EP1642383A2 - Frequency converter for high-speed generators - Google Patents
Frequency converter for high-speed generatorsInfo
- Publication number
- EP1642383A2 EP1642383A2 EP04766126A EP04766126A EP1642383A2 EP 1642383 A2 EP1642383 A2 EP 1642383A2 EP 04766126 A EP04766126 A EP 04766126A EP 04766126 A EP04766126 A EP 04766126A EP 1642383 A2 EP1642383 A2 EP 1642383A2
- Authority
- EP
- European Patent Office
- Prior art keywords
- generator
- voltage
- frequency converter
- network
- frequency
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn
Links
Classifications
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for ac mains or ac distribution networks
- H02J3/38—Arrangements for parallely feeding a single network by two or more generators, converters or transformers
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M5/00—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases
- H02M5/40—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases with intermediate conversion into dc
- H02M5/42—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases with intermediate conversion into dc by static converters
- H02M5/44—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases with intermediate conversion into dc by static converters using discharge tubes or semiconductor devices to convert the intermediate dc into ac
- H02M5/453—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases with intermediate conversion into dc by static converters using discharge tubes or semiconductor devices to convert the intermediate dc into ac using devices of a triode or transistor type requiring continuous application of a control signal
- H02M5/458—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases with intermediate conversion into dc by static converters using discharge tubes or semiconductor devices to convert the intermediate dc into ac using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M5/4585—Conversion of ac power input into ac power output, e.g. for change of voltage, for change of frequency, for change of number of phases with intermediate conversion into dc by static converters using discharge tubes or semiconductor devices to convert the intermediate dc into ac using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only having a rectifier with controlled elements
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P9/00—Arrangements for controlling electric generators for the purpose of obtaining a desired output
- H02P9/14—Arrangements for controlling electric generators for the purpose of obtaining a desired output by variation of field
- H02P9/26—Arrangements for controlling electric generators for the purpose of obtaining a desired output by variation of field using discharge tubes or semiconductor devices
- H02P9/30—Arrangements for controlling electric generators for the purpose of obtaining a desired output by variation of field using discharge tubes or semiconductor devices using semiconductor devices
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M7/00—Conversion of ac power input into dc power output; Conversion of dc power input into ac power output
- H02M7/42—Conversion of dc power input into ac power output without possibility of reversal
- H02M7/44—Conversion of dc power input into ac power output without possibility of reversal by static converters
- H02M7/48—Conversion of dc power input into ac power output without possibility of reversal by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M7/483—Converters with outputs that each can have more than two voltages levels
- H02M7/487—Neutral point clamped inverters
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P2101/00—Special adaptation of control arrangements for generators
- H02P2101/10—Special adaptation of control arrangements for generators for water-driven turbines
Definitions
- the present invention relates to a method for adapting the alternating current generated by a generator or the alternating voltage generated by a generator to a network, the generator being a generator with at least one excitation coil.
- the present invention relates to a device for performing such a method.
- Variable-speed generators or generators in general with a frequency that deviates from the mains frequency are typically transmitted to the power supply network via converters, which adapt the voltage and the frequency generated by the generator to the voltage and frequency of the power supply network connected.
- different devices are used as converters, for example so-called direct converters, in which, for. B. using semiconductor switches (for example thyristors or GTOs, gate turn-off thyristors) in a direct conversion (AC / AC) the two different voltages and frequencies can be set relative to each other.
- Direct converters of this type exist, for example, as so-called cycloconverters or as so-called matrix converters (for example described in US Pat. No. 5,594,636). With natural commutation, they produce undesirable and difficult to eliminate low-frequency components, with forced commutation they have large switching losses.
- a voltage and frequency-adapted connection a generator to a power supply network in the form of an indirect conversion.
- a direct current is first generated from the alternating current generated by the generator in a rectifier, and this direct current is then brought to the voltage and frequency of the power supply network in an inverter.
- Controlled inverters of this type also use semiconductor switches (for example GTOs, IGBTs, Insulated Gate Bipolar Transistors, MOSFETs, Metal Oxide Semiconductor Field Effect Transistors, or IGCTs, Integrated Gate Commutated Thyristors) and have large switching losses at the switching frequencies typically used.
- the object of the invention is therefore to provide a simple, flexible method characterized by low switching losses for adapting the alternating current generated by a generator or the alternating voltage generated by a generator to a network. It is a method in connection with a generator with at least one excitation coil.
- a static frequency converter is used to adapt between the generator and the network, and in that on the one hand, means for controlling the power fed into the network are arranged with which the strength of the excitation field generated by the at least one excitation coil is regulated , and on the other hand a suitable control of the phase position between the frequency converter voltage and the generator or mains voltage is carried out.
- the essence of the invention is therefore to utilize the advantages that are typically associated with the use of static frequency converters, namely simple construction, low switching losses, etc., without having to accept the disadvantages thereof.
- a major disadvantage of static frequency converters is that they do convert the frequency allow between input and output, but not typically a simple control of the ratio of the amplitude of the AC voltage between input and output.
- This disadvantage is now eliminated in a surprisingly simple manner in that, on the one hand, the excitation field of the excitation coil of the generator and on the other hand the phase position between the voltage generated by the controlled rectifier and the generator voltage are regulated accordingly to regulate the power coupled into the network by the generator becomes.
- the proposed circuit or method has the further advantage that it can allow the turbine generator group to start up to the required minimum speed in a simple manner when starting.
- Thermal or other energy sources such as gas turbines cannot generate torque at low speeds. They must first be brought to a minimum speed using an engine before they can output power.
- the generator can only be operated synchronously with the network, i.e. at nominal speed, and an additional starter motor with its own supply and control devices is required (state of the art).
- the additional starting devices can be dispensed with if the converter can start up the generator together with the turbine. To do this:
- the converter can generate any voltage and frequency on the generator side.
- voltage and frequency are roughly proportional to the speed (with constant excitation). For the run-up from standstill to nominal speed, voltage and frequency must also be varied from zero to nominal value.
- the proposed circuit is very suitable for a startup. It can easily generate any voltages and frequencies by operating at higher switching frequencies. The higher losses generated by this mode of operation only occur when starting up, which is allowed because only for a short time, and since similar losses typically occur in a special starting device. As soon as the speed range of energy production is reached, the system switches to low-loss basic frequency clocking.
- the static frequency converter used is an indirect frequency converter.
- it is a static frequency converter designed as a rectifier / inverter with a direct current stage connected in between.
- This simple design which is usually associated with high switching losses if the ratio of the voltages between input and output is to be variably set via a specific circuit of rectifier or inverter, can be achieved by regulating the field of excitation according to the invention and the phase length of the Frequency converter generated voltages can be set without complex measures.
- a further preferred embodiment of the method according to the invention is characterized in that the adaptation takes place via a static frequency converter with a controlled rectifier in basic frequency clocking and / or with a controlled inverter in basic frequency clocking.
- the method is particularly advantageous if both rectifiers and inverters are designed as controlled components with fundamental frequency clocking.
- the use of two pulse inverters arranged to a certain extent in mirror image is particularly simple and is also possible with generators which have to be dynamically regulated in their power coupling to the network due to the control of the excitation coil according to the invention.
- Two-stage converters or three-stage converters can be used for the rectifier as well as for the inverter.
- Three-stage converters are preferred for a generator with only one stator winding group, and two and three-stage converters are very suitable for several winding groups.
- the controlled inverter is preferably a three-stage inverter. Both are preferably operated in basic frequency clocking.
- Such three-stage inverters are known to the person skilled in the art in their general mode of operation and are available, for example, in standard literature such as "Convertisseurs statiques", Hansruedi Buehler, Presses Polytechniques et Universitaires Romandes, 1991.
- Such a method according to the invention is preferably implemented by arranging a central control which, by measuring the voltage and / or current in front of and / or behind the static frequency converter, adjusts the amplitude of the AC voltage fed into the network by appropriately controlling the means for the control the strength of the excitation field generated by the excitation coil.
- the central control also sets a suitable phase angle between
- the active power is mainly determined by the angle, the reactive power (and thus the power factor) by the amplitude.
- the frequency components that may occur outside the actual desired fundamental frequency both on the generator side of the static frequency converter and on the network side of the static frequency converter can be reduced or even completely eliminated by arranging corresponding filter elements on one or both sides.
- bandpass filters, high-pass filters or low-pass filters, or combinations of such filters can be considered. It can also be active or passive Trade components.
- the method according to the invention can be carried out not only in the case of generators with one stator winding group, but equally in the case of generators with two or more winding groups. Accordingly, the groups of three phases generated in each case are converted via individual static frequency converters.
- the coupling to the network behind the static frequency converter is preferably ensured by means of a transformer in which the one group of three phases are guided in a star connection and the other group of three phases in a delta connection.
- the present invention relates to an apparatus for carrying out a method as described above.
- the device preferably comprises a generator with at least one excitation coil which can be regulated by means of adapting the amplitude of the AC voltage to the requirements of the network, a static frequency converter comprising at least one controlled rectifier in basic frequency clocking and at least one controlled inverter in basic frequency clocking and at least one controller for Control of these elements.
- Figure 1 is a schematic representation of the connection of a generator to a power supply network.
- Fig. 3 is a schematic representation acc. Fig. 1, with additional filters for damping harmonics are inserted.
- gears can be used between the actual power source P and the generator for generating electrical energy.
- these usually have the disadvantage that they entail high losses and are maintenance-intensive.
- As the frequency of rotation of the generator ultimately determines the frequency of the alternating current generated with it it is alternatively also possible to connect the generator directly to the power source, possibly via a coupling, and then to adapt the frequency of the generated current to the mains frequency behind the generator by using a frequency converter.
- a frequency converter avoids the mechanical losses occurring in a transmission, but usually leads to energy losses due to the switching or commutation behavior of the switched semiconductor components used therein.
- the system comprises a generator 1, in which a rotating excitation coil 2 induces a corresponding AC voltage in the stator windings 16.
- the rotation of the excitation coil 2 is ensured by a power source P, which can consist of a gas turbine, or else of a water turbine or another kinetic energy source.
- the current sent through the excitation coil 2 can be set as a function of the requirements by means 3 for regulation, which are controlled by a controller 6.
- means 3 for regulation which are controlled by a controller 6.
- thyristor current can be used as a means 3 for regulation if a three-phase network is used as the energy source, or choppers if a direct current is used as the energy source. The manner and target of this control of the means 3 is described below.
- the current generated by the generator 1 is then fed to a frequency converter 9.
- the frequency converter is a so-called static frequency converter.
- possibilities are advantageously provided in front of the frequency converter to measure the current intensity and voltage of the alternating current and to supply the corresponding measured values to the controller 6.
- the frequency converter 9 comprises three parts, ie a rectifier 4, an inverter 5 and a direct current stage 10.
- the rectifier 4 ensures the conversion of the alternating current of the generator 1 with a frequency fGen into direct current.
- This direct current is then in an inverter 5 f to the adjusted frequency to the network N etwork changed.
- the ratio between AC voltage and DC voltage is constant in a two-stage converter with basic frequency switching.
- the ratio between AC voltage and DC voltage can be set as desired.
- harmonics are generated (as with the two-stage converter).
- One of the advantages of the three-stage converter compared to the two-stage converter is the possibility of reduce waves and get a comparatively good waveform. This goal limits the adjustability of the voltage ratio to a small range, the size of which depends on the size of the permitted harmonics.
- the voltage control is now carried out in combination via the converter and the generator excitation.
- the active power is mainly influenced by the phase angle between the generator voltage and the voltage generated by the controlled rectifier (or mains voltage and the voltage generated by the controlled inverter).
- the reactive power (and thus the power factor) is mainly influenced by the ratio of the amplitudes of the generator voltage and the voltage generated by the controlled rectifier (or mains voltage and the voltage generated by the controlled inverter).
- a three-stage pulse rectifier is used as the rectifier 4.
- Such a pulse rectifier is described, for example, in "Convertisseurs statiques”, Hansruedi Bühler, Presses Polytechniques et Universitaires Romandes, 1991 on page 302ff and is therefore known to the person skilled in the art.
- Each of the three phases made available by generator 1 is rectified via a corresponding rectifier circuit, as shown in FIG. 1.
- Semiconductor components such as GTOs, IGBTs, MOSFETs or IGCTs are used as power switches in such a pulse rectifier.
- the rectifier 4 is operated with the so-called basic frequency clocking, ie with a method in which the switching losses or commutation losses that occur are minimal (cf. loc. Cit. P. 147ff.).
- the only disadvantage of this switching method is that the voltage ratio of the input voltage from the generator (UGen) to the DC voltage (U DC) is constant and cannot be regulated without changing the switching method and without the associated switching losses.
- the DC voltage provided in such a three-stage rectification, in which the individual of the three levels are separated from one another by capacitances, is then used as an input for an inverter 5 of the same type, but arranged to a certain extent in mirror image.
- a pulse inverter as has already been described in connection with the rectifier 4, is again used as the inverter 5.
- This pulse-controlled inverter is also operated in its basic frequency clocking so that switching losses are kept to a minimum.
- the AC voltage made available by the inverter 5 in three phases is then fed into the network 8, possibly via a transformer 7.
- U N. etz in other words, such a frequency converter 9 can be used to set any ratio of the frequencies from input (fcen) to output (f etz), but any regulation of the active and reactive power coupled into the network 8 is due to the rigid ratio of tensions not possible.
- the procedure according to the invention is such that the ratio of the voltages is set indirectly via the setting of the current supplied to the excitation coil 2.
- This Possible regulation via the means 3 leads to the excitation field generated by the excitation coil 2 and thus the voltage induced in the stator windings 16 being regulated.
- the control is carried out by the unit 6, which therefor the data available via the measuring devices for voltage measurement 11 and for current measurement 17 for voltage and current respectively. can use for their phase positions and frequencies.
- the desired power with the desired power factor can always be delivered to the network 8.
- this type of control has the great advantage that changes in the power fed into the network 8 are possible on a very short time scale.
- the comparatively good waveform of a three-stage rectifier or inverter makes it possible to use a frequency converter 9 constructed therefrom as a direct connection between generator 1 and network 8. If necessary, as already mentioned, a transformer 7 can additionally be used between frequency converter 9 and network 8.
- the generator can also be a generator with several stator winding groups.
- 2 shows a generator 1 with two stator winding groups 12 and 13. The corresponding three phases of each winding group are then fed separately to a frequency converter.
- the three phases of the first stator winding groups 12 are fed to a first rectifier stage 41 and then brought to the frequency required for the network 8 in an inverter stage 51.
- the three phases of the second stator winding groups 13 are fed to a first rectifier stage 42 and then also brought to the frequency required for the network in an inverter stage 52.
- the three phases of the first group and the second group are then coupled to the network via transformer coils 72 and 73, respectively, by means of transformer coil 71.
- one of the groups is advantageously designed in a star connection and the other group in a delta connection. If the design of either generator 1 or network 8 makes this necessary, it is also possible to eliminate or eliminate harmonic multiples, such as those which typically occur in the proposed rectifier 4 and the proposed inverter 5 in terms of their fundamental frequency clocking, using appropriate filters dampen. This is shown in FIG. 3, where a low pass is provided on the side of the generator 1 via a choke coil 14 in line and a capacitance 15 to earth. In this way, undesired frequency components, which can affect the generator 1 and, for example, lead to torque oscillations, can be eliminated.
- undesired frequency components in the direction of the network 8 can be reduced or even eliminated via a corresponding low-pass filter arranged on the side of the network 8, composed of a choke coil 74 in line and a capacitance 75 to earth.
- a corresponding low-pass filter arranged on the side of the network 8, composed of a choke coil 74 in line and a capacitance 75 to earth.
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- Engineering & Computer Science (AREA)
- Power Engineering (AREA)
- Control Of Eletrric Generators (AREA)
- Ac-Ac Conversion (AREA)
- Supply And Distribution Of Alternating Current (AREA)
- Rectifiers (AREA)
Abstract
The invention relates to a method and a device for adapting the alternating current produced by a generator (1) or the alternating current produced by a generator (1) and supplied to a network (8), said generator (1) having at least one field coil (2). To achieve a flexible adaptation of the power that is supplied to the network (8) with low switching losses, a static frequency converter (9) is used to adapt the current between the generator (1) and the network (8). Means (3) are also provided to control the power that is supplied to the network (8), said means regulating the intensity of the excitation field that is produced by the field coil(s) (2) and the phasing between the frequency converter voltage and the generator voltage or network voltage is appropriately controlled.
Description
Frequenzumwandler für Hochgeschwindigkeitsgeneratoren Frequency converter for high-speed generators
TECHNISCHES GEBIETTECHNICAL AREA
Die vorliegende Erfindung betrifft ein Verfahren zur Anpassung des von einem Generator erzeugten Wechselstroms respektive der von einem Generator erzeugten Wechselspannung an ein Netz, wobei es sich beim Generator um einen Generator mit wenigstens einer Erregerspule handelt. Ausserdem betrifft die vorliegende Er- findung eine Vorrichtung zur Durchführung eines derartigen Verfahrens.The present invention relates to a method for adapting the alternating current generated by a generator or the alternating voltage generated by a generator to a network, the generator being a generator with at least one excitation coil. In addition, the present invention relates to a device for performing such a method.
STAND DER TECHNIKSTATE OF THE ART
Drehzahlvariable Generatoren oder ganz allgemein Generatoren mit einer Frequenz, welche von der Netzfrequenz abweicht, werden typischerweise über Um- richter, welche eine Anpassung der Spannung und der Frequenz, welche von Generator erzeugt wird, an die Spannung und Frequenz des Stromversorgungsnetzes vornehmen, an das Stromversorgungsnetz angeschlossen. Als Umrichter werden zu diesem Zweck unterschiedliche Vorrichtungen verwendet, so beispielsweise so genannte direkte Umrichter, bei welchen z. B. unter Verwendung von Halb- leiterschaltern (zum Beispiel Thyristoren oder GTOs, Gate Turn-Off Thyristors) in einer direkten Konversion (AC/AC) die beiden unterschiedlichen Spannungen und Frequenzen relativ zueinander eingestellt werden. Derartige direkte Umrichter gibt es beispielsweise als so genannte Zyklokonverter oder als so genannte Matrixkonverter (z. B. beschrieben in der US 5,594,636). Bei natürlicher Kommutierung erzeugen sie unerwünschte und schwierig zu eliminierende niederfrequente Frequenzkomponenten, bei gezwungener Kommutierung weisen sie grosse Schaltverluste auf.Variable-speed generators or generators in general with a frequency that deviates from the mains frequency are typically transmitted to the power supply network via converters, which adapt the voltage and the frequency generated by the generator to the voltage and frequency of the power supply network connected. For this purpose, different devices are used as converters, for example so-called direct converters, in which, for. B. using semiconductor switches (for example thyristors or GTOs, gate turn-off thyristors) in a direct conversion (AC / AC) the two different voltages and frequencies can be set relative to each other. Direct converters of this type exist, for example, as so-called cycloconverters or as so-called matrix converters (for example described in US Pat. No. 5,594,636). With natural commutation, they produce undesirable and difficult to eliminate low-frequency components, with forced commutation they have large switching losses.
Alternativ ist es möglich, einen spannungs- und frequenz-angepassten Anschluss
eines Generators an ein Stromversorgungsnetz in Form einer indirekten Konversion zu gewährleisten. Bei einer derartigen Konversion wird zunächst aus dem Wechselstrom, welcher vom Generator erzeugt wird, in einem Gleichrichter ein Gleichstrom erzeugt, und dieser Gleichstrom anschliessend in einem Wechsel- richter auf die Spannung und Frequenz des Stromversorgungsnetzes gebracht. Derartige gesteuerte Umrichter benutzen ebenfalls Halbleiterschalter (zum Beispiel GTO's, IGBT's, Insulated Gate Bipolar Transistors, MOSFET's, Metal Oxide Semiconductor Field Effect Transistors, oder IGCT's, Integrated Gate Commutated Thyristors), und weisen bei den typischerweise verwendeten Schaltfrequenzen grosse Schaltverluste auf.Alternatively, it is possible to have a voltage and frequency-adapted connection a generator to a power supply network in the form of an indirect conversion. In the case of such a conversion, a direct current is first generated from the alternating current generated by the generator in a rectifier, and this direct current is then brought to the voltage and frequency of the power supply network in an inverter. Controlled inverters of this type also use semiconductor switches (for example GTOs, IGBTs, Insulated Gate Bipolar Transistors, MOSFETs, Metal Oxide Semiconductor Field Effect Transistors, or IGCTs, Integrated Gate Commutated Thyristors) and have large switching losses at the switching frequencies typically used.
DARSTELLUNG DER ERFINDUNGPRESENTATION OF THE INVENTION
Der Erfindung liegt demnach die Aufgabe zugrunde, ein einfaches, flexibles, durch niedrige Schaltverluste gekennzeichnetes Verfahren zur Anpassung des von ei- nem Generator erzeugten Wechselstromes respektive der von einem Generator erzeugten Wechselspannung an ein Netz zur Verfügung zu stellen. Es handelt sich dabei um ein Verfahren im Zusammenhang mit einem Generator mit wenigstens einer Erregerspule.The object of the invention is therefore to provide a simple, flexible method characterized by low switching losses for adapting the alternating current generated by a generator or the alternating voltage generated by a generator to a network. It is a method in connection with a generator with at least one excitation coil.
Die Lösung dieser Aufgabe wird dadurch erreicht, dass zur Anpassung zwischen Generator und Netz ein statischer Frequenzumwandler verwendet wird, und dass zur Steuerung der in das Netz eingespeisten Leistung einerseits Mittel angeordnet sind, mit welchen die Stärke des von der wenigstens einen Erregerspule erzeugten Erregerfeldes geregelt wird, und andererseits eine geeignete Ansteuerung der Phasenlage zwischen Frequenzumwandlerspannung und Generator- respektive Netzspannung vorgenommen wird.This object is achieved in that a static frequency converter is used to adapt between the generator and the network, and in that on the one hand, means for controlling the power fed into the network are arranged with which the strength of the excitation field generated by the at least one excitation coil is regulated , and on the other hand a suitable control of the phase position between the frequency converter voltage and the generator or mains voltage is carried out.
Der Kern der Erfindung besteht somit darin, die Vorteile, die typischerweise mit der Verwendung von statischen Frequenzumwandlern verbunden sind, nämlich einfache Bauweise, niedrige Schaltverluste, etc., zu nutzen, ohne deren Nachteile in Kauf nehmen zu müssen. Ein wesentlicher Nachteil von statischen Frequenz- umwandlern besteht nämlich darin, dass sie zwar eine Umwandlung der Frequenz
zwischen Eingang und Ausgang erlauben, nicht aber typischerweise eine einfache Regelung des Verhältnisses der Amplitude der Wechselspannung zwischen Eingang und Ausgang. Dieser Nachteil wird nun eben in überraschend einfacher Weise dadurch behoben, dass zur Regelung der durch den Generator in das Netz ein- gekoppelten Leistung einerseits das Erregerfeld der Erregerspule des Generators, und andererseits die Phasenlage zwischen der vom gesteuerten Gleichrichter erzeugten Spannung und der Generatorspannung entsprechend geregelt wird.The essence of the invention is therefore to utilize the advantages that are typically associated with the use of static frequency converters, namely simple construction, low switching losses, etc., without having to accept the disadvantages thereof. A major disadvantage of static frequency converters is that they do convert the frequency allow between input and output, but not typically a simple control of the ratio of the amplitude of the AC voltage between input and output. This disadvantage is now eliminated in a surprisingly simple manner in that, on the one hand, the excitation field of the excitation coil of the generator and on the other hand the phase position between the voltage generated by the controlled rectifier and the generator voltage are regulated accordingly to regulate the power coupled into the network by the generator becomes.
Die vorgeschlagene Schaltung respektive das vorgeschlagene Verfahren hat den weiteren Vorteil, dass es in einfacher Weise beim Aufstarten den Hochlauf der Turbinen-Generator-Gruppe auf die nötige Minimaldrehzahl ermöglichen kann. Thermische oder andere Energiequellen wie Gasturbinen können bei tiefen Drehzahlen kein Drehmoment erzeugen. Sie müssen mit Hilfe eines Motors zuerst auf eine Minimaldrehzahl gebracht werden, bevor sie Leistung abgeben können. Bei der Lösung " Turbine-Getriebe-Generator-Netz " kann der Generator nur synchron zum Netz, bei Nenndrehzahl also, betrieben werden, und es wird ein zusätzlicher Startmotor mit eigenen Speise- und Regelvorrichtungen benötigt (Stand der Technik).The proposed circuit or method has the further advantage that it can allow the turbine generator group to start up to the required minimum speed in a simple manner when starting. Thermal or other energy sources such as gas turbines cannot generate torque at low speeds. They must first be brought to a minimum speed using an engine before they can output power. With the "turbine-gear-generator-network" solution, the generator can only be operated synchronously with the network, i.e. at nominal speed, and an additional starter motor with its own supply and control devices is required (state of the art).
Bei einer Lösung " Turbine-Generator-Umrichter-Netz " kann auf die zusätzlichen Startvorrichtungen verzichtet werden, falls der Umrichter den Generator mitsamt Turbine hochfahren kann. Hierzu muss:In the case of a "turbine-generator-converter network" solution, the additional starting devices can be dispensed with if the converter can start up the generator together with the turbine. To do this:
1) Energie vom Netz über den Umrichter zum Generatorf Hessen können1) Energy from the network via the converter to the generator can be used
2) der Umrichter auf der Generatorseite beliebige Spannung und Frequenz erzeugen können. Bei einem Generator sind Spannung und Frequenz etwa proportional zur Drehzahl (bei konstanter Erregung). Für den Hochlauf vom Stillstand auf Nenndrehzahl müssen also auch Spannung und Frequenz von Null auf Nennwert variiert werden.2) the converter can generate any voltage and frequency on the generator side. In a generator, voltage and frequency are roughly proportional to the speed (with constant excitation). For the run-up from standstill to nominal speed, voltage and frequency must also be varied from zero to nominal value.
Die vorgeschlagene Schaltung ist für einen Hochlauf sehr geeignet. Sie kann in einfacherweise beliebige Spannungen und Frequenzen erzeugen, indem sie mit höheren Schaltfrequenzen betrieben wird. Die durch diese Betriebsart erzeugten höheren Verluste fallen nur beim Aufstarten an, was erlaubt ist, da nur kurzzeitig,
und da typischerweise in einer speziellen Startvorrichtung ähnliche Verluste anfallen. Sobald der Drehzahlbereich der Energieproduktion erreicht wird, wird auf die verlustarme Grundfrequenztaktung umgeschaltet.The proposed circuit is very suitable for a startup. It can easily generate any voltages and frequencies by operating at higher switching frequencies. The higher losses generated by this mode of operation only occur when starting up, which is allowed because only for a short time, and since similar losses typically occur in a special starting device. As soon as the speed range of energy production is reached, the system switches to low-loss basic frequency clocking.
Mit dieser Schaltung können also die Kosten für eine zusätzliche Startvorrichtung eingespart werden.With this circuit, the costs for an additional starting device can be saved.
Gemäss einer ersten bevorzugten Ausführungsform des vorliegenden Verfahrens handelt es sich beim verwendeten statischen Frequenzumwandler um einen indirekten Frequenzumwandler. Mit anderen Worten handelt es sich um einen als Gleichrichter/Wechselrichter ausgebildeten statischen Frequenzumwandler mit ei- ner dazwischen geschalteten Gleichstromstufe. Diese einfache Bauweise, welche üblicherweise, wenn zusätzlich über eine spezifische Schaltung von Gleichrichter respektive Wechselrichter das Verhältnis der Spannungen zwischen Eingang und Ausgang variabel eingestellt werden soll, mit hohen Schaltverlusten verbunden ist, kann durch die erfindungsgemässe Regelung des Erregerfeldes und die Phasen- läge der vom Frequenzumwandler erzeugten Spannungen ohne komplexe Mass- nahmen eingestellt werden.According to a first preferred embodiment of the present method, the static frequency converter used is an indirect frequency converter. In other words, it is a static frequency converter designed as a rectifier / inverter with a direct current stage connected in between. This simple design, which is usually associated with high switching losses if the ratio of the voltages between input and output is to be variably set via a specific circuit of rectifier or inverter, can be achieved by regulating the field of excitation according to the invention and the phase length of the Frequency converter generated voltages can be set without complex measures.
Eine weitere bevorzugte Ausführungsform des erfindungsgemässen Verfahrens ist dadurch gekennzeichnet, dass die Anpassung über einen statischen Frequenzumwandler mit einem gesteuerten Gleichrichter in Grundfrequenztaktung und/oder mit einem gesteuerten Wechselrichter in Grundfrequenztaktung erfolgt. Ganz besonders vorteilhaft ist das Verfahren, wenn sowohl Gleichrichter als auch Wechselrichter als gesteuerte Bauteile in Grundfrequenztaktung ausgebildet sind. Die Verwendung von zwei gewissermassen spiegelbildlich angeordneten Pulswechselrichtern ist besonders einfach und wird durch die erfindungsgemässe Ansteue- rung der Erregerspule ausserdem auch bei Generatoren möglich, welche in ihrer Leistungsankopplung an das Netz dynamisch geregelt werden müssen.A further preferred embodiment of the method according to the invention is characterized in that the adaptation takes place via a static frequency converter with a controlled rectifier in basic frequency clocking and / or with a controlled inverter in basic frequency clocking. The method is particularly advantageous if both rectifiers and inverters are designed as controlled components with fundamental frequency clocking. The use of two pulse inverters arranged to a certain extent in mirror image is particularly simple and is also possible with generators which have to be dynamically regulated in their power coupling to the network due to the control of the excitation coil according to the invention.
Es können Zweistufenumrichter oder Dreistufenumrichter verwendet werden, für den Gleichrichter wie für den Wechselrichter. Dreistufenumrichter werden bevorzugt bei einem Generator mit nur einer Statorwicklungsgruppe, bei mehreren Wicklungsgruppen sind Zwei- und Dreistufenumrichter sehr geeignet. Bevorzugt
handelt es sich beim gesteuerten Gleichrichter um einen Drei-Stufen-Gleichrichter. Alternativ oder gleichzeitig handelt es sich vorzugsweise beim gesteuerten Wechselrichter um einen Drei-Stufen-Wechselrichter. Beide werden dabei bevorzugt in Grundfrequenztaktung betrieben. Derartige Drei-Stufen-Wechselrichter sind dem Fachmann in ihrer allgemeinen Funktionsweise bekannt, und sind beispielsweise in Standardliteratur wie "Convertisseurs statiques", Hansruedi Bühler, Presses Polytechniques et Universitaires Romandes, 1991, verfügbar.Two-stage converters or three-stage converters can be used for the rectifier as well as for the inverter. Three-stage converters are preferred for a generator with only one stator winding group, and two and three-stage converters are very suitable for several winding groups. Prefers the controlled rectifier is a three-stage rectifier. Alternatively or simultaneously, the controlled inverter is preferably a three-stage inverter. Both are preferably operated in basic frequency clocking. Such three-stage inverters are known to the person skilled in the art in their general mode of operation and are available, for example, in standard literature such as "Convertisseurs statiques", Hansruedi Buehler, Presses Polytechniques et Universitaires Romandes, 1991.
Ein derartiges erfindungsgemässes Verfahren wird bevorzugt realisiert, indem eine zentrale Steuerung angeordnet wird, welche über die Messung von Spannung und/oder Stromstärke vor und/oder hinter dem statischen Frequenzumwandler eine Anpassung der ins Netz eingespeisten Amplitude der Wechselspannung durch eine entsprechende Ansteuerung der Mittel zur Steuerung der Stärke des von der Erregerspule erzeugten Erregerfeldes vornimmt.Such a method according to the invention is preferably implemented by arranging a central control which, by measuring the voltage and / or current in front of and / or behind the static frequency converter, adjusts the amplitude of the AC voltage fed into the network by appropriately controlling the means for the control the strength of the excitation field generated by the excitation coil.
Die zentrale Steuerung stellt ausserdem einen geeigneten Phasenwinkel ein zwi- sehenThe central control also sets a suitable phase angle between
1) Generatorspannung und der durch den gesteuerten Gleichrichter erzeugten Spannung1) Generator voltage and the voltage generated by the controlled rectifier
2) Netzspannung und der durch den gesteuerten Wechselrichter erzeugten Spannung um den gewünschten Leistungsfluss mit gewünschten Leistungsfaktoren zu ermöglichen.2) Mains voltage and the voltage generated by the controlled inverter to enable the desired power flow with the desired power factors.
Die Wirkleistung wird hauptsächlich durch den Winkel bestimmt, die Blindleistung (und damit der Leistungsfaktor) durch die Amplitude.The active power is mainly determined by the angle, the reactive power (and thus the power factor) by the amplitude.
Die möglicherweise auftretenden Frequenzkomponenten ausserhalb der eigentli- chen gewünschten Grundfrequenz sowohl generatorseitig des statischen Fre- quenzumwandlers als auch netzseitig des statischen Frequenzumwandlers können reduziert oder sogar vollständig eliminiert werden, indem auf einer oder beiden Seiten entsprechende Filterelemente angeordnet werden. In Frage kommen beispielsweise Bandpassfilter, Hochpassfilter oder Tiefpassfilter, oder Kombinatio- nen von derartigen Filtern. Es kann sich dabei ausserdem um aktive oder passive
Bauelemente handeln.The frequency components that may occur outside the actual desired fundamental frequency both on the generator side of the static frequency converter and on the network side of the static frequency converter can be reduced or even completely eliminated by arranging corresponding filter elements on one or both sides. For example, bandpass filters, high-pass filters or low-pass filters, or combinations of such filters can be considered. It can also be active or passive Trade components.
Das erfindungsgemässe Verfahren kann nicht nur bei Generatoren mit einer Statorwicklungsgruppe durchgeführt werden, sondern gleichermassen bei Generatoren mit zwei oder mehr Wicklungsgruppen. Entsprechend werden die dabei er- zeugten Gruppen von jeweils drei Phasen über jeweils individuelle statische Frequenzumwandler gewandelt. Zum Beispiel bei einem Generator mit zwei Statorwicklungsgruppen wird bevorzugt die Ankopplung an das Netz hinter dem statischen Frequenzumwandler über einen Transformator sichergestellt, bei welchem die eine Gruppe von drei Phasen in einer Sternschaltung geführt sind und die an- dere Gruppe von drei Phasen in einer Dreieckschaltung.The method according to the invention can be carried out not only in the case of generators with one stator winding group, but equally in the case of generators with two or more winding groups. Accordingly, the groups of three phases generated in each case are converted via individual static frequency converters. For example, in the case of a generator with two stator winding groups, the coupling to the network behind the static frequency converter is preferably ensured by means of a transformer in which the one group of three phases are guided in a star connection and the other group of three phases in a delta connection.
Weitere bevorzugte Ausführungsformen des vorliegenden Verfahrens sind in den abhängigen Ansprüchen beschrieben.Further preferred embodiments of the present method are described in the dependent claims.
Ausserdem betrifft die vorliegende Erfindung eine Vorrichtung zur Durchführung eines Verfahrens, wie es weiter oben beschrieben ist. Die Vorrichtung umfasst vorzugsweise einen Generator mit wenigstens einer über Mittel in Bezug auf die Anpassung der Amplitude der Wechselspannung an die Erfordernisse des Netzes regelbaren Erregerspule, einen statischen Frequenzumwandler umfassend wenigstens einen gesteuerten Gleichrichter in Grundfrequenztaktung und wenigstens einen gesteuerten Wechselrichter in Grundfrequenztaktung sowie wenigstens eine Steuerung zur Steuerung dieser Elemente.In addition, the present invention relates to an apparatus for carrying out a method as described above. The device preferably comprises a generator with at least one excitation coil which can be regulated by means of adapting the amplitude of the AC voltage to the requirements of the network, a static frequency converter comprising at least one controlled rectifier in basic frequency clocking and at least one controlled inverter in basic frequency clocking and at least one controller for Control of these elements.
Weitere bevorzugte Ausführungsformen der erfindungsgemässen Vorrichtung sind in den abhängigen Ansprüchen beschrieben.Further preferred embodiments of the device according to the invention are described in the dependent claims.
KURZE ERLÄUTERUNG DER FIGURENBRIEF EXPLANATION OF THE FIGURES
Die Erfindung soll nachfolgend anhand von Ausführungsbeispielen im Zusammenhang mit den Zeichnungen näher erläutert werden. Es zeigen:The invention will be explained in more detail below using exemplary embodiments in conjunction with the drawings. Show it:
Fig. 1 eine schematische Darstellung des Anschlusses eines Generators an ein Stromversorgungsnetz;Figure 1 is a schematic representation of the connection of a generator to a power supply network.
Fig.2 eine schematische Darstellung gem. Fig. 1 , wobei der Stator des Genera-
tors mit zwei Wicklungsgruppen ausgestaltet ist ; und2 shows a schematic representation acc. 1, the stator of the genera- tors is designed with two winding groups; and
Fig. 3 eine schematische Darstellung gem. Fig. 1, wobei zusätzlich Filter zur Dämpfung von Harmonischen eingefügt sind.Fig. 3 is a schematic representation acc. Fig. 1, with additional filters for damping harmonics are inserted.
WEGE ZUR AUSFÜHRUNG DER ERFINDUNGWAYS OF CARRYING OUT THE INVENTION
Viele Stromerzeugungsanlagen verwenden thermische oder andere Energiequellen wie Gasturbinen als Leistungsquellen. Typischerweise sind derartige Leistungsquellen durch schnelle Rotationsgeschwindigkeiten und damit durch hohe Betriebsfrequenzen gekennzeichnet, sowie durch die Möglichkeit, die Rotations- geschwindigkeit in Anpassung an den Leistungsbedarf zu ändern.Many power generation plants use thermal or other energy sources such as gas turbines as power sources. Power sources of this type are typically characterized by fast rotation speeds and thus by high operating frequencies, and by the possibility of changing the rotation speed in accordance with the power requirement.
Um den unterschiedlichen Rotationsgeschwindigkeiten des Energieerzeugers, welcher beispielsweise in Fig. 1 mit dem Bezugszeichen P symbolisch dargestellt ist, Rechnung zu tragen, können beispielsweise zwischen der eigentlichen Leistungsquelle P und den Generator zur Erzeugung elektrischer Energie Getriebe eingesetzt werden. Diese weisen aber normalerweise den Nachteil auf, hohe Verluste mit sich zu bringen und wartungsintensiv zu sein. Da die Rotationsfrequenz des Generators letzten Endes die Frequenz des damit erzeugten Wechselstromes bestimmt, ist es alternativ auch möglich, den Generator direkt an die Leistungsquelle, gegebenenfalls über eine Kupplung, anzubinden, und anschliessend hinter dem Generator eine Anpassung der Frequenz des erzeugten Stromes an die Netzfrequenz vorzunehmen, indem ein Frequenzumwandler vorgesehen wird. Ein derartiger Frequenzumwandler vermeidet zwar die in einem Getriebe auftretenden mechanischen Verluste, führt aber in der Regel zu Energieverlusten durch das Schalt- respektive Kommutationsverhalten der darin eingesetzten geschalteten Halbleiterbauteile.In order to take into account the different rotational speeds of the energy generator, which is symbolically represented in FIG. 1 by the reference symbol P, for example, gears can be used between the actual power source P and the generator for generating electrical energy. However, these usually have the disadvantage that they entail high losses and are maintenance-intensive. As the frequency of rotation of the generator ultimately determines the frequency of the alternating current generated with it, it is alternatively also possible to connect the generator directly to the power source, possibly via a coupling, and then to adapt the frequency of the generated current to the mains frequency behind the generator by using a frequency converter. Such a frequency converter avoids the mechanical losses occurring in a transmission, but usually leads to energy losses due to the switching or commutation behavior of the switched semiconductor components used therein.
Fig. 1 zeigt nun eine schematische Darstellung eines Stromerzeugers und seiner Ankopplung an ein Netz 8, bei welchem derartige Verluste möglichst gering gehalten werden können, und trotzdem unterschiedliche Rotationsgeschwindigkeiten des Generators möglich sind, ohne dass mechanische Getriebe erforderlich wä- ren.
Das System umfasst einen Generator 1, in welchem eine rotierende Erregerspule 2 eine entsprechende Wechselspannung in den Statorwicklungen 16 induziert. Die Rotation der Erregerspule 2 wird dabei durch eine Leistungsquelle P gewährleistet, welche aus einer Gasturbine bestehen kann, oder aber auch aus einer Was- serturbine oder einer anderen kinetischen Energiequelle.1 now shows a schematic representation of a power generator and its coupling to a network 8, in which such losses can be kept as low as possible, and nevertheless different rotational speeds of the generator are possible without the need for mechanical gears. The system comprises a generator 1, in which a rotating excitation coil 2 induces a corresponding AC voltage in the stator windings 16. The rotation of the excitation coil 2 is ensured by a power source P, which can consist of a gas turbine, or else of a water turbine or another kinetic energy source.
Der durch die Erregerspule 2 geschickte Strom kann über Mittel 3 zur Regelung, welche über eine Steuerung 6 angesteuert werden, in Abhängigkeit der Erfordernisse eingestellt werden. Als Mittel 3 zur Regelung können dabei beispielsweise Thyristorenstrom richterbrücken, wenn als Energiequelle ein dreiphasiges Netz dient, oder Chopper, wenn als Energiequelle ein Gleichstrom dient, eingesetzt werden. Die Art und Weise und Zielvorgabe dieser Steuerung der Mittel 3 wird weiter unten beschrieben.The current sent through the excitation coil 2 can be set as a function of the requirements by means 3 for regulation, which are controlled by a controller 6. For example, thyristor current can be used as a means 3 for regulation if a three-phase network is used as the energy source, or choppers if a direct current is used as the energy source. The manner and target of this control of the means 3 is described below.
Der vom Generator 1 erzeugte Strom wird anschliessend einem Frequenzumwandler 9 zugeführt. Es handelt sich beim Frequenzumwandler um einen so genannten statischen Frequenzkonverter. Um die weiter unten beschriebene Regelung der Umwandlung gewährleisten zu können, sind in vorteilhafter Weise vor dem Frequenzumwandler Möglichkeiten vorgesehen, Stromstärke und Spannung des Wechselstromes zu messen, und die entsprechenden Messwerte der Steuerung 6 zuzuführen. Der Frequenzumwandler 9 umfasst drei Teile, d.h. einen Gleichrichter 4, einen Wechselrichter 5 und eine Gleichstromstufe 10. Der Gleichrichter 4 gewährleistet die Umwandlung des Wechselstroms des Generators 1 mit einer Frequenz fGen in Gleichstrom. Dieser Gleichstrom wird anschliessend in einem Wechselrichter 5 auf die an das Netz angepasste Frequenz f Netz gewandelt. Bei einem Zweistufenumrichter mit Grundfrequenztaktung ist das Verhältnis zwischen Wechselspannung und Gleichspannung konstant.The current generated by the generator 1 is then fed to a frequency converter 9. The frequency converter is a so-called static frequency converter. In order to be able to ensure the regulation of the conversion described further below, possibilities are advantageously provided in front of the frequency converter to measure the current intensity and voltage of the alternating current and to supply the corresponding measured values to the controller 6. The frequency converter 9 comprises three parts, ie a rectifier 4, an inverter 5 and a direct current stage 10. The rectifier 4 ensures the conversion of the alternating current of the generator 1 with a frequency fGen into direct current. This direct current is then in an inverter 5 f to the adjusted frequency to the network N etwork changed. The ratio between AC voltage and DC voltage is constant in a two-stage converter with basic frequency switching.
Bei einem Dreistufenumrichter mit Grundfrequenztaktung ist das Verhältnis zwischen Wechselspannung und Gleichspannung beliebig einstellbar. Es werden aber (wie beim Zweistufenumrichter auch) Oberwellen erzeugt. Einer der Vorteile des Dreistufen- gegenüber dem Zweistufenumrichter ist die Möglichkeit, die Ober-
wellen zu reduzieren und eine vergleichsweise gute Wellenform zu erhalten. Dieses Ziel beschränkt die Einstellbarkeit des Spannungsverhältnisses auf einen kleinen Bereich, dessen Grosse von der Grosse der erlaubten Oberwellen abhängt. Die Spannungsregelung wird nun kombiniert über den Umrichter und die Genera- torerregung durchgeführt.In a three-stage converter with basic frequency switching, the ratio between AC voltage and DC voltage can be set as desired. However, harmonics are generated (as with the two-stage converter). One of the advantages of the three-stage converter compared to the two-stage converter is the possibility of reduce waves and get a comparatively good waveform. This goal limits the adjustability of the voltage ratio to a small range, the size of which depends on the size of the permitted harmonics. The voltage control is now carried out in combination via the converter and the generator excitation.
Für eine freizügige Leistungsregelung muss man sowohl die Amplitude wie die Phasenlage der Spannung einstellen. Die Wirkleistung wird hauptsächlich beein- flusst durch den Phasenwinkel zwischen Generatorspannung und der vom gesteuerten Gleichrichter erzeugten Spannung (respektive Netzspannung und der vom gesteuerten Wechselrichter erzeugten Spannung). Die Blindleistung (und damit der Leistungsfaktor) wird hauptsächlich durch das Verhältnis der Amplituden von Generatorspannung und der vom gesteuerten Gleichrichter erzeugten Spannung (respektive Netzspannung und der vom gesteuerten Wechselrichter erzeugten Spannung) beeinflusst. Als Gleichrichter 4 findet konkret im Ausführungsbeispiel ein dreistufiger Pulsgleichrichter Anwendung. Ein derartiger Pulsgleichrichter ist beispielsweise in "Convertisseurs statiques", Hansruedi Bühler, Presses Polytechniques et Universitaires Romandes, 1991 auf Seite 302ff beschrieben und damit dem Fachmann bekannt. Jede der drei vom Generator 1 zur Verfügung gestellten Phasen wird über eine entsprechende Gleichrichterschaltung, wie sie in Fig. 1 dargestellt ist, gleichgerichtet. Als Leistungsschalter werden in einem derartigen Pulsgleichrichter Halbleiterbauteile wie beispielsweise GTO's, IGBT's, MOSFET's, oder IGCT's eingesetzt.For a free power control you have to set both the amplitude and the phase of the voltage. The active power is mainly influenced by the phase angle between the generator voltage and the voltage generated by the controlled rectifier (or mains voltage and the voltage generated by the controlled inverter). The reactive power (and thus the power factor) is mainly influenced by the ratio of the amplitudes of the generator voltage and the voltage generated by the controlled rectifier (or mains voltage and the voltage generated by the controlled inverter). In the exemplary embodiment, a three-stage pulse rectifier is used as the rectifier 4. Such a pulse rectifier is described, for example, in "Convertisseurs statiques", Hansruedi Bühler, Presses Polytechniques et Universitaires Romandes, 1991 on page 302ff and is therefore known to the person skilled in the art. Each of the three phases made available by generator 1 is rectified via a corresponding rectifier circuit, as shown in FIG. 1. Semiconductor components such as GTOs, IGBTs, MOSFETs or IGCTs are used as power switches in such a pulse rectifier.
Der Gleichrichter 4 wird mit der so genannten Grundfrequenztaktung betrieben, d.h. mit einem Verfahren, in welchem die auftretenden Schaltverluste respektive Kommutationsverluste minimal sind (vgl. dazu loc. cit. S. 147ff). Nachteilig an dieser Schaltungsweise ist nur, dass dabei das Spannungsverhältnis von Eingangsspannung vom Generator (UGen) zu Gleichstromspannung (U Gleich) konstant ist, und nicht ohne Veränderung der Schaltungsweise und ohne die damit verbunde- nen Schaltverluste geregelt werden kann.
Die bei einer derartigen dreistufigen Gleichrichtung zur Verfügung gestellte Gleichspannung, bei welcher die einzelnen der drei Niveaus über Kapazitäten voneinander getrennt sind, wird anschliessend als Eingang für einen gleichartigen, aber ge- wissermassen spiegelbildlich angeordneten Wechselrichter 5 verwendet. Als Wechselrichter 5 findet wiederum ein Pulswechselrichter Anwendung, wie er bereits im Zusammenhang mit dem Gleichrichter 4 beschrieben wurde. Auch dieser Pulswechselrichter wird in seiner Grundfrequenztaktung betrieben, damit Schaltverluste minimal gehalten werden. Entsprechend ergibt sich aber auch hier ein konstantes Verhältnis von Gleichstromspannung (Udeich) zu netzseitiger Wechsel- Stromspannung (UNetz).The rectifier 4 is operated with the so-called basic frequency clocking, ie with a method in which the switching losses or commutation losses that occur are minimal (cf. loc. Cit. P. 147ff.). The only disadvantage of this switching method is that the voltage ratio of the input voltage from the generator (UGen) to the DC voltage (U DC) is constant and cannot be regulated without changing the switching method and without the associated switching losses. The DC voltage provided in such a three-stage rectification, in which the individual of the three levels are separated from one another by capacitances, is then used as an input for an inverter 5 of the same type, but arranged to a certain extent in mirror image. A pulse inverter, as has already been described in connection with the rectifier 4, is again used as the inverter 5. This pulse-controlled inverter is also operated in its basic frequency clocking so that switching losses are kept to a minimum. Correspondingly, however, here too there is a constant ratio of direct current voltage (Udeich) to alternating current voltage on the mains side (Unet).
Die durch den Wechselrichter 5 zur Verfügung gestellte Wechselspannung in drei Phasen wird anschliessend, gegebenenfalls über einen Transformator 7, in das Netz 8 eingespeist. Um wiederum eine erfindungsgemässe Regelung optimal fahren zu können, ist es vorteilhaft, hinter den Wechselrichter 5 eine Spannungsmes- sung 11 respektive eine Stromstärkenmessung 17 vorzunehmen, und die zugehörigen Messwerte der Steuerung 6 zugänglich zu machen.The AC voltage made available by the inverter 5 in three phases is then fed into the network 8, possibly via a transformer 7. In order to be able to optimally drive a control according to the invention, it is advantageous to carry out a voltage measurement 11 or a current measurement 17 behind the inverter 5 and to make the associated measurement values accessible to the controller 6.
Die beschriebene Kombination von zwei spiegelbildlich angeordneten Schaltelementen, Pulswechselrichter respektive Pulsgleichrichter 5, 4 führt dazu, dass, wenn beide mit ihrer Grundfrequenztaktung betrieben werden, ein konstantes Ver- hältnis zwischen Eingangsspannung und Ausgangsspannung vorgegeben ist.The described combination of two switching elements arranged in mirror image, pulse inverters or pulse rectifiers 5, 4 leads to the fact that when both are operated with their fundamental frequency clocking, a constant ratio between input voltage and output voltage is predetermined.
Ucm --const. Ucm --const.
U N. etz : einem derartigen Frequenzumwandler 9 lassen sich mit anderen Worten beliebige Verhältnisse der Frequenzen von Eingang (fcen) zu Ausgang (f etz) einstellen, eine beliebige Regelung der in das Netz 8 eingekoppelten Wirk- und Blindleistung ist aber infolge des starren Verhältnisses der Spannungen nicht möglich.U N. etz: in other words, such a frequency converter 9 can be used to set any ratio of the frequencies from input (fcen) to output (f etz), but any regulation of the active and reactive power coupled into the network 8 is due to the rigid ratio of tensions not possible.
Um dennoch stets die maximal mögliche Leistung von der Energiequelle P mit optimalem Leistungsfaktor in das Netz 8 einspeisen zu können, wird nun erfindungs- gemäss so vorgegangen, dass das Verhältnis der Spannungen indirekt über die Einstellung des der Erregerspule 2 zugeführten Stromes eingestellt wird. Diese
über die Mittel 3 mögliche Regelung führt dazu, dass das von der Erregerspule 2 erzeugte Erregerfeld und damit die in den Statorwicklungen 16 induzierte Spannung geregelt wird. Die Steuerung wird dabei von der Einheit 6 vorgenommen, welche dafür die über die Messgeräte zur Spannungsmessung 11 und zur Strom- Stärkenmessung 17 verfügbaren Daten zur Spannung und zur Stromstärke resp. zu deren Phasenlagen und Frequenzen verwenden kann.In order nevertheless to be able to always feed the maximum possible power from the energy source P into the network 8 with an optimum power factor, the procedure according to the invention is such that the ratio of the voltages is set indirectly via the setting of the current supplied to the excitation coil 2. This Possible regulation via the means 3 leads to the excitation field generated by the excitation coil 2 and thus the voltage induced in the stator windings 16 being regulated. The control is carried out by the unit 6, which therefor the data available via the measuring devices for voltage measurement 11 and for current measurement 17 for voltage and current respectively. can use for their phase positions and frequencies.
So kann trotz festem Verhältnis der Spannungen im statischen Frequenzumwandler 9 stets die gewünschte Leistung mit dem gewünschten Leistungsfaktor an das Netz 8 abgegeben werden. Diese Art der Regelung weist unter anderem den gros- sen Vorteil auf, dass auf einer sehr kurzen Zeitskala Änderungen der in das Netz 8 eingespeisten Leistung möglich sind. Die vergleichsweise gute Wellenform eines Drei-Stufen-Gleichrichters respektive Wechselrichters erlaubt es, einen daraus aufgebauten Frequenzumwandler 9 als direkte Verbindung zwischen Generator 1 und Netz 8 einzusetzen. Falls erforderlich kann, wie bereits erwähnt, zwischen Frequenzumwandler 9 und Netz 8 ein Transformator 7 zusätzlich Anwendung finden.Thus, despite the fixed ratio of the voltages in the static frequency converter 9, the desired power with the desired power factor can always be delivered to the network 8. Among other things, this type of control has the great advantage that changes in the power fed into the network 8 are possible on a very short time scale. The comparatively good waveform of a three-stage rectifier or inverter makes it possible to use a frequency converter 9 constructed therefrom as a direct connection between generator 1 and network 8. If necessary, as already mentioned, a transformer 7 can additionally be used between frequency converter 9 and network 8.
Wie in Fig. 2 dargestellt, kann es sich beim Generator auch um einen Generator mit mehreren Statorwicklungsgruppen handeln. In Fig. 2 ist ein Generator 1 mit zwei Statorwicklungsgruppen 12 und 13 dargestellt. Die entsprechenden drei Pha- sen jeder Wicklungsgruppe werden anschliessend separat jeweils einem Frequenzumwandler zugeführt. Mit anderen Worten werden die drei Phasen der ersten Statorwicklungsgruppen 12 einer ersten Gleichrichterstufe 41 zugeführt und anschliessend in einer Wechselrichterstufe 51 auf die für das Netz 8 erforderliche Frequenz gebracht. In einem separaten Kreis werden die drei Phasen der zweiten Statorwicklungsgruppen 13 einer ersten Gleichrichterstufe 42 zugeführt und anschliessend in einer Wechselrichterstufe 52 ebenfalls auf die für das Netz erforderliche Frequenz gebracht. Anschliessend werden die drei Phasen der ersten Gruppe und der zweiten Gruppe über Transformatorspulen 72 respektive 73 mittels der Transformatorspule 71 an das Netz angekoppelt. Um eine optimale An- kopplung zu gewährleisten, wird in vorteilhafter Weise eine der Gruppen in Sternschaltung und die andere Gruppe in Dreieckschaltung ausgelegt.
Wenn die Auslegung entweder vom Generator 1 oder vom Netz 8 dies erforderlich macht, ist es ausserdem möglich, harmonische Vielfache, wie sie typischerweise bei dem vorgeschlagenen Gleichrichter 4 und dem vorgeschlagenen Wechselrichter 5 in ihrer Grundfrequenztaktung auftreten, über entsprechende Filter zu eli- minieren oder zu dämpfen. Dies ist in Fig. 3 dargestellt, wo auf der Seite des Generators 1 über eine Drosselspule 14 in Linie und eine Kapazität 15 zur Erde ein Tiefpass vorgesehen ist. So können unerwünschte Frequenzkomponenten, welche auf den Generator 1 rückwirken können und beispielsweise zu Drehmomentschwingungen führen können, eliminiert werden. Auf der anderen Seite können über einen entsprechenden, auf der Seite des Netzes 8 angeordneten Tiefpass, aufgebaut aus einer Drosselspule 74 in Linie und einer Kapazität 75 zur Erde, unerwünschte Frequenzkomponenten in Richtung zum Netz 8 reduziert oder gar eliminiert werden. So wird Inselbetrieb oder Standalone Betriebsweise möglich in Analogie zu so genannten Uninterruptible Power Supplies (UPS).
As shown in FIG. 2, the generator can also be a generator with several stator winding groups. 2 shows a generator 1 with two stator winding groups 12 and 13. The corresponding three phases of each winding group are then fed separately to a frequency converter. In other words, the three phases of the first stator winding groups 12 are fed to a first rectifier stage 41 and then brought to the frequency required for the network 8 in an inverter stage 51. In a separate circuit, the three phases of the second stator winding groups 13 are fed to a first rectifier stage 42 and then also brought to the frequency required for the network in an inverter stage 52. The three phases of the first group and the second group are then coupled to the network via transformer coils 72 and 73, respectively, by means of transformer coil 71. In order to ensure optimal coupling, one of the groups is advantageously designed in a star connection and the other group in a delta connection. If the design of either generator 1 or network 8 makes this necessary, it is also possible to eliminate or eliminate harmonic multiples, such as those which typically occur in the proposed rectifier 4 and the proposed inverter 5 in terms of their fundamental frequency clocking, using appropriate filters dampen. This is shown in FIG. 3, where a low pass is provided on the side of the generator 1 via a choke coil 14 in line and a capacitance 15 to earth. In this way, undesired frequency components, which can affect the generator 1 and, for example, lead to torque oscillations, can be eliminated. On the other hand, undesired frequency components in the direction of the network 8 can be reduced or even eliminated via a corresponding low-pass filter arranged on the side of the network 8, composed of a choke coil 74 in line and a capacitance 75 to earth. This makes island operation or standalone operation possible in analogy to so-called uninterruptible power supplies (UPS).
BEZUGSZEICHENLISTE Generator Erregerspule von 1 Mittel, steuerbare Speisung der Erregerspule Gleichrichter, Pulsgleichrichter, Gleichrichterstufe des Frequenzumwand- lers, Wechselrichter, Pulswechselrichter, Wechselrichterstufe des Frequenz- umwandlers, Steuerung, Regelung Transformator Netz Frequenzumwandler, statischer Frequenzkonverter Gleichstromstufe Spannungsmessung erste Statorwicklungsgruppe des Generators zweite Statorwicklungsgruppe des Generators Drosselspule Kondensator, Kapazität Statorwicklung des Generators Strommessung , 42 Gleichrichterstufe zur ersten respektive zweiten Statorwicklungsgruppe des Generators, 52 Wechselrichterstufe zur ersten respektive zweiten Statorwicklungsgruppe des Generators Transformatorspule zum Netz Transformatorspule zur ersten Statorwicklungsgruppe des Generators, Sternschaltung Transformatorspule zur zweiten Statorwicklungsgruppe des Generators, Dreieckschaltung Drosselspule Kondensator, Kapazität Leistungsquelle, z. B. Turbine
REFERENCE SIGNAL LIST generator exciter coil of 1 medium, controllable supply of the exciter coil rectifier, pulse rectifier, rectifier stage of the frequency converter, inverter, pulse inverter, inverter stage of the frequency converter, control, regulation transformer network frequency converter, static frequency converter direct current stage voltage measurement first stator winding group of the generator second generator group Choke coil capacitor, capacitance stator winding of the generator current measurement, 42 rectifier stage to the first or second stator winding group of the generator, 52 inverter stage to the first or second stator winding group of the generator transformer coil to the network transformer coil to the first stator winding group of the generator, star circuit transformer coil to the second stator winding group of the generator, delta circuit, delta circuit Capacity power source, e.g. B. turbine
Claims
1. Verfahren zur Anpassung des von einem Generator (1 ) erzeugten Wechselstroms respektive der von einem Generator (1) erzeugten Wechselspannung an ein Netz (8), wobei es sich beim Generator (1) um einen Generator (1) mit wenigstens einer Erregerspule (2) handelt, dadurch gekennzeichnet, dass zur Anpassung zwischen Generator (1) und Netz (8) ein statischer Frequenzumwandler (9) verwendet wird, und dass zur Steuerung der in das Netz (8) eingespeisten Leistung Mittel (3) angeordnet sind, mit welchen einerseits die Stärke des von der wenigstens einen Erregerspule (2) erzeug- ten Erregerfeldes und andererseits die Phasenlage zwischen Frequenzumwandlerspannung und Generator- respektive Netzspannung geregelt, wird.1. Method for adapting the alternating current generated by a generator (1) or the alternating voltage generated by a generator (1) to a network (8), the generator (1) being a generator (1) with at least one excitation coil ( 2), characterized in that a static frequency converter (9) is used to adapt between the generator (1) and the network (8), and that means (3) are arranged to control the power fed into the network (8) which regulates the strength of the excitation field generated by the at least one excitation coil (2) and the phase position between the frequency converter voltage and the generator or mains voltage.
2. Verfahren nach Anspruch 1 , dadurch gekennzeichnet, dass die Anpassung über einen statischen Frequenzumwandler (9) als Gleichrichter (4, 41 , 42) / Wechselrichter (5, 51 , 52) mit einer dazwischen geschalteten Gleichstromstufe (10) erfolgt.2. The method according to claim 1, characterized in that the adaptation takes place via a static frequency converter (9) as a rectifier (4, 41, 42) / inverter (5, 51, 52) with an intermediate DC stage (10).
3. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekenn- zeichnet, dass die Anpassung über einen statischen Frequenzumwandler (9) mit einem gesteuerten Gleichrichter (4, 41 , 42) in Grundfrequenztaktung und/oder mit einem gesteuerten Wechselrichter (5, 51 , 52) in Grundfrequenztaktung erfolgt.3. The method according to any one of the preceding claims, characterized in that the adaptation via a static frequency converter (9) with a controlled rectifier (4, 41, 42) in fundamental frequency clocking and / or with a controlled inverter (5, 51, 52 ) is done in basic frequency clocking.
4. Verfahren nach Anspruch 3, dadurch gekennzeichnet, dass es sich beim gesteuerten Gleichrichter (4, 41 , 42) um einen Drei-Stufen-Gleichrichter und beim gesteuerten Wechselrichter (5, 51 , 52) um einen Drei-Stufen- Wechselrichter handelt, welche beide in Grundfrequenztaktung betrieben werden. 4. The method according to claim 3, characterized in that the controlled rectifier (4, 41, 42) is a three-stage rectifier and the controlled inverter (5, 51, 52) is a three-stage inverter. which are both operated in basic frequency clocking.
5. Verfahren nach einem der Ansprüche 2 bis 4, dadurch gekennzeichnet, dass der statischen Frequenzumwandler (9) geschaltete Thyristoren wie beispielsweise GTO's, IGBT's, MOSFET's, oder IGCT's, umfasst.5. The method according to any one of claims 2 to 4, characterized in that the static frequency converter (9) comprises switched thyristors such as GTO's, IGBT's, MOSFET's, or IGCT's.
6. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass eine zentrale Steuerung (6) angeordnet ist, welche über die Messung von Spannung (11) und/oder Stromstärke (17) vor und/oder hinter dem statischen Frequenzumwandler (9) eine Anpassung der ins Netz (8) eingespeisten Amplitude der Wechselspannung durch eine entsprechende Ansteuerung der Mittel (3) zur Steuerung der Stärke des von der Erregerspule (2) erzeugten Erregerfeldes vornimmt.6. The method according to any one of the preceding claims, characterized in that a central control (6) is arranged, which one via the measurement of voltage (11) and / or current (17) before and / or after the static frequency converter (9) Adaptation of the amplitude of the alternating voltage fed into the network (8) by appropriate control of the means (3) for controlling the strength of the excitation field generated by the excitation coil (2).
7. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass die Mittel (3) eine Anpassung der vom Generator ins Netz eingespeisten Leistung durch eine entsprechende Ansteuerung der Phasenlage zwischen Generatorspannung und der vom gesteuerten Gleichrichter erzeugten Wechselspannung, respektive der Phasenlage zwischen der Netzspannung und der vom gesteuerten Wechselrichter erzeugten Wechselspannung vornehmen.7. The method according to any one of the preceding claims, characterized in that the means (3) an adaptation of the power fed into the grid by the generator by a corresponding control of the phase position between the generator voltage and the AC voltage generated by the controlled rectifier, or the phase position between the mains voltage and the AC voltage generated by the controlled inverter.
8. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass vor und/oder hinter dem statischen Frequenzumwandler (9) von der Grundfrequenz abweichende Frequenzkomponenten durch zweite Mittel (14, 15, 74, 75) abgedämpft respektive eliminiert werden.8. The method according to any one of the preceding claims, characterized in that in front of and / or behind the static frequency converter (9) frequency components deviating from the fundamental frequency are damped or eliminated by second means (14, 15, 74, 75).
9. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass es sich beim Generator (1) um einen Generator (1) mit zwei oder mehr Statorwicklungsgruppen (12, 13, 16) handelt, und dass die jeweils von einer Statorwicklungsgruppe (12, 13, 16) erzeugte Wechselspan- nung über jeweils je einen statischen Frequenzumwandler (41 , 51 ; 42, 52) umgewandelt wird, wobei insbesondere bevorzugt bei einem Generator (1) mit zwei Statorwicklungsgruppen (12, 13) die Ankopplung an das Netz (8) hinter dem statischen Frequenzumwandler (9) über einen Transformator (7) erfolgt, bei welchem die eine Gruppe von drei Phasen in einer Sternschaltung (72) geführt sind und die andere Gruppe von drei Phasen in einer Dreieckschaltung (73).9. The method according to any one of the preceding claims, characterized in that the generator (1) is a generator (1) with two or more stator winding groups (12, 13, 16), and that each has a stator winding group (12, 13, 16) generated AC voltage voltage is converted via a respective static frequency converter (41, 51; 42, 52), the coupling to the network (8) behind the static frequency converter (9.) being particularly preferred in the case of a generator (1) with two stator winding groups (12, 13) ) via a transformer (7), in which the one group of three phases are guided in a star connection (72) and the other group of three phases in a delta connection (73).
10. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekenn- zeichnet, dass es sich bei den Mitteln (3) um eine Thyristorstromrichterbrücke bei Bezug von Leistung aus einem insbesondere dreiphasigen Netz, respektive um einen Chopper bei Bezug von Leistung in Form von Gleichstrom handelt.10. The method according to any one of the preceding claims, characterized in that the means (3) is a thyristor power converter bridge with reference to power from a three-phase network in particular, or a chopper with reference to power in the form of direct current.
11. Vorrichtung zur Durchführung eines Verfahrens nach einem der Ansprüche 1 bis 10, dadurch gekennzeichnet, dass ein Generator (1) mit wenigstens einer über Mittel (3) zur Anpassung der Amplitude der Wechselspannung an die Erfordernisse des Netzes (8) regelbaren Erregerspule (2), ein statischer Frequenzumwandler (9) umfassend wenigstens einen gesteuerten Gleichrichter (4,41 ,42) in Grundfrequenztaktung und wenigstens einen gesteuerten Wechselrichter (5,51 ,52) in Grundfrequenztaktung sowie wenigstens eine Steuerung (6) zur Steuerung dieser Elemente vorhanden ist.11. Device for performing a method according to one of claims 1 to 10, characterized in that a generator (1) with at least one via means (3) for adapting the amplitude of the AC voltage to the requirements of the network (8) controllable excitation coil (2nd ), a static frequency converter (9) comprising at least one controlled rectifier (4,41, 42) in basic frequency switching and at least one controlled inverter (5,51, 52) in basic frequency switching as well as at least one controller (6) for controlling these elements.
12. Verwendung einer Vorrichtung nach Anspruch 11 zum Hochfahren der Tur- bine (P)-Generator (1 )-Gruppe auf die zur Energieerzeugung nötige Minimaldrehzahl, wobei Energie von Netz (8) über den Frequenzumwandler (9) zum Generator (1) geführt wird und im Frequenzumwandler (9) Spannung und Frequenz von null auf Nennwert variiert werden. 12. Use of a device according to claim 11 for starting up the turbine (P) generator (1) group to the minimum speed required for energy generation, energy from the network (8) being conducted via the frequency converter (9) to the generator (1) is and in the frequency converter (9) voltage and frequency can be varied from zero to nominal value.
Applications Claiming Priority (2)
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DE10330473A DE10330473A1 (en) | 2003-07-05 | 2003-07-05 | Frequency converter for high-speed generators |
PCT/EP2004/051353 WO2005004317A2 (en) | 2003-07-05 | 2004-07-05 | Frequency converter for high-speed generators |
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EP1642383A2 true EP1642383A2 (en) | 2006-04-05 |
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EP04766126A Withdrawn EP1642383A2 (en) | 2003-07-05 | 2004-07-05 | Frequency converter for high-speed generators |
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US (1) | US7180270B2 (en) |
EP (1) | EP1642383A2 (en) |
JP (1) | JP2009514490A (en) |
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2003
- 2003-07-05 DE DE10330473A patent/DE10330473A1/en not_active Withdrawn
-
2004
- 2004-07-05 JP JP2006518215A patent/JP2009514490A/en active Pending
- 2004-07-05 WO PCT/EP2004/051353 patent/WO2005004317A2/en active Application Filing
- 2004-07-05 EP EP04766126A patent/EP1642383A2/en not_active Withdrawn
-
2006
- 2006-01-04 US US11/324,890 patent/US7180270B2/en not_active Expired - Fee Related
Non-Patent Citations (1)
Title |
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See references of WO2005004317A3 * |
Also Published As
Publication number | Publication date |
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US20060214645A1 (en) | 2006-09-28 |
WO2005004317A2 (en) | 2005-01-13 |
JP2009514490A (en) | 2009-04-02 |
WO2005004317A3 (en) | 2005-03-03 |
US7180270B2 (en) | 2007-02-20 |
DE10330473A1 (en) | 2005-01-27 |
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