CN204256111U - Partial discharge detecting system - Google Patents
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- CN204256111U CN204256111U CN201420543383.2U CN201420543383U CN204256111U CN 204256111 U CN204256111 U CN 204256111U CN 201420543383 U CN201420543383 U CN 201420543383U CN 204256111 U CN204256111 U CN 204256111U
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Abstract
The utility model discloses a kind of partial discharge detecting system.This partial discharge detecting system comprises: high pressure produces equipment, is connected to tested cable, produces damp oscillatory wave for exciting tested cable; Fault test set, produces equipment connection with high pressure, for carrying out Partial Discharge Detection to tested cable.Pass through the utility model, solve partial discharge detecting system in correlation technique adopts direct current pressurization to have damage and partial discharge detecting system cannot carry out the problem of withstand voltage test to cable simultaneously, and then the space charge of tested electric cable stoppage place accumulation under avoiding DC voltage causes damage to cable insulation, achieves and carry out withstand voltage test in partial discharge detecting system simultaneously simultaneously.
Description
Technical field
The utility model relates to field of power, in particular to a kind of partial discharge detecting system.
Background technology
Along with the fast development of electric power network technique, twisted polyethylene cable (being called for short XLPE) has good electrical property and thermal behavior, and structure is simple, manufacturing cycle is short, and work tolerable temperature is high, without oil, lay conveniently, power supply safety is reliable, is conducive to beautifying city, is thus widely used in each electric pressure of electric system.But, in the insulation system of twisted polyethylene cable often due to the difficulty in process technology or starting material impure and there is air gap and harmfulness impurity, or because technological reason exists gap or semiconductor is outstanding to insulation course between insulation and semiconductive shielding layer, very easily produce shelf depreciation at these air gaps and impurity tip place, in the middle of the installation and operation process of power cable, also may produce various insulation defect causes shelf depreciation simultaneously.Shelf depreciation is the sign of cable insulation deterioration, also be one of major reason causing insulation degradation, shelf depreciation is the operating larger potential safety hazard of power cable, to a certain degree if shelf depreciation develops into will cause insulation breakdown and cause power grid accident.Therefore, Partial Discharge Detection is carried out to power cable and joint thereof and Position Research has great significance and economic worth.
The detection method for local discharge being applied to cable line at present mainly comprises high frequency partial discharge examination method, ultrahigh frequency, supercritical ultrasonics technology, damp oscillatory wave (OWTS) method etc.High frequency partial discharge examination method core component is this baseline ring current sensor (abbreviation Luo-coil) of Kenneth Rogoff, Luo-coil is from the ground wire of cable splice and cable termination or the pulse of cross interconnected line couples high frequency, this detection method chargedly can carry out Partial Discharge Detection, easy to carry, simple operation, but need to detect each cable splice of cable line, terminal, long cable circuit is carried out detecting comparatively time-consuming, effort.Damp oscillatory wave method (OWTS) has now been successfully applied in the Partial Discharge Detection of 10kV twisted polyethylene cable circuit, not yet promotes in the cable line of 35kV and above.Damp oscillatory wave method (OWTS) adopts direct current pressuring method, damp oscillatory wave is produced by quick-make electric loop after voltage reaches preset value, by damp oscillatory wave, cable and the potential defect of joint are effectively excited, and by calculating the incident wave of pulse signal and the mistiming of reflection wave carries out shelf depreciation source electricity.The method can comprise cable body and cable splice etc. to whole piece cable line and carries out Partial Discharge Detection and locate, but direct current pressurization may produce potential hazard to twisted polyethylene cable.In addition, this complete equipment only carries out Partial Discharge Detection, need adopt other a set of equipment when withstand voltage test, and this brings very large inconvenience to withstand voltage with partial discharge test.
Adopt direct current pressurization to have damage and partial discharge detecting system cannot carry out the problem of withstand voltage test to cable for partial discharge detecting system in correlation technique, not yet propose effective solution at present.
Utility model content
Fundamental purpose of the present utility model is to provide a kind of partial discharge detecting system, adopts direct current pressurization to have damage and partial discharge detecting system cannot carry out the problem of withstand voltage test to cable to solve partial discharge detecting system in correlation technique.
To achieve these goals, according to an aspect of the present utility model, a kind of partial discharge detecting system is provided.This partial discharge detecting system comprises: high pressure produces equipment, is connected to tested cable, produces damp oscillatory wave for exciting tested cable; Fault test set, produces equipment connection with high pressure, for carrying out Partial Discharge Detection to tested cable.
Further, high pressure produces equipment and comprises: power circuit, for providing alternating current; Current processing circuits, first end is connected with power circuit, for being square-wave signal by AC conversion; Resonant tank; Exciting transformer, the first end of this exciting transformer is connected with the second end of current processing circuits, and the second end of this exciting transformer is connected with resonant tank.
Further, current processing circuits comprises: rectification circuit, and the first end of this rectification circuit is connected with power circuit, becomes direct current for the AC rectification provided by power circuit; Filter capacitor, is connected with the second end of rectification circuit; Inverter circuit, is connected with filter capacitor.
Further, fault test set comprises: local discharge signal testing circuit, for detecting the local discharge signal that damp oscillatory wave excites the partial discharge position of tested cable to produce; Shelf depreciation positioning circuit, is connected with local discharge signal testing circuit, for locating the partial discharge position of tested cable.
Further, local discharge signal testing circuit comprises: voltage divider, is connected with tested cable, for gathering the voltage signal of damp oscillatory wave; Signal acquisition circuit, is connected with tested cable, for gathering local discharge signal.
Further, signal acquisition circuit comprises: testing circuit, is connected with tested cable, and wherein, this testing circuit comprises detection impedance and high pressure coupling capacitance; Amplifying circuit, the input end of this amplifying circuit is in parallel with detection impedance; Capture card, the input end of this capture card is in parallel with the output terminal of amplifying circuit.
Further, shelf depreciation positioning circuit comprises: industrial computer, and this industrial computer is connected with the output terminal of capture card, for determining the partial discharge position of tested cable.
Further, this partial discharge detecting system also comprises: controller, and the first end of this controller is connected with inverter circuit, and for when the voltage of tested cable reaches predeterminated voltage, this controller controls inverter circuit short circuit.
Further, this partial discharge detecting system also comprises: on-off circuit, and wherein, this on-off circuit at least comprises any one circuit following: chopper switch, is connected with power circuit, powers for controlling power circuit; Main contactor, is connected with current processing circuits; And key switch, be connected with the second end of controller.
Further, the 3rd end of controller is connected with capture card, and for generation of touching signals, wherein, this touching signals is used for triggering collection card and gathers local discharge signal.
By the utility model, adopting high pressure to produce equipment, be connected to tested cable, producing damp oscillatory wave for exciting tested cable; Fault test set, equipment connection is produced with high pressure, for carrying out Partial Discharge Detection to tested cable, solving partial discharge detecting system in correlation technique adopts direct current pressurization to have damage and partial discharge detecting system cannot carry out the problem of withstand voltage test to cable, and then the space charge of tested electric cable stoppage place accumulation under avoiding DC voltage is to the damage of cable insulation, achieves and carry out withstand voltage test in partial discharge detecting system simultaneously.
Accompanying drawing explanation
The accompanying drawing forming a application's part is used to provide further understanding of the present utility model, and schematic description and description of the present utility model, for explaining the utility model, is not formed improper restriction of the present utility model.In the accompanying drawings:
Fig. 1 is the schematic diagram of the partial discharge detecting system according to the utility model embodiment.
Embodiment
It should be noted that, when not conflicting, the embodiment in the application and the feature in embodiment can combine mutually.Below with reference to the accompanying drawings and describe the utility model in detail in conjunction with the embodiments.
Better the utility model is understood in order to make those skilled in the art, below in conjunction with the accompanying drawing in the utility model embodiment, embodiment of the present utility model is clearly and completely described, obviously, described embodiment is only the embodiment of the utility model part, instead of whole embodiments.Based on the embodiment in the utility model, the every other embodiment obtained under those of ordinary skill in the art do not make creative work prerequisite, all should belong to protection domain of the present utility model.
It should be noted that, term " first ", " second " etc. in instructions of the present utility model and claims and above-mentioned accompanying drawing are for distinguishing similar object, and need not be used for describing specific order or precedence.Should be appreciated that the data used like this can be exchanged in the appropriate case, so as embodiment of the present utility model described herein can except here diagram or describe those except order implement.In addition, term " comprises " and " having " and their any distortion, and intention is to cover not exclusive comprising.
The utility model aims to provide a kind of partial discharge detecting system, this system is the principle withstand voltage according to tested cable variable-frequency series-resonance, namely exciting transformer is utilized to excite series resonant tank, regulate the output frequency of frequency-variable controller, make resonant tank generation series resonance, tested voltage cable is the resonance potential of system.After tested cable reaches predetermined trial voltage, closed electronic switch, makes resonant tank short circuit and starts electric discharge, then tested cable producing damped oscillation wave voltage, utilize fault test set to carry out detection and the location of tested cable local discharge simultaneously.
Fig. 1 is the schematic diagram of the partial discharge detecting system according to the utility model embodiment, and as shown in Figure 1, this partial discharge detecting system comprises: high pressure produces equipment 10, fault test set 20, controller 30 and on-off circuit 40.Wherein, high pressure generation equipment 10 comprises: power circuit 101, current processing circuits 102, resonant tank 103 and exciting transformer 104.Fault test set 20 comprises: local discharge signal testing circuit 201 and shelf depreciation positioning circuit 202.
High pressure produces equipment 10, is connected to tested cable, produces damp oscillatory wave for exciting tested cable.
This high pressure produces equipment 10 and specifically comprises: power circuit 101, for providing alternating current; Current processing circuits 102, first end is connected with power circuit, for being square-wave signal by AC conversion; Resonant tank 103; Exciting transformer 104, the first end of this exciting transformer is connected with the second end of current processing circuits, and the second end of this exciting transformer is connected with resonant tank.
The main alternating current providing 380V or 220V to system of power circuit 101, the alternating current that power circuit provides by this partial discharge detecting system is given current processing circuits 102 and is processed.Wherein this current processing circuits 102 specifically comprises: rectification circuit, the first end of this rectification circuit is connected with power circuit 101, the AC rectification be mainly used in power circuit 101 provides becomes direct current, and this rectification circuit arranges thyristor composition by three teams, carries out parallel connection between two after series connection; Filter capacitor, is connected with the second end of rectification circuit, and the direct current that rectification circuit output end exports is charged in jumbo filter capacitor; Inverter circuit, is connected with filter capacitor, and this inverter circuit, via four insulated gate bipolar transistor IGBT composition inverter bridge, makes direct current signal change square-wave signal into.The square-wave signal generated by inverter circuit outputs to resonant tank 103 via exciting transformer 104, and wherein resonant tank 103 is made up of reactor L and tested cable.By regulating the frequency of driving voltage to make resonant tank 103 reach resonant condition, improving driving voltage, thus making the voltage of tested cable reach preset voltage value.When the voltage of tested cable reaches preset voltage value, carry out the detection of partial discharge position.By resonant tank 103 short circuit, tested cable obtains damp oscillatory wave key player on a team voltage.
Fault test set 20, produces equipment 10 with high pressure and is connected, for carrying out Partial Discharge Detection to tested cable.
This fault test set 20 comprises: local discharge signal testing circuit 201, for detecting the local discharge signal that damp oscillatory wave excites the partial discharge position of tested cable to produce; Shelf depreciation positioning circuit 202, is connected with local discharge signal testing circuit, for locating the partial discharge position of tested cable.
Particularly, local discharge signal testing circuit 201 can comprise: voltage divider, is connected with tested cable, for gathering the voltage signal of damp oscillatory wave; Signal acquisition circuit, is connected with tested cable, for gathering local discharge signal.Wherein this signal acquisition circuit can comprise: testing circuit, is connected with tested cable, and wherein, this testing circuit comprises detection impedance and high pressure coupling capacitance; Amplifying circuit, the input end of this amplifying circuit is in parallel with detection impedance, and the local discharge signal being mainly used in testing circuit to collect amplifies; Capture card, the input end of this capture card is in parallel with the output terminal of amplifying circuit, comprises local discharge signal and damp oscillatory wave voltage signal in capture card.
Particularly, shelf depreciation positioning circuit 202 comprises: industrial computer, this industrial computer is connected with the output terminal of capture card, in industrial computer, data analysis calculating is carried out to the signal in capture card, the electric discharge type of local discharge signal and discharge position are judged, is mainly used to the partial discharge position determining tested cable.
Gathering local discharge signal by exchanging damp oscillatory wave after this partial discharge detecting system carries out AC voltage withstand test to tested cable, carrying out data analysis, judging the electric discharge type, abort situation etc. of tested cable local discharge signal.
This partial discharge detecting system also comprises: controller 30, the first end of this controller is connected with inverter circuit, and for when the voltage of tested cable reaches predeterminated voltage, this controller controls inverter circuit short circuit, make resonant tank generation resonance, produce damp oscillatory wave.Wherein, the 3rd end of controller 30 is connected with capture card, and for generation of touching signals, wherein, this touching signals is used for triggering collection card and gathers local discharge signal.When the voltage of tested cable reaches preset voltage value; the first absolutely empty inverter circuit of controller 30; inverter circuit is made to be equivalent to a Closing Switch; thus make resonant tank short circuit; there is resonance; tested voltage is made to produce damp oscillatory wave; this damp oscillatory wave is carried out dividing potential drop by voltage divider; after sampling, filter cartridge protection, the voltage signal of this damp oscillatory wave is sent to controller; send a touching signals to capture card after controller receives this voltage signal, control capture card and start to gather damp oscillatory wave voltage signal.
The all right on-off circuit 40 of this partial discharge detecting system, wherein, this on-off circuit at least comprises any one circuit following: chopper switch, is connected with power circuit 101, powers for controlling power circuit; Main contactor, is connected with current processing circuits; And key switch, be connected with the second end of controller.
Above-mentioned chopper switch is connected with power circuit 101, and when this chopper switch closes, power circuit 101 provides alternating current to partial discharge detecting system, and when this chopper switch disconnects, power circuit 101 can not provide alternating current to partial discharge detecting system.When this chopper switch closes, main contactor produces equipment 10 for controlling high pressure, and when main contactor closes, high pressure produces equipment 10 and works, and regulates the voltage of tested cable.When the voltage of tested cable reaches preset voltage value, there is series resonance in resonant tank 103, and tested cable produces damp oscillatory wave.Key switch is mainly used in controlling controller 30, and when key switch closes, this controller 30 could realize the control to other parts in partial discharge detecting system.When carrying out partial discharge position location, this controller 30 can also to carry out signal mutual with industrial computer.Realize the function such as the setting to some parameters of local discharge signal and the protection to local discharge signal.
Each oscillation period is obtained local discharge signal and is decomposed into phase place associative mode by this partial discharge detecting system, partial discharge inception voltage is obtained by carrying out the mode of pressurizeing step by step to tested cable, partial discharge extinction voltage and local discharging level three parameters, and by statistical treatment and classification, to identify local discharge signal better, the database of measurement of partial discharge finally can be built according to the example of tested cable or annex typical degradation, thus discriminating device aging performance.
Cable local discharge positioning principle under oscillating wave voltage is according to electromagnetic transmission principle of reflection, produce partial discharge pulse to propagate to cable two ends at shelf depreciation place, if place does not have matched impedance at cable socket, partial discharge pulse will reflect in end, the distance of shelf depreciation range observation end can be calculated according to first that measures at measuring junction along the pulse of measuring junction transmission and mistiming of passing measuring junction pulse back after other end reflection, thus orient the part of shelf depreciation.Under oscillating wave voltage, when each oscillation period discharges according to also measure local can measuring electricity amplitude and this discharge pulse through far-end reflection after pulse amplitude, calculate the position of arcing distance measuring junction.
Producing containing more undesired signal in damped oscillation wavefront variable-frequency resonance power source, these undesired signal amplitudes are comparatively large, may be the thyristor stack actions in variable-frequency power sources, and brilliant circle pipe, IGBT switch motion cause generation.Adopt controller to control inverter circuit in the utility model first embodiment to close by after the switch that wherein two IGBT form, the interference of whole power supply reduces to does not affect the level that measurement is put in office, has good effect.
The utility model partial discharge position detection system carries out shelf depreciation Site Detection and location to XLPE cable under based on the damped oscillation wave voltage of frequency conversion resonance vibration, adopt traditional capacitive coupling local discharge signal, by detecting impedance extraction local discharge signal.The advantage of the high q-factor of resonant circuit makes can also measure local to discharge under a series of sinusoidal decay oscillating voltage.Can put measurement to office owing to utilizing frequency conversion resonance vibration voltage to some controllable silicon and switch motions etc. during tested cable charging and bring interference, therefore measurement of partial discharge circuit uses the interference that the on-off circuit quick-make of inverter circuit composition brings to suppress power supply.The frequency range that measurement of partial discharge frequency band selection is recommended according to IEC60270, and when locating, bandwidth rises to 10MHz.Is obtained shelf depreciation information decomposition each oscillation period for being similar to phase place associative mode under power frequency period, and by statistical treatment and classification, to make to identify local discharge signal better, finally can build the database of measurement of partial discharge according to the example of cable or annex typical degradation, with discriminating device aging performance better.
By the utility model, adopting high pressure to produce equipment, be connected to tested cable, producing damp oscillatory wave for exciting tested cable; Fault test set, equipment connection is produced with high pressure, for carrying out Partial Discharge Detection to tested cable, solving partial discharge detecting system in correlation technique adopts direct current pressurization to have damage and partial discharge detecting system cannot carry out the problem of withstand voltage test to cable, and then the space charge of tested electric cable stoppage place accumulation under avoiding DC voltage is to the damage of cable insulation, achieves and carry out withstand voltage test in partial discharge detecting system simultaneously.
According to the utility model embodiment, the principle of work of partial discharge detecting system is described below:
Improve the voltage of tested cable.First this obtain alternating current to the method that tested cable carries out Partial Discharge Detection, and this alternating current is provided by the power circuit of partial discharge detecting system; Then alternating current is processed, comprise and AC rectification is become direct current, direct current is converted to square-wave signal; Above-mentioned square-wave signal is pressurized on tested cable; By the voltage regulating driving voltage to improve tested cable.Wherein, direct current AC rectification is become to be realized by the rectification circuit of partial discharge detecting system, direct current being converted to square-wave signal is realized by the inverter circuit of partial discharge detecting system, regulates driving voltage to be realized by the exciting transformer of partial discharge detecting system.
When the voltage of tested cable reaches preset voltage value, obtain damp oscillatory wave.By regulating the frequency of driving voltage to make resonant tank generation series resonance, improve the voltage of tested cable.When the voltage of tested cable reaches preset voltage value, control controller and inverter circuit is converted into on-off circuit, by this on-off circuit rapid closing, make resonant tank short circuit, tested cable will obtain damp oscillatory wave sinusoidal voltage.
Obtain local discharge signal.Damp oscillatory wave excites the shortcoming point of tested cable to produce local discharge signal, the testing circuit in shelf depreciation system is utilized to obtain the voltage signal of damp oscillatory wave first, this voltage signal is sent to controller, controller sends trigger pip to capture card when receiving voltage signal, and notice capture card starts to gather local discharge signal.Local discharge signal can amplify through amplifying circuit before arriving capture card.
Partial Discharge Detection is carried out according to local discharge signal.Carry out Partial Discharge Detection according to local discharge signal and comprise detection to tested cable local discharge and location.By carrying out the mode of pressurizeing step by step to tested cable, partial discharge inception voltage is obtained to the detection of tested cable local discharge, partial discharge extinction voltage and local discharging level three parameters, and by statistical treatment and classification, to identify local discharge signal better, the database of measurement of partial discharge finally can be built according to the example of tested cable or annex typical degradation, thus discriminating device aging performance.According to electromagnetic transmission principle of reflection to the location of tested cable local discharge, produce partial discharge pulse to propagate to cable two ends at shelf depreciation place, if place does not have matched impedance at cable socket, partial discharge pulse will reflect in end, the distance of shelf depreciation range observation end can be calculated according to first that measures at measuring junction along the pulse of measuring junction transmission and mistiming of passing measuring junction pulse back after other end reflection, thus orient the part of shelf depreciation
The partial discharge detecting system of the utility model embodiment adopts the voltage improving tested cable; When the voltage of tested cable reaches preset voltage value, obtain damp oscillatory wave; Obtain local discharge signal; Partial Discharge Detection is carried out according to local discharge signal, solving when prior art carries out Partial Discharge Detection to tested cable adopts direct current pressurization have damage to cable and cannot carry out the problem of withstand voltage test simultaneously, and then the space charge of tested electric cable stoppage place accumulation under avoiding DC voltage is to the damage of cable insulation, achieves and carry out withstand voltage test in partial discharge detecting system simultaneously.
The foregoing is only preferred embodiment of the present utility model, be not limited to the utility model, for a person skilled in the art, the utility model can have various modifications and variations.All within spirit of the present utility model and principle, any amendment done, equivalent replacement, improvement etc., all should be included within protection domain of the present utility model.
Claims (7)
1. a partial discharge detecting system, is characterized in that, comprising:
High pressure produces equipment, is connected to tested cable, produces damp oscillatory wave for exciting described tested cable; And
Fault test set, produces equipment connection with described high pressure, for carrying out Partial Discharge Detection to described tested cable,
Wherein, described high pressure generation equipment comprises:
Power circuit, for providing alternating current;
Current processing circuits, first end is connected with described power circuit, for being square-wave signal by described AC conversion;
Resonant tank; And
Exciting transformer, the first end of described exciting transformer is connected with the second end of described current processing circuits, and the second end of described exciting transformer is connected with described resonant tank,
Described current processing circuits comprises:
Rectification circuit, the first end of described rectification circuit is connected with described power circuit, becomes direct current for the AC rectification provided by described power circuit;
Filter capacitor, is connected with the second end of described rectification circuit; And
Inverter circuit, is connected with described filter capacitor,
Described fault test set comprises:
Local discharge signal testing circuit, for detecting the local discharge signal that described damp oscillatory wave excites the partial discharge position of described tested cable to produce; And
Shelf depreciation positioning circuit, is connected with described local discharge signal testing circuit, for locating the partial discharge position of described tested cable.
2. partial discharge detecting system according to claim 1, is characterized in that, described local discharge signal testing circuit comprises:
Voltage divider, is connected with described tested cable, for gathering the voltage signal of described damp oscillatory wave; And
Signal acquisition circuit, is connected with described tested cable, for gathering described local discharge signal.
3. partial discharge detecting system according to claim 2, is characterized in that, described signal acquisition circuit comprises:
Testing circuit, is connected with described tested cable, and wherein, described testing circuit comprises detection impedance and high pressure coupling capacitance;
Amplifying circuit, the input end of described amplifying circuit is in parallel with described detection impedance; And
Capture card, the input end of described capture card is in parallel with the output terminal of described amplifying circuit.
4. partial discharge detecting system according to claim 2, is characterized in that, described shelf depreciation positioning circuit comprises:
Industrial computer, described industrial computer is connected with the output terminal of described capture card, for determining the partial discharge position of described tested cable.
5. partial discharge detecting system according to claim 3, is characterized in that, described detection system also comprises:
Controller, the first end of described controller is connected with described inverter circuit, and for when the voltage of described tested cable reaches predeterminated voltage, described controller controls described inverter circuit short circuit.
6. partial discharge detecting system according to claim 5, is characterized in that, described detection system also comprises:
On-off circuit, wherein, described on-off circuit at least comprises any one circuit following:
Chopper switch, is connected with described power circuit, powers for controlling described power circuit;
Main contactor, is connected with described current processing circuits; And
Key switch, is connected with the second end of described controller.
7. partial discharge detecting system according to claim 5, is characterized in that, the 3rd end of described controller is connected with described capture card, and for generation of touching signals, wherein, described touching signals gathers described local discharge signal for triggering described capture card.
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
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CN104965161A (en) * | 2015-05-29 | 2015-10-07 | 广西电网有限责任公司电力科学研究院 | Cable insulation medium spectrum and partial discharge defect detection method and apparatus |
CN105486987A (en) * | 2014-09-19 | 2016-04-13 | 国家电网公司 | Partial discharge detection system |
CN108318785A (en) * | 2017-01-18 | 2018-07-24 | 上海格鲁布科技有限公司 | A kind of humorous pressure-resistant apparatus of cable string having defect location function |
CN110261746A (en) * | 2019-07-08 | 2019-09-20 | 清华大学深圳研究生院 | Electric cable stoppage detection method based on oscillating wave voltage periodic attenuation characteristic |
CN110749809A (en) * | 2019-11-11 | 2020-02-04 | 深圳供电局有限公司 | GIS fault detection device and system |
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2014
- 2014-09-19 CN CN201420543383.2U patent/CN204256111U/en active Active
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105486987A (en) * | 2014-09-19 | 2016-04-13 | 国家电网公司 | Partial discharge detection system |
CN104965161A (en) * | 2015-05-29 | 2015-10-07 | 广西电网有限责任公司电力科学研究院 | Cable insulation medium spectrum and partial discharge defect detection method and apparatus |
CN104965161B (en) * | 2015-05-29 | 2017-11-07 | 广西电网有限责任公司电力科学研究院 | A kind of cable insulation medium spectrum and shelf depreciation defect inspection method and device |
CN108318785A (en) * | 2017-01-18 | 2018-07-24 | 上海格鲁布科技有限公司 | A kind of humorous pressure-resistant apparatus of cable string having defect location function |
CN110261746A (en) * | 2019-07-08 | 2019-09-20 | 清华大学深圳研究生院 | Electric cable stoppage detection method based on oscillating wave voltage periodic attenuation characteristic |
CN110261746B (en) * | 2019-07-08 | 2021-08-24 | 清华大学深圳研究生院 | Cable defect detection method based on periodic attenuation characteristics of oscillating wave voltage |
CN110749809A (en) * | 2019-11-11 | 2020-02-04 | 深圳供电局有限公司 | GIS fault detection device and system |
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