JP2005073345A - Electric train control unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric train control unit which reduces imbalance in compensation for each main converting device. <P>SOLUTION: The electric train control unit comprises: a converter; a VVVF inverter connected to the DC side of the converter; a plurality of main converting devices composed of a current detecting means for detecting a current on the AC side of the converter; and a voltage control means which controls a converter output voltage so that a current instruction value so calculated that the filter capacitor voltage comes to be a prescribed value agrees with a current value detected by the current detecting means; a voltage detecting means for detecting the voltage of an overhead wire; and an invalid current instruction calculating means for calculating the instruction of invalid current based on the overhead wire voltage detected by the voltage detecting means. The current instruction is corrected with the only invalid current instruction calculated by the invalid current instruction calculating means. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

The present invention relates to an electric vehicle control device.

  In an AC train equipped with a main converter such as a converter and inverter for receiving single-phase AC from the overhead line and driving the main motor, if the overhead line voltage rises, the output voltage of the converter is saturated and the overhead line current is distorted. May increase, or the operation may be stopped due to a protective operation caused by overhead line overvoltage. Conversely, when the overhead line voltage decreases, the converter increases the effective current because it supplies the same power to the inverter. However, if this exceeds the current capacity of the converter, the current is limited and the main motor Torque is reduced. For this reason, there is a possibility that the acceleration / deceleration will be lower than a predetermined value and disturb the operation schedule.

  In order to cope with this problem, Patent Document 1 discloses that reactive power and power factor are adjusted in a direction in which fluctuations in overhead line voltage are suppressed.

  However, when a plurality of main converters are provided during the formation of an AC train, if each main converter controls the reactive current and power factor according to the detected overhead line voltage and the power of the main motor, The correction amount of the reactive current may be unbalanced due to a difference in detection system or a difference in control method. In recent AC trains, a PWM converter is used as the main converter, but a PWM ripple is superimposed on the overhead line voltage for this PWM control. Therefore, it is difficult to accurately extract the fundamental voltage, and the error as the voltage detection system is large. Moreover, the overhead line voltage is a high voltage of 20 kV to 25 kV, and the cost, size, and weight of the detection device increase due to difficulty in insulation. On the other hand, the voltage reduced through the main transformer generally reflects the overhead line voltage and is often used as a signal equivalent to the overhead line voltage. However, the windings of this main transformer may be shared with the control power supplies in the train and the windings for load power supplies such as fluorescent lamps, air conditioners, fans, blowers, etc. The voltage varies. Therefore, the overhead line voltage detected for each main converter does not necessarily show the same value.

The above reactive current imbalance means that a large reactive current flows in a main converter, while a small reactive current flows in a main converter, or a reverse reactive current flows. Conceivable. As described above, when a large reactive current flows in a specific main converter, the current is limited as described above, and the torque is limited.

In addition, the high-frequency component of the current that flows in the overhead line of the AC train (strictly, the current that flows in the rail is called the return current) is used as a signal to the signal equipment, and the return current harmonic that flows from the main converter Has a prescribed value. In the PWM control system converter described above, many harmonics of the carrier frequency component are generated, which affects the above-mentioned regulation. Therefore, in order to cancel the same component, an effect is obtained by performing a phase difference operation that intentionally shifts the carrier phase difference of the converter of the main converter in the knitting. In this phase difference operation, it is ideal that all the converters pass the same current, and if the main converter has a current imbalance, the harmonic canceling effect is reduced. That is, due to the imbalance of the reactive current, a strict phase difference operation cannot be performed, and the return harmonics increase, which may affect various signal devices.
Japanese Patent Laid-Open No. 08-084403 JP 2003-199354 A

Accordingly, an object of the present invention is to provide an electric vehicle control device that can reduce the unbalance of compensation for each main converter.

The object is to detect a converter connected to the overhead line via a main transformer, a VVVF inverter connected to the DC side of the converter via a filter capacitor and driving the main motor, and a current on the AC side of the converter. Current detection means; and voltage control means for controlling the converter output voltage so that the current command value calculated so that the filter capacitor voltage becomes a predetermined value matches the current value detected by the current detection means; A plurality of main converters, voltage detecting means for detecting the voltage of the overhead wire, reactive current command calculating means for calculating a reactive current command based on the overhead wire voltage detected by the voltage detecting means, and the reactive current The current command is corrected by adding the only reactive current command calculated by the command calculation means to the current command of each main converter. It can be achieved by providing a stage.

The object is to detect a converter connected to the overhead line via a main transformer, a VVVF inverter connected to the DC side of the converter via a filter capacitor and driving the main motor, and a current on the AC side of the converter. Current detection means; and voltage control means for controlling the converter output voltage so that the current command value calculated so that the filter capacitor voltage becomes a predetermined value matches the current value detected by the current detection means; A plurality of main converters, voltage detecting means for detecting the voltage of the overhead wire, and each main converter having a reactive current command calculating means for calculating a reactive current command based on the only detected overhead voltage And means for correcting the current command by adding the calculated reactive current command to the current command of each main converter. It can be.

The object is to provide a first converter connected to the overhead line via a main transformer, a VVVF inverter connected to the DC side of the first converter via a filter capacitor and driving the main motor, and the first converter The current detection means for detecting the current on the AC side of the converter, the current command value calculated so that the filter capacitor voltage becomes a predetermined value, and the current value detected by the current detection means match. A plurality of main converters comprising voltage control means for controlling a first converter output voltage; a second converter connected to the overhead line via a main transformer; and an energy connected to the DC side of the second converter Energy storage means for storing the current, current detection means for detecting the current on the AC side of the second converter, and the current value matches a predetermined current command value. An energy storage conversion device comprising a current control means for controlling the output voltage of the second converter, a voltage detection means for detecting the overhead wire voltage, and a reactive current command based on the overhead wire voltage detected by the voltage detection means. Can be achieved by including a reactive current command calculating means for calculating the current and a means for using the reactive current command as a current command for the energy storage conversion device.

The object is to detect a converter connected to the overhead line via a main transformer, a VVVF inverter connected to the DC side of the converter via a filter capacitor and driving the main motor, and a current on the AC side of the converter. Current detection means; and voltage control means for controlling the converter output voltage so that the current command value calculated so that the filter capacitor voltage becomes a predetermined value matches the current value detected by the current detection means; A voltage detection means for detecting the voltage of the overhead wire, a reactive current command calculation means for computing a reactive current command based on the detected overhead wire voltage, and a means for correcting the current command value based on the reactive current command value The reactive current command calculation means has a finite gain in the low frequency region of the input / output gain. It can be achieved.

The object is to detect a converter connected to the overhead line via a main transformer, a VVVF inverter connected to the DC side of the converter via a filter capacitor and driving the main motor, and a current on the AC side of the converter. Current detection means; and voltage control means for controlling the converter output voltage so that the current command value calculated so that the filter capacitor voltage becomes a predetermined value matches the current value detected by the current detection means; A voltage detection means for detecting the voltage of the overhead wire, a reactive current command calculation means for computing a reactive current command based on the detected overhead wire voltage, and a means for correcting the current command value based on the reactive current command value In the electric vehicle control device equipped with the main conversion device consisting of the above, the offset of the voltage detector for detecting the overhead wire voltage is adjusted to be zero. It can be achieved by providing a means for.

The object is to install a plurality of converters that are mounted on an electric vehicle and convert AC power to DC power, a plurality of converter control units that control the plurality of converters, and a reactive current command from the active current of the converter. The reactive current command calculating means can be achieved by outputting the same reactive current command to a plurality of converter control units.

The object is to mount a plurality of converters that are mounted on an electric vehicle and convert AC power into DC power, a plurality of converter control units that control the plurality of converters, voltage detection means that detects a voltage of an overhead wire, and this voltage Reactive current command calculating means for calculating a reactive current command based on the overhead wire voltage detected by the detecting means, and the reactive current command calculating means outputs the same reactive current command to a plurality of converter control units. Can be achieved.

  According to the present invention, it is possible to provide an electric vehicle control device that can reduce the unbalance of compensation for each main converter.

(First embodiment)
An electric vehicle control apparatus according to a first embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration of an electric vehicle control apparatus according to a first embodiment based on the present invention. FIG. 2 is a configuration diagram of a converter control unit in the electric vehicle control apparatus of the first embodiment based on the present invention.

  In the electric vehicle control apparatus according to the first embodiment of the present invention, a single-phase alternating current is supplied to the overhead wire 1 and the rail 3 from a substation (not shown). A current is collected by the pantograph 2 from the overhead line 1, and a converter 11 is connected through a main transformer 5 having three windings. Connected to the DC side of the converter 11 is a filter capacitor 12 for smoothing and a VVVF inverter 14 for driving the main motor 15. The converter control unit 16 is provided in the AC side current detected by the current detector 9 and the third winding 8 of the main transformer so that the filter capacitor voltage Vdc1 detected by the voltage detector 13 becomes a predetermined value. The converter 11 is controlled based on the output of the voltage detector and the reactive current amplitude command IQA * calculated by the overhead wire voltage control unit 17.

  FIG. 2 shows details of converter control in the electric vehicle control apparatus of the first embodiment configured as described above. The input to the converter control unit 16 is an output current Is that is an AC side current of the converter, a filter capacitor voltage Vdc, a tertiary voltage Vs that is a voltage of the third winding of the main transformer 5, and a reactive current amplitude command IQA. * The tertiary voltage is used as an alternative to the overhead line voltage, and may be a voltage detected from the primary voltage that is the first winding voltage of the main transformer 5.

In the converter control unit 16 configured as described above, the zero cross detection unit 27 detects the zero cross based on the tertiary voltage Vs corresponding to the overhead wire voltage. The phase synchronization control unit 28 calculates the overhead wire voltage phase θs for control from the zero cross point of the overhead wire voltage. Here, the zero point of the phase θs is defined as the zero cross point of the overhead wire voltage. The voltage controller 19 receives a deviation between the filter capacitor voltage Vdc output from the subtractor 18 and the DC voltage command Vdc * that is a target value thereof, and the above-described overhead voltage phase θs so that the deviation becomes zero. Based on the above, the effective current command value IP * of the converter is calculated. The reactive current command calculation unit 25 receives the overhead voltage phase θs and a reactive current amplitude command IQA * which is separately described by an external input, and calculates and outputs a reactive current command value IQ *. In the adder 20, the active current command IP * and the reactive current command IQ * are added to calculate the converter output current command Is *. These relationships are as shown in Equation 1. In this equation, the voltage controller 19 uses a PI controller. The first term on the right side is the active current command, and the second term is the reactive current command.

The current control unit 22 calculates the output voltage correction amount Vccmp as shown in Equation 2 so that the detected output current matches the output current command value Is * calculated in Equation 1.

Further, the feedforward term VsFF of the overhead wire voltage is calculated by the power supply voltage FF calculator 26 as shown in Equation 3. Here, Vs * is a conversion value of the rated voltage of the overhead wire to the converter AC side.

  In the adder 23, the output voltage command value Vc * of the converter can be calculated by adding the overhead wire voltage feedforward term VsFF and the output voltage correction amount Vccmp. The PWM control 24 generates a gate to the converter 11 by triangular wave comparison PWM control or the like so that an output voltage that matches the output voltage command value Vc * of the converter is obtained.

  In FIG. 1, two main conversion devices are described. However, there are cases where a plurality of main conversion devices are provided during the formation of an AC train, and the number is not particularly limited to two. Moreover, although the pantograph is common, it may be a separate configuration.

The effective value calculator 39 calculates and outputs the effective value Vs1Rms of the voltage Vs1 of the third winding of the main transformer 5 detected by the voltage detector 10. The overhead wire voltage control unit 17 calculates the reactive current amplitude command IQA *, for example, as shown in Equation 4, in accordance with the tertiary voltage effective value Vs1Rms. Here, Vs3Rms * is a tertiary voltage conversion value of the overhead wire rated voltage effective value.

The reactive current amplitude command IQA *, which is the output of the overhead wire voltage control unit 17, is commonly input to the converter control unit 16 of the two main converters.

  In the electric vehicle control apparatus configured as described above, each main converter controls each effective current of the converter output current so that each filter capacitor voltage Vdc matches the target voltage Vdc *. . On the other hand, the reactive voltage command is calculated by the overhead wire voltage control unit 17 so as to suppress the fluctuation of the overhead wire voltage, and a common command value is given to each main converter.

  Therefore, in order to control only one overhead line voltage, there exists only one overhead line voltage control part, and the only reactive current command is calculated. Since each main converter acts so that a current corresponding to the only reactive current command flows, it is possible to avoid a state where the reactive current is unbalanced between the main converters as much as possible.

  Thereby, it is possible to avoid a decrease in torque of the main motor and an increase in the return current harmonic due to the converter current limitation. Further, in the case of a configuration having an overhead wire voltage control unit in each main converter as in the conventional case, if the gain Kp of Equation 4 is high, reactive current control may interfere between the main converters, leading to instability. There is also. In the present embodiment, since the overhead wire voltage control unit is unique in the formation, a stable overhead wire voltage can be maintained without causing control interference.

  In this embodiment, the overhead line voltage used in the main converter and the overhead line voltage used for stabilization control of the overhead line voltage are detected from the same point, but different detection points are detected by different detectors. There is no problem even if it is detected.

  The electric vehicle control device configured as described above can reduce compensation imbalance for each main converter.

(Second Embodiment)
An electric vehicle control apparatus according to a second embodiment of the present invention will be described in detail with reference to the drawings. FIG. 3 is a block diagram showing a schematic configuration of the electric vehicle control device of the second embodiment based on the present invention. The same structural elements as those shown in FIGS. 1 and 2 are denoted by the same reference numerals and description thereof is omitted. In addition, the electric vehicle control apparatus of 2nd Embodiment based on this invention differs in the structure position of an overhead wire voltage control part from the electric vehicle control apparatus of 1st Embodiment.

  In the electric vehicle control apparatus according to the second embodiment of the present invention, the overhead wire voltage control unit 17 is provided in each converter control unit 16. That is, it is considered as one element constituting the converter control unit 16 (not particularly shown).

The electric vehicle control device configured as described above detects the tertiary voltage Vs1 of the third winding 8 of one main transformer 6, and the effective value calculator 39 calculates the overhead wire voltage effective value. This only overhead wire voltage effective value is input to each overhead wire voltage control unit 17. Here, the control method of the overhead wire voltage control unit 17 is set to have exactly the same characteristics including steady characteristics and transient characteristics.

  In the above configuration, the detected overhead voltage effective value is unique, and the characteristics of the overhead line voltage control unit 17 provided in each main converter are the same. Therefore, the reactive current command of each main converter is the same. . Therefore, the same effect as the electric vehicle control device of the first embodiment can be obtained.

  The electric vehicle control device configured as described above is characterized in that the overhead wire voltage control unit 17 is distributed in comparison with the electric vehicle control device of the first embodiment. That is, in the electric vehicle control device of the first embodiment, the overhead wire voltage control unit 17 controls the main conversion device for driving the main motor, or vehicle information control that controls information as a knitting as its higher order command. Even if configured as a part of the apparatus, it is the only control unit in the vehicle. Therefore, when the operation of the equipment is stopped due to a failure or the like, the function of stabilizing the overhead line voltage as a formation is lost. On the other hand, in the electric vehicle control device according to the second embodiment, the overhead wire voltage control unit 17 is distributed in each main conversion device, thereby reducing the dependency on specific equipment and improving the reliability of the system. Can be made.

  The electric vehicle control device configured as described above can reduce compensation imbalance for each main converter.

(Third embodiment)
An electric vehicle control apparatus according to a third embodiment of the present invention will be described in detail with reference to the drawings. FIG. 4 is a block diagram showing a schematic configuration of the third embodiment based on the present invention. The same structural elements as those shown in FIGS. 1 to 3 are denoted by the same reference numerals and description thereof is omitted. The electric vehicle control device of the third embodiment based on the present invention is different from the electric vehicle control device of the second embodiment in input to the overhead line voltage control unit.

In the electric vehicle control apparatus according to the second embodiment of the present invention, the input voltage to the overhead line voltage control unit 17 provided in each main converter is based on the overhead line voltage detected by a single voltage detector. It was. On the other hand, in the electric vehicle control apparatus according to the third embodiment of the present invention, the overhead line voltage effective value is calculated by the effective value calculation unit 39 provided in each main converter for the overhead line voltage detected by the two voltage detectors 10. The two overhead wire effective values are input to the average voltage calculation unit 29. The average voltage calculation unit 29 obtains an average value based on the two overhead wire voltage effective values and outputs the average value to each overhead wire voltage control unit 17.

  The electric vehicle control device configured as described above obtains an average voltage from a plurality of overhead wire voltage detection values, and each overhead wire voltage control unit 17 calculates a reactive current command value based on the only voltage value. Therefore, the same effect as the electric vehicle control apparatus of the second embodiment is obtained. Furthermore, in the electric vehicle control apparatus of the second embodiment, since the output of a specific voltage detector is used, when the operation is stopped due to a failure or the like, the function of stabilizing the overhead line voltage as a knitting is lost. On the other hand, in the electric vehicle control apparatus of the present embodiment, since it is based on information obtained from a plurality of voltage detectors 10, even if a certain voltage detector 10 is abnormal and the error is large, the influence on the average voltage is not affected. small. Moreover, even if the voltage detector 10 in which abnormality is seen is disconnected, there is no influence on the overhead line voltage control. That is, the reliability of the system can be improved.

  In the electric vehicle control device configured as described above, the average voltage calculation unit 29 receives the overhead wire voltage effective value calculated by the effective value calculation unit 39 provided in each main converter. If this average voltage calculation unit 29 is placed outside the main converter, it is necessary to transmit information to and from the main converter using appropriate transmission means. However, while the overhead line voltage is AC of 50 Hz or 60 Hz, the transmission processing interval is on the order of several ms. Moreover, it is not necessarily synchronized with the overhead line voltage frequency. Therefore, it is highly possible to superimpose low frequency errors including direct current as overhead voltage information to be transmitted by sampling data. However, according to the electric vehicle control device of the present embodiment, the effective value calculation is performed in the main converter, and this is transmitted, so that the cause of the superposition of the low frequency components can be eliminated. Thereby, stable compensation can be made possible without causing a low-frequency disturbance in the reactive current compensation amount.

  The electric vehicle control device configured as described above can reduce compensation imbalance for each main converter.

(Fourth embodiment)
An electric vehicle control apparatus according to a fourth embodiment of the present invention will be described in detail with reference to the drawings. FIG. 5 is a block diagram showing a schematic configuration of the fourth embodiment according to the present invention. Components identical in structure to those described in FIGS. 1 to 4 are designated by the same reference numerals and description thereof is omitted.

The electric vehicle control device of the fourth embodiment based on the present invention is different from the electric vehicle control device of the first embodiment in that there is an energy storage conversion unit 34 and the output of the overhead wire voltage control unit 17 is the main conversion. The difference is that it does not act on the converter control unit of the apparatus but acts on the second converter control unit 37 of the energy storage conversion unit 34.

  In the electric vehicle control apparatus of the fourth embodiment based on the present invention, the main converter has the same configuration and operation as the main converter in the electric vehicle control apparatus of the first embodiment shown in FIG. . However, the reactive current amplitude command IQA * that is the output of the overhead wire voltage control unit 17 does not act on the converter control unit 16 shown in FIG.

  The electric vehicle control device of the fourth embodiment based on the present invention is characterized in that the energy storage conversion unit 34 is provided. The energy storage conversion unit 34 includes a second converter 36, an energy storage unit 35, and a second converter control unit 37. The second converter 36 has the same configuration as the converter 11 and is a full-bridge converter capable of single-phase, four-quadrant operation. An energy storage unit 35 capable of storing energy is connected to the DC side of the second converter 36. The energy storage unit 35 may be an electric double layer capacitor, a battery, or a normal capacitor.

  FIG. 6 is a detailed block diagram of the second converter control unit 37 that controls the gate Gate 3 of the second converter 36. The configuration is the same as that of the converter control unit 16 shown in FIG. However, the current command Is3 * is the reactive current command IQ3 *, and the active current command is not added.

  In the electric vehicle control device configured as described above, the control unit 37 of the second converter is equivalent to the converter control unit 16, and therefore can pass the current Is3 that matches the current command Is3 *. Here, since the reactive current command calculated by the overhead wire voltage control unit 17 is the command value of the second converter control unit 37, the energy storage conversion unit 34 can suppress fluctuations in the overhead wire voltage.

  Further, according to the present embodiment, neither of the two sets of main converters performs reactive current control, and only one separately provided energy storage converter performs its function. Therefore, as in the first aspect, the situation of reactive current imbalance in the main converter does not occur. Furthermore, even if the reactive current of the main conversion device is balanced between the devices, the output current of the converter is increased by flowing the reactive current itself. As described above, this is a factor that causes a reduction in torque of the main motor due to current limitation of the converter. In this embodiment, since a reactive current is passed through the attached energy storage conversion device, the possibility of causing torque reduction or the like can be eliminated.

  In addition, as described above, there is already a technique of using an electric double layer capacitor or a battery for the energy storage unit of the energy storage conversion device so that active power can be stored (Patent Document 2). It is also possible to share the function of this embodiment here.

Further, if the use is limited to the reactive current only as in the present embodiment, a capacitor having a normal capacity is sufficient as the energy storage unit (because there is no transfer of average active power), and the energy storage conversion unit The size, weight, and cost can be reduced.

The electric vehicle control device configured as described above can reduce compensation imbalance for each main converter.

(Fifth embodiment)
An electric vehicle control apparatus according to a fifth embodiment of the present invention will be described in detail with reference to the drawings. FIG. 7 relates to the characteristics of the overhead wire voltage controller 17 as a fifth embodiment relating to claim 5 of the present invention. Note that the same structural elements as those described in FIGS. 1 to 6 are denoted by the same reference numerals and description thereof is omitted.

The configuration of the electric vehicle control apparatus according to the fifth embodiment of the present invention is the same as that of the conventional example of FIG. 10, but limits the input / output characteristics of the overhead line voltage control unit 17.

In FIG. 10, an effective value Vs1Rms of the tertiary voltage Vs1 corresponding to the overhead line voltage is input to the overhead line voltage control unit 17. The reactive current amplitude command IQA1 * is output. The output is calculated by Equation 5 based on the input. Here, Vs3 * Rms is a tertiary voltage converted value of the effective value of the overhead wire rated voltage.

  Formula 5 is a so-called PI controller combined with a high-pass filter (s / (s + g)) to reduce the gain of the low frequency component. FIG. 7 shows the gain characteristic among the transfer characteristics. Since the high-pass filter is combined, the low-frequency gain is reduced, and in particular, the DC component is finite.

  The reason why the reactive current is unbalanced by the conventional configuration is mainly because the overhead wire voltage control unit 17 amplifies the low frequency component of the overhead wire voltage effective value, in particular, the DC error. The PI control (strictly, I control) in which the input / output characteristics of the overhead wire voltage control unit 17 have an infinite gain with a direct current component increases the effective direct current component error with time. The reactive current command diverges in the positive direction of the conversion device and in the negative direction of a certain main conversion device. As in this embodiment, when the low frequency component is finite, a phenomenon of diverging can be avoided.

  The electric vehicle control device configured as described above can reduce compensation imbalance for each main converter.

(Sixth embodiment)
An electric vehicle control apparatus according to a sixth embodiment of the present invention will be described in detail with reference to the drawings. FIG. 8 shows a sixth embodiment relating to claim 6 of the present invention, in which an offset adjusting unit 30 is present at the input to the effective value calculating unit 39. FIG. 9 shows a configuration example of the offset adjustment unit 30. The same structural elements as those shown in FIGS. 1 to 7 are designated by the same reference numerals and the description thereof is omitted.

In the electric vehicle control apparatus according to the fifth embodiment of the present invention, the tertiary voltage Vs1 of the main transformer is input to the switch 32. The switch 32 receives an operation command Gst to the converter 11 (the converter 11 operates when Gst = 1, and stops operation when Gst = 0), and when Gst = 1, 3 When the next voltage Vs1 is output and Gst = 0, the compensation voltage Vs1offset that is the output of the filter 31 is output. The filter 31 is a low-pass filter that passes only low frequency components. The subtractor 33 subtracts the compensation voltage Vs1offset from the tertiary voltage Vs1 and outputs the result from the offset adjustment unit 30.

  In the electric vehicle control apparatus configured as described above, when the converter 11 is stopped (Gst = 0), the tertiary voltage Vs1 corresponding to the overhead line voltage is input to the filter 31, and its low frequency component, that is, the direct current Extract minutes. When the converter 11 is in the operating state (Gst = 1), the input to the filter 31 becomes the output of the filter 31 by the switch 32. That is, the value of the filter 31 is retained. The DC component Vs1offset when the operation of the converter 11 is stopped is acquired, and while the converter is operating, this offset is compensated by the subtractor 33 from the detected value as a compensation voltage. That is, it is possible to remove the DC component superimposed in the voltage detection system including the voltage detector 10. As described above, the reactive current imbalance is caused by the low frequency component of the detected DC voltage. Therefore, the reactive current imbalance can be reduced by removing the DC offset from the detection voltage.

  The electric vehicle control device configured as described above can reduce compensation imbalance for each main converter.

1 is a block diagram showing a first embodiment of the present invention. Configuration example of converter controller Block diagram showing a second embodiment of the present invention The block diagram which shows the 3rd Example of this invention The block diagram which shows the 4th Example of this invention Configuration example of second converter control unit The figure which shows the input / output gain of the overhead wire voltage control system which is the 5th Example of this invention Block diagram showing a sixth embodiment of the present invention Block diagram of voltage offset adjuster

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Overhead wire 2 ... Pantograph 3 ... Rail 4 ... Wheel 5 ... Main transformer 6 ... Primary winding 7 ... Secondary winding 8 ... Tertiary winding 9 ... Current detector 10 ... Voltage detector 11 ... Single phase converter DESCRIPTION OF SYMBOLS 12 ... Filter capacitor 13 ... Voltage detector 14 ... VVVF inverter 15 ... Main motor 16 ... Converter control part 17 ... Overhead voltage control part 18 ... Subtractor 19 ... DC voltage control part 20 ... Adder 21 ... Subtractor 22 ... Current control Unit 23 ... Adder 24 ... PWM control unit 25 ... Reactive current command calculation unit 26 ... Power supply voltage FF calculation unit 27 ... Zero cross detection unit 28 ... Phase synchronization control unit 29 ... Average voltage calculation unit 30 ... Offset adjustment unit 31 ... Filter 32 ... Switcher 33 ... Subtractor 34 ... Energy storage conversion unit 35 ... Energy storage unit 36 ... Second converter 37 ... Second converter control unit 38 ... Current detector 39 ... RMS calculator

Claims (9)

A converter connected to the overhead line via the main transformer;
A VVVF inverter connected to the DC side of the converter via a filter capacitor and driving the main motor;
Current detecting means for detecting the current on the AC side of the converter;
A plurality of main control units comprising a voltage control means for controlling the converter output voltage so that the current command value calculated so that the filter capacitor voltage becomes a predetermined value matches the current value detected by the current detection means. A conversion device;
Voltage detecting means for detecting the voltage of the overhead wire;
Reactive current command calculation means for calculating a reactive current command based on the overhead wire voltage detected by the voltage detection means;
An electric vehicle control device comprising: means for correcting the current command by adding the reactive current command calculated by the reactive current command calculation unit to the current command of each of the main converters. A converter connected to the overhead line via the main transformer;
A VVVF inverter connected to the DC side of the converter via a filter capacitor and driving the main motor;
Current detecting means for detecting the current on the AC side of the converter;
A plurality of main control units comprising a voltage control means for controlling the converter output voltage so that the current command value calculated so that the filter capacitor voltage becomes a predetermined value matches the current value detected by the current detection means. A conversion device;
Voltage detecting means for detecting the voltage of the overhead wire;
Each main converter includes a reactive current command calculating means for calculating a reactive current command based on the detected overhead wire voltage,
An electric vehicle control device comprising: means for correcting the current command by adding the calculated reactive current command to the current command of each main converter. In the electric vehicle control device according to claim 1 and claim 2,
The overhead wire voltage detecting means comprises:
Voltage detection means provided in the main conversion device for detecting an overhead wire voltage;
An electric vehicle control device comprising: an average overhead wire voltage calculating means for calculating an average value based on the overhead wire voltage detected in each main converter. A first converter connected to the overhead line via a main transformer;
A VVVF inverter connected to the DC side of the first converter via a filter capacitor and driving the main motor;
Current detecting means for detecting a current on the AC side of the first converter;
From the voltage control means for controlling the first converter output voltage so that the current command value calculated so that the filter capacitor voltage becomes a predetermined value matches the current value detected by the current detection means. A plurality of main converters,
A second converter connected to the overhead line via a main transformer and an energy storage means connected to the DC side of the second converter and capable of storing energy;
Current detecting means for detecting a current on the AC side of the second converter;
An energy storage conversion device comprising current control means for controlling the output voltage of the second converter so that the current value matches a predetermined current command value;
Voltage detecting means for detecting the overhead wire voltage;
Reactive current command calculating means for calculating a reactive current command based on the overhead wire voltage detected by the voltage detecting means;
An electric vehicle control device comprising: means for using the reactive current command as a current command for the energy storage conversion device. A converter connected to the overhead line via the main transformer;
A VVVF inverter connected to the DC side of the converter via a filter capacitor and driving the main motor;
Current detecting means for detecting the current on the AC side of the converter;
Voltage control means for controlling the converter output voltage so that the current command value calculated so that the filter capacitor voltage becomes a predetermined value and the current value detected by the current detection means match;
Voltage detecting means for detecting the voltage of the overhead wire;
Reactive current command calculation means for calculating a command of reactive current based on the detected overhead wire voltage;
A main conversion device comprising: means for correcting the current command value based on the reactive current command value;
The electric vehicle control apparatus according to claim 1, wherein the reactive current command calculation means has a finite gain in the low frequency range of the input / output gain. A converter connected to the overhead line via the main transformer;
A VVVF inverter connected to the DC side of the converter via a filter capacitor and driving the main motor;
Current detecting means for detecting the current on the AC side of the converter;
Voltage control means for controlling the converter output voltage so that the current command value calculated so that the filter capacitor voltage becomes a predetermined value and the current value detected by the current detection means match;
Voltage detecting means for detecting the voltage of the overhead wire;
Reactive current command calculation means for calculating a command of reactive current based on the detected overhead wire voltage;
A main converter comprising means for correcting the current command value based on the reactive current command value;
An electric vehicle control device comprising: means for adjusting the offset of a voltage detector for detecting the overhead wire voltage to be zero. In the electric vehicle control device according to claim 3,
Each main converter has means for calculating an effective value based on the detected overhead line voltage,
The electric vehicle controller according to claim 1, wherein the average overhead wire voltage calculating means is a means for calculating an average overhead wire voltage based on the effective value calculated in each of the main converters. A plurality of converters mounted on an electric vehicle for converting AC power to DC power;
A plurality of converter control units for controlling the plurality of converters;
Reactive current command calculating means for calculating a command of reactive current from the active current of the converter,
The electric vehicle control device, wherein the reactive current command calculation means outputs the same reactive current command to a plurality of converter control units. A plurality of converters mounted on an electric vehicle for converting AC power to DC power;
A plurality of converter control units for controlling the plurality of converters;
Voltage detection means for detecting the voltage of the overhead wire;
Reactive current command calculating means for calculating a reactive current command based on the overhead wire voltage detected by the voltage detecting means,
The electric vehicle control device, wherein the reactive current command calculation means outputs the same reactive current command to a plurality of converter control units.

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