JP6151649B2 - Power conversion device and power conversion method - Google Patents

Description

  The present invention relates to a power conversion device and a power conversion method used in combination with a plurality of distributed power sources.

  In recent years, a system in which a distributed power source is provided to a consumer and electric power is supplied from the distributed power source in connection with the system is becoming widespread. As the distributed power source, a fuel cell device, a solar power generation device, a storage battery, and the like are used.

  2. Description of the Related Art Conventionally, a distributed power supply generally has a configuration having an inverter inside, and a DC (direct current) voltage is converted into an AC (alternating current) voltage by the inverter. For example, Patent Document 1 describes a configuration of a fuel cell device having an inverter. Therefore, when a plurality of distributed power sources are used in an integrated manner, a configuration in which a DC voltage is converted into an AC voltage in each distributed power source and then integrated with the AC voltage is common.

JP-A-7-123609

  Conventionally, it is common to integrate a plurality of distributed power sources with the above-described configuration, but it is desired to reduce redundancy and integrate a plurality of distributed power sources to a higher degree.

  Therefore, the objective of this invention made | formed in view of this point is to provide the power converter device and power conversion method which can reduce redundancy and can integrate a some distributed power supply more highly.

  In order to solve the above problems, a power converter according to the present invention is a power converter used in combination with at least one power generator and at least one storage battery, and is a first DC supplied from the power generator. A first DC / DC converter capable of boosting a voltage to a DC link voltage; a second DC / DC converter capable of stepping down the DC link voltage to a second DC voltage and supplying the same to a storage battery; And a control unit that controls the first and second DC / DC converters, and when the control unit is in a charging mode in which the storage battery is charged after being disconnected from the grid, the first DC voltage and the second DC / DC converter are controlled. Based on the magnitude relationship of the DC voltage, only the step-up operation by the first DC / DC converter or the step-down operation by the second DC / DC converter may be executed. The features.

  The power converter according to the present invention further includes an inverter in which both the first DC / DC converter and the second DC / DC converter are connected, and the output from each can be collectively converted. It is preferable that grid connection is possible via the inverter.

  Further, in the power conversion device according to the present invention, the control unit does not cause the first DC / DC converter to perform a boost operation when the first DC voltage is higher than the second DC voltage. The step-down operation is preferably performed by the second DC / DC converter.

  Further, in the power conversion device according to the present invention, when the first DC voltage is lower than the second DC voltage, the control unit causes the first DC / DC converter to perform a boosting operation, and It is preferable that the second DC / DC converter not perform the step-down operation.

  In the power converter according to the present invention, the first DC / DC converter includes a first switch for switching whether or not to ground one end of the choke coil, and the second DC / DC converter includes the first DC / DC converter. A second switch coupled in series with the choke coil is provided between the input and output of the DC / DC converter, and when the control unit does not cause the first DC / DC converter to perform a boosting operation, the first switch It is preferable that the switch is always turned off, and the control unit always turns on the second switch when the second DC / DC converter does not perform the step-down operation.

  In the power converter according to the present invention, the first relay disposed in parallel with the first DC / DC converter and the second relay disposed in parallel with the second DC / DC converter. A relay, and when the control unit does not cause the first DC / DC converter to perform a boosting operation, the control unit turns on the first relay to bypass the first DC / DC converter. Preferably, the unit bypasses the second DC / DC converter by turning on the second relay when the second DC / DC converter does not perform the step-down operation.

  Further, in the power conversion device according to the present invention, the power generation device that supplies the first DC voltage to the first DC / DC converter is a solar power generation device, and the control unit includes the first DC / DC converter. When the DC converter is not caused to perform the boosting operation, it is preferable to perform control so that the second DC / DC converter performs MPPT control.

  Further, in the power conversion device according to the present invention, when the control unit does not cause the second DC / DC converter to perform a step-down operation, the first DC / DC converter causes the constant current control or constant voltage of the storage battery to be performed. It is preferable to execute the control.

  Moreover, the power converter device which concerns on this invention WHEREIN: It is preferable that the said control part determines whether the said MPPT control is performed according to the electric power generation condition of the said solar power generation device, and the charging condition of the said storage battery.

  In order to solve the above problem, a power conversion method according to the present invention includes a first DC / DC converter capable of boosting a first DC voltage supplied from a power generation device to a DC link voltage, and the DC link voltage. A power conversion method in a power conversion device including a second DC / DC converter capable of supplying the storage battery with a second DC / DC converter that can be stepped down to a second DC voltage, and disconnecting the power conversion device from a system; Based on the magnitude relationship between the first DC voltage and the second DC voltage, only one of the step-up operation by the first DC / DC converter and the step-down operation by the second DC / DC converter is performed. And the step of executing.

  According to the present invention, redundancy can be reduced and a plurality of distributed power sources can be more highly integrated.

It is a block diagram showing a schematic structure of a power conversion system concerning a 1st embodiment of the present invention. It is a figure explaining operation | movement of the power converter device which concerns on 1st Embodiment of this invention. It is a figure explaining operation | movement of the power converter device which concerns on 2nd Embodiment of this invention.

  Hereinafter, embodiments according to the present invention will be described with reference to the drawings.

[First Embodiment]
FIG. 1 is a block diagram showing a schematic configuration of a power conversion system 100 according to the first embodiment of the present invention. As shown in FIG. 1, the power conversion system 100 includes a power conversion device 10, a solar power generation device 30, a fuel cell device 40, and a storage battery 50. In the present embodiment, the configuration in which the solar power generation device, the fuel cell device, and the storage battery are combined with the power conversion device 10 one by one will be described as an example, but this is only an example. The number of these distributed power sources can be any number. Moreover, the kind of power generation device is not limited to a solar power generation device or a fuel cell device, but can be various power generation devices.

  The power conversion device 10 includes a plurality of DC / DC converters 11, a link capacitor 12, an inverter 13, an interconnection relay 14, and a control unit 15.

  In the configuration of the power conversion device 10 shown in FIG. 1, various control modes are conceivable. As one of them, the power conversion device 10 is disconnected from the system 60 and the solar power generation device 30 and the fuel cell device 40 A mode in which all the generated power is charged in the storage battery 50 (hereinafter referred to as “charging mode”) is also conceivable. In the charging mode, it is preferable to charge the storage battery 50 efficiently. The present invention is particularly aimed at improving the charging efficiency of the storage battery 50 in the charging mode.

  Each DC / DC converter 11 boosts and integrates the DC voltage input from each distributed power supply to an appropriate DC voltage. A node in which the boosted DC voltage is integrated is hereinafter referred to as a “DC link”. In the example illustrated in FIG. 1, the DC / DC converters 11-1, 11-2, and 11-3 are connected to the solar power generation device 30, the fuel cell device 40, and the storage battery 50, respectively.

  The DC / DC converter 11-3 connected to the storage battery 50 is a bidirectional DC / DC converter. When the storage battery 50 is charged, the DC / DC converter 11-3 steps down the DC voltage in the DC link to a voltage suitable for charging the storage battery 50 and charges the storage battery 50. At this time, the control unit 15 can charge the storage battery 50 by controlling the DC / DC converter 11-3 by constant current control (CC control) or constant voltage control (CV control).

  Further, the DC / DC converters 11-1 to 11-3 can be operated in a mode in which the step-up or step-down operation is not executed. For example, when the DC / DC converter 11-1 is executed in a mode that does not perform boosting, the DC / DC converter 11-1 uses the DC link supplied from the solar power generation device 30 with a substantially unchanged voltage as a DC link. Output to. For example, when the DC / DC converter 11-3 is operated in a mode that does not perform step-down, the DC / DC converter 11-3 supplies the voltage of the DC link to the storage battery 50 with almost the same voltage. The technical meaning of operating the DC / DC converter 11 in a mode in which the step-up or step-down operation is not performed, and in which case the mode is operated in this mode will be described later.

  The link capacitor 12 smoothes and stabilizes the DC link voltage. A capacitor for stabilizing the voltage of the DC link may be further provided in each DC / DC converter 11.

  The inverter 13 converts the DC voltage in the DC link into an AC voltage. Further, the AC voltage supplied from the system 60 can be converted into a DC voltage.

  The interconnection relay 14 switches the connection state between the inverter 13 and the system 60. That is, the interconnection relay 14 switches whether the power conversion device 10 is connected to the system 60 or disconnected from the system 60. The power converter 10 is normally connected to the grid 60, but is disconnected from the grid 60 in the charging mode.

  When the power converter 10 is connected to the grid 60, the DC link voltage is higher than the peak-to-peak (Peak to Peak) value of the AC voltage of the grid 60 in order to realize stable interconnection. Must be held at voltage. However, in the charging mode, when the power conversion device 10 is disconnected from the grid 60, it is not necessary to maintain the DC link voltage at a voltage higher than the peak-to-peak value of the AC voltage of the grid 60. . Therefore, the voltage of the DC link can be any voltage that allows the DC / DC converter 11 to operate efficiently.

  The control unit 15 controls and manages the entire power conversion apparatus 10 and can be configured by, for example, a processor. The control performed by the control unit 15 will be further described later.

  The solar power generation device 30 can generate power using sunlight. The solar power generation device 30 includes a solar battery, and directly converts sunlight energy into electric power.

  The fuel cell device 40 generates electric power by a fuel cell that causes an electrochemical reaction of gas such as hydrogen and oxygen supplied from the outside.

  The storage battery 50 can supply electric power by discharging the charged electric power. Moreover, the storage battery 50 can also charge the electric power supplied from the system | strain 60, the solar power generation device 30, or the fuel cell apparatus 40 grade | etc.,. Moreover, the electric power discharged from the storage battery 50 can also be supplied from the power converter 10 to various loads that consume electric power.

(Operation in charge mode)
Hereinafter, in the charging mode, the operation when the power conversion device 10 is disconnected from the grid 60 and the storage battery 50 is charged will be described. As an example, the case where the storage battery 50 is charged with the electric power generated by the solar power generation device 30 will be described.

  As shown in FIG. 1, the power conversion system 100 according to the first embodiment of the present invention includes an inverter for performing DC / AC conversion in the solar power generation device 30, the fuel cell device 40, and the storage battery 50. It is not a configuration. Therefore, for example, when the storage battery 50 is charged with the power generated by the solar power generation device 30, it is not necessary to AC / DC convert the DC / AC converted voltage again and charge it. That is, the storage battery 50 can be charged by the DC power generated by the solar power generation device 30 without being converted into an AC voltage via the DC / DC converter 11-1 and the DC / DC converter 11-3. Therefore, the storage battery 50 can be charged very efficiently.

  Further, in the power conversion system 100 according to the first embodiment of the present invention, in the charging mode, the control unit 15 turns off the interconnection relay 14 and disconnects the power conversion device 10 from the system 60, so that the DC link It is no longer necessary to maintain the voltage at a predetermined high voltage. Therefore, it is not necessary for the DC / DC converter 11-1 to boost the DC voltage of the power generated by the solar power generation device 30 to a predetermined high voltage.

  In this case, since the voltage of the DC link can be an arbitrary voltage, only one of the DC / DC converter 11-1 and the DC / DC converter 11-3 is operated, and the solar power generator 30 and the storage battery 50 are connected. The storage battery 50 can be charged more efficiently by setting the number of stages of the DC converter that operates at 1 to one.

  With reference to FIG. 2, an operation when only one of the DC / DC converter 11-1 and the DC / DC converter 11-3 is operated and the other is not operated will be described. FIG. 2 shows a part of the step-up circuit for the DC / DC converter 11-1 and part of the step-down circuit for the DC / DC converter 11-3. Moreover, in FIG. 2, the description of the fuel cell device 40 and the DC / DC converter 11-2 is omitted.

  The DC / DC converter 11-1 includes a choke coil 111, a diode 112, and a switch 113 that switches whether one end of the choke coil 111 is grounded as a boosting circuit. The switch 113 is a semiconductor transistor such as an FET (Field Effect Transistor). The control unit 15 periodically turns on / off the switch 113 to cause the DC / DC converter 11-1 to perform a boosting operation and boost the DC voltage supplied from the solar power generation device 30 to the DC link voltage. be able to.

  When the DC / DC converter 11-1 is not allowed to perform the boosting operation, the control unit 15 always turns off the switch 113.

  The DC / DC converter 11-3 includes a choke coil 114, a diode 115, and a switch 116 coupled in series with the choke coil 114 between the input and output of the DC / DC converter 11-3 as a step-down circuit. . The switch 116 is a semiconductor transistor such as an FET. The control unit 15 periodically turns on / off the switch 116 to cause the DC / DC converter 11-3 to perform a step-down operation, step down the voltage of the DC link, supply it to the storage battery 50, and charge the storage battery 50. can do.

  When not causing the DC / DC converter 11-3 to perform the step-down operation, the control unit 15 always turns on the switch 116.

  The control unit 15 can acquire information on the voltage across the DC / DC converter 11 from the DC / DC converter 11. The control unit 15 acquires information on the DC voltage of the power generated by the solar power generation device 30 from the DC / DC converter 11-1, and compares the DC voltage with a charging voltage for charging the storage battery 50.

  When the DC voltage of the electric power generated by the solar power generation device 30 is higher than the charging voltage of the storage battery 50, the control unit 15 executes only the step-down operation of the DC / DC converter 11-3 connected to the storage battery 50, The step-up operation of the DC / DC converter 11-1 connected to the photovoltaic device 30 is not executed.

  In addition, when the DC voltage of the electric power generated by the solar power generation device 30 is lower than the charging voltage of the storage battery 50, the control unit 15 performs only the boosting operation of the DC / DC converter 11-1 connected to the solar power generation device 30. The step-down operation of the DC / DC converter 11-3 connected to the storage battery 50 is not executed.

  Normally, the control unit 15 performs MPPT (Maximum Power Point Tracking) control on the DC / DC converter 11-1 connected to the solar power generation device 30 in order to extract the maximum power from the solar power generation device 30. However, when the DC voltage of the electric power generated by the solar power generation device 30 is higher than the charging voltage of the storage battery 50 and the DC / DC converter 11-1 does not perform the boosting operation, the DC / DC converter 11-3 performs MPPT control. It can also be controlled to execute.

  Moreover, the control part 15 is the DC / DC converter 11 when DC voltage of the electric power generated by the solar power generation device 30 is lower than the charging voltage of the storage battery 50 and the DC / DC converter 11-3 does not perform the step-down operation. It is also possible to perform control so that CC control or CV control is executed by -1.

  Moreover, the control part 15 compares the electric power of charge control with respect to the storage battery 50, such as CC control and CV control, and the maximum generated electric power by MPPT control of the solar power generation device 30, and determines whether to perform MPPT control. You can also.

  For example, when the maximum generated power by the MPPT control is larger than the power for the charging control, the control unit 15 performs the power generation of the solar power generation device 30 at the point of the power necessary for the charging control without performing the MPPT control, and MPPT When the maximum generated power by the control is smaller than the power of the charging control, MPPT control may be performed to charge the storage battery 50 using all the maximum power that can be generated by the solar power generation device 30.

[Second Embodiment]
FIG. 3 is a diagram for explaining the operation of the power conversion device 20 according to the second embodiment of the present invention. The power conversion device 20 according to the second embodiment is arranged in parallel with the relay 16 arranged in parallel with the input / output end of the DC / DC converter 11-1 and in parallel with the input / output end of the DC / DC converter 11-3. It differs from the power converter device 10 which concerns on 1st Embodiment by a point provided with the relay 17. FIG. As in FIG. 2, the fuel cell device 40 and the DC / DC converter 11-2 are not shown.

  The second embodiment is different from the first embodiment in the control when the DC / DC converter 11-1 does not execute the step-up operation and the control when the DC / DC converter 11-3 does not execute the step-down operation.

  When not causing the DC / DC converter 11-1 to perform the boosting operation, the control unit 15 turns on the relay 16 to bypass the input / output of the DC / DC converter 11-1. Further, when the DC / DC converter 11-3 is not allowed to perform the step-down operation, the control unit 15 turns on the relay 17 to bypass the input / output of the DC / DC converter 11-3.

  Thus, according to the embodiment of the present invention, the power conversion device 10 includes the first DC / DC converter 11-1 that receives supply of DC voltage from the power generation device, and the second that supplies DC voltage to the storage battery. The configuration includes the DC / DC converter 11-3, and a plurality of distributed power sources can be integrated more highly. Further, since the interconnection relay 14 disconnects the power conversion device 10 from the system 60 and sets the charging mode, it is not necessary to maintain the DC link voltage at a high voltage considering the interconnection with the system 60. The link voltage can be lowered to a voltage suitable for charging the storage battery 50, and the charging efficiency of the storage battery 50 can be improved. Further, in the charging mode, the control unit 15 performs only one of the step-up operation of the first DC / DC converter 11-1 and the step-down operation of the second DC / DC converter 11-3, thereby converting the voltage. The DC / DC converter that performs the operation can be made one stage, and the charging efficiency of the storage battery 50 can be improved.

  Also, a first relay 16 arranged in parallel with the first DC / DC converter 11-1 and a second relay 17 arranged in parallel with the second DC / DC converter 11-3 are provided. When the control unit 15 does not cause the first DC / DC converter 11-1 to perform the step-up operation, the first relay 16 is turned on to bypass the first DC / DC converter 11-1, and the second When the DC / DC converter 11-3 is not to perform the step-down operation, the second relay 17 is turned on to bypass the second DC / DC converter 11-3, and the DC / DC converter 11-1 and Since the loss due to the choke coil or the switch 11-3 can be reduced, the charging efficiency of the storage battery 50 can be further improved.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention.

DESCRIPTION OF SYMBOLS 10 Power converter 11 DC / DC converter 12 Link capacitor 13 Inverter 14 Linkage relay 15 Control part 16 Relay 17 Relay 20 Power converter 30 Solar power generation device 40 Fuel cell apparatus 50 Storage battery 60 System 100 Power conversion system 111 Choke coil 112 Diode 113 switch 114 Choke coil 115 Diode 116 switch

Claims (10)

A power conversion device used in combination with at least one power generation device and at least one storage battery,
A first DC / DC converter capable of boosting the first DC voltage supplied from the power generation device to a DC link voltage;
A second DC / DC converter capable of stepping down the DC link voltage to a second DC voltage and supplying it to a storage battery;
A controller for controlling the first and second DC / DC converters,
When the control unit is in a charging mode in which the storage battery is disconnected from the grid, the first DC / DC converter is based on a magnitude relationship between the first DC voltage and the second DC voltage. A power conversion device that executes only one of the step-up operation by the second step and the step-down operation by the second DC / DC converter. The power converter according to claim 1, further comprising: an inverter to which both the first DC / DC converter and the second DC / DC converter are connected and capable of collectively converting outputs from each. ,
A power conversion device capable of system interconnection via the inverter.   3. The power conversion device according to claim 1, wherein when the first DC voltage is higher than the second DC voltage, the control unit performs a boosting operation on the first DC / DC converter. Without causing the second DC / DC converter to perform a step-down operation.   4. The power conversion device according to claim 1, wherein when the first DC voltage is lower than the second DC voltage, the control unit supplies the first DC / DC converter with the first DC voltage. A power conversion device, wherein a step-up operation is performed and the second DC / DC converter is not allowed to perform a step-down operation. In the power converter according to any one of claims 1 to 4,
The first DC / DC converter includes a first switch for switching whether to ground one end of the choke coil,
The second DC / DC converter includes a second switch coupled in series with the choke coil between the input and output of the DC / DC converter,
The control unit always turns off the first switch when the first DC / DC converter does not perform a boosting operation.
The control unit always turns on the second switch when the second DC / DC converter does not perform the step-down operation. In the power converter according to any one of claims 1 to 4, further,
A first relay disposed in parallel with the first DC / DC converter;
A second relay disposed in parallel with the second DC / DC converter,
When the control unit does not cause the first DC / DC converter to perform a boost operation, the control unit turns on the first relay to bypass the first DC / DC converter;
The control unit turns on the second relay to bypass the second DC / DC converter when the second DC / DC converter does not perform the step-down operation. . In the power converter according to any one of claims 1 to 6,
The power generator that supplies the first DC voltage to the first DC / DC converter is a solar power generator,
The control unit controls the second DC / DC converter to perform MPPT control when the first DC / DC converter does not perform the step-up operation.   8. The power conversion device according to claim 1, wherein the control unit causes the first DC / DC converter to store the storage battery when the second DC / DC converter does not perform a step-down operation. 9. A power converter that performs constant current control or constant voltage control.   The power conversion device according to claim 7, wherein the control unit determines whether to execute the MPPT control according to a power generation state of the photovoltaic power generation device and a charging state of the storage battery. Power converter. A first DC / DC converter capable of boosting the first DC voltage supplied from the power generation device to a DC link voltage; and a second DC / DC converter capable of stepping down the DC link voltage to a second DC voltage and supplying the second DC voltage to the storage battery. A power conversion method in a power conversion device comprising the DC / DC converter of
Disconnecting the power converter from the grid;
Based on the magnitude relationship between the first DC voltage and the second DC voltage, only one of the step-up operation by the first DC / DC converter and the step-down operation by the second DC / DC converter is performed. And a step of executing the power conversion method.

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