JP7426278B2 - power supply system - Google Patents

Description

The present invention relates to a technology for a power supply system having a storage battery.

BACKGROUND ART Conventionally, techniques for power supply systems having storage batteries have been known. For example, as described in Patent Document 1.

Patent Document 1 describes a power supply system that includes a solar power generation unit that can generate electricity using natural energy, a storage battery that can charge and discharge electricity, and a control unit that can control charging and discharging of the storage battery. has been done.

In this power supply system, when a power outage is predicted to occur, the storage battery is kept on standby until late at night (when electricity costs are low), and the storage battery is charged to full capacity at midnight. After that, the storage battery is kept on standby until a power outage occurs, and when the power outage occurs, the storage battery starts discharging. By controlling the operation of the storage battery in this manner, it is possible to make maximum use of the electric power charged in the storage battery when a power outage occurs.

As described above, in the conventional power supply system, it is possible to improve convenience during a power outage by using a storage battery, but there is still room for further improvement from the viewpoint of economy.

Specifically, in the technology described in Patent Document 1, when a power outage is predicted to occur, electric power is purchased to charge the storage battery to full charge. However, if there is a surplus of power generated by the solar power generation unit before a power outage occurs, it should be possible to charge the storage battery with the surplus power (surplus power). That is, the technique described in Patent Document 1 wastes electricity and charges the storage battery, and there is room for improvement from the economic standpoint.

Patent No. 6426922

The present invention has been made in view of the above circumstances, and an object thereof is to provide a power supply system that is both convenient and economical during power outages.

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

That is, in claim 1, the power generating unit includes a power generation unit capable of generating electricity using natural energy, a storage battery capable of charging and discharging the power generated by the power generation unit, and a control unit capable of controlling charging and discharging of the storage battery. However, when the occurrence of a power outage is predicted, the control unit performs a first charging process to charge the storage battery by a charging amount determined according to surplus power from the power generation unit.

According to a second aspect of the present invention, in the first charging process, the control unit charges the storage battery during a late night time period before a predicted time of occurrence of a power outage.

In claim 3, the control unit is configured to perform the determination according to the surplus power from the power generation unit after the storage battery is charged by the first charging process and before the surplus power is generated from the power generation unit. A first discharging process is performed to enable the storage battery to be discharged by the discharge amount.

In a fourth aspect of the present invention, when surplus power is generated from the power generation unit, the control unit performs a second charging process of charging the storage battery to full charge with the surplus power from the power generation unit.

In a fifth aspect of the present invention, the control unit, after charging the storage battery to full charge by the second charging process, prohibits discharging of the storage battery until a predicted time of occurrence of a power outage.

In claim 6, when the occurrence of a power outage is predicted, there is a late night time period before the predicted time of occurrence of the power outage, and surplus power from the power generation unit is not generated before the predicted time of occurrence of the power outage, , a third charging process is performed to charge the storage battery during the late night time period.

In claim 7, when the occurrence of a power outage is predicted and there is no late night time before the predicted time of occurrence of the power outage, the control unit performs a fourth charging process of charging the storage battery with surplus power from the power generation unit. This is what we do.

In claim 8, when the occurrence of a power outage is predicted, there is no late night time period before the predicted time of occurrence of the power outage, and no surplus power is generated from the power generation section before the predicted time of occurrence of the power outage, , a fifth charging process is performed in which the storage battery is charged with power from the grid power source.

The present invention has the following effects.

In claim 1, it is possible to achieve both convenience and economy during a power outage.

In claim 2, economical efficiency can be improved.

In claim 3, it is possible to effectively utilize the electric power charged in the storage battery.

According to the fourth aspect of the present invention, the surplus power can be used to charge the storage battery with power in preparation for the occurrence of a power outage.

In the fifth aspect, since the storage battery can be left fully charged until a power outage occurs, it is possible to fully prepare for a power outage.

According to claim 6, even if surplus power is not generated, it is possible to prepare for a power outage at a relatively low cost.

According to claim 7, even if there is no late night time period, it is possible to prepare for a power outage at a relatively low cost.

According to claim 8, even if electric power cannot be secured at low cost, the storage battery can be charged in preparation for a power outage.

1 is a block diagram showing the configuration of a power supply system according to an embodiment of the present invention. Diagram showing images of conventional control and power outage risk response control. The figure which showed the flowchart of power outage risk response control. 4 is a diagram showing a continuation of the flowchart of FIG. 3. FIG. The figure which showed the specific example when power outage risk response control is performed.

Hereinafter, a power supply system 1 according to an embodiment of the present invention will be described using FIG. 1. Note that in this specification, "upstream side" and "downstream side" are based on the direction of power supply from system power supply K.

The power supply system 1 shown in FIG. 1 supplies power from a system power supply K and generated power to a load H. The power supply system 1 is installed in a house, and supplies power to a load H of the house (for example, house equipment, etc.). The power supply system 1 mainly includes a power storage system 10, a distribution board 20, a power sensor 40, and an EMS 60.

The power storage system 10 stores power and supplies it to a load H. Power storage system 10 is provided between system power supply K and load H. The power storage system 10 includes a solar power generation unit 11, a storage battery 12, and a hybrid power conditioner 13.

The solar power generation unit 11 is a device that generates power using sunlight. The solar power generation unit 11 is composed of a solar battery panel and the like. The solar power generation unit 11 is installed in a sunny place, such as on the roof of a house, for example.

The storage battery 12 is configured to be able to be charged with electric power. The storage battery 12 is composed of, for example, a lithium ion battery. The storage battery 12 is connected to the solar power generation unit 11 via a hybrid power conditioner 13, which will be described later.

The hybrid power conditioner 13 is a device (hybrid power conditioner) that converts electric power as appropriate. The hybrid power conditioner 13 can output the electric power generated by the solar power generation unit 11 and the electric power discharged from the storage battery 12 to the distribution line L (load H), and can also output the electric power flowing through the distribution line L (from the grid power supply K). power) to the storage battery 12. Further, the hybrid power conditioner 13 is configured to be able to acquire information regarding the performance and operating status of the solar power generation unit 11 and the storage battery 12. The hybrid power conditioner 13 is connected to a midway portion (connection point P) of a power distribution line L that connects a system power supply K and a load H (distribution board 20) via an electric line A1. The hybrid power conditioner 13 of the power storage system 10 can perform load following operation in which the electric power to be discharged (output) is adjusted based on the detection result of the electric power sensor 40, which will be described later.

The distribution board 20 distributes power to the loads H. Distribution board 20 is provided downstream of power storage system 10 (connection point P) and is connected to load H. Although only one load H is shown in FIG. 1, the distribution board 20 is connected to a plurality of loads and distributes power to each load. The distribution board 20 supplies the power from the system power supply K and the power discharged from the storage battery 12 to the load H.

The power sensor 40 is provided in the middle of the power distribution line L. More specifically, power sensor 40 is provided upstream of power storage system 10 (connection point P) (immediately upstream of connection point P). The power sensor 40 detects the voltage (supply voltage) and current (supply current) of power (power flowing upstream and power flowing downstream) flowing through the location where the power sensor 40 is provided.

The EMS 60 is an energy management system that manages the operation of the power supply system 1. The EMS 60 includes an arithmetic processing unit such as a CPU, a storage unit such as a RAM or ROM, an input/output unit such as a touch panel, and the like. The storage unit of the EMS 60 stores in advance various information, programs, etc. used when controlling the operation of the power supply system 1. The arithmetic processing unit of the EMS 60 can operate the power supply system 1 by executing the program and performing predetermined arithmetic processing using the various pieces of information.

EMS 60 is electrically connected to hybrid power conditioner 13. The EMS 60 can transmit a predetermined signal to the hybrid power conditioner 13 and control the operation of the storage battery 12 (for example, charging and discharging the storage battery 12, etc.). Further, the EMS 60 is configured to be able to receive a predetermined signal from the hybrid power conditioner 13, and can acquire various information (such as the remaining amount of power stored in the storage battery 12).

In the power supply system 1 configured as described above, the storage battery 12 can be charged with power purchased from the grid power supply K or power generated by the solar power generation unit 11. In addition, in the power supply system 1, the power purchased from the grid power supply K, the power generated by the solar power generation unit 11, and the power charged in the storage battery 12 can be supplied to the residential load H. . Further, in the power supply system 1, the surplus power (surplus power) generated by the solar power generation unit 11 can be reversely flowed to the grid power supply K and sold.

Below, a control mode of power distribution in the power supply system 1 configured as described above will be explained. Specifically, two types of control ("normal control" and "power outage risk response control") will be explained.

First, an example of normal control will be described. Normal control is control of the power supply system 1 during normal times. Note that in the present embodiment, normal time means a case where "power outage risk response control", which will be described later, is not executed.

In normal control, the hybrid power conditioner 13 supplies electric power from the solar power generation section 11 to the load H when the solar power generation section 11 is generating power. Further, the hybrid power conditioner 13 performs a load following operation in which the discharge power of the storage battery 12 is determined based on the detection result of the power sensor 40.

For example, when the power from the solar power generation unit 11 is insufficient for the power consumption of the load H, the power is discharged from the storage battery 12 and the power is supplied to the load H. On the other hand, when the power from the solar power generation unit 11 is surplus to the power consumption of the load H, the hybrid power conditioner 13 charges the storage battery 12 with the surplus power. If there is still surplus power from the solar power generation unit 11 even after charging the storage battery 12 with the maximum charging power (the maximum amount of power that the storage battery 12 can charge per unit time), the hybrid power conditioner 13 uses the surplus power. is caused to flow backward to the grid power supply S.

Note that, as described above, the normal control in this embodiment is a control mode of the power supply system 1 when the power outage risk response control described later is not executed. The specific control mode of the normal control is not limited to the above-mentioned mode, and can be arbitrarily set according to the user's purpose (economy, energy saving, environmental load reduction, etc.).

Next, power outage risk response control will be explained. Power outage risk response control is control for achieving both convenience and economy during power outages when a power outage is predicted to occur. Note that in this embodiment, "power outage risk" means that there is a possibility that a power outage will occur in the future.

First, an overview of power outage risk response control will be explained using FIG. 2.

For comparison, FIG. 2 shows an image of the control described in Patent Document 1 (conventional control) and an image of the power outage risk response control according to the present embodiment. In conventional control, when a power outage risk is detected (predicted), the storage battery is charged to full charge during the previous midnight hours, and the storage battery is kept on standby until the time when the power outage risk occurs. As a result, if a power outage actually occurs, the power stored in the storage battery can be used.

However, with conventional control, the storage battery is kept on standby until the risk of a power outage occurs, so it is difficult to say that the storage battery is fully utilized. Furthermore, even if there is a surplus of power generated by the solar power generation section before the risk of a power outage occurs, the storage battery cannot be charged with the surplus power, so there is room for improvement from an economic standpoint.

In contrast, in the power outage risk response control of the present embodiment, (1) when a power outage risk is detected (predicted), (2) it is predicted whether surplus power will be generated before the power outage risk occurs. (3) If it is predicted that surplus power will be generated, the storage battery 12 is charged to a predetermined target value (late-night charging target) during the late-night hours. In the example of FIG. 2, the storage battery 12 is charged to 70%. That is, the power outage risk response control does not necessarily charge the storage battery 12 to full charge.

Next, (4) the storage battery 12 is appropriately discharged to a predetermined target value (discharge target, 50% in the example of FIG. 2), and the electric power charged in the storage battery 12 is used by the load. Moreover, (5) when surplus power is generated, the storage battery 12 is charged to full charge using the surplus power. Thereafter, the storage battery 12 is put on standby until the time when the risk of power outage occurs.

In this way, in the power outage risk response control, if the generation of surplus power is predicted in advance, the storage battery 12 is charged to the minimum amount necessary during late night hours in anticipation of charging the storage battery 12 with the surplus power. I have to. Thereby, the amount of electricity purchased from the grid power supply K can be suppressed. Also, in the power outage risk response control, the storage battery 12 is discharged within a reasonable range (up to the discharge target) between the time of charging in the late night time period and the time when the power outage risk occurs. Thereby, it is possible to utilize the electric power charged in the storage battery 12.

Next, a detailed flow (flowchart) of the power outage risk response control will be described using FIGS. 3 and 4. Note that the processes in FIGS. 3 and 4 are repeatedly executed by the EMS 60 at predetermined time intervals.

In step S10, the EMS 60 determines whether there is a risk of power outage (possibility of power outage occurring). Here, the presence or absence of a power outage risk can be determined based on various types of information. For example, the EMS 60 can determine whether there is a risk of power outage and the time at which the risk of power outage occurs, based on external information (for example, information on previously planned power outages, etc.) acquired by any method. The EMS 60 can also determine whether there is a risk of power outage based on weather forecasts or the like. For example, if a weather forecast shows that a large typhoon is approaching, it can be determined that there is a risk of power outage.

Note that the period for which the presence or absence of a power outage risk is to be determined (hereinafter referred to as the "target period") can be arbitrarily set. For example, the EMS 60 can determine whether there is a risk of power outage within 24 hours from the current time.

When the EMS 60 determines that there is no risk of power outage, the process moves to step S11. On the other hand, if the EMS 60 determines that there is a risk of power outage, the process moves to step S12.

In step S11, the EMS 60 executes the above-mentioned normal control. That is, if there is no risk of power outage, power outage risk response control is ended and normal control is entered.

On the other hand, in step S12, which is a transition from step S10, the EMS 60 calculates the power demand, power generation amount (generated power), and surplus power (surplus power when the power from the solar power generation unit 11 is supplied to the load H) during the target period. ) to predict. In this process, the EMS 60 makes the prediction based on, for example, information such as a weather forecast obtained from an external source, and various types of information it has in advance (data on past generated power, data on past purchased power, etc.). conduct. The EMS 60 also predicts the power demand and the like at each time (every hour). After performing the process in step S12, the EMS 60 moves to step S13.

In step S13, the EMS 60 determines whether there is a late night time period before the risk of power outage. Specifically, the EMS 60 determines whether there is a time period (midnight time period) in which late-night electricity (relatively cheap electricity) rates are set between the current moment and the time when the risk of power outage is predicted to occur. Determine whether

If the EMS 60 determines that there is late-night power before the risk of a power outage ("YES" in step S13), the process proceeds to step S14. On the other hand, if the EMS 60 determines that there is no late-night power before the risk of a power outage ("NO" in step S13), the process proceeds to step S20 (see FIG. 4).

In step S14, the EMS 60 determines whether surplus power will be generated between midnight and the risk of a power outage. The EMS 60 can perform the process in step S14 based on the power outage risk determined in step S10 and the surplus power predicted in step S12.

When the EMS 60 determines that surplus power will be generated from the late night time period to the risk of a power outage ("YES" in step S14), the process proceeds to step S15. On the other hand, if the EMS 60 determines that surplus power will not be generated between midnight and the risk of power outage ("NO" in step S14), the process proceeds to step S19.

In step S15, the EMS 60 charges the storage battery 12 during the late night time period until the amount of charge of the storage battery 12 reaches the late night charging target. At this time, the storage battery 12 is charged with relatively inexpensive power (late-night power) purchased from the system power supply K (power purchase). Here, the "late night charging target" is the target value for charging the storage battery 12 (target value for the remaining charge amount) in the process of step S15. The late-night charging target can be set in consideration of the discharge power that will be discharged by the storage battery 12 before the risk of power outage occurs and the surplus power that will be generated before the risk of power outage occurs. Specifically, the late-night charging target is set to an appropriate value that allows the storage battery 12 to be fully charged at the end of the time slot in which surplus power is generated (discharge end time to be described later).

As an example, the late-night charging target can be set using the following equations (1) and (2).
Late-night charging target = 1 - (surplus electricity - discharge amount) ÷ electricity storage capacity ... (1)
Late night charging target = (discharge amount / storage capacity) + minimum discharge threshold ... (2)

Here, "surplus power amount" means the accumulation of surplus power (power amount) from the end of the midnight period until the risk of power outage. In addition, the "discharge amount" refers to the amount of electricity that would be purchased from the grid power supply K between the end of the midnight period and the time period when surplus power is generated, assuming that the storage battery 12 does not discharge. It is. Moreover, "storage capacity" is the amount of power that can be charged to the storage battery 12 (capacity of the storage battery 12). In addition, the "minimum discharge threshold" is the minimum value (for example, 0.3 (30%), etc.) of the amount of power that the storage battery 12 should always secure in case of an emergency (for example, during a power outage, etc.). . Although the above formulas (1) and (2) express the late-night charging target as a percentage, it is also possible to multiply the calculated value by 100 and express it as a percentage.

The EMS 60 can set the value calculated using the above equation (1) or equation (2) as the late-night charging target. In particular, the above equation (1) applies when the amount of surplus electricity is relatively small (specifically, when the storage battery 12 cannot be fully charged with only the amount of surplus electricity (the amount of surplus electricity is less than the capacity of the storage battery 12)). It is preferable to use In addition, the above formula (2) applies when the amount of surplus electricity is relatively large (specifically, when the storage battery 12 can be fully charged with only the amount of surplus electricity (the amount of surplus electricity is greater than the capacity of the storage battery 12)). It is preferable to use The EMS 60 can also calculate the above equations (1) and (2), compare the two, and set the larger value as the late-night charging target. The EMS 60 charges the storage battery 12 during the late night time period until the amount of charge reaches the set late night charging target. After performing the process in step S15, the EMS 60 moves to step S16.

In step S16, the EMS 60 discharges the storage battery 12 after the end of the midnight period until the discharge end time or until the amount of charge of the storage battery 12 reaches the discharge target. Here, the "discharge end time" means the time when surplus power starts to be generated. Further, the "discharge target" is a target value for discharging the storage battery 12 (target value for remaining charge amount) in the process of step S16. The discharge target can be set in consideration of the surplus power that will be generated before the risk of a power outage. Specifically, the discharge target is set to a value that can ensure the remaining amount of the storage battery 12 so that the storage battery 12 can be charged to full charge using surplus power.

As an example, the discharge target can be set using the following equation (3).
Discharge target = 1 - surplus electricity amount / storage capacity ... (3)

After performing the process in step S16, the EMS 60 moves to step S17.

In step S17, if surplus power is generated, the EMS 60 charges the storage battery 12 with the surplus power until it is fully charged. When the storage battery 12 becomes fully charged, the EMS 60 puts the storage battery 12 on standby until there is a risk of a power outage.

Further, the EMS 60 discharges the storage battery 12 when the time when a power outage risk occurs (when a power outage occurs). This allows the load H to utilize electric power even during a power outage.

After performing the process in step S17, the EMS 60 moves to step S18.

In step S18, the EMS 60 operates after the risk of power outage has been resolved (for example, when obtaining information that a planned power outage has been cancelled, or when recovering from an actual power outage (power restoration), etc.) ), the normal control described above is executed. That is, when the power outage risk is eliminated, power outage risk response control is ended and normal control is entered.

On the other hand, in step S19 following step S14, the EMS 60 charges the storage battery 12 to full charge during the late night hours. When the storage battery 12 becomes fully charged, the EMS 60 puts the storage battery 12 on standby until there is a risk of a power outage. Further, the EMS 60 discharges the storage battery 12 when the time when a power outage risk occurs (when a power outage occurs). After performing the process in step S19, the EMS 60 moves to step S18.

On the other hand, in step S20 (see FIG. 4) transferred from step S13, the EMS 60 determines whether surplus power will be generated before the risk of power outage. The EMS 60 can perform the process in step S20 based on the power outage risk determined in step S10 and the surplus power predicted in step S12.

When the EMS 60 determines that surplus power will be generated before the risk of a power outage ("YES" in step S20), the process proceeds to step S21. On the other hand, when the EMS 60 determines that surplus power will not be generated before the risk of power outage ("NO" in step S20), the process proceeds to step S25.

In step S21, the EMS 60 determines whether the surplus power amount is greater than the power required to charge the storage battery 12 to full charge (required charge amount=storage capacity−remaining charge amount). Note that the "remaining charge amount" is the amount of power (remaining amount) charged in the storage battery 12. The "remaining charge amount" in step S21 is determined by the remaining amount of the storage battery 12 at the time when surplus power starts to be generated.

When the EMS 60 determines that the surplus power amount is greater than the required charging amount ("YES" in step S21), the process proceeds to step S22. On the other hand, when the EMS 60 determines that the surplus power amount is less than or equal to the required charging amount ("NO" in step S21), the process proceeds to step S24.

In step S22, if surplus power is generated, the EMS 60 charges the storage battery 12 with the surplus power until it is fully charged. At this time, the storage battery 12 is not charged with power from the system power supply K, but only with surplus power.

In addition, at this time, if the storage battery 12 can be sufficiently charged to full charge with the surplus power (that is, if the surplus power is larger than the power required to charge the storage battery 12), it is also possible to discharge the storage battery 12 in advance. It is. In this case, the amount of power that can be discharged (dischargeable amount) can be determined by the following equation (4).
Dischargeable amount = Surplus electricity amount - Storage capacity + Remaining charge amount... (4)

Further, the EMS 60 discharges the storage battery 12 when the time when a power outage risk occurs (when a power outage occurs). This allows the load H to utilize electric power even during a power outage.

After performing the process of step S22, the EMS 60 moves to step S23.

In step S23, the EMS 60 executes the above-mentioned normal control after the risk of power outage is eliminated. That is, when the power outage risk is eliminated, power outage risk response control is ended and normal control is entered.

On the other hand, in step S24, which is a transition from step S21, if surplus power is generated, the EMS 60 charges the storage battery 12 with the surplus power until it is fully charged. At this time, since the surplus power alone is insufficient, the insufficient amount is purchased (purchased power) from the grid power source K and charged. When the storage battery 12 becomes fully charged, the EMS 60 puts the storage battery 12 on standby until there is a risk of a power outage.

Further, the EMS 60 discharges the storage battery 12 when the time when a power outage risk occurs (when a power outage occurs). This allows the load H to utilize electric power even during a power outage.

After performing the process in step S24, the EMS 60 moves to step S23.

On the other hand, in step S25 following step S20, the EMS 60 immediately charges the storage battery 12 until it is fully charged. At this time, the storage battery 12 is charged with the power purchased (purchased power) from the system power supply K. When the storage battery 12 becomes fully charged, the EMS 60 puts the storage battery 12 on standby until there is a risk of a power outage.

Further, the EMS 60 discharges the storage battery 12 when the time when a power outage risk occurs (when a power outage occurs). Specifically, the storage battery 12 discharges power according to the load H by performing load following operation. This allows the load H to utilize electric power even during a power outage.

After performing the process in step S25, the EMS 60 moves to step S23.

As described above, when the EMS 60 determines that there is a risk of power outage ("YES" in step S10 of FIG. 3), the EMS 60 uses various predicted values to determine if there is a risk of a power outage during late night hours or surplus power. It is determined whether there is one (steps S12 to S14). Then, if there is late-night hours or surplus power before the risk of a power outage, the storage battery 12 is charged to the minimum amount during the late-night hours (step S15). This makes it possible to suppress wasteful power purchase (power purchase) from the system power supply K.

Further, the EMS 60 discharges the power charged in the storage battery 12 and utilizes it in the load H, and then uses the surplus power to charge the storage battery 12 to full charge (step S16, step S17). In this way, while effectively utilizing the electric power charged in the storage battery 12, it is possible to charge the storage battery 12 to full charge before the risk of a power outage and prepare for the risk of a power outage.

On the other hand, if the EMS 60 determines that there is a late-night time period before the risk of power outage, but that surplus power will not be generated ("YES" in step S13, "NO" in step S14), the EMS 60 uses relatively inexpensive late-night power. By charging (step S19), it is possible to prepare for the risk of power outage at low cost.

Further, if the EMS 60 determines that surplus power will be generated even though there is no late night time before the risk of power outage ("NO" in step S13, "YES" in step S20 of FIG. 4), the EMS 60 transfers the surplus power to the storage battery 12. charge it. At this time, if the storage battery 12 can be charged to full charge with only the surplus power, the storage battery 12 is charged without purchasing power from the grid power supply K ("YES" in step S21, step S22). On the other hand, if the storage battery 12 cannot be fully charged with the surplus power alone, the insufficient amount is purchased from the grid power supply K and the storage battery 12 is charged ("NO" in step S21, step S23). In this way, by charging the storage battery 12 using surplus power as much as possible, it is possible to prepare for the risk of power outage at low cost.

In addition, if the EMS 60 determines that there is no surplus power during the midnight hours before the risk of a power outage ("NO" in step S13 of FIG. 3, "NO" in step S20 of FIG. 4), the EMS 60 immediately fills the storage battery 12. Charge until fully charged. In this way, when it is not possible to secure power at a low cost (when neither late-night power nor surplus power can be secured), by immediately fully charging the storage battery 12, it is possible to promptly prepare for the risk of power outage. .

A specific example of actual power outage risk response control will be shown below. In addition, in FIG. 5, the charging power of the storage battery 12, the purchased power from the grid power supply K, the discharged power, the power consumption (in-house consumption) of the solar power generated by the load H, the power demand of the load H, the solar The generated power (PV) and the remaining amount of power stored (SOC) of the photovoltaic power generation unit 11 are shown.

In the illustrated example, it is assumed that the late night time period is from 0:00 to 7:00. In the illustrated example, it is assumed that a power outage risk is predicted after 21:00, and that there is a late night time period or surplus power before the power outage risk (steps S10 to S14 in FIG. 3). Therefore, the EMS 60 calculates a late-night charging target and charges the storage battery 12 (step S15).

In the illustrated example, the amount of surplus electricity is 3.7kWh, and the amount of electricity (discharge amount) that will be purchased from midnight until the surplus electricity is generated (7:00 to 9:00) is 2.2kWh. It is assumed that the electricity storage capacity is 5.4 kWh. In this case, if the late-night charging target is calculated using the above equation (1), for example, the late-night charging target = 1 - (3.7 - 2.2) ÷ 5.4 = 0.72 (72%). For this reason, the EMS 60 charges the storage battery 12 until the amount of charge (SOC) of the storage battery 12 reaches 72% during late night hours.

Next, the EMS 60 discharges the storage battery 12 to the discharge target (step S16). Here, when the discharge target is calculated using the above equation (3), the discharge target=1-3.7÷5.4=0.31 (31%). Therefore, the EMS 60 discharges the storage battery 12 after 7 o'clock until the amount of charge (SOC) of the storage battery 12 reaches 31%.

Finally, the EMS 60 charges the storage battery 12 to full charge using the surplus power (step S17), thereby maintaining the storage battery 12 fully charged at the time when the risk of power outage is predicted (21:00). I can do it.

As described above, in the power supply system 1 according to the present embodiment, when a risk of power outage occurs, the storage battery 12 is charged with late-night power to the minimum amount necessary. Then, by discharging the storage battery 12 to utilize the power and charging the surplus power, the storage battery 12 can be fully charged before the risk of a power outage. As a result, economical efficiency can be improved by suppressing wasteful charging (purchasing power from the system power source K) while ensuring charging power for the storage battery 12 that can be used during a power outage.

As described above, the power supply system 1 according to this embodiment,
A solar power generation section 11 (power generation section) capable of generating electricity using natural energy;
a storage battery 12 capable of charging and discharging the power generated by the solar power generation unit 11;
an EMS 60 (control unit) capable of controlling charging and discharging of the storage battery 12;
Equipped with
The EMS 60 is
When the occurrence of a power outage is predicted, a first charging process (step S15) is performed to charge the storage battery 12 by a charging amount determined according to the surplus power from the solar power generation unit 11.

With this configuration, it is possible to achieve both convenience and economy during a power outage. That is, since it is possible to charge only the amount of charge corresponding to the surplus power, it is possible to perform charging in preparation for a power outage while suppressing wasteful charging (power purchase).

Further, the EMS 60 is
In the first charging process, the storage battery 12 is charged during the midnight hours before the expected time of occurrence of a power outage.

With this configuration, economical efficiency can be improved. That is, the storage battery 12 can be charged during late night hours when charges are relatively low.

Further, the EMS 60 is
After the storage battery 12 is charged by the first charging process and before the surplus power from the solar power generation unit 11 is generated, only the discharge amount determined according to the surplus power from the solar power generation unit 11 is generated. A first discharging process (step S16) is performed to enable the storage battery 12 to be discharged.

With this configuration, it is possible to effectively utilize the electric power charged in the storage battery 12. That is, since the storage battery 12 can be charged if surplus power is generated, the power can be discharged and used effectively before surplus power is generated.

Further, the EMS 60 is
When surplus power is generated from the solar power generation unit 11, a second charging process (step S17) is performed to charge the storage battery 12 to full charge with the surplus power from the solar power generation unit 11.

With this configuration, surplus power can be used to charge the storage battery 12 with power in preparation for the occurrence of a power outage. Thereby, there is no need to purchase electric power from the grid power supply K, so economical efficiency can be improved.

Further, the EMS 60 is
After the storage battery 12 is charged to full charge by the second charging process, discharging of the storage battery 12 is prohibited until the predicted time of occurrence of a power outage (step S17).

With this configuration, the storage battery 12 can be kept fully charged until a power outage occurs, so that it is possible to sufficiently prepare for a power outage.

Further, the EMS 60 is
If a power outage is predicted to occur, there is a late night period before the predicted time of occurrence of the power outage, and surplus power is not generated from the solar power generation unit 11 before the predicted time of occurrence of the power outage, the storage battery is used in the late night period. 12 is performed (step S19).

With this configuration, even if surplus power is not generated, it is possible to prepare for a power outage at a relatively low cost. That is, when surplus power is not generated, by charging the storage battery 12 with relatively inexpensive late-night power, it is possible to prepare for a power outage at low cost.

Further, the EMS 60 is
If the occurrence of a power outage is predicted and there is no late night time before the predicted time of occurrence of the power outage, a fourth charging process of charging the storage battery 12 with surplus power from the solar power generation unit 11 (step S22, step S24) This is what we do.

With this configuration, even if there is no late-night time slot, it is possible to prepare for a power outage at a relatively low cost.

Further, the EMS 60 is
If the occurrence of a power outage is predicted, there is no late night time before the predicted time of occurrence of the power outage, and no surplus power is generated from the solar power generation unit 11 before the predicted time of occurrence of the power outage, the power from the grid power source K is A fifth charging process (step S25) is performed to charge the storage battery 12.

With this configuration, even if electric power cannot be secured at low cost, the storage battery 12 can be charged in preparation for a power outage. That is, when charging during late night hours or charging with surplus power is not possible, the storage battery 12 can be charged with power from the grid power supply K in preparation for a power outage.

Note that the solar power generation section 11 according to the present embodiment is an embodiment of the power generation section according to the present invention.
Furthermore, the EMS 60 according to the present embodiment is an embodiment of the control 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 changes can be made within the scope of the invention described in the claims.

The mathematical formulas and numerical values used in this embodiment are merely examples, and any mathematical formulas and numerical values can be used. For example, equations (1) and (2) used in step S15, equation (3) used in step S16, equation (4) used in step S22, etc. can be changed arbitrarily.

Further, the flowchart of the power outage risk response control illustrated in this embodiment is an example, and the processing contents and order can be changed arbitrarily.

Further, in this embodiment, the power generation unit is the solar power generation unit 11 that generates power using sunlight, but it may generate power using other natural energy (for example, hydropower or wind power). It's okay.

Further, in this embodiment, the power supply system 1 is installed in a house, but is not limited to this, and may be installed in an office or the like, for example.

1 Power supply system 10 Power storage system 11 Solar power generation section 12 Storage battery 13 Hybrid power conditioner 60 EMS

Claims (8)

A power generation section that can generate electricity using natural energy,
a storage battery capable of charging and discharging the power generated by the power generation section;
a control unit capable of controlling charging and discharging of the storage battery;
Equipped with
The control unit includes:
When the occurrence of a power outage is predicted, performing a first charging process to charge the storage battery by a charging amount determined according to surplus power from the power generation unit;
Power supply system. The control unit includes:
In the first charging process, the storage battery is charged during a late night time period before the expected time of occurrence of a power outage.
The power supply system according to claim 1. The control unit includes:
After the storage battery is charged by the first charging process and before surplus power is generated from the power generation unit, the storage battery is enabled to be discharged by a discharge amount determined according to the surplus power from the power generation unit. Performing the first discharge treatment,
The power supply system according to claim 1 or claim 2. The control unit includes:
If surplus power is generated from the power generation unit, performing a second charging process of charging the storage battery to full charge with the surplus power from the power generation unit;
The power supply system according to any one of claims 1 to 3. The control unit includes:
After charging the storage battery to full charge through the second charging process, discharging the storage battery is prohibited until a predicted time of occurrence of a power outage.
The power supply system according to claim 4. The control unit includes:
If a power outage is predicted to occur, there is a late night time period before the predicted time of the power outage, and surplus power is not generated from the power generation unit before the predicted time of the power outage, the storage battery is charged during the late night time period. performing the third charging process;
The power supply system according to any one of claims 1 to 5. The control unit includes:
If the occurrence of a power outage is predicted and there is no late night time before the predicted time of occurrence of the power outage, performing a fourth charging process of charging the storage battery with surplus power from the power generation unit;
The power supply system according to any one of claims 1 to 6. The control unit includes:
If a power outage is predicted to occur, there is no late night time before the predicted time of the power outage, and no surplus power is generated from the power generation unit before the predicted time of the power outage, the storage battery is charged with power from the grid power source. The fifth step is to perform the charging process,
The power supply system according to any one of claims 1 to 7.

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