutycycle of this electric current square-wave signal is 1%-99%;
(2) the electric current square-wave signal flows directly into the earth or flows into the earth by the trouble spot through semiconductor layer by the trouble spot of cable sheath, utilize an acquisition of signal instrument sensing point to be set, survey the voltage signal that this electric current square-wave signal forms on ground or on the cable sheath surface;
(3) by the analytical voltage signal, change from the earthy drift of motion tracking, by computed duty cycle, judge sense of current, and voltage waveform and the trouble spot direction surveyed by indicator for displaying;
(4) along the sensing point of the trouble spot direction movable signal detection instrument of indicator for displaying, repeating step (3), voltage waveform and trouble spot direction that sight indicator shows change the localization of faults up to the trouble spot direction that shows.
2. method according to claim 1 is characterized in that: anodal probe and negative pole probe continuously detectable voltage signals and the earth potential drift variation of described acquisition of signal instrument by being provided with at interval.
3. method according to claim 1 is characterized in that: described electric current square-wave signal is the continuous signal of frequency stabilization, and its frequency is between 0.5Hz-2Hz.
4. method according to claim 3 is characterized in that: the dutycycle of described electric current square-wave signal is 1%-99%, but does not comprise 50%.
5. method according to claim 1, it is characterized in that: the determination methods of described step (3) is: when injecting the electric current square-wave signal of positive polarity, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, the direction that anodal probe is arranged on the cable other end is surveyed, the voltage signal that analyze the acquisition of signal instrument anodal probe and negative pole probe in detecting arrive, and carry out bit comparison mutually with the electric current square-wave signal of injecting, both homophases, be judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying waveform and directional arrow; Otherwise, voltage signal carries out bit comparison mutually with the electric current square-wave signal of injection, both are anti-phase, are judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction, and indicator for displaying voltage waveform and directional arrow are expressed.
6. method according to claim 1, it is characterized in that: the determination methods of described step (3) is: when injecting positive polarity and dutycycle less than 50% current signal, the negative pole probe of acquisition of signal instrument is arranged on controllable high-voltage dc constant flowing power direction, anodal probe is surveyed in the direction of the cable other end, the dutycycle of acquisition of signal instrument analytical voltage signal, the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is less than 50%, be judged to be the trouble spot on the cable of the other end of the sensing point of anodal probe direction, indicator for displaying voltage waveform and directional arrow; Otherwise the voltage signal dutycycle that two probes of acquisition of signal instrument are gathered is judged to be the trouble spot on the sensing point and the cable between the controllable high-voltage dc constant flowing power of negative pole probe direction greater than 50%, and indicator for displaying voltage waveform and directional arrow are expressed.
7. device in failure judgement point orientation in the cable sheath fault finding in accordance with the method for claim 1; comprise failure cable and probe; it is characterized in that: also comprise controllable high-voltage dc constant flowing power and acquisition of signal instrument; the output terminal of described controllable high-voltage dc constant flowing power connects an end of failure cable; probe connects the input end of acquisition of signal instrument; described acquisition of signal instrument comprises the input protection unit; magnification processing; computer processing unit; indicator and signal trace zeroing unit; probe connects the input end of magnification processing by the input protection unit; the output terminal of magnification processing connects the input end of computer processing unit; the output terminal of computer processing unit is by the input end of signal trace zeroing unit connection magnification processing, and the output terminal of computer processing unit is link indicator also.
8. device according to claim 7, it is characterized in that: described controllable high-voltage dc constant flowing power comprises square-wave signal generation circuit, feedback control circuit, power supply input rectifying filtering circuit, inverter circuit, high-frequency transformer, high-voltage rectifier and isolation feedback circuit, the input end of power supply input rectifying filtering circuit connects civil power, its output terminal connects the input end of inverter circuit, the output terminal of inverter circuit connects the high-voltage rectifier input end by high-frequency transformer, the output terminal of high-voltage rectifier is connected inverter circuit by isolation feedback circuit with feedback control circuit, the output terminal of square-wave signal generation circuit connects feedback control circuit, and the output terminal of high-voltage rectifier is the output terminal of controllable high-voltage dc constant flowing power.
9. device according to claim 7 is characterized in that: the output terminal of described computer processing unit connects the input end of signal trace zeroing unit by digital to analog converter.
CN2010101304538A 2010-03-23 2010-03-23 Method and device for judging fault point locations in cable protective layer fault detection Active CN101782621B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2010101304538A CN101782621B (en) 2010-03-23 2010-03-23 Method and device for judging fault point locations in cable protective layer fault detection

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Application Number Priority Date Filing Date Title
CN2010101304538A CN101782621B (en) 2010-03-23 2010-03-23 Method and device for judging fault point locations in cable protective layer fault detection

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CN101782621A true CN101782621A (en) 2010-07-21
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Cited By (14)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102590714A (en) * 2012-02-23 2012-07-18 江苏三通仪器系统有限公司 Electric wire fault detector
CN102759686A (en) * 2012-07-26 2012-10-31 山东科汇电力自动化有限公司 Method for locating power cable faults
CN102998592A (en) * 2011-09-13 2013-03-27 中国二十冶集团有限公司 Determining method for cable high-resistance fault points
CN103163422A (en) * 2011-12-15 2013-06-19 西安华傲通讯技术有限责任公司 Device for searching fault points of cable or pipeline
ES2532677A1 (en) * 2014-07-04 2015-03-30 Universidad Politécnica de Madrid Method and system of detection of ground faults in dc networks of isolated cables (Machine-translation by Google Translate, not legally binding)
CN105988061A (en) * 2015-02-05 2016-10-05 云南酷联科技有限公司 High voltage single core cable protective layer fault locating method
CN106990327A (en) * 2017-05-11 2017-07-28 国网江苏省电力公司苏州供电公司 High voltage single-core cable short trouble point detecting method
CN107153153A (en) * 2016-03-02 2017-09-12 费希尔-罗斯蒙特系统公司 Communication line failure is controlled from the detection of hand-held maintenance tool and position fixing process
CN108646144A (en) * 2018-07-25 2018-10-12 国家电网有限公司 A kind of offline distance measuring method of high voltage single-core cable short trouble, apparatus and system
CN110346679A (en) * 2019-08-14 2019-10-18 广东电网有限责任公司 A kind of high-voltage cable joint metallic earthing failure Fast Fixed-point method
CN111711129A (en) * 2020-06-29 2020-09-25 中国化学工程第十一建设有限公司 Construction method for searching and repairing fault of outer sheath of single-core high-voltage cable
CN111948488A (en) * 2020-07-23 2020-11-17 广东电网有限责任公司 Distribution cable fault monitoring system and use method
CN113625112A (en) * 2021-08-11 2021-11-09 国网河北省电力有限公司保定供电分公司 Cable fault positioning method and positioning instrument
US11422203B1 (en) * 2019-02-15 2022-08-23 Maxim Integrated Products, Inc. Current sensing line fault detector

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20010048310A1 (en) * 2000-05-30 2001-12-06 International Rectifier Corporation Motor insulation fault detection by sensing ground leak current
CN1598607A (en) * 2004-08-20 2005-03-23 淄博博鸿电气有限公司 Directional and positioning testing device for fault of direct application type cable sheath
CN1719271A (en) * 2005-07-01 2006-01-11 淄博威特电气有限公司 Cable failure prefixed point detection method and detection device

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20010048310A1 (en) * 2000-05-30 2001-12-06 International Rectifier Corporation Motor insulation fault detection by sensing ground leak current
CN1598607A (en) * 2004-08-20 2005-03-23 淄博博鸿电气有限公司 Directional and positioning testing device for fault of direct application type cable sheath
CN1719271A (en) * 2005-07-01 2006-01-11 淄博威特电气有限公司 Cable failure prefixed point detection method and detection device

Cited By (19)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102998592A (en) * 2011-09-13 2013-03-27 中国二十冶集团有限公司 Determining method for cable high-resistance fault points
CN103163422A (en) * 2011-12-15 2013-06-19 西安华傲通讯技术有限责任公司 Device for searching fault points of cable or pipeline
CN102590714A (en) * 2012-02-23 2012-07-18 江苏三通仪器系统有限公司 Electric wire fault detector
CN102590714B (en) * 2012-02-23 2014-11-19 江苏三通仪器系统有限公司 Electric wire fault detector
CN102759686A (en) * 2012-07-26 2012-10-31 山东科汇电力自动化有限公司 Method for locating power cable faults
ES2532677A1 (en) * 2014-07-04 2015-03-30 Universidad Politécnica de Madrid Method and system of detection of ground faults in dc networks of isolated cables (Machine-translation by Google Translate, not legally binding)
CN105988061A (en) * 2015-02-05 2016-10-05 云南酷联科技有限公司 High voltage single core cable protective layer fault locating method
CN105988061B (en) * 2015-02-05 2019-03-22 云南酷联科技有限公司 A kind of method of high voltage single-core cable protective layer fault location
CN107153153A (en) * 2016-03-02 2017-09-12 费希尔-罗斯蒙特系统公司 Communication line failure is controlled from the detection of hand-held maintenance tool and position fixing process
CN106990327A (en) * 2017-05-11 2017-07-28 国网江苏省电力公司苏州供电公司 High voltage single-core cable short trouble point detecting method
CN106990327B (en) * 2017-05-11 2019-10-18 国网江苏省电力公司苏州供电公司 High voltage single-core cable short trouble point detecting method
CN108646144A (en) * 2018-07-25 2018-10-12 国家电网有限公司 A kind of offline distance measuring method of high voltage single-core cable short trouble, apparatus and system
US11422203B1 (en) * 2019-02-15 2022-08-23 Maxim Integrated Products, Inc. Current sensing line fault detector
CN110346679A (en) * 2019-08-14 2019-10-18 广东电网有限责任公司 A kind of high-voltage cable joint metallic earthing failure Fast Fixed-point method
CN110346679B (en) * 2019-08-14 2021-04-02 广东电网有限责任公司 Method for quickly locating metallic ground fault of high-voltage cable joint
CN111711129A (en) * 2020-06-29 2020-09-25 中国化学工程第十一建设有限公司 Construction method for searching and repairing fault of outer sheath of single-core high-voltage cable
CN111711129B (en) * 2020-06-29 2021-08-17 中国化学工程第十一建设有限公司 Construction method for searching and repairing fault of outer sheath of single-core high-voltage cable
CN111948488A (en) * 2020-07-23 2020-11-17 广东电网有限责任公司 Distribution cable fault monitoring system and use method
CN113625112A (en) * 2021-08-11 2021-11-09 国网河北省电力有限公司保定供电分公司 Cable fault positioning method and positioning instrument

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