CN203587736U - Overhead distributing line ground fault indicating device based on zero-sequence component method - Google Patents
Overhead distributing line ground fault indicating device based on zero-sequence component method Download PDFInfo
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Abstract
The utility model provides an overhead distributing line ground fault indicating device based on a zero-sequence component method. The overhead distributing line ground fault indicating device comprises an electric pole type fault indicator which is mounted on an electric pole used for erecting a distributing line. The electric pole fault indicator detects local zero-sequence currents and zero-sequence voltages, and after the value of the local zero-sequence currents/zero-sequence voltages reaches a prestored zero-sequence current threshold value/zero-sequence voltage threshold value, one-phase grounding alarm is performed. The overhead distributing line ground fault indicating device is not required to be mounted on the distributing line, and can perform real-time monitoring on the one-phase grounding condition of the distributing line, the position of one-phase grounding faults can be positioned quickly and precisely when line faults happen, and therefore powerful support for quickly removing the faults and restoring power is provided.
Description
Technical field
The utility model relates to power technology field, refers to especially a kind of overhead distribution earth fault indicating device based on zero-sequence component method.
Background technology
Overhead distribution is extensively distributed in the vast region of city and country, and most of networking phase, early ageing equipment was serious, and being easily subject to physical environment disturbs and interference from human factor, therefore in operational process, easily there is singlephase earth fault in circuit, affects circuit normal power supply.Therefore, need a kind of scheme that can detection line generation singlephase earth fault.
Phase-to-ground fault detection of the prior art mainly contains following two kinds of modes:
1, the phase-to-ground fault detection scheme based on momentary signal method, this scheme is mainly that Monitoring Line generation single-phase earthing moment line mutual-ground capacitor discharges and recharges a kind of high-frequency current signal causing, detect indicator and monitor after this characteristic signal, as circuit generation singlephase earth fault according to one of;
2, the phase-to-ground fault detection scheme based on injecting signal, its principle is after circuit generation singlephase earth fault, by a kind of special signal generation apparatus, to 10KV circuit, inject a kind of power frequency pulsed current signal, be generally in 50A, detect pointer detection after this characteristic pulse signal, as its judgement rear end occur singlephase earth fault according to one of.
But above-mentioned two schemes all needs indicator is installed on the line, increased the complicacy that distribution line is installed, can not accurately locate in real time position of failure point.
In sum, need a kind of can location fast the exact position of singlephase earth fault occurs on circuit and without the phase-to-ground fault detection device being arranged on distribution line, to can fix a breakdown in time, restore electricity, improve the reliability of electric power system.
Utility model content
The utility model provides a kind of overhead distribution earth fault indicating device based on zero-sequence component method, be used for solving that prior art phase-to-ground fault detection indicator need to be installed on the line and fault detect is quick not, the problem that localization of fault is not accurate enough.The overhead distribution earth fault indicating device based on zero-sequence component method that the utility model provides not only can carry out Real-Time Monitoring and carry out Rapid Alarm when the fault the singlephase earth fault of overhead distribution, and this device is without being arranged on distribution line, install more easy, in addition, this device can also accurately be located singlephase earth fault position, has improved the reliability of electric power system.
A kind of overhead distribution earth fault indicating device based on zero-sequence component method that the utility model provides, comprises the electric pole formula fault detector being installed on on the electric pole of erecting distribution lines; Described electric pole formula fault detector detects local zero-sequence current and residual voltage, and carries out single-phase earthing warning after the value of described local zero-sequence current/residual voltage reaches pre-stored zero-sequence current threshold value/residual voltage threshold value.
Preferably, described electric pole formula fault detector comprises: circuit measuring zero phase sequence current, zero sequence voltage detection circuit, control module, failure indication module and supply module; The output terminal of described circuit measuring zero phase sequence current is connected with described control module; The output terminal of described zero sequence voltage detection circuit is connected with described control module; Described supply module is connected with described control module; Described failure indication module is connected with described control module; Described circuit measuring zero phase sequence current detects local zero-sequence current and provides it to described control module; Described zero sequence voltage detection circuit detects local residual voltage and provides it to described control module; Described supply module is for powering to described control module; Described control module carries out respectively analog to digital conversion by the described local zero-sequence current receiving and residual voltage, and whether the value that judges the local zero-sequence current/residual voltage of the current digital signal form obtaining reaches predetermined zero-sequence current threshold value/residual voltage threshold value, if so, to described failure indication module, send alarm command; The alarm command that described failure indication module is sent according to described control module carries out local single-phase grounding alarm.
Preferably, described circuit measuring zero phase sequence current comprises zero sequence current sensor and zero-sequence current amplifying circuit; The current output terminal of described zero sequence current sensor connects the current input terminal of described zero-sequence current amplifying circuit; Described zero sequence current sensor is used for responding to local zero-sequence current, obtains the induction current that a value is directly proportional to local zero-sequence current value; Described zero-sequence current amplifying circuit offers described control module after the induction current of described zero sequence current sensor output is zoomed into local zero-sequence current.
Preferably, described zero sequence current sensor is: by high permeability material, as iron core, and on described iron core, be wound with enameled wire coiling.
Preferably, described zero sequence voltage detection circuit comprises aluminium sheet, the first resistance, the second resistance and residual voltage amplifying circuit; Described aluminium sheet is parallel to ground and arranges; Described the first resistance is connected described aluminium sheet, other end ground connection with one end after the second resistance series connection; Two voltage input ends of described residual voltage amplifying circuit are connected to described the first resistance two ends, described residual voltage amplifying circuit is used for measuring the voltage at described the first resistance two ends and being enlarged into local residual voltage, and described local residual voltage is offered to described control module.
Preferably, the shell of described electric pole formula fault detector is iron-clad, and one end of described the first resistance and the series circuit of the second resistance is connected described aluminium sheet, and the other end is by the earthing of casing of described electric pole formula fault detector.
Preferably, described supply module comprises electricity-fetching module and the energy-storage module of mutual electrical connection; Described electricity-fetching module comprises solar power generation unit and/or wind power generation unit and/or line of electric force power taking unit, and described electricity-fetching module is used for obtaining electric energy and provides it to described energy-storage module; Described energy-storage module is also connected with described control module, and the electric energy that described energy-storage module is used for storing described electricity-fetching module and provides is also described control module power supply.
Preferably, described energy-storage module comprises super capacitor and/or lead-acid battery and/or lithium battery.
Preferably, above-mentioned any overhead distribution earth fault indicating device based on zero-sequence component method is for high 12 meters and for setting up the electric pole of 10KV distribution line, and described electric pole formula fault detector is 4~6 meters apart from the height on ground.
Preferably, above-mentioned any overhead distribution earth fault indicating device based on zero-sequence component method also comprises Surveillance center, and described electric pole formula fault detector also comprises the communication module being connected with described control module, described Surveillance center by network be arranged in several of same electrical network described in the communication module of electric pole formula fault detector be connected, control module described in each in electric pole formula fault detector is also for sending to described Surveillance center by the value of the local zero-sequence current of the current digital signal form obtaining by described communication module, and if described control module is after testing and judge circuit generation singlephase earth fault, described control module simultaneously also by local communication module notify described Surveillance center this locality single-phase earthing report to the police, the circuit that described Surveillance center forms for all electric pole formula fault detectors that current single-phase earthing is reported to the police is as alarm circuit, if the adjacent electric pole formula fault detector in rear away from last the electric pole formula fault detector that single-phase earthing has been reported to the police in transformer station's direction on described alarm circuit does not carry out single-phase earthing warning, and the zero-sequence current recording away from last the electric pole formula fault detector that single-phase earthing has been reported to the police in transformer station's direction on described alarm circuit is greater than the zero-sequence current that the adjacent electric pole formula fault detector in its rear records, described Surveillance center by described alarm circuit away from being defined as single-phase grounding fault point position between the electric pole formula fault detector adjacent with its rear of last the electric pole formula fault detector that single-phase earthing has been reported to the police in transformer station's direction.
Preferably, described in each the control module in electric pole formula fault detector also for the value of the local residual voltage of the current digital signal form obtaining is sent to described Surveillance center by described communication module; All zero-sequence currents that the storage of described Surveillance center is received and the value of residual voltage, and to described control module, send new zero-sequence current threshold value and new residual voltage threshold value by described communication module; Described control module is also for upgrading self pre-stored zero-sequence current threshold value and residual voltage threshold value according to the current new zero-sequence current threshold value of receiving and new residual voltage threshold value.。
The overhead distribution earth fault indicating device based on zero-sequence component method that the utility model provides only need be arranged on the electric pole for erecting distribution lines, install more easy, this device detects zero-sequence current value and the residual voltage value of circuit on the local electric pole of flowing through based on zero-sequence component method, as long as report to the police at once when local zero-sequence current value/residual voltage value reaches rule of thumb pre-stored zero-sequence current threshold value/residual voltage threshold value, therefore can carry out Real-Time Monitoring to the singlephase earth fault of overhead distribution, and when appearring in distribution line, singlephase earth fault carries out Rapid Alarm.In addition, Surveillance center accurately locates singlephase earth fault position after adding up according to the residual voltage value at each electric pole place of recording, therefore can make managerial personnel in time, fix a breakdown exactly, has improved the reliability of electric power system.
Accompanying drawing explanation
Fig. 1 is zero-sequence component method schematic diagram;
The structural representation of a kind of overhead distribution earth fault indicating device based on zero-sequence component method that Fig. 2 provides for the utility model embodiment;
The structural representation of the overhead distribution earth fault indicating device of the another kind that Fig. 3 provides for the utility model embodiment based on zero-sequence component method;
The structural representation of the overhead distribution earth fault indicating device of the another kind that Fig. 4 provides for the utility model embodiment based on zero-sequence component method;
The structural representation of the overhead distribution earth fault indicating device of the another kind that Fig. 5 provides for the utility model embodiment based on zero-sequence component method;
Fig. 6 implements installation site on electric pole of a kind of electric pole formula fault detector provide and the location diagram between wire for the utility model;
The structural representation of the overhead distribution earth fault indicating device of the another kind that Fig. 7 provides for the utility model embodiment based on zero-sequence component method;
Fig. 8 is a specific embodiment of Fig. 7 shown device.
Embodiment
For finding in time and solve overhand lines earth fault problem, the utility model has proposed a kind of overhead distribution earth fault indicating device based on zero-sequence component method, for making the explanation of the utility model specific embodiment clearer, the zero-sequence component method first the utility model being adopted is below introduced.
At present, the power distribution network of China most areas is all the small current neutral grounding systems such as isolated neutral system, compensated distribution network, be characterized in that circuit only has A, B, C three-phase, there is no the neutral line, voltage between phases is 10KV, and between phase line and the earth, voltage is 5.7KV not occurring under the state of ground connection.In unearthed situation, three-phase current I
a, I
b, I
cvector and three phase-to-ground voltage U
a0, U
b0, U
c0vector be zero.After there is singlephase earth fault, voltage between phases is still 10KV, but the voltage between phase line and the earth changes, Earth Phase voltage-to-ground is zero, unearthed phase-to-ground voltage is 10KV, has produced thus residual voltage, and the vector of three-phase current is non-vanishing simultaneously, different according to line length, there is different zero-sequence current values.
While there is singlephase earth fault, before and after trouble spot, zero-sequence current value has very big difference, and its principle as shown in Figure 1.China electricity grid substation 10KV at present generally can be with 7~15 10KV outlets at present, in Fig. 1, for convenience of expression, three outlets have only been drawn, for convenience of description, that three-phase outlet of upside in Fig. 1 is called to circuit one, that of medial side three-phase outlet is called circuit two, and that three-phase outlet of lower side is called circuit n.Fig. 1 combined circuit principle can analyze: when circuit two occurs after A phase single-phase earthing, all 10KV outlets all there will be zero-sequence current, but the zero-sequence current value size that different circuits and diverse location measure differs greatly.For non-fault line, i.e. circuit in Fig. 1 one, the zero-sequence current of whole piece circuit is (I
c1+ I
b1), on circuit one arbitrary position probing to zero-sequence current be the capacitance current sum of this outlet.For the circuit two that singlephase earth fault occurs, after trouble spot, the zero-sequence current of (trouble spot away from transformer station's 19 1 sides) is (I
c2+ I
b2), but the zero-sequence current I of (close transformer station 19 sides of trouble spot) before trouble spot
dbe the zero-sequence current sum of all circuits, be:
I
D=(I
b1+I
c1)+(I
b2+I
c2)+(I
b3+I
c3)+...+(I
bn+I
cn) (1)
In formula (1), (I
c1+ I
b1) be the zero-sequence current value of the circuit one in Fig. 1, (I
c2+ I
b2) be the zero-sequence current value after trouble spot in circuit two in Fig. 1, (I
bn+ I
cn) be the zero-sequence current value of the unshowned n bar that other do not break down (n is more than or equal to 3 positive integer) outlet in Fig. 1.
As seen from the above analysis, the zero-sequence current value before Single-phase Ground Connection Failure is much larger than the zero-sequence current value behind trouble spot.Especially more when the outlet of substation bus bar, circuit is longer, and the zero-sequence current value that can detect before trouble spot is larger.The utility model is exactly that circuit has produced residual voltage and zero-sequence current according to occurring after singlephase earth fault, and before and after trouble spot, zero-sequence current value has this characteristic feature of very large difference to carry out indicating fault and location.
For making the technical problems to be solved in the utility model, technical scheme and advantage clearer, below in conjunction with accompanying drawing, specific embodiment of the utility model is described in detail.
Thought of the present utility model is: an electric pole formula fault detector is set on each electric pole for erecting distribution lines on distribution line, for detection of local zero-sequence current and residual voltage, and after reaching pre-stored zero-sequence current threshold value/residual voltage threshold value, the value of the local zero-sequence current/residual voltage detecting carries out single-phase earthing warning.That is: rule of thumb in each electric pole formula fault detector, store zero-sequence current threshold value and residual voltage threshold value in advance, before circuit generation singlephase earth fault, residual voltage and zero-sequence current that each electric pole formula fault detector detects are 0, and after circuit generation singlephase earth fault, electric pole formula fault detector on every electric pole on whole distribution line all can detect residual voltage and/or zero-sequence current value, especially the zero-sequence current before Single-phase Ground Connection Failure is much larger than the zero-sequence current behind trouble spot, therefore, when there is singlephase earth fault, the value of zero-sequence current/residual voltage that the electric pole formula fault detector before trouble spot detects can meet or exceed zero-sequence current threshold value/residual voltage threshold value, therefore single-phase earthing can occur reports to the police, and the value of the zero-sequence current/residual voltage detecting due to the electric pole formula fault detector behind trouble spot is less than zero-sequence current threshold value/residual voltage threshold value, therefore do not produce warning, can monitor thus the singlephase earth fault situation of whole distribution line, and locate fast abort situation.
Preferably, as shown in Figure 2, the electric pole formula fault detector in the overhead distribution earth fault indicating device based on zero-sequence component method that the utility model embodiment provides comprises: circuit measuring zero phase sequence current 1, zero sequence voltage detection circuit 2, control module 3, failure indication module 4 and supply module 5.Wherein, control module comprises the first analog to digital conversion interface and the second analog to digital conversion interface, and the output terminal of circuit measuring zero phase sequence current 1 is connected with the first analog to digital conversion interface of control module 3; The output terminal of zero sequence voltage detection circuit 2 is connected with the second analog to digital conversion interface of control module 3; Supply module 5 is connected with control module 3; Failure indication module 4 is connected with control module 3.Circuit measuring zero phase sequence current 1 detects local zero-sequence current and provides it to control module 3.Zero sequence voltage detection circuit 2 detects local residual voltage and provides it to control module 3.Supply module 5 is for giving control module 3 power supplies.Control module 3 by chips such as single-chip microcomputer, DSP as main control chip, gather the first analog to digital conversion interface (not shown) and the zero-sequence current of the second analog to digital conversion interface (not shown) acquisition and the value of residual voltage and it is carried out respectively to analog to digital conversion, and whether the value that judges the local zero-sequence current/residual voltage of the current digital signal form obtaining reaches predetermined zero-sequence current threshold value/residual voltage threshold value, if so, to failure indication module 4, send alarm command.The alarm command that failure indication module 4 is sent according to control module 3 carries out local single-phase grounding alarm.
Preferably, as shown in Figure 3, the circuit measuring zero phase sequence current 1 in Fig. 2 comprises zero sequence current sensor 6 and zero-sequence current amplifying circuit 7.Two current output terminals of zero sequence current sensor 1 are connected with two current input terminals of zero-sequence current amplifying circuit 7 respectively.Wherein, zero sequence current sensor 6 is the local zero-sequence current through local electric pole top distribution line for induced flow, obtains the induction current that a value is directly proportional to local zero-sequence current value; Zero-sequence current amplifying circuit zooms into local zero-sequence current by the induction current of zero sequence current sensor 6 outputs subsequently, and local zero-sequence current is offered to control module 3.
In Fig. 3, the specific works principle of zero sequence current sensor 6 is: three-phase line A, the B, the C difference current flowing I that suppose local electric pole top
a, I
b, I
c, according to Faradic electricity magnetic induction principle, the zero sequence current sensor 6 in the electric pole formula fault detector of installing on local electric pole detects respectively the magnetic field of three electric currents, and its size is ki * I respectively
a/ L
a, ik * I
b/ L
b, ki * I
c/ L
c, wherein ki is a scale-up factor of electric current and magnetic field intensity, L
a, L
b, L
cbe respectively the air line distance of the electric pole formula fault detector of installing on three-phase line A, B, C and the local electric pole of local electric pole top.The induction current I that zero sequence current sensor 6 in the electric pole formula fault detector of installing on local electric pole senses can be calculated as follows:
I=ki×I
a/L
a+ki×I
b/L
b+ki×I
c/L
c (2)
Because the height of electric pole generally is more than ten meter, and spacing between three-phase line A, B, C is all a centimetre magnitude, therefore, and L
a, L
b, L
ccan think approximately equal, therefore, formula (2) can be reduced to:
I=ki×(I
a+I
b+I
c)/L
a (3)
In formula (3), I
a+ I
b+ I
cbe local zero-sequence current value, L
afor certain value, ki is definite value, obviously, and the induction current I that zero sequence current sensor 6 senses and local zero-sequence current relation in direct ratio.Due to when there is not singlephase earth fault, three-phase current sum is zero, so the induction current I=0 that senses of zero sequence current sensor 6, and after there is singlephase earth fault, I
a+ I
b+ I
cbe not equal to zero, so zero sequence current sensor 6 can detect electric current, and zero-sequence current is larger, the induction current I that zero sequence current sensor 6 detects is also larger.
Preferably, the high permeability material such as the zero sequence current sensor shown in Fig. 3 is amorphous alloy is as iron core, and on iron core, is wound with the zero sequence current sensor of enamel wire coil.
Preferably, as shown in Figure 4, the zero sequence voltage detection circuit 2 in Fig. 2 comprises aluminium sheet 8, the first resistance 9, the second resistance 10 and residual voltage amplifying circuit 11.Aluminium sheet 8 is parallel to ground and arranges; The first resistance 9 is connected aluminium sheet 8, other end ground connection with one end after the second resistance 10 series connection; Two voltage input ends of residual voltage amplifying circuit 11 are connected to the two ends of the first resistance 9, for measuring the voltage at the first resistance 9 two ends and being enlarged into local residual voltage, and local residual voltage are offered to control module 3.Obviously, the voltage that residual voltage amplifying circuit also can be by the second resistance 10 two ends in survey sheet 3 herein is also enlarged into local residual voltage.
The principle of work of the zero sequence voltage detection circuit 2 shown in Fig. 4 is: suppose that the three-phase line voltage-to-ground on local electric pole is U
a0, U
b0, U
c0, according to Faradic electricity magnetic induction principle, high-pressure conductor can produce alternating electric field around, and far away apart from conductor, electric field intensity is lower.Medium between circuit and the earth is air, can be equivalent to the electric capacity of a large amount of distributions, and the distributed capacitance between high-voltage conducting wires and the earth can flow through and small discharge current.Because electric pole formula fault detector is arranged on the position in the middle of high-voltage conducting wires and the earth, and wherein there is an aluminium sheet 8 that is parallel to ground, therefore aluminium sheet 8 can be regarded electrode as, this electrode is due in the middle of an electric field, between this electrode and the earth, also can produce electric potential difference, its electromotive force E can be calculated as follows:
E=ku×U
a0/L
a+ku×U
b0/L
b+ku×U
c0/L
c (4)
In formula (4), ku is fixed proportion coefficient, L
a, L
b, L
cthe air line distance that is respectively the electric pole formula fault detector of installing on three-phase line A, B, C and the local electric pole of local electric pole top, is similar to the derivation of formula (3), and when the height of electric pole is during much larger than spacing between three-phase line, above formula can be reduced to:
E=ku×(U
a0+U
b0+U
c0)/L
a (5)
In formula (5), U
a0+ U
b0+ U
c0be local residual voltage value, L
afor certain value, ku is definite value, that is to say, electric potential difference E between aluminium sheet and the earth and the residual voltage of local three-phase conducting wire relation in direct ratio, when circuit is normal, residual voltage is zero, so E=0, after circuit generation singlephase earth fault, residual voltage is non-vanishing, and E is also non-vanishing, now current flowing in the series circuit of the first resistance 9 and the second resistance 10, on the first resistance 9, produce voltage, the scale-up factor that residual voltage amplifying circuit 11 can calculate this voltage according to circuit theory is subsequently enlarged into local residual voltage.
Preferably, the shell of the electric pole formula fault detector shown in Fig. 4 is iron-clad, and one end of the first resistance 9 and the series circuit of the second resistance 10 is connected described aluminium sheet, and the other end is by the earthing of casing of this electric pole formula fault detector.
Preferably, as shown in Figure 5, the supply module 5 in Fig. 2 comprises electricity-fetching module 12 and the energy-storage module 13 of mutual electrical connection.Wherein, electricity-fetching module 12 is for obtaining electric energy and providing it to energy-storage module 13; Energy-storage module 13 is also connected with control module 3, for storing the electric energy that electricity-fetching module 12 provides and being control module 3 power supplies.Electricity-fetching module 12 comprises solar power generation unit and/or wind power generation unit and/or line of electric force power taking unit.Line of electric force power taking unit is by power taking on the line of electric force of current coupling mode from local electric pole.Preferably, energy-storage module 13 comprises that super capacitor and/or lead-acid battery and/or lithium battery etc. have the parts of electric power storage ability.
Preferably, as shown in Figure 6, wherein the direction of three-phase conducting wire A, B, C is vertical paper direction for the installation site of electric pole formula fault detector on electric pole and the position relationship between wire.10KV line wires bar height is 12 meters, and electric pole formula fault detector 14 is 4~6m apart from the height on ground, and electric pole formula fault detector 14 is 6~8m from the distance of wire.Three-phase conducting wire is horizontal, and mutual spacing is 0.7m.Because electric pole formula fault detector 14 is greater than three-phase conducting wire and mutual spacing from the distance of wire, therefore can be similar to and think that the distance of every three-phase conducting wire A, B, C and electric pole formula fault detector 14 is approximately equalised, formula noted earlier (3) and (5) are available.
Figure 7 shows that another kind that the utility model embodiment the provides overhead distribution earth fault indicating device structural representation based on zero-sequence component method, except electric pole formula fault detector 14, this device also comprises Surveillance center 15, and described electric pole formula fault detector 14 also comprises the communication module 16 being connected with control module 3.Surveillance center 15 is connected with the communication module 16 that is arranged in several electric pole formula fault detectors 14 of same electrical network by network.Control module 3 in each electric pole formula fault detector 14 is also for sending to Surveillance center 15 by the local zero-sequence current value of the current digital signal form obtaining by local communication module 16, in addition, if control module 3 has sent alarm command (even described control module after testing and judge circuit generation singlephase earth fault) to failure indication module 4, control module 3 is also reported to the police by communication module 16 notice Surveillance center 15 this locality single-phase earthing simultaneously; The distribution situation of the electric pole formula fault detector that the zero-sequence current value that Surveillance center 15 provides according to current all electric pole formula fault detectors 14 of receiving and current single-phase earthing are reported to the police is determined concrete Single-phase Ground Connection Failure, so that user knows in time Single-phase Ground Connection Failure and it is keeped in repair, further improved the reliability of distribution line.Particularly, the circuit that all electric pole formula fault detectors 14 that Surveillance center 15 reports to the police current single-phase earthing form is as alarm circuit, if the adjacent electric pole formula fault detector 14 in rear away from last the electric pole formula fault detector 14 that single-phase earthing has been reported to the police in transformer station's direction on described alarm circuit does not carry out single-phase earthing warning, and the zero-sequence current recording away from last the electric pole formula fault detector 14 that single-phase earthing has been reported to the police in transformer station's direction on described alarm circuit is obviously greater than the zero-sequence current that the adjacent electric pole formula fault detector 14 in its rear records, Surveillance center 15 by described alarm circuit away from being defined as single-phase grounding fault point position between the electric pole formula fault detector 14 adjacent with its rear of last the electric pole formula fault detector 14 that single-phase earthing has been reported to the police in transformer station's direction.
For example Figure 8 shows that a specific embodiment of Fig. 7 shown device, wherein show in three-phase bus A, B, the C(figure of transformer substation side shown in the upper left corner) and two groups of outlets, the electric pole formula fault detector 14 that the utility model embodiment provides has been installed respectively on electric pole 21~27, and each fault detector Jun Yu Surveillance center 15 connects by GPRS network.When there is single-line ground fault between electric pole 26 and electric pole 27, electric pole 21 from earth point to transformer substation side, the electric pole formula fault detector 14 of installing on electric pole 25 and electric pole 26 all can detect larger zero-sequence current, and the electric pole 27 after earth point and the electric pole formula fault detector 14 that does not occur to install on the electric pole 22~24 in the outlet of ground connection all can only detect less zero-sequence current, therefore, final electric pole 21, the electric pole formula fault detector 14Hui Xiang Surveillance center 15 of installing on electric pole 25 and electric pole 26 uploads larger zero-sequence current value and the single-phase earthing alert notice recording, and all the other electric pole formula fault detector 14 Ze Buhuixiang Surveillance center 15 upload single-phase earthing alert notice, just upload less zero-sequence current value.Zero-sequence current and single-phase earthing alert notice that Surveillance center 15 uploads according to each electric pole formula fault detector 14 of receiving, using electric pole 21, electric pole 25 and electric pole 26 circuit of living in as alarm circuit, because last electric pole formula fault detector 14 on this alarm circuit is positioned at residual voltage that the electric pole formula fault detector 14 on electric pole 26 records much larger than the measured zero-sequence current of its rear electric pole 27, so Surveillance center 15 will be defined as single-phase grounding fault point position between electric pole 26 and electric pole 27.
Preferably, in Fig. 7 shown device, the control module 3 described in each in electric pole formula fault detector 14 is also for sending to Surveillance center 15 by the value of the local residual voltage of the current digital signal form obtaining by communication module 16; All zero-sequence currents that Surveillance center's 15 storages are received and the value of residual voltage, make managerial personnel to reset new zero-sequence current threshold value and new residual voltage threshold value according to historical data, Surveillance center 15 sends the newly-installed new zero-sequence current threshold value of managerial personnel and new residual voltage threshold value by described communication module to described control module; Control module 3 upgrades self pre-stored zero-sequence current threshold value and residual voltage threshold value during also for the new zero-sequence current threshold value receiving and new residual voltage threshold value.
The overhead distribution earth fault indicating device based on zero-sequence component method that the utility model provides only need be arranged on the electric pole for erecting distribution lines, install more easy, this device detects zero-sequence current value and the residual voltage value of circuit on the local electric pole of flowing through based on zero-sequence component method, as long as report to the police at once when local zero-sequence current value/residual voltage value reaches rule of thumb pre-stored zero-sequence current threshold value/residual voltage threshold value, therefore can carry out Real-Time Monitoring to the earth fault of overhead distribution, when appearring in distribution line, singlephase earth fault carries out Rapid Alarm.In addition, Surveillance center accurately locates singlephase earth fault position after adding up according to the residual voltage value at each electric pole place of recording, therefore can make managerial personnel in time, fix a breakdown exactly, has improved the reliability of electric power system.
The above is preferred implementation of the present utility model; should be understood that; for those skilled in the art; do not departing under the prerequisite of principle described in the utility model; can also make some improvements and modifications, these improvements and modifications also should be considered as protection domain of the present utility model.
Claims (11)
1. the overhead distribution earth fault indicating device based on zero-sequence component method, is characterized in that, comprises the electric pole formula fault detector being installed on on the electric pole of erecting distribution lines; Described electric pole formula fault detector detects local zero-sequence current and residual voltage, and carries out single-phase earthing warning after the value of described local zero-sequence current/residual voltage reaches pre-stored zero-sequence current threshold value/residual voltage threshold value.
2. a kind of overhead distribution earth fault indicating device based on zero-sequence component method according to claim 1, it is characterized in that, described electric pole formula fault detector comprises: circuit measuring zero phase sequence current, zero sequence voltage detection circuit, control module, failure indication module and supply module; The output terminal of described circuit measuring zero phase sequence current is connected with described control module; The output terminal of described zero sequence voltage detection circuit is connected with described control module; Described supply module is connected with described control module; Described failure indication module is connected with described control module;
Described circuit measuring zero phase sequence current detects local zero-sequence current and provides it to described control module;
Described zero sequence voltage detection circuit detects local residual voltage and provides it to described control module;
Described supply module is for powering to described control module;
Described control module carries out respectively analog to digital conversion by the described local zero-sequence current receiving and residual voltage, and whether the value that judges the local zero-sequence current/residual voltage of the current digital signal form obtaining reaches predetermined zero-sequence current threshold value/residual voltage threshold value, if so, to described failure indication module, send alarm command;
The alarm command that described failure indication module is sent according to described control module carries out local single-phase grounding alarm.
3. a kind of overhead distribution earth fault indicating device based on zero-sequence component method according to claim 2, is characterized in that, described circuit measuring zero phase sequence current comprises zero sequence current sensor and zero-sequence current amplifying circuit; The current output terminal of described zero sequence current sensor connects the current input terminal of described zero-sequence current amplifying circuit;
Described zero sequence current sensor is used for responding to local zero-sequence current, obtains the induction current that a value is directly proportional to local zero-sequence current value;
Described zero-sequence current amplifying circuit offers described control module after the induction current of described zero sequence current sensor output is zoomed into local zero-sequence current.
4. a kind of overhead distribution earth fault indicating device based on zero-sequence component method according to claim 3, is characterized in that, described zero sequence current sensor is: by high permeability material, as iron core, and be wound with enamel wire coil on described iron core.
5. a kind of overhead distribution earth fault indicating device based on zero-sequence component method according to claim 2, is characterized in that, described zero sequence voltage detection circuit comprises aluminium sheet, the first resistance, the second resistance and residual voltage amplifying circuit; Described aluminium sheet is parallel to ground and arranges; Described the first resistance is connected described aluminium sheet, other end ground connection with one end after the second resistance series connection; Two voltage input ends of described residual voltage amplifying circuit are connected to described the first resistance two ends, described residual voltage amplifying circuit is used for measuring the voltage at described the first resistance two ends and being enlarged into local residual voltage, and described local residual voltage is offered to described control module.
6. a kind of overhead distribution earth fault indicating device based on zero-sequence component method according to claim 5, it is characterized in that, the shell of described electric pole formula fault detector is iron-clad, one end of described the first resistance and the series circuit of the second resistance is connected described aluminium sheet, and the other end is by the earthing of casing of described electric pole formula fault detector.
7. a kind of overhead distribution earth fault indicating device based on zero-sequence component method according to claim 2, is characterized in that, described supply module comprises electricity-fetching module and the energy-storage module of mutual electrical connection;
Described electricity-fetching module comprises solar power generation unit and/or wind power generation unit and/or line of electric force power taking unit, and described electricity-fetching module is used for obtaining electric energy and provides it to described energy-storage module;
Described energy-storage module is also connected with described control module, and the electric energy that described energy-storage module is used for storing described electricity-fetching module and provides is also described control module power supply.
8. a kind of overhead distribution earth fault indicating device based on zero-sequence component method according to claim 7, is characterized in that, described energy-storage module comprises super capacitor and/or lead-acid battery and/or lithium battery.
9. according to a kind of overhead distribution earth fault indicating device based on zero-sequence component method described in claim 1 to 8 any one, it is characterized in that, described electric pole is high 12 meters, for setting up 10KV distribution line; Described electric pole formula fault detector is 4~6 meters apart from the height on ground.
10. according to a kind of overhead distribution earth fault indicating device based on zero-sequence component method described in claim 2 to 8 any one, it is characterized in that, this device also comprises Surveillance center, and described electric pole formula fault detector also comprises the communication module being connected with described control module; Described Surveillance center by network be arranged in several of same electrical network described in the communication module of electric pole formula fault detector be connected;
Control module described in each in electric pole formula fault detector is also for sending to described Surveillance center by the value of the local zero-sequence current of the current digital signal form obtaining by described communication module, and if described control module is after testing and judge local line generation singlephase earth fault, described control module simultaneously also by local communication module notify described Surveillance center this locality single-phase earthing report to the police;
The circuit that described Surveillance center forms for all electric pole formula fault detectors that current single-phase earthing is reported to the police is as alarm circuit, if the adjacent electric pole formula fault detector in rear away from last the electric pole formula fault detector that single-phase earthing has been reported to the police in transformer station's direction on described alarm circuit does not carry out single-phase earthing warning, and the zero-sequence current recording away from last the electric pole formula fault detector that single-phase earthing has been reported to the police in transformer station's direction on described alarm circuit is greater than the zero-sequence current that the adjacent electric pole formula fault detector in its rear records, described Surveillance center by described alarm circuit away from being defined as single-phase grounding fault point position between the electric pole formula fault detector adjacent with its rear of last the electric pole formula fault detector that single-phase earthing has been reported to the police in transformer station's direction.
11. a kind of overhead distribution earth fault indicating devices based on zero-sequence component method according to claim 10, it is characterized in that, the control module described in each in electric pole formula fault detector is also for sending to described Surveillance center by the value of the local residual voltage of the current digital signal form obtaining by described communication module;
All zero-sequence currents that the storage of described Surveillance center is received and the value of residual voltage, and to described control module, send new zero-sequence current threshold value and new residual voltage threshold value by described communication module; Described control module is also for upgrading self pre-stored zero-sequence current threshold value and residual voltage threshold value according to the current new zero-sequence current threshold value of receiving and new residual voltage threshold value.
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| CN201320624173.1U CN203587736U (en) | 2013-10-10 | 2013-10-10 | Overhead distributing line ground fault indicating device based on zero-sequence component method |
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| CN201320624173.1U CN203587736U (en) | 2013-10-10 | 2013-10-10 | Overhead distributing line ground fault indicating device based on zero-sequence component method |
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Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103487725A (en) * | 2013-10-10 | 2014-01-01 | 北京三杰网联科技有限公司 | Overhead distributing line ground fault indicating device based on zero-sequence component method |
| CN105425114A (en) * | 2015-12-22 | 2016-03-23 | 中国神华能源股份有限公司 | Method and device for detection of circuit fault in contact net |
| CN106646126A (en) * | 2016-12-09 | 2017-05-10 | 国网北京市电力公司 | Method, device and system for locating fault |
| CN119891093A (en) * | 2025-03-26 | 2025-04-25 | 川开电气有限公司 | Grounding protection method for low-voltage side of photovoltaic booster type box |
-
2013
- 2013-10-10 CN CN201320624173.1U patent/CN203587736U/en not_active Expired - Lifetime
Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103487725A (en) * | 2013-10-10 | 2014-01-01 | 北京三杰网联科技有限公司 | Overhead distributing line ground fault indicating device based on zero-sequence component method |
| CN103487725B (en) * | 2013-10-10 | 2015-12-02 | 北京三杰网联科技有限公司 | A kind of overhead distribution earth fault indicating device based on zero-sequence component method |
| CN105425114A (en) * | 2015-12-22 | 2016-03-23 | 中国神华能源股份有限公司 | Method and device for detection of circuit fault in contact net |
| CN106646126A (en) * | 2016-12-09 | 2017-05-10 | 国网北京市电力公司 | Method, device and system for locating fault |
| CN119891093A (en) * | 2025-03-26 | 2025-04-25 | 川开电气有限公司 | Grounding protection method for low-voltage side of photovoltaic booster type box |
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