JP6274991B2 - Power converter - Google Patents

Description

  The present invention relates to a power converter that converts alternating current into direct current or converts direct current into alternating current. In particular, the present invention relates to a power conversion device including an arm in which a plurality of converter cells each including a plurality of semiconductor switching elements and a DC capacitor are connected in series.

A modular multi-level power converter (MMC type power converter), which is a voltage-type power converter that is connected to an AC system and a DC system, converts AC to DC, or converts DC to AC, is bidirectional. A unit conversion circuit including a chopper circuit, a full bridge circuit, and a DC capacitor is constituted by a plurality of arms connected in cascade. Each arm has one terminal connected in series to each other via an arm reactor, and this connection point is connected to each phase of the three-phase AC system.
If the MMC type power converter is connected to the system in a state where the DC capacitor of each unit conversion circuit is not charged, an inrush current flows into the DC capacitor through the diode of each unit conversion circuit.

As a countermeasure, in conventional power converters, a variable DC voltage source is connected in parallel with the power converter, which is the main circuit, and the DC capacitor of each unit converter circuit is initialized while gradually increasing the output voltage of the variable DC voltage source. A method of charging is disclosed.
In order to further reduce the size of the device, the individual unit conversion circuits to be charged are sequentially charged so that the output voltage of the variable DC voltage source can be charged with a voltage lower than the AC voltage connected to the power converter. A method is also disclosed (for example, see Patent Document 1).

  In addition, according to another conventional method for starting a power converter, before starting normal operation of a power converter composed of a power converter, a charging resistor, and a DC capacitor, A method is disclosed in which the supplied alternating current is converted into direct current, the obtained direct current is charged into a direct current capacitor via a charging resistor, and the normal operation of the power conversion device is performed after charging (for example, Patent Documents). 2).

JP 2011-24392A Japanese Patent Laid-Open No. 8-130877

  In the power conversion device described in Patent Document 1, the DC capacitor can be initially charged without an AC power supply in the AC system, but a variable DC voltage source for charging is required separately from the power supply of the system. . In such an initial charging method using a variable DC voltage source, since no charging resistor is used, the voltage level of the DC capacitor is gradually increased by monitoring the voltage level of the DC capacitor in order to prevent an inrush current. There is a need. In order to reduce the size of the device, unit conversion other than the unit conversion circuit to be charged is made so that the output voltage of the variable DC voltage source can charge the DC capacitor with a voltage lower than the AC voltage connected to the power converter. The circuit is left uncharged, and each unit conversion circuit to be charged is sequentially charged. However, in this method, the charging time increases as the number of unit conversion circuits increases. Also, a space for providing a variable DC voltage source is required.

  Moreover, in the power converter device of said patent document 2, after completion of the initial charge of a DC capacitor, a power converter device is started and the output is made into a voltage substantially equal to a system voltage. For this reason, it takes time to start. Moreover, since the alternating current is converted into direct current to charge the direct current capacitor, power loss due to power conversion occurs when the direct current capacitor is charged.

  The present invention was made to solve the above-described problems, and it is possible to reduce the size of the apparatus without using an individual power source for initial charging for initial charging of a DC capacitor in the power converter, An object of the present invention is to provide an MMC type power conversion device capable of starting up at high speed while reducing power loss.

The power conversion device according to the present invention includes a leg circuit in which a positive arm and a negative arm are connected in series to each AC phase, and the leg circuits of each phase are connected in parallel between positive and negative DC buses. In the power conversion device including a power converter that performs power conversion between alternating current and direct current and a control device, the positive arm and the negative arm of the leg circuit are connected in series to each other. In addition, one or a plurality of converter cells including a series body of a plurality of semiconductor switching elements and a DC capacitor connected in parallel to the series body are connected in series.
A cell drive control unit operates by being supplied with power from the DC capacitor in the converter cell and controls the semiconductor switching element based on a command value, and the control device monitors the voltage of the DC capacitor. A DC capacitor monitoring unit; and a command generation unit that generates the command value for the converter cell. In the initial charging of the DC capacitor performed when the power converter is started, the voltage of the DC capacitor is driven by the cell drive. reaches the first reference voltage based on the starting voltage of the control unit, and generates the command value, by the cell drive control unit drives the semiconductor switching elements in the converter cells, the command generating unit, the The command value is generated according to the voltage of the DC capacitor, and the command generator generates a DC voltage of the command value in the initial charging of the DC capacitor. Adjust the DUTY ratio of the components, the voltage of the DC capacitor reaches the second reference voltage based on the rated voltage of the DC capacitor, in which the DUTY ratio of the DC voltage component to 50%.

  According to the MMC type power converter according to the present invention, it is possible to shorten the charging time while reducing the power loss in the initial charging of the DC capacitor in the power converter, and the power converter can be started up at high speed. Furthermore, it is possible to reduce the size and cost of the apparatus by eliminating the need for an individual power source for initial charging.

It is a schematic block diagram of the power converter device by Embodiment 1 of this invention. It is the schematic which shows the circuit structure of the power converter by Embodiment 1 of this invention. It is a circuit block diagram of the converter cell in the power converter by Embodiment 1 of this invention. It is a block diagram which shows the structure of the control apparatus and cell drive control part by Embodiment 1 of this invention. It is a flowchart which shows the control operation of the control apparatus and cell drive control part by Embodiment 1 of this invention. It is a figure which shows the relationship between the DC voltage DUTY ratio by the PWM control of the converter cell by Embodiment 1 of this invention, and an alternating current output possible range. It is a figure which shows the relationship between the DC voltage DUTY ratio by the PWM control of the converter cell by Embodiment 2 of this invention, and an alternating current output possible range. It is a flowchart which shows the control operation of the control apparatus and cell drive control part by Embodiment 2 of this invention. It is a circuit block diagram of the converter cell in the power converter by Embodiment 3 of this invention. It is a figure which shows the relationship between the DC voltage DUTY ratio by the PWM control of the converter cell by Embodiment 3 of this invention, and an alternating current output possible range.

Embodiment 1 FIG.
Hereinafter, power conversion device 100 according to Embodiment 1 of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic configuration diagram of a power conversion apparatus according to Embodiment 1 of the present invention.
The power conversion device 100 is connected between the AC system 7 that is a three-phase AC circuit and the high-voltage DC transmission network 1 that is a DC circuit, and performs a power conversion between AC and DC, And a control device 70 that controls the operation of the power converter 50.
Hereinafter, the case where there is no AC power source in the AC system 7 will be described as an example.

As shown in FIG. 1, the power converter 50 has a DC side terminal connected to a charging resistor 4 and a second opening / closing unit 3 connected in parallel to the resistor 4 to short-circuit both ends of the resistor 4. It is connected. In addition, a third opening / closing part 2 that opens and closes the electric circuit is connected in series between the resistor 4 and the high-voltage DC transmission network 1. As a result, the power converter 50 is connected to the high-voltage DC power transmission network 1 via the resistor 4 and the third switching unit 2 by the DC bus, and is connected to the high-voltage DC power transmission network 1 via the DC buses 6P and 6N. Supplied with current.
The AC side terminal of the power converter 50 is connected to a transformer 5 for connecting to the AC system 7. Between the transformer 5 and the alternating current system 7, the 1st switching part 9 which opens and closes an electric circuit is connected in series. As a result, the power converter 50 is linked to the AC system 7 via the transformer 5 and the first opening / closing part 9 by each phase AC line.
In addition, a voltage detection unit 8 that detects an AC voltage output from the power converter 50 and transmits the AC voltage to the control device 70 is provided.

FIG. 2 is a schematic diagram showing a circuit configuration of power converter 50 according to the first embodiment of the present invention.
The power converter 50 is an MMC type power converter. As shown in FIG. 2, one terminal of each of a positive side arm 53a and a negative side arm 53b in which a plurality of converter cells 52 are connected in series is connected in series with each other. Three leg circuits 51 connected to each other are provided, and these leg circuits 51 are connected in parallel between the positive and negative DC buses 6P and 6N. The connection point between the positive side arm 53a and the negative side arm 53b (AC side terminal of the power converter 50) is connected to each phase AC line (U to W), and the other terminal of the positive side arm 53a is connected to the positive electrode. The other side terminal of the negative side arm 53b is connected to the DC bus 6N on the negative side and the DC bus 6N on the negative side. Each of the positive side arm 53a and the negative side arm 53b includes a reactor for adjusting the current, but is omitted because it is not necessary for the description of the present invention.

FIG. 3 is a circuit configuration diagram of converter cell 52 in power converter 50 according to the first embodiment of the present invention.
As shown in the figure, the converter cell 52 is a bidirectional chopper circuit including a series body 60 in which semiconductor switching elements 57a and 57b, to which diodes 59a and 59b are connected in antiparallel, are connected in series. A DC capacitor 56 is connected to the series body 60 in parallel.
Further, a cell drive control unit 55 that receives power supply from the DC capacitor 56 and controls driving of the semiconductor switching elements 57 a and 57 b is connected between the positive and negative terminals of the DC capacitor 56.
The input / output terminal 61 of each converter cell 52 is connected to the input / output terminal 62 of another converter cell 52, and the input / output terminal 62 of each converter cell 52 is connected to the input / output terminal of the other converter cell 52. 61 is connected.
Here, IGBTs are used as the semiconductor switching elements 57a and 57b, but the present invention is not limited to this, and other self-extinguishing semiconductor switching elements may be used.

FIG. 4 is a block diagram showing the configuration of the control device 70 and the cell drive control unit 55 according to the first embodiment of the present invention.
The cell drive control unit 55 in each converter cell 52 detects the voltage of the DC capacitor 56 of its own converter cell 52 and transmits the information to the control device 70 and the command value 71. And a starting portion 31 for starting the semiconductor switching elements 57a and 57b.

  The control device 70 includes a first opening / closing part switching unit 46, a second opening / closing part switching unit 43, a third opening / closing part switching unit 40, a DC capacitor monitoring unit 41, a voltage determination unit 42, and an AC voltage monitoring unit 44. An AC voltage determination unit 45, a communication unit 47, and a command generation unit 48.

The third opening / closing part switching part 40 controls the opening / closing of the third opening / closing part 2, the second opening / closing part switching part 43 controls opening / closing of the second opening / closing part 3, and the first opening / closing part switching part 46 is the first opening / closing part. 9 is controlled.
The DC capacitor monitoring unit 41 monitors the voltage Vc of the DC capacitor 56 in each converter cell 52, and the voltage determination unit 42 compares and determines the voltage Vc and a first reference voltage Vs (described later).
The command generation unit 48 generates a command value 71 used in each cell drive control unit 55, and the communication unit 47 is a means for communicating between the control device 70 and each cell drive control unit 55.
The AC voltage monitoring unit 44 monitors the output AC voltage of the power converter 50, and the AC voltage determination unit 45 compares and determines the output AC voltage and the voltage of the AC system 7.

FIG. 5 is a flowchart showing the control operation of control device 70 and cell drive control unit 55 according to Embodiment 1 of the present invention.
Hereinafter, the operation | movement at the time of starting of the power converter device 100 which concerns on this invention is demonstrated.
The control device 70 is driven by an individual power supply before the power converter 50 is activated, and monitors the voltage of the AC system 7 and the state of the power converter 50. Further, the control device 70 controls the first opening / closing part 9, the second opening / closing part 3 and the third opening / closing part 2, which are switches for opening and closing the electric circuit, to be in an open state before the power converter 50 is activated. In this way, the electric circuit to the AC system 7 is interrupted by opening the first opening / closing part 9, and the electric circuit from the high-voltage DC power transmission network 1 is controlled by controlling the third opening / closing part 2 to the open state. By shutting off and not being supplied with electric power, the second opening / closing part 3 is opened so that both ends of the resistor 4 are not short-circuited. At this time, the semiconductor switching elements 57a and 57b of all the converter cells 52 are in the OFF state.

  First, in order to obtain power from the high-voltage DC transmission network 1, the control device 70 activates the power converter 50 by closing the third opening / closing part 2 by the third opening / closing part switching part 40, and in each converter cell 52. Initial charging of the DC capacitor 56 is started (step S001). When the third switch 2 is closed, the direct current output from the high-voltage DC transmission network 1 flows through the positive DC bus 6P and is supplied to the power converter 50 via the third switch 2 and the resistor 4. . At this time, the direct current is limited by the resistor 4 and is supplied from the DC bus 6P on the positive side of the power converter 50 to the DC capacitor 56 through the input / output terminal 61 and the diode 59a of each converter cell 52. . Normally, the voltage Vc of the DC capacitor 56 of each converter cell 52 is 0 [V] in the initial state. However, the voltage Vc gradually rises by being charged with the power from the high-voltage DC power transmission network 1 in this way.

Next, the DC capacitor monitoring unit 41 monitors the voltage Vc of the DC capacitor 56 (step S002).
Next, the voltage determination unit 42 reaches the first reference voltage Vs based on the starting voltage of the cell drive control unit 55 and is equal to or higher than Vs, with the voltage Vc of the DC capacitor 56 in each converter cell 52. Is determined (step S003). In the present embodiment, the first reference voltage Vs is set to the activation voltage level of the cell drive control unit 55. If the minimum voltage of the voltage Vc of the DC capacitor 56 is smaller than the first reference voltage Vs, the process returns to step S002, and the minimum voltage Vc of the DC capacitor 56 of each converter cell 52 is continuously monitored.

  In step S003, when the minimum voltage among the voltages Vc of the DC capacitors 56 is equal to or higher than the first reference voltage Vs, the cell drive control units 55 in all the converter cells 52 included in the power converter 50 can be activated. Each cell drive control unit 55 is activated by a signal from the communication unit 47. The cell drive control unit 55 detects the voltage Vc of the DC capacitor 56 in each cell drive control unit 55 by the voltage detection unit 30 and transmits it to the control device 70.

  Next, the command generation unit 48 generates a command value 71 for driving and controlling the semiconductor switching elements 57a and 57b according to the voltage Vc of the DC capacitor 56, for example, the average value of each voltage Vc, and each converter cell. The command value 71 is output to the cell drive control unit 55 in 52. Each cell drive control unit 55 receives the command value 71, and the ignition unit 31 drives each semiconductor switching element 57a, 57b based on the command value 71 and the voltage Vc of each DC capacitor 56 by PWM (Pulse Width Modulation). A gate pulse signal for output is output (step S004).

  Thus, when each semiconductor switching element 57a, 57b performs a switching operation based on the gate pulse signal, the power converter 50 converts the DC voltage smoothed by each DC capacitor 56 into an AC voltage including a DC component. And output (step S005). Then, the transformer 5 is excited by this output AC voltage (step S006).

FIG. 6 is a diagram showing the relationship between the DC voltage DUTY ratio by the PWM control of converter cell 52 and the AC output possible range according to Embodiment 1 of the present invention.
The command value 71 from the control device 70 includes the DUTY ratio of the DC voltage component and the DUTY ratio of the AC voltage component, and the output AC voltage of the converter cell 52 is output according to the DUTY ratio of the DC voltage component. The possible range is limited. In the case where the converter cell 52 is a bidirectional chopper circuit as in the present embodiment, when the voltage of the DC capacitor 56 is the rated voltage, the AC voltage is changed when the DUTY ratio of the DC voltage component is 50% as shown in FIG. It is possible to output 100% of the voltage. In the present embodiment, the DUTY ratio of the DC voltage component of the command value 71 is 50%, and the DUTY ratio of the AC voltage component is calculated according to the voltage Vc of the DC capacitor 56. Based on this command value 71, the cell drive control unit 55 of each converter cell 52 switches the semiconductor switching elements 57a and 57b alternately to switch the DC voltage component DUTY ratio to 50%.
The command value 71 can be constituted by a gate voltage signal or a continuous voltage command value.

  In this way, when the voltage Vc of the DC capacitor 56 reaches the voltage for starting the cell drive control unit 55 and the power source for driving the semiconductor switching elements 57a and 57b can be secured, Since the semiconductor switching elements 57a and 57b are driven to output an alternating voltage, it is possible to accelerate the excitation of the transformer.

Next, the voltage determination unit 42 determines whether the voltage Vc (average value) of the DC capacitor 56 in the converter cell 52 reaches the second reference voltage Vsc based on the rated capacitor voltage of the DC capacitor 56 and is equal to or higher than Vsc. It is determined whether or not (step S007). In this embodiment, Vsc is set to a value near the rated voltage of DC capacitor 56. If the voltage Vc (average value) of the DC capacitor 56 is smaller than the second reference voltage Vsc, the process returns to step S004.
In step S007, when the voltage Vc (average value) of the DC capacitor 56 reaches the second reference voltage Vsc, the control device 70 closes the second opening / closing part 3 by the second opening / closing part switching part 43, and the resistor 4 Both ends are short-circuited (step S008).

  Thus, in the initial charging of the DC capacitor 56, the inrush current is suppressed by supplying power through the resistor 4 until the voltage Vc (average value) of the DC capacitor 56 reaches near the rated voltage, and thereafter the resistor 4 is short-circuited to charge the DC capacitor 56 at high speed.

Next, the AC voltage monitoring unit 44 monitors the output AC voltage of the power converter 50 detected by the voltage detection unit 8 (step S009). The AC voltage determination unit 45 controls the opening / closing of the first opening / closing unit 9 based on the AC voltage output from the power converter 50. When the AC system 7 is in operation, the magnitude of the output AC voltage via the transformer 5 of the power converter 50 is compared with the magnitude of the voltage of the AC system 7 (step S010), and the magnitude of the output AC voltage. Is not equal to that of the AC system 7, the process returns to step S009, and the output AC voltage of the power converter 50 is continuously monitored.
When the magnitude of the output AC voltage through the transformer 5 becomes substantially equal to the voltage of the AC system 7 in step S010, the first opening / closing section 9 is closed by the first opening / closing section switching section 46 ( Step S011), power transmission to the AC system 7 is started, and the power conversion apparatus 100 completes the activation process (step S012).

  On the other hand, when the AC system 7 is stopped, in step S010, the AC voltage determination unit 45 compares the magnitude of one voltage on the primary side and the secondary side of the transformer 5 with the rated voltage of the AC system 7. If they are not equal, the process returns to step S009. In step S010, when the magnitude of the voltage on the primary side or the secondary side of the transformer 5 becomes substantially equal to the rated voltage of the AC system 7, the first switching unit 9 is switched by the first switching unit switching unit 46. It is closed (step S011), power transmission to the AC system 7 is started, and the power conversion apparatus 100 completes the startup process (step S012).

In the present embodiment, the voltage determination unit 42 uses the minimum voltage as the voltage Vc of the DC capacitor 56 of each converter cell 52 to perform the determination in step S003 as an example. For example, the voltage Vc of the DC capacitor 56 of any converter cell 52 may be used, or the average value of the voltages Vc may be used. In such a case, from among the plurality of converter cells 52 included in the power converter 50, the voltage Vc of the DC capacitor 56 has reached the starting voltage level of the cell drive control unit 55, so that the semiconductor switching element 57a. , 57b are sequentially started.
In the determination in step 007, the average value is used for the voltage Vc of each converter cell 52, but the average value is not limited thereto.

The case where there is no AC power supply in the AC system 7 has been described above as an example, but the flow of the control operation when the AC power supply is provided will be described below.
In the case where the AC system 7 has an AC power supply, in step S010, the AC voltage determination unit 45 determines the magnitude and phase of the output AC voltage of the power converter 50 as the voltage level of the AC system 7 in operation. And make a comparison with the phase. Then, when the magnitude and phase of the output AC voltage are substantially equal to the magnitude and phase of the voltage of the AC system 7, the first opening / closing part 9 is closed by the first opening / closing part switching part 46 (step S011). Then, power transmission to the AC system 7 is started.
Thus, when the AC system 7 has an AC power supply, in step S010, the AC voltage determination unit 45 compares and determines the phase with the magnitude and phase of the voltage of the AC system 7 in addition to the magnitude of the output AC voltage.

  According to the power conversion device 100 of the present embodiment configured as described above, in the initial charging of the DC capacitor 56 in each converter cell 52 performed when the power converter 50 is started, the voltage Vc of the DC capacitor 56 is the cell. When the voltage for starting the drive control unit 55 is reached, the semiconductor switching elements 57a and 57b can be driven. Thereby, since the output of the AC voltage is started while charging the DC capacitor 56, the excitation of the transformer can be accelerated. Thereby, the starting time required for power transmission to the AC system 7 can be shortened.

In addition, since the DC capacitor 56 is initially charged using the power from the high-voltage DC power transmission network 1, it is not necessary to convert AC to DC, and power loss can be reduced. In addition, since an individual power source for initial charging is not required, cost reduction and size reduction of the power conversion device are possible.
In addition, since the opening and closing of the charging resistor 4 and the second opening / closing part 3 are controlled according to the voltage value of the DC capacitor 56, the inrush current during the initial charging can be suppressed.
In this way, it is possible to provide the power conversion device 100 that can be started up at high speed and has low loss while suppressing inrush current.
In addition, since the transformer 5 is gradually boosted by the output of the power converter 50, an inrush current to the transformer 5 can be prevented and the start-up of the transformer 5 can be stabilized.

Embodiment 2. FIG.
The second embodiment of the present invention will be described below with reference to the drawings, focusing on the differences from the first embodiment. The same parts as those in the first embodiment are denoted by the same reference numerals and the description thereof is omitted.
In power conversion device 100 of the present embodiment, the DUTY ratio of the DC voltage component included in command value 71 output from control device 70 is adjusted according to voltage Vc of DC capacitor 56.
Hereinafter, a case where the AC system 7 has an AC power source will be described as an example.

FIG. 7 is a diagram showing the relationship between the DC voltage DUTY ratio by the PWM control of converter cell 52 and the AC output possible range according to the second embodiment of the present invention.
FIG. 8 is a flowchart showing a control operation of the control device 70 and the cell drive control unit 55 according to the second embodiment of the present invention.
In the flowchart showing the control operation shown in FIG. 5 of the first embodiment, the operations from step S001 to step S003 are the same as those in the present embodiment, and the illustration of steps S001 to S003 is omitted for convenience. To do.

As in the first embodiment, the output AC voltage of power converter 50 is limited in its output possible range by the DUTY ratio of the DC voltage component included in command value 71.
In the initial charging of the DC capacitor 56, the DUTY ratio of the DC voltage component is set to 50% in the first embodiment, but is set to 25% in the present embodiment. The possible output range of the output AC voltage when the DUTY ratio of the DC voltage component is 25% is as shown in FIG. Compared with the case where the DUTY ratio of the DC voltage component shown in FIG. 6 is 50%, the output possible range becomes smaller.
The DUTY ratio of the DC voltage component does not need to be 25%, and may be smaller than 50% of the DUTY ratio capable of outputting 100% AC voltage when the voltage of the DC capacitor 56 is the rated voltage. .

Hereinafter, the operation after step S013 (semiconductor switching element firing) will be described.
The command generator 48 generates a command value 71 according to the voltage Vc of the DC capacitor 56, for example, an average value of the voltages Vc, and outputs the command value 71 to the cell drive controller 55 in each converter cell 52. As described above, the DUTY ratio of the DC voltage component included in the command value 71 is 25%.
When the series body 60 in the converter cell 52 is a bidirectional chopper circuit as in the present embodiment, the AC voltage component DUTY ratio is an AC voltage that can be output according to the value of the voltage Vc of the DC capacitor 56. Limited. For this reason, the DUTY ratio of the AC voltage component is gradually increased in accordance with the value of the voltage Vc of the DC capacitor.

Each cell drive control unit 55 receives the command value 71, and fires each semiconductor switching element 57a, 57b by the firing unit 31 based on the command value 71 and the voltage Vc of each DC capacitor 56 (step S013). The cell drive controller 55 switches the semiconductor switching elements 57a and 57b alternately at a DC voltage component DUTY ratio of 25% (step S014).
The power converter 50 converts the DC voltage smoothed by each DC capacitor 56 into an AC voltage including a DC component and outputs the AC voltage (step S015). Then, the transformer 5 is excited by this output AC voltage (step S016).

  Thus, by making the DUTY ratio of the DC voltage component of the command value 71 smaller than 50%, the DC voltage output from each converter cell 52 is lowered, and between the voltage of the high voltage DC transmission network 1. A differential voltage is generated, and as a result, the current flowing from the DC buses 6P and 6N increases. As a result, the time required for charging the DC capacitor 56 can be further shortened.

Next, in the voltage determination unit 42, the voltage Vc (average value) of the DC capacitor 56 in the converter cell 52 reaches the second reference voltage Vsc based on the rated capacitor voltage of the DC capacitor 56, and Vc ≧ Vsc. It is determined whether or not (step S017). In the present embodiment, the second reference voltage Vsc is set to a value near the rated voltage of the DC capacitor 56.
If the voltage Vc (average value) of the DC capacitor 56 is smaller than the second reference voltage Vsc, the process returns to step S014.
In step S017, when the voltage Vc (average value) of the DC capacitor 56 reaches the second reference voltage Vsc, the control device 70 causes the command generation unit 48 to output the DC voltage component of the command value 71 output to the cell drive control unit 55. The DUTY ratio is changed to 50% to release the AC voltage output restriction (step S018).

Thus, in the initial charging of the DC capacitor 56, first, the initial charging time is shortened by adjusting the DUTY ratio of the DC voltage component to be small so that the current supplied from the DC buses 6P and 6N increases. When the voltage Vc (average value) of the capacitor 56 reaches the vicinity of the rated voltage, the output AC voltage output possible range can be secured by increasing the DUTY ratio of the DC voltage component to 50%.
On the other hand, the DUTY ratio of the AC voltage component increases to the maximum when the voltage Vc (average value) of the DC capacitor 56 reaches around the rated voltage. As a result, the AC output voltage can be quickly increased to the rating.

The control flow after step S018 is the same as step S008 to step S012 in the case where the AC system 7 has an AC power source, as described in the first embodiment, and is shown below.
The control device 70 closes the second opening / closing unit 3 by the second opening / closing unit switching unit 43 and short-circuits both ends of the resistor 4 (step S008).
Next, the AC voltage monitoring unit 44 monitors the output AC voltage of the power converter 50 detected by the voltage detection unit 8 (step S009). The magnitude and phase of the output AC voltage through the transformer 5 of the power converter 50 are compared with the magnitude and phase of the voltage of the AC system 7 in operation (step S010), and the magnitude of the output AC voltage is compared. If the phase is not equal to that of the AC system 7, the process returns to step S009, and the output AC voltage of the power converter 50 is continuously monitored.
In step S010, when the magnitude and phase of the output AC voltage via the transformer 5 become substantially equal to the voltage and phase of the AC system 7, the first opening / closing unit 9 is closed by the first opening / closing unit switching unit 46. (Step S011), power transmission to the AC system 7 is started, and the power conversion apparatus 100 completes the activation process (step S012).

According to the power conversion device 100 of the present embodiment configured as described above, the same effects as those of the first embodiment can be obtained, and the power conversion device 100 that can be started up at high speed and has low loss while suppressing the inrush current. It becomes possible to provide.
Further, since the transformer 5 is gradually boosted by the output current of the power converter 50, an inrush current to the transformer 5 can be prevented, and the start-up of the transformer 5 can be stabilized.

Further, until the voltage Vc of the DC capacitor 56 reaches the rated voltage, the DUTY ratio of the DC component is adjusted to less than 50% so that the amount of current supplied from the DC buses 6P and 6N increases. The time required for charging 56 can be further reduced.
In addition, after the DC capacitor 56 reaches the rated voltage, the AC output voltage is quickly increased by changing the DUTY ratio of the DC voltage component of the command value 71 to 50% and changing the DUTY ratio of the AC voltage component to the maximum. It is possible to raise the rating.
In this way, it is possible to provide the power conversion device 100 that can be activated at higher speed.
In addition, although the said Embodiment 2 demonstrated as an example the case where the alternating current system 7 had alternating current power supply, it is applicable also when there is no alternating current power supply, and there exists the same effect.

Embodiment 3 FIG.
The third embodiment of the present invention will be described below with reference to the drawings focusing on the differences from the second embodiment. Portions similar to those in the second embodiment are given the same reference numerals, and description thereof is omitted.
FIG. 9 is a circuit configuration diagram of converter cell 352 in the power converter according to the third embodiment of the present invention.
In the power conversion apparatus 100 of the present embodiment, as shown in the figure, the converter cell 352 is a full bridge circuit. The converter cell 352 includes two series bodies 360 in which semiconductor switching elements 357a and 357b, to which diodes 359a and 359b are connected in antiparallel, are connected in series. Two series bodies 360 are connected in parallel to form a full bridge circuit, and a DC capacitor 356 is connected in parallel to the full bridge circuit.
Further, a cell drive control unit 355 that receives power supply from the DC capacitor 356 and controls driving of the semiconductor switching elements 357 a and 357 b is connected between the positive and negative terminals of the DC capacitor 356.

As in the second embodiment, when the DC capacitor 356 in each converter cell 352 is initially charged, the command generation unit 48 generates a command value 71 having a DC voltage component DUTY ratio of 25%, The cell drive controller 355 ignites each of the semiconductor switching elements 357a and 357b (see Embodiment 2, Steps S013 and S014).
FIG. 10 is a diagram showing the relationship between the DC voltage DUTY ratio by the PWM control of converter cell 352 according to Embodiment 3 of the present invention and the AC output possible range.
FIG. 10A is a diagram for outputting 100% AC voltage when the DUTY ratio of the DC voltage component is 50%, and FIG. 10B is a diagram for 100% AC voltage when the DUTY ratio of the DC voltage component is 25%. It is a figure to output.

The characteristics when the semiconductor switching elements 357a and 357b of the converter cell 352 are full bridge circuits as in the present embodiment will be described below.
First, as shown in FIG. 10, even when the DUTY ratio of the DC voltage component is less than 50%, it is possible to output 100% AC voltage.
Furthermore, even if the voltage Vc of the DC capacitor 356 is less than the rated voltage, the AC voltage can be output 100% by increasing the DUTY ratio of the AC voltage component as compared with the second embodiment.
For this reason, the minimum value of the voltage Vc of the DC capacitor 356 becomes the rated voltage, and the output AC voltage can be set to the rated voltage at the same time as changing the DUTY ratio of the DC voltage component to 50%.

  Thus, by making the converter cell 352 a full bridge circuit, the output AC voltage can be raised to the rated voltage in a shorter time than the converter cell 52 of the bidirectional chopper circuit according to the first and second embodiments. In addition, the control operation from step S009 to step S012 described in the first and second embodiments is further accelerated, and the time until the AC output is established is further shortened.

According to the power conversion device 100 of the present embodiment configured as described above, the same effect as that of the second embodiment can be obtained. The power conversion device 100 can be started up at high speed and has low loss while suppressing the inrush current. It becomes possible to provide.
Further, since the transformer 5 is gradually boosted by the output current of the power converter 50, an inrush current to the transformer 5 can be prevented, and the start-up of the transformer 5 can be stabilized.

Further, until the voltage Vc of the DC capacitor 356 reaches the rated voltage, the DUTY ratio of the DC component is adjusted to less than 50% so that the current supplied from the DC buses 6P and 6N increases, and the AC voltage By increasing the DUTY ratio of the component to the maximum, the initial charging time of the DC capacitor 356 is shortened, and the time from when the voltage Vc of the DC capacitor 356 reaches the rated voltage to the establishment of the AC voltage is shortened. Is possible.
In this way, it is possible to provide the power conversion device 100 that can be activated at higher speed.

  It should be noted that the present invention can be freely combined with each other within the scope of the invention, and each embodiment can be appropriately modified or omitted.

1 High-voltage DC transmission network, 2 3rd switching part, 2nd switching part, 4 resistor, 5 transformer, 6P, 6N DC bus, 7 AC system, 9 1st switching part, 31 starting part,
41 DC capacitor monitoring unit, 48 command generation unit, 50 power converter, 51 leg circuit, 52,352 converter cell, 53a positive side arm, 53b negative side arm,
55,355 Cell drive controller, 56,356 DC capacitor,
57a, 57b, 357a, 357b semiconductor switching element,
60, 360 series body, 70 control device, 71 command value, 100 power converter.

Claims (10)

A leg circuit in which a positive side arm and a negative side arm are connected in series is provided for each phase of AC, and the leg circuit of each phase is connected in parallel between positive and negative DC buses, and between AC and DC In a power conversion device including a power converter that performs power conversion and a control device,
Each of the positive arm and the negative arm of the leg circuit includes a converter cell including a series body of a plurality of semiconductor switching elements connected in series to each other and a DC capacitor connected in parallel to the series body. Or it is configured by connecting multiple series,
The converter cell is
A power supply is supplied from the DC capacitor in the converter cell to operate, and a cell drive control unit that drives and controls the semiconductor switching element based on a command value,
The control device
A DC capacitor monitoring unit for monitoring the voltage of the DC capacitor;
A command generator for generating the command value to the converter cell,
In the initial charging of the DC capacitor performed at the time of starting the power converter, when the voltage of the DC capacitor reaches a first reference voltage based on the starting voltage of the cell drive control unit, the command value is generated, and the cell the drive control unit drives the semiconductor switching elements in the converter cells,
The command generation unit generates the command value according to the voltage of the DC capacitor,
In the initial charging of the DC capacitor, the command generator adjusts the DUTY ratio of the DC voltage component of the command value, and when the voltage of the DC capacitor reaches a second reference voltage based on the rated voltage of the DC capacitor, A power conversion device characterized in that the DUTY ratio of the DC voltage component is 50% . The command generation unit adjusts a DUTY ratio of the DC voltage component to be less than 50% when the voltage of the DC capacitor is less than the second reference voltage during initial charging of the DC capacitor, The power converter according to claim 1 , wherein the current supplied from the bus is increased. The power converter according to claim 2 , wherein the command generation unit maximizes the DUTY ratio of the AC voltage component of the command value when the DUTY ratio of the DC voltage component is less than 50%. The cell drive control unit detects the voltage of the DC capacitor and transmits it to the control device, and controls the driving of the semiconductor switching element based on the voltage of the DC capacitor and the command value. The power converter device according to any one of claims 1 to 3 . The power converter is connected to an AC circuit through a transformer,
Between the transformer and the AC circuit, a first opening / closing unit that opens and closes an electric circuit is connected in series,
The control device, the power conversion device according to any one of claims 1 to 4, characterized in that for controlling the opening and closing of the first opening and closing unit based on the AC voltage the power converter output . In the initial charging of the DC capacitor, the control device opens the first opening and closing unit at the start of the initial charging, and when the output voltage through the transformer of the power converter becomes substantially equal to the AC circuit, The power converter according to claim 5 , wherein the first opening / closing part is closed. The DC bus of the power converter is connected to a DC circuit via a resistor,
A second opening / closing part that short-circuits both ends of the resistor is connected in parallel to the resistor,
In the initial charging of the DC capacitor, the control device opens the second switching unit at the start of the initial charging, and supplies the DC current from the DC circuit to the power converter via the resistor. ,
When the voltage of the DC capacitor reaches the second reference voltage, the second switching unit is closed, and a DC current from the DC circuit is supplied to the power converter through the second switching unit. power converter according to any one of claims 1 to 3, characterized. The power converter according to any one of claims 1 to 7 , wherein the converter cell is a full bridge circuit having two serial bodies. Between the resistor and the DC circuit, a third open / close unit that opens and closes the electric circuit is connected in series,
The power converter according to claim 7 , wherein the control device closes the third opening / closing part at the start of the initial charging in the initial charging of the DC capacitor. A leg circuit in which a positive side arm and a negative side arm are connected in series is provided for each phase of AC, and the leg circuit of each phase is connected in parallel between positive and negative DC buses, and between AC and DC In a power conversion device including a power converter that performs power conversion and a control device,
Each of the positive arm and the negative arm of the leg circuit includes a converter cell including a series body of a plurality of semiconductor switching elements connected in series to each other and a DC capacitor connected in parallel to the series body. Or it is configured by connecting multiple series,
The converter cell is
A power supply is supplied from the DC capacitor in the converter cell to operate, and a cell drive control unit that drives and controls the semiconductor switching element based on a command value,
The control device
A DC capacitor monitoring unit for monitoring the voltage of the DC capacitor;
A command generator for generating the command value to the converter cell,
In the initial charging of the DC capacitor performed at the time of starting the power converter, when the voltage of the DC capacitor reaches a first reference voltage based on the starting voltage of the cell drive control unit, the command value is generated, and the cell the drive control unit drives the semiconductor switching elements in the converter cells,
The control device generates the command value and generates the command value when the minimum voltage of the DC capacitors included in the converter cell reaches the first reference voltage, and the semiconductor switching element in the converter cell. The power converter device characterized by driving .

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