CN201160258Y - 3-power level integrated gate commutate thyristor frequency converter bridge arm straight-through protector - Google Patents

Abstract

The utility model discloses a bridge-arm through protector for tri-level integrated gate-commutated thyristor transducer, which is characterized in that: the bridge-arm through protector is connected with a direct current circuit of the tri-level integrated gate-commutated thyristor transducer in parallel; the direct current circuit is composed of a parallel rectifier, a DC filtering capacitor and an inverter in sequence; the bridge-arm through protector comprises a protection unit, a bridge-arm through protection control unit which is connected with the protection unit, and a plurality of bridge-arm through signal detection units which are connected with the bridge-arm through protection control unit. The utility model has the advantages that: the bridge-arm through protector can bypass rapidly and reduce the short circuit current of the through bridge arm; the bypass is the reverse surge current generated by the through loop inductance; the energy of DC bus can be consumed and the attenuation process of surge current can be speeded up; after the bridge through is detected, the bypass thyristor can be triggered and the direct current energy can be discharged via the bypass, and warning signals can be sent to the system so as to make the system implement interlock protection; when a bridge-arm through failure is happened, the tri-level IGCT voltage source medium-voltage transducer can be protected effectively.

Description

The three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector

Technical field

The utility model belongs to the bridge arm direct pass protector in the high-power medium voltage converter AC speed regulator, particularly relates to a kind of three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector that can effectively protect three level integrated gate pole conversion transistor voltage-source type medium voltage frequency converter when the bridge arm direct pass fault takes place.

Background technology

Integral gate change transistor (IGCT) is a kind of high-power semiconductor switch device that is used for the advanced person of power converter at present, having the advantages that the conducting electric current is big, the on-state tube voltage drop is low and turn-off fast, is the main device for power switching of making high-power three level medium voltage frequency converters at present.

Figure 1 shows that active front terminal type three level IGCT voltage-source type three-phase medium voltage frequency converters.Because the hardware fault of the fast recovery fly-wheel diode reverse breakdown of IGCT component failure or reverse parallel connection or external trigger control loop or Control Software are write under the situation such as mistake, the shoot through (see figure 2) may appear in a certain phase brachium pontis.The bridge arm direct pass short circuit can have multiple situation, only draws wherein 4 kinds among Fig. 2.

Surpass its cut-off current in case the fatal shortcoming of IGCT is the electric current that flows through it, can not turn-off.The electric current that flows through straight-through brachium pontis IGCT under the shoot through situation substantially exceeds its cut-off current, so this brachium pontis IGCT can not turn-off.Because loop inductance very little (5～20 μ H), if there is not safeguard measure, dc capacitor will rise rapidly by the electric current of straight-through brachium pontis discharge, and surpass the surge current that IGCT allows, and brachium pontis IGCT is damaged.

Solve above-mentioned shoot through problem, protection IGCT, two class methods are roughly arranged: a class is the method that opens circuit, promptly adopt breaking device (as the IGCT device of fast acting fuse, bigger electric current etc.) to be connected on the dc bus, the current path with IGCT during shoot through disconnects; Another kind of is the method for by-pass shunt; promptly adopt semiconductor switch device in parallel with the IGCT loop; and design makes the impedance in by-pass shunt loop less than the impedance of IGCT brachium pontis; when the short circuit of IGCT bridge arm direct pass; open by-pass shunt; the energy of the DC loop of releasing rapidly, the maximum surge current when making the short circuit of IGCT bridge arm direct pass reach the purpose of protection IGCT less than permissible value.

Present existing fast acting fuse, general its fusing time at several ms to 10ms, and the climbing of above-mentioned straight-through fault current is generally at hundreds of A/ μ s, it effectively protects action to start in tens μ s to tens μ s, the response time of therefore existing fast acting fuse is slow excessively, can not satisfy the demand; Simultaneously fast acting fuse will be accomplished middle pressure, big electric current, also suitable difficulty on manufacturing process, and heat radiation and loss become very stubborn problem, handle badly will make its blast; Even if this fast acting fuse has been arranged, the big overvoltage that incision position produces when fusing also may cause IGCT directly to damage, and makes the method for this open circuit protection be not suitable for substantially adopting.

The another kind of method that opens circuit is to adopt the IGCT device of bigger electric current to be connected on the dc bus, and it has overcome the shortcoming of above-mentioned fast acting fuse breaking method substantially, as for the overvoltage that opens circuit, can cushion with the resistance on the IGCT by being connected in parallel on protection.But this method has limitation, and it is suitable for the used IGCT element current of frequency converter less (power output is less) situation, if the used IGCT of frequency converter has been the maximum current specification, then is not suitable for adopting this method.In addition, because the price of IGCT own is higher, adopt the cost of this method higher relatively.

Another shortcoming of open circuit protection is that protection component is connected in the DC loop, flows through direct current during operate as normal, has increased conduction loss, if adopt IGCT also need add radiator.

The method of by-pass shunt has overcome the shortcoming of above-mentioned open circuit protection, is the comparatively suitable effective shoot through guard method of high-power three level IGCT voltage-source type medium voltage frequency converters at present.

Summary of the invention

The utility model provides a kind of three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector that can effectively protect three level integrated gate pole conversion transistor voltage-source type medium voltage frequency converter when the bridge arm direct pass fault takes place for solving the technical problem that exists in the known technology.

The technical scheme that the utility model is taked for the technical problem that exists in the solution known technology is: a kind of three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector; described bridge arm direct pass protector is arranged in parallel by rectifier in parallel successively; in the DC loop of the three level integrated gate pole conversion transistor voltage source frequency converter that dc filter capacitor and inverter constitute; described bridge arm direct pass protector includes protected location; the bridge arm direct pass protection control unit that links to each other with protected location, and a plurality of bridge arm direct pass detecting signal units that link to each other with bridge arm direct pass protection control unit.

Described bridge arm direct pass protector is connected in parallel on the two ends of the dc filter capacitor in the three level integrated gate pole conversion transistor voltage source frequency converter DC loop.

Described a plurality of bridge arm direct pass detecting signal unit is connected to the two ends of each brachium pontis current-rising-rate restriction reactor of three level integrated gate pole conversion transistor voltage source frequency converter.

Described protected location includes surge forward current bypass loop that constitutes the three level integrated gate pole conversion transistor voltage source frequency converter bridge arm direct pass and the reverse surge current bypass loop that constitutes the three level integrated gate pole conversion transistor voltage source frequency converter bridge arm direct pass.

Described surge forward current bypass loop is to be made of thyristor V1, V2 that forward is connected in parallel on the dc bus, and the trigger end of described thyristor V1, V2 is connected with bridge arm direct pass protection control unit.

Described reverse surge current bypass loop is to be made of the diode D1, the D2 that are connected in reverse parallel on the dc bus.

The high energy noninductive resistance of also connecting in described surge forward current bypass loop and the reverse surge current bypass loop.

Described each bridge arm direct pass detecting signal unit includes and is connected with current-limiting resistance R101, the R102 that is connected to brachium pontis current-rising-rate restriction reactor two ends; reverse protection diode D101 that links to each other with the other end of current-limiting resistance R101, R102 and the fiber optic transmitter N101 that links to each other with reverse protection diode D101 two ends respectively, fiber optic transmitter N101 links to each other by optical fiber and bridge arm direct pass protection control unit.

Described bridge arm direct pass protection control unit comprises: through connect signal receives link, through connect signal filtering delay-time, remembers, resets with amplification output circuit, reaches two identical thyristors triggering controlling units, wherein said through connect signal receives link and receives the signal that the bridge arm direct pass detecting signal unit is sent by optical fiber, through the through connect signal filtering delay-time, remember, reset and amplification output circuit, send signal to the thyristor trigger control unit, also send straight-through alarm signal simultaneously to system; Described thyristor triggers controlling unit and receives through connect signal, promptly filtering delay-time, remember, reset and the signal of amplification output circuit, and trigger thyristor V1, V2 according to the signal controlling that is received.

It is identical structure that the corresponding a plurality of optical fiber that connect of fiber optic transmitter N101 in described and a plurality of bridge arm direct pass detecting signal units receive link, it is to be made of fiber optic receiver N201 and coupled respectively resistance R 201, diode D201 that each optical fiber receives link, the diode D201 negative electrode of each optical fiber reception link interconnects the back and links to each other with chip for driving N212 by 4-two NOR gate N211, chip for driving N212 drives transmitter respectively and triggers controlling unit transmission protection control signal to thyristor, and sends straight-through alarm signal to system; Described thyristor triggers the trigger impulse isolation link that controlling unit includes trigger impulse insulating power supply circuit, is made of fiber optic transmitter N221 and fiber optic receiver N222, fiber optic receiver N222 also forms circuit with trigger impulse respectively with trigger impulse insulating power supply circuit and links to each other, trigger impulse forms circuit and links to each other with the trigger impulse amplifying circuit, and the corresponding connection of the output of described trigger impulse amplifying circuit forward is connected in parallel on gate pole and the negative electrode of the thyristor V1/V2 on the dc bus.

Advantage and the good effect that the utlity model has are: three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector of the present utility model, bypass and reduce the short circuit current of straight-through brachium pontis rapidly; The reverse surge current that bypass is produced by the straight circuit inductance; Consume the dc bus energy and accelerate the surge current attenuation process; After detecting bridge arm direct pass, can trigger the bypass thyristor with the bypass dc energy of releasing, and send alarm signal to system, make system's interlock protection.The utility model adopts relatively inexpensive triode thyristor, diode, noninductive resistance etc. to constitute three level IGCT voltage-source type medium voltage frequency converter bridge arm direct pass protectors; cost is low, reliable, can effectively protect three level IGCT voltage-source type medium voltage frequency converters when the bridge arm direct pass fault takes place.

Description of drawings

Fig. 1 is the circuit theory diagrams of active front terminal type three level IGCT voltage-source type three-phase medium voltage frequency converters;

Fig. 2 is the schematic diagram of three kinds of situations of three level IGCT voltage-source type medium voltage frequency converter bridge arm direct pass;

Wherein: Fig. 2 a is the situation owing to V11 (or V13) control fails, the wrong bridge arm direct pass that causes of V11 (or V13) control; Fig. 2 b is the situation owing to V12 (or V14) control fails or the wrong bridge arm direct pass that causes of V12 (or V14) control; Fig. 2 c is the situation owing to the wrong bridge arm direct pass that causes of any 2 IGCT control in any 2 IGCT control fails in the brachium pontis or the brachium pontis; Fig. 2 d is owing to mid point clamp diode D15 reverse breakdown, the situation of the bridge arm direct pass that causes;

Fig. 3 is the three level IGCT voltage-source type medium voltage frequency converter circuit theory diagrams that have bridge arm direct pass protector;

Fig. 4 is the circuit theory diagrams of bridge arm direct pass detecting signal unit;

Fig. 5 is the circuit theory diagrams of bridge arm direct pass protection control unit.

Label among the figure is respectively:

The 1-rectifier; The 2-dc filter capacitor; The 3-inverter; The 4-bridge arm direct pass protector; The 5-protected location; 6-bridge arm direct pass protection control unit; 7-bridge arm direct pass detecting signal unit.

Embodiment

For further understanding summary of the invention of the present utility model, characteristics and effect, exemplify following examples now, and conjunction with figs. to describe three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector of the present utility model in detail as follows:

All be in series with current-rising-rate restriction reactor (as the L11 among Fig. 2, L12) on the forward of each brachium pontis of three-level converter and the negative sense brachium pontis, because the inductance of load motor is much larger than brachium pontis current-rising-rate restriction reactor, current-rising-rate is limited by load inductance mainly during operate as normal, and the pressure drop that produces on the brachium pontis current-rising-rate restriction reactor is very little; When straight-through fault,, make straight-through direct voltage impact when initial to brachium pontis current-rising-rate restriction reactor because capacitance voltage can not suddenly change.Therefore by detecting the voltage (seeing Fig. 3, Fig. 4) on the brachium pontis current-rising-rate restriction reactor, can judge straight-through fault.

As shown in Figure 3; the utility model is based on the principle of by-pass shunt; shunting thyristor V1, V2 and diode D1, the D2 of protection usefulness in parallel on three level IGCT voltage-source type frequency changer direct current bus; and the high energy noninductive resistance R1～R4 that in the protection loop, connects respectively; and the bridge arm direct pass short-circuit signal detects protection link etc., formation bridge arm direct pass protector.The concrete formation of three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector of the present utility model is: described bridge arm direct pass protector 4 is arranged in parallel in the DC loop of the three level integrated gate pole conversion transistor voltage source frequency converter that is made of rectifier 1, dc filter capacitor 2 and inverter 3 in parallel successively; the bridge arm direct pass protection control unit 6 that described bridge arm direct pass protector 4 includes protected location 5, links to each other with protected location 5, and a plurality of bridge arm direct pass detecting signal units 7 that link to each other with bridge arm direct pass protection control unit 6.

Described bridge arm direct pass protector 4 is connected in parallel on the two ends of the dc filter capacitor 2 in the three level integrated gate pole conversion transistor voltage source frequency converter DC loop.

Described a plurality of bridge arm direct pass detecting signal unit 7 is connected to the two ends of each brachium pontis current-rising-rate restriction reactor of three level integrated gate pole conversion transistor voltage source frequency converter.

Described protected location 5 includes surge forward current bypass loop that constitutes the three level integrated gate pole conversion transistor voltage source frequency converter bridge arm direct pass and the reverse surge current bypass loop that constitutes the three level integrated gate pole conversion transistor voltage source frequency converter bridge arm direct pass.

Described surge forward current bypass loop is to be made of thyristor V1, V2 that forward is connected in parallel on the dc bus, and the trigger end of described thyristor V1, V2 is connected with bridge arm direct pass protection control unit 6.

Described reverse surge current bypass loop is to be made of the diode D1, the D2 that are connected in reverse parallel on the dc bus.Reverse parallel connection diode D1, D2 on dc bus, the by-pass shunt reverse surge current; Series connection high energy noninductive resistance R3, R4 in D1, D2 loop are used to consume the energy on the dc bus and accelerate the energy attenuation process of releasing.

The high energy noninductive resistance of also connecting in described surge forward current bypass loop and the reverse surge current bypass loop.Thyristor V1, V2 connect respectively high energy noninductive resistance R1, R2 are connected in parallel on the dc bus, are used for bypass forward fault surge current; The noninductive R1 of high energy, R2 are used to consume the energy on the dc bus, accelerate the dc bus energy attenuation process of releasing;

As shown in Figure 4; described each bridge arm direct pass detecting signal unit 7 includes and is connected with current-limiting resistance R101, the R102 that is connected to brachium pontis current-rising-rate restriction reactor two ends; reverse protection diode D101 that links to each other with the other end of current-limiting resistance R101, R102 and the fiber optic transmitter N101 that links to each other with reverse protection diode D101 two ends respectively, fiber optic transmitter N101 links to each other by optical fiber and bridge arm direct pass protection control unit 6.

L is brachium pontis di/dt restriction inductance among Fig. 4, R101 and R102 are current-limiting resistance, resistance is determined according to the actuation of an alarm electric current, if direct voltage is 3kV, when straight-through fault, brachium pontis di/dt restriction inductance instantaneous voltage reaches 3kV, reaches through the electric current of R101 and R102 input optical fibre transmitter N101 (model HFBR-1521) to be operating current about 40mA, make fiber optic receiver outputs level signals upset among Fig. 5, selecting current-limiting resistance R101 and R102 is 39k Ω.Here fiber optic transmitter that connects by optical fiber and the fiber optic receiver isolation that constitutes the bridge arm direct pass detection signal.D101 (model 1N4002) is the reverse protection diode.

As shown in Figure 5, wherein said through connect signal receives link and receives the signal that bridge arm direct pass detecting signal unit 7 is sent by optical fiber, sends signal to thyristor trigger control unit A13, A14 then, also sends straight-through alarm signal to system simultaneously; Described thyristor triggers controlling unit A13, A14 and receives through connect signal, and triggers thyristor V1, V2 according to the signal controlling that is received.

Described bridge arm direct pass protection control unit 6 comprises: through connect signal receives link A1～A12, the through connect signal filtering delay-time, memory, reset and amplification output circuit N211, N212, and two identical thyristors trigger controlling unit A13, A14, wherein said through connect signal receives link A1～A12 and receives the signal that bridge arm direct pass detecting signal unit 7 is sent by optical fiber, through the through connect signal filtering delay-time, memory, reset and amplification output circuit, to thyristor trigger control unit A13, A14 sends and triggers control signal, also sends straight-through alarm signal to system simultaneously; Described thyristor triggers controlling unit A13, A14 and receives straight-through control signal, promptly filtering delay-time, remember, reset and the signal of amplification output circuit, and trigger thyristor V1, V2 according to the signal controlling that is received.

It is identical structure that the corresponding a plurality of optical fiber that connect of fiber optic transmitter N101 in described and a plurality of bridge arm direct pass detecting signal units 7 receive link A1～A12, it is by fiber optic receiver N201 and coupled respectively resistance R 201 that each optical fiber receives link, diode D201 constitutes, the diode D201 negative electrode of each optical fiber reception link A1～A12 interconnects the back and links to each other with chip for driving N212 by 4-two NOR gate N211, chip for driving N212 drives transmitter respectively and triggers controlling unit A13 to thyristor, A14 sends the protection control signal, and sends straight-through alarm signal to system; Described thyristor triggers the trigger impulse isolation link that controlling unit A13/A14 includes trigger impulse insulating power supply circuit, is made of fiber optic transmitter N221 and fiber optic receiver N222, fiber optic receiver N222 also forms circuit with trigger impulse respectively with trigger impulse insulating power supply circuit and links to each other, trigger impulse forms circuit and links to each other with the trigger impulse amplifying circuit, and the corresponding connection of the output of described trigger impulse amplifying circuit forward is connected in parallel on gate pole and the negative electrode of the thyristor V1/V2 on the dc bus.

A1～A12 is that through connect signal receives link among Fig. 5, and N201 is fiber optic receiver (model HFBR-2521), and D201 is diode (model 1N4148).The anode of D201 among A1～A12 is linked to each other, constitute 12 road through connect signal phases " with " logic.When road and bridge, straight-through fault took place arm, a certain road D201 negative electrode was a level "0" among corresponding A1～A12 when any, made the D201 conducting of this road, and made (anode) public connecting end of 12 road D201 become level "0".

NOR gate N211 (model C D4001) is 4-two input NOR gate.When brachium pontis took place to lead directly to fault, (1# 2#) became level "0" to the N211.1 input, the anti-phase output level"1" of N211.1.R211 and C211 constitute the filtering delay-time link, make N211.3 input (8#) level change time-delay, reach the filter action to the bridge arm direct pass signal, and this filtering time should be controlled at 15～25us.After the bridge arm direct pass deration of signal surpasses the time-delay width; N211.3 output is level "0" by the level"1" upset; N211.2 output immediately is level"1" by the level "0" upset, leads directly to the protection control signal to A13, A14 through Darlington drive circuit N212 (model MC1413) output.The N211.2 output signal is back to N211.3 input (9#), makes at the bridge arm direct pass signal and forms this signal of back memory, until remove memory after unit " Reset " input input reset signal.N211.4 is used for bridge arm direct pass signal memory and resets, and when reset terminal unsettled (promptly disconnecting), is normal operation (being non-resetting) state, is equivalent to reset terminal and is input as one state, and N211.4 is output as " 0 " attitude; When reset terminal connects 0V or obtains a level "0" pulse, N211.4 is output as one state, forces N211.2 to be output as " 0 " attitude, if N211.3 input this moment (8#) is in " 0 " attitude, then N211.3 is output as " 1 ", recovers normal operating conditions.N213 is a fiber optic transmitter, is connected with control system by optical fiber, is used for sending the bridge arm direct pass alarm signal to system, makes system's interlocking.This part circuit constitute the bridge arm direct pass signal filtering delay-time, remember, reset, amplification output circuit.

A13, A14 are the triggering controlling unit of protection thyristor among Fig. 5.

T221 is single-phase transformer (no-load voltage ratio 220V/28V), and alternating current 220V voltage transformation for exchanging 28V voltage, is exported direct current 24V through diode single-phase rectification bridge and filter capacitor C221 rectification that D221～D224 (model 1N5401) forms.N224 is three terminal regulator (model 7815), output DC voltage-stabilizing 15V.This part circuit constitutes triggering insulating power supply circuit.

N221 is fiber optic transmitter (model HFBR-1521), and N222 (model HFBR-2521) is a fiber optic receiver, receives start pulse signal.N221 and N222 constitute the trigger impulse buffer circuit.

N223 is the NE555 timer circuit, is used to make ono shot pulse to become spike train, and resistance R 222 and capacitor C 225 are used for determining the spike train frequency.Capacitor C 227 is used to produce the pulse front edge with derivative action.This part is that core constitutes trigger impulse formation circuit with N223.

R225 is the trigger impulse current-limiting resistance, adjusts according to the thyristor trigger current.V221 (model BU406) is trigger impulse output amplifying triode.This part constitutes the trigger impulse amplifying circuit.

Output G1, K1 are connected respectively to gate pole and the negative electrode of bridge arm direct pass protector thyristor V1, and G2, K2 are connected respectively to gate pole and the negative electrode of bridge arm direct pass protector thyristor V2.

The bridge arm voltage signal of per road and bridge arm current-rising-rate restriction reactor that bridge arm direct pass detecting signal unit 7, bridge arm direct pass protection control unit 6 will be gathered; with 6 the tunnel (or 12 the tunnel; for active front terminal type three level IGCT frequency converters) (one state is normal in the signal AND operation; " 0 " attitude is for straight-through); when wherein any one the tunnel when being judged as straight-through fault; behind filtering wave by prolonging time, send the protection interlocking signal.

With the inverter in the three level IGCT voltage-source type frequency converters is example, when three level IGCT voltage source inverter brachium pontis take place to lead directly to fault, the electric current that flows through straight-through brachium pontis is come from dc filter capacitor discharge, the self-rectifying device of coming, is come from load-side mainly from three the road.Because the equivalent series inductance of rectifier side and load-side big (general mH level), its current-rising-rate that flows to straight-through brachium pontis is lower, and dc filter capacitor loop inductance very little (general hundreds of nH level), so its current-rising-rate that flows to straight-through brachium pontis is very high, be the main electric current source of causing straight-through brachium pontis IGCT surge current to damage.Therefore solve straight-through problem mainly will with the electric energy in the dc filter capacitor as early as possible bypass release.By interlocking disjunction major loop high-voltage switch gear, but cut off electric current from rectifier, though the response time grow (tens of ms), but because of the electric power loop reactance is big relatively, the scope that its electric current generally can bear at IGCT.

When three level IGCT voltage-source type frequency converter brachium pontis take place to lead directly to fault; the utility model bridge arm direct pass short-circuit signal detects link and sends guard signal through filtering delay-time; thyristor V1, V2 are opened in triggering; and trigger by the control system interlocking simultaneously and open all IGCT of three-level converter; make the electric energy demultiplexing in the dc filter capacitor quicken to release, effectively reduce the electric current of straight-through brachium pontis.Series connection high energy noninductive resistance R1, R2 are used to consume the energy on the dc bus in V1, V2 loop.

Because inductance and dc filter capacitor constitute oscillation circuit in the circuit, in straight-through fault, can produce reverse voltage, and forming reverse surge current through the mid point clamp diode of IGCT frequency converter and fly-wheel diode, alignment clamp diode and fly-wheel diode constitute a threat to.For this reason, the utility model is reverse parallel connection diode D1, D2 on dc bus, the diversion reverse surge current.Series connection high energy noninductive resistance R3, R4 are used to consume the energy on the dc bus in D1, D2 loop.

Another effect of R1～R4 is and accelerates the attenuation process of discharging current.

The utility model is applicable to the bridge arm direct pass protection of the three-level voltage source type frequency converter that all use IGCT element composition: 1. be applicable to the frequency converter that adopts diode rectifier and IGCT three-level inverter to constitute; 2. be applicable to the frequency converter that adopts silicon controlled rectifier and IGCT three-level inverter to constitute; 3. be applicable to the frequency converter that adopts diode, thyristor mixed-rectification device and IGCT three-level inverter to constitute; 4. be applicable to the frequency converter that adopts IGCT rectifier and IGCT three-level inverter to constitute.For active front terminal type three level IGCT voltage-source type frequency converters, its rectifier and inverter all are the patterns of three-level current transformer, connect (see figure 1) back-to-back.To this frequency converter, the utility model is applicable to the straight-through error protection of arbitrary brachium pontis in its rectifier and the inverter.

Because bypass thyristor circulating current (atomic little leakage current is only arranged) not when the frequency conversion system operate as normal, so there is not loss to take place.

Claims (10)

1. three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector; it is characterized in that: described bridge arm direct pass protector (4) is arranged in parallel by rectifier (1) in parallel successively; in the DC loop of the three level integrated gate pole conversion transistor voltage source frequency converter that dc filter capacitor (2) and inverter (3) constitute; described bridge arm direct pass protector (4) includes protected location (5); the bridge arm direct pass protection control unit (6) that links to each other with protected location (5), and a plurality of bridge arm direct pass detecting signal units (7) that link to each other with bridge arm direct pass protection control unit (6).

2. three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector according to claim 1 is characterized in that: described bridge arm direct pass protector (4) is connected in parallel on the two ends of the dc filter capacitor (2) in the three level integrated gate pole conversion transistor voltage source frequency converter DC loop.

3. three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector according to claim 1 is characterized in that: described a plurality of bridge arm direct pass detecting signal units (7) are connected to the two ends of each brachium pontis current-rising-rate restriction reactor of three level integrated gate pole conversion transistor voltage source frequency converter.

4. three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector according to claim 1; it is characterized in that: described protected location (5) includes surge forward current bypass loop that constitutes the three level integrated gate pole conversion transistor voltage source frequency converter bridge arm direct pass and the reverse surge current bypass loop that constitutes the three level integrated gate pole conversion transistor voltage source frequency converter bridge arm direct pass.

5. three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector according to claim 4; it is characterized in that: described surge forward current bypass loop is to be made of thyristor V1, V2 that forward is connected in parallel on the dc bus, and the trigger end of described thyristor V1, V2 is connected with bridge arm direct pass protection control unit (6).

6. three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector according to claim 4 is characterized in that: described reverse surge current bypass loop is to be made of the diode D1, the D2 that are connected in reverse parallel on the dc bus.

7. according to claim 4 or 5 or 6 described three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protectors, it is characterized in that: the high energy noninductive resistance of also connecting in described surge forward current bypass loop and the reverse surge current bypass loop.

8. three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector according to claim 1; it is characterized in that: described each bridge arm direct pass detecting signal unit (7) includes and is connected with current-limiting resistance R101, the R102 that is connected to brachium pontis current-rising-rate restriction reactor two ends; reverse protection diode D101 that links to each other with the other end of current-limiting resistance R101, R102 and the fiber optic transmitter N101 that links to each other with reverse protection diode D101 two ends respectively, fiber optic transmitter N101 links to each other by optical fiber and bridge arm direct pass protection control unit (6).

9. three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector according to claim 1, it is characterized in that: described bridge arm direct pass protection control unit (6) comprising: and through connect signal reception link (A1～A12), the through connect signal filtering delay-time, memory, reset and amplification output circuit (N211, N212), and two identical thyristors trigger controlling unit (A13, A14), wherein said through connect signal receives link and receives the signal that bridge arm direct pass detecting signal unit (7) is sent by optical fiber, through the through connect signal filtering delay-time, memory, reset and amplification output circuit, to thyristor trigger control unit (A13, A14) send signal, also send straight-through alarm signal simultaneously to system; Described thyristor triggers controlling unit (A13, A14) and receives through connect signal, promptly filtering delay-time, remember, reset and the signal of amplification output circuit, and trigger thyristor V1, V2 according to the signal controlling that is received.

10, three level integrated gate pole conversion transistor frequency converter bridge arm direct pass protector according to claim 9, it is characterized in that: the corresponding a plurality of optical fiber that connect of the fiber optic transmitter N101 in described and a plurality of bridge arm direct pass detecting signal units (7) receive links, and (A1～A12) is identical structure, it is by fiber optic receiver N201 and coupled respectively resistance R 201 that each optical fiber receives link, diode D201 constitutes, each optical fiber receives link, and (the diode D201 negative electrode of A1～A12) interconnects the back and links to each other with chip for driving N212 by 4-two NOR gate N211, chip for driving N212 drives transmitter respectively and triggers controlling unit (A13 to thyristor, A14) send the protection control signal, and send straight-through alarm signal to system; Described thyristor triggers the trigger impulse isolation link that controlling unit (A13/A14) includes trigger impulse insulating power supply circuit, is made of fiber optic transmitter N221 and fiber optic receiver N222, fiber optic receiver N222 also forms circuit with trigger impulse respectively with trigger impulse insulating power supply circuit and links to each other, trigger impulse forms circuit and links to each other with the trigger impulse amplifying circuit, and the corresponding connection of the output of described trigger impulse amplifying circuit forward is connected in parallel on gate pole and the negative electrode of the thyristor V1/V2 on the dc bus.

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