VOLTAGE SOURCE CONVERTER AND A METHOD FOR OPERATION THEREOF

Abstract

A voltage source converter has a half bridge (18) with two current valves (19, 20) connected in series and an arrangement configured to carry out voltage measurements for determining a value of the DC voltage between opposite poles (21, 22) of a DC side of the converter. Each current valve comprises a semiconductor device (23, 24) controlled by an associated gate drive member (29, 30), each forming gate drive parts of one gate drive unit (28) in common to both current valves. The gate drive unit (28) comprises an isolated two-way communication link (33) between the gate drive members. The arrangement is included in the gate drive unit and configured to measure the entire DC voltage between said opposite poles (21, 22). A converter control device (31) calculates and sends control signals to the gate drive unit based on the result of the voltage measurement.

Claims

1. A voltage source converter comprising a half bridge (18) with two current valves (19, 20) connected in series and configured to be connected to opposite poles (21, 22) of a DC source/load, each said current valve comprising a semiconductor device (23, 24) of turn-off type and a rectifying diode (25, 26) connected in anti-parallel therewith, a midpoint of the half bridge between the two current valves forming an AC side (27) of the converter and being configured to be connected to an AC load/source, two gate drive members (29, 30) each comprising a logic device (46, 47) and a gate drive stage (34, 35) configured to control the semiconductor device (23, 24) of a current valve (19, 20) each to turn on and off according to control signals from a converter control device (31), said converter control device (31) configured to send control signals to said gate drive members (29, 30) for controlling the operation of the converter according to a Pulse Width Modulation pattern for creating an AC fundamental voltage and current on said AC side, and an arrangement configured to carry out voltage measurements for providing a value of the DC voltage between said opposite poles (21, 22) to a first said logic device configured to send information about said DC voltage value to the converter control device (31), wherein said two gate drive members (29, 30) form gate drive parts of one gate drive unit (28) in common to both current valves (19, 20), that said gate drive unit contains an electrically isolating two-way communication link (33) interconnecting said gate drive members, that said arrangement is included in said gate drive unit (28) and comprises a voltage divider (36) connected across the two current valves (19, 20) se as-to measure the entire DC voltage between said opposite poles (21, 22), and that the converter control device (31) is configured to calculate and send said control signals to the gate drive unit (28) based on the result of a said measurement carried out by said arrangement.

2. A voltage source converter according to claim 1, wherein said voltage divider (36) has an output with one of said poles (21, 22) as reference potential, and that said output is connected to processing parts (37, 38, 39, 45) which are included in one, first (29) of said gate drive members.

3. A voltage source converter according to claim 1, wherein said first gate drive member (29) is configured to send information about the DC voltage measured also directly to the second gate drive member (30) and both gate drive members are configured to use information about this voltage to optimize the switching of the semiconductor device (23, 24) of the respective current valve (19, 20).

4. A voltage source converter according to claim 3, wherein said voltage divider (36) has an output with one of said poles (21, 22) as reference potential, said output is connected to processing parts (37, 38, 39, 45) which are included in one, first (29) of said gate drive members, and said first gate drive member (29) is configured to directly use the value of the DC voltage measured by the arrangement for the control of said semiconductor device (24).

5. A voltage source converter according to claim 1, comprising it comprises three said half-bridges (18) each having a said gate drive unit (28) with two said gate drive members (29, 30) for creating a three phase AC fundamental voltage and current on said AC side.

6. A voltage source converter according to claim 1, comprising an even number of said half-bridges (18) each having said gate drive unit (28) with two said gate drive members (29, 30) with each pair of half-bridges configured to be connected to one secondary winding of an AC line railway vehicle main transformer and for creating a single phase AC fundamental voltage and current between them on said AC side.

7. A voltage source converter according to claim 5, wherein a said arrangement is included in the gate drive unit (28) for each said phase.

8. A voltage source converter according to claim 1, wherein the semiconductor devices (23, 24) of the current valves are IGBTs (Insulated Gate Bipolar Transistors) or MOSFETs (Metal Oxide Semiconductor Field Effect Transistors).

9. A voltage source converter according to claim 1, which it is a track-bound vehicle converter (9, 13) configured to be arranged on board a track-bound vehicle (1) and being for example a motor converter (13) configured to deliver power through said AC side of the converter to a motor (15) used to drive the vehicle or an auxiliary converter (9) configured to deliver a voltage on said AC side of the converter to be used for the heating/cooling system of the vehicle and for electrical appliances, such as through sockets arranged in said vehicle.

10. A method of operating a voltage source converter comprising a half bridge (18) with two current valves (19, 20) connected in series and configured to be connected to opposite poles of a DC source/load, each said current valve comprising a semiconductor device (23, 24) of turn-off type and a rectifying diode (25, 26) connected in anti-parallel therewith, a midpoint of the half bridge between the two current valves forming an AC side (27) of the converter and being configured to be connected to an AC load/source, two gate drive members (29, 30) configured to control the semiconductor device of a current valve each to turn on and off according to control signals from a converter control device (31), an arrangement that is a part of the gate drive unit, configured to carry out voltage measurements for determining a value of the DC voltage between said opposite poles and a converter control device (31) configured to send control signals to a first said gate drive member for controlling the operation of the converter according to a Pulse Width Modulation pattern for creating an AC fundamental voltage and current on said AC side, the method comprising the steps: a) carrying out voltage measurements for determining values of the DC voltage between said opposite poles (21, 22) and sending information thereabout to the converter control device (31), and b) calculating control signals for said Pulse Width Modulation Pattern based upon the result of said measurements, wherein the method is carried out for a converter having said two gate members (29, 30) forming gate drive parts of one gate drive unit (28) in common to both current valves (19, 20) and a gate drive unit containing an isolated two-way communication link (33) interconnecting said gate drive members (29, 30), in each said measurement the entire DC voltage between said opposite poles (21, 22) is measured, and that in step b), said control signals are calculated and sent to the gate drive unit (28) based on the result of a said measurement of the entire DC voltage between said opposite poles.

11. A method according to claim 10, wherein information about the DC voltage values in step b) also is used by the two gate drive members (29, 30) to optimize the switching of the semiconductor device (23, 24) of the respective current valve (19, 20).

12. A method according to claim 11, wherein said DC voltage measurements are carried out by one, first (29) of said gate drive members and this gate drive member uses the value of the DC voltage measured directly for controlling said semiconductor device (24) and sends this value further to the other gate drive member (30) for using this value for the control of the semiconductor device (23) belonging to that current valve (19).

13. A computer program comprising computer program code for causing a computer to implement a method according to claim 10, when the computer program is executed by a computer.

14. A computer program product comprising a non-transitory data storage medium which can be read by a computer and on which the program of a computer program according to claim 13 is stored.

15. An electronic converter control unit comprising an execution means, a memory connected to the execution means (41), a memory (42) connected to the execution means and a non-transitory data storage medium (44) which is connected to the execution means and on which the computer program code of a computer program according to claim 13 is stored.

16. A track-bound vehicle having at least one converter according to claim 1.

17. A voltage source converter according to claim 2, wherein said first gate drive member (29) is configured to send information about the DC voltage measured also directly to the second gate drive member (30) and both gate drive members are configured to use information about this voltage to optimize the switching of the semiconductor device (23, 24) of the respective current valve (19, 20).

18. A voltage source converter according to claim 17, comprising three said half-bridges (18) each having a said gate drive unit (28) with two said gate drive members (29, 30) for creating a three phase AC fundamental voltage and current on said AC side.

19. A voltage source converter according to claim 4, comprising three said half-bridges (18) each having a said gate drive unit (28) with two said gate drive members (29, 30) for creating a three phase AC fundamental voltage and current on said AC side.

20. A voltage source converter according to claim 3, comprising three said half-bridges (18) each having a said gate drive unit (28) with two said gate drive members (29, 30) for creating a three phase AC fundamental voltage and current on said AC side.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0029] With reference to the appended drawings, below follows a specific description of an embodiment of the invention cited as an example. In the drawings:

[0030] FIG. 1 is a very schematic view illustrating how different types of converters of the type to which the present invention is directed may be arranged and controlled in a track-bound vehicle,

[0031] FIG. 2 is a schematic circuit diagram of a converter half bridge according to an embodiment of the present invention, and

[0032] FIG. 3 is a schematic view illustrating an electronic converter control unit for implementing the invention.

DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION

[0033] Since the present invention is particularly suited for being used in track-bound vehicles some possible ways of using a voltage source converter according to the invention will now be briefly described with reference made to FIG. 1 without restricting the invention to that field of use. FIG. 1 illustrates schematically how electric power may be fed to a track-bound vehicle 1 from an AC-supply line 2 and used in said vehicle. The vehicle is configured to move along the AC-supply line 2, which accordingly acts as an AC-source and which may for example carry a single phase alternating voltage of 15 kV and 16⅔ Hz (Sweden, Germany etc.) or 25 kV and 50 Hz (Denmark, China, India etc.). The vehicle has a transformer 3 for transforming the voltage from the supply line 2 to a suitable level. The transformer has here two secondary windings 4, 5, one of which being connected to a line converter 6 for delivering a direct voltage of for example 0.8-3 kV on the output thereof. This direct voltage is delivered to an auxiliary converter 7, which is controlled by a converter control device 8 for generating a train of pulses according to a Pulse Width Modulation pattern for delivering a three phase alternating voltage on the output thereof. The output of this converter is connected to a three phase transformer 9 as well as harmonic filters 10 for smoothing out the alternating voltage delivered by a distribution network 11 to sockets arranged in the track-bound vehicle, such as for connection of computers, and to lighting, heating and other appliances.

[0034] The other secondary winding 4 of the transformer is connected to a line converter 12 configured to deliver a direct voltage on the output thereof to the input of a voltage source converter in the form of a motor converter 13 for delivering a three phase alternating voltage on the output thereof to motors 15 in the form of electric machines, for driving the vehicle. Each converter 12, 13 is controlled by a converter control device 16, 14 which determines the PWM pattern of the converter. The motor converter control device 14 will receive orders from the driver of the vehicle for adapting the frequency (induction machine) or phase angle (permanent magnet machine) of the fundamental voltage delivered to the stator windings of the motors to the tractive effort/traction force commanded. In the case of braking the vehicle electric power will flow in the direction from the motors to the AC-supply line through the line converter 12 controlled to deliver a single phase alternating voltage on the AC side thereof. The converters 6, 7, 12 and 13 may be voltage source converters according to the present invention. It is pointed out that the electric system shown in FIG. 1 is only one of several possible appearances of an electric system in a track-bound vehicle.

[0035] A single phase of a voltage source converter 17 according to an embodiment of the invention is schematically illustrated in FIG. 2. The voltage source converter has for each phase a half bridge module 18 with two current valves 19, 20 connected in series and configured to be connected to opposite poles 21, 22 of a DC source or load, such as a DC voltage intermediate link connected to the converters 7 and 13 shown in FIG. 1. Each current valve has a semiconductor device 23, 24 of turn-off type in the form of a MOSFET (an IGBT may do just as well) and a rectifying diode 25, 26 connected in anti-parallel therewith. A midpoint of the half bridge between the two current valves forms an AC side 27 of the converter and is configured to be connected to an inductive impedance, in this case of an AC load.

[0036] The voltage source converter has for each phase a gate drive unit 28 with a first gate drive member 29 configured to control the MOSFET 24 of a first current valve 20 and a second gate drive member 30 configured to control the MOSFET 23 of the other, second current valve 19 to turn on and off (typically with a switching frequency of a few kHz) for creating an AC voltage and current on the AC side 27.

[0037] A converter control device 31 in common to the gate drive units of the three phases is configured to send control signals to each phase through a high speed isolated two-way communication link 32 to the gate drive unit 28 for controlling the operation of the converter, in which the control signals are first received by the first gate drive member 29 which process said signal into separate ON/OFF control signals for itself by a logic device 46 and for the second gate drive member 30 and sends the latter through an isolated two-way communication link 33 to a logic device 47 interconnecting the gate drive members so that the gate drive stages 34, 35 turn the respective MOSFET 24, 23 on or off so as to produce the intended PWM.

[0038] For the operation of the converter it is of importance to know the value of the DC voltage between the poles 21, 22 on the DC side thereof, and this value has to be determined for ensuring that this voltage will never reach a level detrimental to the power semiconductor devices (the MOSFETs) of the current valves. The voltage source converter does for this purpose have an arrangement configured to carry out voltage measurements for determining a value of said DC voltage, and this arrangement is included in the gate drive unit 28 and comprises a voltage divider 36 connected across the two current valves so as to measure the entire DC voltage between the opposite poles 21, 22 of the DC link. Such a fixed resistive voltage divider delivers a low-voltage measurement signal that can be further processed. The same voltage divider hardware may be used for power semiconductor devices, such as IGBTs, used for different voltages, such as rated for 1.7 kV and 3.3 kV. The voltage measuring arrangement consists of a resistive voltage divider 36 and processing parts 37, 38, 39, 45. The processing parts are included in the first gate drive member 29 and consists of a member 37 for selecting the final voltage division factor of said arrangement, a low-pass filter 38, an analog to digital converter 39 and a digital low-pass filter 45. The voltage division factor is controlled by logic device 46.

[0039] Impedance matching to logic device 46 is provided by low-pass filter 38. Information about the resulting DC voltage value is sent through the high speed communication link 32 to the converter control device 31 with a rate of update within in the order of 10 μs, together with other phase status information. The converter control device is configured to calculate and send the control signals to the gate drive unit 28 based on the result of the measurement so carried out by the DC voltage measuring arrangement.

[0040] The information about the DC voltage measured by the arrangement may be used by the converter control device together with load currents measured by separate current sensors (not shown) for calculating turn-on/off times of the semiconductor devices of the current valves. The gate drive unit in the voltage converter according to the invention may autonomously use the DC voltage value information for optimizing switching of the power semiconductor devices, especially for turn-on in the case of IGBTs. The first gate drive member 29 including the arrangement will then directly use the voltage value measured by the arrangement, whereas the other gate drive member 30 uses the value sent from the first gate drive member 29 through the communication link 33.

[0041] Computer program code for implementing a method according to the invention is with advantage included in a computer program which can be read into the internal memory of a computer, e.g. the internal memory of an electronic converter control unit of a track-bound vehicle. Such a computer program is with advantage provided with a computer program product comprising a data storage medium which can be read by a computer and which has the computer program stored on it. FIG. 3 illustrates very schematically an electronic converter control unit 40 comprising an execution means 41, e.g. a central processor unit (CPU) for execution of computer software. The execution means 41 communicates with a memory 42, e.g. of the RAM type, via a data bus 43. The electronic converter control unit 40 also comprises a non-transitory data storage medium 44, e.g. in the form of a flash memory or a memory of the ROM, PROM, EPROM or EEPROM type. The execution means 41 communicates with the data storage medium 44 via the data bus 43. The computer program comprises computer program code for implementing a method according to the invention.

[0042] The invention is of course in no way restricted to the embodiment described above, since many possibilities for modifications thereof are likely to be obvious to one skilled in the art without having to deviate from the scope of the invention defined in the appended claims.

[0043] It is for redundancy advantageous to have a voltage measuring arrangement in each gate drive unit of a multiple phase voltage source converter, but it is within the scope of the invention to have an arrangement in only one or two of the gate drive units in the case of a three phase voltage source converter.

[0044] Furthermore, one gate drive unit may control a plurality of half bridge semiconductor modules connected in parallel but belonging to the same phase, for instance four modules connected in parallel and each having two current valves connected in series making a total of 8 current valves for that phase.