CN208571622U - A kind of fault processing system of Multi-end flexible direct current transmission route - Google Patents
A kind of fault processing system of Multi-end flexible direct current transmission route Download PDFInfo
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- CN208571622U CN208571622U CN201821030563.5U CN201821030563U CN208571622U CN 208571622 U CN208571622 U CN 208571622U CN 201821030563 U CN201821030563 U CN 201821030563U CN 208571622 U CN208571622 U CN 208571622U
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- Y—GENERAL 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
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- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/60—Arrangements for transfer of electric power between AC networks or generators via a high voltage DC link [HVCD]
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Abstract
The utility model relates to flexible direct current export technique fields, more particularly to a kind of fault processing system of Multi-end flexible direct current transmission route, the system includes the high voltage DC breaker for being connected to each output end of flexible direct current converter station, it further include the current-limiting inductance being connected between flexible direct current converter station output end and high voltage DC breaker and energy dissipation circuit, the current-limiting inductance is in parallel with energy dissipation circuit, and current-limiting inductance is used for fault current limiting;Energy of the energy dissipation circuit for the fault current that dissipates.By using the utility model, following effect may be implemented: current-limiting inductance preferably inhibits fault current peak value, and cuts down the fault current rate of climb, and can reduce failure removal to high voltage DC breaker Breaking capacity and the requirement for cut-offfing speed;The energy of metal oxide arrester MOA in energy-absorbing resistance and high voltage DC breaker dissipation fault current jointly, can be extinguished with acceleration disturbance electric current, to improve Fault Isolation speed.
Description
Technical field
The utility model relates to flexible direct current export technique field more particularly to a kind of Multi-end flexible direct current transmission routes
Fault processing system.
Background technique
Multi-end flexible direct current transmission system can be separately adjustable to the progress of active and reactive power, has in fields such as new energy
Have wide practical use.However, since Multi-end flexible direct current transmission system DC side is in low impedance characteristic, the event of DC line
Barrier current peak is big and the rate of climb is fast.Compared with the conventional high-tension DC transmission system based on line commutation inverter, multiterminal
Flexible HVDC transmission system lacks current limiting low-voltage function, and great fault current is easy so that converter and line insulation damage
It is bad.Meanwhile the Breaking capacity of high voltage DC breaker and cut-off underspeed at present, be unable to satisfy multiterminal flexible direct current system therefore
Hinder the requirement of excision.
It is that fault current limiting can be by increasing in converter station submodule at present in Multi-end flexible direct current transmission system
Bonus point stream or current limliting module, but the method for increasing auxiliary circuit inhibits fault current to a certain extent, reduces device damage
It is bad, the safety of system is improved, but thorough isolated fault is difficult to using single circuit, generally required by the open circuit of exchange side
Device, and then lead to system shutdown.Another current limliting means is exactly the inverter that exploitation has novel topological structure, but this kind of increasing
The complexity for having added system structure and control is unfavorable for multiterminal flexible direct current system and thinks complicated DC grid extension.
Notification number is the patent of invention of CN 106300309A, discloses a kind of flexible direct current with fast restoration capabilities
Electric network fault current limiter.The current limiter includes four one pole pipe group D1~D4 of series connection, square shape iron core, winding L1 and winding L2,
Wherein, four series diode group D1~D2 constitute a single-phase rectification bridge respectively as four bridge arms;Winding L1 is wound on mouth
The side of font iron core after winding is connected with DC bias supplies Udc1, connects in the common cathode pole P of D1, D3 and being total to for D2, D4
Between anode spot N: in the other side coiling winding L2 of square shape iron core;After winding L2 connects with dc switch S, connect in direct current
The both ends of source Udc2.The occluder configurations are complicated, and it is more to be related to device count, need also to need configuration bias supply, increase
The investment of current limiter is unfavorable for being widely used in multiterminal flexible direct current system.
Utility model content
To solve the above problems, the utility model proposes a kind of fault processing systems of Multi-end flexible direct current transmission route.
The utility model proposes a kind of fault processing systems of Multi-end flexible direct current transmission route, including are connected to soft
The high voltage DC breaker of the property each output end of DC converter station, further includes being connected to flexible direct current converter station output end and high pressure
Energy dissipation circuit between dc circuit breaker for the current-limiting inductance of fault current limiting and for the fault current energy that dissipates,
The current-limiting inductance is in parallel with energy dissipation circuit, and the energy dissipation circuit includes bidirectional thyristor T1, the T2 being connected in parallel
And the connection direction of energy-absorbing resistance Rr, described bidirectional thyristor T1, T2 are on the contrary, one end of the energy-absorbing resistance Rr connects current limliting
The output end of inductance, the other end connect the sys node of bidirectional thyristor T1, T2.
Preferably, disconnecting switch is also connected between the current-limiting inductance and high voltage DC breaker, it is described to keep apart
Close the aftercurrent for cutting off high voltage DC breaker.
By using the utility model, following effect may be implemented:
1. in the event of a failure, fault current becomes larger, while current-limiting inductance impedance value increases, and current-limiting inductance can drop at this time
Low fault current peak value, and the fault current rate of climb is cut down, protect change of current device to damage from overcurrent, and reduce to high pressure
The Breaking capacity of dc circuit breaker and the requirement for cut-offfing speed;
2. the energy of metal oxide arrester MOA in energy-absorbing resistance and high voltage DC breaker dissipation fault current jointly
Amount, acceleration disturbance electric current extinguish.
Detailed description of the invention
Utility model will be further described in detail below with reference to the attached drawings and specific embodiments.
Fig. 1 is the topological circuit figure of the utility model;
Fig. 2 is for electric network model schematic diagram in embodiment;
Fig. 3 is failure to actuate for embodiment mesohigh DC DC breaker, and current-limiting inductance Lmn and energy dissipation circuit are not thrown
Fashionable, flexible direct current converter station 2 exchanges the analogous diagram of side three-phase current;
Fig. 4 is failure to actuate for embodiment mesohigh DC DC breaker, and current-limiting inductance Lmn and energy dissipation circuit are not thrown
It is fashionable, the analogous diagram of 2 diode current of flexible direct current converter station;
Fig. 5 is failure to actuate for embodiment mesohigh DC DC breaker, and current-limiting inductance Lmn and energy dissipation circuit are not thrown
It is fashionable, the DC line current simulations figure at nearly 2 end of converter station direct current cables Cable12;
Fig. 6 is failure to actuate for embodiment mesohigh DC DC breaker, current-limiting inductance Lmn and energy dissipation circuit investment
When, the analogous diagram of the exchange side three-phase current of flexible direct current converter station 2;
Fig. 7 is failure to actuate for embodiment mesohigh DC DC breaker, current-limiting inductance Lmn and energy dissipation circuit investment
When, the analogous diagram of 2 diode current of flexible direct current converter station;
Fig. 8 is failure to actuate for embodiment mesohigh DC DC breaker, current-limiting inductance Lmn and energy dissipation circuit investment
When, the analogous diagram of the DC line electric current at nearly 2 end of converter station direct current cables Cable12;
Fig. 9 is and current-limiting inductance Lmn and energy dissipation circuit investment for embodiment mesohigh DC DC breaker actuation
When, the analogous diagram of 1 ac-side current of flexible direct current converter station;
Figure 10 is for embodiment mesohigh DC DC breaker actuation, and current-limiting inductance Lmn and energy dissipation circuit are thrown
It is fashionable, the analogous diagram of the IGBT convertor unit electric current of flexible direct current converter station 1;
Figure 11 is for embodiment mesohigh DC DC breaker actuation, and current-limiting inductance Lmn and energy dissipation circuit are thrown
It is fashionable, the Simulation of SAR power image figure of flexible direct current converter station 1;
Figure 12 is for embodiment mesohigh DC DC breaker actuation, and current-limiting inductance Lmn and energy dissipation circuit are thrown
It is fashionable, the analogous diagram of 2 ac-side current of flexible direct current converter station;
Figure 13 is for embodiment mesohigh DC DC breaker actuation, and current-limiting inductance Lmn and energy dissipation circuit are thrown
It is fashionable, the analogous diagram of the IGBT convertor unit electric current of flexible direct current converter station 2;
Figure 14 is for embodiment mesohigh DC DC breaker actuation, and current-limiting inductance Lmn and energy dissipation circuit are thrown
It is fashionable, the Simulation of SAR power image figure of flexible direct current converter station 2;
Figure 15 is for embodiment mesohigh DC DC breaker actuation, and current-limiting inductance Lmn and energy dissipation circuit are thrown
It is fashionable, the analogous diagram of 3 ac-side current of flexible direct current converter station;
Figure 16 is for embodiment mesohigh DC DC breaker actuation, and current-limiting inductance Lmn and energy dissipation circuit are thrown
It is fashionable, the analogous diagram of the IGBT convertor unit electric current of flexible direct current converter station 3;
Figure 17 is for embodiment mesohigh DC DC breaker actuation, and current-limiting inductance Lmn and energy dissipation circuit are thrown
It is fashionable, the Simulation of SAR power image figure of flexible direct current converter station 3.
Specific embodiment
Below in conjunction with attached drawing, the technical solution of the utility model is further described, but the utility model and unlimited
In these embodiments.
The basic thought of the utility model is to increase current-limiting inductance and energy in existing Multi-end flexible direct current transmission route
Dissipating circuit is measured, current-limiting inductance is used for fault current limiting, energy of the energy dissipation circuit for the fault current that dissipates.
In conjunction with attached drawing 1, a kind of fault processing system of Multi-end flexible direct current transmission route is present embodiments provided, including is divided
It is not connected to the high voltage DC breaker of each output end of flexible direct current converter station, further includes that be connected to flexible direct current converter station defeated
Current-limiting inductance Lmn and energy dissipation circuit between outlet and high voltage DC breaker, the current-limiting inductance and energy dissipation electricity
Road is in parallel, and high voltage DC breaker includes the main switch being connected in parallel and metal oxide arrester MOA.
Specifically, energy dissipation circuit includes bidirectional thyristor T1, T2 being connected in parallel and energy-absorbing resistance Rr, it is described double
To the connection direction of thyristor T1, T2 on the contrary, the output end of one end connection current-limiting inductance of the energy-absorbing resistance Rr, the other end connect
Connect the sys node of bidirectional thyristor T1, T2.
As the further preferred of the present embodiment, it is also connected with and keeps apart between current-limiting inductance and high voltage DC breaker
It closes, the disconnecting switch is used to cut off the aftercurrent of high voltage DC breaker.
Current-limiting inductance Lmn, since what is passed through is direct current tolerance, is presented extremely low when system is operated normally in DC side
Impedance value, when breaking down, DC current amplitude becomes larger, and impedance value increases rapidly, and can preferably inhibit fault current
Peak value, and the fault current rate of climb is cut down, converter station internal diode can be effectively protected and damaged from overcurrent, simultaneously
It can reduce for high voltage DC breaker Breaking capacity and the requirement for cut-offfing speed;Energy dissipation circuit is by bidirectional thyristor
T1, T2 and energy-absorbing resistance Rr composition, after the main switch of high voltage DC breaker is cut-off, thyristor T1 and T2 triggering and conducting makes
The energy-absorbing resistance Rr and metal oxide arrester MOA in high voltage DC breaker dissipation fault current energy jointly is obtained, is reduced
The pressure of power-absorbing metal oxide arrester MOA dissipation fault current in high voltage DC breaker, so that acceleration disturbance is electric
Stream extinguishes.
In actual electric network system, corresponding fault processing system is installed in each converter station.Fig. 2 is electricity of the invention
Pessimistic concurrency control schematic diagram.Voltage ± the 200kV, G of system shown in Figure 2 DC side are exchange side power supply, DC side rated current
0.5kA, direct current cables Cable12 length be 200km, direct current cables Cable13 length be 100km, CLC13, CLC31,
CLC12, CLC21 respectively indicate the current-limiting circuit of current-limiting inductance and energy dissipation circuit composition, and CB12, CB13, CB21 distinguish table
Show high voltage DC breaker, iCable21For the electric current at the nearly flexible direct current converter station end direct current cables Cable12.
When breaking down at the 10km apart from flexible direct current converter station 2, Fig. 3 is that high voltage direct current dc circuit breaker is motionless
Make, when current-limiting inductance Lmn and energy dissipation circuit are not put into, flexible direct current converter station 2 exchanges the analogous diagram of side three-phase current, figure
In, ia2, ib2, ic2Indicate that flexible direct current converter station exchanges side three-phase current;Fig. 4 is that high voltage direct current dc circuit breaker is failure to actuate, and is limited
When galvanic electricity sense Lmn and energy dissipation circuit are not put into, the analogous diagram of 2 diode current of flexible direct current converter station, in figure, iD1,
iD2, iD3Indicate flexible direct current converter station diode current;Fig. 5 is that high voltage direct current dc circuit breaker is failure to actuate, current-limiting inductance Lmn
When not put into energy dissipation circuit, the DC line current simulations at nearly 2 end of flexible direct current converter station direct current cables Cable12
Scheme, in figure, iCable21For the electric current at the nearly flexible direct current converter station end direct current cables Cable12;Fig. 6 is high voltage direct current direct current interruption
Device is failure to actuate, and when current-limiting inductance Lmn and energy dissipation circuit are put into, the exchange side three-phase current of flexible direct current converter station 2 is imitated
True figure;Fig. 7 is that high voltage direct current dc circuit breaker is failure to actuate, and when current-limiting inductance Lmn and energy dissipation circuit are put into, flexible direct current is changed
The analogous diagram of 2 diode currents of stream station;Fig. 8 is that high voltage direct current dc circuit breaker is failure to actuate, current-limiting inductance Lmn and energy dissipation electricity
When road is put into, the analogous diagram of the DC line electric current at nearly 2 end of converter station direct current cables Cable12;Fig. 9 is disconnected for high voltage direct current direct current
The movement of road device, and when current-limiting inductance Lmn and energy dissipation circuit investment, the analogous diagram of 1 ac-side current of flexible direct current converter station;
Figure 10 is the movement of high voltage direct current dc circuit breaker, and when current-limiting inductance Lmn and energy dissipation circuit investment, flexible direct current converter station
The analogous diagram of 1 IGBT convertor unit electric current;Figure 11 is the movement of high voltage direct current dc circuit breaker, and current-limiting inductance Lmn and energy
When dissipating circuit is put into, the Simulation of SAR power image figure of flexible direct current converter station 1;Figure 12 is the movement of high voltage direct current dc circuit breaker, and is limited
When galvanic electricity sense Lmn and energy dissipation circuit are put into, the analogous diagram of 2 ac-side current of flexible direct current converter station;Figure 13 is high straightening
Dc circuit breaker movement is flowed, and when current-limiting inductance Lmn and energy dissipation circuit investment, the IGBT change of current of flexible direct current converter station 2
The analogous diagram of cell current;Figure 14 is the movement of high voltage direct current dc circuit breaker, and current-limiting inductance Lmn and energy dissipation circuit are put into
When, the Simulation of SAR power image figure of flexible direct current converter station 2;Figure 15 is the movement of high voltage direct current dc circuit breaker, and current-limiting inductance Lmn and energy
When measuring dissipating circuit investment, the analogous diagram of 3 ac-side current of flexible direct current converter station;Figure 16 is dynamic for high voltage direct current dc circuit breaker
Make, and when current-limiting inductance Lmn and energy dissipation circuit investment, the emulation of the IGBT convertor unit electric current of flexible direct current converter station 3
Figure;Figure 17 is the movement of high voltage direct current dc circuit breaker, and when current-limiting inductance Lmn and energy dissipation circuit investment, flexible direct current is changed
The Simulation of SAR power image figure at stream station 3.
Fig. 3-5 shows that during fault transient, current-limiting inductance can effectively inhibit with energy dissipation circuit and exchange side
Electric current, diode current and DC line electric current, and make DC line electric current lower than high voltage DC breaker Breaking capacity.
During this period, if cutting off DC line fault using high voltage DC breaker, it will be avoided that completely diode is damaged because of overcurrent,
To which acceleration system is restored.
Fig. 6-17 shows to cut off failure using the fault processing system, it is possible to prevente effectively from IGBT convertor unit occurred
Stream realizes that failure is quickly cut off, and remaining system can fast quick-recovery stable operation after failure removal.
When line fault occurs, and before detecting line fault, high voltage DC breaker is in closed state, two-way
Thyristor T1, T2, which are in, cut-offs state, and current-limiting inductance increases resistance value as fault current becomes larger, to inhibit fault current peak
Value, and weaken the rate of climb of fault current;
When detecting DC line fault, the main switch of high voltage DC breaker is cut-off, simultaneously bi-directionally thyristor T1, T2
Triggering and conducting, energy-absorbing resistance Rr dissipation failure together with the metal oxide arrester MOA in high voltage DC breaker is electric at this time
The energy of stream, so that acceleration disturbance circuit extinguishes, reducing letting out for metal oxide arrester MOA can bear;
After some time, fault current rapidly decays to the numerical value close to zero, and disconnecting switch cut-offs the high straightening of excision
Flow the aftercurrent of the metal oxide arrester MOA in breaker.
By using the utility model, following effect may be implemented:
1. in the event of a failure, fault current becomes larger, while current-limiting inductance impedance value increases, and current-limiting inductance can drop at this time
Low fault current peak value, and the fault current rate of climb is cut down, protect change of current device to damage from overcurrent, and reduce to high pressure
The Breaking capacity of dc circuit breaker and the requirement for cut-offfing speed;
2. the energy of metal oxide arrester MOA in energy-absorbing resistance and high voltage DC breaker dissipation fault current jointly
Amount, acceleration disturbance electric current extinguish.
Those skilled in the art of the present invention can do described specific embodiment various
The similar mode of modify or supplement or adopt substitutes, but without departing from the spirit of the present application or surmounts appended right and want
Seek range defined in book.
Claims (2)
1. a kind of fault processing system of Multi-end flexible direct current transmission route, including to be connected to flexible direct current converter station each
The high voltage DC breaker of output end, which is characterized in that further include being connected to flexible direct current converter station output end and high voltage direct current
Energy dissipation circuit between breaker for the current-limiting inductance of fault current limiting and for the fault current energy that dissipates, it is described
Current-limiting inductance Lmn is in parallel with energy dissipation circuit, the energy dissipation circuit include bidirectional thyristor T1, T2 for being connected in parallel with
And the connection direction of energy-absorbing resistance Rr, described bidirectional thyristor T1, T2 are on the contrary, one end connection current limliting of the energy-absorbing resistance Rr is electric
Feel the output end of Lmn, the other end connects the sys node of bidirectional thyristor T1, T2.
2. the fault processing system of Multi-end flexible direct current transmission route according to claim 1, which is characterized in that described
Disconnecting switch is also connected between current-limiting inductance and high voltage DC breaker, the disconnecting switch is for cutting off high voltage direct current open circuit
The aftercurrent of device.
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
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CN108879750A (en) * | 2018-06-29 | 2018-11-23 | 国网浙江省电力有限公司杭州供电公司 | A kind of fault processing system and its control method of Multi-end flexible direct current transmission route |
CN109449892A (en) * | 2018-10-17 | 2019-03-08 | 天津大学 | A kind of failure current limit method of direct current system decentralized capacitance configuration |
WO2020244015A1 (en) * | 2019-06-04 | 2020-12-10 | 上海交通大学 | Direct current limiter topology suitable for flexible direct current transmission system |
CN112086943A (en) * | 2020-09-02 | 2020-12-15 | 东南大学 | Active fault current-limiting circuit and all-solid-state direct current breaker |
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2018
- 2018-06-29 CN CN201821030563.5U patent/CN208571622U/en active Active
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108879750A (en) * | 2018-06-29 | 2018-11-23 | 国网浙江省电力有限公司杭州供电公司 | A kind of fault processing system and its control method of Multi-end flexible direct current transmission route |
CN109449892A (en) * | 2018-10-17 | 2019-03-08 | 天津大学 | A kind of failure current limit method of direct current system decentralized capacitance configuration |
CN109449892B (en) * | 2018-10-17 | 2019-12-27 | 天津大学 | Fault current limiting method for direct current system distributed capacitor configuration |
WO2020244015A1 (en) * | 2019-06-04 | 2020-12-10 | 上海交通大学 | Direct current limiter topology suitable for flexible direct current transmission system |
CN112086943A (en) * | 2020-09-02 | 2020-12-15 | 东南大学 | Active fault current-limiting circuit and all-solid-state direct current breaker |
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