WO2017059924A1 - Multi-level converter having a redundancy module - Google Patents

Abstract

The invention relates, among other things, to a multi-level converter (5) having a plurality of sub-modules (10, 40), which are connected in series and which each have at least one capacitor (13, 43) and output current by means of the capacitor (13, 43) in discharging phases and draw current in order to charge the capacitor (13, 43) in charging phases. According to the invention, the multi-level converter (5) has at least one redundancy module (20, 50), which is inactive in a normal operating mode of the multi-level converter (5) and operates as a sub-module (10, 40) in a substitute operating mode of the multi-level converter (5), and a switching device (100, 500) is connected in parallel with the redundancy module (20, 50) or with a redundancy module series circuit (21, 51) having the redundancy module (20, 50), which switching device is switched on in the normal operating mode and is switched off in the substitute operating mode.

Description

description

The invention relates to a multilevel converter with a plurality of submodules connected in series, each having at least one capacitor and in

Discharge phases accommodate outward flow abge ^¬ ben and in charging phase current for charging the capacitor means of the capacitor.

Such a multilevel converter is known, for example, from the publication "An Innovative Modular Multilevel Converter Topology Suitable for Wide Power Range" (A. Lesnicar and R. Marquardt, 2003 IEEE Bologna Power Tech Conference, 23.-26.

June 2003, Bologna, Italy). In this previously known Multilevelumrichter is a so-called Marquardt converter arrangement, which comprises at least two parallel series circuits ge ^¬ switched. Each of the parallel-connected series circuits each comprises at least two series-connected submodules, each comprising at least two switches and one capacitor. By suitable control of the switches, the voltage level at the output of the multilevel converter can be set specifically.

The invention is based on the object, a

Specify Multilevelumrichter in which in case of failure of submodules further safe operation is possible, at least for a certain additional period of time.

This object is achieved by a

Multilevel converter solved with the features of claim 1. Advantageous embodiments of the multilevel converter according to the invention are specified in subclaims.

Thereafter, the invention provides that the

Multilevel converter has at least one redundancy module, which in a normal operating mode of the multilevel converter is active and in a standby mode of the

Multilevelumrichters works as a submodule, and to the Redun ^¬ danzmodul or to the redundancy module having Re ^¬ dundanzmodulreihenschaltung a switching device is connected in parallel, which is turned on in the normal operating mode and switched off in the substitute operating mode.

A significant advantage of the invention

Multilevelumrichters is that in case of failure of one or - depending on the design - several active submodules another operation of the multilevel converter or at least a safe shutdown of

Multilevel converter is possible because failed submodules can be replaced by activating redundancy modules. The activation of the redundancy ^{module (s) may take place} according to the invention by switching off a parallel switching device, ie reliably and quickly. By From ^¬ switch of the switching means, the redundancy module lying parallel or redundant modules in parallel are supplied with voltage, so that their capacitors can be charged and the redundant modules are operational.

The redundancy modules for the replacement mode and the already active in normal operation mode submoduls preference ^¬ as identical or identical.

With a view to sufficient redundancy, it is considered to be ^advantageous if at least two submodules of the

Multilevel inverters are redundancy modules. Preferably, the at least two redundant modules are electrically switched ge ^¬ in series and form the above-mentioned redundancy module row scarf ^¬ processing. Overlooking minimal electrical losses in the on switch ^¬ th state, it is considered advantageous if the

Switching device has a mechanical switch. The mechanical switch is in the normal operating mode of the The multilevel converter is switched on and switched off in the substitute operating mode of the multilevel converter.

The switching device preferably has a parallel circuit which comprises at least one mechanical switch and a semiconductor switch connected in parallel thereto.

The semiconductor switch is preferably switched off both in the normal operating mode of the multilevel converter and in the alternative operating mode of the multilevel converter. The semicon ^¬ conductor switch is preferably used only for shorting the mechanical switch during the opening of the switch contacts of the mechanical switch to prevent the occurrence of a Lichtbo ^¬ gene or to shorten the occurrence of an arc.

As a semiconductor switch, a thyristor is preferably used. Particularly in the case that it is full bridge modules at the submodules and the redundant modules, it is considered advantageous if the switching means comprises a parallel circuit comprising at least a mechanical switch and two parallel thereto unidirectional switching semiconductor switch, said unidirektio ^¬ nal switching semiconductor switches are interconnected opposite polarity.

In the case of the latter embodiment, it is the special advantage when the switching means comprises a parallel ^¬ circuit comprising at least one mechanical scarf ^¬ ter and two connected in parallel with thyristors, the thyristors are connected with opposite polarity. Incidentally, it is advantageous if an impedance, for example in the form of an ohmic resistance, is connected in series with the switching device, in particular with the semiconductor switch and / or with the mechanical switch. Such Impedance can be used to limit the current as well as to intentionally cause a voltage drop, which co-determines or influences the charging of the capacitor (s) of the redundancy module (s).

In the latter embodiment, the switch in series with the impedance, preferably the semiconductor switch, is preferably not opened until the capacitor or capacitors of the submodule are sufficiently charged and the submodule is operable and capable of communication with a control device of the multilevel converter.

The invention also relates to an arrangement with a multilevel converter, as has been described above.

The arrangement or the multilevel converter itself preferably has a control device which is connected to the mentioned mechanical switch and the mentioned at least one semiconductor switch.

In a preferred embodiment of the arrangement it is provided that the control device is designed such that it in the context of activation of the replacement operation of the Multilevelumrichters, before, during or after the off ^¬ switch of the mechanical switch, turns on the semiconductor switch, preferably by at a control input, in particular ignition input, the semiconductor switch or the semiconductor switch a periodic control signal, in particular a pulse comb applies.

The control means is preferably configured such that it can be turned on the semiconductor switch or a semiconductor switch or repeatedly, in particular by means of a periodic control signal turns on, until they insbesonde ^¬ re of the redundancy module, receives a signal that the amounts ^¬ off state of the mechanical switch signaled. The control device is preferably the current through the monitor the mechanical switch and leave the semiconductor switch on until the current reaches or falls below a preset threshold. Alternatively or additionally, the controller may be configured such that it makes the semiconductor switch or a semiconductor switch is turned on, or repeatedly, into ^¬ particular by means of a periodic control signal Power On ^¬ tet, and one for a fixed period of time after the mechanical switch or the application is switched off Switch-off command to the mechanical switch.

In order to avoid an over-voltage across the capacitor of the or of the redundant modules, and an overload and possibly destruction of the redundant modules, it will be advantageous angese ^¬ hen, when the control device is designed such that it switches on or turned on the semiconductor switch or the semiconductor switches when the voltage across a capacitor of the redundancy module reaches or exceeds a predetermined maximum voltage and / or the sum voltage of the voltages of the capacitors of the redundancy module series circuit reaches or exceeds a predetermined maximum sum voltage. In a preferred specific embodiment of the arrangement, it is provided that the redundancy module is or has a half-bridge module which, in addition to the capacitor, has two series-connected switching elements, to each of which a diode is connected in parallel, wherein the series connection of the switching elements and thus the series connection the diodes is parallel to the capacitor, the diodes are polarized such that at a positive polarity of a current flowing through the half-bridge module, the capacitor can be charged at ^¬ switched switching elements and at a negative polarity of a current flowing through the half-bridge current of the capacitor when turned off

Switching elements can not be loaded, and the control device is designed such that it is the replacement operation of the multilevel converter and the mechanical

Switch off when the current through the Halbbrückenmo ^¬ module has the negative polarity or performs its zero crossing in the direction of negative polarity.

With respect to the arrangement of the redundant modules, it is considered in view of the distribution of electrical potentials within the Multilevelumrichters be advantageous if the Re ^¬ dundanzmodule are veau on a smallest possible Gleichspannungsni-. The redundancy modules are preferably connected directly or as directly as possible to AC voltage connections of the multilevel converter. It is insbeson ^¬ particular advantageous if more submodules between the DC voltage terminals of the Multilevelumrichters and the one or more redundancy modules are within series circuits containing the submodules and the redundant modules, as between the alternating-voltage terminals and the one or more redundancy modules.

The electrical energy for generating control or ignition signals for switching on the semiconductor switch and for switching off ^¬ the mechanical switch, for example for He ^¬ testify said Pulskamms, preferably removes the control device of the capacitors or the intermediate circuits of other submodules.

It is particularly advantageous in view of the electric potential distribution when the electric power for Erzeu ^¬ gene of control or trigger signals is removed (exclusively or at least, too) of a capacitor and the intermediate circuit of a submodule which is electrically adjacent as possible and at a similar Potential, at least not to unter ^¬ different potential, as the Schalteinrich ^¬ tion is triggered. It when an electrically immediately adjacent (ie directly connected to this switching device) submodule for energy extraction is ^zoomed in is particularly advantageous. The invention also relates to a method for operating a multilevel converter, which has a plurality of submodules connected in series, each having at least one capacitor and deliver in discharge phases by means of the capacitor current to the outside and record in charging phases current for charging the capacitor.

According to the invention it is provided that the Multilevelumrichter is operated in a normal operating mode, as long as the sub-modules, or a predetermined number of sub-modules is betriebsfä ^¬ hig, and if one of the sub-modules or sub ^¬ the predetermined number of operational submodules exceed at least one redundancy module activates is, by a switching device which is electrically connected in parallel to the redundancy module or one of the redundancy module having redundancy module series circuit, is switched from its normal in ^¬ operating mode switched state to its off state.

With regard to the advantages of the method according to the invention, reference is made to the above statements in connection with the multilevel converter according to the invention and the arrangement according to the invention. Preferably, after the opening of the switching device in the parallel redundancy modules, first

Submodule capacitors are charged so that the submodule's own sub-module power supply can ramp up, and then kept charged until the controller of the submodule

Multilevel converter or a submodule own control the

Control of the capacitor voltages of the submodule capacitors takes over.

Afterwards, the redundancy modules can be used like normal submodules for voltage formation. Before the transition to normal operation, it is possible to test the newly commissioned submodules (previously redundancy modules). The switching direction, in particular its semiconductor switch (preferably thyristor) can serve as protection during this test phase.

The invention will be explained in more detail with reference to exemplary embodiments; thereby show exemplarily:

Figure 1 shows an embodiment of a three-phase

 Multilevel converter equipped with a plurality of submodule devices, each having a plurality of submodules, and a plurality of redundancy devices, each having a plurality of redundancy modules,

FIG. 2 shows an exemplary embodiment of a submodule device which, in the multilevel converter according to FIG

1, wherein the Submodulein- direction submodules in the form of half-bridge modules, Figure 3 shows an embodiment of a Redundanzein ^¬ direction, which can be used in the Multilevelumrichter according to Figure 1, wherein the redundancy device submodules in the form of half-bridge modules,

4 shows an exemplary embodiment of a submodule device that can be used in the multilevel converter according to FIG. 1, the submodule device having submodules in the form of full bridge modules, FIG.

5 shows an exemplary example of a Redundanzein ^¬ device which can be used in the Multilevelumrichter according to FIG 1, wherein the redundancy danzeinrichtung submodules in the form of a full bridge modules comprising, FIG. 6 shows, by way of example, the time profile of a control ^signal which is suitable for repeated ignition of semiconductor switches of the redundancy devices according to FIGS. 3 and 5,

an exemplary embodiment of a redundancy ^¬ direction, which can be used in the Multilevelumrichter according to Figure 1, wherein an impedance is connected in series with a semiconductor switch of the redundancy device, and an embodiment of a Redundanzein ^¬ direction, which are used in the Multilevelumrichter according to FIG can, wherein in parallel with the semiconductor switches of the redundancy device in each case an impedance is connected in series.

For the sake of clarity, the same reference numbers are always used in the figures for identical or comparable components.

FIG. 1 shows an exemplary embodiment of a three-phase multilevel converter 5. This includes AC voltage terminals W5 for feeding or exiting alternating ^¬ current and two DC voltage terminals G5a and G5b, where a DC or a variable-time DC power is fed or removed. The direction of the energy flow and the time profile of the output voltage, whether at the AC voltage terminals W5 or the DC voltage terminals G5a and G5b, depends on the driving of submodule devices SME, which are connected in series in series circuits R1, R2 and R3. Such a control can be taken over by a central control device ZSE.

Each of the three series circuits Rl, R2 and R3 is in the embodiment of Figure 1 each with eight in series switched sub-module devices SME and two inductors L equipped. Between each of the two inductors L there is an intermediate connection Za, which lies in terms of potential between the four submodules SME in FIG. 1 and the four submodules SME in FIG. 1 and forms one of the three AC voltage connections W5 of the multilevel converter 5.

In each case four submodule devices SME form in the

Multilevel converter 5 according to FIG. 1, a submodule device group SG which lies electrically between one of the intermediate connections Z and one of the DC voltage connections.

In each of the Submoduleinrichtungsgruppen SG preferably at least one switching device T is present, which is connected in parallel to one of the submodule devices SME and makes them a redundancy RE: If the respective switching device T is turned on, the parallel submodule device SME is short-circuited and thereby deactivated. If the respective switching device T ^¬ turned off, so the parallel lying Submoduleinrichtung SME is activated so that this, like the other be ^¬-sensitive in operation Submoduleinrichtungen SME operates. The respective switching state of the switching device T ^¬ decision is thus made on the operating state of the parallel sub ^¬ module means SME or whether it is enabled and works as a normal Submoduleinrichtung or not. The already mentioned central control device ZSE is used in

Normal mode of operation monitor the operation of ^{befindli ¬} chen submodule devices SME. Presents them here that some or more of the actively operated Submo ^¬ duleinrichtungen SME or its sub-modules have failed, it will activate redundancy means RE directly or with the inclusion of a different local control means in the respective Submoduleinrichtungsgruppe SG so that they completely or (in the case of submodule devices with several submodules) can only partially replace failed submodule devices SME.

With regard to the arrangement of the redundancy devices RE within the series circuits R1 to R3, it is considered advantageous if they are at the lowest possible DC voltage level. For this reason, the redundancy ^¬ equipment RE within the series circuits Rl to R3 in the embodiment according to figure 1 are possible liehst directly or directly connected to the alternating-voltage terminals of the W5

Multilevel converter 5 connected. It is in particular ^¬ sondere advantageous if RE are within the series circuits Rl to R3 more Submoduleinrichtungen SME between the DC terminals and G5a G5b and the redundancy device as between the alternating-voltage terminals W5 and the redundancy device RE.

FIG. 2 shows an exemplary embodiment of a submodule device SME that can be used in the multilevel converter 5 according to FIG. The Submoduleinrichtung SME may comprise a single sub-module 10 or - as in the embodiment according to FIG 2 - a plurality of Submodu ^¬ len 10, which are connected in series. In the sub-modules 10 of Figure 2 is so-called half-bridge ^¬ modules, each comprising two switching elements 11, which may be each formed by a switching Halbleiterkompo ^¬ component, such as a transistor or the like. To each of the switching elements 11 ne 12 is connected in parallel. Parallel to the series ^{scarf ¬} tion of the switching elements 11 and the diodes 12 is a capacitor thirteenth

The outer terminals of the submodule device SME, which are used to form the series circuit Rl, R2, and R3, respectively, are identified by the reference symbols A1 and A2 (see also FIG. 1). FIG. 3 shows an exemplary embodiment of a redundancy ^device RE that can be used in the multilevel converter 5 according to FIG. The redundancy device RE may comprise a single redundancy module 20 or - as in the embodiment according to Figure 3 - a plurality of Redun ^¬ danzmodulen 20 connected in series and form a Redundanzmo ^¬ dulreihenschaltung 21st

The redundancy modules 20 according to FIG. 3 may be half-bridge modules, as have been described in connection with FIG. In other words, the redundancy modules 20 may be modules that are identical to the submodules 10 of the submodule device SME according to FIG. 2; With regard to the construction of the half-bridge modules or the redundancy modules according to FIG. 3, reference should therefore be made to the above explanations.

Parallel to the redundancy module series circuit 21, a switching device 100 is switched, which is switched on in the normal operating mode of the Multilevelumrichters 5 and switched off in Ersatzbe ^¬ operating mode of the Multilevelumrichter 5.

In the exemplary embodiment according to FIG. 3, the switching device 100 has a parallel circuit which comprises at least one mechanical switch 110 and a semiconductor switch 120 connected in parallel thereto. In the semiconductor switch 120 is preferably a Thyris ^¬ tor. The already mentioned central control device ZSE or one of the redundancy device RE assigned and this controlling another, local (preferably the central control device ZSE subordinate) control device LSE is preferably ^¬ designed such that they in the context of activation of the replacement operation of the Multilevelumrichters 5, ie before, during or after switching off the mechanical switch 110, to a control input E120, in particular ignition input, of the semiconductor switch 120 a periodic control signal ST, preferably a Pulskamm as in Figure 6 by way of example Darge ^¬ represents, applies.

The electrical energy for generating the control or ignition signal ST, for example, of the pulse comb according to FIG 6, ent ^¬ the controller ZSE or LSE preferably increases from the capacitors or the intermediate circuits of other sub-modules 10 of Figure 2 or other Submoduleinrichtungen SME according to FIG 1. it is particularly advantageous in view of the electric potential distribution in the series circuits Rl to R3 according to Figure 1, when the electric power for Erzeu ^¬ gene of the control or the ignition signal and the pulse comb Fi gur according ^¬ 6 by a capacitor or Discharge circuit of a Submo- module 10 is removed, which is as close as possible electrically and at a similar potential, at least not to unter ^¬ different potential as the semiconductor switch 120 is located. It is particularly advantageous if an electrically directly adjacent (ie directly connected to)

Submodule 10 is used.

If more other sub-modules 10 for energy extraction for the purpose of generating the control or Zündsig ^¬ Nals, for example, of the pulse comb according to Figure 6 are to be herangezo ^¬ gene so accordingly preferably also electrically adjacent or possible lying on similar potentials submodules chosen for reasons of redundancy.

The control device ZSE or LSE will preferably leave the semiconductor switch 120 switched on or repeatedly, in particular by means of the periodic control signal ST according to FIG. 6, until the mechanical switch 110 is completely switched off and deionized and the current passed through it falls below a predetermined threshold. The controller ZSE or LSE will monitor for this purpose, the current through the mechanical switch 110 is preferably by means of a not shown in the figures, the current sensor via ^¬. Alternatively or additionally, it may be provided that the control device ZSE or LSE the semiconductor switch 120 for a fixed predetermined period of time, which begins with the switching off of the mechanical switch 110 or with the generation or application of a corresponding turn-off, turned on, or repeated, in particular by means of periodic control signal according to Figure 6, turns on.

It is also advantageous if the control device ZSE or LSE is configured such that it switches the semiconductor switch 120 on again at a later time or can be switched on, provided that the voltage across the individual capacitors of the redundancy modules 20 reaches or exceeds a predetermined maximum voltage ^¬ and / or the sum voltage of the voltages of the capacitors of the redundancy module series circuit 21 reaches or exceeds a predetermined maximum sum voltage.

The outer terminals of the redundancy RE, which are used to form the series circuit Rl, R2, and R3 are designated by the reference characters AI and A2 (see also Figure 1).

FIG. 4 shows a further exemplary embodiment of a submodule device SME which can be used in the multilevel converter 5 according to FIG. The submodule device SME may comprise a single submodule 40 or, as in the exemplary embodiment according to FIG. 4, a multiplicity of submodules 40 which are connected in series.

In the submodules 40 according to Figure 4, there are so-called full-bridge modules, each of which includes four switching elements 41, which overall forms can be in each case by a switching Halbleiterkompo ^¬ component, such as a transistor or the like. To the switching elements 41, a diode 42 is connected in parallel in each case. The switching elements are connected in pairs in series. Parallel to the series scarf ^¬ lines is a capacitor 43. The outer terminals of the submodule device SME, which are used to form the series circuit Rl, R2, and R3, respectively, are identified by the reference symbols A1 and A2 (see also FIG. 1).

FIG. 5 shows a further exemplary embodiment of a redundancy device RE which can be used in the multilevel converter 5 according to FIG. The Redundanzeinrich- tung RE may comprise a single redundancy module 50 or - as in the embodiment according to Figure 5 - a plurality of redundancy modules 50 connected in series and form a Re ^¬ dundanzmodulreihenschaltung 51st The redundancy modules 50 according to FIG. 5 may be full-bridge modules, as have been described in connection with FIG. 4; With regard to the structure of the full bridge modules or the redundancy modules 50 according to FIG. 5, reference should therefore be made to the above explanations.

Parallel to the module row redundancy circuit 51, a switching device 500 is connected in parallel, which is turned on in Normalbe ^¬ operating mode of the Multilevelumrichters 5 and is turned off in the replacement mode of operation Multilevelumrichters. 5

The switch means 500 comprises in the embodiment according to FIG 5 to a parallel circuit comprising at least egg ^¬ NEN mechanical switch 110 and switched in parallel to two ended semiconductor switch 120th The semiconductor switches 120 are preferably thyristors, which are connected in parallel or opposite polarity. The above-mentioned central controller ZSE or one of the redundancy device RE assigned to other, local STEU ^¬ ereinrichtung LSE is preferably designed such that they in connection with the activation of the replacement operation of the Multilevelumrichters 5, before then, during or after the off ^¬ switch of the mechanical switch 110, to the control inputs of the semiconductor switches 120 E120 periodic control signals ST, preferably combs pulse is shown by way of example in Figure 6, applies.

The electrical energy for generating the control and ignition ^¬ signals such as the pulse combs according to Figure 6, takes the control device ZSE or LSE preferably capacitors of the intermediate circuits con- or the other sub-modules 10 or 40 according to Figure 2 or 4 or other Submodule devices SME according to FIG. 1. In view of the electrical potential distribution in the series circuits R1 to R3 according to FIG. 1, it is particularly advantageous if the electrical energy for generating the control or ignition signals or the pulse combs according to FIG or intermediate circuit of a submodule 10 is removed, which is as close as possible electrically and at a similar potential, at least not to ^¬ different potential as the semiconductor switch 120 is located. It is particularly advantageous if an electrically directly adjacent (ie, directly connected to the semiconductor ^switches 120) submodule 10 is used.

If, for reasons of redundancy, a plurality of other submodules 10 are to be used to generate energy for the purpose of generating the control or ignition signals, it is accordingly preferable to also choose electrically adjacent as possible and lying at similar potential submodules. The control device ZSE or LSE will preferably leave the semiconductor ^scarf ter ^¬ ter 120 turned on or repeatedly, in particular by means of the periodic control signal ST according to Figure 6, turn on until the mechanical switch 110 is turned off and the current passed through it falls below a predetermined threshold ne. For this purpose, the control device ZSE or LSE will monitor the current through the mechanical switch 110, preferably by means of a current sensor, not shown in the figures. Alternatively or additionally, it may be provided that the control device ZSE or LSE the semiconductor switches for a fixed period of time after the mechanical switch 110 or the generation or application of a corresponding disconnection command to the power off with 120 turned on, or as derholt ^¬, in particular by means of the periodic Control signal ST according to Figure 6, turns on. It is also advantageous if the control device ZSE or LSE is configured such that it switches the semiconductor switch 120 on again at a later time or leaves it on, provided that the voltage across the individual capacitors of the redundancy modules 50 reaches or exceeds a predetermined maximum voltage and / or or the sum voltage of the voltages of the capacitors of the redundancy module series circuit 51 reaches or exceeds a predetermined sum maximum voltage. The outer terminals of the redundancy device RE, the

Formation of the series circuit Rl, R2, or R3 are used, are denoted by the reference numerals AI and A2 (see also Figure 1). 6 shows an exemplary embodiment of the amplitudes ^¬ running a control signal ST, which constitutes a pulse sequence or a pulse comb, over the time t. The control signal ST is suitable for repeated or periodic switching on of the semiconductor switches 120 according to FIGS. 3 and 5.

FIGS. 7 and 8 show further exemplary embodiments of redundancy devices RE which can be used in the multilevel converter 5 according to FIG. In these exemplary embodiments, for example for the purpose of current limitation, an impedance Z is in each case connected in series with the semiconductor switches 120. Incidentally, the impedance Z can serve to intentionally cause a voltage drop, which in turn causes the charging of the capacitors of the redundancy mode. specifically influenced. Preferably, the semiconductor switch lying with the Impe ^¬ impedance Z in series is opened only 120 in this case are when the capacitors of the Redundanzmo ^¬ modules sufficiently, so charged, for example, to a predetermined minimum voltage and the redundant modules are be ^¬ drive capable.

When the impedance Z is preferably an ohmic resistor, an inductor or a combination of an inductor and a resistor, ^¬ example, in the form of a series or parallel connection.

The impedance Z may, for example, be one in which the real part is at least 10 times larger in magnitude than the imaginary part.

Although the invention in detail by preferred execution ^¬ examples has been illustrated and described in detail, the invention is not limited by the disclosed examples and other variations can be derived therefrom by the skilled artisan without departing from the scope of the invention.

Reference sign list

5 multilevel converters

 10 submodule

11 switching element

 12 diode

 13 capacitor

 20 redundancy module

 21 redundancy module series connection

40 submodule

 41 switching element

 42 diode

 43 capacitor

 50 redundancy module

51 redundancy module series connection

 100 switching device

 110 mechanical switch

 120 semiconductor switch

 500 switching device

AI external connection of the submodule device

A2 outer terminal of the submodule device

E120 control input

 G5a DC voltage connection

G5b DC voltage connection

 L inductance

 LSE local control device

 Rl series connection

 R2 series connection

R3 series connection

 RE redundancy device

 SG Submodule Setup Group

 SME submodule device

 ST control signal

t time

 T switching device

 W5 AC connection

Z impedance intermediate terminal

central control device

Claims

claims

1. Multilevel converter (5) with a plurality of submodules (10, 40) connected in series, each of which has at least one

Have condenser (13, 43) and deliver in discharge phases by means of the capacitor (13, 43) current to the outside and record in La ^¬ dephasen current to charge the capacitor (13, 43),

d a d u r c h e c e n c i n e s that

the Multilevelumrichter (5) has at least one redundancy module (20, 50) which is in a normal operating mode of the Multilevelumrichters (5) is inactive and in a replacement ^¬ operation mode of the Multilevelumrichters (5) as a submodule (10, 40) operates, and

to the redundancy module (20, 50) or to the Redun ^¬ danzmodul (20, 50) having redundancy module series circuit (21, 51) switching means (100, 500) is connected in parallel, the switched on in normal operation mode, and is turned off in the replacement mode.

2. multilevel converter (5) according to claim 1,

d a d u r c h e c e n c i n e s that

 at least two submodules (10, 40) of the

 Multilevel converter (5) Redundancy modules (20, 50) are and

the at least two redundancy modules (20, 50) are electrically connected in series and form the redundancy ^{module series} circuit (21, 51).

3. multilevel converter (5) according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

the switching device (100, 500) has a mechanical switch (110).

4. Multilevel converter (5) according to one of the preceding claims, characterized in that

the switching device (100, 500) has a parallel circuit which comprises at least one mechanical switch (110) and a further switch connected in parallel thereto, which is preferably a semiconductor switch

(120) and / or with which preferably an impedance is connected in series.

5. Multilevel converter (5) according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

within series circuits (R1, R2, R3) containing the submodules (10, 40) and the redundancy modules (20, 50), more submodules (10, 40) between DC voltage connections (G5a, G5b) of the multilevel converter (5) and the one or more Re ^¬ dundanzmodulen (20, 50) than between alternating voltage terminals (W5) of the Multilevelumrichters (5) and the redundancy or the modules (20, 50).

6. multilevel converter (5) according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

- The switching device (100, 500) comprises a parallel circuit comprising at least one mechanical switch (110) and two parallel unidirectionally scarf ^¬ tende semiconductor switch (120),

 - Wherein the unidirectionally switching semiconductor switch (120) are connected in opposite polarity.

7. Multilevel converter (5) according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

 - The switching device (100, 500) comprises a parallel circuit comprising at least one mechanical switch (110) and two parallel connected thyristors,

- Wherein the thyristors are connected in opposite polarity.

8. Arrangement with a multilevel converter (5) according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

the arrangement or the Multilevelumrichter (5) itself has a control device (ZSE, LSE) connected to the mechanical switch (110) and the at least one semiconductor scarf ^¬ ter (120) is in communication.

9. Arrangement according to claim 8,

d a d u r c h e c e n c i n e s that

- The redundancy module (20, 50) is or has a half-bridge module, in addition to the capacitor (13, 43) two series-connected switching elements (11, 41), to which each Weil ^¬ a diode (12, 42) is connected in parallel , up, wherein the series circuit (Rl, R2, R3) of the switching ^¬ elements (11, 41) and thus the series circuit (Rl, R2, R3) of the diodes (12) parallel to the capacitor (13, 43) .

 - The diodes (12) are polarized such that at a positive polarity of a flowing through the half-bridge module

Current of the capacitor (13, 43) when switched off

Switching elements (11, 41) can be charged with a negative polarity and a flowing ^¬ sequent by the half-bridge module current of the capacitor (13, 43) in its powered-down switching elements (11, 41) can not be loaded, and

- The control device (ZSE, LSE) is designed such that it activates the replacement operation of the Multilevelumrichters (5) and the mechanical switch (110) turns off when the current through the half-bridge module has the negative Po ^¬ larity or its zero crossing in the direction of negative polarity performs.

10. Arrangement according to one of the preceding claims 8 to 9,

d a d u r c h e c e n c i n e s that

the control device (ZSE, LSE) is designed in such a way that it is activated as part of the activation of the replacement operation of the Multilevelumrichters (5), ie before, during or after switching off the mechanical switch (110) to a control input, in particular ignition, the semiconductor switch (120) or the semiconductor switch (120) a periodic control signal (ST), in particular a pulse comb applies ,

11. Arrangement according to one of the preceding claims 8 to 10,

d a d u r c h e c e n c i n e s that

the control device (ZSE, LSE) is designed such that it makes the semiconductor switch (120) or the semiconductor switch (120) is turned on or repeated insbeson ^¬ particular by means of a periodic control signal (ST), Power On ^¬ tet until it, in particular from the Redundancy module (20, 50), receives a signal indicating the off state of the mecha ^¬ African switch (110).

12. Arrangement according to one of the preceding claims 8 to 9,

d a d u r c h e c e n c i n e s that

the control device (ZSE, LSE) is designed such that it can be turned on the semiconductor switch (120) or the semiconductor switch (120) or repeated insbeson ^¬ particular by means of a periodic control signal (ST) switching on tet, namely for a fixed period after this

Turning off the mechanical switch (110) or applying a turn-off command to the mechanical switch (110).

13. Arrangement according to one of the preceding claims 8 to 12,

d a d u r c h e c e n c i n e s that

the control device (ZSE, LSE) is designed in such a way that it switches on or keeps the semiconductor switch (120) or the semiconductor switches (120) switched on, when the voltage across a capacitor (13, 43) of the redundancy module

(20, 50) reaches or ^exceeds a predetermined maximum voltage and / or the sum voltage of the voltages of the capacitors of the redundancy module series circuit (21, 51) predetermined sum maximum voltage reached or exceeded ^¬ tet.

14. Arrangement according to one of the preceding claims 8 to 13,

d a d u r c h e c e n c i n e s that

the electrical energy for generating control signals for the switching device (100, 500) is taken exclusively or at least also from a capacitor (13, 43) or an intermediate circuit of a submodule (10, 40) which is electrically connected to this switching device (100, 500) is directly connected.

15. Method for operating a multilevel converter (5), which has a plurality of submodules connected in series (10,

40), each having at least one capacitor (13, 43) and deliver in discharge phases by means of the capacitor (13, 43) current to the outside and receive in charging phases current for charging the capacitor (13, 43),

d a d u r c h e c e n c i n e s that

 the multilevel converter (5) is operated in a normal operating mode as long as the submodules (10, 40) or a predetermined number of submodules (10, 40) are operable, and

- upon failure of one of the submodules (10, 40) or at reduced ^¬ exceed the predetermined number of operational submodules (10, 40) at least one redundancy module (20, 50) is activated by a switching device (100, 500) electrically connected to the Redundancy module (20, 50) or one of the redundancy module (20, 50) having Redundanzmodulrei ^¬ henschaltung (21, 51) is connected in parallel, is switched from its in the normal operating mode switched state in its off state.