JP2023050869A - power supply system - Google Patents

Abstract

To provide a power supply system capable of reducing electric power charges by lowering the maximum demand value.SOLUTION: A storage battery 32 connected between a system power supply S and a load group H and capable of charging and discharging electric power from a predetermined supply source (the system power supply S and a solar power generation unit 31 and a control unit 40 that controls charging and discharging the storage battery 32 are included. The power storage battery 32 is set with a lower limit of remaining charge indicating the lower limit of the power that can be discharged normally out of the remaining charge. The control unit 40 issues an emergency discharge instruction to enable discharge from the storage battery 32 (steps S209 and S210), during each demand period, when the demand value (expected demand value) of the demand time period is predicted to exceed a first reference value (emergency discharge instruction condition×safety factor) (Yes in step S201) and can lower the lower limit of the remaining amount of the storage battery 32 (step S209) when there is a storage battery 32 with a remaining charge level equal to or lower than the lower limit of remaining capacity (NO in step S208) before the emergency discharging instruction is given.SELECTED DRAWING: Figure 5

Description

The present invention relates to technology of a power supply system having a storage battery that can charge and discharge power.

2. Description of the Related Art Conventionally, technology of a power supply system that includes a storage battery connected between a system power supply and a load and controls charging and discharging of the storage battery is known. For example, it is as described in Patent Document 1.

Patent Literature 1 describes a storage battery system in which a storage battery is connected to an electric line that connects a commercial system and a load. With such a configuration, a relatively large amount of electric power charged in the storage battery can be supplied to the load as needed.

In such a storage battery system, an electricity charge is collected for power purchased from the commercial grid. In addition, as one of the contract contents of electricity charges, there is a demand charge system. The demand rate system is a system in which the contract power for each month is determined based on the maximum demand value (maximum power demand) for the month or the maximum power demand for the past 11 months, whichever is greater. Here, the demand value means the average power consumption within a time period (demand time limit) of 30 minutes, and the maximum value of this demand value is called the maximum demand value. For this reason, in order to suppress the electricity charge under the demand charge system, it is desirable to find a way to lower the maximum demand value.

JP 2012-44733 A

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 reducing the power charge by lowering the maximum demand value. .

The problems to be solved by the present invention are as described above, and the means for solving the problems will now be described.

That is, in claim 1, there is provided a power supply system for supplying power to a load connected to a system power supply, which is connected between the system power supply and the load and charges and discharges power from a predetermined supply source. and a control unit that controls charging and discharging of the storage battery, and the storage battery is set with a lower limit of remaining amount indicating the lower limit of the power that can be normally discharged out of the remaining amount of charge, and the When the control unit predicts that the demand value of the demand time period exceeds the first reference value during each demand time period, the control unit issues an emergency discharge instruction to enable discharge from the storage battery, and the remaining charge amount reaches the lower limit value of the remaining amount. When there is the following storage battery, it is possible to lower the lower limit of remaining capacity of the storage battery before issuing the emergency discharge instruction.

In claim 2, the control unit can acquire the power consumption from the system power supply, and the actual value of the power consumption up to the present time in the demand time period and the use of the remaining time of the demand time period Based on the predicted value of the power amount, it is determined whether or not the demand value of the demand time period exceeds the first reference value.

In claim 3, the control unit calculates the predicted value of the power usage for the remaining time based on the power usage for the most recent predetermined period.

In claim 4, a plurality of the storage batteries are provided, and the control section issues the emergency discharge instruction in order from the storage battery with the highest remaining charge among the plurality of storage batteries.

In claim 5, after issuing the emergency discharge instruction, the control unit predicts that the demand value of the demand time period does not exceed the first reference value or a second reference value smaller than the first reference value. In this case, the emergency discharge instruction can be canceled.

According to a sixth aspect of the present invention, when the emergency discharge instruction is canceled, the control unit can raise the reduced remaining capacity lower limit value to the original remaining capacity lower limit value.

In claim 7, after canceling the emergency discharge instruction, if there is a storage battery with a remaining charge amount that is less than the increased lower limit value of remaining amount, the control unit issues a priority charging instruction to allow the storage battery to be charged. It is something to do.

In claim 8, a plurality of the storage batteries are provided, and when there are a plurality of storage batteries whose remaining charge levels are less than the lower limit value for which the remaining charge levels have been increased, the controller controls the storage battery with the lowest remaining charge level among the plurality of storage batteries. The priority charging instruction is given in order from .

As effects of the present invention, the following effects are obtained.

In claim 1, the power charge can be reduced by lowering the maximum demand value.

In claim 2, the demand value can be predicted with high accuracy.

In claim 3, the demand value can be predicted with higher accuracy.

In claim 4, the maximum demand value can be lowered efficiently.

In claim 5, it is possible to suppress the unnecessary use of electric power for emergencies such as power outages.

In claim 6, it is possible to further suppress the useless use of electric power for emergencies such as power outages.

In claim 7, electric power for emergencies such as power outages can be stored in the storage battery.

In claim 8, the storage battery can be efficiently charged.

1 is a block diagram showing the configuration of a power supply system according to one embodiment of the present invention; FIG. FIG. 2 is a block diagram showing an example of a power supply mode when a charge/discharge mode is executed; FIG. 10 is a block diagram showing an example of a power supply mode when the charge remaining amount of the storage battery decreases and reaches the lower limit value of the remaining amount when the charge/discharge mode is executed; 4 is a flow chart showing a flow regarding a power supply mode; The flowchart which showed the emergency electric discharge flow. FIG. 6 shows a continuation of FIG. 5; 4 is a flowchart showing a priority discharge flow; FIG. 4 is a block diagram showing an example of a power supply mode when a demand value excess suppression function is executed; FIG. 2 is a block diagram showing another configuration of the power supply system according to one embodiment of the present invention;

Below, the electric power supply system 1 which concerns on one Embodiment of this invention is demonstrated.

A power supply system 1 shown in FIG. 1 supplies a load H with power from a system power source S or power generated using sunlight. A power supply system 1 according to the present embodiment is installed in an office T. As shown in FIG. An office T is provided with electrical equipment (load group H) that consumes power. In this embodiment, the office T is assumed to have three load groups HA, HB, and HC. A load group H is connected to a system power source S.

In the office T, the power purchased from the system power supply S can be used for the power consumed by the load group H. When electric power is purchased from the system power source S, electricity charges are collected from the electric power company for the purchased electric power. In the present embodiment, it is assumed that a demand rate system is adopted as the content of the contract for the electricity rate of the office.

Here, as described above, the demand rate system is based on the larger value of the maximum demand value (maximum demand power) for the month and the maximum demand power for the past 11 months. It is a system to decide. The demand value refers to the average power consumption within a time period (demand time limit) of 30 minutes, and the maximum value of this demand value is called the maximum demand value.

The power supply system 1 according to the present embodiment is designed to reduce the maximum demand value, thereby suppressing the electricity charge under the demand charge system. The power supply system 1 includes a distribution line 10 , a smart meter 20 , a power storage system 30 and a controller 40 .

The distribution line 10 connects the system power supply S and the three load groups H. As shown in FIG. Specifically, one end side of the distribution line 10 is connected to the system power supply S. As shown in FIG. The other end of the distribution line 10 is branched into three, and each branched end is connected to the load group H. As shown in FIG. In addition, below, the said one end side (system power supply S side) in the distribution line 10 may be called "upstream side", and the said other end side (load group H side) may be called "downstream side."

The smart meter 20 is capable of measuring power. The smart meter 20 is installed in the middle of the distribution line 10 (near the grid power source S). The smart meter 20 is connected to a control unit 40 to be described later, and can transmit measurement results to the control unit 40 .

The power storage system 30 can generate power using sunlight and can charge and discharge power. The power storage system 30 includes a solar power generation unit 31 , a storage battery 32 , a power measurement unit 33 and a power conditioner 34 .

The solar power generation unit 31 is a device that generates power using sunlight. The solar power generation unit 31 is configured by a solar cell panel or the like. The photovoltaic power generation unit 31 is installed in a sunny place such as the roof of the office T. The solar power generation unit 31 is connected to a power conditioner 34 which will be described later.

The storage battery 32 is capable of charging and discharging electric power. The storage battery 32 is configured by, for example, a lithium ion battery. The storage battery 32 is connected to a power conditioner 34, which will be described later. The storage battery 32 has a discharge mode, a charge mode, a standby mode, and a charge/discharge mode as operation modes. A detailed description of these modes will be given later.

In this embodiment, it is assumed that the maximum discharge power of the storage battery 32 is 2 [kW]. It is also assumed that the maximum charging power of the storage battery 32 is 2 [kW].

In addition, a predetermined remaining amount (hereinafter referred to as "lower limit of remaining amount") is set in the storage battery 32 as a remaining amount of charge for securing power in an emergency such as a power failure. That is, the lower limit value of the remaining amount of the storage battery 32 indicates the minimum remaining amount of charge that is always ensured in normal times. It should be noted that the set remaining amount lower limit value can be automatically changed when the later-described demand value excess suppression function is executed. In this embodiment, it is assumed that the initial value of the lower limit of the remaining amount of the storage battery 32 (the value before change in the emergency discharge flow described later) is set to 50% of the storage capacity (maximum capacity). It is also assumed that the lower limit of remaining capacity can be lowered in units of 10%.

In addition, a predetermined remaining amount (hereinafter referred to as “minimum remaining amount”) is set in the storage battery 32 as a remaining amount of charge for maintaining the operating state of the storage battery 32 . When the remaining charge amount of the storage battery 32 reaches the minimum remaining amount, the charging mode is executed to maintain (protect) the operating state, and charging is performed forcibly. The minimum remaining amount cannot be changed unlike the remaining amount lower limit value. In this embodiment, the minimum remaining amount is set to 5% of the power storage capacity (maximum capacity).

The power measurement unit 33 is capable of measuring power. The power measurement unit 33 is installed on the distribution line 10 immediately upstream of a connecting portion between the power conditioner 34 and the distribution line 10, which will be described later. More specifically, the power measurement unit 33 is configured to prevent other electric wires or electric devices from being connected between the connection portion (between the power conditioner 34 and the distribution line 10 ) and the power measurement unit 33 in the distribution line 10 . is installed in The power measurement unit 33 is connected to the power conditioner 34 and can transmit the measurement result to the power conditioner 34 .

The power conditioner 34 is a hybrid power conditioner capable of appropriately converting electric power. The power conditioner 34 is connected to the solar power generation section 31 and the storage battery 32 as described above. In addition, the power conditioner 34 is connected to the middle portion of the distribution line 10 . Thus, the power conditioner 34 is provided between the photovoltaic power generation section 31 , the storage battery 32 and the distribution line 10 .

Thereby, the power generated by the photovoltaic power generation unit 31 can be output to the distribution line 10 via the power conditioner 34 . Also, the power generated by the photovoltaic power generation unit 31 can be charged to the storage battery 32 via the power conditioner 34 . Also, the discharged power of the storage battery 32 can be output to the distribution line 10 via the power conditioner 34 . Further, the power flowing through the distribution line 10 (power from the system power supply S) can be charged to the storage battery 32 via the power conditioner 34 .

Also, the power conditioner 34 is connected to the power measuring unit 33 as described above. The inverter 34 can acquire information about the magnitude and direction (upstream or downstream) of the power flowing through the installation location of the power measuring unit 33 . The power conditioner 34 can control charging and discharging of the storage battery 32 based on the information acquired from the power measurement unit 33 .

Thus, the power storage system 30 can output the power generated by the solar power generation unit 31 and the discharged power of the storage battery 32 to the distribution line 10 via the power conditioner 34 . In addition, the power storage system 30 can charge the storage battery 32 with power generated by the photovoltaic power generation unit 31 and power from the system power supply S via the power conditioner 34 .

In this embodiment, three power storage systems 30 are provided. The three power storage systems 30 (more specifically, the power conditioners 34 of the power storage systems 30) are connected to the distribution line 10, respectively. Specifically, the three power storage systems 30 are connected one by one (in series) in the electric power flow direction between the smart meter 20 and the load group H on the distribution line 10 .

The control unit 40 controls the mode of power supply in the power supply system 1 by controlling the mode of operation of the power storage system 30 . The control unit 40 is connected to the power conditioners 34 of the three power storage systems 30 .

The control unit 40 can control the storage battery 32 via the power conditioner 34 . Specifically, the control unit 40 can switch the operation mode of the storage battery 32 . Also, the control unit 40 can change the lower limit of the remaining amount of the storage battery 32 .

Also, the control unit 40 can acquire information about the power storage system 30 via the power conditioner 34 . Specifically, the control unit 40 can acquire information about the remaining charge of the storage battery 32 . In addition, the control unit 40 can acquire information about the operating mode in which the storage battery 32 is being executed.

Also, the control unit 40 is connected to the smart meter 20 . The control unit 40 can acquire information about measurement results from the smart meter 20 . Specifically, the control unit 40 can acquire information about power received from the system power supply S to the distribution line 10 .

Also, the control unit 40 can perform various functions. These various functions include a demand value excess suppression function. A detailed description of the demand value excess suppression function will be given later.

In addition, the control unit 40 can execute a flow related to the mode of power supply. As will be described later, the flow relating to the power supply mode includes a plurality of sequentially executed flows (an emergency discharge flow, a priority charge flow and a normal flow, which will be described later). In the emergency discharge flow, the priority charge flow, and the normal flow, an appropriate operation mode of the storage battery 32 as described above is executed.

The operation modes (discharge mode, charge mode, standby mode, and charge/discharge mode) of the storage battery 32 will be described below.

In this embodiment, as described above, three power storage systems 30 (that is, three storage batteries 32) are provided, but the content of the operation mode of each storage battery 32 is the same.

The discharge mode is a mode in which the storage battery 32 is discharged by load following operation. When the discharge mode is executed, the storage battery 32 enters a dischargeable state according to the measurement result of the power measurement unit 33 . Specifically, when the power measurement unit 33 measures the power flowing downstream, the storage battery 32 discharges the power corresponding to the measured power, and enters a discharged state.

Note that when the power measurement unit 33 measures the power flowing downstream (when the photovoltaic power generation unit 31 is generating power), the power generated by the photovoltaic power generation unit 31 is output to the distribution line 10. However, it is assumed that the total load group H is insufficient.

Further, when the discharge mode is executed, even if the power measurement unit 33 measures the power flowing downstream, if the remaining charge of the storage battery 32 is not a dischargeable remaining amount (for example, the remaining charge is When the remaining amount is the lower limit value or the minimum remaining amount), the storage battery 32 cannot be discharged, and is switched to a standby mode, which will be described later.

The charging mode is a mode for charging the storage battery 32 . When the charging mode is executed, the storage battery 32 charges the power generated by the photovoltaic power generation unit 31 prior to the power from the system power supply S. The storage battery 32 also charges power from the system power supply S when the power generated by the solar power generation unit 31 is smaller than the maximum charging power of the storage battery 32 or when the solar power generation unit 31 is not generating power. Note that when part of the power generated by the photovoltaic power generation unit 31 is charged in the storage battery 32 , the rest of the generated power is output to the distribution line 10 .

Also, even when the charge mode is executed, the storage battery 32 cannot be charged when it is fully charged, and is switched to a standby mode, which will be described later. In this case, all of the power generated by the photovoltaic power generation unit 31 is output to the distribution line 10 .

A standby mode is a mode which makes the storage battery 32 stand by. When the standby mode is executed, the storage battery 32 is not charged/discharged while being in an operating state.

The charge/discharge mode is a mode in which the storage battery 32 is charged/discharged by load following operation. When the charge/discharge mode is executed, the storage battery 32 becomes chargeable/dischargeable according to the measurement result of the power measurement unit 33 .

Specifically, similarly to the discharge mode, when the power measurement unit 33 measures the power flowing downstream, the storage battery 32 discharges the power corresponding to the measured power and enters the discharge state.

Note that when the power measurement unit 33 measures the power flowing downstream (when the photovoltaic power generation unit 31 is generating power), the power generated by the photovoltaic power generation unit 31 is output to the distribution line 10. However, it is assumed that the total load group H is insufficient.

Further, when the charge/discharge mode is executed, even if the power measurement unit 33 measures the power flowing downstream, if the remaining charge of the storage battery 32 is not a dischargeable remaining amount (for example, the remaining charge is the lower limit of the remaining amount or the lowest remaining amount), the storage battery 32 cannot be discharged and is switched to the standby mode.

When the charge/discharge mode is executed, the storage battery 32 is charged with power corresponding to the measured power when the power measurement unit 33 measures the power flowing upstream, and enters the charging state. Here, when the power measuring unit 33 measures the power flowing upstream, it is assumed that the power generated by the photovoltaic power generation unit 31 is output to the distribution line 10 and is surplus to the load group H. be. That is, when the power generated by the photovoltaic power generation unit 31 is surplus with respect to the load group H, the storage battery 32 is charged by the surplus amount of the generated power.

Further, when the charge/discharge mode is executed, even if the power generated by the photovoltaic power generation unit 31 is surplus to the load group H, the storage battery 32 can be charged when it is fully charged. Can not. In this case, the storage battery 32 enters a standby state in which charging/discharging is not performed while maintaining the charging/discharging mode. Further, in this case, all the power generated by the photovoltaic power generation unit 31 is output to the distribution line 10 .

Further, when the charge/discharge mode is executed, if the power measurement unit 33 does not measure the power flowing upstream and downstream, the storage battery 32 maintains the charge/discharge mode and does not perform charging/discharging. state. Note that when the power measurement unit 33 does not measure the power flowing upstream and downstream, for example, the power generated by the photovoltaic power generation unit 31 is output to the distribution line 10, and the surplus and shortage of the load group H If not (balanced state) is assumed.

In this way, in the discharge mode or the charge/discharge mode, the power output from the power storage system 30 to the distribution line 10 (specifically, the power generated by the solar power generation unit 31 and the discharged power of the storage battery 32) is transferred to the load group H. If there is no surplus, it is supplied to the load group H in question.

Note that in the discharge mode or the charge/discharge mode, the power output from the power storage system 30 to the distribution line 10 (specifically, the power generated by the solar power generation unit 31) is surplus with respect to the load group H. , reverse power flow to the system power source S.

In addition, the processing related to switching of the operation mode of the storage battery 32 is defined in the flow related to the power supply mode executed by the control unit 40 . Note that the flow regarding the power supply mode will be described later.

An example of a power supply mode when the charge/discharge mode is executed will be described below with reference to FIGS. 2 and 3. FIG.

The block diagrams of FIGS. 2 and 3 show an example of how power is supplied when the charge/discharge mode is executed. It is assumed that the total of (the power consumption of) the load group H is 50 [kW]. In addition, in the explanation using the block diagrams from FIG. 2 onward, for convenience of explanation, it is assumed that the photovoltaic power generation unit 31 is not generating power. Also, in FIG. 3, illustration of the control unit 40 and the like is omitted for the sake of convenience.

In the block diagrams below, the memory (four rectangular frames) described inside the storage battery 32 is an image of the remaining charge of the storage battery 32 . Specifically, the number of colored frames among the four rectangular frames indicates a rough ratio of the remaining charge to the maximum capacity. Also, a black frame indicates that the remaining charge amount is a remaining amount that can be discharged. Also, a light black frame indicates that the remaining charge amount is a remaining amount that cannot be discharged (when the remaining charge amount is the lower limit of the remaining amount). That is, in FIG. 2, all the storage batteries 32 have a remaining amount of charge that can be discharged.

As shown in FIG. 2, when the total of the load group H is 50 [kW], even if the maximum discharge power (2 [kW]) is discharged from the three storage batteries 32, the load group H short of the total. Therefore, the electric power (44 [kW]) short of the discharged electric power of the three storage batteries 32 is received from the system power supply S to the distribution line 10 . In this way, the discharged power of the three storage batteries 32 and the power from the system power supply S are supplied to the load group H.

Here, in the demand charge system, the electricity charge is determined based on the maximum demand value. Therefore, it is necessary to suppress the maximum demand value in order to suppress the power rate. Therefore, in the present embodiment, the target upper limit of the demand value (hereinafter referred to as "demand upper limit") is set to 45 [kW]. In the example shown in FIG. 2, the power (44 [kW]) from the system power source S is smaller than the demand upper limit value (45 [kW]).

However, if, for example, the storage battery 32 continues to discharge and the remaining charge of the storage battery 32 decreases and reaches the lower limit of the remaining capacity, the storage battery 32 cannot be discharged. In this case, the power received by the distribution line 10 from the system power source S increases.

FIG. 3 shows an example of a power supply mode when the remaining charge levels of all the storage batteries 32 decrease from the state shown in FIG. 2 and reach the lower limit of remaining capacity.

In this case, as shown in FIG. 3, since the three storage batteries 32 cannot be discharged, the power received from the system power source S to the distribution line 10 is reduced from 44 [kW] shown in FIG. 2 to 50 [kW]. and increase. In this way, if the state in which the power received by the distribution line 10 continues to increase, the demand value exceeds the upper limit of the demand (45 [kW]), and the electricity rate in the demand rate system becomes relatively high. There is a problem of storage.

On the other hand, the power supply system 1 according to the present embodiment has a function (demand value suppression function) for suppressing the maximum demand value. The demand value suppression function is executed by the processing (emergency discharge flow) of the control unit 40 .

Below, the flow regarding the power supply mode will be described with reference to the flowchart of FIG. 4 .

The flow relating to the power supply mode is repeatedly executed by the control unit 40 at predetermined timings. Note that the flow relating to the power supply mode is executed every minute during each demand time period (30 minutes).

In step S101, the control unit 40 calculates an expected demand value. Here, the "expected demand value" is a predicted value of the power consumption (integrated value of power consumption) in the demand time period (hereinafter referred to as "the demand time period") to which the current time (at the time of the processing in step S101) belongs. The expected demand value is calculated using Equation 1 below.
Expected demand value = (accumulated value of demand time period + maximum value of 1-minute accumulated value in the last n minutes × remaining time) × 2 (Equation 1)

Here, the "integrated value of the demand time period" is the integrated value of the power from the system power supply S that has already been used by the load group H from the start of the demand time period to the present time (the power consumption from the system power supply S). is. That is, the "integrated value of the demand time period" is the actual value of the power consumption up to the present time in the demand time period.

Further, in this specification, the “m-minute integrated value” means an integrated value (used electric power amount) of the power consumption from the system power supply S for m minutes. That is, the “maximum one-minute integrated value in the most recent n minutes” is the largest value among the integrated values of power consumption for one minute in the most recent n minutes (for example, three minutes). Also, the "remaining time" is the time from the current time to the end of the demand time period. That is, "maximum integrated value for 1 minute in the last n minutes x remaining time" means the (maximum) integrated value of electric power predicted to be used from the current time until the end of the demand time period. . It should be noted that the "last n minutes" is not limited to within the demand time period, and may extend over the demand time period before the demand time period. Also, the reason for multiplying by "2" is to convert the 30-minute integrated value into a demand value.

After performing the process of step S101, the control unit 40 proceeds to step S102.

In step S102, control unit 40 executes an emergency discharge flow. The emergency discharge flow is a flow for executing the demand value excess suppression function. A detailed description of the emergency discharge flow will be given later. After performing the process of step S102, the control unit 40 proceeds to step S103.

In step S103, the control unit 40 determines whether or not emergency discharge is being performed. In this process, the control unit 40 makes this judgment based on whether or not the emergency flag is ON. The emergency flag is a flag that indicates that the lower limit of the remaining amount of the storage battery 32 has been lowered from the initial value. When the control unit 40 determines that the emergency discharge is not being performed (the emergency flag is OFF) ("NO" in step S103), the process proceeds to step S104. On the other hand, when the control unit 40 determines that the emergency discharge is being performed (the emergency flag is ON) (“YES” in step S103), the control unit 40 temporarily ends the flow regarding the power supply mode.

In step S104, the control unit 40 determines whether or not there is a storage battery 32 whose remaining charge level is less than the set value. This setting value can be any value, for example, the initial value (50%) of the lower limit of remaining capacity.

When the control unit 40 determines that there is a storage battery 32 whose remaining charge level is less than the set value ("YES" in step S104), the process proceeds to step S105. On the other hand, when the control unit 40 determines that there is no storage battery 32 whose remaining charge level is less than the set value ("NO" in step S104), the process proceeds to step S106.

In step S105, the control unit 40 executes the priority charging flow. The priority charging flow is a flow for preferentially charging the storage battery 32 whose remaining charge level is less than a set value. A detailed description of the priority charging flow will be given later. After performing the process of step S105, the control unit 40 temporarily terminates the flow regarding the power supply mode.

In step S106, the control unit 40 executes the normal control flow. In the normal control flow, the control unit 40 executes the charge/discharge mode as the operation mode of the three storage batteries 32 . That is, when the normal control flow is executed, the three storage batteries 32 are in a chargeable/dischargeable state according to the measurement result of the power measurement unit 33 (see FIG. 2). After performing the process of step S106, the control unit 40 once terminates the flow regarding the power supply mode.

The emergency discharge flow will be described in detail below with reference to the flow charts of FIGS. 5 and 6. FIG.

In the emergency discharge flow, when the demand value is likely to exceed the upper limit of the demand and the remaining amount of charge reaches the lower limit of the remaining amount and there is a storage battery 32 that cannot be discharged, the lower limit of the remaining amount is changed. By (pulling down), the storage battery 32 can be discharged again.

In the emergency discharge flow, as described above, the process for lowering the lower limit of the remaining amount of the storage battery 32 and discharging from the storage battery 32 (steps S201 to S211), and raising the lowered lower limit of the remaining amount of the storage battery 32 (to the original and a process for stopping discharge from the storage battery 32 (steps S301 to S312). A detailed description is given below.

First, the processing (steps S201 to S211) for lowering the lower limit of the remaining amount of the storage battery 32 and discharging the storage battery 32 will be described.

In step S201, the control unit 40 determines whether or not the expected demand value is equal to or greater than the emergency discharge instruction condition×safety factor. The value calculated in step S101 of FIG. 4 is used as the expected demand value. The "emergency discharge instruction condition" is a reference for determining whether steps S209 and S210 (emergency discharge) to be described later are performed, and is set to the demand upper limit value (45 [kW]). In addition, the emergency discharge instruction condition is multiplied by a safety factor in order to provide a margin against excess of the demand value. The safety factor is set to 0.8, for example.

When the control unit 40 determines that the expected demand value is equal to or greater than the emergency discharge instruction condition×safety factor ("YES" in step S201), the control unit 40 proceeds to step S202. On the other hand, when the control unit 40 determines that the expected demand value is smaller than the emergency discharge instruction condition×safety factor ("NO" in step S201), the process proceeds to step S301 shown in FIG.

In step S202, the control unit 40 sets the emergency flag to ON. Also, the control unit 40 sets the normal flag to OFF. Thus, when the emergency flag is ON, the normal flag is OFF. Note that the normal flag is a flag indicating whether or not to execute the normal control flow. That is, when the lower limit of the remaining amount of the storage battery 32 is lowered from the initial value, the normal control flow of step S104 is not executed (see FIG. 4). After performing the process of step S202, the control unit 40 proceeds to step S203.

In step S203, the control unit 40 calculates the emergency discharge permission number. Note that the number of emergency discharge permitted batteries means the number of storage batteries 32 that need to start discharging in order to prevent the demand value from exceeding the upper limit value of demand. In other words, the number of emergency discharge-permitted number means the number of storage batteries 32 whose remaining charge lower limit needs to be changed (reduced) when there are storage batteries 32 that cannot be discharged because the remaining charge reaches the remaining charge lower limit. . The emergency discharge permission number is calculated using Equation 2 below. As the emergency discharge permission number, a value obtained by rounding up the decimal point of the value calculated using Equation 2 below is adopted.
Emergency discharge permitted number = [{(expected demand value - emergency discharge instruction condition x safety factor) / 2} / (remaining time - control lag)] / (discharge performance / 60) (Equation 2)

Here, "expected demand value - emergency discharge instruction condition x safety factor" means how much the expected demand value exceeds the emergency discharge instruction condition x safety factor, which is divided by 2. Thus, the 1-hour integrated value is converted into the 30-minute integrated value. In addition, the “control lag” means a time lag from an instruction by the control unit 40 to the actual operation of the storage battery 32 . In addition, "discharge performance" means the maximum discharge power of the storage battery 32 (2 [kW] in this embodiment), and by dividing this by 60, the instantaneous value is converted into a one-minute integrated value. there is The emergency discharge-permitted number is updated (decremented by one) by the process of step S209 described later, and the emergency discharge-permitted number calculated in step S203 is treated as the initial value of the emergency discharge-permitted number. .

After performing the process of step S203, the control unit 40 proceeds to step S204.

In step S204, the control unit 40 calculates the emergency discharge instruction order. Note that the emergency discharge instruction order means a criterion for determining which of the three storage batteries 32 should be preferentially lowered when the lower limit of the remaining amount of the storage battery 32 needs to be lowered. The emergency discharge command order is set so that the remaining charge levels of the three storage batteries 32 are compared, and the order increases in order from the storage battery 32 with the highest remaining charge level.

Specifically, it is calculated that the storage battery 32 with the largest remaining amount of charge among the three storage batteries 32 has the first emergency discharge instruction order. In addition, it is calculated that the storage battery 32 with the second largest remaining amount of charge among the three storage batteries 32 has the second highest emergency discharge instruction order. In addition, it is calculated that the storage battery 32 with the third largest remaining amount of charge among the three storage batteries 32 is ranked third in the emergency discharge instruction order.

After performing the process of step S204, the control unit 40 proceeds to step S205. It should be noted that, when the process proceeds from step S204 to step S205, the control unit 40 discharges the number of storage batteries 32 (three times in the present embodiment) according to the emergency discharge instruction order calculated (set) in the process of step S204. The processing from step S205 to step S211 is repeated. That is, the control unit 40 sequentially focuses on the storage battery 32 ranked first, the storage battery 32 ranked second, and the storage battery 32 ranked third in the emergency discharge instruction order, and targets the targeted storage battery 32 from step S205 to step S205. The processing up to S211 is repeated.

In step S205, the control unit 40 determines whether or not the emergency discharge permission number is greater than zero. Here, as the emergency discharge permitted number in step S205, in the case of the first step S205 processing after the transition from step S204 to step S205, the emergency discharge permitted number calculated in the processing of step S203. Initial values are used. Further, when the process of step S205 is performed for the second time or later, the updated value of the emergency discharge permission number calculated in the process of step S211, which will be described later, is used.

If the control unit 40 determines that the number of emergency discharge permitted units is greater than 0 ("YES" in step S205), the process proceeds to step S206. On the other hand, when the control unit 40 determines that the emergency discharge permission number is not greater than 0 (that is, it is 0) ("NO" in step S205), the emergency discharge flow is once terminated, and the power supply mode is , the flow moves to step S103.

In step S206, the control unit 40 determines whether the remaining charge of the storage battery 32 (that is, the storage battery 32 that is the target of the processing from steps S205 to S211 among the three storage batteries 32) is greater than the minimum remaining charge. determine whether or not When the control unit 40 determines that the remaining charge amount of the storage battery 32 is larger than the minimum remaining amount ("YES" in step S206), the process proceeds to step S207. On the other hand, if the control unit 40 determines that the remaining charge amount of the storage battery 32 is not greater than the minimum remaining amount (that is, is equal to or less than the minimum remaining amount) ("NO" in step S206), then the storage battery Processing from step S205 to step S211 is performed for the storage battery 32 one rank lower than 32 as a target. Note that if the storage battery 32 is the storage battery 32 with the lowest priority, the control unit 40 once terminates the emergency discharge flow, and proceeds to step S103 of the flow regarding the power supply mode.

In step S207, the control unit 40 determines whether or not the operating state of the storage battery 32 is in a discharging state (that is, discharging). When the control unit 40 determines that the operating state of the storage battery 32 is not the discharging state ("NO" in step S207), the process proceeds to step S208. On the other hand, if the control unit 40 determines that the operation state of the storage battery 32 is in the discharging state ("YES" in step S207), then the storage battery 32 one rank lower than the storage battery 32 is targeted, Processing from step S205 to step S211 is performed. Note that if the storage battery 32 is the storage battery 32 with the lowest priority, the control unit 40 once terminates the emergency discharge flow, and proceeds to step S103 of the flow regarding the power supply mode.

In step S208, the control unit 40 determines whether or not the remaining amount of charge of the storage battery 32 is greater than the lower limit of remaining amount. When the control unit 40 determines that the remaining amount of charge of the storage battery 32 is not greater than the lower limit of remaining amount (that is, equal to or less than the lower limit of remaining amount) ("NO" in step S208), the process proceeds to step S209. On the other hand, when the control unit 40 determines that the remaining charge amount of the storage battery 32 is greater than the remaining amount lower limit value ("YES" in step S208), the process proceeds to step S210.

In step S209, the control unit 40 changes the current remaining amount lower limit value to a new remaining amount lower limit value (remaining amount lower limit value smaller than the current remaining amount lower limit value). Here, if the process is the first step S209 after the transition from step S204 to step S205, the control unit 40 sets the initial value (for example, 50 %) to a new lower limit value (eg, 40%). Then, the control unit 40 instructs the storage battery 32 to discharge. Specifically, the control unit 40 switches the operation mode of the storage battery 32 to the discharge mode.

On the other hand, in step S210, the control unit 40 instructs the storage battery 32 to discharge. Specifically, the control unit 40 switches the operation mode of the storage battery 32 to the discharge mode.

After performing the process of step S209 or step S210, the control unit 40 proceeds to step S211.

In step S211, the control unit 40 calculates an updated value of the number of units permitted for emergency discharge. The updated value of the emergency discharge permitted number is calculated using Equation 3 below.
Updated value of emergency discharge permitted number = current emergency discharge permitted number - 1 (Equation 3)

Here, the "current number of units permitted for emergency discharge" means the number of units permitted for emergency discharge calculated in the process of step S203 in the case of the processing of the first step S211 after the transition from step S204 to step S205. is the initial value of Also, in the case of step S211 for the second time or later, it is the updated value of the emergency discharge permission number calculated in the previous process of step S211.

After performing the processing of step S211, the control unit 40 performs the processing of steps S205 to S211 next targeting the storage battery 32 one rank lower than the storage battery 32 concerned. Note that if the storage battery 32 is the storage battery 32 with the lowest order, the control unit 40 once terminates the contracted capacity excess suppression flow, and proceeds to step S103 of the flow regarding the power supply mode.

In this way, the process (steps S201 to S211) for lowering the lower limit of the remaining amount of the storage battery 32 and discharging the storage battery 32 is executed.

That is, the case where the expected demand value for the relevant demand time period is equal to or greater than the emergency discharge instruction condition x the safety factor ("YES" in step S201) means that the demand value for the relevant demand time period is likely to exceed the upper limit of demand. is.

Therefore, in such a case, by issuing a discharge instruction and switching the operation mode of the storage battery 32 to the discharge mode (step S210), the power received from the system power supply S to the distribution line 10 is reduced, and the demand for the demand time period is reduced. It is possible to suppress the value from exceeding the upper demand limit. However, if the remaining amount of charge in the storage battery 32 is equal to or less than the lower limit of remaining amount, the storage battery 32 cannot be discharged. NO"), change the current lower limit of remaining capacity to a new lower limit of remaining capacity, and issue a discharge instruction (step S209). As a result, the storage battery 32 that cannot be discharged can be discharged.

FIG. 8 shows an example of a power supply mode when the demand value excess suppression function is executed. Specifically, in FIG. 8, before the state shown in FIG. 3 is reached, that is, when the demand value is likely to exceed the upper demand limit (45 [kW]), the remaining lower limit value of all the storage batteries 32 is set to the initial value. An example of a power supply mode is shown when (50%) is reduced to 40%.

As shown in FIG. 8, when the lower limit of the remaining amount is lowered, the three power storage systems 30 can be discharged. can. That is, it is possible to prevent the demand value of the demand time period from exceeding the upper limit of demand (45 [kW]).

In the process of step S203, a value obtained by rounding up the decimal point of the value calculated using Equation 2 above is used as the emergency discharge permitted number. As a result, it is possible to prevent the demand value from exceeding the upper limit value of the demand, thereby preventing a shortage of electric power. In this way, it is possible to effectively suppress an increase in the maximum demand value.

In addition, in the processing of step S204 and the like, the lower limit of the remaining amount is lowered in order from the storage battery 32 with the highest remaining amount of charge. As a result, for example, the lower limit of the remaining amount of the storage battery 32 with a small remaining amount of charge is lowered while the lower limit of the remaining amount of the storage battery 32 with a large amount of remaining amount of charge remains unchanged. It is possible to prevent the remaining amount from running short quickly (the storage battery 32 becoming undischargeable soon). That is, it is possible to prevent the need to immediately lower the lower limit value of the remaining capacity of the other storage battery 32, thereby efficiently suppressing an increase in the maximum demand value.

Also, in the processing of step S206, it is determined whether or not the remaining charge amount of the storage battery 32 is greater than the minimum remaining amount, and the lower limit of remaining amount is lowered for the storage battery 32 whose remaining charge amount is equal to or less than the minimum remaining amount. prevent As a result, although the remaining amount of charge in the storage battery 32 is smaller than the minimum remaining amount, discharging is started, and as a result, charging is performed forcibly (the amount of power received from the system power supply S to the distribution line 10 is further increased). ).

Next, the processing (steps S301 to S313) for increasing (returning to) the lowered lower limit of remaining capacity of the storage battery 32 will be described.

In step S301 after shifting from step S201 ("NO" in step S201) as described above, the control unit 40 determines whether or not the emergency flag is ON. When the control unit 40 determines that the emergency flag is ON ("YES" in step S301), the process proceeds to step S303. On the other hand, when the control unit 40 determines that the emergency flag is not ON (it is OFF) ("NO" in step S301), the process proceeds to step S302.

In step S302, the control unit 40 sets the normal flag to ON. After performing the process of step S302, the control unit 40 once terminates the emergency discharge flow, and proceeds to step S103 of the flow regarding the power supply mode.

In step S303, the control unit 40 calculates the number of emergency discharge canceled units. Note that the number of emergency discharge cancellation means the number of storage batteries 32 whose remaining lower limit is raised (raising is no problem) when there are storage batteries 32 whose remaining lower limit is lowered from the initial value. The number of emergency discharge canceled units is calculated using Equation 4 below. As for the number of emergency discharge canceled units, a value obtained by rounding down the decimal point of the value calculated using Equation 4 below is employed.
Emergency discharge cancellation number = [{(emergency discharge cancellation condition x safety factor - expected demand value) / 2} / (remaining time - control lag)] / (discharge performance / 60) (Equation 4)

Here, the emergency discharge cancellation condition is a power value set smaller than the emergency discharge instruction condition. For example, in the present embodiment, the emergency discharge cancellation condition is set to 35 [kW], which is smaller than the emergency discharge instruction condition (45 [kW]). In addition, "emergency discharge cancellation condition x safety factor - expected demand value" means how much margin the expected demand value has for the emergency discharge cancellation condition x safety factor, and this is divided by 2. , the 1-hour integrated value is converted into a 30-minute integrated value.

After performing the process of step S303, the control unit 40 proceeds to step S304.

In step S304, the control unit 40 calculates the emergency discharge cancellation order. Note that the emergency discharge cancellation order means a criterion for determining which of the three storage batteries 32 should be preferentially raised when the lower limit of the remaining amount of the storage battery 32 is raised. The emergency discharge cancellation order is set so that the remaining charge levels of the three storage batteries 32 are compared, and the order of the storage batteries 32 with the lowest remaining charge levels increases.

Specifically, it is calculated that the storage battery 32 with the least amount of remaining charge among the three storage batteries 32 has the first emergency discharge cancellation order. In addition, it is calculated that the storage battery 32 with the second smallest remaining amount of charge among the three storage batteries 32 has the second priority in the emergency discharge cancellation order. In addition, it is calculated that the storage battery 32 with the third lowest remaining charge among the three storage batteries 32 has the third priority in the emergency discharge cancellation order.

After performing the process of step S304, the control unit 40 proceeds to step S305. It should be noted that, when the control unit 40 proceeds from step S304 to step S305, the control unit 40 discharges only the number of storage batteries 32 (three times in the present embodiment) according to the emergency discharge cancellation order calculated (set) in the process of step S304. The processing from step S305 to step S309 is repeated. That is, the control unit 40 sequentially focuses on the storage battery 32 ranked first, the storage battery 32 ranked second, and the storage battery 32 ranked third in the priority of canceling emergency discharge, and targets the storage battery 32 of interest from step S305 to step S305. The processing up to S309 is repeated.

In step S305, the control unit 40 determines whether or not the operating state of the storage battery 32 is in a discharging state (that is, discharging). When the control unit 40 determines that the operating state of the storage battery 32 is not the discharging state ("NO" in step S305), the process proceeds to step S309. On the other hand, when the control unit 40 determines that the operating state of the storage battery 32 is the discharging state ("YES" in step S305), the process proceeds to step S306.

In step S306, control unit 40 determines whether or not the number of emergency discharge canceled units is greater than zero. Here, if the process of step S308 has not yet been executed after the transition from step S304 to step S305, the emergency discharge canceled number calculated in the process of step S303 is used as the number of emergency discharge canceled in step S306. The initial value of is used. Further, when the process of step S308 has already been executed after the process has shifted from step S304 to step S305, the updated value of the emergency discharge cancellation number calculated in the process of step S308 is used. If the control unit 40 determines that the number of emergency discharge canceled units is greater than 0 ("YES" in step S306), the process proceeds to step S308. On the other hand, when the control unit 40 determines that the number of emergency discharge canceled units is not greater than 0 (that is, is 0) ("NO" in step S306), the process proceeds to step S307.

In step S307, the control unit 40 sets the continuation flag to ON. Note that the continuation flag is a flag that serves as a criterion for determining whether to set the emergency flag to OFF after performing the processing from step S305 to step S309. After performing the processing of step S307, the control unit 40 performs the processing of steps S305 to S309 targeting the storage battery 32 one rank lower than the storage battery 32 concerned. Note that if the storage battery 32 is the storage battery 32 with the lowest rank, the control unit 40 proceeds to step S310.

In step S308, the control unit 40 calculates the update value of the number of emergency discharge cancellations. The updated value of the emergency discharge cancellation number is calculated using Equation 5 below.
Updated value of the number of emergency discharge canceled = Current number of emergency discharge canceled - 1 (Equation 5)

Here, the "current number of vehicles whose emergency discharge has been canceled" refers to the number of vehicles whose emergency discharge has been canceled calculated in the process of step S303 in the case of the processing of the first step S308 after the transition from step S304 to step S305. is the initial value of Further, for the process of step S308 from the second time onwards, it is the updated value of the emergency discharge cancellation number calculated in the previous process of step S308.

After performing the processing of step S308, the control unit 40 proceeds to step S309.

In step S309, the control unit 40 changes the current remaining amount lower limit value to the initial value. Then, the control unit 40 instructs the storage battery 32 to wait. Specifically, the control unit 40 switches the operation mode of the storage battery 32 to the standby mode. After performing the processing of step S309, the control unit 40 then performs the processing of steps S305 to S309 targeting the storage battery 32 one rank lower than the storage battery 32 concerned. Note that if the storage battery 32 is the storage battery 32 with the lowest rank, the control unit 40 proceeds to step S310.

In step S310, control unit 40 determines whether or not the continuation flag is OFF. When the control unit 40 determines that the continuation flag is OFF ("YES" in step S310), the process proceeds to step S312. On the other hand, when the control unit 40 determines that the continuation flag is not OFF (it is ON) ("NO" in step S310), the process proceeds to step S311.

In step S311, the control unit 40 sets the continuation flag to OFF. After performing the process of step S311, the control unit 40 once terminates the emergency discharge flow, and proceeds to step S103 of the flow regarding the power supply mode.

In step S312, control unit 40 sets the emergency flag to OFF. After performing the processing of step S312, the control unit 40 once terminates the emergency discharge flow, and proceeds to step S103 of the flow regarding the power supply mode.

In this way, the process (steps S301 to S312) for raising (returning to the original value) the lowered lower limit of the remaining capacity of the storage battery 32 and stopping discharge from the storage battery 32 is executed.

That is, when there is almost no possibility that the demand value will exceed the upper limit of the demand ("NO" in step S201), discharging is not continued while the lower limit of the remaining amount of the storage battery 32 is lowered from the initial value. , the lower limit of the remaining amount of the storage battery 32 is returned to the initial value to stop discharging ("YES" in step S305, see step S309 and the like). In this way, when there is almost no possibility that the demand value will exceed the upper limit value of the demand, it is possible to suppress unnecessary use of the power of the storage battery 32 that can be used in an emergency such as a power failure.

Before step S303, a step of determining whether or not the expected demand value is smaller than the emergency discharge cancellation condition (which is set smaller than the emergency discharge instruction condition (see step S201)) is provided. If it is smaller than the emergency discharge cancellation condition, the process may proceed to step S303. As a result, it is possible to prevent the lower limit value of the remaining capacity of the storage battery 32 from being frequently lowered and raised alternately.

Further, in the process of step S303, a value obtained by omitting the decimal point from the value calculated using Equation 4 above is used as the number of emergency discharge canceled units. As a result, it is possible to suppress an excess of the demand value due to stopping discharge from the storage battery 32 . In this way, it is possible to effectively suppress an increase in the maximum demand value.

In addition, in the processing of step S304 and the like, the lower limit of the remaining amount is increased in order from the storage battery 32 with the smallest remaining amount of charge. As a result, for example, the lower limit of the remaining charge of the storage battery 32 with a large remaining charge is raised, while the lower limit of the remaining charge of the storage battery 32 with a small remaining charge remains unchanged. It is possible to prevent the remaining charge from running short quickly (storage battery 32 becoming unable to discharge immediately). That is, it is possible to suppress the need to immediately lower the lower limit of the remaining capacity of the other storage battery 32, and consequently to suppress the frequent occurrence of alternate lowering and raising of the lower limit of the remaining capacity of the storage battery 32. can.

The priority charging flow will be described in detail below with reference to the flowchart of FIG.

The priority charging flow means that, after the emergency discharge instruction is canceled, when it is considered that the demand value will not exceed even if the storage battery 32 is charged in preparation for subsequent emergency discharge instructions (and in an emergency), It is used to issue a charging instruction to the storage battery 32 .

In step S401, the control unit 40 determines whether or not the expected demand value is smaller than the emergency discharge cancellation condition. Here, the emergency discharge cancellation condition is, as described above, a power value set smaller than the emergency discharge instruction condition (for example, 45 [kW]), for example, set to 35 [kW].

When the control unit 40 determines that the expected demand value is not smaller than the emergency discharge cancellation condition (that is, is equal to or greater than the emergency discharge cancellation condition) ("YES" in step S401), the process proceeds to step S408. On the other hand, when the control unit 40 determines that the expected demand value is smaller than the emergency discharge cancellation condition ("NO" in step S401), the process proceeds to step S402.

In step S402, the control unit 40 calculates the number of vehicles allowed for priority charging. It should be noted that the number of priority charging allowed means the number of storage batteries 32 that need to start charging in order to secure the remaining charge of the storage batteries 32 . The number of vehicles allowed for priority charging is calculated using Equation 6 below. As the number of vehicles permitted for priority charging, a value obtained by rounding down the decimal point of the value calculated using Equation 6 below is adopted.
Priority charging allowed number = [{(emergency discharge cancellation condition x safety factor - expected demand value) / 2} / (remaining time - control lag)] / (charging performance / 60) (Equation 6)

Here, "emergency discharge cancellation condition x safety factor - expected demand value" means the predicted value of how much margin the expected demand value has with respect to the emergency discharge cancellation condition x safety factor. By dividing by 2, the 1-hour integrated value is converted into a 30-minute integrated value. In addition, "charging performance" means the maximum charging power of the storage battery 32 (2 [kW] in this embodiment), and by dividing this by 60, the instantaneous value is converted into a one-minute integrated value. there is

After performing the process of step S402, the control unit 40 proceeds to step S403.

In step S403, the control unit 40 calculates the priority charging instruction order. Note that the priority charging instruction order means a criterion for determining which of the three storage batteries 32 should be preferentially charged when the storage battery 32 needs to be preferentially charged. The priority charging instruction order is set so that the remaining charge levels of the three storage batteries 32 are compared, and the order of the storage batteries 32 with the lowest remaining charge levels increases.

Specifically, it is calculated that the storage battery 32 with the least remaining charge level among the three storage batteries 32 has the first priority charging instruction order. In addition, it is calculated that the storage battery 32 with the second smallest remaining amount of charge among the three storage batteries 32 has the second priority charging instruction order. In addition, it is calculated that the storage battery 32 with the third lowest remaining amount of charge among the three storage batteries 32 has the third priority charging instruction order.

After performing the process of step S403, the control unit 40 proceeds to step S404. It should be noted that when the control unit 40 proceeds from step S403 to step S404, the control unit 40 charges only the number of storage batteries 32 (three times in this embodiment) according to the priority charging instruction order calculated (set) in the process of step S403. The processing from step S404 to step S409 is repeated. That is, the control unit 40 sequentially focuses on the storage battery 32 with the first, second, and third priority charging instruction orders, and targets the storage battery 32 from step S404 to step S404. The processing up to S409 is repeated.

In step S404, the control unit 40 determines that the remaining charge amount of the storage battery 32 (that is, the storage battery 32 that is the target of the processing from steps S404 to S408 among the three storage batteries 32) is the lower limit of the remaining amount (initial value). When the control unit 40 determines that the remaining charge amount of the storage battery 32 is less than the remaining amount lower limit value ("YES" in step S404), the process proceeds to step S405. On the other hand, when the control unit 40 determines that the remaining amount of charge of the storage battery 32 is not less than the lower limit of remaining amount (that is, is equal to or greater than the lower limit of remaining amount) (“NO” in step S404), the process proceeds to step S408. Transition. In addition, when the remaining charge amount of the storage battery 32 is equal to or higher than the lower limit remaining amount, it is considered that the remaining charge amount of the storage battery 32 ranked lower than that of the storage battery 32 is also equal to or higher than the lower limit remaining amount. For this reason, it is not necessary to perform the processing from step S404 to step S409 again for the storage battery 32 having a lower rank than the storage battery 32 concerned.

In step S405, the control unit 40 determines whether or not the operating state of the storage battery 32 is other than the charging state (that is, discharging or waiting). When the control unit 40 determines that the operating state of the storage battery 32 is other than the charging state ("YES" in step S405), the process proceeds to step S406. On the other hand, if the control unit 40 determines that the operating state of the storage battery 32 is not other than the charged state ("NO" in step S405), then the storage battery 32 one rank lower than the storage battery 32 is targeted. , the processing from step S404 to step S409 is performed. Note that if the storage battery 32 is the storage battery 32 with the lowest priority, the control unit 40 once terminates the priority charging flow, and once terminates the flow regarding the power supply mode.

In step S<b>406 , control unit 40 determines whether or not the number of vehicles allowed for priority charging is greater than zero. If the control unit 40 determines that the number of vehicles permitted for priority charging is greater than 0 ("YES" in step S406), the process proceeds to step S407. On the other hand, when the control unit 40 determines that the number of vehicles permitted for priority charging is not greater than 0 (that is, is 0) ("NO" in step S406), the process proceeds to step S408.

In step S<b>407 , the control unit 40 instructs the storage battery 32 to charge. Specifically, the control unit 40 switches the operation mode of the storage battery 32 to the charge mode. The storage battery 32 is charged until the remaining amount of charge reaches the lower limit of the remaining amount (50% of the maximum capacity). Note that the remaining charge after charging is not limited to this, and can be any value. For example, the battery may be charged to 100% of the maximum capacity.

After performing the process of step S407, the control unit 40 proceeds to step S409.

In step S409, the control unit 40 calculates an updated value of the number of vehicles allowed for priority charging. The updated value of the number of vehicles allowed for priority charging is calculated using Equation 7 below.
Updated value of number of vehicles permitted for priority charging = Current number of vehicles permitted for emergency discharge - 1 (Equation 7)

After performing the processing of step S409, the control unit 40 then performs the processing of steps S404 to S409 targeting the storage battery 32 one rank lower than the storage battery 32 concerned. Note that if the storage battery 32 is the storage battery 32 with the lowest priority, the control unit 40 once terminates the priority charging flow, and once terminates the flow regarding the power supply mode.

On the other hand, in step S408, the control unit 40 instructs the storage battery 32 to stand by. The control unit 40 switches the operation mode of the storage battery 32 to the standby mode.

After performing the process of step S408, the control unit 40 temporarily terminates the priority charging flow and also temporarily terminates the flow regarding the power supply mode.

In this way, when it is considered that the demand value will not exceed the demand value even if the storage battery 32 is charged after the emergency discharge instruction is canceled, the charging instruction for the storage battery 32 is issued. As a result, the remaining charge of the storage battery 32 can be secured in preparation for subsequent emergency discharge instructions and emergencies such as power outages.

As described above, the power supply system 1 according to this embodiment is
A power supply system that supplies power to a load group H connected to a system power supply S,
a storage battery 32 connected between the system power supply S and the load group H and capable of charging and discharging electric power from a predetermined supply source (the system power supply S and the solar power generation unit 31);
a control unit 40 that controls charging and discharging of the storage battery 32;
and
The storage battery 32 is
A lower limit of remaining charge is set to indicate the lower limit of the power that can be discharged in normal times.
The control unit 40 is
During each demand time period, when it is predicted that the demand value (expected demand value) of the demand time period exceeds the first reference value (emergency discharge instruction condition x safety factor) ("YES" in step S201 of Fig. 5), the An emergency discharge instruction is issued to enable discharge from the storage battery 32 (steps S209 and S210 in FIG. 5),
If there is a storage battery 32 with a remaining charge level equal to or less than the lower limit of remaining capacity ("NO" in step S208 of FIG. 5), the lower limit of remaining capacity of the storage battery 32 can be lowered before issuing the emergency discharge instruction. There is (step S209 in FIG. 5).

With such a configuration, it is possible to reduce power charges by lowering the maximum demand value.
Specifically, during each demand time period, that is, in real time (every one minute), the demand value of the demand time period is predicted, and when this predicted value (expected demand value) is likely to exceed the upper limit of demand, the storage battery 32, the maximum demand value can be suppressed with high accuracy.
However, even if a discharge instruction is issued to the storage battery 32, the storage battery 32 cannot be discharged if the remaining amount of charge in the storage battery 32 is equal to or less than the remaining amount lower limit value. Therefore, when the remaining charge amount of the storage battery 32 is equal to or less than the remaining amount lower limit value, the current remaining amount lower limit value is changed to a new remaining amount lower limit value, and then a discharge instruction is issued. As a result, the non-dischargeable storage battery 32 can be made dischargeable.
In addition, since the demand value for the demand time period is predicted without using external information such as weather information and past power data, running costs for maintaining and purchasing these data can be suppressed.

Further, in the power supply system 1,
The control unit 40 is
It is possible to acquire the amount of power used from the system power supply S,
Whether the demand value for the demand time period exceeds the first reference value based on the actual value of the power consumption up to the present time in the demand time period and the predicted value of the power consumption for the remaining time of the demand time period (step S201 in FIG. 5).

With such a configuration, the demand value can be predicted with high accuracy.

Further, in the power supply system 1,
The control unit 40 is
A predicted value of the power consumption for the remaining time is calculated based on the power consumption for the most recent predetermined period (for example, 3 minutes).

With such a configuration, the demand value can be predicted with higher accuracy.

Further, in the power supply system 1,
A plurality of the storage batteries 32 are provided,
The control unit 40 is
Among the plurality of storage batteries 32, the emergency discharge instruction is given in order from the storage battery 32 with the highest remaining charge (step S204 in FIG. 3).

With such a configuration, the maximum demand value can be efficiently lowered.
Specifically, for example, as a result of discharging the storage battery 32 having a smaller remaining charge than others, it is possible to prevent the storage battery 32 from immediately running out of the remaining charge that can be discharged (immediate discharge failure of the storage battery 32). be able to.

Further, in the power supply system 1,
The control unit 40 is
When it is predicted that the demand value of the demand time period does not exceed the first reference value or a second reference value smaller than the first reference value (emergency discharge cancellation condition x safety factor) after the emergency discharge instruction is issued. , the emergency discharge instruction can be canceled (step S309 in FIG. 6).

With such a configuration, it is possible to suppress unnecessary use of electric power for emergencies such as power outages.

Further, in the power supply system 1,
The control unit 40 is
When the emergency discharge instruction is canceled, the lowered lower limit of remaining capacity (for example, 40% of the maximum capacity) can be raised to the original lower limit of remaining capacity (for example, 50% of the maximum capacity) (see FIG. 6). Step S309).

With such a configuration, it is possible to further suppress the useless use of power for emergencies such as power outages.

Further, in the power supply system 1,
The control unit 40 is
After canceling the emergency discharge instruction, if there is a storage battery 32 with a remaining amount of charge less than the increased lower limit value of remaining amount (YES in step S404 in FIG. 7), a priority charging instruction is issued to allow the storage battery 32 to be charged. (Step S407 in FIG. 7).

With such a configuration, power can be stored in the storage battery 32 for emergencies such as power outages.

Further, in the power supply system 1,
A plurality of the storage batteries 32 are provided,
The control unit 40 is
When there are a plurality of storage batteries 32 whose remaining charge levels have been increased and are less than the lower limit value of remaining charge levels, the priority charging instruction is given in order from the storage battery 32 with the lowest remaining charge level among the plurality of storage batteries 32 .

With such a configuration, the storage battery 32 can be efficiently charged.
Specifically, for example, as a result of charging the storage battery 32 having a larger remaining charge amount than others, it is possible to suppress unevenness in the remaining charge amount.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above configurations, and various modifications are possible within the scope of the invention described in the claims.

For example, in the present embodiment, the power supply system 1 is installed in the office T, but it may be installed in any place or building such as a factory, an apartment, a house, a hospital, or the like.

Moreover, in the present embodiment, three power storage systems 30 are provided, but the present invention is not limited to this. For example, the number may be two or one. Also, in the present embodiment, the power storage system 30 is arranged in series with the distribution line 10, but may be arranged in parallel as shown in FIG.

Moreover, although the power storage system 30 is configured to have the solar power generation unit 31 , the solar power generation unit 31 may not be included. In addition to (or instead of) the photovoltaic power generation unit 31, other power supply sources (for example, fuel cells, hydroelectric power generation units that generate power using natural energy other than sunlight, wind power generation units, etc.) may have.

In addition, in the present embodiment, the control unit 40 is configured to be provided outside the power storage system 30, but may be configured to be provided inside the power storage system 30, such as being incorporated inside the storage battery 32, and the configuration is limited. not to be

Also, in the present embodiment, the emergency discharge instruction condition is set to 45 [kW], but the present invention is not limited to this. Further, in the present embodiment, the emergency discharge cancellation condition is set to 35 [kW], but it is not limited to this. However, the emergency discharge cancellation condition needs to be set smaller than the emergency discharge instruction condition.

Also, in the present embodiment, the lower limit of the remaining amount of the storage battery 32 can be lowered in units of 10% of the storage capacity (maximum capacity), but the amount of reduction can be any value. Further, when raising the lower limit of the remaining amount of the storage battery 32, the lower limit of the remaining amount can be raised step by step (rather than immediately returning to the initial value).

Also, in the present embodiment, the minimum remaining amount is set to 5% of the power storage capacity (maximum capacity), but the present invention is not limited to this. However, the minimum remaining amount must be set smaller than the initial value of the lower limit of remaining amount.

1 power supply system 31 photovoltaic power generation unit 32 storage battery 40 control unit S system power supply H load group

Claims (8)

A power supply system that supplies power to a load connected to a grid power supply,
a storage battery connected between the system power supply and the load and capable of charging and discharging power from a predetermined supply source;
a control unit that controls charging and discharging of the storage battery;
and
The storage battery
A lower limit of remaining charge is set to indicate the lower limit of the power that can be discharged in normal times.
The control unit
During each demand time period, when it is predicted that the demand value of the demand time period will exceed the first reference value, perform an emergency discharge instruction to enable discharge from the storage battery,
When there is a storage battery with a remaining charge amount equal to or less than the lower limit of remaining amount, the lower limit of remaining amount of the storage battery can be lowered before issuing the emergency discharge instruction.
power supply system. The control unit
It is possible to acquire the amount of power used from the system power supply,
Whether the demand value for the demand time period exceeds the first reference value based on the actual value of the power consumption up to the present time in the demand time period and the predicted value of the power consumption for the remaining time of the demand time period to determine whether
The power supply system according to claim 1. The control unit
calculating a predicted value of the power usage for the remaining time based on the power usage for the most recent predetermined period;
3. The power supply system of claim 2. A plurality of the storage batteries are provided,
The control unit
performing the emergency discharge instruction in order from a storage battery with a large remaining amount of charge among the plurality of storage batteries;
The power supply system according to any one of claims 1 to 3. The control unit
After issuing the emergency discharge instruction, when it is predicted that the demand value of the demand time period does not exceed the first reference value or a second reference value smaller than the first reference value, the emergency discharge instruction can be canceled. be,
The power supply system according to any one of claims 1 to 4. The control unit
When the emergency discharge instruction is canceled, the lowered lower limit of remaining amount can be raised to the original lower limit of remaining amount.
The power supply system according to claim 5. The control unit
After canceling the emergency discharge instruction, if there is a storage battery with a remaining charge amount that is less than the raised lower limit value of remaining amount, give a priority charging instruction that the storage battery can be charged.
The power supply system according to claim 6. A plurality of the storage batteries are provided,
The control unit
If there are a plurality of storage batteries whose remaining charge levels have been raised and are less than the lower limit value of remaining charge levels, the priority charging instruction is given in order from the storage battery with the lowest remaining charge level among the plurality of storage batteries;
The power supply system according to claim 7.

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