The invention relates to a control device of an electric power converter comprising control means controlling turn-on of power semi-conductor legs,
said electric power converter comprising:
a DC power supply comprising a first positive voltage line, a second negative voltage line, and a third intermediate voltage line connected to a common point of filtering capacitors connected to said first line and to said second line,
conversion means having at least three legs connected between said positive, negative or intermediate voltage lines and outputs to supply at least one output voltage,
control means controlling turn-on of said legs of the conversion means,
said control means comprising processing means to supply modulation signals of control signals of said legs.
The invention also relates to an electric power converter comprising such a control device.
The invention also relates to a method for controlling such a converter.
Known converter control devices control commutation legs with power semi-conductors to supply output voltages supplying a load. When the converters are of the three-level type like the one represented in
In a control circuit 6 of the prior art, a first channel controls half-arms on the positive voltages side and a second channel controls half-arms on the negative voltages side.
Known control devices control the common point voltage of the capacitors in a slow manner. This type of control implies capacitors of very high values to guarantee an acceptable voltage variation of the intermediate voltage. With this type of control, the positive and negative voltages are also over-dimensioned to compensate losses in power semi-conductors. Moreover, the type of control of known devices is incompatible with the use of an over-modulation enabling the losses to be reduced.
The object of the invention is to provide a device and a method for controlling a converter enabling improved regulation of the intermediate voltage and enhanced control of the converter legs, and also to provide a converter comprising one such device.
In a control device according to the invention the control means comprise:
regulating means in conjunction with means for determining a general control component,
voltage signal inputs to supply said regulating means with signals representative of voltages between said positive, negative and intermediate voltage lines, or of the variations of the intermediate voltage, and
current signal inputs to supply said regulating means with current signals representative of output currents of the converter legs,
said means for determining the general control component determining the general control component according to said modulation signals, to said signals representative of voltages and to said signals representative of currents to take part in regulation of the intermediate voltage.
Preferably, said regulating means comprise a first regulating module processing a first combination of a product of modulation signals and of output currents, the general control component being dependent on a signal representative of said first combination and a signal representative of a variation of the intermediate voltage.
Advantageously, said regulating means comprise a second regulating module processing a second combination of a product of squared modulation signals and of output currents, the general control component being dependent on a signal representative of a quotient between a difference of said second combination with respect to a signal representative of a variation of the intermediate voltage and said first combination.
Advantageously, said regulating means comprise a module for detecting the sign of a result of said first combination, the general control component being dependent on a signal representative of a product between a signal representative of said sign and a signal representative of a variation of the intermediate voltage.
In a preferred embodiment, the means for determining the general control component comprise over-modulation control means to supply a general control component comprising mid-point voltage regulation signals and over-modulation control signals.
Preferably, said over-modulation control signals comprise means for controlling signal priority, regulating signals taking priority over over-modulation signals.
Preferably, said over-modulation control means position the semi-conductors of the legs during over-modulation to supply a voltage according to a first voltage value corresponding to the voltage of the positive line, a second voltage value corresponding to the voltage of the negative line, or a third voltage value corresponding to the mid-point voltage.
Advantageously, said over-modulation control means position the semi-conductors of the legs during over-modulation according to a modulation signal the closest to signals representative of said first positive voltage, of said second negative voltage, or of said intermediate voltage.
Advantageously, said over-modulation control means position the semi-conductors of the legs during over-modulation according to a modulation signal modified by a regulation signal, said modified modulation signal being the closest to signals representative of said first positive voltage, of said second negative voltage, or of said intermediate voltage.
Preferably, the over-modulation control means comprise means for controlling modulation signal saturation risks.
An electric converter according to the invention comprising:
a control device having control means controlling turn-on of power semi-conductor legs,
a DC power supply comprising a first positive voltage line, a second negative voltage line, and a third intermediate voltage line connected to a common point of filtering capacitors connected to said first line and to said second line,
conversion means having at least three legs connected between said positive, negative and intermediate voltage lines and outputs to supply at least one output voltage,
control means controlling turn-on of said legs of the conversion means according to modulation signals comprising general control component signals,
comprises at least one control device as defined above and current measuring means arranged on output conductor lines and connected to said control device to supply signals representative of currents to means for determining the general control component and to regulating means to be used in determining the general control component regulating the intermediate voltage.
A method for controlling an electric power converter comprising:
a DC power supply comprising a first positive voltage line, a second negative voltage line, and a third intermediate voltage line connected to a common point of filtering capacitors connected to said first line and to said second line,
conversion means having at least three legs connected between said positive, negative and intermediate voltage lines and outputs to supply at least one output voltage,
control means controlling turn-on of said legs of the conversion means,
according to the invention comprises:
determination of a general control component according to modulation signals, to signals representative of voltages or of a voltage variation of the intermediate line and/or of the positive and negative voltage lines, and to signals representative of currents in output conductors, and
regulation of the voltage variation of the intermediate line via the general control component.
Preferably, the general control component is also determined according to over-modulation processing.
Preferably, the general control component is determined with regulation of the intermediate voltage taking priority over over-modulation.
Advantageously, over-modulation processing is performed at three levels and applies selection of a closest modulation signal with respect to signals representative of the positive, negative or intermediate voltages.
Other advantages and features will become more clearly apparent from the following description of particular embodiments of the invention given as non-restrictive examples only and represented in the accompanying drawings in which:
FIGS. 4 to 7 represent modelling diagrams for a device according to an embodiment of the invention;
In a device according to an embodiment of the invention, the control circuit comprises a processing unit to supply modulation signals MC1, MC2 of control signals of said legs and a regulating circuit 20 associated with a module for determining a general control component CG. The control circuit comprises voltage signal inputs to supply said regulating circuit with signals representative of voltages V0, between said positive, negative and intermediate voltage lines, or of the variations of the intermediate voltage ΔV0, and current signal inputs to supply the regulating circuit 20 with current signals IS123 representative of output currents of the converter legs.
The regulating circuit and the module for determining the general control component determine the general control component CG according to said modulation signals MC1, to said signals representative of voltage V0 and ΔV0 and to said signals representative of currents IS123 to take part in regulation of the intermediate voltage V0.
A block diagram of such a device is represented in
Thus, a converter comprises a device for measuring the currents IS123 arranged on output conductor lines and connected to said control circuit to supply signals representative of currents to the module for determining the general control component CG and to the regulating circuit 20 to be used in determining the general control component regulating the intermediate voltage ΔV0.
FIGS. 4 to 7 represent modelling diagrams of operation of the converter legs and of regulation of the intermediate voltage variation. The current I0 on the common voltage point V0 is the sum of the currents of the two voltage lines IL1 and IL2 supplying the legs 20, 21, 22. Output voltages VS1, VS2, VS3 are referenced with respect to the common point V0. Its output currents IS1, IS2 and IS3 are supplied by the currents IL1 and IL2 of which they constitute a sum of the positive or negative currents according to the signs of the output voltages controlled by modulation signals. In
Thus, in a first equating example (1), the current in the common point I0 can be expressed as a function of quantities P and E respectively corresponding to the instantaneous power on output of the converter and to the DC line voltage on input of the converter. This current value is dependent on a first product sum comprising modulation signals MC1, and output current values and controlled by the signs of the modulation signal and on a second sum comprising a product of a general control component CG and of a sum of output currents controlled by the sign of the modulation signals.
This modelling can be used with reciprocal functions for controlling the voltage V0, since reducing the current variation in I0 also implies reducing the voltage variation ΔV0. A modelling of this kind is represented by a circuit 100 in
In a preferred embodiment of the invention another approximated modelling 101 enables a good stability in dynamic operating mode. This modelling can be represented by an equation as set out below.
This modelling is based on product sums of absolute values. It leads in particular to making the initial system causal and non-recursive. A corrector defined with this approximation of the initial system enables dynamic control of regulation of the intermediate voltage V0 of the common point to be supported correctly.
The regulating circuit 20 comprises a first regulating module 41 processing a first combination of a product of modulation signals MC1 and output currents IS123, the general control component being dependent on a signal 43 representative of said first combination and of a signal representative of an intermediate voltage variation ΔV0, ΔV0m or ΔV0f.
The regulating circuit 20 preferably comprises a second regulating module 42 processing a second combination of a product of squared modulation signals MC1 and output currents IS123, and supplying a signal 44 representative of said processing. An operator 45 performs the difference between the voltage variation signal ΔV0, ΔV0m or ΔV0f and the signal 44, and an operator 46 performs a quotient between the result of the operator 45 and the signal 43. Therefore, the general control component CG is then dependent on a signal representative of a quotient between a difference of said second combination compared with a signal representative of a variation of the intermediate voltage and said first combination. A filtering module improves the functioning of the system by filtering the general control component output signal.
In the embodiment of
In the diagram of
In a particular embodiment, the general control component CG intended for regulation of the intermediate voltage variation also comprises over-modulation signals to reduce the power losses and to reduce the voltage of the voltage lines V1 and V2, over-modulation consisting in forcing turn-on of the power semi-conductors for a preset time. In this case, determination of the general control component CG uses a circuit controlling an over-modulation OM to supply a general control component comprising regulation signals of mid-point voltage V0, ΔV0 and over-modulation control signals OM.
In
The control circuit, in particular in the unit 51, comprises a module 52 controlling signal priority, the regulation signals taking priority over the over-modulation signals. For example in case of incompatibility between regulation and over-modulation, priority is given to regulation.
The over-modulation control unit 51 positions the semi-conductors of the legs during over-modulation to supply a voltage according to a first voltage value corresponding to the voltage of the positive line V1, a second voltage value corresponding to the voltage of the negative line V2, or a third voltage value corresponding to the mid-point value V0.
Preferably, said over-modulation control unit 51 positions the semi-conductors of the legs during over-modulation according to a modulation signal closest to the signals representative of said first positive voltage V1, of said second negative voltage V2, or of said intermediate voltage V0.
Advantageously, said over-modulation control unit 51 positions the semi-conductors of the legs during over-modulation according to a modulation signal modified by a regulation signal, said modified modulation signal being closest to signals representative of said first positive voltage V1, of said second negative voltage V2, or of said intermediate voltage V0.
For example, selection modules 53 and 54 controlled by the module 52 select over-modulation values OM1 or OM2 applied to the general control component by modules 55 or 56 or no over-modulation.
Said over-modulation control unit 51 comprises a module controlling modulation signal saturation risks.
In
The method comprises a signal measurement or acquisition step 70. Then, in a step 71, determination of a general control component CG is performed according to modulation signals MC1, to signals representative of voltages or of voltage variation ΔV0 of the intermediate line V0 and/or the positive voltage V1 and negative voltage V2 lines, and to signals representative of currents in output conductors IS123. In a step 72, regulation of the intermediate line voltage variation is performed via the general control component CG.
A step 73 enables the over-modulation OM to be applied to the general control component to be processed. Thus, the general control component is also determined according to over-modulation processing. In a step 74, the general control component is determined with priority to regulation of the intermediate voltage over over-modulation.
Preferably, in a step 75, processing of the general control component is performed on three levels and applies selection of a closest modulation signal with respect to signals representative of positive, negative or intermediate voltages. A step 76 processes saturation risks and a step 77 applies the general control component to modulation signals.
Conversion devices according to embodiments can be in particular inverters, uninterruptible power supplies, variable speed drives, unidirectional or bidirectional power converters, or frequency converters.
The invention applies in particular to three-phase converters with three DC voltage levels with three or four legs, but other converters having a different number of legs and/or of phases may be concerned.
The semi-conductors of these converters are advantageously insulated gate bipolar transistors called IGBT but other types of semi-conductors can be used. The legs can comprise several semi-conductors connected in series and/or in parallel according to the voltages, currents or electric powers used. For example, the input or output voltages can range from a few tens of volts to a thousand volts for low voltage power system applications or have voltages of several thousands of volts in particular in medium/high voltage applications. The input or output currents can range from a few amperes to more than a thousand amperes.
In an other technical language, the legs of the converter can be also named arms or branches.
Number | Date | Country | Kind |
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0501888 | Feb 2005 | FR | national |