JP6795968B2 - Power supply system - Google Patents

Description

The present invention relates to a technology of a power supply system having a power generation unit capable of generating electric power using natural energy and a storage battery capable of charging and discharging electric power.

Conventionally, a technique of a power supply system having a power generation unit capable of generating electric power using natural energy and a storage battery capable of charging and discharging electric power has been known. For example, as described in Patent Document 1.

The power supply system described in Patent Document 1 includes a power generation unit (photovoltaic power generation unit), a storage battery, and a hybrid power conditioner. The control unit of the hybrid power conditioner controls the storage battery according to the power generation state of the power generation unit and the like. As a result, the electric power generated by the power generation unit and the electric power discharged from the storage battery are supplied to the load.

However, in Patent Document 1, when a plurality of power generation units, storage batteries, and hybrid power conditioners are provided, the plurality of hybrid power conditioners individually control the storage batteries. In this case, there is a possibility that the storage battery on the downstream side is discharged even though the power generated by the power generation unit on the upstream side is reverse-flowed (photovoltaic power generation unit 2 (N) shown in FIG. 2 and Storage battery 3 (1)). In this case, the power generated by the power generation unit on the upstream side cannot cover the power consumption of the load. As described above, in the prior art, the power generation unit sells the power and the storage battery discharges the power at the same time, and the power generated by the power generation unit cannot be effectively utilized by the load.

Japanese Unexamined Patent Publication No. 2016-140125

The present invention has been made in view of the above circumstances, and the problem to be solved is to provide a power supply system capable of effectively utilizing the power generated by the power generation unit in a load. is there.

The problem to be solved by the present invention is as described above, and next, the means for solving this problem will be described.

That is, in claim 1, a first supply unit having a power generation unit capable of generating power using natural energy and supplying the generated power to a load, and a first supply unit rather than the first supply unit. It has a storage battery that is arranged on the load side and can charge the power generated by the first supply unit and the power from the system power source, and can discharge the charged power and supply it to the load. The second supply unit, the detection unit capable of detecting the power flowing back to the system power source, the detection result of the detection unit can be acquired, and the storage battery can be controlled, and the detection unit is configured. A control unit that regulates the discharge of the storage battery when the reverse power is detected is provided, and the control unit includes the storage battery when the detection unit detects the reverse power. Is changed to a state where it can be charged and cannot be discharged .

In the second aspect of the present invention, the control unit changes the storage battery to a non-dischargeable state when the detection unit detects the reverse power flow.

In claim 3, a first supply unit having a power generation unit capable of generating power by using natural energy and supplying the generated power to a load, and a load more than the first supply unit. A second storage battery, which is arranged on the side and can charge the power generated by the first supply unit and the power from the system power source, and can discharge the charged power and supply it to the load. The supply unit, the detection unit that can detect the power flowing back to the system power source, and the detection unit that can acquire the detection result of the detection unit and can control the storage battery, and the detection unit is the reverse It is provided with a control unit that regulates the discharge of the storage battery when the power to be flowed is detected, and the control unit discharges the storage battery when the detection unit detects the power to be flowed in the reverse direction. It is changed to an impossible state, and as a power supply mode, it has a first mode for selling the power generated by the power generation unit, and the storage battery has a first time in the first mode. During the period from to the second time to the second time, the discharge is possible, and in the first mode, the detection unit detects the power to be reverse-flowed, and the second time is the current state. When it is later than the time, the second time is set to the current time .

In claim 4, the control unit detects the power to be reverse power flowed by the detection unit in the first mode, and the second time is later than the current time. , The first time is set to a time when the power generation unit cannot generate electric power .

In claim 5, as the power supply mode, the storage battery has a first mode for selling the power generated by the power generation unit, and the storage battery starts from the third time in the first mode. Until the fourth time, the state becomes chargeable and undischargeable, and in the first mode, the detection unit detects the power to be reverse power flow, and the third time. Is later than the current time, the third time is set to the current time .

In claim 6, when the control unit detects the power to be reverse power flowed by the detection unit in the first mode and the third time is later than the current time. , The fourth time is set to a time when the power generation unit cannot generate electric power .

In the seventh aspect, as a power supply mode, there is a second mode for the purpose of consuming the electric power generated by the power generation unit with the load, and the control unit has the second mode in the second mode. When the detection unit detects the reverse power flow, the power supply mode of the storage battery is switched to the first mode .

In claim 8, a first supply unit having a power generation unit capable of generating electricity by using natural energy and supplying the generated power to a load, and a load more than the first supply unit. A second storage battery that is arranged on the side and can charge the electric power generated by the first supply unit and the electric power from the system power source, and can discharge the charged electric power and supply the charged electric power to the load. The supply unit, the detection unit that can detect the power flowing back to the system power supply, and the detection unit that can acquire the detection result of the detection unit and can control the storage battery, and the detection unit is the reverse A control unit that regulates the discharge of the storage battery when the power to be flowed is detected is provided, and the first supply unit charges the power generated by the power generation unit and the power from the system power source. It is possible to have a storage battery capable of discharging the charged electric power and supplying it to the load .

In claim 9, the first supply unit can charge the electric power generated by the power generation unit and the electric power from the system power source, and discharges the charged electric power to supply the charged electric power to the load. It has a possible storage battery.

In claim 10, a first supply unit having a power generation unit capable of generating power by using natural energy and supplying the generated power to a load, and a load more than the first supply unit. A second storage battery, which is arranged on the side and can charge the power generated by the first supply unit and the power from the system power source, and can discharge the charged power and supply it to the load. The supply unit, the detection unit that can detect the power flowing back to the system power source, and the detection unit that can acquire the detection result of the detection unit and can control the storage battery, and the detection unit is the reverse The second supply unit further includes a power generation unit capable of generating electricity by utilizing natural energy , and includes a control unit that regulates the discharge of the storage battery when the power to be flowed is detected. ..

As the effect of the present invention, the following effects are exhibited.

In claim 1, the electric power generated by the power generation unit can be effectively utilized by the load. In addition, the electric power generated by the power generation unit can be effectively utilized in the load and the storage battery.

In claim 2, the electric power generated by the power generation unit can be effectively utilized by the load.

In claim 3, the electric power generated by the power generation unit can be effectively utilized by the load. Moreover, the discharge of the storage battery can be easily stopped.

In claim 4, the electric power charged in the storage battery can be effectively utilized by the load.

In claim 5, the discharge of the storage battery can be easily stopped.

In claim 6, the electric power charged in the storage battery can be effectively utilized by the load.

In claim 7, when the power supply mode is the second mode, the charging of the storage battery can be regulated by using the first mode.

In claim 8, the electric power generated by the power generation unit can be effectively utilized by the load. In addition, the electric power generated by the power generation unit can be charged to many storage batteries.

In claim 9, many storage batteries can be charged with the electric power generated by the power generation unit.

In claim 10, the electric power generated by the power generation unit can be effectively utilized by the load. In addition, natural energy can be used to generate more electricity.

The block diagram which showed the power supply system which concerns on 1st Embodiment. A block diagram showing a power selling / discharging state. The flowchart which showed the discharge stop processing when the power sale mode is set. The block diagram which showed the state after executing the discharge stop processing. A flowchart showing the discharge stop processing when the eco mode is set. In the second embodiment, the flowchart which showed the discharge stop processing when the power selling mode is set. In the second embodiment, the flowchart which showed the discharge stop processing when the eco mode is set. The block diagram which showed the power supply system which concerns on 3rd Embodiment. The block diagram which showed the power sale discharge state in 3rd Embodiment. The flowchart which showed the discharge stop processing at the time of setting the power sale mode in 3rd Embodiment. The block diagram which showed the state after executing the discharge stop processing in the 3rd Embodiment. The flowchart which showed the discharge stop processing when the eco mode is set in the 3rd Embodiment. FIG. 5 is a flowchart showing a discharge stop process when the power selling mode is set in the fourth embodiment. In the fourth embodiment, the flowchart which showed the discharge stop processing when the eco mode is set. The block diagram which showed the power supply system which concerns on 5th Embodiment. The block diagram which showed the power selling discharge state in 5th Embodiment. FIG. 5 is a flowchart showing a discharge stop process when the power selling mode is set in the fifth embodiment. FIG. 5 is a block diagram showing a state after executing the discharge stop process in the fifth embodiment. FIG. 5 is a flowchart showing a discharge stop process when the eco mode is set in the fifth embodiment. In the sixth embodiment, the flowchart which showed the discharge stop processing when the power selling mode is set. In the sixth embodiment, the flowchart which showed the discharge stop processing when the eco mode is set. The block diagram which showed the power supply system which concerns on 7th Embodiment.

Hereinafter, the power supply system 1 according to the embodiment of the present invention will be described with reference to FIGS. 1 to 5.

The power supply system 1 is provided in a house or the like, and supplies power from the system power supply K or power generated by using sunlight to the load H. The power supply system 1 mainly includes a first power storage system 1 (1) to an Nth power storage system 1 (N) and a control unit 60. Note that "N" in the Nth power storage system 1 (N) is a variable indicating the number of power storage systems installed, and specifically indicates that an integer of 2 or more is entered.

The first power storage system 1 (1) stores power generated by using sunlight and supplies it to the load H. The first power storage system 1 (1) includes a first photovoltaic power generation unit 2 (1), a first storage battery 3 (1), a first hybrid power conditioner 4 (1), and a first sensor 5 (1).

The first photovoltaic power generation unit 2 (1) is a device that generates electricity using sunlight. The first photovoltaic power generation unit 2 (1) is composed of a solar cell panel or the like. The first photovoltaic power generation unit 2 (1) is installed in a sunny place such as on the roof of a house.

The first storage battery 3 (1) is configured to be rechargeable with electric power. The first storage battery 3 (1) is composed of, for example, a lithium ion battery. The first storage battery 3 (1) is connected to the first photovoltaic power generation unit 2 (1) via a first hybrid power conditioner 4 (1) or the like, which will be described later.

The first hybrid power conditioner 4 (1) is a device (hybrid power conditioner) that appropriately converts electric power. The first hybrid power controller 4 (1) can output the electric power generated by the first photovoltaic power generation unit 2 (1) and the electric power discharged from the first storage battery 3 (1) to the load H, and the first The power generated by the photovoltaic power generation unit 2 (1) and the power from the grid power source K can be output to the first storage battery 3 (1). The first hybrid power conditioner 4 (1) is connected to the first connection point P1 (1) of the power path L that supplies power from the system power supply K to the load H.

The first sensor 5 (1) is provided between the first connection point P1 (1) and the second connection point (not shown) to which the second power storage system is connected in the power path L. The first sensor 5 (1) determines the voltage (supply voltage) and the current (supply current) of the electric power (for example, the electric power supplied to the load H and the first storage battery 3 (1)) circulating in the provided portion. To detect. The first sensor 5 (1) is connected to the first hybrid power conditioner 4 (1) and is configured to be able to output a signal related to the detection result to the first hybrid power conditioner 4 (1).

The second power storage system (not shown) to the Nth power storage system 1 (N) are configured in the same manner as the first power storage system 1 (1) except that the connection point with the power path L is different. The second power storage system to the Nth power storage system 1 (N) are arranged on the upstream side (system power supply K side) of the first connection point P1 (1) (first power storage system 1 (1)) of the power path L. The connection points to be connected (see the N-1 connection point P1 (N-1) and the Nth connection point P1 (N) shown in FIG. 1) are connected in order. In such a first power storage system 1 (1) to an Nth power storage system 1 (N), the Nth power storage system 1 (N) is arranged on the most upstream side.

The control unit 60 manages the information of the power storage system 1 (1 to N) and controls the operation of the power storage system 1 (1 to N). The control unit 60 is mainly composed of an arithmetic processing unit such as a CPU, a storage device such as a RAM or ROM, an input / output device such as a touch panel, and the like. The control unit 60 can control the output of the electric power generated by the photovoltaic power generation unit 2 (1 to N) and the charge / discharge of the storage battery 3 (1 to N). Further, the control unit 60 stores a program and various information in the storage device, and by reading the program and various information in the arithmetic processing unit and processing the program, the power selling mode and the eco mode described later are executed. can do. Such a control unit 60 is configured by, for example, an EMS (Energy Management System).

Further, the control unit 60 is connected to the hybrid power conditioner 4 (1 to N). The control unit 60 uses the signal output from the hybrid power conditioner 4 (1 to N) to detect the detection result of the sensor 5 (1 to N) and the solar power generation unit 2 (1 to N) and the storage battery 3 (1 to N). Information on the operating status can be obtained.

Hereinafter, in the power supply system 1 configured as described above, the flow of supplying power to the storage batteries 3 (1 to N) and the load H will be briefly described.

The electric power from the grid power supply K and the photovoltaic power generation units 2 (1 to N) is supplied to the load H via the electric power path L. In this way, the resident of the house can turn on the lighting, use the cooking utensils and the air conditioner by using the electric power from the grid power supply K and the photovoltaic power generation units 2 (1 to N).

In this case, if the power consumption of the load H can be covered only by the power from the photovoltaic power generation units 2 (1 to N), it is possible not to use the power from the grid power source K. In this way, the amount of power purchased from the grid power supply K can be reduced, and the power charge can be saved.

Further, the electric power from the grid power supply K and the photovoltaic power generation unit 2 (1 to N) can be supplied to the storage battery 3 (1 to N) at an appropriate time zone. The electric power supplied to the storage battery 3 (1 to N) can be charged to the storage battery 3 (1 to N). The time zone in which the storage battery 3 (1 to N) is charged can be arbitrarily set by the resident. For example, if the time zone is set to midnight, the storage battery 3 (1 to N) can be charged with low-priced midnight electricity. Further, if the time zone is set to the daytime time zone, the electric power from the photovoltaic power generation unit 2 (1 to N) can be charged to the storage battery 3 (1 to N).

Further, the electric power charged in the storage batteries 3 (1 to N) can be supplied to the load H via the electric power path L. Specifically, when the storage battery 3 (1 to N) is discharged, the discharged electric power is supplied to the load H via the power path L. The time zone in which the storage battery 3 (1 to N) is discharged can be arbitrarily set by the resident. For example, if the time zone is set to the daytime time zone, the low-priced midnight electricity charged in the storage battery 3 (1 to N) can be used in the daytime time zone. In this way, the amount of power (purchased power) from the grid power supply K can be reduced during the daytime, and the power charge can be saved.

Next, the power supply mode (mode) in the power supply system 1 will be described.

The power supply system 1 has a power selling mode and an eco mode as power supply modes. The power selling mode and the eco mode can be arbitrarily set by, for example, operating the touch panel of the control unit 60 by a resident of a house.

The power selling mode is a mode for the purpose of selling the power generated by the photovoltaic power generation unit 2 (1 to N) (to obtain financial profit by reverse power flow to the grid power supply K). Further, the power selling mode is a mode in which the time zone for charging / discharging the storage battery 3 (1 to N) can be arbitrarily set.

More specifically, in the power selling mode, the storage battery 3 (1 to N) has a time for starting charging (hereinafter referred to as "charging start time") and a time for ending charging (hereinafter referred to as "charging end time"). ") And is set. In the present embodiment, the time zone from the charging start time to the charging end time is set to be a midnight time zone. For example, if the charging start time is set to 23:00 and the charging end time is set to 7:00, the storage battery 3 (1 to N) is charged from 23:00 to 7:00 the next day.

Further, in the power selling mode, the storage battery 3 (1 to N) is referred to as a time for starting discharge (hereinafter referred to as "discharge start time") and a time for ending discharge (hereinafter referred to as "discharge end time"). ) And is set. In the present embodiment, the time zone from the discharge start time to the discharge end time is set to be the daytime time zone. For example, if the discharge start time is set to 8 o'clock and the discharge end time is set to 20:00, the storage battery 3 (1 to N) discharges from 8:00 to 20:00 as needed.

Such a charging start time, a charging end time, a discharge start time, and a discharge end time can be arbitrarily set by, for example, operating the touch panel of the control unit 60 by a resident of a house. Further, the charging start time, the charging end time, the discharge start time and the discharge end time are stored in the storage device of the control unit 60.

In the power selling mode, the hybrid power conditioner 4 (1 to N) confirms the amount of electric energy (capacity) charged in the storage battery 3 (1 to N), and whether or not charging / discharging is possible according to the confirmed electric energy. Judge as appropriate. For example, the hybrid power conditioner 4 (1 to N) does not issue a discharge instruction when the storage battery 3 (1 to N) is full. The hybrid power conditioner 4 (1 to N) does not give a charging instruction when the storage battery 3 (1 to N) is fully charged. Further, the hybrid power conditioner 4 (1 to N) does not issue a discharge instruction when the storage battery 3 (1 to N) is fully charged during the time period from the charging start time to the charging end time. Further, in the hybrid power conditioner 4 (1 to N), when the time zone from the charging start time to the charging end time and the time zone from the discharging start time to the discharging end time overlap, the storage battery 3 (1 to N) is used. Priority is given to charging.

The eco-mode is a mode for the purpose of consuming the electric power generated by the photovoltaic power generation unit 2 (1 to N) at the load H (obtaining an energy saving effect by consuming the electric power at the load H).

When the eco mode is set, when the photovoltaic power generation unit 2 (1 to N) is generating power, the power from the photovoltaic power generation unit 2 (1 to N) becomes the power consumption of the load H. On the other hand, when there is a surplus, the surplus power is charged to the storage battery 3 (1 to N) without flowing back to the system power source K. When the storage batteries 3 (1 to N) are fully charged, the surplus power is reverse-fed to the grid power supply K. Further, when the eco mode is set, when the power from the photovoltaic power generation unit 2 (1 to N) is insufficient with respect to the power consumption of the load H, the storage battery 3 (1 to N) is discharged and the storage battery 3 (1 to N) is discharged. The electric power from 1 to N) is supplied to the load H.

In this way, in the eco mode, the storage battery 3 (1 to N) is not charged and discharged according to a preset time as in the power selling mode, but the power from the photovoltaic power generation unit 2 (1 to N) is supplied. The storage battery 3 (1 to N) is charged and discharged according to the magnitude relationship between the load H and the power consumption of the load H (whether or not the power from the photovoltaic power generation unit 2 (1 to N) is surplus). The control unit 60 can set such a power selling mode and an eco mode differently for each power storage system 1 (1 to N) (storage battery 3 (1 to N)).

In the power selling mode and the eco mode as described above, power is preferentially supplied to the load H from the power storage system arranged on the downstream side. The power storage system that supplies the electric power preferentially supplies the electric power from the photovoltaic power generation unit to the load H among the photovoltaic power generation unit and the storage battery. In such a configuration, as shown in FIG. 2, the solar power generation unit may sell the power and discharge the storage battery at the same time.

Specifically, as shown in FIG. 2, the load H consuming 2000 W of electric power is first supplied with electric power from the first power storage system 1 (1) arranged on the most downstream side. The first power storage system 1 (1) preferentially supplies the electric power (1000 W) from the first photovoltaic power generation unit 2 (1) to the load H. At this time, the first sensor 5 (1) detects 1000 W and transmits a signal regarding the detection result to the first hybrid power conditioner 4 (1). The first hybrid power conditioner 4 (1) detects that the power from the first photovoltaic power generation unit 2 (1) does not cover the power consumption of the load H based on the detection result of the first sensor 5 (1). Then, the first storage battery 3 (1) is discharged. At this time, the first hybrid power conditioner 4 (1) performs a load following operation for determining the amount of electric power to be discharged from the first storage battery 3 (1) based on the detection result of the first sensor 5 (1). As a result, the first storage battery 3 (1) shown in FIG. 2 discharges 1000 W of electric power. As a result, the first power storage system 1 (1) shown in FIG. 2 covers the power consumption of the load H with the power from the first photovoltaic power generation unit 2 (1) and the first storage battery 3 (1).

In the state shown in FIG. 2, the photovoltaic power generation unit from the second power storage system to the Nth power storage system 1 (N) arranged on the upstream side of the first power storage system 1 (1) is the first photovoltaic power generation unit. Similar to 2 (1), it generates 1000 W of electric power. Since the power consumption of the load H is covered by the power from the first power storage system 1 (1), the generated power (1000 W) is reverse-flowed (sold). In this case, the first storage battery 3 (1) is discharged even though the power generated by the photovoltaic power generation unit 2 (1 to N) can cover the power consumption of the load H, and the photovoltaic power generation unit 2 (1) The power generated in ~ N) cannot be effectively used by the load H. Hereinafter, a state in which such power selling and discharging are performed at the same time (state shown in FIG. 2) is referred to as a “power selling / discharging state”.

If the power from the first power storage system 1 (1) (power from the first photovoltaic power generation unit 2 (1) and the first storage battery 3 (1)) cannot cover the power consumption of the load H, the second Electric power is supplied from the power storage system in the same manner as in the first power storage system 1 (1). If the power consumption of the load H still cannot be covered, power is supplied from the third power storage system. As described above, in the power selling mode and the eco mode, when the power consumption of the load H cannot be covered, the first photovoltaic power generation unit 2 (1), the first storage battery 3 (1), and the second photovoltaic power generation unit , ..., Electric power from the N-1th storage battery 3 (N-1), the Nth photovoltaic power generation unit 2 (N), and the Nth storage battery 3 (N) is sequentially supplied to the load H.

The control unit 60 according to the present embodiment suppresses the power selling / discharging state as shown in FIG. 2 by performing the discharge stop processing, and the solar power generation unit 2 (1 to N) generates power. We are trying to make effective use of electricity.

Hereinafter, the discharge stop process will be described with reference to FIGS. 3 to 5.

In the initial setting, the discharge stop process differs depending on whether the power selling mode is set for the power storage system 1 (1 to N) or the eco mode is set. Therefore, first, the contents of the discharge stop processing when the power selling mode is set for the power storage system 1 (1 to N) will be described.

As shown in FIG. 3, first, in step S10, the control unit 60 determines whether the Nth photovoltaic power generation unit 2 (N) is selling power (the power generated by the Nth photovoltaic power generation unit 2 (N)). Is reverse power flow). At this time, the control unit 60 acquires the detection result of the Nth sensor 5 (N) from the Nth hybrid power conditioner 4 (N). Then, the control unit 60 confirms whether or not the Nth photovoltaic power generation unit 2 (N) is selling power based on the acquisition result.

As described above, power is preferentially supplied to the load H from the power storage system arranged on the downstream side. Therefore, if the Nth photovoltaic power generation unit 2 (N) of the Nth power storage system 1 (N) arranged on the most upstream side is not selling power, the first photovoltaic power generation unit arranged on the downstream side thereof. It means that power is not sold from 2 (1) to N-1 photovoltaic power generation unit 2 (N-1). Therefore, the control unit 60 confirms whether the Nth photovoltaic power generation unit 2 (N) is selling power, and whether or not all the photovoltaic power generation units 2 (1 to N) are selling power. Can be confirmed. When the control unit 60 determines that the Nth photovoltaic power generation unit 2 (N) is selling power, the control unit 60 proceeds to step S20. On the other hand, when the control unit 60 determines that the Nth photovoltaic power generation unit 2 (N) is not selling power, the control unit 60 proceeds to step S50.

In step S20, the control unit 60 of the first storage battery 3 (1) to the N-1th storage battery 3 (N-1), that is, the storage batteries 3 (1 to N-1) excluding the Nth storage battery 3 (N). Check if the discharge end time is earlier than the current time. At this time, the control unit 60 acquires the discharge end time of the storage battery 3 (1 to N-1) from the storage device. Further, the control unit 60 acquires the current time by using the clock function provided in the control unit 60. Then, the control unit 60 confirms whether or not the discharge end time is earlier than the current time by comparing the acquired discharge end time with the current time. At this time, the control unit 60 sets the discharge end time of the storage battery 3 (1 to N-1) only when all the discharge end times of the storage battery 3 (1 to N-1) are earlier than the current time. Judge that it is before the current time.

If the discharge end time of the storage battery 3 (1 to N-1) is earlier than the current time, the storage battery 3 (1 to N-1) is already in a non-dischargeable state. In this case, even if the Nth photovoltaic power generation unit 2 (N) sells power, the storage battery 3 (1 to N-1) does not discharge. Further, even if the Nth storage battery 3 (N) is in a dischargeable state (even if the discharge end time is not before the current time), the Nth photovoltaic power generation unit 2 (N) sells the power. If so, the Nth hybrid power conditioner 4 (N) determines that the discharge is not necessary, and the discharge is stopped. As described above, when the discharge end time of the storage batteries 3 (1 to N-1) is earlier than the current time (step S20: YES), all the storage batteries 3 (1 to N) are in a non-dischargeable state. The power is not sold and discharged. Therefore, when the control unit 60 determines in step S20 that the discharge end time is earlier than the current time, the control unit 60 ends the discharge stop process.

On the other hand, when the discharge end time of the storage battery 3 (1 to N-1) is not earlier than the current time (step S20: NO), the storage battery 3 (1 to N-1) is in a dischargeable state. .. In this case, the storage batteries 3 (1 to N-1) may be discharged while the Nth photovoltaic power generation unit 2 (N) or the like is selling power, resulting in a power selling discharge state. In this case, the control unit 60 shifts to step S30.

In step S30, the control unit 60 appropriately transmits a signal from the first hybrid power conditioner 4 (1) to the N-1 hybrid power conditioner 4 (N-1), and the discharge of the storage battery 3 (1 to N-1) is completed. Change the time to the current time. As a result, the control unit 60 puts the storage battery 3 (1 to N-1) into a non-discharging state (stops discharging) via the hybrid power conditioner 4 (1 to N-1). The control unit 60 shifts to step S40 after the process of step S30.

In step S40, the control unit 60 changes the discharge end time of the storage battery 3 (1 to N-1) to a preset power generation stop time in the same manner as in step S30. The power generation stop time is a time when the photovoltaic power generation unit 2 (1 to N) cannot generate power, and is a time when the sun is considered to have set in the present embodiment. Specifically, the power generation stop time according to the present embodiment is set at 20:00. As a result, the control unit 60 can make the storage battery 3 (1 to N-1) undischargeable until the photovoltaic power generation unit 2 (1 to N) cannot generate power. The control unit 60 ends the discharge stop process after the process of step S40.

According to this, as shown in FIG. 4, the control unit 60 stops the discharge of the storage battery 3 (1 to N-1) and suppresses the power sale discharge state (step S30), and the load H. The power consumption (2000 W) can be covered only by the power of the photovoltaic power generation unit 2 (1 to N). Therefore, the electric power of the photovoltaic power generation unit 2 (1 to N) can be effectively utilized.

Here, when the power is sold and discharged, the unit price of the power purchased by the electric power company is lower than the unit price of the power when the power is not sold and discharged. Therefore, if the power selling / discharging state is suppressed by the discharge suppressing process according to the first embodiment, the power of the photovoltaic power generation unit 2 (1 to N) can be sold without lowering the unit price of the power. As a result, it is possible to prevent a decrease in monetary profit from selling electricity.

As shown in FIG. 3, in step S50 of transition from step S10 when the Nth photovoltaic power generation unit 2 (N) is not selling power, the control unit 60 uses the storage battery 3 (1) in the same manner as in step S10. It is confirmed whether or not the discharge start time of ~ N-1) is earlier than the current time.

If the discharge start time of the storage battery 3 (1 to N-1) is earlier than the current time, the storage battery 3 (1 to N-1) is already in a dischargeable state. In this case, the storage battery 3 (1 to N) has already been discharged. Further, when the Nth photovoltaic power generation unit 2 (N) does not sell the power, the Nth storage battery 3 (N) is discharged because it is determined by the Nth hybrid power conditioner 4 (N) that it needs to be discharged. ing. In this way, when the discharge start time of the storage batteries 3 (1 to N-1) is earlier than the current time (step S50: YES), all the storage batteries 3 (1 to N) are discharged and the load H In the photovoltaic power generation unit 2 (1 to N), the insufficient power is covered with respect to the power consumption of the above. Therefore, when the control unit 60 determines in step S50 that the discharge start time is earlier than the current time, the control unit 60 ends the discharge stop process.

On the other hand, when the discharge start time is not earlier than the current time (step S50: NO), the storage battery 3 (1 to N-1) is in a state in which discharge is impossible due to the above-mentioned step S30 or the like. .. In this case, the power that is insufficient in the photovoltaic power generation unit 2 (1 to N) with respect to the power consumption of the load H is covered by the Nth storage battery 3 (N) and the grid power supply K. In this case, the control unit 60 shifts to step S60.

In step S60, the control unit 60 changes the discharge start time of the storage battery 3 (1 to N-1) to the current time in the same manner as in step S30. As a result, the control unit 60 can make the storage battery 3 (1 to N-1) in a dischargeable state. As a result, the storage battery 3 (1 to N-1) can be started to be discharged, and the storage battery 3 (1 to N) can cover the power shortage of the power from the photovoltaic power generation unit 2 (1 to N). The control unit 60 shifts to step S70 after the process of step S60.

In step S70, the control unit 60 changes the discharge end time of the storage battery 3 (1 to N-1) to a preset power generation start time in the same manner as in step S30. The power generation start time is a time when the photovoltaic power generation unit 2 (1 to N) can generate power, and is a time when the sun is considered to rise in this embodiment. Specifically, the power generation start time according to the present embodiment is set at 6 o'clock. As a result, the control unit 60 can make the storage battery 3 (1 to N-1) dischargeable until the photovoltaic power generation unit 2 (1 to N) starts power generation. The control unit 60 ends the discharge stop process after the process of step S70.

According to this, when the power of the photovoltaic power generation unit 2 (1 to N) cannot cover the power consumption of the load H (step S10: NO), the control unit 60 uses the storage battery 3 (1 to N-1). Can be discharged (step S60). As a result, even if the photovoltaic power generation unit 2 (1 to N) is generating power, the storage battery 3 (1 to N) can be discharged without being in the power selling / discharging state. Therefore, while effectively utilizing the electric power of the photovoltaic power generation unit 2 (1 to N), the storage battery 3 (1 to N) can be discharged when necessary to suppress the amount of electricity purchased.

Next, the contents of the discharge stop processing when the eco mode is set for the power storage system 1 (1 to N) in the initial setting will be described.

As shown in FIG. 5, first, in step S110, the control unit 60 confirms whether or not the Nth photovoltaic power generation unit 2 (N) is selling power, as in step S10. When the control unit 60 determines that the Nth photovoltaic power generation unit 2 (N) is selling power, the control unit 60 proceeds to step S120. On the other hand, when the control unit 60 determines that the Nth photovoltaic power generation unit 2 (N) is not selling power, the control unit 60 proceeds to step S170.

In step S120, the control unit 60 confirms whether or not the mode of the storage battery 3 (1 to N-1) is the power selling mode. At this time, the control unit 60 acquires the mode of the storage battery 3 (1 to N-1) from the storage device. Then, the control unit 60 confirms whether or not the mode of the storage battery 3 (1 to N-1) is the power selling mode based on the acquisition result. At this time, the control unit 60 determines that the mode of the storage battery 3 (1 to N-1) is the power selling mode only when all the storage batteries 3 (1 to N-1) are in the power selling mode. When the control unit 60 determines that the mode of the storage battery 3 (1 to N-1) is the power selling mode, the control unit 60 proceeds to step S140. On the other hand, when the control unit 60 determines that the mode of the storage battery 3 (1 to N-1) is not the power selling mode, the control unit 60 shifts to step S130.

In step S130, the control unit 60 transmits a signal to the hybrid power conditioner 4 (1 to N-1) and changes the mode of the storage battery 3 (1 to N-1) to the power selling mode. The control unit 60 shifts to step S150 after the process of step S130.

In steps SS140 to S160, the control unit 60 performs the same processing as in steps S20 to S40. That is, the control unit 60 confirms whether or not the discharge end time of the storage battery 3 (1 to N-1) is before the current time (step S140), and the discharge end time is before the current time. If it is determined that this is not the case, the discharge start time and discharge end time of the storage battery 3 (1 to N-1) are changed (steps S150 and S160). The control unit 60 ends the discharge stop process after the process of step S160.

As described above, the control unit 60 changes the mode of the storage battery 3 (1 to N-1) to the power selling mode when the eco mode is set for the power storage system 1 (1 to N). , The discharge start time and discharge end time of the storage battery 3 (1 to N-1) are changed. As a result, the control unit 60 can stop the discharge of the storage battery 3 (1 to N) in the same manner as when the eco mode is set for the power storage system 1 (1 to N), so that the power can be sold. It is possible to suppress the discharge state.

Further, in step S170 in which the Nth photovoltaic power generation unit 2 (N) shifts from step S110 when the power is not sold, the control unit 60 uses the storage battery 3 (1 to N-1) in the same manner as in step S120. Check if the mode of is eco mode. If the Nth photovoltaic power generation unit 2 (N) is not selling power, it will not be in the power selling / discharging state, so it is necessary to stop the discharging of the storage battery 3 (1 to N-1) (change to the power selling mode). There is no. Therefore, the control unit 60 ends the discharge stop process when it is determined that the mode of the storage battery 3 (1 to N-1) is the eco mode. Further, when the control unit 60 determines that the mode of the storage battery 3 (1 to N-1) is not the eco mode, the control unit 60 shifts to step S180, and in the same manner as in step S130, of the storage battery 3 (1 to N-1). Change the mode to eco mode.

As described above, the control unit 60 temporarily changes the storage battery 3 (1 to N-1) to the power selling mode when the eco mode is set for the power storage system 1 (1 to N). , The discharge of the storage battery 3 (1 to N) can be stopped by using the setting of the power selling mode (discharge start time and discharge end time). According to this, the control unit 60 uses the existing mode (without creating a new mode), suppresses the power selling / discharging state, and effectively uses the power of the photovoltaic power generation unit 2 (1 to N). It can be utilized.

As described above, the power supply system 1 according to the first embodiment can generate power by using natural energy and can supply the generated power to the load H. The Nth solar power generation unit 2 (N). The Nth power storage system 1 (N) (first supply unit) having the (power generation unit) and the Nth power storage system 1 (N) arranged on the load H side of the Nth power storage system 1 (N). ) And the power from the grid power supply K can be charged, and the charged power can be discharged and supplied to the load H from the first storage battery 3 (1) to the N-1 storage battery. The first power storage system 1 (1) having up to 3 (N-1) (storage battery) to the N-1 power storage system 1 (N-1) (second supply unit) and the system power supply K are reversed. The Nth sensor 5 (N) (detection unit) capable of detecting the tidal power and the detection result of the Nth sensor 5 (N) can be acquired, and the first storage battery 3 (1) to the N-th 1 The storage battery 3 (N-1) is configured to be controllable, and when the Nth sensor 5 (N) detects the reverse power flow, the first storage battery 3 (1) to the N-1. It includes a control unit 60 that regulates discharge to the storage battery 3 (N-1).

With this configuration, it is possible to prevent the power from being sold and discharged, so that the power generated by the Nth photovoltaic power generation unit 2 (N) can be effectively utilized by the load H.

Further, when the Nth sensor 5 (N) detects the reverse power flow, the control unit 60 goes from the first storage battery 3 (1) to the N-1 storage battery 3 (N-1). Is changed to a state in which it cannot be discharged.

With this configuration, it is possible to stop the discharge of the storage battery 3 (1 to N-1) and suppress the state of being sold and discharged. Therefore, the power generated by the Nth photovoltaic power generation unit 2 (N) can be used. It can be effectively used with a load H.

Further, as a power supply mode, the first storage battery 3 (1) has a power selling mode (first mode) for the purpose of selling the power generated by the Nth solar power generation unit 2 (N). ) To the N-1 storage battery 3 (N-1) are in a dischargeable state from the discharge start time (first time) to the discharge end time (second time) in the power selling mode. In the power selling mode, the control unit 60 detects the reverse power flowed by the Nth sensor 5 (N) (step S10: YES), and the discharge end time is later than the current time. (Step S20: NO), the discharge end time is set to the current time (step S30).

With this configuration, the discharge of the storage battery 3 (1 to N-1) can be easily stopped.

Further, in the power selling mode, the control unit 60 detects the power to be reverse power flowed by the Nth sensor 5 (N), and the discharge end time is later than the current time. The discharge start time is set to the power generation stop time (the time when the Nth photovoltaic power generation unit 2 (N) cannot generate electric power) (step S40).

With this configuration, the storage battery 3 (1 to N-1) can be discharged after the time when the photovoltaic power generation unit 2 (1 to N) cannot generate electric power. As a result, the storage battery 3 (1 to N-1) can be discharged while suppressing the state of being sold and discharged, and the electric power charged in the storage battery 3 (1 to N-1) can be effectively utilized by the load H. can do.

Further, as a power supply mode, the control unit has an eco-mode (second mode) for the purpose of consuming the power generated by the Nth photovoltaic power generation unit 2 (N) with the load H. Reference numeral 60 denotes the first storage battery 3 (1) to the N-1 storage battery 3 when the Nth sensor 5 (N) detects the reverse power flow (step S110: YES) in the eco mode. The power supply mode up to (N-1) is switched to the power selling mode (step S130).

With this configuration, when the power supply mode is the eco mode, the first storage battery 3 (1) to the N-1 storage battery 3 (N-1) can be charged using the power selling mode. Can be regulated.

Further, the Nth power storage system 1 (N) can charge the electric power generated by the Nth photovoltaic power generation unit 2 (N) and the electric power from the system power supply K, and can also charge the charged electric power. It has an Nth storage battery 3 (N) that can be discharged and supplied to the load H.

With this configuration, the electric power generated by the Nth photovoltaic power generation unit 2 (N) can be charged to many storage batteries.

Further, from the first power storage system 1 (1) to the N-1 power storage system 1 (N-1), the first photovoltaic power generation unit 2 (1) to the N-th that can generate power by using natural energy. It further has 1 solar power generation unit 2 (N-1) (power generation unit).

With such a configuration, it is possible to generate more electric power by utilizing natural energy.

The Nth photovoltaic power generation unit 2 (N) according to the first embodiment is an embodiment of the power generation unit of the first supply unit according to the present invention.
Further, the Nth power storage system 1 (N) according to the first embodiment is an embodiment of the first supply unit according to the present invention.
Further, the first storage battery 3 (1) to the N-1 storage battery 3 (N-1) according to the first embodiment are embodiments of the storage battery of the second supply unit according to the present invention.
Further, the first power storage system 1 (1) to the N-1 power storage system 1 (N-1) according to the first embodiment are one embodiment of the second supply unit according to the present invention.
Further, the Nth sensor 5 (N) according to the first embodiment is an embodiment of the detection unit according to the present invention.
Further, the power selling mode according to the first embodiment is an embodiment of the first mode according to the present invention.
The power generation stop time according to the first embodiment is an embodiment of a time when electric power cannot be generated.
Further, the eco-mode according to the first embodiment is an embodiment of the second mode according to the present invention.
The discharge start time according to the first embodiment is an embodiment of the first time according to the present invention.
The discharge end time according to the first embodiment is an embodiment of the second time according to the present invention.
Further, from the first photovoltaic power generation unit 2 (1) to the N-1 photovoltaic power generation unit 2 (N-1) according to the first embodiment, the power generation unit of the second supply unit according to the present invention is implemented. It is a form of.
Further, the Nth storage battery 3 (N) according to the first embodiment is an embodiment of the storage battery of the first supply unit according to the present invention.

Next, the power supply system according to the second embodiment will be described.

The power supply system according to the second embodiment is configured in the same manner as the power supply system 1 according to the first embodiment, except that the contents of the discharge stop processing are different.

Hereinafter, the discharge stop processing according to the second embodiment will be described with reference to FIGS. 6 and 7.

The discharge stop process according to the second embodiment is different from the discharge stop process according to the first embodiment in that the charge start time and the charge end time are changed.

First, the contents of the discharge stop processing when the power selling mode is set for the power storage system 1 (1 to N) in the initial setting will be described.

As shown in FIG. 6, first, in step S210, the control unit 60 confirms whether or not the Nth photovoltaic power generation unit 2 (N) is selling power, as in step S10 according to the first embodiment. To do. When the control unit 60 determines that the Nth photovoltaic power generation unit 2 (N) is selling power, the control unit 60 proceeds to step S220. On the other hand, when the control unit 60 determines that the Nth photovoltaic power generation unit 2 (N) is not selling power, the control unit 60 proceeds to step S260.

In step S220, the control unit 60 confirms whether or not the charging start time of the storage battery 3 (1 to N-1) is earlier than the current time in the same manner as in step S20 according to the first embodiment. ..

If the charging start time of the storage battery 3 (1 to N-1) is earlier than the current time, the storage battery 3 (1 to N-1) is already in a rechargeable state. Further, as described above, when the time zone from the charging start time to the charging end time and the time zone from the discharging start time to the discharging end time overlap, the charging of the storage battery 3 (1 to N-1) has priority. Will be done. In this case, even if the storage battery 3 (1 to N-1) is fully charged, the storage battery 3 (1 to N-1) is not discharged with priority. As described above, in the second embodiment, if the battery is in a rechargeable state, it cannot be discharged. Therefore, when the charging start time of the storage battery 3 (1 to N-1) is earlier than the current time, even if the Nth photovoltaic power generation unit 2 (N) sells power, the storage battery 3 (1 to N-1) is sold. -1) does not discharge. In the second embodiment, such a rechargeable and non-dischargeable state is simply referred to as a "rechargeable state".

Further, even if the Nth storage battery 3 (N) is in a dischargeable state (even if the charging start time is not before the current time), the Nth photovoltaic power generation unit 2 (N) sells the power. If so, the Nth hybrid power conditioner 4 (N) determines that the discharge is not necessary, and the discharge is stopped. As described above, when the charging start time of the storage batteries 3 (1 to N-1) is earlier than the current time (step S220: YES), all the storage batteries 3 (1 to N) are in a state in which they cannot be discharged. The power is not sold and discharged. Therefore, when the control unit 60 determines in step S220 that the charging start time is earlier than the current time, the control unit 60 ends the discharge stop process.

On the other hand, when the charging start time of the storage battery 3 (1 to N-1) is not earlier than the current time (step S220: NO), the storage battery 3 (1 to N-1) cannot be charged (charge / discharge impossible). It is in a state where it cannot be charged and can be discharged. In this case, the storage batteries 3 (1 to N-1) may be discharged while the Nth photovoltaic power generation unit 2 (N) or the like is selling power, resulting in a power selling discharge state. In this case, the control unit 60 shifts to step S230.

In step S230, the control unit 60 changes the charging start time of the storage battery 3 (1 to N-1) to the current time in the same manner as in step S30 according to the first embodiment. As a result, the control unit 60 makes the storage batteries 3 (1 to N-1) rechargeable. As a result, the control unit 60 charges the storage battery 3 (1 to N) with the electric power of the photovoltaic power generation unit 2 (1 to N). The control unit 60 shifts to step S240 after the process of step S230.

In step S240, the control unit 60 sets the charge end time of the storage battery 3 (1 to N-1) as the power generation stop time (photovoltaic power generation unit 2 (1 to N)) in the same manner as in step S30 according to the first embodiment. Change to the time when power cannot be generated). As a result, the control unit 60 can charge the storage battery 3 (1 to N-1) until the photovoltaic power generation unit 2 (1 to N) cannot generate power. The control unit 60 shifts to step S250 after the process of step S240.

In step S250, the control unit 60 sets the discharge end time of the storage battery 3 (1 to N-1) as the power generation start time (photovoltaic power generation unit 2 (1 to N)) in the same manner as in step S30 according to the first embodiment. Change to the time when can generate electricity). As a result, the control unit 60 can make the storage battery 3 (1 to N-1) in a dischargeable state until the photovoltaic power generation unit 2 (1 to N) can generate power. The control unit 60 ends the discharge stop process after the process of step S250.

According to this, the control unit 60 starts charging the storage battery 3 (1 to N-1) and suppresses the state of selling and discharging the power (step S230), and generates the power consumption of the load H by photovoltaic power generation. It is possible to cover only the electric power of the part 2 (1 to N).

Further, in step S260 transitioning from step S210 when the Nth photovoltaic power generation unit 2 (N) is not selling power, the control unit 60 uses the storage battery 3 (in the same manner as in step S10 according to the first embodiment). It is confirmed whether or not the discharge start time of 1 to N-1) is earlier than the current time. The control unit 60 ends the discharge stop process when it determines that the discharge start time is earlier than the current time. When the control unit 60 determines that the discharge start time is not earlier than the current time, the control unit 60 proceeds to step S270.

In step S270, the control unit 60 changes the charge end time and discharge start time of the storage battery 3 (1 to N-1) to the current time in the same manner as in step S30 according to the first embodiment. As a result, the control unit 60 puts the storage batteries 3 (1 to N-1) into a state in which they cannot be charged and can be discharged. As a result, the storage battery 3 (1 to N-1) can be discharged, and the storage battery 3 (1 to N) can cover the power consumption of the load H, which is insufficient for the photovoltaic power generation unit 2 (1 to N). it can. The control unit 60 ends the discharge stop process after the process of step S270.

According to the above, when there is a possibility that the control unit 60 will be in the power selling / discharging state (steps S210: YES, S220: NO), the solar power generation unit 2 (1) is connected to the storage battery 3 (1 to N-1). The power of (N) can be charged (steps S230 to S250). As a result, not only the power consumption of the load H is covered by the power of the photovoltaic power generation unit 2 (1 to N), but also the power consumption of the photovoltaic power generation unit 2 (1 to N) that is surplus with respect to the power consumption of the load H Electric power can be charged to the storage batteries 3 (1 to N-1). Therefore, the electric power of the photovoltaic power generation unit 2 (1 to N) can be effectively utilized.

Next, the contents of the discharge stop processing when the eco mode is set for the power storage system 1 (1 to N) in the initial setting will be described.

As shown in FIG. 7, first, in step S310, the control unit 60 determines whether the Nth photovoltaic power generation unit 2 (N) is selling power, as in step S110 according to the first embodiment. When the control unit 60 determines that the Nth photovoltaic power generation unit 2 (N) is selling power, the control unit 60 proceeds to step S320. On the other hand, when the control unit 60 determines that the Nth photovoltaic power generation unit 2 (N) is not selling power, the control unit 60 proceeds to step S370. When the control unit 60 shifts to step S370, the control unit 60 changes the mode of the storage battery 3 (1 to N-1) to the eco mode as necessary, and ends the discharge stop process, as in steps S170 and S180. Steps S370 and S380).

In step S320, the control unit 60 confirms whether or not the mode of the storage battery 3 (1 to N-1) is the power selling mode, as in step S120 according to the first embodiment. When the control unit 60 determines that the mode of the storage battery 3 (1 to N-1) is the power selling mode, the control unit 60 proceeds to step S340. On the other hand, when the control unit 60 determines that the mode of the storage battery 3 (1 to N-1) is not the power selling mode, the control unit 60 shifts to step S330.

In step S330, the control unit 60 changes the mode of the storage battery 3 (1 to N-1) to the power selling mode as in step S130 according to the first embodiment. The control unit 60 shifts to step S350 after the process of step S330.

In steps S340 to S360, the control unit 60 performs the same processing as in steps S220 to S240. That is, the control unit 60 confirms whether or not the charging start time of the storage battery 3 (1 to N-1) is earlier than the current time (step S340), and the charging start time is earlier than the current time. If it is determined that this is not the case, the charging start time and charging end time of the storage batteries 3 (1 to N-1) are changed (steps S350 and S360). The control unit 60 ends the discharge stop process after the process of step S360.

As described above, the control unit 60 temporarily changes the storage battery 3 (1 to N-1) to the power selling mode when the eco mode is set for the power storage system 1 (1 to N). , The power selling / discharging state can be regulated by using the charging start time and the charging end time of the power selling mode. According to this, the control unit 60 can suppress the power selling / discharging state without creating a new mode, and can also transfer the power of the photovoltaic power generation unit 2 (1 to N) to the storage battery 3 (1 to N-). It can be charged to 1).

As described above, in the power supply system according to the second embodiment, the control unit 60 detects the reverse power flow of the Nth sensor 5 (N), the first storage battery 3 (1). The N-1th storage battery 3 (N-1) is changed to a state in which it can be charged and cannot be discharged.

With this configuration, the storage battery 3 (1 to N) is charged with the power of the Nth photovoltaic power generation unit 2 (N), which is surplus with respect to the power consumption of the load H, so that the power sale / discharge state is set. Since it can be suppressed, the electric power generated by the Nth photovoltaic power generation unit 2 (N) can be effectively utilized by the load H and the storage battery 3 (1 to N).

Further, as a power supply mode, it has a power selling mode for the purpose of selling the power generated by the Nth photovoltaic power generation unit 2 (N), and the first storage batteries 3 (1) to N-1. Up to the storage battery 3 (N-1), in the power selling mode, from the charging start time (third time) to the charging end time (fourth time), the storage battery 3 (N-1) is in a state where it can be charged and cannot be discharged. In the power selling mode, the control unit 60 detects the reverse power flowed by the Nth sensor 5 (N) (step S310: YES), and the charging start time is later than the current time. In the case (step S340: NO), the charging start time is set to the current time (step S350).

With this configuration, the discharge of the storage battery 3 (1 to N-1) can be easily stopped.

Further, when the control unit 60 detects the power to be reverse power flowed by the Nth sensor 5 (N) in the power selling mode and the charging start time is later than the current time. , The charging end time is set to the power generation stop time (step S360).

With this configuration, the electric power charged from the first storage battery 3 (1) to the N-1th storage battery 3 (N-1) can be effectively utilized by the load H.

The charging start time according to the first embodiment is an embodiment of the third time according to the present invention.
The charging end time according to the first embodiment is an embodiment of the fourth time according to the present invention.

Next, the power supply system 301 according to the third embodiment will be described with reference to FIGS. 8 to 12.

In the following, the devices configured in the same manner as the power supply system 1 according to the first embodiment are designated by the same reference numerals as those in the first embodiment, and the description thereof will be omitted.

As shown in FIG. 8, the power supply system 301 according to the third embodiment is from the first power storage system 1 (1) to the Nth power storage system 1 (N) and from the first photovoltaic power generation system 37 (1). It includes up to the Nth first photovoltaic power generation system 37 (N) and a control unit 360.

The first photovoltaic power generation system 37 (1) supplies the electric power generated by using sunlight to the load H. The first photovoltaic power generation system 37 (1) is arranged on the upstream side of the Nth power storage system 1 (N). The first photovoltaic power generation system 37 (1) includes a first photovoltaic power generation unit 38 (1), a first power generation sensor 39 (1), and the like.

The first photovoltaic power generation unit 38 (1) includes a solar cell panel, a power conditioner for appropriately converting the generated power, and the like. The first photovoltaic power generation unit 38 (1) is connected to the first photovoltaic connection point P37 (1) arranged on the upstream side of the Nth connection point P1 (N) of the power path L.

The first power generation sensor 39 (1) is provided between the system power supply K and the first photovoltaic connection point P37 (1) in the power path L, and detects the voltage and current of the power flowing through the provided location. To do. The first power generation sensor 39 (1) is connected to the first solar power generation unit 38 (1) (power conditioner), and is configured to be able to output a signal related to the detection result to the first solar power generation unit 38 (1).

The second photovoltaic power generation system (not shown) to the Nth photovoltaic power generation system 37 (N) are the same as the first photovoltaic power generation system 37 (1) except that the connection point with the power path L is different. It is composed of. The second photovoltaic power generation system to the Nth photovoltaic power generation system 37 (N) are on the upstream side of the first photovoltaic power generation connection point P37 (1) (first photovoltaic power generation system 37 (1)) of the power path L. (See N-1 solar connection point P37 (N-1) and Nth solar connection point P37 (N) shown in FIG. 8). In such a first photovoltaic power generation system 37 (1) to the Nth photovoltaic power generation system 37 (N), the Nth photovoltaic power generation system 37 (N) is arranged on the most upstream side.

The control unit 360 is configured in the same manner as the control unit 60 according to the first embodiment, except that it is connected to the hybrid power conditioner 4 (1 to N) and the solar power generation unit 38 (1 to N). The control unit 360 can acquire information on the detection result of the power generation sensor 39 (1 to N) and the like from the signal output from the solar power generation unit 38 (1 to N).

As described above, in the power supply system 301 according to the third embodiment, another device (photovoltaic power generation system 37 (1 to N)) is provided on the upstream side of the Nth power storage system 1 (N). In that respect, it differs from the power supply system 1 of the first embodiment.

In such a power supply system 301, as shown in FIG. 9, the storage batteries 3 (1 to N) from the first power storage system 1 (1) to the Nth power storage system 1 (N) (the first storage battery in FIG. 9). When 3 (1)) is discharged, there is a possibility that the power is sold and discharged.

Next, the discharge stop processing of the power supply system 301 according to the third embodiment will be described with reference to FIGS. 10 to 12.

The discharge stop process according to the third embodiment is a process for suppressing the state of selling electricity and discharging by changing the discharge start time and the discharge end time, as in the discharge stop process according to the first embodiment. .. The target of the discharge stop process according to the third embodiment is different from the discharge stop process according to the first embodiment.

First, the contents of the discharge stop processing when the power selling mode is set for the power storage system 1 (1 to N) in the initial setting will be described.

As shown in FIG. 10, first, in step S410, the control unit 360 is the Nth photovoltaic power generation unit 38 (N) of the Nth photovoltaic power generation system 37 (N) in the same manner as in step S10 according to the first embodiment. Check if N) is selling electricity.

In the third embodiment, it is the sunlight of the photovoltaic power generation unit 2 (1 to N) of the power storage system 1 (1 to N) and the photovoltaic power generation system 37 (1 to N) that generate power using sunlight. It is a power generation unit 38 (1 to N). Of the photovoltaic power generation units 2 (1 to N) and 38 (1 to N), the Nth solar power generation unit 38 (N) is arranged on the most upstream side. Therefore, if the Nth photovoltaic power generation unit 38 (N) is not selling power, the other photovoltaic power generation units 2 (1 to N-1) and 38 (1 to N-1) are not selling power either. It will be. Therefore, the control unit 60 confirms whether or not the Nth photovoltaic power generation unit 38 (N) located on the most upstream side of the power supply system 301 is selling power, thereby generating all the photovoltaic power generation. It is possible to confirm whether or not the units 2 (1 to N) and 38 (1 to N) are selling power. When the control unit 60 determines that the Nth photovoltaic power generation unit 38 (N) is selling power, the control unit 60 proceeds to step S420. On the other hand, when the control unit 60 determines that the Nth photovoltaic power generation unit 38 (N) is not selling power, the control unit 60 proceeds to step S450.

The control unit 360 that has moved to step S420 confirms the discharge end times of all the storage batteries 3 (1 to N) in the same manner as in steps S20 to S40 according to the first embodiment, and all the storage batteries according to the result. The discharge start time and discharge end time of 3 (1 to N) are changed (steps S420 to S440).

On the other hand, the control unit 360 that has moved to step S450 confirms the discharge start times of all the storage batteries 3 (1 to N) in the same manner as in steps S50 to S70 according to the first embodiment, and all according to the result. The discharge start time and discharge end time of the storage batteries 3 (1 to N) of the above are changed (steps S450 to S470).

As described above, the control unit 360 according to the third embodiment ends the discharge of all the storage batteries 3 (1 to N) when there is a possibility that the power is sold and discharged (steps S410: YES, S420: NO). The time is being changed (step S430). As a result, as shown in FIG. 11, the control unit 360 discharges all the storage batteries 3 (1 to N) when another power generation device is arranged on the upstream side of the Nth power storage system 1 (N). Can be stopped to prevent the power from being sold and discharged.

Next, the contents of the discharge stop processing when the eco mode is set for the power storage system 1 (1 to N) in the initial setting will be described.

As shown in FIG. 12, first, in step S510, the control unit 360 confirms whether or not the Nth photovoltaic power generation unit 38 (N) is selling power, as in step S410. When the control unit 360 determines that the Nth photovoltaic power generation unit 38 (N) is selling power, the control unit 360 proceeds to step S520. On the other hand, when the control unit 360 determines that the Nth photovoltaic power generation unit 38 (N) is not selling power, the control unit 360 proceeds to step S570.

The control unit 360 that has moved to step S520 confirms the modes and discharge end times of all the storage batteries 3 (1 to N) in the same manner as in steps S120 to S160 according to the first embodiment, and all according to the results. The mode, discharge start time, and discharge end time of the storage batteries 3 (1 to N) are changed (steps S520 to S560).

On the other hand, the control unit 360 that has moved to step S570 confirms the modes of all the storage batteries 3 (1 to N) in the same manner as in steps S170 and S180 according to the first embodiment, and all the storage batteries according to the result. The mode of 3 (1 to N) is changed to the eco mode (steps S570 and S580).

According to the above, the control unit 360 according to the third embodiment uses the discharge start time and the discharge end time of the power selling mode even when the eco mode is set for the power storage system 1 (1 to N). Then, the discharge of all the storage batteries 3 (1 to N) can be stopped. As a result, the control unit 360 can prevent the power storage system 1 (1 to N) from being in the power selling / discharging state even when the eco mode is set.

Next, the power supply system according to the fourth embodiment will be described.

The power supply system according to the fourth embodiment is configured in the same manner as the power supply system 301 according to the third embodiment, except for the content of the discharge stop processing. The discharge stop process according to the fourth embodiment is a process for suppressing the state of power selling and discharging by changing the charge start time and the charge end time, as in the discharge stop process according to the second embodiment. .. The target of the discharge stop process according to the fourth embodiment is different from the discharge stop process according to the second embodiment.

Hereinafter, the discharge stop processing of the power supply system according to the fourth embodiment will be described with reference to FIGS. 13 and 14.

First, the contents of the discharge stop processing when the power selling mode is set for the power storage system 1 (1 to N) in the initial setting will be described.

As shown in FIG. 13, first, in step S610, the control unit 360 determines whether the Nth photovoltaic power generation unit 38 (N) is selling power, as in step S510 according to the third embodiment. When the control unit 360 determines that the Nth photovoltaic power generation unit 38 (N) is selling power, the control unit 360 proceeds to step S620. On the other hand, when the control unit 360 determines that the Nth photovoltaic power generation unit 38 (N) is not selling power, the control unit 360 proceeds to step S660.

The control unit 360 that has moved to step S620 confirms the modes and charging start times of all the storage batteries 3 (1 to N) in the same manner as in steps S220 to S260 according to the second embodiment, and all according to the result. The charge start time, charge end time, and discharge end time of the storage batteries 3 (1 to N) of the above are changed (steps S620 to S650).

On the other hand, the control unit 360 that has moved to step S660 confirms the discharge start times of all the storage batteries 3 (1 to N) in the same manner as in steps 260 and S270 according to the second embodiment, and all according to the result. The charge end time and discharge start time of the storage batteries 3 (1 to N) of the above are changed (steps S660 and S670).

As described above, the control unit 360 according to the fourth embodiment starts charging all the storage batteries 3 (1 to N) when there is a possibility that the power is sold and discharged (steps S610: YES, S620: NO). The time is being changed (step S630). As a result, the control unit 360 starts charging all the storage batteries 3 (1 to N) when another power generation device is arranged on the upstream side of the Nth power storage system 1 (N), and sells and discharges electricity. It is possible to suppress the situation.

Next, the contents of the discharge stop processing when the eco mode is set for the power storage system 1 (1 to N) in the initial setting will be described.

As shown in FIG. 14, first, in step S710, the control unit 360 determines whether the Nth photovoltaic power generation unit 38 (N) is selling power, as in step S610. When the control unit 360 determines that the Nth photovoltaic power generation unit 38 (N) is selling power, the control unit 360 proceeds to step S720. On the other hand, when the control unit 360 determines that the Nth photovoltaic power generation unit 38 (N) is not selling power, the control unit 360 proceeds to step S770.

The control unit 360 that has moved to step S720 confirms the modes and charging start times of all the storage batteries 3 (1 to N) in the same manner as in steps S320 to S360 according to the second embodiment, and all according to the result. The mode, charging start time, and charging end time of the storage batteries 3 (1 to N) are changed (steps S720 to S760).

On the other hand, the control unit 360 shifted to step S770 confirms the modes of all the storage batteries 3 (1 to N) in the same manner as in steps S370 and S380 according to the second embodiment, and all the storage batteries according to the result. The mode of 3 (1 to N) is changed to the eco mode (steps S770 and S780).

According to the above, the control unit 360 according to the fourth embodiment uses the charging start time and charging end time of the power selling mode even when the eco mode is set for the power storage system 1 (1 to N). Then, charging of all the storage batteries 3 (1 to N) can be started. As a result, the control unit 360 can prevent the power storage system 1 (1 to N) from being in the power selling / discharging state even when the eco mode is set.

The first photovoltaic power generation unit 38 (1) to the Nth photovoltaic power generation unit 38 (N) according to the third embodiment and the fourth embodiment are the power generation units of the first supply unit according to the present invention. It is an embodiment.
Further, from the first photovoltaic power generation system 37 (1) to the Nth photovoltaic power generation system 37 (N) according to the third embodiment and the fourth embodiment, one of the implementations of the first supply unit according to the present invention. It is a form.
Further, the first storage battery 3 (1) to the Nth storage battery 3 (N) according to the third embodiment and the fourth embodiment are one embodiment of the storage battery of the second supply unit according to the present invention.
Further, the first power storage system 1 (1) to the Nth power storage system 1 (N) according to the third embodiment and the fourth embodiment are one embodiment of the second supply unit according to the present invention.
Further, the Nth power generation sensor 39N according to the third embodiment and the fourth embodiment is an embodiment of the detection unit according to the present invention.

Next, the power supply system 501 according to the fifth embodiment will be described with reference to FIGS. 15 to 19.

In the following, the devices configured in the same manner as the power supply system 1 according to the first embodiment are designated by the same reference numerals as those in the first embodiment, and the description thereof will be omitted.

As shown in FIG. 15, the power supply system 501 according to the fifth embodiment includes the first power storage system 1 (1) to the Nth power storage system 1 (N) and the first storage battery systems 57 (1) to N. It includes a storage battery system 57 (N) and a control unit 560.

The first storage battery system 57 (1) is for charging and discharging electric power. The first storage battery system 57 (1) is arranged on the downstream side of the power storage system 1 (1 to N). The first storage battery system 57 (1) includes a first storage battery 58 (1), a first power conditioner 59 (1), a first storage battery sensor 60 (1), and the like.

The first storage battery 58 (1) is configured in the same manner as the first storage battery 3 (1) of the first power storage system 1 (1). The first power conditioner 59 (1) is connected to the first storage battery 58 (1) and appropriately converts the electric power charged in the first storage battery 58 (1) and the electric power discharged from the first storage battery 58 (1). The first power conditioner 59 (1) is connected to the first storage battery connection point P57 (1) arranged on the downstream side of the first connection point P1 (1) of the power path L.

The first storage battery sensor 60 (1) is provided between the first storage battery connection point P57 (1) and the second storage battery connection point (not shown) to which the second storage battery system is connected in the power path L. Detects the voltage and current of the electric power flowing through the specified location. The first storage battery sensor 60 (1) is connected to the first power conditioner 59 (1) and is configured to be able to output a signal related to the detection result to the first power conditioner 59 (1).

The second storage battery system (not shown) to the Nth storage battery system 57 (N) are configured in the same manner as the first storage battery system 57 (1) except that the connection point with the power path L is different. From the second storage battery system to the Nth storage battery system 57 (N), the first storage battery connection point P57 (1) (first storage battery system 57 (1)) and the first connection point P1 (1) (first) of the power path L It is sequentially connected to and from the power storage system 1 (1) (see the Nth storage battery connection point P57 (N) shown in FIG. 15). In such a first storage battery system 57 (1) to an Nth storage battery system 57 (N), the Nth storage battery system 57 (N) is arranged on the most upstream side.

The first storage battery system 57 (1) to the Nth storage battery system 57 (N) configured in this way are time zones set by the discharge start time and the discharge end time when the power selling mode is set. In addition to discharging, charging is performed in a time zone set by the charging start time and the charging end time. Further, the first storage battery system 57 (1) to the Nth storage battery system 57 (N) are required to charge the electric power of the photovoltaic power generation units 2 (1 to N) when the eco mode is set. The charged electric power is discharged according to the above.

The control unit 560 is configured in the same manner as the control unit 60 according to the first embodiment, except that it is connected to the hybrid power conditioner 4 (1 to N) and the power conditioner 59 (1 to N). The control unit 560 can acquire information on the detection result of the storage battery sensor 60 (1 to N) and the like from the signal output from the power conditioner 59 (1 to N).

As described above, the power supply system 501 according to the fifth embodiment is provided with another device (storage battery system 57 (1 to N)) on the downstream side of the first power storage system 1 (1). , It is different from the power supply system 1 of the first embodiment.

In such a power supply system 501, as shown in FIG. 16, the storage batteries 58 (1 to N) and the first storage system 1 (1 to N) from the first storage battery system 57 (1) to the Nth storage battery system 57 (N) ( When the storage batteries 3 (1 to N) (the first storage battery 58 (1) in FIG. 16) from 1) to the N-1 storage system 1 (N-1) are discharged, there is a possibility that the power is sold and discharged. There is.

Next, the discharge stop process of the power supply system 501 according to the fifth embodiment will be described with reference to FIGS. 17 to 19.

The discharge stop process according to the fifth embodiment is a process for suppressing the state of selling electricity and discharging by changing the discharge start time and the discharge end time, as in the discharge stop process according to the first embodiment. .. The target of the discharge stop process according to the fifth embodiment is different from the discharge stop process according to the first embodiment.

First, the contents of the discharge stop processing when the power selling mode is set for the power storage system 1 (1 to N) and the storage battery system 57 (1 to N) in the initial setting will be described.

As shown in FIG. 17, first, in step S810, the control unit 560 confirms whether or not the Nth photovoltaic power generation unit 2 (N) is selling power, as in step S10 according to the first embodiment. To do.

In the fifth embodiment, it is the solar power generation units 2 (1 to N) of the power storage system 1 (1 to N) that generate power using sunlight, as in the first embodiment. Therefore, if the Nth photovoltaic power generation unit 2 (N) does not sell power, the other photovoltaic power generation units 2 (1 to N-1) also do not sell power. Therefore, the control unit 560 confirms whether or not the Nth photovoltaic power generation unit 2 (N) is selling power, as in the first embodiment, and thereby all the photovoltaic power generation units 2 (1 to 1). Check if N) is selling electricity. When the control unit 560 determines that the Nth photovoltaic power generation unit 2 (N) is selling power, the control unit 560 proceeds to step S820. On the other hand, the control unit 560 shifts to step S850 when it is determined that the Nth photovoltaic power generation unit 2 (N) is not selling power.

The control unit 560 that has moved to step S820 is a storage battery other than the Nth storage battery 3 (N) of the Nth power storage system 1 (N), that is, the storage battery 3 (1) in the same manner as in steps S20 to S40 according to the first embodiment. The discharge end times of ~ N-1) and 58 (1 to N) are confirmed, and the discharge start time and discharge end time of the storage batteries 3 (1 to N-1) and 58 (1 to N) are confirmed according to the results. (Steps S820-S840). In the following, storage batteries other than the Nth storage battery 3 (N) will be referred to as "other storage batteries 3 (1 to N-1) and 58 (1 to N)".

On the other hand, the control unit 560 shifted to step S850 sets the discharge start time of the other storage batteries 3 (1 to N-1) and 58 (1 to N) in the same manner as in steps S50 to S70 according to the first embodiment. After confirming, the discharge start time and discharge end time of the other storage batteries 3 (1 to N-1) and 58 (1 to N) are changed according to the result (steps S850 to S870).

As described above, when there is a possibility that the control unit 560 according to the fifth embodiment will be in the power selling / discharging state (steps S810: YES, S820: NO), the other storage batteries 3 (1 to N-1). The discharge start time of 58 (1 to N) is changed (step S830). As a result, as shown in FIG. 18, when another power storage device is arranged on the downstream side of the first power storage system 1 (1), the control unit 360 uses the other storage batteries 3 (1 to N-1). -It is possible to stop the discharge of 58 (1 to N) and suppress the state of selling and discharging power.

Next, the contents of the discharge stop processing when the eco-mode is set for the power storage system 1 (1 to N) and the storage battery system 57 (1 to N) in the initial setting will be described.

As shown in FIG. 19, first, in step S910, the control unit 560 confirms whether or not the Nth photovoltaic power generation unit 2 (N) is selling power, as in step S110 according to the first embodiment. To do. When the control unit 560 determines that the Nth photovoltaic power generation unit 2 (N) is selling power, the control unit 560 proceeds to step S920. On the other hand, when the control unit 560 determines that the Nth photovoltaic power generation unit 2 (N) is not selling power, the control unit 560 proceeds to step S970.

The control unit 560 that has moved to step S920 sets the modes and discharge end times of the other storage batteries 3 (1 to N-1) and 58 (1 to N) in the same manner as in steps S120 to S160 according to the first embodiment. After confirming, the modes, discharge start time and discharge end time of the other storage batteries 3 (1 to N-1) and 58 (1 to N) are changed according to the result (steps S920 to S960).

On the other hand, the control unit 560 shifted to step S970 confirms the modes of the other storage batteries 3 (1 to N-1) and 58 (1 to N) in the same manner as in steps S170 and S180 according to the first embodiment. , The mode of the other storage batteries 3 (1 to N-1) and 58 (1 to N) is changed to the eco mode according to the result (steps S970 and S980).

According to the above, the control unit 560 according to the fifth embodiment is in the power selling mode even when the eco mode is set for the power storage system 1 (1 to N) and the storage battery system 57 (1 to N). The discharge of the other storage batteries 3 (1 to N-1) and 58 (1 to N) can be stopped by using the discharge start time and the discharge end time. As a result, the control unit 560 can prevent the power storage system 1 (1 to N) and the storage battery system 57 (1 to N) from being in the power selling / discharging state even when the eco mode is set.

Next, the power supply system according to the sixth embodiment will be described.

The power supply system according to the sixth embodiment is configured in the same manner as the power supply system 501 according to the fifth embodiment except for the content of the discharge stop processing. The discharge stop process according to the sixth embodiment is a process for suppressing the state of power selling and discharging by changing the charge start time and the charge end time, as in the discharge stop process according to the second embodiment. .. The target of the discharge stop process according to the sixth embodiment is different from the discharge stop process according to the second embodiment.

Hereinafter, the discharge stop processing of the power supply system according to the sixth embodiment will be described with reference to FIGS. 20 and 21.

First, the contents of the discharge stop processing when the power selling mode is set for the power storage system 1 (1 to N) and the storage battery system 57 (1 to N) in the initial setting will be described.

As shown in FIG. 20, first, in step S1010, the control unit 560 confirms whether or not the Nth photovoltaic power generation unit 2 (N) is selling power, as in step S210 according to the second embodiment. To do. When the control unit 560 determines that the Nth photovoltaic power generation unit 2 (N) is selling power, the control unit 560 proceeds to step S1020. On the other hand, when the control unit 560 determines that the Nth photovoltaic power generation unit 2 (N) is not selling power, the control unit 560 shifts to step S1060.

The control unit 560 that has shifted to step S1020 sets the modes and charging start times of the other storage batteries 3 (1 to N-1) and 58 (1 to N) in the same manner as in steps S220 to S260 according to the second embodiment. After confirming, the charging start time, charging end time and discharge end time of the other storage batteries 3 (1 to N-1) and 58 (1 to N) are changed according to the result (steps S1020 to S1050).

On the other hand, the control unit 560 shifted to step S1060 sets the discharge start time of the other storage batteries 3 (1 to N-1) and 58 (1 to N) in the same manner as in steps 260 and S270 according to the second embodiment. After confirming, the charge end time and discharge start time of the other storage batteries 3 (1 to N-1) and 58 (1 to N) are changed according to the result (steps S1060 and S1070).

As described above, when there is a possibility that the control unit 560 according to the sixth embodiment will be in a power selling / discharging state (steps S1010: YES, S1020: NO), the other storage batteries 3 (1 to N-1). The charging start time of 58 (1 to N) is changed (step S1030). As a result, the control unit 560 can use the other storage batteries 3 (1 to N-1) and 58 (1 to N) when another power storage device is arranged on the downstream side of the Nth power storage system 1 (N). It is possible to start charging and suppress the state of selling and discharging electricity.

Next, the contents of the discharge stop processing when the eco-mode is set for the power storage system 1 (1 to N) and the storage battery system 57 (1 to N) in the initial setting will be described.

As shown in FIG. 21, first, in step S1110, the control unit 560 confirms whether or not the Nth photovoltaic power generation unit 2 (N) is selling power, as in step S1010. When the control unit 560 determines that the Nth photovoltaic power generation unit 2 (N) is selling power, the control unit 560 proceeds to step S1120. On the other hand, when the control unit 560 determines that the Nth photovoltaic power generation unit 2 (N) is not selling power, the control unit 560 proceeds to step S1170.

The control unit 560 that has shifted to step S1120 sets the modes and charging start times of the other storage batteries 3 (1 to N-1) and 58 (1 to N) in the same manner as in steps S320 to S360 according to the second embodiment. After confirming, the modes, charging start time and charging end time of the other storage batteries 3 (1 to N-1) and 58 (1 to N) are changed according to the result (steps S112 to S1160).

On the other hand, the control unit 560 shifted to step S1170 confirms the modes of the other storage batteries 3 (1 to N-1) and 58 (1 to N) in the same manner as in steps S370 and S380 according to the second embodiment. , The mode of the other storage batteries 3 (1 to N-1) and 58 (1 to N) is changed to the eco mode according to the result (steps S1170 and S1180).

According to the above, the control unit 560 according to the sixth embodiment is in the power selling mode even when the eco mode is set for the power storage system 1 (1 to N) and the storage battery system 57 (1 to N). The charging of the other storage batteries 3 (1 to N-1) and 58 (1 to N) can be started by using the charging start time and the charging end time. As a result, the control unit 560 can prevent the power storage system 1 (1 to N) and the storage battery system 57 (1 to N) from being in the power selling / discharging state even when the eco mode is set.

The Nth photovoltaic power generation unit 2 (N) according to the fifth embodiment and the sixth embodiment is an embodiment of the power generation unit of the first supply unit according to the present invention.
Further, the Nth power storage system 1 (N) according to the fifth embodiment and the sixth embodiment is an embodiment of the first supply unit according to the present invention.
Further, the other storage batteries 3 (1 to N-1) and 58 (1 to N) according to the fifth embodiment and the sixth embodiment are one embodiment of the storage battery of the second supply unit according to the present invention. is there.
Further, the first power storage system 1 (1) to the N-1 power storage system 1 (N-1) and the first storage battery system 57 (1) to the Nth storage battery system 57 according to the fifth embodiment and the sixth embodiment. Up to (N) is an embodiment of the second supply unit according to the present invention.
Further, the Nth sensor 5 (N) according to the fifth embodiment and the sixth embodiment is an embodiment of the detection unit according to the present invention.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, the electric power supply system is intended to supply electric power to a house, but is not limited to this, and may be configured to supply electric power to an office or the like.

Further, the power generation unit uses sunlight as natural energy, but the present invention is not limited to this, and for example, hydraulic power, wind power, tidal power, or the like may be used.

Further, the storage battery 3 (1 to N) is composed of a lithium ion battery, but is not limited to this, and may be composed of, for example, a nickel hydrogen battery or the like.

Further, the control unit 60 is supposed to stop the discharge of the storage battery 3 (1 to N-1) by setting the discharge end time and the charge start time, but the present invention is not limited to this, and for example, The discharge of the storage battery may be stopped by transmitting a command to stop the discharge of the storage battery to the hybrid power conditioner 4 (1 to N).

Further, in steps S20 and S140, when the discharge end time of the storage battery 3 (1 to N-1) is the same as the current time, the control unit 60 does not necessarily change the discharge end time or the like (to steps S30 and S150). There is no need to (shift), and for example, the discharge stop process may be terminated.

Further, in steps S220 and S340, when the charging start time of the storage battery 3 (1 to N-1) is the same as the current time, the control unit 60 does not necessarily change the charging start time or the like (to steps S230 and S350). There is no need to (shift), and for example, the discharge stop process may be terminated.

Further, the power generation stop time is set at 20:00, but the time is not limited to this as long as the photovoltaic power generation unit 2 (1 to N) cannot generate power, and is set at an arbitrary time. be able to. In addition, the power generation stop time does not have to be set to the same value throughout the year, and is appropriately changed (reset every day) based on, for example, the time of sunset according to the month and day. It may be.

Further, the power generation start time is set at 6 o'clock, but the time is not limited to this as long as the solar power generation unit 2 (1 to N) starts power generation, and any time can be used. Can be set. In addition, the power generation start time does not have to be set to the same value throughout the year, and is appropriately changed (reset every day) based on, for example, the time of sunrise according to the month and day. There may be.

Further, the power supply system 1 does not necessarily have to include the power storage system 1 (1 to N). For example, as in the power supply system 701 according to the seventh embodiment shown in FIG. 22, the power storage system 1 (1 to 1). The configuration may not include N).

The power supply system 701 according to the seventh embodiment includes the photovoltaic power generation system 37 (1 to N) according to the third embodiment, the storage battery system 57 (1 to N) according to the fifth embodiment, and the control unit 760. , Equipped with. The photovoltaic power generation system 37 (1 to N) is arranged on the upstream side of the Nth storage battery system 57 (N). In the control unit 760, is the Nth photovoltaic power generation unit 38 (N) of the Nth photovoltaic power generation system 37 (N) selling power in the same manner as in the discharge stop processing according to the third embodiment and the fourth embodiment? Confirm whether or not, and perform discharge stop processing. Further, the control unit 760 appropriately changes the mode of the storage battery 58 (1 to N), the charging start time, and the like according to the determination result and the like. As described above, the power supply system can be applied to a system that does not include the power storage system 1 (1 to N).

1 Power supply system 1 (1 to N-1) Power storage system (second supply unit)
3 (1 to N-1) Storage battery 1 (N) Nth power storage system (first supply unit)
2 (N) Nth Solar Power Generation Department (Power Generation Department)
5 (N) Nth sensor (detector)
H load K system power supply

Claims (10)

A first supply unit that has a power generation unit that can generate electricity using natural energy and can supply the generated power to a load,
It is arranged on the load side of the first supply unit, can charge the electric power generated by the first supply unit and the electric power from the system power supply, and discharges the charged electric power to discharge the load. A second supply unit with a storage battery that can be supplied to
A detector that can detect the power that flows backward to the system power supply,
A control unit that can acquire the detection result of the detection unit and can control the storage battery, and regulates the discharge of the storage battery when the detection unit detects the reverse power flow.
Equipped with
The control unit
When the detection unit detects the reverse power flow, the storage battery is changed to a state in which it can be charged and cannot be discharged.
Power supply system. The control unit
When the detection unit detects the reverse power flow, the storage battery is changed to a non-dischargeable state.
The power supply system according to claim 1. A first supply unit that has a power generation unit that can generate electricity using natural energy and can supply the generated power to a load,
It is arranged on the load side of the first supply unit, can charge the electric power generated by the first supply unit and the electric power from the system power supply, and discharges the charged electric power to discharge the load. A second supply unit with a storage battery that can be supplied to
A detector that can detect the power that flows backward to the system power supply,
A control unit that can acquire the detection result of the detection unit and can control the storage battery, and regulates the discharge of the storage battery when the detection unit detects the reverse power flow.
Equipped with
The control unit
When the detection unit detects the reverse power flow, the storage battery is changed to a non-dischargeable state.
As a power supply mode, it has a first mode for the purpose of selling the power generated by the power generation unit.
The storage battery is
In the first mode, the discharge is possible from the first time to the second time.
The control unit
In the first mode, when the detection unit detects the reverse power flow and the second time is later than the current time, the second time is set to the current time. Set,
Power supply system. The control unit
In the first mode, when the detection unit detects the reverse power flow and the second time is later than the current time, the power generation unit sets the first time. Set the time when electricity cannot be generated,
The power supply system according to claim 3 . As a power supply mode, it has a first mode for the purpose of selling the power generated by the power generation unit.
The storage battery is
In the first mode, the battery becomes rechargeable and non-dischargeable from the third time to the fourth time.
The control unit
In the first mode, when the detection unit detects the reverse power flow and the third time is later than the current time, the third time is set to the current time. Set,
The power supply system according to claim 1 or 2 . The control unit
In the first mode, when the detection unit detects the reverse power flow and the third time is later than the current time, the power generation unit sets the fourth time. Set the time when electricity cannot be generated,
The power supply system according to claim 5. As a power supply mode, it has a second mode for the purpose of consuming the power generated by the power generation unit with the load.
The control unit
In the second mode, when the detection unit detects the reverse power flow, the power supply mode of the storage battery is switched to the first mode.
The power supply system according to any one of claims 3 to 6 . A first supply unit that has a power generation unit that can generate electricity using natural energy and can supply the generated power to a load,
It is arranged on the load side of the first supply unit, can charge the electric power generated by the first supply unit and the electric power from the system power supply, and discharges the charged electric power to discharge the load. A second supply unit with a storage battery that can be supplied to
A detector that can detect the power that flows backward to the system power supply,
A control unit that can acquire the detection result of the detection unit and can control the storage battery, and regulates the discharge of the storage battery when the detection unit detects the reverse power flow.
Equipped with
The first supply unit
It has a storage battery capable of charging the electric power generated by the power generation unit and the electric power from the system power source, and discharging the charged electric power to supply the load to the load.
Power supply system. The first supply unit
It has a storage battery capable of charging the electric power generated by the power generation unit and the electric power from the system power source, and discharging the charged electric power to supply the load to the load.
The power supply system according to any one of claims 1 to 7 . A first supply unit that has a power generation unit that can generate electricity using natural energy and can supply the generated power to a load,
It is arranged on the load side of the first supply unit, can charge the electric power generated by the first supply unit and the electric power from the system power supply, and discharges the charged electric power to discharge the load. A second supply unit with a storage battery that can be supplied to
A detector that can detect the power that flows backward to the system power supply,
A control unit that can acquire the detection result of the detection unit and can control the storage battery, and regulates the discharge of the storage battery when the detection unit detects the reverse power flow.
Equipped with
The second supply unit is
It also has a power generation unit that can generate electricity using natural energy.
Power supply system.

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