JP5050718B2 - Power conversion device and power conversion control method - Google Patents

Description

  The present invention relates to a power conversion device and a power conversion control method, and more particularly to a power conversion device and a power conversion control method for preventing fluctuations in power supplied to a load device even when an abnormality occurs in power supply by a power source. .

A power conversion device is widely used as a device that protects a device by supplying a certain amount of power to the device regardless of a power failure such as a power failure, a momentary power failure, or a brownout. A power supply device equipped with such a power conversion device is also called an uninterruptible power supply device because it supplies power to a device even if a power failure occurs.
FIG. 7 is a diagram illustrating a general power converter. The illustrated power conversion device keeps the power supplied from the AC power source 1 to the load device 4 constant. The power converter includes a converter circuit (forward converter) 2 that converts electric power supplied from an AC power source into a DC voltage, an inverter circuit (inverse converter circuit) 3 that converts the converted DC voltage into a predetermined AC voltage, AC A secondary battery 6 is provided to supply power to the load device 4 when power supply by the power source 1 is stopped.

Further, in the illustrated power converter, a DC / DC converter circuit such as a bidirectional chopper circuit 33 is connected to the DC unit 11 between the converter 2 and the inverter 3. The bidirectional chopper circuit 33 is provided for optimizing the operation of the secondary battery 6.
In the conventional power conversion device, a lead storage battery or the like has been used as the secondary battery 6, but in recent years, an electric double layer capacitor (EDLC) is used instead of the secondary battery 6. is there. An EDLC is an electricity storage device that has the advantages of high charge / discharge efficiency, short charge / discharge time, and long cycle life.

However, EDLC has a drawback that its energy density is smaller than that of a lead battery or a lithium battery. For example, Patent Literature 1 and Patent Literature 2 can be cited as conventional techniques for compensating for such a defect. The power control device described in Patent Document 1 is provided with a secondary battery and an EDLC in parallel, and supplies power from the EDLC to the load device immediately after the occurrence of a power failure. Thereafter, the power supply source is switched to the secondary battery.
According to such Patent Document 1, it is possible to immediately respond to a sudden change in the power supplied by the power source 1, and thereafter stably supply power to the load device.

Patent Document 2 describes a hybrid fuel system using a secondary battery and EDLC in combination. In this system, when power consumption increases instantaneously, power is supplied by EDLC, and the current discharged from the secondary battery is limited. According to such Patent Document 2, it is possible to prevent the life of the secondary battery from being reduced and to cope with a rapid change in power consumption.
JP 2002-34179 A JP 2002-110210 A

However, in Patent Document 1 and Patent Document 2 described above, the secondary battery and the ELDC are charged via the converter circuit after the power is restored from the power failure. For this reason, in addition to the current supplied to the load device, a charging current for a power storage device such as a secondary battery or ELDC flows into the converter circuit.
In a power conversion device provided with only a secondary battery, the maximum charging current of the secondary battery is generally about 10% of the rated current that can be passed through the converter circuit, so that it can be charged within the design margin. . However, in order to realize high-speed charging, which is a feature of EDLC, it is necessary to flow more current than can be passed through a converter circuit provided in a power conversion device including only a secondary battery. For this reason, in order to provide EDLC in a power converter in a prior art, it may be necessary to change the current rating of a converter circuit and to make a converter circuit larger.
The present invention has been made in view of the above points, and provides a power conversion device that can use an EDLC without changing the current rating of a converter circuit. It is an object to be able to cope with a change in supply current.

  In order to solve the above problems, a power conversion device according to claim 1 of the present invention includes a forward converter that converts alternating current power supplied from an alternating current power source into direct current power, and a direct current that is converted by the forward converter. An inverter that converts power into AC power of a desired frequency, a first power storage unit that is connected to a DC unit that connects the forward converter and the inverter in series, and a DC unit that is connected A second power storage unit that can be charged and discharged faster than the first power storage unit, and during normal operation, the AC power supply supplies power to the load device via the forward converter and the reverse converter, When an abnormality occurs in the AC power source, the second power storage unit supplies power to the load device with priority over the first power storage unit, and when the AC power source returns, the second power storage unit supplies the power to the load device. 2 of storage unit After electrodeposition, wherein the AC power supply to charge the first power storage unit through the forward converter.

  The power conversion device according to claim 2 of the present invention is the power conversion device according to claim 1, wherein the first power storage unit includes a first power storage device and a voltage value of DC power supplied from the first power storage device. A first DC / DC converter circuit for converting the second power storage unit, the second power storage unit being capable of charging / discharging at a higher speed than the first power storage device, and the DC power supplied from the second power storage device. A second DC / DC converter circuit for converting a voltage value is provided.

Power converter according to claim 3 of the present invention includes a first order converter for converting AC power supplied from an AC power supply into DC power, the DC power converted by said first forward converter An inverter that converts AC power of a desired frequency, and a first storage unit and a second storage unit that have a DC output connected to a DC unit that connects the forward converter and the inverse converter in series. The first power storage unit is configured to supply power from a first power storage device and a second forward converter that is different from the first forward converter from the AC power source. A first charging unit that charges one power storage device; and a first discharge unit that discharges the first power storage device charged by the first charging unit, wherein the second power storage unit includes the first power storage device. Can charge and discharge faster than And 2 electricity storage device, a second charging means for charging said second power storage device to supply electric power by another third forward converter and the first forward converter from the AC power source, the second charge Second discharging means for discharging the second power storage device charged by the means, and during normal operation, the AC power supply supplies power to the load device via the first forward converter and the reverse converter. And the first power storage device is charged via the first charging means and the second power storage device is charged via the second charging means. The charging unit and the second charging unit respectively stop charging, and the second discharging unit supplies power from the second power storage device to the load device with priority over the first discharging unit, and the AC power source When I returned The AC power supply is characterized by charging each said first storage device via the first charging means, said second storage device via the second charging means.

The power conversion device according to claim 4 of the present invention is the power conversion device according to claim 3, wherein the second discharging means has a charging function of charging the second power storage device, and the AC power supply is restored. After the second discharging means supplies power from the first electricity storage device to the second electricity storage device via the first discharge means to charge the second electricity storage device to a predetermined voltage level, the AC power supply Charging the first power storage device through the first charging means and charging the second power storage device through the second charging means.
The power conversion device according to claim 5 of the present invention is the power conversion device according to any one of claims 2 to 4, wherein the first power storage device has a capacity greater than that of the second power storage device. The second power storage device is a power storage device having a longer cycle life than the first power storage device.

  A power conversion control method according to claim 6 of the present invention includes a forward converter that converts alternating current power supplied from an alternating current power source into direct current power, and direct current power converted by the forward converter with alternating current having a desired frequency. More than the 1st electrical storage unit connected to the direct-current part which connects the reverse converter which converts into electric power, the forward converter and the inverse converter in series, and the direct-current part connected to the direct-current part In a power conversion control method applied to a power conversion device having a second power storage unit that can be charged and discharged at high speed, during normal operation of the AC power supply, the AC power supply is connected via the forward converter and the reverse converter. A normal control process for supplying power to the load device, and if an abnormality occurs in the AC power supply during the normal control process, power is supplied from the second power storage unit to the load device in preference to the first power storage unit. You When the AC power source is restored from the abnormality control step and the abnormality control step, the AC power source is connected to the first power storage unit via the forward converter after the second power storage unit is charged by the first power storage unit. And a return control step of charging.

According to a seventh aspect of the present invention, there is provided a power conversion control method comprising: a first forward converter that converts alternating current power supplied from an alternating current power source into direct current power; and the direct current power converted by the forward converter in a desired manner. and inverse converter for converting the AC power of a frequency, the first forward converter and the inverter is connected to a DC portion connected in series, a first power storage device from the AC power source the first First charging means for charging the first power storage device by supplying power by a second forward converter different from the forward converter, and discharging the first power storage device charged by the first charging means. A first power storage unit comprising: a first discharge means; a second power storage device capable of charging and discharging at a higher speed than the first power storage device; and a third separate from the AC power source to the first forward converter. the supplied power by the forward converter A power conversion apparatus comprising: a second power storage unit comprising: a second charging unit that charges the second power storage device; and a second discharge unit that discharges the second power storage device charged by the second charging unit. The power conversion control method is applied, wherein the AC power supply supplies power to the load device via the first forward converter and the reverse converter, and the first charging means via the first charging means. an electricity storage device, and the normal control process of charging each said second power storage device through the second charging means, when an abnormality in the AC power supply in the normal control process is generated, the first charging means and said second An abnormality control step in which the second charging unit stops charging, and the second discharging unit supplies power from the second power storage device to the load device with priority over the first discharging unit; If the AC power supply in the control process is returned, carriage return the AC power supply Charge the respective said first power storage device via the first charging means, said second storage device via the second charging means And a control step.

  According to the first aspect of the present invention, when the AC power supply is operating normally, power is supplied to the load device via the forward converter and the reverse converter, and when an abnormality occurs in the AC power supply, the second power storage When power is supplied to the load device by the unit and the AC power supply is restored, the AC power supply charges the first power storage unit via the forward converter after the second power storage unit is charged by the first power storage unit. Can do. For this reason, since a 2nd electrical storage unit can be charged at high speed without going through a forward converter, the structure of the same current rating as a 1st electrical storage unit can be applied to a 2nd electrical storage unit.

Therefore, the invention according to claim 1 is a power conversion device that can use the second power storage unit that can charge and discharge faster than the first power storage unit without changing the current rating of the forward converter (converter circuit). Can provide. Such a power converter can cope with a sudden change in supply current without increasing the circuit configuration.
According to the second aspect of the present invention, the first power storage unit capable of controlling the discharge voltage and the second power storage unit capable of charging and discharging at a higher speed than the first power storage unit and the discharge voltage being controllable are relatively simple. It can be realized by the configuration.

  According to the third aspect of the present invention, the first charging means for charging the first power storage device by supplying power from the AC power source without going through the forward converter, and the power from the AC power source without going through the forward converter. The second charging means for supplying and charging the second power storage device eliminates the need to supply current for charging the first power storage device and the second power storage device from the forward converter. For this reason, the power converter device which can charge a 2nd electrical storage device at high speed, without changing the current rating of a forward converter can be provided.

According to the invention described in claim 4, since the second discharging means has a charging function for charging the second power storage device, it is necessary to supply a current for charging the second power storage device from the second charging means. Disappear. Therefore, it is possible to provide a power converter that can charge the second power storage device at high speed without changing not only the forward converter but also the current rating of the second charging means.
According to the fifth aspect of the present invention, since the first power storage device has a larger capacity than the second power storage device, the first power storage device can stably supply power to the load device. In addition, since the second power storage device used for power supply with priority has a longer cycle life than the first power storage device, the first power storage device having a shorter cycle life can be extended.

  According to the sixth aspect of the present invention, when the AC power supply operates normally, power is supplied to the load device via the forward converter and the reverse converter, and when an abnormality occurs in the AC power supply, the second power storage When power is supplied to the load device by the unit and the AC power supply is restored, the AC power supply charges the first power storage unit via the forward converter after the second power storage unit is charged by the first power storage unit. Can do. For this reason, since a 2nd electrical storage unit can be charged at high speed without going through a forward converter, the structure of the same current rating as a 1st electrical storage unit can be applied to a 2nd electrical storage unit.

  According to the seventh aspect of the invention, when the AC power supply is operating normally, the AC power supply supplies power to the load device via the forward converter and the reverse converter, and the first power storage device is supplied via the first charging means. The second power storage device is charged via the second charging means, and when an abnormality occurs in the AC power supply, the first charging means and the second charging means stop charging, and the second discharging means When power is supplied from the second power storage device to the load device preferentially over the first discharging means, and the AC power is restored, the AC power supplies the first power storage device via the first charging means and the second charging means. The second power storage device can be charged via each. For this reason, since a 2nd electrical storage unit can be charged at high speed without going through a forward converter, the structure of the same current rating as a 1st electrical storage unit can be applied to a 2nd electrical storage unit.

Embodiments 1 to 3 according to the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram for explaining the configuration of the power conversion apparatus according to the first embodiment. In the first embodiment, the illustrated power conversion device is applied to an uninterruptible power supply.
The power conversion device is a converter 2 that is a forward converter that converts AC power supplied from the AC power supply 1 into DC power, and an inverse converter that converts DC power converted by the converter 2 into desired AC power. And an inverter 3. The converter 2 and the inverter 3 are connected in series, and a portion where the converter 2 and the inverter 3 are connected is defined as a DC unit 11. The DC unit 11 is connected to a first power storage unit 9 and a second power storage unit 10 that can be charged and discharged faster than the first power storage unit 9.

Furthermore, the power conversion device of the first embodiment includes a control circuit 12 that controls the converter 2, the inverter 3, the first power storage unit 9, and the second power storage unit 10. The control circuit 12 includes a CNV control unit 12 a that controls the converter 2, an INV control unit 12 b that controls the inverter 3, a first power storage unit 9, and a chop control unit 12 c that controls the second power storage unit 10.
The control circuit 12a may be configured as a part of a control unit that controls the entire uninterruptible power supply. Moreover, it may be provided as a structure which controls a power converter device independently. The signal line s for controlling the power converter by the control circuit 12 is indicated by a one-dot chain line in the figure, and is distinguished from a solid line indicating the flow of power.

  The first power storage unit 9 includes a secondary battery 6 that is a first power storage device, and a first DC / DC conversion circuit that converts a voltage value of DC power supplied from the secondary battery 6. The second power storage unit includes an electric double layer capacitor (EDLC) 8 that can be charged / discharged faster than the secondary battery 6 and a second DC / DC conversion circuit that converts the voltage value of the DC power supplied from the EDLC 8. I have. The load device 4 is a device or the like that operates by receiving power supplied from the AC power source 1.

In the first embodiment, a CHOP circuit is applied to both the first DC / DC conversion circuit and the second DC / DC conversion circuit. The first DC / DC converter circuit is referred to as CHOP circuit 5, the second DC / DC converter circuit is referred to as CHOP circuit 7, the current flowing through CHOP circuit 5 is referred to as Ichop1, and the current flowing through CHOP circuit 7 is referred to as Ichop2.
In the power conversion device according to the first embodiment configured as described above, the AC power source 1 supplies power to the load device 4 via the converter 2 and the inverter 3 during normal operation. Further, when an abnormality such as a power failure occurs in the AC power supply 1, the second power storage unit 10 supplies power to the load device 4 with priority over the first power storage unit 9. When the AC power supply 1 returns from the abnormality, the AC power supply 1 charges the first power storage unit 9 via the converter 2 after charging the second power storage unit 10 by the first power storage unit 9.

  FIG. 2 is a time chart for explaining the operation of the power conversion device shown in FIG. 1, and is a diagram for explaining a power conversion control method by the power conversion device. In the figure, the horizontal axis indicates time t, and the vertical axis indicates the current value, and the mesh lines in the figure indicate the types of operation of each component such as constant output voltage control, discharging, and charging, respectively. The illustrated process is performed by the control circuit 12.

The power supply mode described at the top in the figure indicates the state of the AC power supply 1. In the first embodiment, there are three power modes: normal, power failure, and power recovery. The operation when the power supply mode is normal corresponds to the normal process of the power conversion control method of the first embodiment. Further, the operation at the time of power supply mode power failure corresponds to the abnormal process of the power conversion control method of the first embodiment, and the operation at the time of power supply mode recovery corresponds to the return process of the power conversion control method of the first embodiment.
In the figure, Iinv represents the current value of the inverter 3, and Icnv represents the current value of the converter 2. I chop1 is the current value of the secondary battery 6, and I chop2 is the current value of the EDLC 8. Hereinafter, the operation of the power conversion apparatus according to the first embodiment will be described for each power supply mode with reference to FIG.

(Power mode: Normal)
During the normal operation of the AC power supply 1, the CNV control unit 12 a monitors the voltage value of the DC power output from the converter 2. Then, the monitored voltage is controlled so as to be kept constant regardless of the voltage drop due to the power consumed by the inverter 3, the first power storage unit 9, and the second power storage unit 10 in the subsequent stage. Such control is referred to as constant output voltage control in the figure.
Further, the INV control unit 12b monitors the voltage value output from the inverter 3. Then, the current Iinv is controlled so that a constant AC voltage is supplied to the load device 4 regardless of the load applied to the inverter 3. The CNV control unit 12a causes the converter 2 to control Icnv so as to convert the power supplied from the AC power source 1 and output a DC voltage having a constant value.
Further, the chop control unit 12 c controls the CHOP circuit 5 and the CHOP circuit 7. By this control, the CHOP circuit 5 and the CHOP circuit 7 perform the floating charge control so that the voltage value of the electric power stored in the secondary battery and the EDLC 8 connected to each is kept at a constant value (floating charge voltage). It is carried out.

(Power mode: Power failure)
When a power failure occurs and the AC power supply 1 no longer supplies power to the load device 4 by the power, the CNV control unit 12a electrically disconnects the converter 2 and the AC power supply 1 by gate-off by a circuit (not shown). At this time, the EDLC 8 is discharged, and power is supplied to the load device via the CHOP circuit 7 and the inverter 3. The chop control unit 12 c controls the electric power supplied from the EDLC 8 to the CHOP circuit 7 so that a constant DC voltage is supplied from the inverter 3. The INV control unit 12b monitors the output voltage of the inverter 3 and controls the inverter 3 so that a constant alternating current is output as in the normal state.

The chop control unit 12c terminates the discharge of the EDLC 8 when the EDLC 8 reaches a certain discharge end voltage. Then, the CHOP circuit 5 is controlled to start discharging the secondary battery 6 simultaneously with the end of discharging of the EDLC 8. At this time, the CHOP circuit 5 controls the value of the DC voltage supplied to the inverter 3 to be constant. Note that the control for switching the power storage device that supplies power to the inverter 3 can be smoothly performed by wrapping the operations of the CHOP circuit 7 and the CHOP circuit 5.
In the first embodiment, as described above, the EDLC 8 having a longer cycle life than the secondary battery 6 is used to supply power to the load device 4. For this reason, when the power failure time is short, it is not necessary to supply power to the load device 4 using the secondary battery 6. For this reason, increase in the frequency | count of charging / discharging of the secondary battery 6 can be suppressed, and the lifetime of the secondary battery 6 can be extended.

(Power mode: Power recovery)
When the AC power supply 1 returns from the power failure (recovers power), the CNV control unit 12a monitors the voltage value of the DC power output from the converter 2 and starts constant output voltage control, as in the normal state. The INV control unit 12 b continues the constant output voltage control so that a constant alternating voltage is output from the inverter 3.
Simultaneously with the start of control of the converter 2, the chop control unit 12c controls the secondary battery 6 and the CHOP circuit 5 to start high-speed charging of the EDLC 8. At this time, the chop control unit 12c calculates the amount of charging current necessary for high-speed charging of the EDLC 8 by calculation. Then, the obtained charging current is given as a charging command to the CHOP circuit 7 and also given as a discharging current command to the CHOP circuit 5. By such processing, the electric power stored in the secondary battery 6 is discharged, and the EDLC 8 is charged.

  With the above operation, the EDLC 8 can be charged at high speed without the electric power stored in the secondary battery 6 passing through the converter 2. Therefore, in the first embodiment, it is not necessary to change the current rating of the converter 2 when the EDLC 8 is charged at high speed. Further, if the charging time of the EDLC 8 is set to be equal to or longer than the discharging time of the secondary battery 6, the charging current withstand capacity of the CHOP circuit 7 becomes a value less than or equal to the discharging current withstand capacity of the secondary battery. It becomes possible to apply to the 2nd electrical storage unit 10, without changing the specification.

The chop control unit 12c switches the charging control of the CHOP circuit 7 from the high speed charging to the floating charging after the high speed charging of the EDLC 8 is completed. Due to the floating charging, the voltage of the EDLC 8 is kept at the value of the floating voltage. Further, the chop control unit 12c causes the CHOP circuit 5 to start floating charging of the secondary battery 6 so as to keep the voltage of the secondary battery 6 at a floating voltage. At this time, the current Icnv flowing through the converter 2 increases by an amount necessary for charging the secondary battery 6.
As described above, the power conversion device according to the first embodiment can use the EDLC 8 that can be charged / discharged faster than the secondary battery 6 without changing the current rating of the converter 2, and the power conversion control. Can provide a method. Such a power converter and a power conversion control method can cope with a sudden change in supply current without increasing the circuit configuration.

(Embodiment 2)
Next, Embodiment 2 of the present invention will be described. FIG. 3 is a diagram for explaining the configuration of the power conversion device according to the second embodiment of the present invention. The illustrated configuration includes the same configuration as the configuration described in the first embodiment, and the same configuration is denoted by the same reference numeral, and the description is partially omitted.
In the current converter according to the second embodiment, the AC power source 1, the converter 2, and the inverter 3 are connected in series by the DC unit 11 as in the power converter described in the first embodiment. Further, the second power storage unit 30 and the first power storage unit 39 are connected to the DC unit 11.

  The first power storage unit 39 is charged by the AC / DC converter 35 and the AC / DC converter 35 that charge the secondary battery 6 by supplying power from the secondary battery 6 and the AC power source 1 without going through the converter 2. Further, a DC / DC converter 15 for discharging the secondary battery 6 is provided. The second power storage unit 30 includes an EDLC 8 that can be charged and discharged faster than the secondary battery 6, an AC / DC converter 37 that charges the EDLC 8 by supplying power from the AC power supply 1 without going through the converter 2, and AC / DC conversion A DC / DC converter 17 for discharging the EDLC 8 charged by the battery 37 is provided.

  In the above configuration, the secondary battery 6 functions as the first power storage device, the AC / DC converter 35 functions as the first charging means, and the DC / DC converter 15 functions as the first discharging means. The EDLC 8 functions as a second power storage device, the AC / DC converter 37 functions as a second charging unit, and the DC / DC converter 17 functions as a second discharging unit. Currents output from the DC / DC converter functioning as the charging means are denoted as Ichg1 and Ichg2, and currents output from the DC / DC converter functioning as the discharging means are denoted as Ichop1 and Ichop2.

  The power conversion device according to the second embodiment includes a control circuit 32 that controls the above configuration in an integrated manner. The control circuit 32 includes a CNV control unit 32 a that controls the converter 2, an INV control unit 32 b that controls the inverter 3, a first power storage unit 39, and a charge / discharge control unit 32 c that controls the second power storage unit 30. The signal line s for controlling the power converter by the control circuit 32 is indicated by a one-dot chain line in the figure, and is distinguished from a solid line indicating the flow of power.

In the power converter of Embodiment 2, during normal operation, the AC power supply 1 supplies power to the load device 4 via the converter 2 and the inverter 3 and charges the secondary battery 6 via the AC / DC converter 35. To do. Further, the EDLC 8 is charged via the AC / DC converter 37.
When an abnormality occurs in the AC power supply 1, the AC / DC converter 35 and the AC / DC converter 37 stop charging, and the DC / DC converter 17 has priority over the DC / DC converter 15 in the EDLC 8. Power is supplied to the load device 4. Further, when the AC power supply 1 is restored, the AC power supply 1 charges the secondary battery 6 via the AC / DC converter 35 and the EDLC 8 via the AC / DC converter 37.

FIG. 4 is a time chart for explaining the operation of the power conversion device shown in FIG. 3, and is a diagram for explaining a power conversion control method by the power conversion device. In the figure, the horizontal axis indicates time t, and the vertical axis indicates the current value, and the mesh lines in the figure indicate the types of operation of each component such as constant output voltage control, discharging, and charging, respectively. The illustrated process is performed by the control circuit 32.
Also in the second embodiment, there are three power modes: normal, power failure, and power recovery. The operation when the power mode is normal corresponds to the normal process of the power conversion control method of the second embodiment. Further, the operation at the time of power mode blackout corresponds to the abnormal process of the power conversion control method of the second embodiment, and the operation at the time of power mode recovery corresponds to the return process of the power conversion control method of the second embodiment.

  In the figure, Iinv represents the current value of the inverter 3, and Icnv represents the current value of the converter 2. I chop1 is the current value of the secondary battery 6, and I chop2 is the current value of the EDLC 8. Icng1 is a current value supplied from the AC / DC converter 35 to the secondary battery 6, and Ichng2 is a current value supplied from the AC / DC converter 37 to the EDLC 8. Hereinafter, operation | movement of the power converter device of Embodiment 2 is demonstrated for every power supply mode using FIG.

(Power mode: Normal)
During the normal operation of the AC power supply 1, the CNV control unit 32 a monitors the voltage value of the DC power output from the converter 2. Then, the monitored voltage is controlled so as to be kept constant regardless of the voltage drop due to the power consumed by the inverter 3, the first power storage unit 39, and the second power storage unit 30 in the subsequent stage. Such control is referred to as constant output voltage control in the figure.
Further, the INV control unit 32b monitors the voltage value output from the inverter 3. Then, the current Iinv is controlled so that a constant AC voltage is supplied to the load device 4 regardless of the load applied to the inverter 3. The CNV control unit 32a causes the converter 2 to control Icnv so as to convert the power supplied from the AC power source 1 and output a DC voltage having a constant value.
Further, the charge / discharge control unit 32 c controls the DC / DC converter 15 and the DC / DC converter 17. By this control, the DC / DC converter 15 and the DC / DC converter 17 are float-charged so that the voltage value of the electric power stored in the secondary battery and the EDLC 8 connected to each is kept at a constant value. Control is in progress. At this time, the charge / discharge control unit 32c performs control so that the DC / DC converter 17 and the DC / DC converter 15 are stopped and placed in a standby state.

(Power mode: Power failure)
When a power failure occurs and the AC power supply 1 no longer supplies power to the load device 4 by the power, the CNV control unit 32a electrically disconnects the converter 2 and the AC power supply 1 by gate-off by a circuit (not shown). Further, the AC / DC converter 35 and the AC / DC converter 37 each stop the charging operation until the AC power source 1 is restored.
At this time, the charge / discharge control unit 32 c controls the AC / DC converter 17 to discharge the EDLC 8. Discharge power is supplied to the load device 4 via the inverter 3. The charge / discharge control unit 32 c controls the AC / DC converter 17 so that a constant DC voltage is supplied from the inverter 3. The INV control unit 32b monitors the output voltage of the inverter 3 and controls the inverter 3 so that a constant alternating current is output, as in the normal state.

  The charge / discharge control unit 32c controls the DC / DC converter 17 to end the discharge of the EDLC 8 when the EDLC 8 reaches a certain discharge end voltage. Then, the DC / DC converter 15 is controlled to start discharging the secondary battery 6 simultaneously with the end of discharging of the EDLC 8. At this time, the DC / DC converter 15 controls the value of the DC voltage supplied to the inverter 3 to be constant. Note that the control for switching the power storage device that supplies power to the inverter 3 can be smoothly performed by wrapping the operations of the DC / DC converter 17 and the DC / DC converter 15.

(Power mode: Power recovery)
When the AC power supply 1 recovers from a power failure, the CNV control unit 32a monitors the voltage value of the DC power output from the converter 2 and starts constant output voltage control, as in the normal state. The INV control unit 32 b continues the constant output voltage control so that a constant alternating voltage is output from the inverter 3.
Simultaneously with the start of control of the converter 2, the charge / discharge control unit 32 c controls the AC / DC converter 37 to start high-speed charging of the EDLC 8. At this time, the charge / discharge control unit 32c monitors the charge level of the EDLC 8, and switches the charge control to floating charge when the voltage of the EDLC 8 exceeds a predetermined voltage. The AC / DC converter 35 is charged with the maximum current until the secondary battery 6 reaches a predetermined voltage value, and then the control is switched to floating charging. At this time, the DC / DC converter 15 and the DC / DC converter 17 are stopped and are in a standby state.

  According to the second embodiment, all currents for charging the EDLC 8 and the secondary battery 6 are supplied to the AC / DC converter 35 and the AC / DC converter 37 without going through the converter 2. For this reason, the converter 2 only needs to supply the current required by the inverter 3, and it is possible to provide a power converter that can charge the power storage device such as the EDLC 8 at a high speed while keeping the current rating of the converter 2 constant. .

(Embodiment 3)
Next, a third embodiment of the present invention will be described. FIG. 5 is a diagram for explaining the configuration of the power conversion device according to the third embodiment of the present invention. The illustrated configuration includes the same configuration as the configuration described in the second embodiment, and the same configuration is denoted by the same reference numeral and the description is partially omitted.
The current converter of Embodiment 3 is configured by replacing the DC / DC converter 17 of the power converter described in Embodiment 2 with a DC / DC converter 57. The difference between the direct current / direct current converter 17 and the direct current / direct current converter 57 is that the direct current / direct current converter 17 has only a discharge function for extracting electric power from the EDLC 8, whereas the direct current / direct current converter 57 has the discharge function together with the EDLC8. It is a point which has the structure which can be bidirectionally charged.

  In the power conversion device according to the third embodiment, when the AC power supply 1 is restored from a power failure, the AC / DC converter 35 supplies power from the secondary battery 6 to the EDLC 8 via the DC / DC converter 57 so that the EDLC 8 is predetermined. Then, the AC power supply 1 operates to charge the secondary battery 6 through the AC / DC converter 35 and the EDLC 8 through the AC / DC converter 37, respectively.

FIG. 6 is a time chart for explaining the operation of the power conversion device shown in FIG. 5, and is a diagram for explaining a power conversion control method by the power conversion device. In the figure, the horizontal axis indicates time t, and the vertical axis indicates the current value, and the mesh lines in the figure indicate the types of operation of each component such as constant output voltage control, discharging, and charging, respectively. The illustrated processing is performed by the control circuit 32 as in the second embodiment.
Hereinafter, operation | movement of the power converter device of Embodiment 3 is demonstrated using FIG. Note that the power conversion device according to the third embodiment operates in the same manner as in the second embodiment when the AC power source 1 is normal or during a power failure, and operates differently from the second embodiment only when power is restored. For this reason, in the following description, only the operation mode at the time of power recovery of the power conversion device of the third embodiment will be described.

(Power mode: Power recovery)
When the AC power supply 1 recovers from a power failure, the CNV control unit 32a monitors the voltage value of the DC power output from the converter 2 and starts constant output voltage control, as in the normal state. The INV control unit 32 b continues the constant output voltage control so that a constant alternating voltage is output from the inverter 3.
Simultaneously with the start of control of the converter 2, the charge / discharge control unit 32 c calculates the amount of charging current required for high-speed charging of the EDLC 8 by calculation. Then, the obtained charging current is given to the DC / DC converter 57 as a charge command, and is given to the DC / DC converter 15 as a discharge current command. By such processing, the electric power stored in the secondary battery 6 is discharged, and the EDLC 8 is charged at high speed.

After the high-speed charging, the charge / discharge control unit 32c controls the AC / DC converter 37 to supply power from the AC power source 1 to the EDLC 8 and perform floating control. Further, the AC / DC converter 35 is float-charged from the maximum current charge, and the voltage value of the secondary battery 6 is kept constant. Note that after the start of floating charging, the DC / DC converter 15 and the DC / DC converter 57 are in a standby state.
According to the third embodiment, power necessary for charging the EDLC 8 can be supplied without going through the converter 2 or the AC / DC converter 37. For this reason, it is not necessary to change the current rating of the converter 2 in order to charge the EDLC 8 at high speed, and the current capacity of the AC / DC converter 37 can be reduced.

It is a figure for demonstrating the structure of the power converter device of Embodiment 1 of this invention. It is a time chart for demonstrating operation | movement of the power converter device shown in FIG. It is a figure for demonstrating the structure of the power converter device of Embodiment 2 of this invention. It is a time chart for demonstrating operation | movement of the power converter device shown in FIG. It is a figure for demonstrating the structure of the power converter device of Embodiment 3 of this invention. It is a time chart for demonstrating operation | movement of the power converter device shown in FIG. It is the figure which illustrated the general power converter.

Explanation of symbols

1 AC power supply,
2 Converter 3 Inverter 4 Load device 5, 7 CHOP circuit 6 Secondary battery 9, 10, 30, 39 Power storage unit 11 DC unit 12, 32 Control circuit 15, 17, 57 DC / DC converter 35, 37 AC / DC conversion vessel

Claims (7)

A forward converter for converting AC power supplied from an AC power source into DC power;
An inverse converter that converts the DC power converted by the forward converter into AC power of a desired frequency;
The 1st electrical storage unit connected to the direct-current part which connects the forward converter and the reverse converter in series, and the 2nd electrical storage unit which is connected to the direct-current part and can charge / discharge faster than the 1st electrical storage unit And
During normal operation, the AC power supply supplies power to the load device via the forward converter and the reverse converter, and when an abnormality occurs in the AC power supply, the second power storage unit is the first power storage unit. When power is supplied to the load device more preferentially and the AC power supply is restored, after the second power storage unit is charged by the first power storage unit, the AC power supply is connected to the first power converter via the forward converter. A power conversion device, wherein the power storage unit is charged. The first power storage unit includes a first power storage device and a first DC / DC conversion circuit that converts a voltage value of DC power supplied from the first power storage device. The second power storage unit includes:
A second power storage device that can be charged / discharged at a higher speed than the first power storage device, and a second DC / DC conversion circuit that converts a voltage value of DC power supplied from the second power storage device. Item 4. The power conversion device according to Item 1. A first forward converter that converts AC power supplied from an AC power source into DC power;
An inverse converter that converts the DC power converted by the first forward converter into AC power of a desired frequency;
A first power storage unit and a second power storage unit having a direct current output connected to a direct current unit that connects the forward converter and the reverse converter in series;
The first power storage unit includes:
A first charging device for charging the first power storage device by supplying power from the AC power supply by a second forward converter different from the first forward converter; First discharging means for discharging the first power storage device charged by the charging means,
The second power storage unit is
Power is supplied from a second power storage device that can be charged and discharged faster than the first power storage device, and a third forward converter different from the first forward converter from the AC power supply, and the second power storage device A second charging means for charging the battery, and a second discharging means for discharging the second power storage device charged by the second charging means,
During normal operation, the AC power supply supplies power to the load device via the first forward converter and the reverse converter, and supplies the first power storage device via the first charging means to the second power supply. When the second power storage device is charged via the charging means and an abnormality occurs in the AC power supply, the first charging means and the second charging means stop charging, and the second discharging means When power is supplied from the second power storage device to the load device with priority over the first discharging means, and the AC power supply is restored, the AC power supply causes the first power storage device to pass through the first charging means. The power conversion device charges each of the second power storage devices via the second charging means. The second discharging means has a charging function of charging the second power storage device;
When the AC power supply is restored, the second discharge unit supplies power from the first power storage device to the second power storage device via the first discharge unit to bring the second power storage device to a predetermined voltage level. The said AC power supply charges the said 1st electrical storage device through the said 1st charging means, and the said 2nd electrical storage device through the said 2nd charging means after charging, respectively, The said 2nd electrical storage device is characterized by the above-mentioned. Power converter.   The first power storage device is a power storage device having a larger capacity than the second power storage device, and the second power storage device is a power storage device having a longer cycle life than the first power storage device. 5. The power conversion device according to any one of items 1 to 4. A forward converter for converting AC power supplied from an AC power source into DC power;
An inverse converter that converts the DC power converted by the forward converter into AC power of a desired frequency;
The 1st electrical storage unit connected to the direct-current part which connects the forward converter and the reverse converter in series, and the 2nd electrical storage unit which is connected to the direct-current part and can charge / discharge faster than the 1st electrical storage unit A power conversion control method applied to a power conversion device having:
During normal operation of the AC power supply, a normal control step of supplying power from the AC power supply to the load device via the forward converter and the reverse converter,
When an abnormality occurs in the AC power supply during the normal control step, an abnormality control step of supplying power from the second power storage unit to the load device preferentially over the first power storage unit;
In the abnormality control step, when the AC power source is restored, the AC power source charges the first power storage unit via the forward converter after the second power storage unit is charged by the first power storage unit. When,
A power conversion control method comprising: A first forward converter that converts AC power supplied from an AC power source into DC power;
An inverse converter that converts the DC power converted by the forward converter into AC power of a desired frequency;
The first forward converter and the inverse converter are connected to a direct current unit that connects the first forward converter and the reverse converter in series, and the first forward storage device and the second forward converter different from the first forward converter from the alternating current power source. a first charging means for charging said first power storage device and powered by vessel, first power storage having a a first discharge means for discharging the first power storage device is charged by the first charging means Power is supplied by a unit and a second power storage device that can be charged and discharged faster than the first power storage device, and a third forward converter different from the first forward converter from the AC power source, and the first A power conversion apparatus comprising: a second power storage unit comprising: a second charging unit that charges the second power storage device; and a second discharge unit that discharges the second power storage device charged by the second charging unit. Applied power conversion control A law,
The AC power supply supplies electric power to the load device via the first forward converter and the reverse converter, and the first power storage device via the first charging means and the second charging means. Normal control step of charging the second power storage device respectively, and when an abnormality occurs in the AC power supply during the normal control step, the first charging means and the second charging means respectively stop charging, and An abnormality control step of supplying power from the second power storage device to the load device preferentially over the first discharging means;
If the AC power returns in the abnormal control step, said AC power supply to the first power storage device via the first charging means, Charge the respective said second power storage device through the second charging means and a carriage return control process,
A power conversion control method comprising:

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