CN203101587U

CN203101587U - Over-current turn-off test device for flexible direct current power transmission MMC valve

Info

Publication number: CN203101587U
Application number: CN 201220614194
Authority: CN
Inventors: 罗湘; 查鲲鹏; 高冲; 吴亚楠; 周竞之
Original assignee: State Grid Smart Grid Research Institute of SGCC; State Grid Corp of China SGCC; C Epri Electric Power Engineering Co Ltd
Current assignee: Global Energy Interconnection Research Institute Co Ltd; State Grid Corp of China SGCC; C Epri Electric Power Engineering Co Ltd
Priority date: 2012-11-19
Filing date: 2012-11-19
Publication date: 2013-07-31
Anticipated expiration: 2022-11-19

Abstract

The utility model provides an over-current turn-off test device for a flexible direct current power transmission MMC valve. The over-current turn-off test device for the flexible direct current power transmission MMC valve comprises a sample valve, a switching switch, a load loop, a circuit switch and a charging power source. The over-current turn-off test device can meet over-current turn-off test requirements of the MMC valve, can provide transient heat intensity, transient fault current intensity, transient high voltage intensity, subsidiary circuit loss intensity, current change rate (di/dt) intensity and voltage change rate (dv/dt) intensity similar to practical operation conditions and provides bases for the practical operation conditions.

Description

A kind of excess current of flexible DC power transmission MMC valve is closed breaking test device

Technical field

The utility model belongs to electric and electronic technical field, and the excess current that is specifically related to a kind of flexible DC power transmission MMC valve is closed breaking test device.

Background technology

Starting along with flexible DC power transmission (VSC-HVDC) technology in electric system applied, and the reliability of its core component---high-power high voltage insulated gate bipolar transistor (IGBT) valve becomes the key of security of system.Because the VSC-HVDC device generally has, voltage is high, electric current is large, characteristics capacious, being difficult to build the identical full live road with actual operating mode in experimental enviroment is tested, therefore how to build equivalent hookup in experimental enviroment, carry out the test suitable with actual operating mode intensity and become the key of dealing with problems.

VSC-HVDC based on modularization multi-level converter (MMC) as shown in Figure 1, is to realize utilizing the IGBT valve to carry out a kind of mode of direct current transportation.Its core component is called the MMC valve, and in normal operating condition, submodule, by the cooperation of upper and lower two IGBT, can be exported two kinds of level: 0 level and condenser voltage.

In the actual motions based on turn-off device valve high power electronic equipment such as flexible direct current, there are two kinds of excess current operating modes in the turn-off device IGBT in the MMC valve.A kind of is the submodule inside that causes due to fault or the bridge arm direct pass between submodule; Another kind is the slow overcurrent of IGBT caused due to a variety of causes, the difference of two kinds of excess current be the current-rising-rate of the first excess current and current amplitude all very large.No matter the excess current of which kind of operating mode occurs, and all needs control circuit the pulse of excess current locking IGBT can be detected in time with protection device.

The utility model content

For the deficiencies in the prior art; the utility model provides a kind of excess current of flexible DC power transmission MMC valve to close breaking test device, and the test valve causes that for meeting it is correct that IGBT drives the design of maximum current, voltage and temperature stress effect under the excess current operating condition of protecting.

The excess current of a kind of flexible DC power transmission MMC valve that the utility model provides is closed breaking test device, and its improvements are, described device comprises test product valve, change-over switch, load circuit, contactor and the charge power supply connected successively.

Wherein, described test product valve comprises the first submodule and second submodule of series connection;

Described the first submodule comprises IGBT module T ₁₁, IGBT module T ₁₂, resistance D ₁₁, resistance D ₁₂and capacitor C _sM1; Described IGBT module T ₁₁with described IGBT module T ₁₂the series connection after with described capacitor C _sM1parallel connection, described resistance D ₁₁with described resistance D ₁₂the series connection after with described capacitor C _sM1in parallel;

The second submodule comprises IGBT module T ₂₁, IGBT module T ₂₂, resistance D ₂₁, resistance D ₂₂and capacitor C _sM2; Described IGBT module T ₂₁with described IGBT module T ₂₂the series connection after with described capacitor C _sM2parallel connection, described resistance D ₂₁with described resistance D ₂₂the series connection after with described capacitor C _sM2in parallel;

The IGBT module T of described series connection ₁₁with IGBT module T ₁₂the intermediate point leading-out terminal, be the high-voltage output end of the first submodule;

The IGBT module T of described series connection ₂₁with IGBT module T ₂₂intermediate point and described IGBT module T ₁₂connect, and leading-out terminal, be the second submodule high-voltage output end;

Described capacitor C _sM2anodal leading-out terminal, be the second submodule capacitor high voltage end;

Described capacitor C _sM2the negative pole leading-out terminal, be the second submodule low-voltage output.

Wherein, described IGBT module T ₁₁, IGBT module T ₁₂, IGBT module T ₂₁with IGBT module T ₂₂include antiparallel diode and IGBT.

Wherein, described change-over switch comprises change-over switch K _t1with change-over switch K _t2;

Described change-over switch K _t1two terminals of corresponding configuration, terminal D ₁with terminal U ₁; Described terminal D ₁with the second submodule capacitor high voltage end, be connected; Described terminal U ₁with the first submodule high-voltage output end, be connected;

Described change-over switch K _t2two terminals of corresponding configuration, terminal D ₂with terminal U ₂; Described terminal D ₂with the second submodule high-voltage output end, be connected; Described terminal U ₂with the second submodule low-voltage output, be connected;

Described change-over switch K _t1with described change-over switch K _t2interlock.

Wherein, described load circuit comprises load branch I and load branch II;

Described load branch I comprises the K switch of series connection ₁with load reactance device L ₁;

Described load branch II comprises the K switch of series connection ₂with load reactance device L ₂;

After described load branch I and described load branch II parallel connection, its two ends meet respectively change-over switch K _t1with change-over switch K _t2.

Wherein, described charge power supply is connected in parallel on described load circuit two ends;

The positive pole of described charge power supply is by described contactor K and change-over switch K _t1connect, after its minus earth with terminal U ₂connect.

Compared with the prior art, the beneficial effects of the utility model are:

1, method provided by the invention is by the cooperation of hookup and control system, some (≤5) individual pulse width excess current stress adjustable, that interpulse period is adjustable is put on tested converter valve MMC valve, make the tested converter valve tolerance transient current suitable with actual excess current operating mode, heat and the loss intensity of transient state, the test examination of realization to tested valve accident operating condition, and test method provided by the invention is convenient, simple for the realization of different tests mode, very favourable for the security of test unit;

2, the excess current of flexible DC power transmission MMC valve provided by the invention is turn-offed the requirement that test method meets MMC valve excess current shutoff test fully, can provide Transient Thermal intensity, transient fault strength of current, transient state high-voltage strength, accessory circuit loss intensity, current changing rate (di/dt) intensity, voltage change ratio (dv/dt) intensity that same actual operating mode is suitable, for actual condition provides foundation.

The accompanying drawing explanation

The electrical structure diagram of the MMC valve that Fig. 1 provides for the utility model.

The excess current that Fig. 2 provides for the utility model is closed the electric topological diagram of breaking test device.In figure, A ₁end is the first submodule high-voltage output end; A ₂end is the second submodule high-voltage output end; B ₁end is the second submodule capacitor high voltage end; B ₂end is the second submodule low-voltage output; C _sM1, C _sM1be respectively the electric capacity of the first submodule and the second submodule; D ₁₁, D ₁₂be the resistance of the first submodule; T ₁₁, T ₁₂be IGBT module, the D of the first submodule ₂₁, D ₂₂be the resistance of the second submodule; T ₂₁, T ₂₂it is the IGBT module of the second submodule; K _t1, K _t2for change-over switch; D ₁, U ₁, D ₂, U ₂be respectively terminal; K ₁, K ₂be respectively the switch of load branch I and load branch II; L ₁, L ₂be respectively the load reactance device of load branch I and load branch II; K is contactor; E is charge power supply.

The excess current that Fig. 3 provides for the utility model is closed the triggering sequential chart of breaking test device test product valve.

The excess current that Fig. 4 provides for the utility model is closed breaking test device test product valve test waveform figure.

Embodiment

Below in conjunction with accompanying drawing, embodiment of the present utility model is described in further detail.

The utility model is that the test valve causes that for meeting it is correct that IGBT drives the design of maximum current, voltage and temperature stress effect under the excess current operating condition of protecting.

The excess current of a kind of flexible DC power transmission MMC valve that the present embodiment proposes is closed breaking test device, comprises the test product valve, change-over switch, load circuit, contactor and the charge power supply that connect successively.

Wherein, test product valve comprises the first submodule and second submodule of series connection;

Described IGBT module T ₁₁, IGBT module T ₁₂, IGBT module T ₂₁with IGBT module T ₂₂include antiparallel diode and IGBT.

The change-over switch of the present embodiment comprises change-over switch K _t1with change-over switch K _t2;

The load circuit of the present embodiment comprises load branch I and load branch II;

The charge power supply of the present embodiment is connected in parallel on described load circuit two ends;

The present embodiment provides a kind of excess current of flexible DC power transmission MMC valve to turn-off test method again, and described method comprises the steps:

(1) test product valve being connected with charge power supply with load circuit, is the test product valve charging;

Concrete steps are: by change-over switch K _t1be connected change-over switch K with the high-voltage output end of test product valve the first submodule _t2be connected with the low-voltage output of test product valve the second submodule, drop into charge circuit, give the first submodule and the charging of the second submodule of test product valve, until disconnect described change-over switch K after testing requirements voltage _t1with described change-over switch K _t2.

(2) the current peak size be set based on the test is selected the load reactance device of load circuit;

Concrete steps are:

1) the judgement test needs the size of current of use, if large electric current is selected the load reactance device L of load circuit ₁if little electric current is selected the load reactance device L of load circuit ₂;

2) select load reactance device L ₁or load reactance device L ₂, the load switch that closed pair is answered.Load reactance device L wherein ₁value be less than load reactance device L ₂value, load reactance device L ₁value and load reactance device L ₂value all according to testing requirements, set.

(3) select the subjects of test product valve according to test objective, and by the corresponding change of the change-over switch of load circuit;

Concrete steps are:

Pipe IGBT module T on the second submodule that 1. if subjects is described test product valve ₂₁, change-over switch K _t1be connected change-over switch K with the capacitor high voltage end of test product valve the first submodule _t2with the high-voltage output end of test product valve the second submodule, be connected;

Pipe IGBT module T under the second submodule that 2. if subjects is described test product valve ₂₂, keep change-over switch K _t1with change-over switch K _t2invariant position.

(4), according to the subjects of the time trigger test product valve of setting, detect the withstand voltage degree of test product valve.

As shown in Figure 3, its transverse axis is time (t) to the triggering sequential chart of setting, the amplitude that the longitudinal axis is switching value, 0 and 1.Concrete steps are:

<1>t of on-test ₀=0 constantly, triggers the IGBT as subjects, and pulse width is Δ t ₁; Δ t ₁scope be 0～50 μ s, it is determined according to testing requirements.

<2>through Δ t ₂after time, t ₁constantly again trigger the IGBT as subjects, pulse width is Δ t ₁; Δ t ₂scope be 0～10ms, it is determined according to testing requirements.

<3>through Δ t ₂after time, t ₂constantly again trigger the IGBT as subjects, pulse width is still Δ t ₁;

<4 > repeating step<3 > n time, the withstand voltage degree of detection test product valve, and record.N time, the scope of its frequency n is determined according to testing requirements, but n≤5.

As shown in Figure 4, it closes breaking test device test product valve test waveform figure for excess current.As can be seen from the figure, Current rise, to the level of protection of device, drives protection to make the device locking, has reached the purpose of protection device; Can, in single test, repeatedly repeat the locking process according to testing requirements simultaneously.

Finally should be noted that: above embodiment is only in order to illustrate that the technical solution of the utility model is not intended to limit, although with reference to above-described embodiment, the utility model is had been described in detail, those of ordinary skill in the field are to be understood that: still can modify or be equal to replacement embodiment of the present utility model, and do not break away from any modification of the utility model spirit and scope or be equal to replacement, it all should be encompassed in the middle of claim scope of the present utility model.

Claims

1. a kind of overcurrent shutdown test device of flexible direct current transmission MMC valve, it is characterized in that, described device comprises sample valve, changeover switch, load circuit, circuit switch and charging power supply connected successively. the

2. The over-current shut-off test device as claimed in claim 1, wherein the sample valve comprises a first submodule and a second submodule connected in series;

The first sub-module includes IGBT module T ₁₁ , IGBT module T ₁₂ , resistor D ₁₁ , resistor D ₁₂ and capacitor C _SM1 ; the IGBT module T ₁₁ and the IGBT module T ₁₂ are connected in series with the capacitor C _SM1 connected in parallel, the resistor D ₁₁ and the resistor D ₁₂ are connected in parallel with the capacitor C _SM1 after being connected in series;

The second sub-module includes an IGBT module T ₂₁ , an IGBT module T ₂₂ , a resistor D ₂₁ , a resistor D ₂₂ and a capacitor C _SM2 ; the IGBT module T ₂₁ and the IGBT module T ₂₂ are connected in parallel with the capacitor C _SM2 after being connected in series, The resistor D ₂₁ and the resistor D ₂₂ are connected in parallel with the capacitor C _SM2 after being connected in series;

The terminal at the middle point of the series-connected IGBT module _T11 and IGBT module _T12 is the high-voltage output terminal of the first submodule;

The intermediate point of the series connected IGBT module _T21 and IGBT module _T22 is connected to the IGBT module _T12 , and a terminal is drawn out, which is the high-voltage output terminal of the second sub-module;

The positive lead-out terminal of the capacitor C _SM2 is the high-voltage end of the second sub-module capacitor;

The negative lead-out terminal of the capacitor C _SM2 is the low-voltage output terminal of the second sub-module.

3 . The over-current shutdown test device according to claim 2 , wherein the IGBT module T ₁₁ , the IGBT module T ₁₂ , the IGBT module T ₂₁ and the IGBT module T ₂₂ all include anti-parallel diodes and IGBTs.

4. The overcurrent shutdown test device as claimed in claim 2, wherein the switch comprises a switch K _T1 and a switch K _T2 ;

The changeover switch K _T1 is correspondingly configured with two terminals, terminal _D1 and terminal _U1 ; the terminal _D1 is connected to the high voltage end of the capacitor of the second submodule; the terminal _U1 is connected to the high voltage output end of the first submodule;

The switch K _T2 is correspondingly configured with two terminals, terminal _D2 and terminal _U2 ; the terminal _D2 is connected to the high-voltage output end of the second submodule; the terminal _U2 is connected to the low-voltage output end of the second submodule;

The changeover switch K _T1 is linked with the changeover switch K _T2 .

5. over-current shutdown test device as claimed in claim 4, is characterized in that, described load circuit comprises load branch circuit I and load branch circuit II;

The load branch I includes a switch K ₁ and a load reactor L ₁ connected in series;

The load branch II includes a switch K ₂ and a load reactor L ₂ connected in series;

After the load branch I and the load branch II are connected in parallel, their two ends are respectively connected to a switch K _T1 and a switch K _T2 .

6. The overcurrent shutdown test device as claimed in claim 4, wherein the charging power supply is connected in parallel at both ends of the load circuit;

The positive pole of the charging power supply is connected to the switch K _T1 through the circuit switch K, and its negative pole is connected to the terminal _U2 after being grounded.