JP2018182973A - Inverter control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve accuracy of phase synchronous processing of an inverter output voltage with a load bus voltage without complicating a structure.SOLUTION: An A-D converter 11 converts the voltage of a load bus into voltage data being a digital value. A first correction amount calculation unit 12 calculates a first correction amount which is used for correcting the angular velocity of the output voltage of an inverter, according to a phase difference between voltage data and reference data output by a reference data output unit 15. An angular velocity calculation unit 13 calculates an angular velocity after correction according to the first correction amount. An integrator 14 integrates the angular velocity after the correction with a period shorter than the sampling period of the A-D converter 11, and calculates a phase angle. A command generation unit 16 generates a voltage command to the inverter according to the phase angle. A control unit 17 outputs a control signal for switching turning-on and turning-off of a switching element that the inverter has, according to the voltage command.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an inverter control device that controls inverters that perform parallel operation.

  In an inverter system including a plurality of inverters performing parallel operation, a lead-through line of a phase synchronization signal used for phase synchronization of output voltages of the plurality of inverters may not be provided. In the inverter system, during operation of the inverter, it may be instructed to load other inverter's load bus. In this case, after the phase synchronization between the output voltage of the other inverter and the voltage of the load bus is established by a PLL (Phase Locked Loop), the other inverter is input to the load bus. The inverter system adjusts the frequency of the inverter according to the drooping characteristic of the effective current calculated from the output voltage and the output current of the inverter while the plurality of inverters are in parallel operation, thereby a cross current between the inverters Suppress the occurrence of

  The inverter parallel operation device disclosed in Patent Document 1 has a synchronization detector that detects the synchronization by introducing the output voltage of the standby inverter and the voltage of the load bus, and sends the inverter to the load bus after synchronization is established. .

Japanese Utility Model Application Publication No. 1-157586

  When an inverter system including a plurality of inverters performing parallel operation is realized by an analog circuit, characteristics of the control circuit change depending on ambient temperature or age. Changes in control circuit characteristics may degrade PLL synchronization performance. In addition, changes in the characteristics of the control circuit may degrade the performance of the frequency adjustment circuit that adjusts the frequency of the inverter in accordance with the drooping characteristics of the active current of the inverter. When the inverter system is implemented by a digital circuit to suppress changes in the characteristics of the control circuit, the operation period of the PLL and the operation period of the frequency adjustment circuit, and the sampling period of an analog-to-digital (AD) converter Need to match. Therefore, if the phase difference between the output voltage of the inverter and the voltage of the load bus is small, the phase of the output voltage of the inverter may not sufficiently follow the phase change of the voltage of the bus load. In order to improve the accuracy of phase synchronization processing between the output voltage of the inverter and the voltage of the load bus, the calculation period of PLL and the calculation period of frequency adjustment circuit are shortened, and the sampling period of A-D converter is shortened. Must. Therefore, the structure of the inverter system may be complicated and the manufacturing cost may increase.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to improve the accuracy of phase synchronization processing between the output voltage of the inverter and the voltage of the load bus without complicating the structure.

  In order to achieve the above object, an inverter control device according to the present invention is connected to a load bus via a bus switch, and is inverter controlled to control an inverter that supplies AC power to a load via the bus switch and the load bus. The apparatus is an A-D converter, a first correction amount calculation unit, an angular velocity calculation unit, an integrator, a command generation unit, a control unit, and a switch switching unit. The A-D converter acquires the voltage of the load bus and converts the voltage of the load bus into voltage data which is a digital value according to the sampling cycle. The first correction amount calculation unit calculates a first correction amount to be used for correcting the angular velocity of the output voltage according to the phase difference between the voltage data and the output voltage of the inverter. The angular velocity calculation unit calculates the corrected angular velocity in accordance with the first correction amount. The integrator integrates the corrected angular velocity with a cycle shorter than the sampling cycle to calculate a phase angle. The command generation unit generates a voltage command to the inverter according to the phase angle. The control unit outputs a control signal corresponding to the voltage command to the inverter. The switch switching unit turns on the bus switch when the phase difference between the voltage data and the output voltage is equal to or less than the threshold, thereby turning on the inverter to the load bus.

  According to the present invention, the angular velocity is integrated in a cycle shorter than the sampling cycle of the A-D converter, and the phase angle used to generate the voltage command to the inverter is calculated, without complicating the structure. It is possible to improve the accuracy of the phase synchronization process between the output voltage and the voltage of the load bus.

Block diagram showing an example of an inverter system according to Embodiment 1 of the present invention Block diagram showing an example of an inverter system according to Embodiment 1 mounted on a railway vehicle Block diagram showing a configuration example of the inverter control device according to the first embodiment Block diagram showing another configuration example of the inverter control device according to the first embodiment FIG. 6 shows an example of the output voltage of the inverter in the first embodiment. The figure which shows the example of the voltage data in Embodiment 1, and a phase angle. Block diagram showing a configuration example of an inverter control device according to Embodiment 2 of the present invention Block diagram showing a configuration example of an inverter control device according to a third embodiment of the present invention The figure which shows the example of the phase angle in Embodiment 3, and a carrier wave. The figure which shows the example of the phase angle in Embodiment 3, and a carrier wave. Block diagram showing another configuration example of the inverter control device according to the third embodiment

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the figures, the same or equivalent parts are denoted by the same reference numerals.

Embodiment 1
FIG. 1 is a block diagram showing an example of an inverter system according to a first embodiment of the present invention. The inverter system 1 includes inverters 30a and 30b, an inverter control device 10a that controls the inverter 30a, and an inverter control device 10b that controls the inverter 30b. Although the number of inverters included in the inverter system 1 is two in the example of FIG. 1, the inverter system 1 can include any number of inverters and an inverter control device provided for each inverter. In the example of FIG. 1, the outputs of the inverters 30a and 30b are three-phase alternating current. Inverter 30a is connected to each of the U-phase, V-phase, and W-phase of load bus bar 4 via bus switch 3a. The inverter 30 b is connected to each of the U phase, the V phase, and the W phase of the load bus 4 via the bus switch 3 b.

  The loads 2 a and 2 b are connected to the load bus 4. The inverter 30 a supplies AC power to the load 2 a via the bus switch 3 a and the load bus 4. The inverter 30 b supplies AC power to the load 2 b via the bus switch 3 b and the load bus 4. The inverter control devices 10a and 10b obtain the voltage of the load bus 4 and establish phase synchronization between the voltage of the load bus 4 and the output voltage of the inverters 30a and 30b, and then use the inverters 30a and 30b as the load bus 4 throw into. After establishing phase synchronization between the voltage of the load bus 4 and the output voltage of the inverters 30a and 30b, the generation of the cross current between the inverters 30a and 30b is suppressed by inputting the inverters 30a and 30b to the load bus 4. It is possible.

  FIG. 2 is a block diagram showing an example of an inverter system according to the first embodiment mounted on a railway vehicle. The positive terminal of the input side of the inverters 30 a and 30 b is connected to the current collector 6 via the circuit breaker 7 and the reactor 8. The negative terminal on the input side of the inverters 30a and 30b is grounded. The power obtained from the overhead wire 5 via the current collector 6 is supplied to the inverter system 1 via the circuit breaker 7 and the reactor 8. When the inverter system 1 is mounted on a railway vehicle, the inverters 30a and 30b operate as an auxiliary power supply. The loads 2a and 2b are, for example, an air conditioner and a lighting device. For example, the inverter 30a and the load 2a are mounted on the first car, and the inverter 30b and the load 2b are mounted on the second car.

  In the inverter system 1, for example, when the bus switch 3b is turned on and the inverter 30b is in operation, the inverter 30a may be turned on to the load bus 4 and the inverters 30a and 30b may be operated in parallel. Before turning on the inverter 30 a to the load bus 4, the inverter control device 10 a establishes phase synchronization between the output voltage of the inverter 30 a and the voltage of the load bus 4. By establishing phase synchronization between the output voltage of the inverter 30a and the voltage of the load bus bar 4, it is possible to suppress the generation of the cross current between the inverters 30a and 30b. Since the structures of the inverter control devices 10a and 10b are the same, the inverter control device 10a will be described.

  FIG. 3 is a block diagram showing a configuration example of the inverter control device according to the first embodiment. The inverter control device 10a converts the voltage of the load bus 4 into voltage data which is a digital value, an analog-to-digital (A-D) converter 11, and reference data output from the reference data output unit 15 described later. The first correction amount calculator 12 calculates a first correction amount used to correct the angular velocity of the output voltage of the inverter 30a according to the phase difference with the data. The first correction amount calculation unit 12 calculates a first correction amount from outputs of the phase comparator 121, the loop filter 122, and the loop filter 122, which multiplies the voltage data by the reference data and outputs the multiplication result. Amplifier 123 is provided.

  The inverter control device 10a further integrates the corrected angular velocity in a cycle shorter than the sampling cycle of the A-D converter 11 by the angular velocity calculation unit 13 which calculates the corrected angular velocity according to the first correction amount to obtain a phase angle. , And a reference data output unit 15 for outputting a digital value corresponding to the output voltage of the inverter 30a according to the phase angle. The angular velocity calculation unit 13, the integrator 14 and the reference data output unit 15 cooperate to operate as a VCO (Voltage-Controlled Oscillator). A PLL (Phase Locked Loop) is formed by the first correction amount calculation unit 12, the angular velocity calculation unit 13 operating as a VCO, the integrator 14, and the reference data output unit 15.

  The inverter control device 10a further includes a command generation unit 16 that generates a voltage command to the inverter 30a according to the phase angle, and a control unit 17 that outputs a control signal according to the voltage command to the inverter 30a. The inverter control device 10a further includes a switch switching unit 18 that switches on and off of the bus switch 3a according to the output of the loop filter 122, that is, the phase difference between the voltage data and the reference data.

  Each part of the inverter control device 10a will be described. The A-D converter 11 obtains, for example, the U-phase voltage of the load bus bar 4 and A-D converts the U-phase voltage to generate voltage data. The AD converter 11 may acquire a V-phase voltage or a W-phase voltage instead of the U-phase voltage. The reference data output unit 15 outputs reference data that is a digital value that outputs a digital value corresponding to the output voltage of the inverter 30 a according to the phase angle calculated by the integrator 14. When the U-phase voltage of the load bus 4 is a sine wave, the reference data is a cosine value corresponding to the phase angle.

  The phase comparator 121 outputs the result of multiplying the voltage data by the reference data to the loop filter 122. The multiplication result includes a component of difference in frequency between voltage data and reference data and a component of sum. The loop filter 122 removes the harmonic component of the multiplication result, that is, the component of the sum of the frequency of the voltage data and the reference data, and outputs the phase difference between the voltage data and the reference data. The output of the loop filter 122 corresponds to the phase difference between the voltage of the load bus 4 and the output voltage of the inverter 30a. For example, the output of the loop filter 122 corresponds to the phase difference between the U-phase voltage of the load bus 4 and the U-phase voltage of the output of the inverter 30a. The first amplifier 123 multiplies the output of the loop filter 122 by the PLL gain to calculate a first correction amount that is a correction amount from the initial angular velocity. The initial angular velocity is an initial value of the angular velocity of the inverter 30a, and is an angular velocity corresponding to the rated frequency of the inverter 30a. The initial angular velocity is, for example, an angular velocity corresponding to a value larger than the rated frequency of the inverter by about 0.5 Hz, that is, 50.5 Hz or 60.5 Hz.

  The angular velocity calculation unit 13 calculates the corrected angular velocity by adding the initial angular velocity to the first correction amount output from the first amplifier 123. The integrator 14 integrates the corrected angular velocity with a cycle shorter than the sampling cycle of the A-D converter 11 to calculate a phase angle. The operation cycle of the integrator 14 is, for example, 1/16 of the sampling cycle. When the sampling period of the A-D converter 11 is, for example, 10 microseconds, the integration period of the integrator 14 is 0.625 microseconds. The command generation unit 16 generates a voltage command to the inverter 30a according to the phase angle. For example, the command generation unit 16 generates voltage commands of the U phase, the V phase, and the W phase to the inverter 30 a according to the phase angle of the U phase output by the integrator 14. The control unit 17 sends a control signal for switching on and off of the switching element of the inverter 30a to the inverter 30a. When the phase difference between the voltage data and the reference data is equal to or less than the threshold value, the switch switching unit 18 turns on the bus switch 3 a to turn on the inverter 30 a to the load bus 4. By setting the threshold value to a sufficiently small value, it is possible to apply inverter 30 a to load bus 4 after establishing phase synchronization between the output voltage of inverter 30 a and the voltage of load bus 4.

  With the above-described configuration, inverter control device 10a can apply inverter 30a to load bus 4 after establishing phase synchronization between the output voltage of inverter 30a and the voltage of load bus 4. Even if the phase difference between the output voltage of the inverter 30a and the voltage of the load bus 4 is small by making the integration period of the integrator 14 shorter than the sampling period of the A-D converter 11, the output of the inverter 30a It is possible to make the phase of the voltage follow the phase of the voltage of the load bus 4. Since only the operation cycle of the integrator 14 needs to be shortened and the sampling cycle of the A-D converter 11 may be fixed, phase synchronization between the output voltage of the inverter and the voltage of the load bus 4 is possible without complicating the structure. It is possible to improve the processing accuracy.

  FIG. 4 is a block diagram showing another configuration example of the inverter control device according to the first embodiment. The inverter control device 10a shown in FIG. 4 is a second one used for correcting the angular velocity of the output voltage of the inverter 30a according to the effective current of the output current of the inverter 30a and the effective current drooping characteristic in addition to the configuration of FIG. A second correction amount calculation unit 19 that calculates the correction amount, and a first correction amount and a second correction amount are input, and one for the first correction amount and the second correction amount is output. The switch 20 is further provided. The second correction amount calculating unit 19 multiplies the effective current by an effective current calculating unit 191 that calculates an effective current from the output voltage and the output current of the inverter 30a, and a drooping characteristic gain that is a gain corresponding to the drooping characteristic of the effective current. A second amplifier 192 is provided to calculate a second correction amount by doing this.

  The effective current calculation unit 191 obtains the output voltage and the output current of the inverter 30a, and calculates an effective current from the output voltage and the output current. The active current calculation unit 191 operates in the same cycle as the sampling cycle of the AD converter 11, and calculates an active current that is a digital value from the output voltage and output current of the inverter 30a. The second amplifier 192 multiplies the effective current by the drooping characteristic gain to calculate a second correction amount indicating the amount of change from the initial angular velocity. The switch switching unit 18 switches on and off of the bus switch 3a and the correction switch 20 according to the output of the loop filter 122, that is, the phase difference between the voltage data and the reference data.

  FIG. 5 is a diagram showing an example of the output voltage of the inverter in the first embodiment. During the operation of inverter 30b, at time T1, input of inverter 30a is instructed. At time T1, the bus switch 3a is open. At time T1, the inverter control device 10a starts phase synchronization processing of the output voltage of the inverter 30a and the voltage of the load bus 4. Thereafter, at time T2, when phase synchronization between the output voltage of the inverter 30a and the voltage of the load bus 4 is established, the inverter control device 10a turns on the bus switch 3a, and the inverter 30a is turned on to the load bus 4. As shown in FIG. 5, during the phase synchronization process, the amplitude of the output voltage of the inverter 30a increases as indicated by a ramp function.

  The output voltage of the inverter 30a and the load bus bar 4 which the inverter control unit 10a performs when the inverter control unit 10a shown in FIG. 4 is instructed to turn on the inverter 30a while the bus switch 3a is open The phase synchronization process with the voltage of While the bus switch 3a is open, the switch switching unit 18 controls the correction switch 20 to cause the correction switch 20 to output the first correction amount. The A-D converter 11 obtains a U-phase voltage, performs A-D conversion of the U-phase voltage according to a sampling cycle, and generates voltage data.

  The phase comparator 121 multiplies the voltage data by the reference data, and outputs the multiplication result. The loop filter 122 removes the harmonic component of the multiplication result, and outputs the phase difference between the voltage data and the reference data. The first amplifier 123 calculates a first correction amount by multiplying the phase difference between the voltage data and the reference data by a predetermined PLL gain. The correction switch 20 outputs a first correction amount. The angular velocity calculation unit 13 calculates the corrected angular velocity by adding the initial angular velocity to the first correction amount output from the correction switch 20. The integrator 14 integrates the corrected angular velocity with a cycle shorter than the sampling cycle of the A-D converter 11 to calculate a phase angle. The integrator 14 sends the phase angle to the reference data output unit 15 and the command generation unit 16. The reference data output unit 15 outputs reference data corresponding to the phase angle.

  The command generation unit 16 generates a voltage command to the inverter 30a according to the phase angle. In the first embodiment, command generation unit 16 generates a U-phase voltage command, a V-phase voltage command, and a W-phase voltage command according to the phase angle. The command generation unit 16 may generate a voltage command according to the phase angle and the amplitude indicated by the rated voltage of the inverter 30a or the amplitude of the voltage of the load bus 4 indicated by the voltage data. The control unit 17 generates a control signal for switching on / off of the switching element of the inverter 30a according to the voltage command, and outputs the control signal to the inverter 30a.

  When the phase difference output from the loop filter 122 is equal to or less than the threshold value, the switch switching unit 18 turns on the bus switch 3a, controls the correction switch 20, and outputs the second correction amount to the correction switch 20. Let Thereby, inverter 30a is input to load bus bar 4, and frequency adjustment processing of inverter 30a according to the drooping characteristic of the effective current of inverter 30a, which will be described later, is started. When the phase difference output from the loop filter 122 is equal to or less than the threshold and the ratio of the amplitude of the voltage of the load bus 4 to the amplitude of the output voltage of the inverter 30a is equal to or less than the threshold The switch 3a may be turned on and the correction switch 20 may be switched. The threshold value can be determined according to the accuracy required for the phase synchronization process between the voltage of the load bus 4 and the output voltage of the inverter 30a.

  The adjustment of the frequency of the inverter 30a according to the drooping characteristic of the effective current of the inverter 30a after the inverter 30a is input to the load bus 4 will be described. The active current calculation unit 191 calculates an active current from the output voltage and the output current of the inverter 30a. The second amplifier 192 calculates a second correction amount by multiplying the effective current by the drooping characteristic gain. The correction switch 20 outputs a second correction amount. The subsequent processing is the same as in the phase synchronization processing described above. By setting the drooping characteristic gain as a negative gain, the frequency of the inverter 30a can be lowered when the effective current increases.

  FIG. 6 is a diagram showing an example of voltage data and a phase angle in the first embodiment. The sampling period in the AD converter 11 is C1. The integrator 14 integrates the angular velocity with a period C2 shorter than C1 to calculate a phase angle. The integrator 14 integrates the angular velocity at a cycle C2 shorter than C1 to improve the followability of the phase of the output voltage of the inverters 30a and 30b with respect to the phase of the voltage of the load bus 4. That is, the accuracy of the phase synchronization process between the output voltage of inverters 30a and 30b and the voltage of load bus 4 is improved. Further, since only the operation period of the integrator 14 is shortened, it is not necessary to use an A-D converter having a variable sampling period as the A-D converter 11, so that complication of the structure can be avoided, and the manufacturing cost It is possible to suppress the increase of

  In the inverter control devices 10a and 10b shown in FIG. 4, since the correction switch 20 is switched in response to the closing of the bus switches 3a and 3b, the continuity of the phase angle is secured. Further, the integrator 14 used to calculate the phase angle is shared by phase synchronization processing before the inverters 30a and 30b are input to the load bus 4 and frequency adjustment processing after the inverters 30a and 30b are input to the load bus 4. Thus, the structure of the inverter control devices 10a and 10b can be simplified.

  As described above, according to the inverter control devices 10a and 10b according to the first embodiment, the integrator 14 integrates the angular velocity to calculate the phase angle at a cycle shorter than the sampling cycle of the AD converter 11. Thus, it is possible to improve the accuracy of the phase synchronization process of the output voltage of the inverters 30a and 30b and the voltage of the load bus 4 without complicating the structure.

Second Embodiment
FIG. 7 is a block diagram showing a configuration example of an inverter control device according to a second embodiment of the present invention. The inverter control devices 10a and 10b according to the second embodiment further include a phase correction unit 21 in addition to the configuration of the inverter control devices 10a and 10b shown in FIG. The phase correction unit 21 corrects the phase angle by adding the determined phase correction amount to the phase angle output from the integrator 14. The command generation unit 16 generates a voltage command in accordance with the corrected phase angle. The phase correction unit 21 performs correction for advancing the phase angle, for example, according to the delay of the phase that may occur in the control circuit of the inverter control devices 10a and 10b and the main circuit of the inverters 30a and 30b. Thus, even if phase delays occur in the control circuit and the main circuit, no phase difference occurs between the output voltage of inverters 30a and 30b and the voltage of load bus 4. Therefore, it is possible to suppress the generation of the cross current between the inverters 30a and 30b.

  As described above, according to the inverter control devices 10a and 10b according to the second embodiment of the present invention, for example, the inverter 30a is corrected by correcting the phase angle according to the phase delay that may occur in the control circuit and the main circuit. It is possible to suppress the generation of cross current between 30b.

Third Embodiment
FIG. 8 is a block diagram showing a configuration example of an inverter control device according to a third embodiment of the present invention. In addition to the configuration of inverter control devices 10a and 10b shown in FIG. 4, inverter control devices 10a and 10b according to the third embodiment use PWM (for generating control signals in control unit 17 according to the phase angle). The apparatus further includes a carrier generation unit 22 that generates a carrier of a pulse width modulation (Pulse Width Modulation) method. The carrier generation unit 22 outputs a division ratio according to the angular velocity, a division ratio output unit 221, a divider 222 that divides a reference signal from a crystal oscillator (not shown) to generate a carrier clock, and a phase angle It includes a phase angle detection unit 223 that detects the timing when it is 0 degrees, and a carrier synchronization unit 224 that generates a carrier according to the timing when the phase angle is 0 and the carrier clock.

  The division ratio output unit 221 outputs a division ratio according to the angular velocity. The division ratio is determined according to the angular velocity based on the oscillation frequency of the crystal oscillator so that the period of the carrier wave becomes a value obtained by dividing the fluctuation period of the phase angle by a natural number. The divider 222 divides the reference signal from the crystal oscillator to generate a carrier clock. The phase angle detection unit 223 detects the timing when the phase angle becomes 0 degree and notifies the carrier synchronization unit 224. The carrier wave synchronization unit 224 generates a carrier wave having a phase whose phase angle becomes 0 degree is the initial phase and whose initial phase is 0 degree according to the carrier wave clock. According to the above configuration, the carrier generation unit 22 generates a carrier having a phase where the phase angle becomes 0 degree is 0 degree and the period is a value obtained by dividing the variation period of the phase angle by a natural number. The carrier generation unit 22 sends the carrier to the control unit 17. The control unit 17 generates a control signal based on the voltage command generated by the command generation unit 16 and the carrier wave generated by the carrier generation unit 22, and outputs the control signal to the inverters 30a and 30b.

  FIG. 9 and FIG. 10 are diagrams showing examples of the phase angle and the carrier in the third embodiment. In FIG. 9, the phase of the carrier wave is 0 degree at the timing when the phase angle becomes 0 degree. The period of the carrier wave is a value obtained by dividing the fluctuation period C3 of the phase angle by a natural number. In the example of FIG. 9, the period of the carrier wave is a value obtained by dividing the fluctuation period C3 of the phase angle by six. Similarly in FIG. 10, the phase of the carrier wave is 0 degree when the phase angle is 0 degree. The period of the carrier wave is a value obtained by dividing the fluctuation period C4 of the phase angle by a natural number. In the example of FIG. 10, the period of the carrier wave is a value obtained by dividing the fluctuation period C4 of the phase angle by six. Since the frequency divider 222 divides the reference signal from the crystal oscillator by the division ratio determined in accordance with the angular velocity to generate the carrier clock, the output voltage of the inverters 30a and 30b is synchronized with the carrier. It is possible.

  By providing the carrier generation unit 22, the output voltage of the inverters 30a and 30b is synchronized with the carrier, so that the non-theoretical harmonics are not superimposed on the return current of the inverters 30a and 30b. Therefore, the induction disorder by which the signal wave used by security devices such as ATC (Automatic Train Control: Automatic Train Control) and ATS (Automatic Train Stop: Automatic Train Stop) due to superposition of non-theoretical harmonics is interrupted. It is possible to suppress the occurrence of

  FIG. 11 is a block diagram showing another configuration example of the inverter control device according to the third embodiment. The inverter control devices 10a and 10b illustrated in FIG. 11 include the above-described carrier wave generation unit 22 in addition to the configuration of the inverter control devices 10a and 10b illustrated in FIG. The operation of the carrier wave generator 22 is as described above. However, the phase angle detection unit 223 detects timing when the corrected phase angle output from the phase correction unit 21 becomes 0 degree.

  As described above, according to the inverter control devices 10a and 10b according to the third embodiment of the present invention, the occurrence of induction failure is suppressed by using the control signal based on the carrier wave synchronized with the output voltage of the inverters 30a and 30b. It is possible.

  Embodiments of the present invention are not limited to the above-described embodiments. The outputs of the inverters 30a, 30b may be single phase alternating current.

  DESCRIPTION OF SYMBOLS 1 inverter system, 2a, 2b load, 3a, 3b bus switch, 4 load bus, 5 overhead wire, 6 current collector, 7 circuit breaker, 8 reactor, 10a, 10b inverter control device, 11 AD converter, 12 First correction amount calculation unit, 13 angular velocity calculation unit, 14 integrator, 15 reference data output unit, 16 command generation unit, 17 control unit, 18 switch switching unit, 19 second correction amount calculation unit, 20 correction switch , 21 phase correction unit, 22 carrier generation unit, 30a, 30b inverter, 121 phase comparator, 122 loop filter, 123 first amplifier, 191 active current calculation unit, 192 second amplifier, 221 division ratio output unit, 222 divider, 223 phase angle detector, 224 carrier synchronizer.

Claims (5)

An inverter control device connected to a load bus via a bus switch and controlling an inverter that supplies AC power to the load via the bus switch and the load bus,
An A-D converter which acquires the voltage of the load bus and converts the voltage of the load bus into voltage data which is a digital value according to a sampling cycle;
A first correction amount calculation unit that calculates a first correction amount used to correct the angular velocity of the output voltage according to the phase difference between the voltage data and the output voltage of the inverter;
An angular velocity calculation unit that calculates the corrected angular velocity according to the first correction amount;
An integrator which calculates the phase angle by integrating the corrected angular velocity at a period shorter than the sampling period;
A command generation unit that generates a voltage command to the inverter according to the phase angle;
A control unit that outputs a control signal corresponding to the voltage command to the inverter;
A switch switching unit that applies the inverter to the load bus by turning on the bus switch when the phase difference between the voltage data and the output voltage is equal to or less than a threshold value;
An inverter control device comprising: A second one for acquiring the output voltage and the output current of the inverter, and correcting the angular velocity of the output voltage according to an effective current calculated from the output voltage and the output current and an effective current drooping characteristic. A second correction amount calculation unit that calculates the correction amount;
A correction switch which receives the first correction amount and the second correction amount and outputs one of the first correction amount and the second correction amount;
And further
The angular velocity calculation unit calculates the corrected angular velocity in accordance with one of the first correction amount and the second correction amount output from the correction switch.
The switch switching unit turns on the bus switch when the phase difference between the voltage data and the output voltage is equal to or less than the threshold, and controls the correction switch to set the second switch to the correction switch. Output the correction amount of
The inverter control device according to claim 1. The system further includes a phase correction unit that corrects the phase angle by adding a phase correction amount determined to the phase angle,
The command generation unit generates the voltage command in accordance with the phase angle corrected by the phase correction unit.
The inverter control device according to claim 1. In the pulse width modulation method, the phase at which the phase angle becomes 0 is an initial phase, the value of the initial phase is 0, and the period is a value obtained by dividing the fluctuation period of the phase angle by a natural number. And a carrier generation unit that generates a carrier.
The control unit outputs the control signal generated based on the carrier wave.
The inverter control device according to claim 1. The phase of the timing when the phase angle corrected by the phase correction unit becomes 0 is the initial phase, and the value of the initial phase is 0, and the period is a variation of the phase angle corrected by the phase correction unit A carrier generation unit for generating a carrier of a pulse width modulation system, which is a value obtained by dividing a period by a natural number;
The control unit outputs the control signal generated based on the carrier wave.
The inverter control device according to claim 3.

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