WO2022017618A1

WO2022017618A1 - Assembly and method for operating same

Info

Publication number: WO2022017618A1
Application number: PCT/EP2020/070906
Authority: WO
Inventors: Dominik ERGIN; Felix Kammerer; Sebastian Müller
Original assignee: Siemens Aktiengesellschaft
Priority date: 2020-07-24
Filing date: 2020-07-24
Publication date: 2022-01-27
Also published as: EP4162599A1

Abstract

The invention relates inter alia to an assembly (400) having a first converter (10, 401, 402) and a second converter (10, 401, 402), which each have a direct voltage side (12), wherein both direct voltage sides are in each case connected to one another with a connection and with a common reference potential (BP) and form with the other connection in each case a direct voltage connection (411, 412) of a common direct voltage system (410). According to the invention, it is provided that the converters (10, 401, 402) each have each a central device (ZE) which is designed to transmit at least one voltage specification (Uaus,soll) relating to switched-off partial modules (TM) to module control devices (MSE) of their module devices (ME1-ME6) and to transmit at least one value (W1, W2) to the central device (ZE) of the respective other converter (10, 401, 402), wherein the converter-related voltage specification (Uaus,soll) depends on at least one value (W1, W2) which the respective central device (ZE) receives from the central device (ZE) of the respective other converter (10, 401, 402).

Description

description

Arrangement and procedure for its operation

The invention relates to arrangements with converters and methods for their operation.

The publication "Modular Multilevel Converter:

A universal concept for HVDC networks and extended DC bus applications" (R. Marquardt, 2010 International Power

Electronics Conference, pages 502 to 507, 978-1-4244-5393-1/10, 2010 IEEE) discloses an electrical converter in the form of a multilevel converter, which has an at least two-phase AC voltage side with at least two AC voltage connections, a DC voltage side and modular devices comprises, each having a series circuit with at least two sub-modules electrically connected in series. The sub-modules each comprise an energy store and at least two switching elements, of which at least one switching element is switched on when the sub-module is switched on or off and all switching elements are switched off in the blocked operating state.

A multilevel converter with a different type of sub-modules is known from the international publication WO 2015/036149 A1.

Converters of the type described can be connected to form arrangements comprising a first converter and a second converter, each having a DC voltage side. The DC voltage sides can each be connected to one another and to a common reference potential with one connection and each form a DC voltage connection of a common common DC voltage system with the other connection. The object of the invention is to specify an arrangement with converters which enables the converter to be operated in a particularly advantageous manner.

According to the invention, this object is achieved by an arrangement having the features according to patent claim 1 . Advantageous refinements of the arrangement according to the invention are specified in subclaims.

According to the invention, it is provided that the module devices each have a module control device for controlling the sub-modules of their respective module device, the converters each have a central device that is designed to provide the module control devices of the module devices of their own converter with at least one voltage specification that affects switched-off sub-modules , to transmit stuffs and to transmit at least one value to the central device of the other converter in each case, the converter-related voltage specification depending on at least one value that the respective central device receives from the central device of the other converter in each case, and the module devices are each designed for this are to meet the voltage specification of their central facility, or at least approximately to meet them, by switching none, one or more of their sub-modules to the switched-off operating state.

A major advantage of the arrangement according to the invention is that due to the exchange of values between the converters provided according to the invention and the determination of voltage specifications that relate to switched-off sub-modules, both symmetrical operation, for example when precharging the converter after commissioning, is relatively to each other as well as a symmetrical operation can be achieved relative to the common reference potential. DC currents via the reference potential can be avoided or at least reduced. The sub-modules preferably each have a sub-module control device. The sub-module control devices preferably determine the operating state of their sub-modules by controlling the switching elements.

It is advantageous if the converters, after commissioning, in which all sub-modules are initially in the blocked operating state and the sub-module control devices are not yet capable of communication due to the lack of sufficient charge of their assigned energy storage devices, are first switched to charging mode, and the sub-module control devices each with it their assigned Modulsteuerein device communicate as soon as they have become capable of communication during charging, and the central devices gene the module control devices of their converter at least during charging the voltage specification, which relates to switched sub-modules, transmit.

It is particularly advantageous if, after commissioning, in which all sub-modules are initially in the blocked operating state and the sub-module controller is not yet capable of communication due to the lack of a sufficient state of charge of its assigned energy stores, the converters first switch to a charging mode that includes at least a first and a two te charging phase includes, are shifted, and the central devices transmit the voltage specification, which relates to switched-off sub-modules, to the module control devices of their converter at least in the second charging phase of the charging operation. One advantage of the latter configuration is that the converters can make a transition from the first charging phase to the second charging phase in each of the module devices, even if not all sub-modules of the module device in question are capable of communication and therefore cannot yet be controlled. By specifying the voltage specification, the module devices can advantageously already be transferred to an optimized charging mode in the second charging phase, in which some of the sub-modules whose energy stores are at least for a communication drive are already sufficiently charged, continue to be charged in a targeted manner and others are specifically excluded from further charging. This procedure makes it possible, for example, for some of the sub-modules to have much higher charging voltages than others or the average of the sub-modules at the time when all sub-modules of all modular devices are capable of communication and can therefore be controlled. A further advantage of the last-mentioned embodiment can be seen in the fact that by specifying the voltage specification, asymmetries between the charging states of the module devices are minimized in a targeted manner or their occurrence can be prevented or at least prevented as best as possible; For example, if the first voltage specification is selected to be greater for one of the module devices than for another module device, the total voltage of the partial module voltages in the first-mentioned module device will rise less quickly than in the second-mentioned module device, and vice versa.

It is advantageous if the specified voltage threshold is dimensioned in such a way that it is reached or exceeded even if not all sub-modules of the respective module device are capable of communication.

The module control devices are preferably designed to transmit voltage values transmitted by the sub-module control devices or sum values derived therefrom to the higher-level central device of their converter.

The central devices are preferably designed to switch over those of their module control devices in which the sum of the transmitted voltage values or the transmitted total value reaches or exceeds a predetermined voltage threshold from the first to the second charging phase of the charging operation by providing these module control devices with the voltage specification, which relates to switched off sub-modules. The voltage specification for the first and second converters is preferably changed in each case until the difference value, which indicates the difference between the operating points of the converters, is zero or falls below a predetermined limit.

The voltage specification for the first and/or second converter preferably depends on a voltage difference between a first partial voltage, which is present between the two connections on the DC voltage side of the first converter, and a second partial voltage, which is present between the two connections on the DC voltage side of the second converter applied, from.

It is advantageous if the voltage specification for the first converter is increased when the first partial voltage is greater than the second partial voltage, and reduced when the second partial voltage is greater than the first partial voltage, and/or the voltage specification for the second converter is reduced is decorated when the first partial voltage is greater than the second partial voltage, and is increased when the second partial voltage is greater than the first partial voltage.

Alternatively or additionally, the voltage specification for the first and/or second converter can advantageously depend on the energy difference between the energy stored in the energy stores of the first converter and the energy stored in the energy stores of the second converter.

It is particularly advantageous if the voltage specification for the first and/or second converter depends on the energy difference between a first mean value, which is formed by averaging the energies stored in the module devices of the first converter, and a second mean value, which is formed by averaging the energies stored in the module devices of the second converter are formed. With regard to an exchange of energy values, it is also considered advantageous if the voltage specification for the first converter depends on the level of an energy difference between the energy stored in the energy stores of the first converter and the energy stored in the energy stores of the second converter, specifically is increased when a first energy value indicating the energy stored in the first converter is greater than a second energy value indicating the energy stored in the second converter, and is reduced when the second energy value is greater than the first energy value, and/or the voltage specification for the second converter is increased when the second energy value is greater than the first energy value and decreased when the first energy value is greater than the second energy value.

The charging operation is preferably carried out from the common DC voltage system, and the voltage specifications for the first converter and the second converter are preferably determined according to:

Uout,soll = f(Udc, Uacl, Ufinal,soll, t, kp, El, E2,

Vaus,soll,maxi) and

Uout,soll2 = f(Udc, Uac2, Ufinal,soll, t, kp, El, E2,

Uoff,set,max2) and

Vac1 designates the AC voltage present on the AC voltage side of the first converter and Vac2 the AC voltage present on the AC voltage side of the second converter. Uout,setpoint denotes the voltage specification for the first converter and Uout,setpoint2 the voltage specification for the second converter. Ufinal,soll designates the target voltage sum from the sub-module voltages of the module devices present at the energy stores of the sub-modules after the end of the charging phase and at the beginning of normal operation for both converters, from the operating point of the two to be set converter at the start of normal operation, kp designates an adjustable amplification factor, El an energy value which specifies the energy stored in the energy stores of the first converter, and E2 an energy value which specifies the energy stored in the energy stores of the second converter, f designates a function that increases over time t, preferably in steps or ramps, from zero to a respective maximum value

Uout,set,maxi = Ufinal,set - 0.25*Udc-0.5Uacl + kp(El-E2) or

Uout,set,max2 = Ufinal,set - 0.25*Udc-0.5Uac2 + kp(E2-El) increases.

The invention also relates to a converter, in particular for an arrangement as described above, the converter having a DC voltage side and comprising modules that each have a series connection with at least two sub-modules electrically connected in series, and each sub-module has an energy store and at least two switching elements, of which at least one switching element is switched on when the partial module is switched on or switched off, and all switching elements are switched off in the blocked operating state. According to the invention, it is provided that the module devices each have a module control device for controlling the sub-modules of their respective module device, the converter has a central device that is designed to transmit at least one voltage specification, which relates to switched-off sub-modules, to the module control devices of its own module devices and to transmit at least one value to a central facility of another converter, with the converter-related voltage specification depending on at least one value that the respective central facility receives from the central facility of the other converter, and the module facilities are each equipped for this are formed to meet the voltage specification of their central facility, or at least approximately to meet them, by putting none, one or more of their sub-modules into the switched-off operating state.

With regard to the advantages and advantageous configurations of the converter according to the invention, reference is made to the above statements in connection with the arrangement according to the invention and its advantageous configurations.

The invention also relates to a central device for a converter as described above and for an arrangement as described above. According to the invention, it is provided that the central device is designed to transmit at least one voltage specification, which relates to switched-off sub-modules, to module control devices assigned to module devices and to transmit at least one value to a central device of another converter, the converter-related voltage specification having at least one value depends, which the respective central facility receives from the central facility of the other converter.

With regard to the advantages and advantageous configurations of the central device according to the invention, reference is made to the above statements in connection with the arrangement according to the invention and its advantageous configurations.

The invention also relates to a Modulsteuerein direction for a converter, as described above, or an arrangement as described above. According to the invention, it is provided that the module control device is designed to transmit voltage values transmitted by sub-module control devices or sum values derived therefrom to a higher-level central device, and this is also designed to meet a voltage specification of the central device by switching at least one sub-module capable of communication into the switched-off operational state. With regard to the advantages and advantageous configurations of the module control device according to the invention, reference is made to the above statements in connection with the arrangement according to the invention and its advantageous configurations.

The invention also relates to a method for operating an arrangement with a first converter and a second converter, each of which has a DC voltage side, with the two DC voltage sides being connected to one connection and to a common reference potential and to the other Each connection forms a DC voltage connection of a common community DC voltage system, the converters each comprising module devices which each have a series circuit with at least two sub-modules electrically connected in series, and the sub-modules each comprise an energy store and at least two switching elements, one of which is switched on or switched off operating state of the sub-modules at least one switching element is switched on and in the blocked operating state all switching elements are switched off. According to the invention, it is provided that the module devices each have a module control device that controls the sub-modules of their respective module device, a central device transmits at least one voltage specification, which relates to switched-off sub-modules, to the module control devices of the module devices of its own converter, and at least one value to the central device of the transmitted to the other converter in each case, with the converter-related voltage specification depending on at least one value that the respective central device receives from the central device of the other converter in each case, and the module devices meet the voltage specification of their central device or at least approximately meet it by not having one, one or more their sub-modules into the switched-off operating state. With regard to the advantages and advantageous configurations of the method according to the invention, reference is made to the above statements in connection with the arrangement according to the invention and its advantageous configurations.

The invention is explained in more detail below with reference to exemplary embodiments; show examples:

Figure 1 shows an embodiment of an inventive

Arrangement,

FIG. 2 shows an exemplary embodiment of a converter according to the invention, which can be used in the arrangement according to FIG.

Figure 3 shows a first embodiment of a for

Converter according to Figure 2 suitable sub-module,

FIG. 4 shows a second exemplary embodiment of a partial module suitable for the converter according to FIG. 2,

Figure 5 shows an embodiment of a Modulsteuerein direction, and

FIG. 6 shows an exemplary embodiment of a central device according to the invention.

For the sake of clarity, the figures always use the same reference symbols for identical or comparable components.

FIG. 1 shows an arrangement 400, which includes a first converter 401 and a second converter 402 and is designed in what is known as a “bipole rigid” topology. Each of the two converters 401 and 402 has a first connection side and a second connection side. The first two connection sides are each three-phase AC voltage sides 11, which have three AC voltage connections WS1-WS3.

The two second connection sides are DC voltage sides 12, one connection of which is connected to one another and via an impedance Z to a common reference potential BP, and the other connection forms a DC voltage connection 411 and 412 of a common common DC voltage system 410. In the following, it is assumed, for example, that the reference potential BP is ground potential and the impedance Z is a ground impedance.

One challenge is to precharge the converters 401 and 402 and the common DC voltage system 410 after commissioning for high-voltage direct current transmission (= HVDC/HVDC), namely via the DC voltage connections 411 and 412 and via a line system 420 connected to them. The line system 420 for the two DC voltage connections 411 and 412 is shown in FIG. 1 in a greatly simplified form in the form of two equivalent capacitors Cdc.

If the converters 401 and 402 are started up independently of one another, a current flow I to the reference potential (i.e. current I

0) occur. Since the connection to the ground potential is implemented in the form of the grounding impedance Z, there is a significant energy input into the grounding impedance Z due to the current flow I. This energy input is undesirable because it negatively affects the design and the costs of the grounding connection. Furthermore, due to the current flow I via the earth impedance Z, a potential shift of the arrangement 400 relative to earth potential can occur.

The purpose of the mode of operation of the converters 401 and 402 described below is to avoid an excessive potential shift at the ground connection during charging and thus to keep the current flow via the earth connection within small, defined limits. As will be explained in detail below, the charging operation preferably takes place in at least two charging phases.

The converters 401 and 402 according to Figure 1 each have a central device ZE, which is designed to provide module devices ME1-ME6 of their own converter with a voltage specification Uout,setpoint or Uout,setpoint2, which switched off sub-modules TM (cf. Figure 2 ) relates to determining how to transmit at least one value W1 or W2 to the central device ZE of the other converter in each case.

The converter-related voltage specifications Uout,setpoint and Uout,setpoint2, which each converter 401 and 402 determines, each also depend on the value W1 or W2 that the respective central device ZE receives from the central device ZE of the other converter in each case.

The module devices ME1-ME6 are each designed to meet or at least approximately meet the voltage specification Uout,setpoint or Uout,setpoint2 of their central device ZE by switching none, one or more of their submodules TM to the switched-off operating state.

The values W1 and W2 received from the other converter allow each of the two converters 401 and 402 to change its voltage specification Uout,setpoint or Uout,setpoint2 in such a way that a difference value indicating the difference between the operating points of the converters 401 and 402 is zero amounts to or falls below a predetermined limit.

It is advantageous if the voltage specifications Uout,setpoint or Uout,setpoint2 for the converters 401 and 402 are based on a voltage difference between a first partial voltage Udcl, which is present between the two terminals of the DC voltage side 12 of the first converter 401, and a second partial voltage Udc2 which is between the two terminals of the DC voltage side 12 of the second converter 402 is applied depends.

For example, the voltage specification Uout,setpoint for the first converter 401 can be increased when the first partial voltage Udcl is greater than the second partial voltage Udc2, and reduced when the second partial voltage Udc2 is greater than the first partial voltage Udcl. In a corresponding manner, the voltage specification Uout,setpoint2 for the second converter 401 and 402 can be reduced when the first partial voltage Udcl is greater than the second partial voltage Udc2, and increased when the second partial voltage Udc2 is greater than the first partial voltage Udcl. With such an embodiment, the values W1 and W2 exchanged between the converters 401 and 402 preferably also indicate at least the first partial voltage Udcl and the second partial voltage Udc2.

It is also advantageous if the voltage specifications Uaus,soll and Uaus,soll2 for the first and second converter 401 and 402 are based on the energy difference between the energy stored in the energy stores ES (see FIGS. 2 to 6) of the first converter 401 and the energy stored in the energy store ES of the second converter 402 . In such a configuration, the values W1 and W2, which are exchanged between the converters 401 and 402, preferably also indicate at least energy values which describe the energy stored in the energy stores ES.

For example, the voltage specification Uout,setpoint for the first converter 401 and the voltage specification Uout,setpoint2 for the second converter 402 can be based on the energy difference between a first mean value, which is formed by averaging the energies stored in the modules of the first converter 401, and a second mean value, which is formed by averaging the energies stored in the module devices of the second converter 402. In such an embodiment, the values W1 and W2 ranging between the converters 401 and 402 are exchanged, preferably at least also the average values described.

It is particularly advantageous if the voltage specification Uout,soll for the first converter 401 depends on the level of an energy difference between the energy stored in the energy stores of the first converter 401 and the energy stored in the energy stores of the second converter 402, namely increased when a first energy value indicative of the energy stored in the first converter 401 is greater than a second energy value indicative of the energy stored in the second converter 402, and is reduced when the second energy value is greater than the first energy value. Alternatively or additionally, the voltage specification for the second converter 402 can be increased if the second energy value is greater than the first energy value and reduced if the first energy value is greater than the second energy value. In such an embodiment, the values W1 and W2 exchanged between the converters 401 and 402 preferably also indicate at least the described energy values.

It is particularly simple and advantageous if the voltage specifications Uout,setpoint and Uout,setpoint2 for the first converter 401 and the second converter 402 are determined during charging from the common DC voltage system 410 according to:

Uout,soll = f(Udc, Uacl, Ufinal,soll, t, kp, El, E2,

Vaus,soll,maxi) and

Uout,soll2 = f(Udc, Uac2, Ufinal,soll, t, kp, El, E2,

Uoff,set,max2) and

Uacl designates the AC voltage applied to the AC voltage side 11 of the first converter 401 (e.g. as amplitude or effective value of the phase-to-phase voltage) and Uac2 the AC voltage side 11 of the second converter ters 402 applied AC voltage (e.g. as amplitude or effective value of the phase-to-phase voltage). Ufinal,soll designates a target voltage sum from the sub-module voltages of the module devices present at the energy stores ES of the sub-modules TM (see Figures 2 to 6) after the end of the charging phase and at the beginning of normal operation for both converters 401 and 402, which range from the operating point to be set to the both converters 401 and 402 at the beginning of normal operation depends. kp is an adjustable gain factor. El designates an energy value, which is transmitted as value W1 to the second converter 402 and indicates the energy stored in the energy stores ES of the first converter 401 . E2 denotes an energy value, which is transmitted as value W2 to the first converter 401 and indicates the energy stored in the energy stores ES of the second converter 402. f is a function that increases over time t, preferably in steps or ramps, from Zero to a respective maximum value

Uout,set,maxi = Ufinal,set - 0.25*Udc-0.5Uacl + kp(El-E2) Uout,set,max2 = Ufinal,set - 0.25*Udc-0.5Uac2 + kp(E2- El) increases.

FIG. 2 shows an exemplary embodiment of a converter 10, which can be used as a first converter 401 and as a second converter 402 in the arrangement 400 according to FIG. For the further explanations below, it is assumed by way of example that the converter 10 is used as the converter 401 in the arrangement 400 according to FIG.

In the exemplary embodiment according to FIG. 2, the DC voltage side 12 has two DC voltage terminals G1 and G2. The DC voltage connection G1 at the top in FIG. 2 can form the DC voltage connection 411 of the common community DC voltage system 410 according to FIG. The lower in the figure 2 DC voltage terminal G2 can the impedance Z can be connected to the common reference potential BP according to FIG.

The converter 10 includes six module devices ME-ME6, each of which has a series connection with two or more sub-modules TM electrically connected in series and a module control device MSE for controlling the sub-modules TM of the respective module device ME-ME6. The module control devices MSE are connected to a higher-level central device ZE of the converter 10 via communication lines, which are not shown in detail in FIG. 2 for reasons of clarity.

The sub-modules TM each comprise a sub-module control unit TMSE, an energy store ES (see Figures 3 and 4) and at least two switching elements, of which at least one switching element is switched on both when the sub-module TM is switched on and when it is switched off and in the blocked operating state of the sub-module all switching elements are switched off. The sub-module control device TMSE determines the operating state of its sub-module TM by activating the switching elements.

FIG. 3 shows an exemplary embodiment of a partial module TM in the form of what is known as a half-bridge module, which can be used in converter 10 according to FIG. The partial module TM according to FIG. 3 comprises two switching elements S1 and S2, each of which is formed by a transistor and a freewheeling diode connected in parallel, and an energy store ES in the form of a capacitor. In addition, FIG. 3 shows the submodule control device TMSE, which controls the two switching elements S1 and S2.

FIG. 4 shows an exemplary embodiment of a partial module TM in the form of a so-called full-bridge module, which can be used in converter 10 according to FIG. The partial module TM comprises four switching elements S1 to S4, each of which is connected by a transistor and a parallel-connected release Running diode are formed, and an energy store ES in the form of a capacitor. In addition, FIG. 4 shows the submodule control device TMSE, which controls the four switching elements S1 to S4.

Referring again to FIG. 2, the module control devices MSE in the converter 10 are suitable in normal operation to ensure a predetermined flow of energy between the two connection sides 11 and 12 of the converter 10 by activating the submodule control devices TMSE of their submodules TM.

However, after the converter 10 has been started up, the sub-module control devices TMSE are not yet able to communicate due to a lack of sufficient charging status of their associated energy store ES; the sub-module control devices TMSE can also not yet activate their associated switching elements S1-S2 according to FIG. 3 or S1-S4 according to FIG. 4, which is why the switching elements are also still switched off. In other words, after start-up for each module device ME1-ME6, all sub-modules TM are initially in the blocked operating state because the energy stores ES are not yet sufficiently charged and therefore none of the switching elements can be switched on.

For this reason, after the converter 10 has been put into operation, it is first put into a charging mode that includes a first and a second charging phase. As will be explained in more detail below, the charging operation can take place from the AC voltage side 11 or the DC voltage side 12 by applying an AC voltage to the AC voltage connections WS1-WS3 or a DC voltage to the DC voltage connections G1 and G2. In the following, it is assumed, for example, that the converter 10 is charged from the common DC voltage system 410 according to FIG. 1, ie on the DC voltage side 12. As soon as the sub-module control devices TMSE are able to communicate during the first charging phase, because their energy stores ES are sufficiently charged and can provide operating energy, they each begin to communicate with their assigned module control device MSE. As part of the communication, the sub-module control devices TMSE each transmit voltage values U, which indicate the respective voltage at their energy store ES, to the module control device MSE that is higher than them.

The module control devices MSE in turn transmit the voltage values U transmitted by the sub-module control devices TMSE or total values Sui (with i=1, 2, the superordinate central facility ZE. The index i identifies the assigned module device MEi, ie ME1-ME6, and thus its module control devices MSE. Since the converter 10 according to FIG. 2 has six module control devices MSE, six cumulative values Sul-Su6 are transmitted to the central device ZE.

The central device ZE is designed to switch those module control devices MSE, in which the sum of the transmitted voltage values or the transmitted total value already reaches or exceeds a specified voltage threshold Smin, to the second charging phase of the charging operation by providing these module control devices MSE with a voltage specification Uout, is to, which relates to switched-off sub-modules TM, transmitted. In other words, the modular devices ME1-ME6 are each individually placed in the second charging phase as soon as they qualify for it.

Specifically, the voltage specification Uout,should preferably define the total voltage that switched-off sub-modules should reach. The module devices ME1-ME6 are designed to meet the voltage specification Uout, set or at least as best as possible by putting none, one or more of their communication-capable sub-modules TM in the switched off th operating state and charging the energy storage cher ES, the are in the on and blocked operating state.

The algorithm as to how the partial modules TM to be switched off are determined is arbitrary; the best possible fulfillment of the voltage specification of the central device ZE can be determined, for example, by a simulation in the sense of computer-assisted trying out all possible operating constellations of the communication-capable submodules TM and the subsequent selection of that operating constellation that guarantees the best possible fulfillment of the voltage specification. In view of the computing power of today's processors and the relatively small number of sub-modules in converters, such a brute force-like approach can be carried out without any problems.

In order to achieve the fastest possible transition from the first charging phase to the second charging phase for all sub-modules TM, the specified voltage threshold Smin is dimensioned in such a way that it is reached or exceeded even if not all sub-modules TM of the respective modular device ME1- ME6 are capable of communication. By switching off already communication-capable sub-modules TM at an early stage, the available charging voltage can be used advantageously for the sub-modules TM that are not yet capable of communication, so that they can communicate more quickly than would be the case if all sub-modules TM were charged simultaneously.

The specified voltage threshold Smin is preferably dimensioned in such a way that it is reached or exceeded when a specified number, which is between 25% and 50%, of the sub-modules TM of the respective modular device ME1-ME6 carries, is able to communicate with sub-modules TM. Alternatively, the specified voltage threshold Smin can be between 25% and 50% of the total voltage to be expected in the event that all sub-modules TM of the respective modular device ME1-ME6 were capable of communication.

The central device ZE determines the voltage specification Uout,soll as a function of the respective energy difference between the energy stored in the energy stores ES of its own converter 10 or the corresponding energy value El and the energy stored in the other converter 402 of the arrangement 400 according to FIG or the corresponding energy value E2, as explained above by way of example in connection with FIG.

FIG. 5 shows an exemplary embodiment of a module control device MSE, which can be used in the converter 10 according to FIG. The module control device MSE includes a computing device 100 and a memory 110. A software program module SPM_mse is stored in the memory 110, which when executed by the computing device 100 causes the module control device MSE to operate as described above by way of example.

FIG. 6 shows an exemplary embodiment of a central device ZE, which can be used in the converter 10 according to FIG. The central device ZE includes a computing device 200 and a memory 210. A software program module SPM_ze is stored in the memory 210, which when executed by the computing device 200 causes the central device ZE to operate as described above by way of example.

The arrangement 400 described above by way of example and the converters 401 and 402 or their operating methods can have one or more of the properties or features listed below: - The operating method preferably comprises a two-stage pre-charging method, which is coordinated via two converters 401 and 402 connected in series.

The operating method can be characterized in that partially active converters 401 and 402 can also be started up during the pre-charging.

- The operating method can be distinguished by the fact that to coordinate the second (active) charging phase, the average arm energy (module installation energy) or the average total voltage between the two DC voltage connections Gl and G2 of the converters 401 and 402 is exchanged.

- The operating method can be characterized in that, based on the difference in the mean module device energies of the module devices ME1-ME6 and/or the mean voltages between the two DC voltage connections Gl and G2 of the converters 401 and 402, the setpoint value for the DC charging voltage of the respective converter 401 and 402 is changed.

- The operating method can be used for both half- and full-bridge converters, especially multilevel converters (MMCs).

- The operating method allows the pre-charging of an HVDC station or its two converters while at the same time minimizing the energy input into the ground impedance Z. This allows optimization both with regard to the design and the costs in the ground connection.

Although the invention has been illustrated and described in detail by means of preferred exemplary embodiments, the invention is not restricted by the disclosed examples and other variations can be derived therefrom by a person skilled in the art without departing from the protective scope of the invention. reference sign

10 converters

11 first connection side / AC voltage side

12 second connection side / DC voltage side

100 computing device

110 memory

200 computing device

210 memory

400 arrangement

401 converter

402 converters

410 Community DC Voltage System

411 DC voltage connection

412 DC voltage connection 420 line system

BP reference potential

Cdc replacement capacitor

ES energy storage

Gl DC connection

G2 DC voltage connection

I current flow

ME1-ME6 modular devices

MSE module control device

S1-S4 switching elements

Smin specified voltage threshold

SPM_mse software program module

Sui sum value

TM submodule

TMSE sub-module controller

Off, voltage should exist

Uout, should voltage specification

Uout, target2 voltage specifications

Udcl partial voltage

Udc2 partial voltage

W1 value

W2 value WS1 AC voltage connection WS2 AC voltage connection WS3 AC voltage connection Z Impedance ZE Central device

Claims

patent claims

1. Arrangement (400) with a first converter (10, 401, 402) and a second converter (10, 401, 402), each having a DC voltage side (12), the two DC voltage sides (12) each having a connection are connected to each other and to a common reference potential (BP) and with the other connection in each case a DC voltage connection (411, 412) of a common common DC voltage system (410), wherein

- The converters (10, 401, 402) each comprise modular devices (ME1-ME6), each of which has a series circuit with at least two partial modules (TM) electrically connected in series, and

- The sub-modules (TM) each have an energy store (ES) and at least two switching elements (S1-S4), of which at least one switching element (S1-S4) is switched on when the sub-modules (TM) are switched on or off, and all of them are switched on in the blocked operating state Switching elements (S1-S4) are switched off, characterized in that

- The modular devices (ME1-ME6) each have a module control device (MSE) for controlling the sub-modules (TM) of their respective modular device (ME1-ME6),

- The converters (10, 401, 402) each have a central device (ZE), which is designed to provide the module control devices (MSE) of the module devices (ME1-ME6) of their own converter (10, 401, 402) with at least one span to transmit the voltage specification (Uoff,soll), which relates to the switched-off sub-modules (TM), and to transmit at least one value (W1, W2) to the central device (ZE) of the other converter (10, 401, 402),

- the converter-related voltage specification (Uaus,soll) depends on at least one value (Wl, W2) that the respective central device (ZE) receives from the central device (ZE) of the respective other converter (10, 401, 402), and

- The modular devices (ME1-ME6) are each designed to set the voltage specification (Uaus,soll) of their central unit direction (ZE), or at least approximately to fulfill them, by putting none, one or more of their sub-modules (TM) into the switched-off operating state.

2. Arrangement (400) according to claim 1, characterized in that

- The sub-modules (TM) each have a sub-module control device (TMSE), which determine the operating state of their sub-modules (TM) by controlling the switching elements (S1-S4),

- the converter (10, 401, 402) after commissioning, in which all sub-modules (TM) are initially in the blocked operating state and the sub-module control devices (TMSE) are not yet able to communicate due to a lack of sufficient charge state of their associated energy stores (ES), are first placed in a charging mode, and

- The sub-module control devices (TMSE) each communicate with their associated module control device (MSE) as soon as they have become capable of communication during charging, and

- The central devices (ZE) the module control devices (MSE) of their converter (10, 401, 402) at least during the charging operation, the voltage specification (Uaus,soll), which relates to switched off sub-modules (TM), transmit.

3. Arrangement (400) according to any one of the preceding claims, characterized in that

- the converter (10, 401, 402) after commissioning, in which all sub-modules (TM) are initially in the blocked operating state and the sub-module control devices (TMSE) are not yet able to communicate due to a lack of sufficient charge state of their associated energy stores (ES), are first placed in a charging mode, which comprises at least a first and a second charging phase, and - The central devices (ZE) the module control devices (MSE) of their converter (10, 401, 402) at least in the second charging phase of the charging operation, the voltage specification (Uaus,soll), which relates to switched off sub-modules (TM), transmit.

4. Arrangement (400) according to any one of the preceding claims, characterized in that

- the module control devices (MSE) are designed to transmit voltage values transmitted by the sub-module control devices (TMSE) or total values derived therefrom to the higher-level central device (ZE) of their converter (10, 401, 402), and

- The central devices (ZE) are designed to switch those of their module control devices (MSE) for which the sum of the transmitted voltage values or the transmitted sum value reaches or exceeds a predetermined voltage threshold from the first to the second charging phase of the charging operation by they these module control devices (MSE) the voltage specification

(Uaus,soll), which relates to switched off sub-modules (TM), transmit.

5. Arrangement (400) according to one of the preceding claims, characterized in that the voltage specification (Uaus,soll) for the first and second converter (10, 401, 402) is changed until the difference between the operating points of the converter ter (10, 401, 402) indicating difference value is zero or falls below a predetermined limit.

6. Arrangement (400) according to one of the preceding claims, characterized in that the voltage specification (Uaus,soll) for the first and/or second converter (10, 401, 402) depends on a voltage difference between a first partial voltage (Udcl), which is present between the two terminals of the DC voltage side (12) of the first converter (10, 401, 402), and a two th partial voltage (Udc2) between the two terminals of the DC voltage side (12) of the second converter (10,

401, 402) depends.

7. Arrangement (400) according to any one of the preceding claims, characterized in that

- the voltage specification (Uaus,soll) for the first converter (10, 401, 402) is increased when the first partial voltage (Udcl) is greater than the second partial voltage (Udc2), and reduced when the second partial voltage (Udc2) is greater than the first partial voltage (Udcl), and/or

- the voltage specification (Uaus,soll) for the second converter (10, 401, 402) is reduced when the first partial voltage (Udcl) is greater than the second partial voltage (Udc2), and increased when the second partial voltage (Udc2) is greater than the first partial voltage (Udcl).

8. Arrangement (400) according to one of the preceding claims, characterized in that the voltage specification (Uout,soll) for the first and/or second converter (10, 401, 402) depends on the energy difference between the energy stores (ES) of the energy stored in the first converter (10, 401, 402) and the energy stored in the energy stores (ES) of the second converter (10, 401, 402).

9. Arrangement (400) according to one of the preceding claims, characterized in that the voltage specification (Uaus,soll) for the first and/or second converter (10, 401, 402) depends on the energy difference between a first mean value, which is determined by averaging the energies stored in the module devices (ME1-ME6) of the first converter (10, 401, 402), and a second mean value, which is calculated by averaging the in the module devices (ME1-ME6) of the second converter (10, 401, 402 ) stored energies is formed depends.

10. Arrangement (400) according to any one of the preceding claims, characterized in that

- The voltage specification (Uaus,soll) for the first converter (10, 401, 402) of the height of an energy difference between the rule in the energy stores (ES) of the first converter (10, 401, 402) stored energy and in the Energy storage (ES) of the second converter (10, 401,

402) depends on stored energy, namely increased if a first energy value indicative of the energy stored in the first converter (10, 401, 402) is greater than a second energy value indicative of energy stored in the second converter (10, 401, 402). , and is reduced if the second energy value is greater than the first energy value, and/or

- The voltage specification (Uaus,soll) for the second converter (10, 401, 402) is increased when the second energy value is greater than the first energy value, and reduced when the first energy value is greater than the second energy value.

11. Arrangement (400) according to one of the preceding claims, characterized in that the charging operation takes place from the common DC voltage system (410) and the voltage specifications for the first converter (10, 401, 402) and the second converter (10, 401, 402 ) are determined according to:

Uout,soll = f(Udc, Uacl, Ufinal,soll, t, kp, El, E2,

Vaus,soll,maxi) and

Uout,soll2 = f(Udc, Uac2, Ufinal,soll, t, kp, El, E2,

Uoff,set,max2) and

- where Uacl designates the AC voltage applied to the AC voltage side of the first converter (10, 401, 402) and Uac2 designates the AC voltage applied to the AC voltage side of the second converter (10, 401, 402), Uout,setpoint is the voltage specification (Uout,setpoint ) for the first Converter (10, 401, 402) and Uout,soll2 denotes the voltage specification (Uoff,soll) for the second converter (10, 401, 402),

- where Ufinal,soll is the target voltage sum from the partial module voltages of the module devices (ME1-ME6) present at the energy stores (ES) of the partial modules (TM) after the end of the charging phase and at the beginning of normal operation for both converters (10, 401, 402). , which are set by the operating point of the two converters (10, 401,

402) at the beginning of normal operation,

- where kp is an adjustable amplification factor, El an energy value that indicates the energy stored in the energy stores (ES) of the first converter (10, 401, 402), and E2 indicates an energy value that in the energy stores (ES) of the second converter (10, 401, 402) indicates stored energy, denotes and

- where f is a function that increases over time t, preferably in steps or ramps, from zero to a respective maximum value

Uout,set,maxi = Ufinal,set - 0.25*Udc-0.5Uacl + kp (El- E2) or

Uout,set,max2 = Ufinal,set - 0.25*Udc-0.5Uac2 + kp (E2- El) increases.

12. Converter (10, 401, 402), in particular for an arrangement (400) according to one of the preceding claims, wherein the converter (10, 401, 402) has a DC voltage side (12) and comprises modular devices (ME1-ME6). , each having a series circuit with at least two sub-modules (TM) electrically connected in series, and the sub-modules (TM) each include an energy store (ES) and at least two switching elements (S1-S4), of which in the switched-on or switched-off operating state of the sub-module (TM) at least one switching element (S1-S4) is switched on and in the blocked operating state all switching elements (S1-S4) are switched off, characterized in that - The modular devices (ME1-ME6) each have a module control device (MSE) for controlling the sub-modules (TM) of their respective modular device (ME1-ME6),

- The converter (10, 401, 402) has a central device (ZE) which is designed to send the module control devices (MSE) of their own module devices (ME1-ME6) at least one voltage specification (Uaus,soll), which sub-modules ( TM) concerns, and to transmit at least one value (Wl, W2) to a central device (ZE) of another converter (10, 401, 402),

- wherein the converter-related voltage specification (Uaus,soll) depends on at least one value (Wl, W2) that the respective central device (ZE) receives from the central device (ZE) of the other converter (10, 401, 402), and

- where the module devices (ME1-ME6) are each designed to meet the voltage specification (Uaus,soll) of their central device (ZE) or at least approximately to fulfill them by having none, one or more of their sub-modules (TM) in switch to the switched-off operating state.

13. Central device (ZE) for a converter (10, 401, 402), in particular a converter (10, 401, 402) according to claim 12 or an arrangement (400) according to one of the preceding claims 1 to 11, characterized in that that

- The central device (ZE) is designed to transmit module control devices (MSE) assigned to module devices (ME1-ME6) at least one voltage specification (Uaus,soll), which relates to the switched-off sub-modules (TM), and at least one value (Wl, W2) to a central device (ZE) of another converter (10, 401, 402),

- Wherein the converter-related voltage specification (Uaus,soll) depends on at least one value (Wl, W2) which the respective central device (ZE) receives from the central device (ZE) of the other converter (10, 401, 402).

14. Module control device (MSE) for a converter (10,

401, 402), in particular a converter (10, 401, 402) according to claim 12 or an arrangement (400) of one of the preceding claims 1 to 11, characterized in that

- this is designed to transmit voltage values transmitted by partial module control devices (TMSE) or sum values derived therefrom to a higher-level central device (ZE), and

- This is also designed to meet a voltage specification (Uaus,soll) of the central device (ZE) by putting at least one communication-capable sub-module (TM) into the switched-off operating state.

15. A method for operating an arrangement (400) with a first converter (10, 401, 402) and a second converter (10, 401, 402), each having a DC voltage side (12), the two DC voltage sides (12) each because they are connected to one another and to a common reference potential (BP) with one connection and each form a DC voltage connection of a common common DC voltage system (410) with the other connection, with the converters (10, 401, 402) each having modular devices (ME1-ME6) comprise, each having a series circuit with at least two sub-modules electrically connected in series

(TM), and the sub-modules (TM) each have an energy store (ES) and at least two switching elements (S1-S4), of which at least one switching element (S1-S4) is active when the sub-module (TM) is switched on or off. is switched on and in the blocked operating state all switching elements (S1-S4) are switched off, characterized in that

- The modular devices (ME1-ME6) each have a module control device (MSE), which controls the sub-modules (TM) of their respective modular device (ME1-ME6),

- A central device (ZE) the module control devices (MSE) of the module devices (ME1-ME6) of their own converter ters (10, 401, 402) at least one voltage specification

(Uaus,soll), which relates to the switched-off sub-modules (TM), and transmits at least one value (Wl, W2) to the central device (ZE) of the other converter (10, 401, 402),

- wherein the converter-related voltage specification (Uoff,soll) depends on at least one value (Wl, W2) that the respective central device (ZE) receives from the central device (ZE) of the respective other converter (10, 401, 402), and

- The module devices (ME1-ME6) meet the voltage specification (Uaus,soll) of their central device (ZE) or at least approximately fulfill them by putting none, one or more of their sub-modules (TM) into the switched-off operating state.