JP2021002935A - Power conditioner - Google Patents

Abstract

To provide a power conditioner capable of reducing wasteful consumption of electricity stored in a storage battery.SOLUTION: A power conditioner 3 comprises: switches SW11 and SW12 connected in series on first cable runs L311 and L312; switches SW21 and SW22 connected in series on second cable runs L321 and L322; a switch SW3 whose one end is connected to the first cable run L311, and the other end is connected between the switch SW21 on the second cable run L321 and an autonomous operation terminal te351; a switch SW4 whose one end is connected to the second cable run L322 and the other end is grounded; a switch SW23 whose one end is connected between the switch SW22 on the second cable run L322 and an autonomous operation terminal te352, and the other end is grounded; and a control circuit 91 switching the switches SW11, SW12, SW21, SW22, SW3, SW4, and SW23 into either a system interconnection operation mode or an autonomous operation mode.SELECTED DRAWING: Figure 1

Description

The present invention relates to a power conditioner.

A storage battery that can supply power to multiple home appliances, a plurality of power measuring instruments that measure the power consumed by each home appliance, and the remaining capacity of the storage battery and the power consumption of each home appliance are measured from the storage battery and each power measuring device. Based on the power information acquisition unit that is sequentially acquired, the power consumption of the home appliance selected by the user, and the remaining capacity of the storage battery, the usable time in which the storage battery can supply power to the selected home appliance is sequentially calculated. A power management device including a processing unit and an information providing unit that informs the user of the usable time has been proposed (see, for example, Patent Document 1). By using this power management device, when operating independently without receiving power from the power system, the usable time of the storage battery can be estimated according to the operating state of the electric equipment in the house.

Japanese Unexamined Patent Publication No. 2014-36465

By the way, for example, when the power supply from the grid power supply is cut off and the home electric appliance is operated only by the electric power supplied from the storage battery, only the home electric appliance having a relatively high necessity of operation is operated and the necessity of operation is relatively low. It is desirable to reduce the consumption of electricity stored in the storage battery per unit time as much as possible by stopping the home appliances. Here, in the power management device described in Patent Document 1, the selected home electric appliance can be stopped for the first time when the user performs an operation of selecting the home electric appliance to be stopped. Therefore, for example, when a power failure occurs in the grid power supply while all home appliances are operating, the electricity stored in the storage battery is wasted between the time of the power failure and the selection of the home appliances to be stopped by the user. Will be consumed by.

The present invention has been made in view of the above reasons, and an object of the present invention is to provide a power conditioner capable of reducing wasteful consumption of electricity stored in a storage battery.

In order to achieve the above object, the power conditioner according to the present invention
DC bus line and
A DC-DC converter connected between the storage battery, the storage battery, and the DC bus line, which converts the DC voltage output from the storage battery into a preset constant voltage and outputs the DC voltage to the DC bus line.
An inverter connected to the DC bus line and converting a DC voltage supplied through the DC bus line into an AC voltage,
A pair of first electric circuits connected to the inverter and
A system terminal for supplying an AC voltage connected to the pair of first electric circuits and supplied from a system power supply to the pair of first electric circuits,
A self-sustaining operation terminal connected to the inverter via a pair of second electric circuits and for outputting an AC voltage to a load.
A first switch connected in series on the pair of first electric paths,
A second switch connected in series on the pair of second electric circuits,
One end is connected between the first switch and the system terminal in one of the pair of first electric circuits, and the other end is the second switch and the self-sustaining operation in one of the pair of second electric circuits. The third switch connected between the terminals and
A fourth switch whose one end is connected between the second switch and the self-sustaining operation terminal on the other side of the pair of second electric circuits and whose other end is grounded.
A fifth switch whose one end is connected between the second switch and the self-sustaining operation terminal on the other side of the pair of second electric circuits and whose other end is grounded.
The first mode in which the first switch, the third switch and the fourth switch are closed and the second switch and the fifth switch are in the open state, and the first switch, the third switch and the said. A switch control unit for switching to either a second mode in which the fourth switch is in the open state and the second switch and the fifth switch are in the closed state is provided.

The power conditioner according to the present invention is
A voltmeter that measures the output voltage of the storage battery,
An ammeter that measures the current flowing through the fourth switch in the first mode,
A storage amount calculation unit that calculates the storage amount of the storage battery based on the output voltage measured by the voltmeter, and
A power consumption calculation unit that calculates the power consumption of the load connected to the self-sustaining operation terminal based on the current value of the current flowing through the fourth switch measured by the ammeter in the first mode.
Based on the stored amount calculated by the stored amount calculation unit and the power consumption calculated by the power consumption calculation unit, it is possible to continue supplying power from the storage battery to the load in the second mode. It may be further provided with a supplyable time calculation unit for calculating a power supply available time.

The power conditioner according to the present invention is
In the second mode, a display unit that displays information indicating the power supply available time calculated by the supply available time calculation unit may be further provided.

The power conditioner according to the present invention is
In the second mode, a supplyable time information generation unit that generates supplyable time information indicating the power supplyable time calculated by the supplyable time calculation unit, and a supplyable time information generation unit.
It may further include a transmission unit that transmits the supplyable time information generated by the supplyable time information generation unit to the terminal device.

The power conditioner according to the present invention is
Further provided with a determination unit for determining whether AC is supplied from the system power supply to the system terminal or whether AC supplied from the system power supply to the system terminal is cut off.
When the determination unit determines that alternating current is being supplied from the system power supply to the system terminal, the switch control unit includes the first switch, the second switch, the third switch, the fourth switch, and the like. When the fifth switch is switched to the first mode and it is determined that the alternating current supplied from the system power supply to the system terminal is cut off, the first switch, the second switch, the third switch, and the above The fourth switch and the fifth switch may be switched to the second mode.

The power conditioner according to the present invention is
The system power supply supplies AC power to the system terminals in a single-phase, three-wire system.
The system terminal has a grounding electrode terminal and has a grounding electrode terminal.
The other end of the fourth switch may be connected to the grounding electrode terminal.

The power conditioner according to the present invention is
It may further include a PV converter connected to the DC bus line to convert the DC power generated by the power generation facility and output it to the DC bus line.

According to the present invention, for example, when the switch control unit stops supplying the AC voltage from the system power supply, the first switch, the second switch, the third switch, the fourth switch, and the fifth switch are changed to the above-mentioned first switch. It is possible to switch from the mode to the second mode described above. As a result, for example, even if the supply of AC voltage from the grid power supply is stopped, only the load that wants to continue supplying power is connected to the self-sustaining operation terminal, so that the power from the storage battery to the load connected to the self-sustaining operation terminal Only supply will continue. Therefore, it is possible to reduce the wasteful consumption of the electricity stored in the storage battery after the supply of the AC voltage from the system power supply is stopped.

It is a figure which shows the structure of the power-source system which concerns on embodiment of this invention. It is a block diagram of the control circuit which concerns on embodiment. It is a flowchart which shows an example of the flow of the power conditioner control processing executed by the control circuit which concerns on embodiment. It is operation explanatory drawing of the power conditioner which concerns on embodiment. It is operation explanatory drawing of the power conditioner which concerns on embodiment. It is a block diagram of the control circuit which concerns on the modification. It is a block diagram of the control circuit which concerns on the modification. It is a flowchart which shows an example of the flow of the power conditioner control processing executed by the control circuit which concerns on a modification. It is a figure which shows a part of the structure of the power conditioner which concerns on a modification.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The power conditioner according to the present embodiment supplies electric power to the load from the photovoltaic power generation equipment, the storage battery, etc. in connection with the grid power source. The power conditioner according to the present embodiment has a DC bus line, a DC-DC converter connected between the storage battery and the DC bus line, and a DC voltage connected to the DC bus line and supplied from the DC bus line. It is equipped with an inverter that converts to AC voltage and outputs it. Here, the DC-DC converter converts the DC voltage output from the storage battery into a preset constant voltage and outputs it to the DC bus line. Further, the power conditioner includes a pair of first electric circuits connected to the inverter, a system terminal connected to the pair of first electric circuits, and a system terminal for supplying an AC voltage supplied from the system power supply to the pair of first electric circuits. It is provided with a self-sustaining operation terminal connected to the inverter via a pair of second electric circuits and for outputting alternating current to the load. Further, the power conditioner includes a first switch connected in series on a pair of first electric lines, a second switch connected in series on a pair of second electric lines, a third switch, and a fourth switch. , A fifth switch, and so on. Here, the third switch has one end connected between the first switch and the system terminal in one of the pair of first electric circuits and the other end with the second switch in one of the pair of second electric circuits. It is connected to the self-sustaining operation terminal. Further, one end of the fourth switch is connected between the second switch and the self-sustained operation terminal on the other end of the pair of second electric circuits, and the other end is grounded. One end of the fifth switch is connected between the second switch and the self-sustaining operation terminal on the other end of the pair of second electric circuits, and the other end is grounded. Further, the power conditioner has a first mode in which the first switch, the third switch and the fourth switch are in the closed state and the second switch and the fifth switch are in the open state, and the first switch, the third switch and the first switch. A switch control unit for switching between a second mode in which the four switches are in the open state and the second and fifth switches are in the closed state is provided. Then, when the switch control unit stops supplying AC from the system power supply, the first switch, the second switch, the third switch, the fourth switch, and the fifth switch are changed from the first mode to the second mode. It is to switch to. Here, the configuration of the power supply system including the power conditioner according to the present embodiment will be described.

As shown in FIG. 1, the power supply system according to the present embodiment includes a solar cell 1, a storage battery 2, and a power conditioner 3 connected to the solar cell 1, the storage battery 2, and the system power supply 4. The grid power supply 4 supplies AC power to the power conditioner 3 in a single-phase three-wire system, for example. The power conditioner 3 includes a PV converter 31, an inverter 32, a DC-DC converter 33, a DC bus line (hereinafter referred to as “HVDC bus”) L3, and a pair of first electric lines L311 and L312. Second electric lines L321, L322, terminal blocks 34, 35, switches SW11, SW12, SW21, SW22, SW23, SW3, SW4, current meter 8, voltmeter 331, control circuit 91, and display unit 92. And.

The PV converter 31 is a DC-DC converter that boosts the DC voltage input from the solar cell 1 and outputs it to the HVDC bus L3. Here, the HVDC bus L3 is maintained at a preset constant DC voltage. The inverter 32 is a bidirectional DC-AC inverter, which is connected to the HVDC bus L3 and converts the DC voltage input from the HVDC bus L3 into an AC voltage and outputs the DC voltage to the self-supporting load 5. Further, the inverter 32 converts the AC voltage supplied from the system power supply 4 into a DC voltage and outputs the AC voltage to the HVDC bus L3.

The DC-DC converter 33 is a bidirectional DC-DC converter, which is connected between the storage battery 2 and the HVDC bus L3, and has a discharge mode and an HVDC bus L3 that discharge the electricity stored in the storage battery 2 to the HVDC bus L3. It operates in one of the operation modes of the charging mode in which the storage battery 2 is charged by supplying electric power to the storage battery 2. Here, when the DC-DC converter 33 operates in the discharge mode, the output voltage of the storage battery 2 is boosted and output to the HVDC bus L3 so that the output voltage to the HVDC bus L3 becomes constant. Further, when the DC-DC converter 33 operates in the charging mode, the DC power input from the HVDC bus L3 is stepped down and output to the storage battery 2.

The pair of first electric circuits L311 and L312 and the pair of second electric circuits L321 and L322 are connected to the inverter 32, respectively. The terminal block 34 is connected to the pair of first electric circuits L311 and L312, and is grounded with the system terminals teU and teW for supplying the AC power supplied from the system power supply 4 to the pair of first electric circuits L311 and L312. It has a grounding electrode terminal teO. The terminal block 35 is connected to a pair of second electric circuits L321 and L322, and has independent operation terminals te351 and te352 for outputting AC power to the independent load 5. The self-supporting load 5 is a so-called AC load such as a household electric appliance that operates by being supplied with AC power, for example.

The switches SW11 and SW12 are first switches connected in series on the pair of first electric lines L311 and L312, and the switches SW21 and SW22 are connected in series on the pair of second electric lines L321 and L322, respectively. This is the second switch. One end of the switch SW3 is connected between the switch SW11 in the first electric circuit L311 and the system terminal teU of the terminal block 34, and the other end is between the switch SW21 in the second electric line L321 and the self-sustained operation terminal te351 of the terminal block 35. It is a third switch connected to. The switch SW4 is a fourth switch in which one end is connected between the switch SW22 in the second electric circuit L322 and the self-sustained operation terminal te352 of the terminal block 35, and the other end is connected to the grounding electrode terminal teO of the terminal block 34. .. The switch SW23 is a fifth switch in which one end is connected between the switch SW22 in the second electric circuit L322 and the self-sustained operation terminal te352 of the terminal block 35, and the other end is grounded. As the switches SW11, SW12, SW21, SW22, SW23, SW3, SW4, a semiconductor switch, a mechanical relay switch, or the like can be adopted.

The ammeter 8 is connected between the second electric circuit L322 and the switch SW4, measures the current flowing through the switch SW4 when the switch SW4 is closed, and outputs a current measurement value signal indicating the measured current value to the control circuit 91. Output to. The voltmeter 331 measures the output voltage of the storage battery 2 and outputs a voltage measurement value signal indicating the measured voltage value to the control circuit 91. The display unit 92 is a display device such as a liquid crystal display.

The control circuit 91 has, for example, an MPU (Micro Processing Unit) and a memory. Then, by executing the program stored in the memory, the MPU calculates the PV converter control unit 911, the inverter control unit 912, the DC-DC converter control unit 913, the switch control unit 914, and the amount of electricity stored, as shown in FIG. It functions as a unit 915, a power consumption calculation unit 916, a supplyable time calculation unit 917, a determination unit 918, and a display control unit 919. The PV converter control unit 911 generates a control signal for controlling the PV converter 31 so that its output voltage becomes constant, and outputs the control signal to the PV converter 31. The inverter control unit 912 generates a control signal for operating the inverter 32 and outputs the control signal to the inverter 32. The DC-DC converter control unit 913 generates a control signal for operating the DC-DC converter 33 in either the charge mode or the discharge mode, and outputs the control signal to the DC-DC converter 33.

The switch control unit 914 controls the open / closed state of each of the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4. Specifically, the switch control unit 914 switches the combination of the open / closed states of the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 to either the grid interconnection operation mode or the independent operation mode. Here, the grid interconnection operation mode corresponds to the first mode in which the switches SW11, SW12, SW3, and SW4 are in the closed state and the switches SW21, SW22, and SW23 are in the open state. On the other hand, the self-sustaining operation mode corresponds to the second mode in which the switches SW11, SW12, SW3, and SW4 are in the open state and the switches SW21, SW22, and SW23 are in the closed state.

Further, although not shown in FIG. 1, a normal load used at the time of grid connection is connected between the terminal block 34 and the grid power supply 4. In the grid interconnection operation mode, the normal load is supplied from the grid power supply 4 or the power conditioner 3, but in the self-sustaining operation mode, the switches SW11 and SW12 are in the open state, so that no power is supplied. That is, the normal load is a load that cannot be used during a power failure. The self-sustaining load 5 is supplied with power from the system power supply 4 via SW3 in the grid interconnection operation mode, and is supplied with power from the inverter 32 in the self-sustaining operation mode. That is, the self-supporting load 5 can be used even during a power failure.

The electricity storage amount calculation unit 915 acquires the output voltage of the storage battery 2 measured by the voltmeter 331 from the voltage measurement value signal input from the voltmeter 331. Then, the storage amount calculation unit 915 calculates the storage amount of the storage battery 2 based on the acquired output voltage of the storage battery 2.

The power consumption calculation unit 916 was measured by the ammeter 8 from the current value measurement signal input from the ammeter 8 when the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 were in the grid interconnection operation mode. Acquires the current value of the current flowing through the switch SW4. Then, the power consumption calculation unit 916 calculates the power consumption of the self-sustaining load 5 connected to the self-sustaining operation terminals te351 and te352 of the terminal block 35 based on the current value of the current flowing through the acquired switch SW4.

The supplyable time calculation unit 917 has switches SW11, SW12, based on the storage amount of the storage battery 2 calculated by the storage amount calculation unit 915 and the power consumption of the self-supporting load 5 calculated by the power consumption calculation unit 916. When the SW21, SW22, SW23, SW3, and SW4 are in the self-sustaining operation mode, the power supply available time during which the storage battery 2 can continue to supply power to the self-sustaining load 5 is calculated.

The determination unit 918 is either supplying AC power from the system power supply 4 to the system terminals teU and teW of the terminal block 34, or the system, based on the input / output status between the inverter 32 and the first electric lines L311 and L312. It is determined whether the supply of AC power from the power supply 4 to the system terminals teU and teW is cut off. Here, the determination unit 918 detects a power failure by, for example, a detection method based on the frequency feedback method with step injection (JEM1498) defined by JEMA (Japan Electric Industry Association).

The display control unit 919 causes the display unit 92 connected to the control circuit 91 via an interface (not shown) to display the information indicating the power supply available time calculated by the supply available time calculation unit 917.

Next, the power conditioner control process executed by the control circuit 91 according to the present embodiment will be described with reference to FIGS. 3 to 5. This power conditioner control process is started, for example, when the power conditioner 3 is activated in a state where power can be supplied from the system power supply 4 to the first electric circuits L311 and L312 via the system terminals teU and teW. The control circuit 91 is a process of controlling the operation of the PV converter 31, a process of controlling the operation of the inverter 32, and a process of controlling the operation of the DC-DC converter 33 in parallel with the execution of the power conditioner control process. To execute.

First, as shown in FIG. 3, the switch control unit 914 sets the open / closed state of the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 to the above-mentioned grid interconnection operation mode (step S101). At this time, in the power conditioner 3, as shown in FIG. 4, the switches SW11, SW12, SW3, and SW4 are in the open state, and the switches SW21, SW22, and SW23 are in the open state. Here, for example, when the potential of the system terminal teU becomes higher than the ground potential, as shown by the arrow AR1 in FIG. 4, the switch SW3, the self-sustaining operation terminal te351, the self-supporting load 5, the self-sustaining operation terminal te352, from the first electric circuit L311 The current flows in the order of the switch SW4. That is, a DC voltage is output between the independent operation terminals te351 and te352 during the grid interconnection operation of the power conditioner 3.

Returning to FIG. 3, next, the power consumption calculation unit 916 is input from the ammeter 8 when the open / closed state of the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 is in the grid interconnection operation mode. From the current value measurement signal, the current value of the current flowing through the switch SW4 measured by the ammeter 8 is acquired (step S102). Here, the power consumption calculation unit 916 acquires the current value of the current flowing through the switch SW4 during the grid interconnection operation of the power conditioner 3.

Subsequently, the power consumption calculation unit 916 calculates the power consumption of the self-sustaining load 5 connected to the self-sustaining operation terminals te351 and te352 of the terminal block 35 based on the current value of the current flowing through the acquired switch SW4. Information indicating the calculated power consumption is stored in the memory (step S103).

After that, the determination unit 918 determines whether or not the supply of AC power from the system power supply 4 to the system terminals teU and teW is cut off (step S104). Here, when the determination unit 918 determines that AC power is being supplied from the system power supply 4 to the system terminals teU and teW (step S104: No), the process of step S102 is executed again. On the other hand, it is assumed that the determination unit 918 determines that the supply of AC power from the system power supply 4 to the system terminals teU and teW is not cut off (step S104: Yes). In this case, the switch control unit 914 sets the open / closed state of the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 to the above-mentioned independent operation mode (step S105). At this time, in the power conditioner 3, as shown in FIG. 5, the switches SW11, SW12, SW3, and SW4 are in the closed state, and the switches SW21, SW22, and SW23 are in the open state.

Returning to FIG. 3, next, the electricity storage amount calculation unit 915 acquires the output voltage of the storage battery 2 measured by the voltmeter 331 from the voltage measurement value signal input from the voltmeter 331 (step S106). Subsequently, the storage amount calculation unit 915 calculates the storage amount of the storage battery 2 based on the acquired output voltage of the storage battery 2 (step S107).

After that, the supplyable time calculation unit 917 acquires information indicating the power consumption calculated by the power consumption calculation unit 916 stored in the memory. Then, the supplyable time calculation unit 917 determines the switch SW11 based on the storage amount of the storage battery 2 calculated by the storage amount calculation unit 915 and the power consumption of the self-supporting load 5 calculated by the power consumption calculation unit 916. , SW12, SW21, SW22, SW23, SW3, SW4 are in the self-sustaining operation mode, and the power supply available time capable of continuing to supply power from the storage battery 2 to the self-sustaining load 5 is calculated (step 108). Next, the display control unit 919 causes the display unit 92 to display the information indicating the power supply available time calculated by the supply available time calculation unit 917 (step S109).

Subsequently, the determination unit 918 determines whether or not the supply of AC power from the system power supply 4 to the system terminals teU and teW is resumed (step S110). When the determination unit 918 determines that the state in which the supply of AC power from the system power supply 4 to the system terminals teU and teW is cut off continues (step S110: No), the process of step S106 is executed again. On the other hand, when the determination unit 918 determines that the supply of AC power from the system power supply 4 to the system terminals teU and teW is restarted (step S110: Yes), the process of step S101 is executed again.

As described above, according to the power conditioner 3 according to the present embodiment, when the switch control unit 914 stops supplying AC power from the system power supply 4, the switches SW11, SW12, SW21, SW22, SW23, SW3 and SW4 are switched from the grid interconnection operation mode to the independent operation mode. As a result, even if the supply of AC power from the system power supply 4 is stopped, the self-sustaining load 5 that is desired to be supplied and continued is connected to the self-sustaining operation terminals te351 and te352, whereby the self-sustaining operation terminals te351 and te352 are connected from the storage battery 2. The power supply to the self-supporting load 5 connected to is continued. Therefore, it is possible to reduce the wasteful consumption of the electricity stored in the storage battery 2 after the supply of the AC power from the system power supply 4 is stopped.

By the way, when a power failure occurs in the system power supply 4 due to a disaster, it may take some time to restore the system power supply 4. Therefore, the user is requested to be able to adjust the power consumption of the self-supporting load 5 while checking the amount of electricity stored in the storage battery 2.

On the other hand, the power conditioner 3 according to the present embodiment includes a voltmeter 331 that measures the output voltage of the storage battery 2, an ammeter 8 that measures the current flowing through the switch SW4 in the grid interconnection operation mode, and storage. A quantity calculation unit 915, a power consumption calculation unit 916, and a supplyable time calculation unit 917 are provided. Here, the electricity storage amount calculation unit 915 calculates the electricity storage amount of the storage battery 2 based on the output voltage measured by the voltmeter 331. Further, the power consumption calculation unit 916 calculates the power consumption of the self-sustaining load 5 connected to the self-sustaining operation terminals te351 and te352 based on the current value measured by the ammeter 8. Further, the supplyable time calculation unit 917 is operated from the storage battery 2 to the self-sustaining load 5 in the self-sustaining operation mode based on the storage amount calculated by the storage amount calculation unit 915 and the power consumption calculated by the power consumption calculation unit 916. Calculate the power supply available time that can continue to supply power to. Further, the power conditioner 3 includes a display unit 92 that displays information indicating the power supply available time calculated by the supplyable time calculation unit 917 in the self-sustaining operation mode. As a result, the user can check the amount of electricity stored in the storage battery 2 via the display unit 92 during the self-sustaining operation of the power conditioner 3, so that the power of the self-sustaining load 5 is increased according to the amount of electricity stored in the storage battery 2. Consumption can be adjusted. For example, when it is necessary to continue supplying power to the self-supporting load 5 from 17:00 to 6 hours in the evening, information indicating that the power supply available time to the display unit 92 is 6 hours at 15:00 in the daytime. Is displayed. In this case, the user can decide to refrain from using electricity until 17:00.

Further, the power conditioner 3 according to the present embodiment includes a determination unit 918 for determining whether the supply of AC power from the system power supply 4 to the system terminals teU and teW is cut off. Then, when it is determined by the determination unit 918 that AC power is being supplied from the system power supply 4 to the system terminals teU and teW, the switch control unit 914 switches the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4. , Switch to grid interconnection operation mode. On the other hand, when the switch control unit 914 determines that the AC power supplied from the system power supply 4 to the system terminals teU and teW is cut off, the switch control unit 914 operates the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 independently. Switch to mode. As a result, if the home appliances to be used are connected to the self-sustaining operation terminal in advance even when a power failure occurs, it is not necessary to reconnect the home appliances to be used by the user to the self-sustaining operation terminal after the power failure occurs. In addition, since the system automatic operation mode is automatically switched to the independent operation mode when a power failure occurs in the system power supply 4, the time required for the switching is shortened, and the electricity stored in the storage battery 2 is wasted. Can be reduced.

Although the embodiments of the present invention have been described above, the present invention is not limited to the configuration of the above-described embodiments. For example, as shown in FIG. 6, the control circuit 2091 may have a supply available time information generation unit 2921 and a transmission unit 2922. In FIG. 6, the same reference numerals as those in FIG. 2 are attached to the same configurations as those in the embodiment. The supplyable time information generation unit 2921 generates the supplyable time information indicating the power supply available time calculated by the supplyable time calculation unit 917 in the grid interconnection operation mode. The transmission unit 2922 transmits the supply available time information generated by the supply available time information generation unit 2921 to the terminal device 2093. The terminal device 2093 may be a mobile terminal device such as a smartphone. The transmission unit 2922 may transmit the supplyable time information to the terminal device 2093 via, for example, the Internet. Alternatively, the transmission unit 2922 may transmit the supplyable time information to the terminal device 2093 via a LAN (Local Area Network).

According to this configuration, the user can confirm the power supply available time calculated by the supplyable time calculation unit 917 via the terminal device 2093, so that the user's convenience can be enhanced.

In the embodiment, the determination unit 918 determines whether or not the supply of AC power from the system power supply 4 is cut off based on the input / output status between the inverter 32 and the first electric circuits L311 and L312. An example has been described in which the switch control unit 914 switches the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 to either the grid interconnection operation mode or the independent operation mode according to the determination result of the determination unit 918. .. However, the present invention is not limited to this, and as shown in FIG. 7, for example, a mode switching switch 3094 for the user to manually switch the modes of the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 is connected to the control circuit 3091. It may be the one that has been done. In FIG. 7, the same reference numerals as those in FIG. 2 are attached to the same configurations as those in the embodiment. In this case, the control circuit 3091 sets the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 into either a grid interconnection operation mode or an independent operation mode according to the operation content of the user's mode switching switch 3094. The configuration may have a mode setting unit 3923 to be set. For example, the mode changeover switch 3094 may have an independent operation start button (not shown) and a grid interconnection operation start button (not shown). In this case, when the user presses the independent operation start button, the mode setting unit 3923 sets the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 to the independent operation mode. On the other hand, when the user presses the grid interconnection operation start button, the mode setting unit 3923 sets the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 to the grid interconnection operation mode.

Here, the power conditioner control process executed by the control circuit 3091 according to this modification will be described with reference to FIG. In FIG. 8, the same reference numerals as those in FIG. 3 are attached to the same processes as the power conditioner control process executed by the control circuit 91 according to the embodiment. First, as shown in FIG. 8, a series of processes from steps S101 to S104 are executed. Then, in step S104, it is assumed that the determination unit 918 determines that the supply of AC power from the system power supply 4 to the system terminals teU and teW is not cut off (step S104: Yes). In this case, the electricity storage amount calculation unit 915 acquires the output voltage of the storage battery 2 measured by the voltmeter 331 from the voltage measurement value signal input from the voltmeter 331 (step S401). Next, the storage amount calculation unit 915 calculates the storage amount of the storage battery 2 based on the acquired output voltage of the storage battery 2 (step S402). Subsequently, the supplyable time calculation unit 917 described above based on the storage amount of the storage battery 2 calculated by the storage amount calculation unit 915 and the power consumption of the self-sustaining load 5 calculated by the power consumption calculation unit 916. The power supply available time of (step 403) is calculated. After that, the display control unit 919 causes the display unit 92 to display the information indicating the power supply available time calculated by the supply available time calculation unit 917 (step S404).

Next, the mode setting unit 3923 determines whether or not the independent operation start button has been pressed (step S405). When the mode setting unit 3923 determines that the independent operation start button has not been pressed within a preset time (step S405: No), the operation of the power conditioner is stopped (step S406), and the power conditioner is adjusted. The control process ends.

On the other hand, when the mode setting unit 3923 determines that the independent operation start button is pressed (step S405: No), the mode setting unit 3923 sets the switches SW11, SW12, SW21, SW22, SW23, SW3, and SW4 to the above-mentioned independent operation mode (step S405: No). Step S105). Subsequently, the determination unit 918 determines whether or not the supply of AC power from the system power supply 4 to the system terminals teU and teW is resumed (step S110). When the determination unit 918 determines that the state in which the supply of AC power from the system power supply 4 to the system terminals teU and teW is cut off continues (step S110: No), the process of step S106 is executed again. On the other hand, when the determination unit 918 determines that the supply of AC power from the system power supply 4 to the system terminals teU and teW is restarted (step S110: Yes), the process of step S101 is executed again.

According to this configuration, the user can freely select whether to continue or stop the operation of the power conditioner in a state where the power supply from the system power supply 4 is cut off, so that the convenience of the user can be improved. ..

In the embodiment, an example in which the ammeter 8 is connected between the second electric circuit L322 and the switch SW4 has been described, but the position of the ammeter 8 is not limited to this. For example, as in the power conditioner 4003 shown in FIG. 9, the ammeter 8 may be connected between the switch SW3 and the first electric circuit L311.

Hereinafter, embodiments and modifications of the present invention (including those described in the description; the same shall apply hereinafter) have been described, but the present invention is not limited thereto. The present invention includes an appropriate combination of embodiments and modifications, and an appropriate modification.

The present invention is suitable as a power conditioner for grid interconnection.

1: Solar battery, 2: Storage battery, 3,4003: Power conditioner, 4: System power supply, 5: Load, 8: Voltmeter, 31: PV converter, 32: Inverter, 33: DC-DC converter, 34,35 : Terminal block, 91, 2091, 3091: Control circuit, 92: Display unit, 331: Voltmeter, 911: PV converter control unit, 912: Inverter control unit, 913: DC-DC converter control unit, 914: Switch control unit , 915: Storage amount calculation unit, 916: Power consumption calculation unit, 917: Supplyable time calculation unit, 918: Judgment unit, 919: Display control unit, 2093: Terminal device, 2921: Supplyable time information generation unit, 2922: Transmission unit, 3094: Mode changeover switch, 3923: Mode setting unit, L3: HVDC bus, L311, L312: 1st electric circuit, L321, L322: 2nd electric circuit, SW11, SW12, SW21, SW22, SW23, SW3, SW4 : Switch, te351, te352: Independent operation terminal, teU, teW: System terminal, teO: Grounding electrode terminal

Claims (7)

DC bus line and
A DC-DC converter connected between the storage battery, the storage battery, and the DC bus line, which converts the DC voltage output from the storage battery into a preset constant voltage and outputs the DC voltage to the DC bus line.
An inverter connected to the DC bus line and converting a DC voltage supplied through the DC bus line into an AC voltage,
A pair of first electric circuits connected to the inverter and
A system terminal for supplying an AC voltage connected to the pair of first electric circuits and supplied from a system power supply to the pair of first electric circuits,
A self-sustaining operation terminal connected to the inverter via a pair of second electric circuits and for outputting an AC voltage to a load.
A first switch connected in series on the pair of first electric paths,
A second switch connected in series on the pair of second electric circuits,
One end is connected between the first switch and the system terminal in one of the pair of first electric circuits, and the other end is the second switch and the self-sustaining operation in one of the pair of second electric circuits. The third switch connected between the terminals and
A fourth switch whose one end is connected between the second switch and the self-sustained operation terminal on the other side of the pair of second electric circuits and whose other end is grounded.
A fifth switch whose one end is connected between the second switch and the self-sustaining operation terminal on the other side of the pair of second electric circuits and whose other end is grounded.
The first mode in which the first switch, the third switch, and the fourth switch are closed and the second switch and the fifth switch are in the open state, and the first switch, the third switch, and the said. A switch control unit for switching to either a second mode in which the fourth switch is in the open state and the second switch and the fifth switch are in the closed state is provided.
Power conditioner. A voltmeter that measures the output voltage of the storage battery,
An ammeter that measures the current flowing through the fourth switch in the first mode,
A storage amount calculation unit that calculates the storage amount of the storage battery based on the output voltage measured by the voltmeter, and
A power consumption calculation unit that calculates the power consumption of the load connected to the self-sustaining operation terminal based on the current value of the current flowing through the fourth switch measured by the ammeter in the first mode.
Based on the stored amount calculated by the stored amount calculation unit and the power consumption calculated by the power consumption calculation unit, it is possible to continue supplying power from the storage battery to the load in the second mode. It is further equipped with a supplyable time calculation unit that calculates a power supplyable time.
The power conditioner according to claim 1. In the second mode, the display unit further includes a display unit that displays information indicating the power supply available time calculated by the supply available time calculation unit.
The power conditioner according to claim 2. In the second mode, a supplyable time information generation unit that generates supplyable time information indicating the power supplyable time calculated by the supplyable time calculation unit, and a supplyable time information generation unit.
A transmission unit that transmits the supplyable time information generated by the supplyable time information generation unit to the terminal device is further provided.
The power conditioner according to claim 2 or 3. Further provided with a determination unit for determining whether AC is supplied from the system power supply to the system terminal or whether AC supplied from the system power supply to the system terminal is cut off.
When the determination unit determines that alternating current is being supplied from the system power supply to the system terminal, the switch control unit includes the first switch, the second switch, the third switch, the fourth switch, and the like. When the fifth switch is switched to the first mode and it is determined that the alternating current supplied from the system power supply to the system terminal is cut off, the first switch, the second switch, the third switch, and the above The fourth switch and the fifth switch are switched to the second mode.
The power conditioner according to any one of claims 1 to 4. The system power supply is a single-phase three-wire system that supplies AC power to the system terminals.
The system terminal has a grounding electrode terminal and has a grounding electrode terminal.
The other end of the fourth switch is connected to the grounding electrode terminal.
The power conditioner according to any one of claims 1 to 5. A PV converter connected to the DC bus line to convert the DC power generated by the power generation facility and output to the DC bus line is further provided.
The power conditioner according to any one of claims 1 to 6.

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