CN203800578U - High-voltage direct-current circuit breaker - Google Patents

Abstract

The utility model discloses a high-voltage direct-current circuit breaker. The high-voltage direct-current circuit breaker includes a current conversion branch, a main circuit breaker branch, a high-speed switch energy supply unit, a main loop reactor unit and a main loop disconnecting switch unit; the current conversion branch is an LC oscillation branch; an adjustable reactor and a plurality of high-speed switch energy absorbing and voltage equalizing modules are connected in series with each other so as to form the main circuit breaker branch; a high-speed switch, a lightning arrester and an RC voltage equalizing branch are connected in parallel with one another so as to form each high-speed switch energy absorbing and voltage equalizing module; the high-speed switch energy supply unit can ensure the quickness and cooperativity of the high-speed switches; the main loop reactor unit is used for decreasing the rise rate of failure current; and a main loop protection switch unit is used for protecting internal components after the circuit breaker is switched off successfully. Based a high-speed repulsion mechanism and an insulation transformer, the high-voltage direct-current circuit breaker has high switch-off speed, and can prevent the fault current from rising to large amplitude; and the high-voltage direct-current circuit breaker can withstand high voltage level, has high switch-off reliability and is simple in structure and low in cost.

Description

A kind of high voltage DC breaker

Technical field

The utility model belongs to AC network field, more specifically, relates to a kind of high voltage DC breaker.

Background technology

Based on voltage source converter (Voltage Source Converter, VSC) the high pressure (>=35kV) direct current network (High Voltage Direct Current Grid, HVDCG) of structure is considered to solve the grid-connected preferred plan with sending outside of extensive outlying wind farm group.The high-voltage direct current power grid of take is wind-powered electricity generation collects platform, has avoided intrinsic stability (voltage, frequency, the phase place etc.) problem of AC network, thus for wind-electricity integration provide flexible grid-connected may.But the new problem of bringing is the isolation of direct-current short circuit fault and the new technologies such as DC circuit breaker of excision short trouble, wherein especially the most key with DC circuit breaker.

When being short-circuited fault, the Low ESR of direct current system causes short circuit current to rise rapidly, therefore must guarantee that DC circuit breaker excises reliably short trouble within the short as far as possible time.Meanwhile, because DC circuit breaker needs to bear higher transient recovery voltage during drop-out current, must guarantee that main switch branch road meets insulating requirements.

In prior art, often adopt hydraulic pressure or pneumatic means to open main switch, operate time is slow, causes short circuit current to rise to excessive value, and circuit breaker is difficult to cut-off large electric current; When electric pressure is higher, the existing DC circuit breaker class of insulation cannot meet the demands, and cannot bear large voltage, bang easily occurs and wear.

Utility model content

For above defect or the Improvement requirement of prior art, the purpose of this utility model has been to provide a kind of high voltage DC breaker, has solved the problem that existing high voltage DC breaker is difficult to cut-off large electric current and bears large voltage.

The high voltage DC breaker that the utility model provides comprises main circuit breaker branch road, change of current branch road, high-speed switch supply unit, major loop reactor unit and major loop Disconnecting switch unit; Described major loop Disconnecting switch unit comprises the first isolating switch and the second isolating switch; Described main circuit breaker branch road comprises a plurality of high-speed switch energy-absorbing pressure modules that are connected in series successively and the Regulatable reactor of connecting with described high-speed switch energy-absorbing pressure module; One end of described Regulatable reactor is connected with described major loop reactor unit by described the first isolating switch, and the other end of described Regulatable reactor is connected with described high-speed switch energy-absorbing pressure module; Described change of current branch road is connected with described main circuit breaker branch circuit parallel connection; Described high-speed switch supply unit is connected with the feeder ear in a plurality of high-speed switch energy-absorbing pressure modules respectively, for power supply being provided to the high-speed switch operating mechanism of each high-speed switch energy-absorbing pressure module.

Wherein, described high-speed switch energy-absorbing pressure module comprises that high-speed switch K, the first lightning arrester MOV and the RC that are connected in parallel successively all press branch road; The first capacitor C that described RC all presses branch road to comprise to be connected in series successively ₀with the first resistance R ₀.

Wherein, described high-speed switch supply unit comprises a plurality of insulating transformers unit, and each insulating transformer unit comprises the iron core T of segmentation serial connection, is wrapped in a former limit winding on described iron core T and the secondary winding of a plurality of mutually insulateds; Described former limit winding is for being electrically connected to city, and a plurality of secondary windings are connected with the feeder ear in each high-speed switch energy-absorbing pressure module respectively.

Wherein, described insulating transformer unit also comprises the insulation framework G of full skirt shape structure, is positioned at the periphery of described iron core T.

Wherein, described major loop reactor unit comprises reactor L ₃, the second resistance R ₁, the first diode D ₁, the second lightning arrester MOV ₂, the 3rd resistance R ₂, the second diode D ₂with the second capacitor C ₃; Described the first diode D ₁negative electrode by described the second resistance R ₁with described reactor L ₃one end connect, described the first diode D ₁anode and described reactor L ₃the other end; Described the second lightning arrester MOV ₂be connected in parallel on described reactor L ₃two ends; Described the second diode D ₂anode and described reactor L ₃one end connect, described the second diode D ₂negative electrode by described the second capacitor C ₃ground connection; Described the 3rd resistance R ₂with described the second diode D ₂be connected in parallel.

Wherein, described change of current branch road comprises the first inductance L ₁, the second inductance L ₂, the 3rd capacitor C ₁, the 4th capacitor C ₂, transformer T ₁, three electrode gap S _gfill energy unit with commutation capacitor; Described three electrode gap S _gfirst end by described the first inductance L ₁be connected with the link of described main circuit breaker branch road with described the first isolating switch; Described three electrode gap S _gthe second end by the second inductance L being connected in series successively ₂with the 3rd capacitor C ₁be connected with the link of described the second isolating switch with described main circuit breaker branch road; Described transformer T ₁former limit be used for connecting civil power, described transformer T ₁one end of secondary coil by described the 4th capacitor C ₂with described three electrode gap S _gthe 3rd end connect, described transformer T ₁the other end ground connection of secondary coil; Commutation capacitor fill can unit for to described the 3rd capacitor C ₁charging.

Wherein, described commutation capacitor fills and can comprise high-speed switch S in unit ₃, the 4th resistance R ₃with the 5th resistance R ₄, described the 4th resistance R ₃with described the 5th resistance R ₄be connected in series in successively described the 3rd capacitor C ₁month described the second inductance L ₂link and ground between, described high-speed switch S ₃with described the 4th resistance R ₃be connected in parallel.

The utility model, by the series connection of many pack modules, can meet the requirement of different electric pressures flexibly.Each module is born identical voltage, by one or more transformers with mutually insulated secondary, to the operating mechanism of high-speed switch K, provides power supply.Due to the series connection of high-speed switch energy-absorbing pressure module, high-speed switch in modules is also connected in series, the contact of high-speed switch is all in high potential, and because insulating transformer adopts many group secondary structures, make the operating mechanism being connected with insulating transformer secondary also be in high potential, thereby greatly reduce the contact of high-speed switch K and the insulating requirements between operating mechanism, make DC circuit breaker can bear large voltage.

Accompanying drawing explanation

The theory diagram of the high voltage DC breaker based on rapid repulsion mechanism and insulating transformer that Fig. 1 provides for the utility model;

The circuit diagram of high-speed switch energy-absorbing pressure module in the high voltage DC breaker based on rapid repulsion mechanism and insulating transformer that Fig. 2 provides for the utility model;

The structure chart of insulating transformer in the high voltage DC breaker based on rapid repulsion mechanism and insulating transformer that Fig. 3 provides for the utility model;

The schematic diagram of change of current branch road in the high voltage DC breaker based on rapid repulsion mechanism and insulating transformer that Fig. 4 provides for the utility model;

The circuit diagram of major loop reactor unit in the high voltage DC breaker based on rapid repulsion mechanism and insulating transformer that Fig. 5 provides for the utility model;

The physical circuit figure of the high voltage DC breaker based on rapid repulsion mechanism and insulating transformer that Fig. 6 provides for the utility model.

Embodiment

In order to make the purpose of this utility model, technical scheme and advantage clearer, below in conjunction with drawings and Examples, the utility model is further elaborated.Should be appreciated that specific embodiment described herein is only in order to explain the utility model, and be not used in restriction the utility model.In addition,, in each execution mode of described the utility model, involved technical characterictic just can not combine mutually as long as do not form each other conflict.

In the utility model embodiment, rapid repulsion mechanism is the mechanical type high-speed switch based on electromagnetic repulsion force action.High-speed switch (Ultra-Fast Switch) mainly refers to that the switch motion time, in several milliseconds, is different from a few tens of milliseconds of traditional switch, because its responsiveness is far above traditional switch, therefore be called high-speed switch.

As shown in Figure 1, the high voltage DC breaker that the utility model provides comprises change of current branch road 2, main circuit breaker branch road 1, high-speed switch supply unit 3, major loop reactor unit 4 and major loop Disconnecting switch unit 5.Some high-speed switch energy-absorbing pressure modules 12 that main circuit breaker branch road 1 comprises Regulatable reactor 11 and connects with it, this main circuit breaker branch road 1 provides power supply by high-speed switch supply unit 3 to the high-speed switch operating mechanism in high-speed switch energy-absorbing pressure module 12.This main circuit breaker branch road 1 is in parallel with change of current branch road 2, then connects with major loop reactor unit 4 and major loop Disconnecting switch unit 5, forms the Modular HVDC breaker body structure based on rapid repulsion mechanism and insulating transformer.

Wherein, a plurality of high-speed switch energy-absorbing pressure module 12 series connection.As shown in Figure 2, each module all presses branch circuit parallel connection to form by a high-speed switch K, a lightning arrester MOV and a RC.High-speed switch K is the mechanical switch based on rapid repulsion mechanism, lightning arrester MOV is the Zinc-oxide piezoresistor for dissipation energy final drop-out current, RC in each module all presses branch road to be used for realizing all pressures between each high-speed switch energy-absorbing pressure module, thereby guarantee that single high-speed switch can arc reignition not occur because bearing overvoltage, causes failure of interruption.During normal operation, high-speed switch K is all in closing position, the line current high-speed switch K that only flows through.When short trouble generation being detected, high-speed switch K opens rapidly, and arcing occurs, due to the effect of change of current branch road oscillating current, and high-speed switch K generation current zero crossing, arc extinction; Now high-speed switch K two ends can produce larger transient recovery voltage, and in module, RC all presses branch road to play all pressure effects, prevent that the bang of single rapid repulsion K switch from wearing; When voltage rises to lightning arrester MOV clamp voltage, electric current is transferred to rapidly the lightning arrester MOV branch road in high-speed switch energy-absorbing pressure module, and the energy in circuit is absorbed by lightning arrester MOV, until electric current reduces to zero, completes and cut-offs.Because the magnitude of voltage that individual module bears is limited, therefore, by the series connection of many pack modules, can meet flexibly the requirement of different electric pressures.Each module is born identical voltage, by one or more transformers with mutually insulated secondary, to the operating mechanism of high-speed switch K, provides power supply.Due to the series connection of high-speed switch energy-absorbing pressure module, high-speed switch in modules is also connected in series, the contact of high-speed switch is all in high potential, and because insulating transformer adopts many group secondary structures, make the operating mechanism being connected with insulating transformer secondary also be in high potential, thereby greatly reduce the contact of high-speed switch K and the insulating requirements between operating mechanism, make DC circuit breaker can bear large voltage.

Wherein, the Regulatable reactor 11 with a plurality of high-speed switch energy-absorbing pressure modules 12 are connected, had both participated in producing LC reversing oscillating current, played again and suppressed the effect that fault current rises, and the fall off rate while simultaneously also having reduced current zero-crossing point, avoids arc reignition;

Wherein, as shown in Figure 3, high-speed switch supply unit 3 adopts one or more insulating transformers with mutually insulated secondary to provide power supply to each tandem tap operating mechanism.Insulating transformer is composed in series by the iron core T segmentation of insulating, and iron core outside puts insulation framework G again to increase creepage distance.Insulation framework can adopt the shapes such as insulator umbrella.Transformer secondary is wrapped in the middle of two strand insulation skeletons.

Wherein, as shown in Figure 4, change of current branch road 2 is LC vibration branch road, for generation of reverse current zero crossing extinguish arcs and for automatic reclosing, realizes quick-speed turning on-off.Commutation capacitor C ₁from system power taking, be precharged to system voltage.Commutation capacitor C ₁can adopt capable of charging in many ways to be precharged to system voltage, such as resistance grounded or the charging of employing transformer.

Wherein, change of current branch road 2 adopts three electrode gap S _gconducting, passes through capacitor C ₂protection charge circuit; The LC oscillation circuit of change of current branch road for adopting three electrode gaps to trigger.After short trouble being detected through certain time-delay, the automatic control transformer T of DC circuit breaker control system ₁former square tube electricity, triggers three electrode gap S _gconducting, commutation capacitor C ₁with inductance L ₁and L ₂produce series resonance, for the blow-out of high-speed switch K provides reverse current.In addition inductance L, ₁and L ₂be distributed in three electrode gap S _gboth sides, isolation three electrode gap S _gtrigger voltage, avoids trigger voltage string to capacitor C ₁or high-speed switch K.

Wherein, as shown in Figure 5, major loop reactor unit 4 is by reactor L ₃, resistance R ₁, diode D ₁, lightning arrester MOV ₂, resistance R ₂, diode D ₂and capacitor C ₃form.This major loop reactor unit is by reactor L ₃play the effect of the climbing that reduces fault current.When cut-offfing fault current, diode D ₁and resistance R ₁for reactor L ₃the induced voltage producing provides discharge paths, prevents reactor L ₃it is excessive that voltage is born at two ends; When fault current rises rapidly, lightning arrester MOV ₂by voltage clamping protection reactor L ₃, capacitor C ₃, diode D ₂and resistance R ₂the loop forming is used for clamping down on reactor L ₃left end current potential.

Wherein, major loop Disconnecting switch unit 5 comprises the first isolating switch 51 and the second isolating switch 52.Can adopt high-speed switch.In normal operation and failure on-off process, the first isolating switch 51 and the second isolating switch 52 are all in closure state.After circuit breaker cut-offs successfully, isolating switch is opened, protection DC circuit breaker inner member.

Compared with prior art, the beneficial effects of the utility model are: (1), by the series connection of a plurality of high-speed switch energy-absorbing pressure modules, can meet the DC circuit breaker requirement of different electric pressures neatly.(2) by adopting insulating transformer to provide power supply to the operating mechanism of high-speed switch, because operating mechanism is in high potential, greatly reduce the insulating requirements between contact and operating mechanism, guaranteed that rapid repulsion switch is reliable and moved simultaneously.

The Modular HVDC circuit breaker based on rapid repulsion mechanism and insulating transformer the utility model proposes adopts the direct current of active type transfer current to cut-off method, produces impressed current zero crossing drop-out current.

Modular HVDC circuit breaker in the present embodiment adopts the high voltage DC breaker that shown in accompanying drawing 6, a plurality of high-speed switch series connection form.

Each high-speed switch energy-absorbing pressure module in the present embodiment all presses branch circuit parallel connection to form by a high-speed switch K, a lightning arrester MOV and a RC.High-speed switch K is for adopting the high-speed switch based on rapid repulsion mechanism of insulating transformer isolation, lightning arrester MOV is the Zinc-oxide piezoresistor for dissipation energy final drop-out current, RC in each module all presses a route resistance R and capacitor C to be composed in series, for realizing all pressures between modules.During normal operation, high-speed switch K is all in closing position, the line current high-speed switch K that only flows through.When short trouble generation being detected, high-speed switch K opens rapidly, and arcing occurs, due to the effect of change of current branch road oscillating current, and high-speed switch K generation current zero crossing, arc extinction; Now high-speed switch K two ends can produce larger transient recovery voltage, and in module, RC branch road plays all pressure effects, prevent that the bang of single rapid repulsion switch from wearing; When voltage rises to lightning arrester MOV clamp voltage, electric current is transferred to rapidly lightning arrester MOV branch road, and the energy in circuit is absorbed by lightning arrester MOV, until electric current reduces to zero, completes and cut-offs.Because the magnitude of voltage that individual module bears is limited, therefore, by the series connection of many pack modules, can meet flexibly the requirement of different electric pressures.

High-speed switch supply unit in the present embodiment, as shown in Figure 4, mainly provides power supply by the transformer with a plurality of mutually insulated secondary to each tandem tap operating mechanism.Transformer is composed in series by the iron core segmentation of insulating, and insulation framework is added in iron core outside, to increase creepage distance.Insulation framework can adopt the shapes such as insulator umbrella.Transformer secondary is wrapped in the middle of two strand insulation skeletons.

The detailed process of this DC circuit breaker disjunction direct current is as follows:

(1) when circuit normally moves, high-speed switch K is all positioned at closing position, and electric current only circulates from main switch branch road; Switch S ₃open capacitor C ₁charge to system voltage;

(2) when being short-circuited fault, line current rises rapidly, and DC circuit breaker is opened eight high-speed switch K after fault current being detected immediately simultaneously, and arcing occurs;

(3) elapsed time t ₁after time delay, by triggering three electrode gap S _gconducting, capacitor C ₁with inductance L, L ₁and L ₂series resonance produces oscillating current, and current transfer is to change of current branch road;

(4) capacitor C ₁because fault current flows into constantly charging, when reaching lightning arrester MOV clamp voltage, lightning arrester MOV conducting, current transfer is to lightning arrester MOV;

(5) lightning arrester MOV constantly consumes line inductance and capacitor C ₁the energy storing, until line current reduces to zero, completes and cut-offs, and now commutation capacitor fills and can move unit, switch S ₃closure, commutation capacitor C ₁charge to rapidly system voltage; Elapsed time t ₂after, eight high-speed switch K of conducting again.If fault type is temporary fault, reclosing success; If fault type is nonvolatile fault, repeating step (3) (4), completes electric current and cut-offs.

Those skilled in the art will readily understand; the foregoing is only preferred embodiment of the present utility model; not in order to limit the utility model; all any modifications of doing within spirit of the present utility model and principle, be equal to and replace and improvement etc., within all should being included in protection range of the present utility model.

Claims (7)

1. a high voltage DC breaker, is characterized in that, comprises main circuit breaker branch road (1), change of current branch road (2), high-speed switch supply unit (3), major loop reactor unit (4) and major loop Disconnecting switch unit (5);

Described major loop Disconnecting switch unit (5) comprises the first isolating switch (51) and the second isolating switch (52);

Described main circuit breaker branch road (1) comprises a plurality of high-speed switch energy-absorbing pressure modules (12) that are connected in series successively and the Regulatable reactor (11) of connecting with described high-speed switch energy-absorbing pressure module (12); One end of described Regulatable reactor (11) is connected with described major loop reactor unit (4) by described the first isolating switch (51), and the other end of described Regulatable reactor (11) is connected with described high-speed switch energy-absorbing pressure module (12);

Described change of current branch road (2) is connected in parallel with described main circuit breaker branch road (1);

Described high-speed switch supply unit (3) is connected with the feeder ear in a plurality of high-speed switch energy-absorbing pressure modules (12) respectively, for power supply being provided to the high-speed switch operating mechanism of each high-speed switch energy-absorbing pressure module (12).

2. high voltage DC breaker as claimed in claim 1, is characterized in that, described high-speed switch energy-absorbing pressure module (12) comprises that high-speed switch K, the first lightning arrester MOV and the RC that are connected in parallel successively all press branch road; The first capacitor C that described RC all presses branch road to comprise to be connected in series successively ₀with the first resistance R ₀.

3. high voltage DC breaker as claimed in claim 1, it is characterized in that, described high-speed switch supply unit (3) comprises a plurality of insulating transformers unit, each insulating transformer unit comprises the iron core T of segmentation serial connection, is wrapped in a former limit winding on described iron core T and the secondary winding of a plurality of mutually insulateds;

Described former limit winding is for being electrically connected to city, and a plurality of secondary windings are connected with the feeder ear in each high-speed switch energy-absorbing pressure module (12) respectively.

4. high voltage DC breaker as claimed in claim 3, is characterized in that, described insulating transformer unit also comprises the insulation framework G of full skirt shape structure, is positioned at the periphery of described iron core T.

5. high voltage DC breaker as claimed in claim 1, is characterized in that, described major loop reactor unit (4) comprises reactor L ₃, the second resistance R ₁, the first diode D ₁, the second lightning arrester MOV ₂, the 3rd resistance R ₂, the second diode D ₂with the second capacitor C ₃;

Described the first diode D ₁negative electrode by described the second resistance R ₁with described reactor L ₃one end connect, described the first diode D ₁anode and described reactor L ₃the other end;

Described the second lightning arrester MOV ₂be connected in parallel on described reactor L ₃two ends;

Described the second diode D ₂anode and described reactor L ₃one end connect, described the second diode D ₂negative electrode by described the second capacitor C ₃ground connection;

Described the 3rd resistance R ₂with described the second diode D ₂be connected in parallel.

6. high voltage DC breaker as claimed in claim 1, is characterized in that, described change of current branch road (2) comprises the first inductance L ₁, the second inductance L ₂, the 3rd capacitor C ₁, the 4th capacitor C ₂, transformer T ₁, three electrode gap S _gfill energy unit with commutation capacitor;

Described three electrode gap S _gfirst end by described the first inductance L ₁be connected with the link of described main circuit breaker branch road (1) with described the first isolating switch (51);

Described three electrode gap S _gthe second end by the second inductance L being connected in series successively ₂with the 3rd capacitor C ₁be connected with the link of described the second isolating switch (52) with described main circuit breaker branch road (1);

Described transformer T ₁former limit be used for connecting civil power, described transformer T ₁one end of secondary coil by described the 4th capacitor C ₂with described three electrode gap S _gthe 3rd end connect, described transformer T ₁the other end ground connection of secondary coil;

Commutation capacitor fill can unit for to described the 3rd capacitor C ₁charging.

7. high voltage DC breaker as claimed in claim 6, is characterized in that, described commutation capacitor fills and can comprise high-speed switch S in unit ₃, the 4th resistance R ₃with the 5th resistance R ₄,

Described the 4th resistance R ₃with described the 5th resistance R ₄be connected in series in successively described the 3rd capacitor C ₁month described the second inductance L ₂link and ground between,

Described high-speed switch S ₃with described the 4th resistance R ₃be connected in parallel.