JP7089960B2 - Power conditioner and power storage system - Google Patents

Description

The present invention relates to a power conditioner and a power storage system.

By combining a solar power generation system with an electric vehicle, storage battery, etc., the electricity generated by solar power generation is stored in the storage battery during the day, and the electricity is transferred to the electric vehicle at night. The development of a tribrid power storage system (application trademark) that can cope with a long-term power failure by using the stored electricity is being promoted (see, for example, Non-Patent Document 1).

Further, in such a distributed power supply system, a plurality of input sources such as a grid power supply, a solar panel, and a storage battery, a power bus that receives and outputs inputs from these plurality of input sources, and an input that is output from the power bus. A power interchange system is configured with a storage battery that centrally receives power from the source, a battery for EV (electric vehicle), and multiple output sources of system power supply (regeneration), and for input control between multiple input sources. By giving priority to the power bus in descending order of set voltage and controlling the input to the power bus, and giving priority to the output to multiple output sources in ascending order of set voltage, control is performed among multiple power devices. A system is also disclosed in which priorities are given, input / output control is performed from the highest priority to a certain set value, and the excess or deficiency of the power surplus is reduced by the power device with the lower priority. (See, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2018-38126

Tribrid power storage system, [online], Nichicon Corporation, [Search on June 1, 2018], Internet <URL: http://www.nichicon.co.jp/products/tribrid/>

However, in the invention described in Patent Document 1, the priority and the output voltage are associated with each other so that the higher the output priority is, the higher the output voltage is, and the output priority is always fixed.
Therefore, when the voltage of the power bus (hereinafter referred to as "intermediate voltage") is set to the output voltage of the source with high output priority, and the power supply from the source with high output priority becomes impossible for some reason. In addition, there is a problem that the desired electric power cannot be supplied to the electric power bus (furthermore, the load connected to the electric power bus).

Further, if the power consumption of the load is larger than the power supplied from the source having a higher output priority, the intermediate voltage drops. In this case, the intermediate voltage is the output of the source having a higher priority. Power could not be supplied from sources below the voltage and with higher priority, which could lead to system problems.

Therefore, the present invention has been made in view of the above-mentioned problems, and even when the power supply from the supply source having a high output priority becomes impossible, the desired power is supplied to the power bus and the intermediate voltage is supplied. The main purpose is to provide a power conditioner and a power storage system capable of maintaining a proper value.

Embodiment 1; One or more embodiments of the present invention include an inverter that converts DC power supplied via a power bus from a plurality of sources that supply DC power into AC power, and a predetermined output priority. Based on the order, the output voltage of the source having the higher output priority among the plurality of sources so as to be supplied with power to the power bus is higher than the output voltage of the source having the lower output priority. The control unit is provided with a control unit that selects and controls the power supply source to supply power to the power bus, and the control unit determines that the supply source having a high output priority cannot output. While maintaining the output priority, the output voltage of the supply source having a low output priority and being in an output-capable state can be reduced to the output voltage of the supply source having a high output priority determined to be in the output-unable state. We are proposing a power conditioner that boosts power and supplies power to the power bus from a source with a lower output priority.

Embodiment 2; In one or more embodiments of the present invention, the control unit supplies the supply when the supply source having the higher output priority is in the operation stop range based on the detection information from the supply source. We are proposing a power conditioner that determines that the source is in an unoutput state.

Embodiment 3; In one or more embodiments of the present invention, at least one of the plurality of supply sources is a storage battery, and the control unit has the output priority order based on the residual storage capacity information from the storage battery. We propose a power conditioner that determines that the storage battery is in an output-disabled state when the residual storage capacity of the high storage battery is equal to or less than the specified value or the residual capacity value set by the user.

Embodiment 4; One or more embodiments of the present invention is the power conditioner according to any one of Embodiments 1 to 3 in which AC power is supplied from the inverter to the load, and the control unit is the load. When the power consumption of the power is larger than the power supplied from the source having the higher output priority and the voltage value of the power bus drops to the output voltage of the source having the lower output priority, the output priority is high. We are proposing a power conditioner that supplies power from a supply source having a lower output priority to the power bus as well as power supply from the supply source.

Embodiment 5; In one or more embodiments of the present invention, charge / discharge control is performed on a power generation device that generates electric power by using renewable energy as the plurality of supply sources and an in-vehicle storage battery mounted on an electric vehicle. In a power storage system equipped with a V2H stand and a stationary storage battery unit, it is determined to be a power conditioner including an inverter that converts DC power supplied from the plurality of supply sources via a power bus into AC power. The output voltage of the supply source having the higher output priority among the plurality of supply sources excluding the power generation device is used as the output voltage of the source having the lower output priority so that the power is supplied to the power bus based on the output priority. A control unit that is set to be higher than the output voltage and that selects and controls the power source to supply power to the power bus is provided, and the control unit outputs the power source having the higher output priority. When it is determined that the output is not possible, the output priority is low while maintaining the output priority, and the output voltage of the supply source that is in the output enable state is high in the output priority that is determined to be in the output impossible state. We are proposing a power storage system that boosts the power to the output voltage of the power source and supplies power to the power bus from the power source with the lower output priority.

Embodiment 6; In one or more embodiments of the present invention, there is substantially no power supply from the power generation device to the power bus, and the source of either the stationary storage battery unit or the V2H stand. When is determined to be prioritized over the other source, the control unit consumes the load greater than the power supplied from the one source and the voltage value of the power bus is the other. When the voltage drops to the output voltage of the supply source of the above, a power storage system is proposed in which the power of the other supply source is supplied to the power bus as well as the power supply from the one supply source.

Embodiment 7; In one or more embodiments of the present invention, power is supplied from the power generation device to the power bus, and the source of either the stationary storage battery unit or the V2H stand is the other source. When it is determined to give priority to, the control unit consumes the load larger than the power supplied from the power generation device, and the voltage value of the power bus becomes the output voltage of the one supply source. We have proposed a power storage system in which the power from one of the power sources is supplied to the power bus as well as the power supplied from the power generation device.

8; In one or more embodiments of the present invention, power is supplied from the power generation device to the power bus, and the source of either the stationary storage battery unit or the V2H stand is the other source. When it is determined to give priority to, the control unit has the power consumption of the load larger than the sum of the power supplied from the power generation device and the power supplied from one of the power sources. We propose a power storage system in which when the voltage value of the bus drops to the output voltage of the other supply source, the power of the other supply source is supplied to the power bus together with the sum power.

According to one or more embodiments of the present invention, there is an effect that the intermediate voltage can be maintained at an appropriate value even when the voltage output of the power source having the highest priority cannot be supplied.
This also has the effect of preventing system problems.
Furthermore, there is an effect that it is possible to construct a system that reflects the intention of the user while preventing problems on the system.

It is a block diagram of the power storage system which concerns on 1st Embodiment of this invention. It is a block diagram of the power conditioner which concerns on 1st Embodiment of this invention. It is a figure which showed the priority order and the intermediate voltage of each power source which concerns on 1st Embodiment of this invention. It is a processing flow of the control part which concerns on 1st Embodiment of this invention. It is a processing flow of the control part which concerns on 1st Embodiment of this invention. It is a processing flow of the control part which concerns on 1st Embodiment of this invention. It is a figure which showed the priority order and the intermediate voltage of each power source when the voltage output of the power source of the highest priority which concerns on 1st Embodiment of this invention becomes unsupplyable. It is a processing flow of the control part which concerns on the 2nd Embodiment of this invention. It is a figure which showed the transition of the intermediate voltage in a plurality of sources which concerns on 2nd Embodiment of this invention. It is a figure which showed the transition of the intermediate voltage in a plurality of sources which concerns on 2nd Embodiment of this invention. It is a figure which showed the transition of the intermediate voltage in a plurality of sources which concerns on 2nd Embodiment of this invention.

<First Embodiment>
The first embodiment of the present invention will be described with reference to FIGS. 1 to 7.

<Configuration of power storage system>
Hereinafter, the configuration of the power storage system 10 according to the present embodiment will be described with reference to FIG. 1.
In this embodiment, a configuration in which a control unit described later is provided in the power conditioner will be described as an example, but a configuration in which the control unit is provided in a power conditioner other than the power conditioner may be used.

The power storage system 10 according to the present embodiment includes a single-function power storage system (a power storage system in which a solar power conditioner is separated) and a multifunctional power storage system (a solar power conditioner and a storage battery connected to a solar cell). It is a power storage system that can be used for both a power storage power conditioner connected to a unit and a charge / discharge circuit connected to an electric vehicle), and is particularly used as a supply source for supplying DC power. In addition to solar cells, it is suitable for an on-vehicle storage battery mounted on an electric vehicle such as an electric vehicle (EV) or a fuel cell vehicle, or a power storage system to which a plurality of sources of a stationary storage battery unit are connected.
Here, it is optional to connect the solar cell as a supply source, and it is sufficient that a plurality of DC power supply sources are connected. Further, the DC power supply source may be one that converts the power generated by AC power generation such as hydroelectric power generation and wind power generation into DC power by a converter and supplies it.

As shown in FIG. 1, the power storage system 10 according to the present embodiment includes a breaker 110 for a storage battery system, a power conditioner 200, a stationary storage battery unit 240, and a V2H (Vehicle to Home) connected to an electric vehicle 260. ) The stand 250, the solar cell module (power generation device) 300, the main breaker 410, the branch breaker 420, the changeover switch 430, and the important load branch breaker 440 are included.
As shown in FIG. 1, a commercial grid interconnection device 500 such as ENE-FARM (registered trademark) may be connected to the commercial power system side of the main circuit breaker 410.

The breaker 110 for the storage battery system is constantly supplied with electric power from commercial power. For example, when an abnormality occurs in the power conditioner 200 or the storage battery unit 240, the breaker 110 for the storage battery system operates to cut the electric circuit. Open.

The power conditioner 200 is connected to a commercial power system via a breaker 110 for a storage battery system, and is a power generation module using renewable energy such as a solar battery module 300 that generates power by sunlight, or a stationary storage battery unit. It is said that it can be connected to an electric vehicle 260 having a power supply function to the outside via 240 (hereinafter, simply referred to as "stationary storage battery") or V2H stand 250.

The power conditioner 200 converts, for example, DC power (generated power) generated by renewable energy such as sunlight and DC power (discharge power) from the stationary storage battery 240 into a predetermined voltage by a converter, and then AC. In addition to converting to electric power, DC power (discharge power) from the V2H stand 250 is converted to AC power. The converted AC power can be supplied to the system output connected to the critical load and the general load via the breaker 110 for the storage battery system.
Further, the power generated from the solar cell module 300 and / or the commercial power converted into DC power is used as the charging power, and is mounted on the electric vehicle 260 via the stationary storage battery 240 and / or the V2H stand 250 via the converter. It is possible to charge the in-vehicle storage battery 261 (FIG. 2).

<Structure of power conditioner>
As shown in FIG. 2, the power conditioner 200 includes converters 211 and 212, an inverter 221 and a control unit 230, and an output priority setting unit 231. The following configuration is an example, and other configurations may be used as long as they can perform the same function.

The converter 211 converts the DC power boosted to a predetermined DC voltage based on the DC power from the solar cell module 300.

The converter 212 converts the DC power (discharge power) from the stationary storage battery 240 into boosted DC power. The converter 212 is a stationary storage battery 240 using DC power converted from commercial power converted to DC power by the inverter 221 into a predetermined DC voltage or DC power from another source such as the solar cell module 300 as charging power. It is a bidirectional converter that supplies power to.

The inverter 221 converts the DC power generated by renewable energy such as sunlight including the power generated by the solar cell module 300 into AC power, and also converts the DC power (discharge power) from the stationary storage battery 240 or the V2H stand 250. ) Is converted to AC power.
Further, in order to charge the stationary storage battery 240 and / or the in-vehicle storage battery 261, commercial power is converted into DC power.

The control device 222 controls the inverter 221 and various converters.

The control unit 230 outputs the output voltage to the converter 212 or the V2H stand 250 so as to output the determined output priority and the voltage associated with the output priority to the in-vehicle storage battery 261 and the stationary storage battery 240. Take control.
The output priority and the voltage value associated with the output priority are stored in an internal RAM (Random Access Memory) or the like (not shown). Further, the output priority of the in-vehicle storage battery 261 and the stationary storage battery 240 is determined based on the output priority set by the user via the output priority setting unit 231 described later.

Further, the control unit 230 communicates with the stationary storage battery 240 via the communication line to acquire, for example, information on the residual storage capacity and temperature of the stationary storage battery 240.
Further, the control unit 230 communicates with the electric vehicle 260 via the V2H stand 250 using, for example, CAN communication, and acquires information and the like regarding the residual storage capacity of the in-vehicle storage battery 261.
Further, if the temperature information of the vehicle-mounted storage battery 261 is detected on the electric vehicle 260 side, the control unit 230 also acquires the temperature information of the vehicle-mounted storage battery 261.

Then, the control unit 230 compares the residual storage capacity of the acquired stationary storage battery 240 or the residual storage capacity of the in-vehicle storage battery 261 with a predetermined specified value or a specified value set by the user.
Further, the control unit 230 compares the temperature information of the stationary storage battery 240 or the temperature information of the in-vehicle storage battery 261 with the temperature in the operation stop range.
Further, the control unit 230 monitors the intermediate voltage. Here, the intermediate voltage means a voltage on the power bus PB connecting the inverter 221 (DC side), the converters 211, 212, and the bidirectional converter 251.
The standard value of the residual storage capacity is stored in, for example, a RAM or the like, and information such as an operation stop range due to temperature is stored in, for example, a ROM (Read Only Memory) inside the control unit 230 (not shown). There is.

The output priority setting unit 231 is provided in a housing of the power conditioner 200, a remote controller for controlling the power storage system 10, and the like, and for example, the output priority is set by user operation.
The output priority setting in the output priority setting unit 231 may be performed by key input of a switch or the like, or by touching a button displayed on the touch panel.
For example, as shown in FIG. 3, when the priority of the initial setting is the above figure, the user sets the priority of the stationary storage battery 240 to be the highest via the output priority setting unit 231. When this is done, the control unit 230 rewrites the stored information of the RAM as shown in the lower figure of FIG. 3 according to the setting.

<Structure of V2H stand>
The V2H stand 250 has a built-in bidirectional converter 251, and the bidirectional converter 251 converts the DC power (discharge power) from the in-vehicle storage battery 261 into boosted DC power, while the inverter 221 converts it into DC power. DC power obtained by converting commercial power into a predetermined DC voltage or DC power from another source such as the solar cell module 300 is supplied to the in-vehicle storage battery 261 as charging power.
As these converters, for example, a step-up or buck-boost chopper type converter can be exemplified.

Further, the V2H stand 250 is connected to the power conditioner 200 by a communication cable, and is charged / discharged controlled based on a control command from the power conditioner 200, and the power conditioner 200 is connected to the power conditioner 200 by using the communication cable. It is possible to output the state of the in-vehicle storage battery 261 and the like.

<About other configurations>
In the solar cell module 300, a plurality of solar cell cells are arranged and protected by glass, resin, or a frame, and are generally called a solar panel or a solar cell panel.

Output power from commercial power is constantly supplied to the main breaker 410. For example, an abnormal overcurrent flows in the secondary circuit (load, electric circuit, etc.) due to factors such as electric leakage, overload, and short circuit. At that time, the main breaker 410 operates to open the electric circuit.
The main circuit breaker 410 is a breaker having a trip function.

One end of the branch breaker 420 is connected to the main breaker 410, and the other end is connected to each general load.

The changeover switch 430 can be switched between the commercial power system output side and the self-sustaining output side. In the normal state (during commercial power interconnection), the changeover switch 430 is connected to the self-sustaining output side, and commercial power is supplied to the important load via the breaker 110 for the storage battery system and the power conditioner 200.
Further, commercial power is supplied to the general load via the main breaker 410. On the other hand, in the event of a power failure, the commercial power system and the power conditioner 200 are disconnected, and the power based on at least one of the storage battery unit 240, the V2H stand 250 (vehicle-mounted storage battery) and the solar cell module 300 becomes an important load from the power conditioner 200. It can be supplied.
Further, when the breaker 110 for the storage battery system is in the off state, such as when the power conditioner 200 fails, by manually switching the changeover switch 430 to the system output side, commercial power is supplied to the important load via the main breaker 410. Be supplied.

One end of the critical load branch breaker 440 is connected to the changeover switch 430, and the other end is connected to each critical load. Here, as the important load, lighting, a refrigerator, an air conditioner, and the like can be exemplified.

When the commercial grid interconnection device 500 is connected to the grid output, the power supplied from the commercial grid interconnection device 500 can be supplied to the critical load and the general load.

<Processing of control unit>
Specific processing of the control unit 230 will be described with reference to FIG.

As shown in the upper figure of FIG. 3, the control unit 230 sets the output priority of the V2H stand 250 capable of outputting the discharge power from the in-vehicle storage battery 261 via the output priority setting unit 231 to be the highest. When is set, control is performed based on the initial settings in the above figure.
Here, it is assumed that the power generated from the solar cell module 300 is not substantially supplied.
Specifically, the V2H stand 250 is set to the highest priority, and the output voltage (inverter 221 side) from the V2H stand 250 is 390 V for the control unit in the V2H stand 250, for example, by using CAN communication. A control signal for controlling the bidirectional converter 251 in the V2H stand 250 is transmitted (step S110).
On the other hand, the output voltage of the converter 212 connected to the stationary storage battery 240 is set to 370V.
Therefore, the intermediate voltage is boosted to the output voltage 390V of the V2H stand having a higher voltage value, and the discharge power of the vehicle-mounted storage battery 261 is supplied from the V2H stand 250 having a higher output priority to the power bus PB.

On the other hand, when the user has set the output priority of the stationary storage battery 240 to be the highest via the output priority setting unit 231, control is performed based on the setting shown in the lower figure of FIG.
Here, too, it is assumed that the power generated from the solar cell module 300 is not substantially supplied.
Specifically, the stationary storage battery 240 is set to the highest priority, and the converter 212 is controlled so that the output voltage from the converter 212 becomes 390V with respect to the converter 212 connected to the stationary storage battery 240 (step S110). ).
On the other hand, the output voltage of the V2H stand 250 is set to 370V.
Therefore, the intermediate voltage is boosted to the output voltage 390V of the converter 212 connected to the stationary storage battery 240 having a high voltage value, and the discharge power from the stationary storage battery 240 having a high output priority is supplied to the power bus PB.

The control unit 230 acquires the residual storage capacity of the storage battery from the highest storage battery (stationary storage battery 240 or in-vehicle storage battery 261) at a predetermined timing during operation (step S120).

Then, the control unit 230 compares the residual storage capacity acquired from the highest storage battery with the predetermined standard value of the residual storage capacity (step S130).
Here, the standard value of the residual storage capacity means the residual storage capacity in a state where the storage battery cannot be output (discharged).

As a result of the comparison in step S130, when it is determined that the acquired residual storage capacity is equal to or higher than the predetermined standard value of the residual storage capacity (“NO” in step S130), the control unit 230 processes the process in step S120. return.
Whether or not the threshold value (specified value) is included in the comparison determination can be appropriately changed.

On the other hand, when it is determined as a result of comparison in step S130 that the acquired residual storage capacity is smaller than the predetermined standard value of the residual storage capacity (“YES” in step S130), the control unit 230 determines. For example, as shown in FIG. 7, the output voltage from the storage battery whose output priority is next and is in the output enable state is boosted (step S140).
Specifically, as shown in FIG. 7, when the output priority of the stationary storage battery 240 is higher than that of the V2H stand 250, the stationary storage battery 240 is connected to the in-vehicle storage battery 261 in an output capable state while maintaining the output priority. The V2H stand 250 (bidirectional converter 251) is used to boost the output voltage of the V2H stand 250 from 370V before the change to 390V and to change the output voltage of the converter 212 connected to the stationary storage battery 240 from 390V to 370V. ) And the converter 212.
As a result, the discharge power from the V2H stand 250 (vehicle-mounted storage battery 261) is supplied to the power bus PB instead of the stationary storage battery 240.
When the V2H stand 250 is not in the output enable state, the output priority is further lower and the output voltage of the supply source in the output enable state is boosted.

In the example shown in FIG. 5, when the temperature of the storage battery whose output priority is set to the highest by the user is within the operation stop temperature range, the control unit 230 controls as follows (step S210).

The control unit 230 acquires the temperature information of the highest-level storage battery at a predetermined timing during operation (step S220).

Then, the control unit 230 compares the acquired temperature information with the predetermined operation stop temperature (step S230).

If, as a result of the comparison in step S230, it is determined that the acquired temperature is equal to or lower than the predetermined operation stop temperature (“NO” in step S230), the control unit 230 returns the process to step S220.
Whether or not the threshold value (operation stop temperature) is included in the comparison determination can be appropriately changed.

On the other hand, when it is determined as a result of comparison in step S230 that the acquired temperature is higher than the predetermined operation stop temperature (“YES” in step S230), the control unit 230 is, for example, shown in FIG. As shown, the output voltage from the storage battery in which the output priority is next and is in the output enable state is boosted (step S240).
Specifically, as shown in FIG. 7, when the output priority of the stationary storage battery 240 is higher than that of the V2H stand 250, the stationary storage battery 240 is connected to the in-vehicle storage battery 261 in an output capable state while maintaining the output priority. The V2H stand 250 (bidirectional converter 251) is used to boost the output voltage of the V2H stand 250 from 370V before the change to 390V and to change the output voltage of the converter 212 connected to the stationary storage battery 240 from 390V to 370V. ) And the converter 212.
As a result, the discharge power from the V2H stand 250 (vehicle-mounted storage battery 261) is supplied to the power bus PB instead of the stationary storage battery 240.
When the V2H stand 250 is not in the output enable state, the output priority is further lower and the output voltage of the supply source in the output enable state is boosted.

In the example shown in FIG. 6, when the residual storage capacity of the storage battery whose output priority is set to the highest by the user is smaller than the user-set capacity set by the user, the control unit 230 controls as follows. (Step S310).

The control unit 230 acquires the residual storage capacity of the storage battery from the highest storage battery (stationary storage battery 240 or in-vehicle storage battery 261) at a predetermined timing during operation (step S320).

Then, the control unit 230 compares the residual storage capacity acquired from the highest-level storage battery with the user-set capacity (step S330).

If, as a result of the comparison in step S330, it is determined that the acquired residual storage capacity is equal to or greater than the user-set capacity (“NO” in step S330), the control unit 230 returns the process to step S320.
Whether or not the threshold value (user-set capacity) is included in the comparison determination can be appropriately changed.

On the other hand, when it is determined as a result of comparison in step S330 that the acquired residual storage capacity is smaller than the user-set capacity (“YES” in step S330), the control unit 230 has, for example, the next output priority. The output voltage from the storage battery located at and in the output capable state is boosted (step S340).
Specifically, as shown in FIG. 7, when the output priority of the stationary storage battery 240 is higher than that of the V2H stand 250, the stationary storage battery 240 is connected to the in-vehicle storage battery 261 in an output capable state while maintaining the output priority. The V2H stand 250 (bidirectional converter 251) is used to boost the output voltage of the V2H stand 250 from 370V before the change to 390V and to change the output voltage of the converter 212 connected to the stationary storage battery 240 from 390V to 370V. ) And the converter 212.
As a result, the discharge power from the V2H stand 250 (vehicle-mounted storage battery 261) is supplied to the power bus PB instead of the stationary storage battery 240.
After that, for example, when the user-set capacity is changed downward by the user, the stationary storage battery 240 becomes in a dischargeable state.
In this case, the output voltage of the converter 212 connected to the stationary storage battery 240 is boosted from 370V before the change to 390V, and the V2H stand 250 connected to the in-vehicle storage battery 261 is changed from 390V to 370V. , Converter 212 and V2H stand 250 (bidirectional converter 251).
As a result, the discharge power from the stationary storage battery 240 is supplied to the power bus PB instead of the V2H stand 250 (vehicle-mounted storage battery 261).

As described above, according to the present embodiment, the inverter 221 that converts the DC power supplied via the power bus PB from a plurality of supply sources that supply the DC power into AC power, and a predetermined output. Based on the priority, the output voltage of the source with the higher output priority among multiple sources is set to be higher than the output voltage of the source with the lower output priority so that the power is supplied to the power bus PB. At the same time, the control unit 230 is provided with a control unit 230 that selects and controls a supply source to supply power to the power bus PB, and the control unit 230 gives priority to output when it is determined that a supply source having a high output priority cannot output. While maintaining the order, the output voltage of the supply source with low output priority and output enable state is boosted to the output voltage of the supply source with high output priority determined to be in the output impossible state, and the output priority is increased. Controls the power bus PB to be powered from a low source.
That is, when the control unit 230 determines that the supply source having a high output priority (for example, the stationary storage battery 240) is in the output impossible state, the control unit 230 other than the supply source in which the output priority is maintained and the output is not possible. The output voltage of the supply source (for example, the V2H stand 250 connected to the vehicle-mounted storage battery 261) is boosted to maintain the voltage of the power bus PB, that is, the intermediate voltage.
Therefore, the intermediate voltage value can be maintained at an appropriate value even when the supply source having a high output priority becomes unable to output. In addition, this can prevent problems in the system.

Further, according to the present embodiment, the control unit 230 states that when the supply source having a high output priority is in the operation stop range, the supply source is in the output disabled state based on the detection information from the supply source. to decide.
Therefore, by accurately determining the output disabled state of a supply source such as a storage battery having a high output priority, the intermediate voltage value is maintained at an appropriate value even when the power source with a high priority becomes an output disabled state. can.
In addition, this can prevent problems in the system.

Further, according to the present embodiment, at least one of the plurality of supply sources is a storage battery, and the control unit 230 has a specified value of the residual storage capacity of the storage battery having a high output priority based on the residual storage capacity information from the storage battery. Alternatively, when it is equal to or less than the residual capacity value set by the user, it is determined that the storage battery unit is in the output disabled state.
Therefore, by accurately determining the output disabled state of the storage battery having a high output priority, the intermediate voltage value can be maintained at an appropriate value even when the storage battery having a high output priority is output disabled.
In addition, this can prevent problems in the system.

<Second embodiment>
The difference between the present embodiment and the first embodiment is that the control unit 230 has the following functions in addition to the functions described in the first embodiment. Hereinafter, the control unit of this embodiment will be referred to as "control unit 230A".

<Processing of control unit>
Specific processing of the control unit 230A will be described with reference to FIGS. 8 to 11.

The control unit 230A determines whether or not power is supplied from the solar cell module (power generation device) 300 to the power bus PB (step S410).
At this time, when the control unit 230A determines that the power supply from the solar cell module (power generation device) 300 to the power bus PB is substantially nonexistent (“No” in step S410), then the power bus PB It is determined whether or not the voltage (intermediate voltage) is lower than the output power of the supply source (stationary storage battery 240 in FIG. 9) having a high output priority (step S420).

Then, when the control unit 230A determines that the intermediate voltage is lower than the output voltage of the supply source (stationary storage battery 240 in FIG. 9) having a high output priority (“Yes” in step S420), the control unit 230A determines. The converter 212 is controlled so as to supply power from a supply source having a high output priority (stationary storage battery 240 in FIG. 9) to the power bus PB (step S430).
Here, when the power consumption of the load is larger than the discharge power from the stationary storage battery 240, the intermediate voltage decreases.
Then, when the intermediate voltage drops to the output voltage of 370V of the supply source having a low output priority (V2H stand 250 in FIG. 9) (“Yes” in step S440), the discharge from the V2H stand 250 is also started, and the power bus is started. Discharge power from the V2H stand 250 is supplied to the PB together with the discharge power from the stationary storage battery 240 (step S450).
This makes it possible to make up for the shortage of load power consumption.
Further, when the control unit 230A determines that the intermediate voltage is equal to or higher than the output voltage of the supply source having the higher output priority (“No” in step S420), and the intermediate voltage is equal to or higher than the output voltage of the supply source having the lower output priority. When the determination (“No” in step S440) is made, the process is returned to step S410.

On the other hand, in step S410, when the control unit 230A determines that the power is supplied from the solar cell module (power generation device) 300 to the power bus PB (“Yes” in step S410), the control unit 230A is next. In addition, it is determined whether or not the intermediate voltage is lower than the output voltage of the supply source having a high output priority (stationary storage battery 240 in FIG. 10) (step S460).

At this time, when the control unit 230A determines that the intermediate voltage is higher than the output voltage of the supply source (stationary storage battery 240 in FIG. 10) having a high output priority (“No” in step S460), the control unit 230A Returns the process to step S410.
In this case, it means that the power consumption of the load is covered by the power generated from the solar cell module 300 (the generated power is larger than the power consumption of the load).

On the other hand, when the power consumption of the load is larger than the power generated from the solar cell module 300, the intermediate voltage decreases. Then, when the intermediate voltage drops to the output voltage of 390 V of the supply source having a high output priority (stationary storage battery 240 in FIG. 10) (“Yes” in step S460), the discharge from the stationary storage battery 240 is also started. The electric power bus PB is supplied with the electric power generated from the solar cell module 300 and the electric power discharged from the stationary storage battery 240 (step S470).
This makes it possible to make up for the shortage of load power consumption.

Next, the control unit 230A determines whether or not the intermediate voltage is lower than the output voltage of the supply source having a lower output priority (for example, the V2H stand 250 in FIG. 11) (step S480).

When the power consumption of the load is larger than the sum of the power generated from the solar cell module 300 and the discharge power from the supply source having a high output priority (stationary storage battery 240 in FIG. 11), the intermediate voltage decreases. ..
Then, when the intermediate voltage drops to the output voltage of 370V of the supply source having a low output priority (V2H stand 250 in FIG. 11) (“Yes” in step S480), the discharge from the V2H stand 250 is also started, and the power bus is started. Discharge power from the V2H stand 250 is supplied to the PB together with the above-mentioned sum power (step S490).
This makes it possible to make up for the shortage of load power consumption.
Further, when the control unit 230A determines that the intermediate voltage is equal to or higher than the output voltage of the supply source (stationary storage battery 240) having a high output priority (“No” in step S460), and the supply source having a low output priority (V2H). When it is determined that the output voltage of the stand 250) or higher (“No” in step S480), the process is returned to step S410.

As described above, according to the present embodiment, in addition to the functions described in the first embodiment, the power consumption of the load of the control unit 230A is larger than the power supply from the source having a high output priority. When the intermediate voltage value drops to the output voltage of the source with the lower output priority, the power bus PB is supplied with the power from the source with the higher output priority as well as the power from the source with the lower output priority. Take control.
Therefore, even if the power consumption of the load is large and the intermediate voltage value drops to the output voltage of the source with the lower output priority, the power from the source with the lower output priority is also supplied to the power bus. By doing so, the intermediate voltage can be maintained at the output voltage of the source having a low output priority, and the shortage of the power consumption of the load can be compensated.

Further, according to the present embodiment, there is substantially no power supply from the solar cell module (power generation device) 300 to the power bus PB, and one of the supply sources of the stationary storage battery 240 and the V2H stand 250 is the other. When it is determined to give priority to the supply source, the control unit 230A consumes a load larger than the power supplied from one source, and the voltage value (intermediate voltage value) of the power bus PB decreases. When the voltage drops to the output voltage of the other supply source, the power is supplied from one supply source as well as the power of the other supply source to the power bus PB.
Therefore, even if the power consumption of the load is large and the intermediate voltage value drops to the output voltage of the source with the lower output priority (the other source), the power from the source with the lower output priority is also the power. By controlling the supply to the bus PB, the intermediate voltage can be maintained at the output voltage of the supply source having a low output priority, and the shortage of the power consumption of the load can be compensated.

Further, according to the present embodiment, power is supplied from the solar cell module (power generation device) 300 to the power bus, and one of the supply sources of the stationary storage battery 240 and the V2H stand 250 has priority over the other supply source. When it is determined to cause the control unit 230A, the power consumption of the load is larger than the power supply from the solar cell module (power generation device) 300, and the intermediate voltage value is lowered to the output voltage of one of the supply sources. When it decreases, the power is supplied from the solar cell module (power generation device) 300, and the power of one of the supply sources is also controlled to be supplied to the power bus PB.
Therefore, even if the power consumption of the load is large and the intermediate voltage value drops to the output voltage of the source with the higher output priority (one source), the power from the source with the higher output priority is also the power. By controlling the supply to the bus PB, the intermediate voltage can be maintained at the output voltage of the supply source having a high output priority, and the shortage of the power consumption of the load can be compensated.

Further, according to the present embodiment, power is supplied from the solar cell module (power generation device) 300 to the power bus PB, and one of the supply sources of the stationary storage battery 240 and the V2H stand 250 is supplied to the other supply source. When it is determined to give priority, the control unit 230A consumes an intermediate voltage in which the power consumption of the load is larger than the sum of the power supplied from the solar cell module (power generation device) 300 and the power supplied from one of the sources. When the value drops to the output voltage of the other supply source, control is performed so that the power of the other supply source is supplied to the power bus PB as well as the sum power.
Therefore, even if the power consumption of the load is large and the intermediate voltage value drops to the output voltage of the source with the lower output priority (the other source), the power from the source with the lower output priority is also the power. By controlling the supply to the bus, the intermediate voltage can be maintained at the output voltage of the supply source having a low output priority, and the shortage of the power consumption of the load can be compensated.

Although the embodiments and examples of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to the embodiments or the embodiments and does not deviate from the gist of the present invention. Design etc. are also included.
For example, in the embodiment of the power storage system, two types of a stationary storage battery and a V2H stand are shown as a plurality of supply sources other than the power generation device (installation of the power generation device is optional), but the present invention is not limited to this.
For example, the power storage system may be provided with the same type of DC source as a plurality of supply sources other than the power generation device, or may be provided with three or more types of DC sources.
Further, in the above embodiment, it is determined whether or not the supply source is in the operation stop range based on the temperature information from the supply source (storage battery), but the detection information is not limited to this, and the abnormality of the supply source is not limited to this. -It may be determined whether or not the operation is within the operation stop range based on the information on the operation / stop such as the failure state.

10; Power storage system 110; Breaker for storage battery system 130; Main breaker 200; Power conditioner 211; Converter 212; Bidirectional converter 221; Inverter 222; Control device 223; Protection device 230; Control unit 231; Output priority setting unit 240 Stationary storage battery 250; V2H stand 251; Bidirectional converter 260; Electric vehicle 261; In-vehicle storage battery 300; Solar battery module 410; Main breaker 420; Branch breaker 430; Changeover switch 440; Branch breaker 500 for critical load; Commercial grid connection System equipment

Claims (4)

An inverter that converts DC power supplied from multiple sources that supply DC power via a power bus into AC power,
Based on a predetermined output priority, the output voltage of the source having the higher output priority among the plurality of sources is output from the source having the lower output priority so that the power is supplied to the power bus. A control unit that is set to be higher than the voltage and selects and controls the supply source to supply power to the power bus.
Equipped with
When the control unit determines that the supply source having a high output priority cannot output, the output voltage of the supply source having a low output priority and being in an output capable state while maintaining the output priority. By changing the set value to the output voltage set value of the source having the higher output priority determined to be in the output impossible state, the output voltage of the source having the lower output priority is boosted , and the output priority is lower. A power conditioner characterized in that power is supplied from a supply source to the power bus. The control unit is characterized in that, based on the detection information from the supply source, when the supply source having a high output priority is in the operation stop range, the supply source is determined to be in an output-disabled state. The power conditioner according to claim 1. At least one of the plurality of sources is a storage battery.
Based on the residual storage capacity information from the storage battery, the control unit is in a state where the storage battery cannot be output when the residual storage capacity of the storage battery having a high output priority is equal to or less than a specified value or a user-set residual capacity value. The power conditioner according to claim 1 or 2, wherein the power conditioner is determined to be present. A power storage system equipped with a power generation device that uses renewable energy as multiple supply sources to generate electricity, a V2H stand that controls charge / discharge of the in-vehicle storage battery mounted on the electric vehicle, and a stationary storage battery unit. In
A power conditioner including an inverter that converts DC power supplied from the plurality of supply sources via a power bus into AC power.
The output voltage of the supply source having the higher output priority among the plurality of supply sources excluding the power generation device is supplied with the lower output priority so that the power is supplied to the power bus based on the determined output priority. A control unit that selects and controls the supply source to supply power to the power bus while setting the voltage to be higher than the output voltage of the source.
Equipped with
When the control unit determines that the supply source having a high output priority cannot output, the output voltage of the supply source having a low output priority and being in an output capable state while maintaining the output priority. By changing the set value to the output voltage set value of the source having the higher output priority determined to be in the output impossible state, the output voltage of the source having the lower output priority is boosted, and the output priority is lower. A power storage system characterized in that power is supplied from a supply source to the power bus.

Images