POWER CONVERTER ARRANGEMENT AND CONTROL METHOD THEREFOR

Abstract

A method controls a converter assembly which has a line-commutated converter. The line-commutated converter has an alternating voltage terminal which can be connected via a phase conductor to an alternating voltage network. The converter assembly further has a switch module branch which is arranged serially in the phase conductor and which contains a series circuit of switch modules at each of the terminals of which bipolar voltages can be generated which add up to a branch voltage. A connection voltage to a connection point between the switch module branch and the converter is controlled by adjusting an amplitude of a positive sequence component of the branch voltage. The converter assembly is configured to carry out a control method for controlling the converter assembly.

Claims

1-10. (canceled)

11. A control method for a power converter configuration having a line-commutated power converter with an AC voltage terminal configured for connecting to an AC voltage grid via a phase line, the power converter configuration further containing a switching module branch disposed in series in the phase line and having a series connection of switching modules, the switching modules having terminals and at each of the terminals bipolar voltages are able to be generated and add up to produce a branch voltage, the method comprises the steps of: controlling a link voltage at a linking point between the switching module branch and the line-commutated power converter by adjusting an amplitude of a positive-sequence system of the branch voltage.

12. The method according to claim 11, which further comprises controlling a branch energy of the switching module branch by adjusting a phase of the positive-sequence system of the branch voltage.

13. The method according to claim 12, which further comprises carrying out a balancing of energy storage unit voltages of the switching modules by adjusting an amplitude and a phase of a negative-sequence system of the branch voltage.

14. The method according to claim 11, wherein the power converter configuration has a respective switching module branch for each phase of the AC voltage grid, adjustments being carried out for all switching module branches.

15. The method according to claim 14, which further comprises generating a voltage setpoint value for the branch voltage, the voltage setpoint value is formed of a positive-sequence system setpoint value and a negative-sequence system setpoint value, wherein the positive-sequence system setpoint value is generated in consideration of a total energy setpoint value and a link voltage setpoint value, and the negative-sequence system setpoint value is generated in consideration of switching module branch energies.

16. The method according to claim 11, which further comprises using the method to compensate for a line impedance of the AC voltage grid.

17. The method according to claim 11, which further comprises using an AC-voltage-side current as a reference variable for determining the positive-sequence system.

18. A power converter configuration, comprising: a line-commutated power converter having an AC voltage terminal configured for connecting to an AC voltage grid via a phase line; a switching module branch disposed in series in the phase line and having a series connection of switching modules, said switching modules having terminals and at each of said terminals bipolar voltages which add up to produce a branch voltage are able to be generated; and a controller for controlling a link voltage, the power converter configuration configured to carry out the method according to claim 11 by means of said controller.

19. The power converter configuration according to claim 18, wherein said line-commutated power converter is a thyristor-based power converter which has a three-phase bridge circuit with six phase branches.

20. The power converter configuration according to claim 18, wherein the power converter configuration is configured for a voltage of more than 100 kV.

Description

[0020] The invention will be explained in more detail below on the basis of FIGS. 1 to 5.

[0021] FIG. 1 shows a schematic representation of an exemplary embodiment of a power converter arrangement according to the invention;

[0022] FIG. 2 shows a schematic representation of an exemplary embodiment of a switching module branch for a power converter arrangement according to the invention;

[0023] FIG. 3 shows a schematic representation of a full-bridge switching module;

[0024] FIG. 4 shows a schematic representation of a vector diagram for branch current and branch voltage of a switching module branch;

[0025] FIG. 5 shows a schematic representation of a flow diagram of an exemplary embodiment of a method according to the invention.

[0026] FIG. 1 shows a power converter arrangement 1, which is connected, at a grid connection point 4, to a three-phase AC voltage grid 5. The power converter arrangement 1 comprises a line-commutated power converter 2. The power converter 2 is arranged between a DC voltage grid or DC voltage line 3 and a linking point 25. The power converter 2 comprises six power converter arms or power converter valves 6-11, which each extend between one of the DC voltage poles 12 or 13 of the power converter 2 and one of the three AC voltage terminals 14-16. A series connection of thyristors 17 is arranged in each of the power converter arms 6-11. The power converter 2 is connected to the AC voltage grid 5 by means of the AC voltage terminals 14-16 via three phase lines 21-23.

[0027] The power converter arrangement 1 further comprises a first switching module branch 18, a second switching module branch 19 and a third switching module branch 20. The first switching module branch 18 is introduced in series into a first phase line 21, the second switching module branch 19 is introduced in series into a second phase line 22 and the third switching module branch 20 is introduced in series into a third phase line 23. In the example shown in FIG. 1, the three switching module branches 18-20 are of identical design, but this does not generally have to be the case. The design of the switching module branches 18-20 is discussed in more detail in FIG. 2 below.

[0028] A voltage dropped across the switching branches 18-20 is denoted Uc. The power-converter-side line-to-ground voltage is denoted U1, and the grid-side line-to-ground voltage is accordingly denoted U2. The switching module branches 18-20 are used to compensate for a line impedance Xnetz and/or a converter-side impedance Xc and to stabilize a link voltage Uac at the linking point 25 in order to guarantee stable and reliable operation of the power converter arrangement 1, and in particular of the power converter 2. For this purpose, the power converter arrangement 1 has a central control unit 24, which is configured both to control the power converter 2, or to initiate the actuation of the semiconductor switches, and to control the switching module branches, or to initiate the actuation of the semiconductor switches used there.

[0029] FIG. 2 shows a switching module branch 30, which is suitable for use as one of the switching module branches 18-20 of the power converter arrangement 1 of FIG. 1. The switching module branch 30 has a first terminal 31 and a second terminal 32 for switching into a phase line of an AC voltage grid. Between the two terminals 31, 32 is arranged a series connection of switching modules 331-33n, the number of which is in principle arbitrary and can be tailored to the particular application, indicated by a dotted line 34 in FIG. 2. The design of the switching modules 331-33n is discussed in more detail in FIG. 3 below. It goes without saying here that not all of the switching modules 331-33n have to be of identical design.

[0030] An actuation unit 35 is provided to carry out or to initiate the actuation of the switching modules 331-33n. The actuation unit 35 is provided with communication means which allow, for example, communication with a superordinate central open-loop or closed-loop control unit of a power converter arrangement.

[0031] FIG. 3 shows an example of a switching module 40 for the switching branch 30 of FIG. 2, the switching module 40 being a full-bridge switching module. The switching module 40 comprises a first turn-off semiconductor switch H1, with which a first freewheeling diode D1 is connected in antiparallel, and a second turn-off semiconductor switch H2, with which a second freewheeling diode D2 is connected in antiparallel, wherein the first and second semiconductor switches H1, H2 are connected to each other in a first semiconductor series connection and have the same forward direction. The switching module 40 further comprises a third turn-off semiconductor switch H3, with which a third freewheeling diode D3 is connected in antiparallel, and a fourth turn-off semiconductor switch H4, with which a fourth freewheeling diode D4 is connected in antiparallel, wherein the third and fourth semiconductor switches H3, H4 are connected to each other in a second semiconductor series connection and have the same forward direction. The two semiconductor series connections are arranged in parallel with each other and with an energy storage unit C, on which an energy storage unit voltage Uk is present. Furthermore, the switching module further comprises a first connection terminal X1, which is arranged between the semiconductor switches H1, H2 of the first semiconductor series connection, and a second connection terminal X2, which is arranged between the semiconductor switches H3, H4 of the second semiconductor series connection. The semiconductor switches H1-4 are able to be actuated, i.e. are able to be turned on and/or turned off, independently of each other by means of a suitable actuation unit. Suitable actuation of the semiconductor switches H1-4 can be used to generate a voltage (switching module voltage) at the terminals X1,2, which voltage corresponds to the voltage Uk present on the energy storage unit C, a voltage −Uk or a zero voltage.

[0032] FIG. 4 shows a vector diagram 50. The vector diagram 50 illustrates that the reference frame of the branch current ic is chosen for controlling the branch voltage Uc. In this case, the branch current ic through the switching module branch or branches corresponds to the line current iN. The vector of the branch voltage Uc has a phase angle phi in relation to the branch current ic and can thus be broken down into a d component Uc,d parallel to the branch current ic and a q component Uc,q perpendicular to the branch current ic. These two components are used for the voltage or energy control.

[0033] A schematic flow diagram 60 of an example of the control sequence is shown in FIG. 5. In this instance, control is based on the case of a three-phase embodiment of the power converter arrangement, wherein a first switching module branch is arranged in a first phase line, a second switching module branch is arranged in a second phase line and a third switching module branch is arranged in a third phase line, in a similar manner to the arrangement shown in FIG. 1. The three switching module branches together are referred to as a converter below.

[0034] According to the example shown in FIG. 5, a setpoint value Wref for the converter total energy is compared with a measured value W of the converter total energy, forming an energy difference DeltaW. The energy difference DeltaW is delivered to a first controller 61. The output of the first controller 61 provides a first d component Ud1 of the voltage in the reference frame of the branch current ic. At the same time, a setpoint value Uref for the link voltage at a linking point between the power converter and the switching module branches is compared with a measured value U of the link voltage, forming a voltage difference DeltaU. The energy difference DeltaU is delivered to a second controller 62. The output of the second controller 62 provides a first q component Uq1 of the voltage in the reference frame of the branch current ic. The d component Ud1 and the q component Uq1 are transformed by means of a rotational transformation in a rotational transformation block 63 with a rotation matrix R(Theta)=(cos(Theta),−sin(Theta)/sin(Theta), cos(Theta)), wherein Theta denotes a normalization angle of the current reference frame, and are therefore converted into a first positive-sequence system component Uconv,alpha+ of the alpha component Uconv,alpha of the voltage that is to be set at the converter and a second positive-sequence system component Uconv,beta+ of the beta component Uconv,beta of the voltage that is to be set at the converter.

[0035] A first, second and third branch energy value W1,W2,W3 are delivered to a transformation block 64 and transformed, by means of a Clarke transformation, into corresponding alpha and beta components Walpha and Wbeta. These are delivered to a third controller 65 and a fourth controller 66, respectively, the outputs of which provide a second d component Ud2 and a second q component Uq2 of the voltage in the reference frame of the branch current ic. The second d component Ud2 and the second q component Uq2 are transformed by means of a rotational transformation in a second rotational transformation block 67 with a rotation matrix R(Theta)=(cos(Theta), sin(Theta)/−sin(Theta), cos(Theta)) and are therefore converted into a first negative-sequence system component Uconv,alpha− of the alpha component Uconv,alpha of the voltage that is to be set at the converter and a second negative-sequence system component Uconv,beta− of the beta component Uconv,beta of the voltage that is to be set at the converter.

[0036] The voltage that is to be set at the converter thus consists of Uconv,alpha=Uconv,alpha++Uconv,alpha− and Uconv,beta=Uconv,beta++Uconv,beta−.