JP2020137306A - Power management device, power management method, and program - Google Patents

Abstract

To make it possible, in the case of power being transferred between a plurality of users, to appropriately determine a breakdown on the transferred power.SOLUTION: A power management device for performing power management for a power management area in which, between supply user facilities making surplus power, which is surplus in the facilities, flow reversely and receiving user facilities making demand power flow forward, the surplus power of the supply user facilities is transferred to the receiving user facilities, is configured to comprise an effectively transferred power determination unit that for each supply user facility, determines effectively transferred power, which is power used as demand power for receiving user facilities of surplus power made to flow reversely.SELECTED DRAWING: Figure 14

Description

The present invention relates to power management devices, power management methods and programs.

When the surplus electric energy of one electric power consumer is transferred to another electric power consumer, one electric power consumer is made to grasp the surplus electric energy and the required electric energy of another electric power consumer. A power management device is known (see, for example, Patent Document 1). As a result, it is possible to prevent the ratio of the amount of electric power interchanged between electric power consumers and the amount of commercial AC electric power used by each electric power consumer from becoming unclear.

Japanese Unexamined Patent Publication No. 2011-101532

In the case of sharing power among multiple consumers, for example, there is a case where one customer wants to understand how much power has been accommodated by which customer. .. Alternatively, there is a case where it is desired to grasp how much power that a certain consumer has back-fed is accommodated by each of the consumers on the receiving side. In other words, when power is exchanged among a plurality of consumers, it may be desired to determine the breakdown of the exchanged electric power.

The present invention has been made in view of such circumstances, and an object of the present invention is to be able to appropriately determine the breakdown of the interchanged electric power when the electric power is interchanged among a plurality of consumers. And.

One aspect of the present invention for solving the above-mentioned problems is a supply consumer facility between a supply consumer facility that reverse-feeds surplus power in-house and a receiving consumer facility that reverse-flows the demand power. It is a power management device that manages power in response to the power management area where the surplus power of the above is accommodated to the receiving consumer facility, and the receiving demand of the surplus power that has been reverse-flowed for each supply consumer facility. It is a power management device provided with an effective interchange power determination unit that determines the effective interchange power that is assumed to be used as the demand power of a house facility.

In one aspect of the present invention, the surplus power of the supply consumer facility is the receiving consumer facility between the supply consumer facility that reverse-feeds the surplus power that is surplus in-house and the receiving consumer facility that causes the demand power to flow forward. It is a power management method in a power management device that manages power corresponding to a power management area that is flexible to the above, and the demand of the receiving consumer facility among the surplus power that has been reverse-flowed for each supply consumer facility. It is a power management method including an effective interchange power determination step for determining an effective interchange power that is assumed to be used as electric power.

In one aspect of the present invention, the surplus power of the supply consumer facility is the receiving consumer facility between the supply consumer facility that reverse-feeds the surplus power that is surplus in-house and the receiving consumer facility that causes the demand power to flow forward. A computer as a power management device that manages power corresponding to a power management area that is flexible to the power management area is used as the power demand of the receiving consumer facility among the surplus power that has been reverse-flowed for each supply consumer facility. It is a program for functioning as an effective accommodating power determination unit for determining the effective accommodating power to be determined.

According to the present invention, when the electric power is exchanged among a plurality of consumers, the effect that the breakdown of the exchanged electric power can be appropriately determined can be obtained.

It is a figure which shows the configuration example of the electric power management system in 1st Embodiment. It is a figure which shows the structural example of the consumer facility in 1st Embodiment. It is a figure which shows an example of the operation schedule formulation of the storage battery in 1st Embodiment. It is a figure which shows an example of the operation schedule formulation of the storage battery in 1st Embodiment. It is a figure which shows an example of the operation schedule formulation of the storage battery in 1st Embodiment. It is a figure which shows an example of the operation schedule formulation of the storage battery in 1st Embodiment. It is a figure which shows the configuration example of the electric power management apparatus in 1st Embodiment. It is a flowchart which shows the example of the processing procedure executed by the power management apparatus in 1st Embodiment. It is a figure which shows an example of the operation schedule formulation of the storage battery in 2nd Embodiment. It is a figure which shows an example of the operation schedule formulation of the storage battery in 2nd Embodiment. It is a flowchart which shows the example of the processing procedure executed by the power management apparatus in 2nd Embodiment. It is a figure which shows another example of the operation schedule formulation of the storage battery in the modified example of 2nd Embodiment. It is a flowchart which shows the example of the processing procedure executed by the electric power management apparatus in the modification of 2nd Embodiment. It is a figure which shows the determination example of the effective interchange electric energy in 3rd Embodiment. It is a figure which shows the determination example of the effective interchange electric energy in 3rd Embodiment. It is a figure which shows the configuration example of the electric power management apparatus in 3rd Embodiment. It is a flowchart which shows the example of the processing procedure which the power management apparatus in 3rd Embodiment executes in relation to the determination of the effective interchange electric energy. It is a figure which shows the determination example of the effective interchange electric energy in 4th Embodiment. It is a figure which shows the determination example of the effective interchange electric energy in 4th Embodiment. It is a flowchart which shows the example of the processing procedure which the power management apparatus in 4th Embodiment executes in relation to the determination of the effective interchange electric energy.

<First Embodiment>
FIG. 1 is a diagram showing a configuration example of the power management system 1 according to the present embodiment. The electric power management system 1 in the present embodiment collectively manages electric power in consumer facilities such as houses, commercial facilities, and industrial facilities corresponding to a plurality of consumer facilities in a predetermined area range. Such a power management system 1 corresponds to, for example, TEMS (Town Energy Management System) or CEMS (Community Energy Management System).

The electric power management system 1 of the present embodiment performs electric power management for the electric facilities of each consumer facility 100 in a certain range of areas shown as the electric power management area 10 in the figure. The consumer facility 100 corresponds to, for example, a residential facility, a commercial facility, an industrial facility, or the like.
The area corresponding to the power management area 10 of the present embodiment may be formed by one cohesive area range, or may be formed by a plurality of geographically discrete area ranges.

The power management system 1 of the present embodiment is designed so that power can be exchanged (accommodated) between a plurality of consumer facilities 100 via a power line.

The electric power management device 300 executes electric power control for the electric equipment in the consumer facility 100 belonging to the electric power management area 10. For this purpose, the power management device 300 shown in the figure is connected to each of the consumer facilities 100 via the network NW so that they can communicate with each other. As a result, the power management device 300 can control the operation of the electrical equipment provided in the consumer facility 100.
The power management device 300 of the present embodiment controls the operation of the electric equipment provided in the consumer facility 100, for example, based on a power control plan formulated in advance corresponding to a predetermined unit period (for example, one day (24 hours)). be able to.
The electric power control plan includes, for example, a schedule formulated for charging / discharging a storage battery included in the consumer facility 100, and a schedule for turning on / off and operating a predetermined electric facility (load) included in the consumer facility 100.

FIG. 2 shows an example of a configuration of electrical equipment in the consumer facility 100. The consumer facility 100 in the figure includes a power measuring unit 101, a power generation device 103, a storage battery 104, a load 105, and an in-facility power management device 200. The figure shows an example of a consumer facility 100 equipped with both a power generation device and a storage battery.

The power measuring unit 101 measures the forward power flow power and the reverse power flow power. That is, the power measuring unit 101 measures the received power. The received power is, for example, the difference between the forward power flow power and the reverse power flow power.
In the consumer facility 100, the power supplied from the commercial power supply line DL on the side of the general power transmission and distribution business operator to the power coupling point P of the power measuring unit 101, the power generation device 103, and the storage battery 104 is the forward power. On the other hand, the power output from the power generation device 103 and the storage battery 104 and supplied from the coupling point P to the commercial power supply line DL via the power measurement unit 101 is reverse power flow power.
When the direction of the forward power is positive, if the reverse power is smaller than the forward power, the received power is measured as a positive value, and if the reverse power is larger than the forward power, the received power is negative. Measured as the value of.

The power generation device 103 is a facility that receives sunlight to generate power. The power generation device 103 includes a solar cell and a PCS (Power Conditioning System). The power generation device 103 receives sunlight to generate electric power, converts the electric power obtained by the power generation into alternating current by PCS, and outputs the electric power.

The electric power generated by the power generation device 103 can be supplied as a power source for the load 105. Further, the electric power generated by the power generation device 103 can be charged to the storage battery 104. Further, the electric power generated by the power generation device 103 can be reverse-flowed by being output from the coupling point P to the commercial power supply line DL via the electric power measuring unit 101.

The power generation device 103 may be a device that generates electricity by using other renewable energies such as wind power and geothermal energy.

The storage battery 104 is a facility that stores electric power input for charging and discharges and outputs the stored electric power. The storage battery 104 includes, for example, a storage battery and an inverter (power conditioner). The storage battery stores (charges) electric power and outputs (discharges) the stored electric power. The inverter converts the electric power for charging the storage battery from alternating current to direct current, and converts the electric power output from the storage battery by discharging from direct current to alternating current. That is, the inverter performs bidirectional conversion of the electric power input / output by the storage battery 104.

The storage battery 104 can be charged by inputting the electric power of the commercial power supply supplied via the coupling point P. Further, the storage battery 104 can be charged by inputting the electric power generated by the power generation device 103.
Further, the storage battery 104 can supply the stored electric power as a power source for the load 105. Further, the storage battery 104 can reverse power flow by outputting the stored electric power from the coupling point P to the commercial power supply line DL via the electric power measuring unit 101.

The load 105 collectively indicates a predetermined device or equipment that consumes electric power for its own operation in the consumer facility 100. It should be noted that the type and number of devices and equipment as loads provided by each consumer facility 100 may be different.
The load 105 can operate by inputting the commercial power supply supplied from the coupling point P. Further, the load 105 can operate by inputting the electric power generated by the power generation device 103. Further, the load 105 can operate by inputting the electric power output from the storage battery 104.

The in-facility power management device 200 controls the electric equipment (power generation device 103, storage battery 104, load 105, etc.) in the consumer facility 100.
Further, the in-facility power management device 200 can input the information of the received power measured by the power measuring unit 101 and use the input information of the received power for various controls.
In addition, the facility power management device 200 communicates with the power management device 300.

The electric power management device 300 and the electric equipment in the consumer facility 100 may be configured to communicate with each other. However, as in the present embodiment, the in-facility electric power management device 200 in the consumer facility 100 provides the electric equipment. Power management in the power management system 1 can be performed more efficiently if the power management device 300 and the power management device 200 in the facility communicate with each other after being controlled in an integrated manner.

In the power management system 1 having the above configuration, when the power management device 300 formulates a power control plan for a unit period (for example, one day (24 hours)), the storage battery 104 provided in the consumer facility 100 is described as follows. Develop a driving schedule for.

First, for understanding, an example of formulating an operation schedule of the storage battery 104 corresponding to the transfer (accommodation) of electric power between two consumer facilities will be described with reference to FIGS. 3 and 4.
In FIG. 3, the predicted surplus powers GA1-1 and GB1-1 are shown.
The predicted surplus power GA1-1 is specified in the consumer facility A1, which is one of the plurality of consumer facilities 100, in a unit period (here, the case of one day (24 hours) is taken as an example). The demand-responding surplus power predicted for each division period (here, the case of 1 hour is taken as an example) is shown. The demand-responsive surplus power corresponds to one consumer facility 100, and the generated power obtained by the power generation of the power generation device 103 and the power consumed by the load 105 in one consumer facility 100 ( It is derived based on (power demand). Specifically, the demand-responsive surplus power can be obtained as the difference between the demanded power and the generated power in one consumer facility 100.
Further, the predicted surplus power GB1-1 is the demand-corresponding surplus power predicted for each division period in the unit period at the consumer facility B1, which is one of the plurality of consumer facilities 100 other than the consumer facility A1. Is shown.

According to the predicted surplus power GA1-1, it is predicted that the consumer facility A1 will generate 1 kW in the division period T1, 2 kW in the division period T2, 2 kW in the division period T3, and 1 kW in the division period T4. ing.
Further, the maximum storage capacity of the storage battery 104 in the consumer facility A1 is 4 kWh, and the rated power (an example of the allowable maximum power) is 2 kW. The rated power is determined according to the specifications of the inverter included in the storage battery 104, and is the maximum value of the power allowed for charging (and discharging). The maximum storage capacity is the maximum value of the amount of electric power that can be stored in the storage battery 104.
In the present embodiment, the maximum storage capacity may be, for example, the charge capacity specified as the specification of the storage battery 104, or may be obtained in consideration of the deterioration of the storage battery 104 with respect to the charge capacity when the storage battery 104 is new. The charged charging capacity may be used. Further, the maximum storage capacity does not necessarily have to be defined as the capacity that can be charged to the storage battery 104 when the minimum value of SOC (State Of Charge) is 0% and the maximum value is 100%. For example, the minimum value of SOC in the definition of the maximum storage capacity may be a predetermined value larger than 0%, and the maximum value of SOC may be a predetermined value smaller than 100%.
In the present embodiment, such storage maximum capacity, rated power, and the like are constraint conditions for the storage battery 104.
Further, in the above example, the rated power of the storage battery 104 is used as it is as the maximum allowable power. However, the allowable maximum power may be a value smaller than the rated power so as to give a predetermined margin to the rated power of the storage battery 104, for example.

According to the predicted surplus power GB1-1, it is predicted that the consumer facility B1 will generate 1 kW in the division period T1, 3 kW in the division period T2, 3 kW in the division period T3, and 1 kW in the division period T4. ing.
Further, as a constraint condition of the storage battery 104 in the consumer facility B1, the maximum storage capacity is 10 kWh and the rated power is 4 kW.

In this case, if the demand-responsive surplus power generated in the consumer facility A1 is charged to the storage battery 104 in the same consumer facility A1 from a state where the SOC is 0%, the result is as follows.
First, the demand-responsive surplus electric energy of 1 kWh (1 kW × 1 h) in the division period T1 can be charged to the storage battery 104 of the consumer facility A1. Further, the storage battery 104 of the consumer facility A1 can also be charged with the demand-responsive surplus electric energy of 2 kWh in the next division period T2.
However, at the stage when the division period T2 is completed, the amount of electric power (stored electric energy) stored in the storage battery 104 of the consumer facility A1 is 3 kWh, and the remaining amount of stored electric energy that can be charged is 1 kWh. Therefore, in the division period T3, the stored electric energy of the storage battery 104 of the consumer facility A1 becomes 4 kWh in the middle of 30 minutes from the start, and no more electric power can be stored.
Therefore, in the consumer facility A1 in this case, the demand-corresponding surplus electric energy of 2 kWh, which is 1/30 kWh in the latter half of the division period T3 and 1 kWh in the division period T4, cannot be charged to the storage battery 104 of the consumer facility A1. It is determined that a surplus state occurs.
As described above, the surplus power for demand that is not charged to the storage battery 104 in one consumer facility 100 is also described as the surplus power for charge.

On the other hand, when the demand-responsive surplus power generated in the consumer facility B1 is charged to the storage battery 104 in the same consumer facility B1 from a state where the SOC is 0%, the result is as follows.
First, the demand-responsive surplus electric energy of 1 kWh in the division period T1 can be charged to the storage battery 104 of the consumer facility B1. In addition, the storage battery 104 of the consumer facility B1 can also be charged with the demand-responsive surplus power amount of 3 kWh in the next division period T2. In addition, the storage battery 104 of the consumer facility B1 can also be charged with the demand-responsive surplus electric energy of 3 kWh in the next division period T3. Further, the storage battery 104 of the consumer facility B1 can also be charged with the demand-responsive surplus electric energy of 1 kWh in the next division period T4.
As described above, in the consumer facility B1, the maximum storage capacity of the storage battery 104 is 10 kWh, while the total amount of surplus electricity corresponding to the demand generated by the division periods T1 to T4 is 8 kWh. Therefore, it is determined that the storage battery 104 can be charged with all the demand-responsive surplus electric energy generated by the division periods T1 to T4.

That is, in the case of the above example, the power management device 300 generates charge-compatible surplus power in the consumer facility A1 based on the predicted surplus power GA1-1 and GB1-1, but the charge-compatible surplus power is generated in the consumer facility B1. Determine that it does not occur.
The power management device 300 classifies the consumer facility 100 that generates surplus power for charging as a supply consumer facility, and the consumer facility 100 that does not generate surplus power for charging as a receiving consumer facility.
The supply consumer facility is a consumer facility 100 that supplies surplus power for charging to other consumer facilities in order to accommodate electric power. The receiving consumer facility is the consumer facility 100 that receives the supply of the chargeable surplus power from the supply consumer facility and charges the storage battery 104 with the supplied chargeable surplus power.
In the example of the figure, the power management device 300 classifies the consumer facility A1 as a supply consumer facility and the consumer facility B1 as a receiving consumer facility.

Here, in the predicted surplus power GA1-1, the charge-corresponding surplus power amount generated in the latter half 30 minutes of the division period T3 is 1 kWh. On the other hand, the consumer facility B1 has already charged the storage battery 104 at 3 kW by its own generated power in the latter half 30 minutes of the division period T3. Since the rated power of the storage battery 104 of the consumer facility B1 is 4 kW, the remaining amount of power that can be charged to the storage battery 104 of the consumer facility B1 is 0.5 (= (4) in the latter half 30 minutes of the division period T3. -3) kW x 0.5 hours) kWh. Therefore, of the 1 kWh of surplus electric energy for charging generated in the consumer facility A1 in the latter half 30 minutes of the division period T3, 0.5 kWh corresponding to the surplus electric energy for charging W1 is the consumer facility B1. Although the storage battery 104 can be charged, the remaining 0.5 kWh corresponding to the chargeable surplus electric energy W2 cannot be charged.
In the next division period T4, the 1kWh chargeable surplus electric energy W3 generated in the consumer facility A1 can charge the storage battery 104 of the consumer facility B1.

As described above, in the example of the predicted surplus power GA1-1 and GB1-1 in the figure, 0.5 kWh of the 2 kWh chargeable surplus power generated in the consumer facility A1 cannot be accommodated in the consumer facility B1. The result is obtained. Further, in this case, the total amount of stored electric energy of the storage battery 104 of the consumer facility B1 is 9.5 kWh, which is a margin of 0.5 kWh with respect to the maximum storage capacity of 10 kWh.
From the viewpoint of the utilization efficiency of the generated power in the power management area 10, it is preferable to reduce the amount of surplus power for charging that cannot be charged to the receiving consumer facility as much as possible.
Hereinafter, the surplus power for charging that cannot be charged to the receiving consumer facility at the supply consumer facility 1 is also described as excess power.

Therefore, when it is determined that the excess power is generated as described above, the power management device 300 of the present embodiment is exceeded by formulating the operation schedule of the storage battery 104 of the receiving consumer facility as follows. Aim to reduce power consumption.

As an example of formulating an operation schedule for charging the storage battery 104 of the receiving consumer facility, the predicted surplus power interchange results GA1-2 and GB1-2 are shown in the figure.
According to the predicted surplus power interchange results GA1-2 and GB1-2, as an operation schedule of the storage battery 104 of the consumer facility B1, first, in the division period T1, 1 kW of surplus power corresponding to the demand generated in the consumer facility B1 Therefore, the storage battery 104 of the customer facility B1 is charged with 1 kW of charging power.
Next, in the division period T2, the storage battery 104 of the consumer facility B1 is charged with the charging power of 3 kW according to the demand-responsive surplus power of 3 kW generated in the consumer facility B1.
Next, for one hour as the division period T3, the storage battery 104 of the consumer facility A1 is charged with a charging power of 1 kW. As a result, in the division period T3, the consumer facility A1 charges the storage battery 104 of the consumer facility A1 with 1 kWh of the surplus electric energy corresponding to the demand of 2 kWh generated in-house, and the remaining 1 kWh of electric energy is demanded. It will be reverse power flow from the house facility A1.
Further, the storage battery 104 of the consumer facility B1 is charged with a charging power of 4 kW corresponding to the rated power. As a result, in the division period T3, the consumer facility B1 charges the private storage battery 104 with the amount of surplus power corresponding to the demand of 3 kWh generated in-house and the amount of power of 1 kWh supplied from the grid (commercial power supply line DL). Will be done. As a result, in the division period T3, the consumer facility B1 charges the storage battery 104 of the consumer facility B1 with the charge-corresponding surplus electric energy W5 of 1 kWh out of the 2 kWh demand-corresponding surplus electric energy generated in the consumer facility A1. be able to.
Further, in the next division period T4, the storage battery 104 of the consumer facility A1 is set to have a charging power of 0 kW so that it is not charged. Further, the storage battery 104 of the consumer facility B1 is charged with a charging power of 2 kW. As a result, the storage battery 104 of the consumer facility B1 can be charged with the 1 kWh of surplus electric energy W3 generated in the consumer facility A1.
In this case, at the stage when the division period T4 ends, the stored electric energy of the storage battery 104 of the consumer facility A1 becomes 4 kWh, which is equal to the maximum stored capacity, and the stored electric energy of the storage battery 104 of the consumer facility B1 becomes the maximum stored capacity. It becomes the same 10kWh.

Further, in response to the states of the predicted surplus power GA1-1 and GB1-1, the power management device 300 replaces the predicted surplus power interchange results GA1-2 and GB1-2 with the predicted surplus power interchange result GA1 in FIG. -3, GB1-3 can also formulate an operation schedule of the storage battery 104 of the consumer facility B1.

That is, the power management device 300 first sets the operation schedule as follows in the division period T1. That is, the power management device 300 sets an operation schedule for causing the storage battery 104 of the consumer facility A1 to be charged with the charging power of 1 kW according to the 1 kW demand response surplus power generated in the consumer facility A1. Further, the power management device 300 sets an operation schedule for causing the storage battery 104 of the consumer facility B1 to be charged with the charging power of 1 kW according to the 1 kW demand-responsive surplus power generated in the consumer facility B1.

Next, the power management device 300 sets the operation schedule as follows in the division period T2. That is, the power management device 300 sets an operation schedule for causing the storage battery 104 of the consumer facility A1 to charge the 2 kW demand-corresponding surplus power generated in the consumer facility A1 with the charging power of 1 kW. Further, the power management device 300 sets an operation schedule for causing the storage battery 104 of the consumer facility B1 to be charged by the charging power of 4 kW, which is 1 kW higher than the demand-responsive surplus power of 3 kW generated in the consumer facility B1.
As a result, in the division period T2, the storage battery 104 of the consumer facility B1 can be charged with 1 kWh of the charge-corresponding surplus electric energy W4 out of the 2 kWh demand-corresponding surplus electric energy generated in the consumer facility A1.

Next, in the division period T3, the operation schedule is set as follows. That is, the power management device 300 sets an operation schedule in which the storage battery 104 of the consumer facility A1 is charged with the charging power of 1 kW with respect to the 2 kW demand-corresponding surplus power generated in the consumer facility A1. Further, the power management device 300 sets an operation schedule for causing the storage battery 104 of the consumer facility B1 to charge at 4 kW, which is 1 kW higher than the demand-responsive surplus power of 3 kW generated at the consumer facility B1. As a result, even in the division period T3, the storage battery 104 of the consumer facility B1 can be charged with the 1 kWh chargeable surplus electric energy W5 of the 2 kWh demand-corresponding surplus electric energy generated in the consumer facility A1.

In this case, at the stage when the division period T3 ends, the stored power of the storage battery 104 of the consumer facility A1 is 3 kWh, which is 1 kWh less than the maximum storage capacity (4 kWh), and the stored power of the storage battery 104 of the consumer facility B1 is stored. It is 9 kWh, which is 1 kWh less than the maximum capacity (10 kWh).
Therefore, the power management device 300 sets the operation schedule as follows in the next division period T4. That is, the power management device 300 sets an operation schedule for causing the storage battery 104 of the consumer facility A1 to be charged with the charging power of 1 kW according to the 1 kW demand-responsive surplus power generated in the consumer facility A1. Further, an operation schedule is set in which the storage battery 104 of the consumer facility B1 is charged with the charging power of 1 kW according to the 1 kW demand-corresponding surplus power generated in the consumer facility B1.
As a result, in the division period T4, the 1 kW demand response surplus power generated in the consumer facility A1 is charged to the storage battery 104 of the consumer facility A1, and the 1 kW demand response surplus generated in the consumer facility B1. Electric power is charged to the storage battery 104 of the consumer facility B1.
Also in this case, at the stage when the division period T4 is completed, the stored electric energy of the storage battery 104 of the consumer facility A1 becomes 4 kWh, which is equal to the maximum storage capacity, and the stored electric energy of the storage battery 104 of the consumer facility B1 is the maximum stored. It becomes 10 kWh equal to the capacity.

That is, the power management device 300 supplies the demand-corresponding surplus power (that is, the storage battery 104) of the consumer facility B1 in the period (including the excess power section) before the section (excess power section) in which the excess power occurs within the unit period. It may be determined whether or not there is a section (margin section) in which the charging power) is smaller than the rated power of the storage battery 104. When the power management device 300 determines that there is a margin section, the power management device 300 is generated at the consumer facility B1 within a range not exceeding the rated power of the inverter for the storage battery 104 of the consumer facility B1 in the time zone corresponding to the margin section. It may be possible to charge with a charging power higher than the surplus power corresponding to the demand.

Further, with reference to FIGS. 5 and 6, an example of formulating an operation schedule of the storage battery 104 of the receiving consumer facility will be described when there are a plurality of supplying consumer facilities and a plurality of receiving consumer facilities. In the explanation of the figure, the case where there are two supply consumer facilities and two receiving consumer facilities are taken as an example.
In FIG. 5, the predicted surplus powers GA11-1, GA12-1, GB11-1, and GB12-1 are shown.
The predicted surplus power GA11-1 corresponds to the demand predicted for each predetermined division period (1 hour) in the unit period (1 day) at the consumer facility A11, which is one of the plurality of customer facilities 100. It shows the surplus power.
The predicted surplus power GA12-1 indicates the demand-corresponding surplus power predicted for each predetermined division period in the unit period at the consumer facility A12, which is one of the plurality of consumer facilities 100.
The predicted surplus power GB11-1 corresponds to the demand predicted for each predetermined division period (1 hour) in the unit period (1 day) at the consumer facility B11, which is one of the plurality of consumer facilities 100. It shows the surplus power.
The predicted surplus power GB12-1 indicates the demand-corresponding surplus power predicted for each predetermined division period in the unit period at the consumer facility B12, which is one of the plurality of consumer facilities 100.

Further, regarding the constraint conditions (maximum storage capacity, rated power of the inverter) of the storage battery 104 in each of the consumer facilities A11, A12, B11, and B12, the following cases will be taken as an example.
The storage battery 104 of the consumer facility A11 has a maximum storage capacity of 10 kWh and a rated power of 4 kW.
The storage battery 104 of the consumer facility A12 has a maximum storage capacity of 3 kWh and a rated power of 2 kW.
The storage battery 104 of the consumer facility B11 has a maximum storage capacity of 6 kWh and a rated power of 2 kW.
The storage battery 104 of the consumer facility B12 has a maximum storage capacity of 7 kWh and a rated power of 2 kW.

According to the predicted surplus power GA11-1, it is predicted that the consumer facility A11 will generate 1 kW in the division period T1, 4 kW in the division period T2, 4 kW in the division period T3, and 2 kW in the division period T4. ing.
In this case, when the demand-responsive surplus power generated in the consumer facility A11 is charged to the storage battery 104 of the same consumer facility A11 from a state where the SOC is 0% as described above, At the timing when the first half 30 minutes of the division period T4 has elapsed, the stored power amount becomes 10 kWh, which is equal to the maximum stored capacity. Therefore, in the consumer facility A11, the demand-corresponding surplus electric energy of 1 kWh corresponding to the latter half 30 minutes of the division period T4 is generated as the charge-corresponding surplus electric energy.

Further, according to the predicted surplus power GA12-1, in the consumer facility A12, 1 kW in the division period T1, 2 kW in the division period T2, 2 kW in the division period T3, and 1 kW in the division period T4 are generated. It is predicted.
In this case, if the demand-responsive surplus power generated at the consumer facility A12 is charged to the storage battery 104 of the same consumer facility A12 from a state where the SOC is 0%, the division period T2 At the elapsed timing, the stored power amount becomes 3 kWh, which is equal to the maximum stored capacity. Therefore, in the consumer facility A12, the demand-corresponding surplus electric energy of 3 kWh corresponding to the division periods T3 and T4 is generated as the charge-corresponding surplus electric energy.

Further, according to the predicted surplus power GB11-1, in the consumer facility B11, the demand-corresponding surplus power of 1 kW in the division period T1, 2 kW in the division period T2, 1 kW in the division period T3, and 0 kW in the division period T4 is generated. It is predicted.
In this case, if the demand-responsive surplus power generated at the consumer facility B11 is charged to the storage battery 104 of the same consumer facility B11 from a state where the SOC is 0%, up to the classification period T3. It is possible to charge all of the surplus electric energy of 4 kWh in response to the demand. Therefore, in the consumer facility B11, surplus power for charging is not generated. At this stage, the storage battery 104 of the consumer facility B11 still has a margin of accumulating 2 kWh.

Further, according to the predicted surplus power GB12-1, in the consumer facility B12, the demand response surplus power of 1 kW in the division period T1, 2 kW in the division period T2, 2 kW in the division period T3, and 0 kW in the division period T4 is generated. It is predicted.
In this case, if the demand-responsive surplus power generated at the consumer facility B12 is charged to the storage battery 104 of the same consumer facility B12 from a state where the SOC is 0%, up to the classification period T3. It is possible to charge all of the 5kWh demand-responsive surplus electric energy. Therefore, in the consumer facility B12, surplus power for charging is not generated. At this stage, the storage battery 104 of the consumer facility B12 still has a margin of being able to store an electric energy of 2 kWh.

Therefore, in this case, the power management device 300 classifies the consumer facilities A11 and A12 as supply consumer facilities, and classifies the consumer facilities B11 and B12 as supply consumer facilities.

Next, the power management device 300 determines whether or not there is an excess power section in the supply consumer facility as follows.
In this case, first, in the consumer facility A11 as the supply consumer facility, a charge-corresponding surplus electric energy W11 of 1 kWh (2 kW × 0.5 h) is generated in the latter half 30 minutes of the division period T4. Regarding the surplus electric power W11 for charging, 1 kWh can be charged to the storage battery 104 of the consumer facility B11 with a charging power of 2 kW equivalent to the rated power in the latter half 30 minutes of the classification period T4 (at this time, the consumer facility). The charging power of the storage battery 104 of A11 is 0 kW). Since the storage capacity of the storage battery 104 of the consumer facility B11 becomes 5 kWh by this charging, the storage battery 104 of the consumer facility B11 still has a margin of being able to store 1 kWh of electric energy with respect to the maximum storage capacity of 6 kWh.
Further, as described above, the chargeable surplus electric energy W11 is charged to the storage battery 104 of the consumer facility B11, so that all the demand corresponding surplus electric power is charged in the consumer facility A11. Therefore, in the consumer facility A11, there is no excess power section.

Next, in the consumer facility A12 as another supply consumer facility, a charge-corresponding surplus electric energy of 2 kWh in the division period T3 and a charge-corresponding surplus electric energy of 1 kWh in the division period T4 are generated.
In this case, in the division period T3, the storage battery 104 of the consumer facility B11 is charged with a charging power of 2 kW. As a result, the storage battery 104 of the consumer facility B11 can be charged with 1 kWh of the chargeable surplus electric energy W12 of the 2 kWh chargeable surplus electric energy in the consumer facility A12.
However, at this charging stage, during the division period T3, the storage battery 104 of the consumer facility B11 is charged with a charging power of 2 kW, which is equivalent to the rated power. Further, the storage battery 104 of the consumer facility B12 has already been charged with a charging power of 2 kW, which is equivalent to the rated power, for charging the demand-responsive surplus power generated in the consumer facility B12. Therefore, the 1 kWh of surplus electric energy W13 remaining in the consumer facility A12 cannot be charged in any of the storage batteries 104 of the consumer facilities B11 and B12.
Further, in the consumer facility A12, a charge-corresponding surplus electric energy W14 of 1 kWh (1 kW × 1 h) is generated in the division period T4. At the timing when the division period T3 of the consumer facility A12 ends, the storage capacity of the storage battery 104 of the consumer facility B12 is 5 kWh, and there is a margin of 2 kWh with respect to the maximum storage capacity of 7 kWh. Further, in the consumer facility B12, no surplus power for demand is generated in the division period T4. Therefore, by executing the charging operation of the storage battery 104 of the consumer facility B12 with the charging power of 1 kW in the division period T4, the chargeable surplus electric energy W14 can be charged to the storage battery 104 of the consumer facility B12 (at this time). , The charging power of the storage battery 104 of the consumer facility A12 is set to 0 kW).
As described above, in the example of the figure, it is determined that the consumer facility A12 has an excess power section due to the charge-corresponding surplus electric energy W13 corresponding to the division period T3.

In this case, as shown in FIG. 6, the power management device 300 formulates an operation schedule of the storage battery 104 in each of the customer facilities B11 and B12, which are the receiving consumer facilities.
In this case, first, in the division period T3, the power management device 300 is charged by the storage battery 104 of the consumer facility A12 with a charging power of 1 kW, and is charged by the storage battery 104 of the consumer facility B11 with a charging power of 2 kW. Set the operation schedule to be performed. As a result, the storage battery 104 of the consumer facility B11 can be charged (accommodated) with 1 kWh of the chargeable surplus electric energy W12 of the 2 kWh chargeable surplus electric energy in the consumer facility A12.

Here, when the storage battery 104 of the consumer facility B11 is charged with the chargeable surplus electric energy W12 as described above, as described with reference to FIG. 5, 1 kWh of charge is supported in the same division period T3. With respect to the surplus electric energy W13, neither the consumer facilities B11 nor B12 can be charged.

Therefore, the power management device 300 in this case determines that the storage battery 104 of the consumer facility B12 is charged with the chargeable surplus electric energy W16 of 1 kWh in the division period T1 instead of the chargeable surplus electric energy W13. For this purpose, the power management device 300 sets the operation schedule in the division period T1 as follows. That is, the power management device 300 is set so that the storage battery 104 of the consumer facility A12 is charged with a charging power of 0 kW, and the storage battery 104 of the consumer facility B12 is charged with a charging power of 2 kW.

Further, regarding the chargeable surplus electric energy W14 in the division period T4, the charging power of the storage battery 104 of the consumer facility A12 is set to 0 kW, and the storage battery 104 of the consumer facility B12 is set to be charged with the charging power of 1 kW. , The storage battery 104 of the consumer facility B12 may be accommodated.

In this way, even when there are a plurality of supply consumer facilities and a plurality of receiving consumer facilities, the power management device 300 specifies a margin section of the receiving consumer facility in the period before the excess power section in the unit period. .. The power management device 300 uses charging power higher than the demand-responsive surplus power generated at the receiving consumer facility within the range not exceeding the rated power for the storage battery 104 of the receiving consumer facility during the period corresponding to the spare section. Develop an operation schedule to charge the battery.
By formulating the operation schedule of the storage battery 104 in this way, in the present embodiment, it is possible to suppress the excess power generated in the supply consumer facility.

A configuration example of the power management device 300 of the present embodiment will be described with reference to FIG. 7. The power management device 300 in the figure includes a communication unit 301, a control unit 302, and a storage unit 303.

The communication unit 301 executes communication with the in-facility power management device 200 of the consumer facility 100 in the power management area 10 via the network NW.

The control unit 302 executes various controls in the power management device 300. The function as the control unit 302 is realized by executing a program by a CPU (Central Processing Unit) provided in the power management device 300.
The control unit 302 includes a demand response surplus power acquisition unit 321, a consumer facility classification unit 322, a power control plan formulation unit 323, and a power control unit 324.

The demand-response surplus power acquisition unit 321 acquires the demand-response surplus power predicted based on the predicted generated power and the predicted demand power in the unit period for each consumer facility 100.
The predicted generated power is a predicted result of the transition of the generated power obtained by the power generation device 103 generating power in a unit period according to the time axis. The predicted power demand is a prediction result of the transition of the power consumed by the load 105 (power demand) in a unit period according to the time axis.
The demand response surplus power acquisition unit 321 acquires, for example, parameters (prediction parameters) used for deriving (predicting) the predicted generated power and the predicted demand power from the power management record storage unit 333. The prediction parameters include, for example, information on the generated power and the actual power demand for the corresponding consumer facility 100 in the past fixed period. Further, information such as a weather forecast may be included in the parameters. The demand-response surplus power acquisition unit 321 derives the predicted generated power and the predicted demand power in a unit period by using the acquired parameters.
Then, the demand-response surplus power acquisition unit 321 derives the demand-response surplus power for each hour in the unit period by obtaining the difference between the predicted generated power for each hour and the predicted demand power in the unit period. In this way, the demand-response surplus power acquisition unit 321 acquires the demand-response surplus power.

The consumer facility classification unit 322 demands the storage battery 104 in a unit period based on the demand response surplus power acquired by the demand response surplus power acquisition unit 321 and the storage maximum capacity of the storage battery 104 for each consumer facility 100. It is classified into supply consumer facilities where surplus power for charging is generated when the corresponding surplus power is charged, and receiving consumer facilities where surplus power for charging is not generated.

In a unit period, the power control planning department 323 uses the demand-responsive surplus power of the supply consumer facility and the demand-response surplus power of the receiving consumer facility to the storage battery 104 (an example of the target storage battery) of the receiving consumer facility. , Judge whether there is an excess power section when charging with the maximum allowable power corresponding to the rated power.
When the power control planning unit 323 determines that there is an excess power section, the supply consumer in the section where the demand-response surplus power of the receiving consumer facility is smaller than the allowable maximum power in the period before the excess power section. Develop a power control plan so that the target storage battery is charged with surplus power that meets the demand of the facility.

The electric power control unit 324 controls the operation of the electric equipment in the consumer facility 100 as the electric power control.
For this purpose, the power control unit 324 transmits a command to the in-facility power management device 200 of the consumer facility 100 via the communication unit 301. In response to receiving the command, the facility power management device 200 controls the electrical equipment in the consumer facility 100. As described above, the power control by the in-facility power management device 200 is performed via the in-facility power management device 200 of the consumer facility 100.

The storage unit 303 stores various types of information used in the power management device 300. The storage unit 303 in the figure includes a consumer facility information storage unit 331, a power control plan storage unit 332, and a power management record storage unit 333.

The consumer facility information storage unit 331 stores the consumer facility information for each consumer facility 100 in the power management system 1. The consumer facility information includes various information regarding the corresponding consumer facility 100. For example, the customer facility information includes personal information regarding the name, address, etc. of the corresponding customer, information regarding the electrical equipment provided in the corresponding customer facility 100, and the like.
In the case of the present embodiment, the consumer facility information includes information regarding the specifications of the storage battery 104 provided in the corresponding consumer facility 100. The information regarding the specifications of the storage battery 104 includes information such as charge capacity and rated power.

The power control plan storage unit 332 stores information on the power control plan formulated by the power control plan formulation unit 323.
The electric power control unit 324 controls the electric equipment for each customer facility 100 based on the information of the electric power control plan stored in the electric power control plan storage unit 332. As a result, in the power management system 1, the electric equipment for each customer facility 100 can be operated according to the formulated power control plan.

The power management record storage unit 333 stores the past power management record of the power management system 1. The power management results include the power generated and the power demanded by each consumer facility 100 for each unit period in the past. It also includes the actual results of charge / discharge operation of the storage battery 104 in each consumer facility 100 in the past unit period.

The in-facility power management device 200 of the consumer facility 100 may each store the power management results of the corresponding customer facility 100. In this case, the power management device 300 can obtain the same information stored in the power management record storage unit 333 by collecting the power management results from each of the consumer facilities 100. In this case, the power management record storage unit 333 may be omitted.

An example of a processing procedure executed by the power management device 300 of the present embodiment in connection with the formulation of the operation schedule of the storage battery 104 in the operation plan will be described with reference to the flowchart of FIG.
Step S101: As described in FIGS. 3 and 5, in formulating the operation schedule of the storage battery 104, each of the consumer facilities 100 in the power management system 1 is either a supply consumer facility or a receiving consumer facility. It is classified into.
Therefore, the consumer facility classification unit 322 of the power management device 300 selects one consumer facility 100 to be classified from the consumer facilities 100 of the power management system 1.

Step S102: The demand response surplus power acquisition unit 321 acquires the parameters (forecast parameters) used for deriving (forecasting) the predicted generated power and the predicted demand power of the consumer facility 100 to be classified selected in step S101. To do.
As described above, the demand-responsive surplus power acquisition unit 321 may acquire the past power generation power, demand power, and the like of the consumer facility 100 to be classified from the power management performance storage unit 333 as prediction parameters. ..
In addition, the demand response surplus power acquisition unit 321 may also acquire weather forecast information and the like in the time zone corresponding to the unit period for which the operation schedule is to be formulated as prediction parameters.

Step S103: The demand response surplus power acquisition unit 321 derives the generated power and the demand power in the unit period for which the operation schedule is to be formulated in the customer facility 100 to be classified by using the prediction parameters acquired in step S102 ( Predict. The derived generated power and demand power are the predicted generated power and the predicted demand power, respectively.
In the present embodiment, the prediction method of the predicted generated power and the predicted demand power is not particularly limited.
Further, as described above, the predicted generated power and the predicted demand power in the present embodiment indicate the values for each time in the unit period of the prediction target.

Step S104: The demand-response surplus power acquisition unit 321 derives the demand-response surplus power of the consumer facility 100 to be classified based on the predicted generated power and the predicted demand power derived in step S103. The demand-response surplus power acquisition unit 321 may derive the demand-response surplus power based on, for example, the difference between the predicted generated power and the predicted demand power.

Step S105: The consumer facility classification unit 322 derives the maximum storage capacity of the storage battery 104 included in the consumer facility 100 to be classified. As described above, the consumer facility classification unit 322 derives the maximum storage capacity based on the charge capacity indicated as the specifications of the storage battery 104 included in the classification target consumer facility 100 stored in the consumer facility information storage unit 331. You can do it.

Step S106: The consumer facility classification unit 322 classifies the consumer facility to be classified into either a supply consumer facility or a receiving consumer facility.
For this purpose, the consumer facility classification unit 322 determines whether or not the charge-corresponding surplus power is generated by, for example, the demand-corresponding surplus power derived in step S104 and the storage maximum capacity derived in step S105. To do.
As an example of the simplest judgment, the consumer facility classification unit 322 determines that if the demand-response surplus power is larger than the maximum storage capacity, a charge-supporting surplus power is generated, and if the demand-response surplus power is smaller than the storage maximum capacity, It may be determined that no surplus power for charging is generated.
Then, the consumer facility classification unit 322 classifies the consumer facility 100 to be classified as a supply consumer facility when it is determined that the charge-compatible surplus power is generated, and when it is determined that the charge-compatible surplus power is not generated. Is classified as a receiving consumer facility.

Step S107: After the process of step S106, the consumer facility classification unit 322 determines whether or not the classification of all the consumer facilities 100 to be classified in the power management system 1 is completed.
If the unclassified consumer facility 100 remains, the process is returned to step S101 to classify the unclassified consumer facility 100.

Step S108: When it is determined in step S106 that the classification of all the consumer facilities 100 to be classified is completed, the power control plan formulation unit 323 determines that the consumer facilities 100 classified as supply consumer facilities 100. From among these, select one supply-demand facility as an operation plan formulation target. In the following description, the consumer facility 100 selected in step S108 will be described as a target supply consumer facility.

Step S109: The power control plan formulation unit 323 identifies the excess power section of the target supply consumer facility in the unit period for which the operation schedule is to be formulated.
Therefore, when the power control planning unit 323 simulates charging the storage battery 104 of the same target supply consumer facility with the surplus power corresponding to the demand generated in the target supply consumer facility, the SOC of the storage battery 104 Is 100%, and the section in which the demand-corresponding surplus power (that is, the charge-corresponding surplus power) that cannot be charged is generated is specified. Specifically, in the correspondence with the predicted surplus power GA1-1 in FIG. 3, the latter half 30 minutes of the division period T3 and the division period T4 are sections in which the charge-corresponding surplus power is generated.
Next, the power control planning unit 323 performs a simulation of charging the storage battery 104 of the receiving consumer facility in the same specified section with the surplus power corresponding to charging in the specified section. At this time, the charging simulation is performed on the premise that the maximum storage capacity and the rated power, which are the constraints of the storage battery 104 of the receiving consumer facility, are not exceeded.
As a result of the simulation, if all of the surplus power corresponding to charging can be charged to the storage battery 104 of the receiving consumer facility, it means that the excess power has not occurred. In this case, the power control planning unit 323 obtains a specific result that the excess power section does not exist.
Further, as a result of the simulation, if the storage battery 104 of the receiving consumer facility has surplus power corresponding to charging that cannot be charged, it means that excess power has been generated. In this case, the power control planning unit 323 specifies the section in which the excess power is generated as the excess power section.
Specifically, in the correspondence with the predicted surplus power GA1-1 in FIG. 3, since excess power as the charge-corresponding surplus power amount W2 is generated in the latter half 30 minutes of the division period T3, the latter half 30 of the division period T3 Minutes are identified as excess power sections.

Step S110; After step S109, the power control planning unit 323 determines whether or not the excess power section has been specified for all the supply consumer facilities.
If there is a supply consumer facility for which the excess power section has not yet been specified, the process is returned to step S108.

Step S111: The power control plan formulation unit 323 formulates an operation schedule of the storage battery 104 of the receiving consumer facility.
That is, in the period before the excess power section specified in step S109, the demand-response surplus power of the supply consumer facility charges the target storage battery in the section where the demand-response surplus power of the receiving consumer facility is smaller than the allowable maximum power. The hourly charging power of the storage battery 104 of the consumer facility (supply consumer facility, receiving consumer facility) is set so as to be performed.
In this case, the power control planning unit 323 sets the hourly charging power of the storage battery 104 of the consumer facility in consideration of the rechargeable capacity and the rated power, which are the constraint conditions of the storage battery 104 of the customer facility.

Step S112: The power control plan formulation unit 323 reflects the operation schedule of the storage battery 104 of the receiving consumer facility formulated in step S111 in the power control plan.
The power control plan reflecting the operation schedule of the storage battery 104 of the receiving consumer facility is stored in the power control plan storage unit 332. The power control unit 324 controls the electric equipment and the like in the power management system 1 according to the power control plan stored in the power control plan storage unit 332.

<Second Embodiment>
Subsequently, as a second embodiment, a specific example of an operation schedule formulation method for the storage battery 104 of the consumer facility for suppressing excess power will be described. The description of the present embodiment will be a description of a specific example of the process as step S111 in FIG.

Previously, the example of the operation schedule formulation described with reference to FIGS. 3 to 6 was to explain an example of a flexible pattern that is possible in maximizing the reduction of excess power without following a specific algorithm. A specific example of formulating an operation schedule of the storage battery 104 according to an example of the operation schedule formulating method of the present embodiment will be described with reference to FIGS. 9 and 10.

First, with reference to FIG. 9, as one of the simplest examples, an example of formulating an operation schedule of the storage battery 104 corresponding to the transfer (accommodation) of electric power between two consumer facilities will be described.
In the figure, as in FIG. 3, the predicted surplus power GA1-1 of the consumer facility A1 which is the supply consumer facility and the predicted surplus power GB1-1 of the consumer facility B1 which is the receiving consumer facility are shown. ing.
Further, in the figure, the constraint conditions of the storage battery 104 in each of the consumer facilities A1 and B1 are the same as in FIG. That is, the constraint conditions of the storage battery 104 in the consumer facility A1 are that the maximum storage capacity is 4 kWh and the rated power (an example of the allowable maximum power) is 2 kW. The constraint conditions of the storage battery 104 in the consumer facility B1 are that the maximum storage capacity is 10 kWh and the rated power is 4 kW.
Further, also in the figure, the case where the SOC of each storage battery 104 of the consumer facilities A1 and B1 is 0% at the start of the division period T1 is taken as an example.
Further, regarding the predicted surplus power GA1-1 and GB1-1 in the figure, similarly to FIG. 3, when the control for accommodating the excess power is performed in the section where the excess power is generated, a part of the excess power is used. The result shows that a certain amount of surplus power W2 corresponding to charging cannot be accommodated.

Corresponding to the case of the predicted surplus power GA1-1 and GB1-1 in the figure, the power control plan formulation unit 323 of the power management device 300 of the present embodiment has the predicted surplus power interchange results GA1-4 and GB1 in the figure. As shown as -4, the operation schedule of the storage battery 104 is formulated (charge / discharge schedule is set).

First, the power control plan formulation unit 323 makes the following determinations for the division period T1 which is the first target section among the target sections for which the power control plan is formulated. That is, the electric power control plan formulation unit 323 determines whether or not the electric power can be interchanged from the consumer facility A1 which is the supply consumer facility to the consumer facility B1 which is the receiving consumer facility. At this time, the power control planning unit 323 considers that the constraint condition of the storage battery 104 of the consumer facility B1 is satisfied.

In the classification period T1, 1 kWh of surplus electric energy W21 corresponding to demand is generated at the consumer facility A1. On the other hand, in the same division period T1, the consumer facility B1 generates 1 kWh of surplus electric energy for demand.
In this case, assuming that the demand-corresponding surplus electric energy W21 is accommodated for the storage battery 104 of the consumer facility B1, the storage battery 104 of the consumer facility B1 has 1 kWh of the demand-corresponding surplus electric energy and the demand-corresponding surplus generated in its own house. A total of 2 kWh of electric energy is charged together with the electric energy W21. In this case, since the storage battery 104 of the consumer facility B1 stores 2 kWh out of the maximum storage capacity of 10 kWh, the remaining amount of stored power that can be charged is 8 kWh, and the battery can be charged with less than the rated power of 4 kW. .. That is, satisfying the constraint condition of the storage battery 104 of the consumer facility B1, the power control planning unit 323 determines that all of the 1 kWh demand-responsive surplus electric energy W21 generated in the consumer facility A1 can be accommodated. ..
Therefore, the power control plan formulation unit 323 sets the charging power of 0 kW for the storage battery 104 of the consumer facility A1 and does not charge the storage battery 104 of the consumer facility B1 in the division period T1 as the operation schedule, and does not charge the storage battery 104 of the consumer facility B1. Is set to charge with a charging power of 2 kW (= 1 kW + 1 kW). As a result, the consumer facility A1 causes the private storage battery 104 to reverse power flow to the system instead of charging the private storage battery 104 with the 1 kWh of surplus electric energy W21 generated in-house. In addition, the consumer facility B1 charges the private storage battery 104 with a total of 2 kWh, which is 1 kWh of surplus electric energy for demand generated in-house and 1 kWh of surplus electric energy for demand that is reverse-flowed from consumer facility A1. Will let you.

Next, the electric power control plan formulation unit 323 similarly determines whether or not the electric power can be interchanged from the consumer facility A1 to the consumer facility B1 in the division period T2 following the division period T1.
In the division period T2, the consumer facility A1 generates 2 kW of demand-responsive surplus power, and the consumer facility B1 generates 3 kW of demand-response surplus power. Since the rated power of the storage battery 104 of the consumer facility B1 is 4 kW, there is a margin of 1 kW before the rated power is reached. Further, even if the storage battery 104 of the consumer facility B1 is charged with 4 kWh in the division period T2, the total amount of stored power in the storage battery 104 of the consumer facility B1 is 6 kWh (= 2 kWh + 4 kWh) due to the division periods T1 to T2. It can store up to 4 kWh. Therefore, in this case, the power control planning unit 323 uses 1 kWh of the demand-responsive surplus power W22 of the 2 kWh of demand-responsive surplus power generated at the consumer facility A1 as the storage battery 104 of the consumer facility B1. Judged to be flexible.
Therefore, the power control plan formulation unit 323 sets the operation schedule to charge the storage battery 104 of the consumer facility A1 with 1 kW of charging power in the division period T2, and 4 kW (4 kW) of the storage battery 104 of the consumer facility B1. = 3kW + 1kW) is set to charge the battery. As a result, the demand-responsive surplus electric energy W22 generated in the consumer facility A1 can be accommodated by charging the storage battery 104 of the consumer facility B1.

Next, the electric power control plan formulation unit 323 similarly determines whether or not electric power can be interchanged from the consumer facility A1 to the consumer facility B1 in the division period T3 following the division period T2.
In the division period T3, the consumer facility A1 generates 2 kW of demand-responsive surplus power, and the consumer facility B1 generates 3 kW of demand-response surplus power. Since the rated power of the storage battery 104 of the consumer facility B1 is 4 kW, there is a margin of 1 kW before the rated power is reached. Further, even if the storage battery 104 of the consumer facility B1 is charged with 4 kWh in the division period T3, the total amount of stored power in the storage battery 104 of the consumer facility B1 is 10 kWh (= 2 kWh + 4 kWh + 4 kWh) according to the division periods T1 to T3. The storage battery 104 can be charged. Therefore, in this case, the power control planning unit 323 transfers 1 kWh of the demand-responsive surplus power W23 out of the 2 kWh of demand-responsive surplus power generated at the consumer facility A1 to the storage battery 104 of the consumer facility B1. Determined to be flexible.
Therefore, the power control plan formulation unit 323 sets the operation schedule to charge the storage battery 104 of the consumer facility A1 at 1 kW during the division period T3, and charges the storage battery 104 of the consumer facility B1 at 4 kW (=). 3 kW + 1 kW) is set to be charged. As a result, the demand-responsive surplus electric energy W23 generated in the consumer facility A1 can be accommodated by charging the storage battery 104 of the consumer facility B1.

Next, the electric power control plan formulation unit 323 similarly determines whether or not electric power can be interchanged from the consumer facility A1 to the consumer facility B1 in the division period T4 following the division period T3.
In the division period T4, the consumer facility A1 generates 1 kW of demand-responsive surplus power, and the consumer facility B1 generates 1 kW of demand-response surplus power. In this case, the storage battery 104 of the consumer facility B1 cannot be charged any more because the stored electric energy has reached the maximum storage capacity of 10 kWh at the stage of the division period T3. Therefore, the power control plan formulation unit 323 determines that the power cannot be interchanged from the consumer facility A1 to the consumer facility B1 during the division period T4.

As can be understood from the above description with respect to FIG. 9, in the operation schedule formulation method of the present embodiment, first, the storage battery 104 of the supply consumer facility can be accommodated in order from the first target section. If there is surplus electricity to meet demand, we will formulate an operation schedule so that it will be flexible. Therefore, as in the case of the division period T4 in the figure, when all the target sections are not completed, the stored electric energy of the storage battery 104 of the receiving consumer facility reaches the maximum stored capacity, and the battery cannot be charged any more. May be. On the other hand, the storage battery 104 of the supply consumer facility may be in a state in which the stored electric energy does not reach the maximum stored capacity and can be charged. The figure shows an example in which the storage battery 104 of the consumer facility B1 at the stage when the division period T4 is reached is in such a state.
In this case, the storage battery 104 of the supply consumer facility has a margin in the remaining storable capacity, whereas the storage battery 104 of the receiving consumer facility has a margin in the remaining storable capacity. That is, a reversal state occurs in which excess power is generated at the receiving consumer facility. In order to suppress the excess power as much as possible, it is preferable to be able to eliminate or suppress such a reverse state.

Therefore, when it is determined that the power cannot be interchanged from the supply consumer facility to the receiving consumer facility, the power control plan formulation unit 323 may further perform the following procedure.
That is, the power control plan formulation unit 323 determines whether or not the demand-responsive surplus power of the receiving consumer facility can be accommodated in the storage battery 104 of the supplying consumer facility in the division period T4. In the example of the figure, the stored electric energy of the storage battery 104 of the consumer facility A1 during the division period T3 is 2 kWh, and there is a margin of 2 kWh with respect to the maximum stored capacity of 4 kWh.
Further, in the division period T4, the demand-corresponding surplus electric energy W24 (corresponding to the charge-corresponding surplus electric energy W3 in the predicted surplus electric power GA1-1) of 1 kWh is generated in the consumer facility A1.
On the other hand, in the division period T4, the consumer facility B1 generates 1 kWh of surplus electric energy W25 to meet the demand. In this case, as shown in the figure, when the demand-responsive surplus electric energy W25 is transferred to the consumer facility A1, the storage battery 104 of the consumer facility A1 is charged with the same 2 kW as the rated electric power. As a result, the stored electric energy becomes 4 kWh, which is equal to the maximum stored capacity.
Therefore, in this case, the electric power control planning unit 323 determines that the demand-corresponding surplus electric energy W25 of the consumer facility B1 can be accommodated in the storage battery 104 of the consumer facility A1.
Therefore, as an operation schedule, the power control plan formulation unit 323 does not charge the storage battery 104 of the consumer facility B1 in the division period T4, and the storage battery 104 of the customer facility A1 is charged with 2 kW of charging power. Set to charge.
By setting the operation schedule in such a division period T4, it is possible to eliminate the excess power as the demand response surplus power amount W25 generated in the receiving consumer facility.

The procedure for reducing the excess power generated at the receiving consumer facility is that the stored power amount of the storage battery 104 of the receiving consumer facility reaches the maximum storage capacity, and the receiving consumer facility receives the receiving power. This is done in response to the determination that the interchange of electricity to the facility is not possible.
However, the procedure for reducing the excess power generated in the receiving consumer facility is to accommodate the power from the supplying consumer facility to the receiving consumer facility because the charging power for the storage battery 104 of the receiving consumer facility exceeds the rated power. It may also be performed when it is determined that is not possible.

In this way, the power control plan formulation unit 323 sets the constraint condition (storeable electric energy) of the storage battery 104 of the receiving consumer facility for each target section in the order of the earliest time of the target section for which the power control plan is to be formulated. And the maximum allowable electric power), it is determined whether or not the storage battery 104 of the receiving consumer facility can be accommodated among the demand-responsive surplus electric power of the supplying consumer facility. When it is determined that the flexibility is possible, the power control plan formulation unit 323 sets the charging power of the storage battery of the receiving consumer facility in the target section so that the flexibility is performed.
Then, when the power control planning unit 323 determines that the surplus power corresponding to the demand of the supply consumer facility cannot be accommodated in the storage battery 104 of the receiving consumer facility in the target section of 1, the restriction of the storage battery 104 of the supply consumer facility Based on the conditions, it is determined whether or not at least a part of the demand-responsive surplus power of the receiving consumer facility can be accommodated in the storage battery 104 of the supplying consumer facility. When it is determined that there is power that can be accommodated, the power control planning unit 323 sets the charging power of the storage battery of the supply consumer facility in the target section 1 so that the power can be accommodated.

Next, with reference to FIG. 10, an example of formulating an operation schedule in the present embodiment will be described when there are a plurality of supply consumer facilities and a plurality of receiving consumer facilities.
In the figure, as in FIG. 5, an example is shown in which the supply consumer facilities are the consumer facilities A11 and A12 and the receiving consumer facilities are the consumer facilities B11 and B12. .. Further, the pattern of the predicted surplus power predicted for each of the consumer facilities A11, A12, B11, and B12 is the same as that of the predicted surplus power GA11-1, GA12-1, GB11-1, and GB12-1 of FIG. An example of the case is shown.
Further, the constraint conditions (maximum storage capacity, rated power) of the storage battery 104 in each of the consumer facilities A11, A12, B11, and B12 are the same as in FIG. That is, the storage battery 104 of the consumer facility A11 has a maximum storage capacity of 10 kWh and a rated power of 4 kW. The storage battery 104 of the consumer facility A12 has a maximum storage capacity of 3 kWh and a rated power of 2 kW. The storage battery 104 of the consumer facility B11 has a maximum storage capacity of 6 kWh and a rated power of 2 kW. The storage battery 104 of the consumer facility B12 has a maximum storage capacity of 7 kWh and a rated power of the inverter of 2 kW.
Further, also in the figure, the case where the SOC of each storage battery 104 of the consumer facilities A11, A12, B11, and B12 is 0% at the start of the division period T1 is taken as an example.
In this case, when the control for accommodating the excess power is performed in the section where the excess power is generated, the classification period of the consumer facility A11 is the same as that shown as the chargeable surplus power amount W13 in FIG. Excess power is generated corresponding to T3.

Corresponding to the predicted surplus power shown in the figure, the power control planning unit 323 of the power management device 300 sets the predicted surplus power interchange results GA11-3, GA12-3, GB11-3, GB12-3 in the figure. As shown, the operation schedule of each storage battery 104 is formulated (charge / discharge schedule is set).
First, the power control plan formulation unit 323 makes the following determinations for the division period T1 which is the first target section among the target sections for which the power control plan is formulated. That is, the electric power control planning unit 323 determines whether or not electric power can be interchanged from the consumer facilities A11 and A12, which are supply consumer facilities, to the consumer facilities B11 and B12, which are recipient consumer facilities. judge. At this time, the power control planning unit 323 considers that the constraint conditions of the storage batteries 104 of the consumer facilities B11 and B12 are satisfied.

In the classification period T1, 1 kWh of surplus electric energy W31 for demand is generated at the consumer facility A11, and 1 kWh of surplus electric energy for demand W32 is generated at the consumer facility A12. On the other hand, in the same division period T1, the consumer facility B11 generates 1 kWh of surplus electricity for demand, and the customer facility B12 generates 1 kWh of surplus electricity for demand.
In this case, the power control plan formulation unit 323 determines that it is possible to accommodate the demand-responsive surplus electric energy W31 from the consumer facility A11 to the storage battery 104 of the consumer facility B11. Further, the electric power control plan formulation unit 323 determines that it is possible to accommodate the demand-responsive surplus electric energy W32 from the consumer facility A12 to the storage battery 104 of the consumer facility B12.
In this case, the power control plan formulation unit 323 accommodates the demand-responsive surplus electric energy W31 from the consumer facility A11 to the storage battery 104 of the consumer facility B12, and the storage battery 104 of the consumer facility A12 to the consumer facility B11. It may be determined that the surplus electric energy W32 corresponding to the demand can be accommodated.
Therefore, as an operation schedule, the power control planning unit 323 charges the storage batteries 104 of the consumer facilities A11 and A12 with a charging power of 0 kW (that is, does not execute charging) in the division period T1 and demands. The storage batteries 104 of the house facilities B11 and B12 are set to be charged with a charging power of 2 kW (= 1 kW + 1 kW), respectively. As a result, the storage batteries 104 of the consumer facilities B11 and B12 can charge the demand-responsive surplus electric energy W31 and W32, respectively, together with the demand-responsive surplus electric energy of 1 kWh generated in the private facility. That is, the demand-responsive surplus electric energy W31 and W32 are accommodated in the consumer facilities B11 and B12, respectively.

Next, the electric power control plan formulation unit 323 similarly determines whether or not the electric power can be interchanged from the consumer facilities A11 and A12 to the consumer facilities B11 and B12 in the division period T2.
In the division period T2, the consumer facility B11 generates 2 kWh of demand-responsive surplus power equal to the rated power, and the consumer facility B12 also generates 2 kWh of demand-responsive surplus power equal to the rated power. In this case, since the storage batteries 104 of the consumer facilities B11 and B12 charge the demand-responsive surplus power equal to the rated power, it is impossible to charge the power more than the rated power.
Therefore, the electric power control plan formulation unit 323 determines that it is not possible to exchange electric power from the consumer facilities A11 and A12 to the consumer facilities B11 and B12 during the division period T2.
In this case, the power control plan formulation unit 323 charges the storage battery 104 of the consumer facility A11 with a charging power of 4 kW and the storage battery 104 of the consumer facility A12 with a charging power of 2 kW in the division period T2 as an operation schedule. The storage battery 104 of the consumer facility B11 is set to be charged with 2 kW of charging power, and the storage battery 104 of the consumer facility B12 is set to be charged with 2 kW of charging power. As a result, each of the storage batteries 104 of the consumer facilities A11, A12, B11, and B12 will be charged with the demand-responsive surplus power generated in the private facilities.

Next, the electric power control plan formulation unit 323 determines whether or not the electric power can be interchanged from the consumer facilities A11 and A12 to the consumer facilities B11 and B12 in the division period T3.
In the division period T3, the consumer facility A11 has 4 kW, the consumer facility A12 has 2 kW, and the surplus power corresponding to the demand is generated. In addition, the consumer facility B11 generates 1 kW, and the consumer facility B12 generates 2 kW of surplus power for demand. In this case, in the consumer facility B12, the surplus power corresponding to the demand is 2 kW, which is equal to the rated power, so that the storage battery 104 cannot be charged.
On the other hand, in the consumer facility B11, since the demand-corresponding surplus power is 1 kW with respect to the rated power of 2 kW, further 1 kW can be charged. In this case, it is possible to accommodate 1 kWh of electric energy from both the consumer facilities A11 and A12 for the storage battery 104 of the consumer facility B11.
However, since the maximum storage capacity of the storage battery 104 in the consumer facility A12 is 3 kW, 1 kWh of the demand-responsive surplus electric energy W33 of the generated 2 kWh demand-responsive surplus electric energy can be charged at the private facility. It cannot be done and becomes excess power.
On the other hand, in the consumer facility A11, the storage capacity of the storage battery 104 is 4 kWh at the end of the division period T2, and 6 kWh can be stored. That is, in the consumer facility A11, the storage battery 104 can be charged with the demand-corresponding surplus electric energy of 4 kWh generated in the division period T3.
Therefore, the electric power control plan formulation unit 323 in this case determines that the 1 kWh demand-corresponding surplus electric energy W33, which is the excess power in the consumer facility A12, can be accommodated in the consumer facility B11. According to this determination result, the power control plan formulation unit 323 charges the storage battery 104 of the consumer facility A11 with a charging power of 4 kW and the storage battery 104 of the consumer facility A12 with 1 kW in the division period T3 as an operation schedule. It is set to charge with charging power, charge the storage battery 104 of the consumer facility B11 with charging power of 2 kW (= 1 kW + 1 kW), and charge the storage battery 104 of the consumer facility B12 with charging power of 2 kW. As a result, 1 kWh of surplus electric energy W33 for demand is accommodated from the consumer facility A12 to the consumer facility B11.

Next, the electric power control plan formulation unit 323 determines whether or not the electric power can be interchanged from the consumer facilities A11 and A12 to the consumer facilities B11 and B12 in the division period T4.
At the stage when the division period T3 is completed, the storage capacity of the consumer facility B11 is 6 kWh, which has reached the maximum storage capacity. Therefore, the electric power control plan formulation unit 323 determines that it is impossible to exchange electric power with the consumer facility B11 in the division period T4 following the division period T3. On the other hand, in the consumer facility B12, no surplus power for demand is generated during the division period T4. Further, since the storage capacity of the storage battery 104 of the consumer facility B12 at the end of the division period T3 is 6kWh and 1kWh can be stored, it is possible to charge at a maximum of 1kW in one hour as the division period T4. Is.
On the other hand, in the division period T4, the demand-responsive surplus power of the consumer facilities A11 and A12 is 2 kW and 1 kW, respectively. In this case, it is possible to accommodate 1 kWh of electric energy from both the consumer facilities A11 and A12 for the storage battery 104 of the consumer facility B12.
However, since the maximum storage capacity of the storage battery 104 in the consumer facility A12 is 3 kWh, the generated 1 kWh chargeable surplus electric energy W34 (in this case, which is also the demand-responsive surplus electric energy) should be charged in the private facility. It becomes excess power without being able to do it.
On the other hand, in the consumer facility A11, the storage capacity of the storage battery 104 is 8 kWh at the end of the division period T3, and 2 kWh can be stored. That is, in the consumer facility A11, the storage battery 104 can be charged with the demand-corresponding surplus electric energy of 2 kWh generated in the division period T4.
On the other hand, since the storage capacity of the storage battery 104 of the consumer facility B11 has reached the maximum storage capacity of 6 kWh at the end of the division period T3, it cannot be charged any more.
Therefore, the power control plan formulation unit 323 in this case determines that the 1 kWh chargeable surplus electric energy W34, which is the excess power in the consumer facility A12, can be accommodated in the consumer facility B12. According to this determination result, the power control plan formulation unit 323 charges the storage battery 104 of the consumer facility A11 with a charging power of 2 kW and the storage battery 104 of the consumer facility A12 with 0 kW in the division period T4 as an operation schedule. Charging with charging power, the storage battery 104 of the consumer facility B11 is set to be charged with 0 kW of charging power, and the storage battery 104 of the consumer facility B12 is set to be charged with 1 kW of charging power. As a result, 1 kWh of surplus electric energy W34 for charging is accommodated from the consumer facility A12 to the consumer facility B12.

An example of a processing procedure executed by the power management device 300 of the present embodiment regarding the formulation of an operation schedule will be described with reference to the flowchart of FIG. The process of FIG. 8 may be applied as the process of step S111 of FIG.
In the following, the case where the processing procedure example of FIG. 11 is the processing in step S111 of FIG. 8 will be taken as an example. When the processing procedure example of FIG. 11 is applied as the processing of step S111 of FIG. 8, the processing of steps S108 to S110 of FIG. 8 is omitted because it is not necessary to specify the excess power section in advance. Good.

Step S201: In the power management device 300, the power control planning unit 323 determines that all the consumer facilities are the receiving consumer facilities (no surplus power for charging is generated) as the classification result by the processing of steps S101 to S107 in FIG. Determine if it was classified as a consumer facility).

Step S202: When it is determined that all the consumer facilities are the receiving consumer facilities, the power control planning unit 323 sets the operation schedule as a demand response surplus generated for each target section at each consumer facility. The charging power of the storage battery 104 is set so that the power is charged.

Step S203: If not all consumer facilities are classified as beneficiary facilities in step S201, the group of consumer facilities classified includes supply consumer facilities and beneficiary consumer facilities. It will be. In this case, the power control planning unit 323 selects one target section from the target sections in the order of earliest time.

Step S204: Next, the power control planning unit 323 determines whether or not it is possible to accommodate the surplus power corresponding to the demand from the supply consumer facility to the receiving consumer facility in the target section selected in step S203. judge.
Step S205: When it is determined that the surplus power corresponding to the demand can be accommodated from the supply consumer facility to the receiving consumer facility, the power control plan formulation unit 323 receives the receiving consumer from the receiving consumer facility of the accommodating source. Calculate the amount of power that can be accommodated in the facility.
Step S206: The electric power control planning unit 323 sets the supply consumer facility and the receiving consumer facility as the operation schedule in the selected target section so that the electric energy calculated in step S205 is interchanged. The charging power of the storage battery 104 in each is set.
In the supply consumer facility, if the demand-response surplus power amount is larger than the charge power amount corresponding to the charge power set in step S206 in the selected target section, the charge power amount is subtracted from the demand-response surplus power amount. The amount of electricity generated is reversed.
Further, in the receiving consumer facility, the storage battery 104 performs a charging operation with the set charging power in the selected target section, so that the reverse power flow is charged when the reverse power flow is performed from the supply consumer facility. It will be. At this time, if the reverse power flow power is smaller than the charging power set in the receiving consumer facility (including the case where the reverse power flow power is zero), the receiving customer facility has the power difference of the reverse power flow power with respect to the charging power. The storage battery 104 is charged with the amount of electric power corresponding to the above.

Step S207: When it is determined in step S204 that the surplus power corresponding to the demand from the supply consumer facility to the receiving consumer facility cannot be accommodated, the power control planning unit 323 provides the opposite accommodation to step S204. It is determined whether or not it is possible to accommodate surplus electricity for demand from the receiving consumer facility to the supplying consumer facility.
Step S208: When it is determined that the surplus power corresponding to the demand from the receiving consumer facility to the supplying consumer facility can be accommodated, the power control planning unit 323 supplies the accommodating destination from the receiving consumer facility of the accommodating source. Calculate the amount of power that can be accommodated in the consumer facility.
Step S209: The electric power control planning unit 323 sets the supply consumer facility and the receiving consumer facility as an operation schedule in the selected target section so that the electric energy calculated in step S208 is accommodated. The charging power of the storage battery 104 in each is set.

Step S210: If it is determined in step S207 that the surplus power for demand cannot be accommodated from the receiving consumer facility to the supplying consumer facility, the supply consumer facility and the receiving consumer facility may be in either direction. It means that the electric power cannot be accommodated.
In this case, the power control planning unit 323 requests that the demand-responsive surplus power be charged to the consumer facility in which the storage battery 104 of the demand-responsive surplus power can be charged at the private facility. Set the charging power to. Further, for the consumer facility where the storage battery 104 of the demand-responsive surplus power cannot be charged at the private facility, the demand-responsive surplus power is reverse-flowed as excess power. The excess power that is reversely flowed in this way is not particularly charged to the storage battery 104 of another consumer facility.

Step S211: After the process of step S206 or step S210, the power control planning unit 323 determines whether or not the setting of the charging power of each customer facility in all the target sections is completed.
If the target section in which the charging power of the consumer facility is not set remains, the process is returned to step S203. When the setting of the charging power of the consumer facility is completed, the processing shown in the figure is completed.

In each of the above embodiments, the consumer facility as the power interchange source and the consumer facility as the interchange destination are not limited to a one-to-one relationship, and may be one-to-many or many-to-one. There may be.
Since the operation schedule of the storage battery 104 formulated as in each of the above embodiments corresponds to the accommodation of the surplus power corresponding to the demand, the storage battery 104 of the customer facility of the accommodation source and the accommodation destination is charged. Explains electric power. However, under each of the above embodiments, for example, in a target section where charging is not specified for the storage battery 104, the content of discharging the storage battery 104 with a certain discharge power for supplying power to the load 105 of the private facility is operated. May be included in the schedule.

<Modified example of the second embodiment>
In the second embodiment, the operation schedule is formulated so that if there is a demand-responsive surplus power that can be accommodated from the supply consumer facility to the storage battery 104 of the receiving consumer facility in order from the first target section, the operation schedule is always accommodated. Is being done. On top of that, while the stored electric energy of the storage battery 104 of the receiving consumer facility has reached the maximum stored capacity, the stored electric energy of the storage battery 104 of the supplying consumer facility has not reached the maximum stored capacity and is in a rechargeable state. In this section, surplus electricity corresponding to the demand of the receiving consumer facility may be supplied to the supplying consumer facility side.
On the other hand, in this modification, the total amount of excess power generated in the supply consumer facility (unit total excess power amount) in a predetermined number of consecutive division periods (unit continuous division period) is obtained and the corresponding response is taken. During the unit continuous division period, the operation schedule will be formulated so that the required unit total excess electric energy will be accommodated in the receiving facility. The unit continuous division period may correspond to a unit period, or may be a period in which a part of the division periods in the unit period is continuous.

FIG. 12 shows an example of formulating an operation schedule in this modified example. In the figure, an example is shown in the case where the predicted surplus powers GA1-1 and GB1-1 are the same as those in FIG. Further, in the explanation of the figure, the case where the unit continuous division period is the division periods T1 to T4 will be taken as an example.

In this case, the power control plan formulation unit 323 of this modification obtains the total unit excess power generated in the consumer facility A1 which is the supply consumer facility during the target unit continuous division period (T1 to T4). The demand-responsive surplus power generated in the consumer facility A1 during the target unit continuous division period (T1 to T4) is 6 kWh, and the maximum storage capacity of the storage battery 104 is 4 kWh. Therefore, the power control plan formulation unit 323 calculates that the unit total excess power amount is 2 kWh (6 kWh-4 kWh).

Then, the electric power control planning unit 323 indicates that in the target unit continuous division period, for example, the division periods T1 to T4 are ordered according to the passage of time (in reverse order or random order with respect to the passage of time). The amount of surplus power for demand that can be accommodated from facility A1 to consumer facility B1 is calculated. Then, the power control plan formulation unit 323 sets the charging power of each storage battery 104 in the consumer facilities A1 and B1 in the corresponding division period so that the calculated surplus electric power corresponding to the demand can be accommodated. The power control planning unit 323 performs such processing until the total amount of interchanged power reaches the amount of power corresponding to the total amount of excess power per unit. The power control planning department 323 will not consider the power interchange from the consumer facility A1 to the consumer facility B1 for the subsequent division period, and will use the consumer facility A1 and the consumer facility B1 in-house. The charging power of each storage battery 104 in the consumer facilities A1 and B1 is set so that the generated surplus power corresponding to the demand is charged.
Specifically, in the example of the figure, first, the power control plan formulation unit 323 determines that the chargeable surplus electric energy W21 of 1 kWh can be accommodated in the division period T1. Therefore, the power control planning unit 323 sets a charging power of 1 kW for the storage battery 104 of the consumer facility A1 and a charging power of 2 kW for the storage battery 104 of the consumer facility B1 in accordance with the division period T1. Set. The total amount of interchangeable power at this stage is 1 kWh.

Next, the power control plan formulation unit 323 determines that the chargeable surplus electric energy W22 of 1 kWh can be accommodated in the division period T2. Therefore, the power control planning unit 323 sets a charging power of 1 kW for the storage battery 104 of the consumer facility A1 and a charging power of 4 kW for the storage battery 104 of the consumer facility B1 in accordance with the division period T2. Set. Then, the total amount of interchangeable electric energy at this stage is 2 kWh.
Therefore, in the subsequent division periods T3 and T4, the power control plan formulation department 323 will charge the customer facility so that the demand-responsive surplus power generated in the customer facilities A1 and B1 is charged to the own storage battery 104, respectively. The charging power of the storage batteries 104 of A1 and B1 is set.
That is, the power control plan formulation unit 323 sets the charging power of 2 kW for the storage battery 104 of the consumer facility A1 and sets the charging power of 3 kW for the storage battery 104 of the consumer facility B1 in the division period T3.
Further, the power control plan formulation unit 323 sets 1 kW of charging power for the storage battery 104 of the consumer facility A1 and 1 kW of charging power for the storage battery 104 of the consumer facility B1 in the division period T4.

By formulating the operation schedule of this modified example as well, it is possible to effectively perform power interchange in response to the restrictions on the rated power of the storage battery 104 and the maximum storage capacity.

An example of a processing procedure executed by the power management device 300 of the present embodiment regarding the formulation of an operation schedule will be described with reference to the flowchart of FIG. The process of FIG. 8 may be applied as the process of step S111 of FIG.
In the following, the case where the processing procedure example of FIG. 13 is the processing in step S111 of FIG. 8 will be taken as an example. When the processing procedure example of FIG. 13 is applied as the processing of step S111 of FIG. 8, the processing of steps S108 to S110 of FIG. 8 is omitted because it is not necessary to specify the excess power section in advance. Good.

The processing of steps S2101 and S2102 may be the same as the processing of steps S201 and S202 of FIG.

Step S2103: If not all consumer facilities are classified as beneficiary facilities in step S201, the group of consumer facilities classified includes supply consumer facilities and beneficiary consumer facilities. It will be.
In this case, the power control planning unit 323 calculates the total excess power generated in the unit continuous division period. The power control planning unit 323 sets the calculated total excess power as the current total remaining excess power.

Step S2104: The power control planning unit 323 selects one target section from the division periods in the unit continuous division period in order of earliest time.

Step S2105: Next, the power control planning unit 323 determines whether or not the current total residual power amount is greater than zero for the target section selected in step S2104. The residual total excess power amount is a value obtained by subtracting the total of the flexible power amount calculated each time step S2107 is executed from the current total residual power amount.

Step S2106: When the total residual power amount is larger than zero, the power control planning unit 323 accommodates the demand-responsive surplus power from the supply consumer facility to the receiving consumer facility in the target section selected in step S2104. Is possible or not.
Step S2107: When it is determined that the surplus power corresponding to the demand can be accommodated from the supply consumer facility to the receiving consumer facility, the power control planning unit 323 determines that the receiving consumer of the accommodation source to the receiving consumer facility. Calculate the amount of power that can be accommodated in the facility. In this case, the power control planning unit 323 may calculate the interchangeable electric energy so as not to cause the result that the residual total excess electric energy becomes smaller than zero.
Step S2108: The power control planning unit 323 updates the remaining total excess power amount by subtracting the flexible power amount calculated in this step S2107 from the current total residual power amount.

Step S2109: When it is determined in step S2105 that the total residual power amount is not greater than zero (that is, it is zero), or when it is determined in step S2106 that the demand-responsive surplus power cannot be accommodated. Alternatively, after the process of step S2108, the power control planning unit 323 executes the following process. That is, the power control plan formulation unit 323 sets the charging power of the storage battery 104 in each of the supply consumer facility and the receiving consumer facility.
If it is determined in step S2105 that the total residual power amount is not greater than zero, or if it is determined in step S2106 that the surplus power for demand cannot be accommodated, the supply consumer facility receives the receiving consumer. There is no power interchange to the facility. In such a case, the power control plan formulation unit 323 sets the charging power of the storage battery 104 in each of the supply consumer facility and the receiving consumer facility so that the demand response surplus power generated in-house is charged.
Further, when the process of step S2108 is performed, the charging power of the storage battery 104 in each of the supply consumer facility and the receiving consumer facility is set so that the electric energy calculated in step S2107 is interchanged. To do.

Step S2110: After the process of step S2109, the power control planning unit 323 determines whether or not the setting of the charging power of each consumer facility in all the target sections is completed.
If the target section in which the charging power of the consumer facility is not set remains, the process is returned to step S2104. When the setting of the charging power of the consumer facility is completed, the processing shown in the figure is completed.

<Third Embodiment>
Subsequently, the third embodiment will be described. As a result of accommodating the surplus power shown in each figure in each of the above embodiments, a pattern is shown in which the excess power generated in the supply consumer facility of 1 is eliminated by the accommodation to the receiving consumer facility.
However, even if the operation schedule is formulated and the operation is controlled as in each of the above embodiments, for example, the power generation device 103 generates considerably more power generation than expected, so that the supply consumer facility The excess power generated in the above may not be eliminated.

FIG. 14 shows an example in which the excess power generated in the supply consumer facility is not eliminated as described above.
The figure conforms to the example of FIG. That is, in the figure, an example is shown in which the supply consumer facilities are the consumer facilities A11 and A12, and the receiving consumer facilities are the consumer facilities B11 and B12.
Further, in the figure, the consumer facilities A11, A12, B11, and B12 are obtained by performing the operation control according to the established operation schedule, and the consumer facilities A11 and A12 and the consumer facilities are obtained. The results of power interchange between B11 and B12 (GA11-11, GA12-11, GB11-11, GB12-11) are shown.
Further, the constraint conditions (maximum storage capacity, rated power) of the storage battery 104 in each of the consumer facilities A11, A12, B11, and B12 are the same as in FIG. That is, the storage battery 104 of the consumer facility A11 has a maximum storage capacity of 10 kWh and a rated power of 4 kW. The storage battery 104 of the consumer facility A12 has a maximum storage capacity of 3 kWh and a rated power of 2 kW. The storage battery 104 of the consumer facility B11 has a maximum storage capacity of 6 kWh and a rated power of 2 kW. The storage battery 104 of the consumer facility B12 has a maximum storage capacity of 7 kWh and a rated power of 2 kW.
Further, also in the figure, the case where the SOC of each storage battery 104 of the consumer facilities A11, A12, B11, and B12 is 0% at the start of the division period T1 is taken as an example.

The surplus power pattern shown in FIG. 10 differs from the surplus power pattern shown in FIG. 10 in the following points. That is, it is different from the surplus power pattern of FIG. 10 in that, in the division period T4, the consumer facility A11 further generates a charge-corresponding surplus electric energy W35 of 2 kWh.

Then, in the figure, the same operation schedule as in the case of FIG. 10 is formulated, and the surplus power pattern showing the result of performing the operation control according to the formulated operation schedule is shown.
That is, in the division period T1, the 1 kWh of surplus electric energy W31 generated at the consumer facility A11 and the 1 kWh surplus electric energy W32 generated at the consumer facility A12 are the consumer facility B11. It was accommodated as if the storage battery 104 of B12 was charged.
Further, in the division period T3, 1 kWh of surplus electric energy W33 generated in the consumer facility A12 was accommodated as being charged in the storage battery 104 of the consumer facility B11.

Further, in the division period T4, the consumer facility A11 generates a chargeable surplus electric energy W35 of 2 kWh, and the consumer facility A12 generates a chargeable surplus electric energy W34 of 1 kWh. Since the storage batteries 104 of the consumer facilities A11 and B11 are already fully charged at the stage when the division period T4 is reached, they are not charged, so that the surplus electric energy W35 and W34 corresponding to charging are reverse-fed. ..
In this way, during the division period T4, a total of 3 kWh of surplus power for charging is reverse-flowed at the consumer facilities A11 and A12, while a 1 kWh charging power amount W36 is transferred to the storage battery 104 at the consumer facility B12. It is charging.

As in the division period T4 in the figure, when the chargeable surplus power on the supply consumer facility side is larger than the rechargeable capacity (free capacity) of the storage battery 104 on the receiving consumer facility side in one division period, During the division period, the supply-demand facility side generated inflexible excess power that remained unflexible (cannot be resolved). Specifically, in the division period T4 in the figure, 1 kWh was accommodated out of the total 3 kWh of surplus electric energy for charging generated in the consumer facilities A11 and A12, but 2 kWh was used as the inflexible excess electric energy. Occurred.
In this case, in the division period T4, the 1kWh charging electric energy W36 accommodated in the consumer facility B12 is partially accommodated in a total of 3kWh of surplus electric energy for charging, which is reverse power flowed from the consumer facilities A11 and A12. You can think of it as a thing.
In addition, considering the price setting according to the actual power interchange between consumer facilities, it is preferable that the breakdown of the power interchanged from multiple supply consumer facilities to one receiving consumer facility is appropriately determined. ..

Therefore, in the present embodiment, as in the example of the figure, when the chargeable surplus power on the supply consumer facility side is larger than the rechargeable capacity (free capacity) of the storage battery 104 on the receiving consumer facility side, there are a plurality of cases. The breakdown of the electricity supplied from the supply consumer facility to the receiving consumer facility 1 is defined as follows. That is, in the present embodiment, it is determined that the electric energy is evenly distributed from each of the plurality of supply consumer facilities to one beneficiary consumer facility.

Specifically, in the figure, in the division period T4, for the charging electric energy W36 of 1 kWh accommodated in the consumer facility B12, 0.5 kWh obtained by dividing 1 kWh into two equal parts is accommodated by each of the consumer facilities A11 and A12. An example is shown as defined as.
That is, for the consumer facility A11, of the 2 kWh of surplus electric energy W35 for charging, 0.5 kWh of electric energy W351 is accommodated in the consumer facility B12, and the remaining 1.5 kWh of electric energy W352 is inflexible. The amount of excess power.
Regarding the consumer facility A12, of the 1 kWh of surplus electric energy W34 for charging, 0.5 kWh of electric energy W341 is accommodated in the consumer facility B12, and the remaining 0.5 kWh of electric energy W342 is inflexible. The amount of excess power.

In this way, by determining the breakdown of the power interchanged from multiple supply consumer facilities to the receiving consumer facility, the receiving consumer facility side supplies how much and what amount of the total amount of the accommodated power. The breakdown of whether or not it was accommodated from the consumer facility is determined. In addition, in the supply consumer facility, the breakdown of how much electricity is transferred to which receiving consumer facility and how much excess electricity is inflexible is determined.
In addition, in the present embodiment, it is effective to make the effective interchange power amount interchanged from the plurality of supply consumer facilities to one receiving consumer facility equal among the plurality of supply consumer facilities. We are trying to obtain the appropriateness for determining the amount of interchangeable power.

Further, contrary to the example of FIG. 14, there is a case where the rechargeable electric energy of the storage battery 104 of the receiving consumer facility is larger than the chargeable surplus electric energy of the supplying consumer facility side.
FIG. 15 shows an example in which the rechargeable electric energy of the storage battery 104 of the receiving consumer facility is larger than the chargeable surplus electric energy of the supplying consumer facility side as described above. There is.
In the figure, as in FIG. 14, an example is shown in which the supply consumer facilities are the consumer facilities A11 and A12 and the receiving consumer facilities are the consumer facilities B11 and B12. ..
In the figure, the consumer facilities A11, A12, B11, and B12 obtained by performing the operation control according to the established operation schedule for each of the consumer facilities A11, A12, B11, and B12. The results of power interchange with and from B12 (GA11-12, GA12-12, GB11-12, GB12-12) are shown.

The constraint conditions (maximum storage capacity, rated power) of the storage battery 104 in each of the consumer facilities A11, A12, B11, and B12 corresponding to the figure are as follows. That is, the storage battery 104 of the consumer facility A11 has a maximum storage capacity of 10 kWh and a rated power of 4 kW. The storage battery 104 of the consumer facility A12 has a maximum storage capacity of 3 kWh and a rated power of 2 kW. The storage battery 104 of the consumer facility B11 has a maximum storage capacity of 8 kWh and a rated power of 2 kW. The storage battery 104 of the consumer facility B12 has a maximum storage capacity of 7 kWh and a rated power of the inverter of 2 kW. That is, in comparison with the case of FIG. 14, the case where the maximum storage capacity of the storage battery 104 of the consumer facility B11 is 8 kWh instead of 6 kW is taken as an example.
Further, in the figure, the case where the SOC of each storage battery 104 of the consumer facilities A11, A12, B11, and B12 is 0% at the start of the division period T1 is taken as an example.

The surplus power pattern shown in FIG. 14 differs from the surplus power pattern shown in FIG. 14 in the following points. That is, the 2kWh chargeable surplus electric energy W35 generated in the consumer facility A11 in the division period T4 in FIG. 14 is not generated in the figure.
Then, in the figure, the operation schedule is the same as in the case of FIG. 14 in the division periods T1 to T3, and is formulated as follows in the division period T4.
That is, in the example of FIG. 14, since the storage battery 104 of the consumer facility B11 was already in a fully charged state at the stage when the division period T3 ended, the storage battery 104 was not charged in the division period T4. It was.
On the other hand, in the case of the figure, when the division period T4 is started, the storage battery 104 of the consumer facility B11 has a margin of 2 kWh with respect to the maximum storage capacity of 8 kWh. Therefore, the figure shows an example in which the operation schedule is set so that the storage battery 104 of the consumer facility B11 charges 2 kWh in the division period T4. Further, in the division period T4 of the consumer facility B12, an example in which the operation schedule is set so that the storage battery 104 charges 1 kWh is shown as in the case of FIG.

As a result, in the division period T1, the 1 kWh of surplus electric energy W31 generated at the consumer facility A11 and the 1 kWh surplus electric energy W32 generated at the consumer facility A12 are combined with the consumer facility B11. , B12 storage battery 104 was accommodated as charged.
Further, in the division period T3, 1 kWh of surplus electric energy W33 generated in the consumer facility A12 was accommodated as being charged in the storage battery 104 of the consumer facility B11.

Further, in the division period T4, a charge-corresponding surplus electric energy W34 of 1 kWh was generated at the consumer facility A12. In the division period T4, since the storage battery 104 of the consumer facility A12 is already in a fully charged state and is not charged, the chargeable surplus electric energy W34 is reverse power flow.
In this way, during the division period T4, a total of 1 kWh of surplus power for charging was reverse-fed on the supply consumer facility side. On the other hand, on the receiving consumer facility side, at the timing when the division period T4 is started, the total chargeable capacity (free capacity) of 2 kWh in the consumer facility B11 and the chargeable capacity of 1 kWh in the consumer facility B12 are 3 kWh in total. There was a rechargeable capacity. Then, over the division period T4, charging was performed for a total rechargeable capacity of 3 kWh.

In this case, in the division period T4, the chargeable surplus electric energy W34 reversely flowed from the consumer facility A12 is accommodated so as to be included in the total of 3 kWh charged in the storage battery 104 on the consumer facilities B11 and B12 sides. You can think of it as a thing. Even in such a case, as in the case of FIG. 14, it is preferable that the breakdown of the electric power interchanged from one supply consumer facility to the plurality of receiving consumer facilities is appropriately determined.

Therefore, in the present embodiment, when the rechargeable surplus power on the supply consumer facility side is smaller than the rechargeable capacity (free capacity) of the storage battery 104 on the receiving consumer facility side, a plurality of supply consumer facilities from one supply consumer facility. The breakdown of the electricity supplied to the receiving consumer facilities is defined as follows. That is, in the present embodiment, it is determined that the electric power reverse-fed by one supply consumer facility is evenly distributed to a plurality of receiving consumer facilities.

Specifically, in the figure, in the division period T4, the electric energy of 0.5 kWh, which is one of the two equal parts of the 1 kWh of surplus electric energy for charging W34 reverse tide from the consumer facility A12. It is assumed that W342 is accommodated in the consumer facility B11 and another 0.5 kWh of electric energy W341 is accommodated in the consumer facility B12.

In this way, by determining the breakdown of the power interchanged from multiple supply consumer facilities to the receiving consumer facilities, and for the supply consumer facilities, how much electricity is interchanged to which receiving consumer facility. A breakdown of what has been done is determined. With respect to the receiving consumer facility, the breakdown of how much of the electric energy charged in the storage battery 104 is accommodated from the supplying consumer facility and is the electric energy other than the accommodating is determined.
In this case as well, the effective interchangeable electric energy that is interchanged from one supply consumer facility to the plurality of recipient consumer facilities is made equal among the plurality of recipient consumer facilities. We are trying to obtain the appropriateness of the decision.

FIG. 16 shows a configuration example of the power management device 300 of the present embodiment. In the figure, the same parts as those in FIG. 7 are designated by the same reference numerals and the description thereof will be omitted.
The power management device 300 in the figure further includes an effective interchange power determination unit 325 in the control unit 302.
The effective interchange power determination unit 325 uses the rechargeable surplus power (an example of surplus power) that has been reverse-flowed for each supply consumer facility to charge the storage battery 104 of the receiving consumer facility (an example of demand power). Determine the effective interchangeable power amount to be used as. Specifically, the effective interchange power is the power amounts W341 and W351 in FIG. 14, the power amounts W341 and W342 in FIG. 15, and the like. In the present embodiment, the effective interchange power is treated as an electric energy rather than a power value.

Further, the power management device 300 in the figure further includes a power breakdown information storage unit 334 in the storage unit 303.
The power breakdown information storage unit 334 stores the power breakdown information reflecting the determination result of the effective interchange power by the effective interchange power determination unit 325 for each consumer facility 100.
As the power breakdown information corresponding to the consumer facility 100 of 1, for example, the amount of interchangeable power, the amount of inflexible excess power, and the amount of interchanged power for each unit period may be shown. Further, the power breakdown information may indicate the amount of interchangeable power, the amount of excess power that cannot be accommodated, and the amount of power to be accommodated for each predetermined time such as a division period in one unit period.

With reference to the flowchart of FIG. 17, an example of a processing procedure executed by the power management device 300 of the present embodiment in relation to the determination of the effective interchange power (effective interchange power amount) will be described.
Step S301: In the power management device 300, the effective interchange power determination unit 325 stores the power management record for a certain period in the past, which is the target of determining the effective interchange power amount, in the power management record storage. Obtained from unit 333. In the following description, in step S301, a case where the power management record for a predetermined unit period is acquired as the power management record for a certain period will be taken as an example.

Step S302: The effective interchangeable power determination unit 325 selects one division period in the unit period as the determination target (target division period) of the effective interchangeable power. Each time the process of step S302 is repeated, for example, the first to last division period in the unit period may be sequentially selected as the target division period.

Step S303: The effective interchange power determination unit 325 receives the consumer facility 100 included in the power management area 10 as the supply consumer facility in the target classification period based on the power management results of the classification period selected in step S302. Classify as one of consumer facilities. Then, the effective interchange power determination unit 325 determines whether or not the chargeable surplus power on the supply consumer facility side is equal to or greater than the rechargeable capacity on the receiving consumer facility side during the target classification period.

Step S304: When it is determined in step S303 that the chargeable surplus power on the supply consumer facility side is equal to or greater than the rechargeable capacity on the receiving consumer facility side, the effective interchange power determination unit 325 executes the following processing. .. That is, the effective interchange power determination unit 325 divides the charge power amount of the receiving consumer facility into equal parts. At this time, when there are a plurality of receiving consumer facilities, the effective interchange power determination unit 325 may equally divide the total value of the charging electric energy of the plurality of receiving consumer facilities, for example.

Step S305: The effective interchange power determination unit 325 sets the charge power amount equally divided by step S304 as the effective interchange power amount that each of the supply consumer facilities in the target classification period accommodates the receiving consumer facility.

Step S306: When it is determined in step S303 that the chargeable surplus power on the supply consumer facility side is less than the rechargeable capacity on the receiving consumer facility side, the effective interchange power determination unit 325 executes the following processing. To do. That is, the effective interchange power determination unit 325 divides the charge-corresponding surplus power amount of the supply consumer facility into equal parts. At this time, when there are a plurality of supply consumer facilities, the effective interchange power determination unit 325 may equally divide the total value of the chargeable surplus power of the plurality of supply consumer facilities, for example.

Step S307: The effective interchangeable power determination unit 325 sets the chargeable surplus electric energy equally divided by step S306 as the effective interchangeable electric energy interchanged from the supply consumer facility to the receiving consumer facility in the target classification period. ..

Step S308: After the process of step S305 or after the process of step S307, the effective interchange power determination unit 325 determines whether or not the process of determining the effective interchange power amount has been completed for all the division periods.
If there is still a division period that is not subject to the process of determining the effective accommodative electric energy, the process is returned to step S302.

Step S309: When the process of determining the effective accommodating electric energy for all the division periods is completed, the effective accommodating electric energy determination unit 325 reflects the determination result of the effective accommodating electric energy so far corresponding to the target unit period. Generates power breakdown information. The effective interchange power determination unit 325 stores the generated power breakdown information in the power breakdown information storage unit 334.

<Modified example of the third embodiment>
In the third embodiment described above, the effective interchange power amount from the plurality of supply consumer facilities to one receiving consumer facility is equally divided among the plurality of supply consumer facilities.
On the other hand, in this modification, the effective electric energy that is interchanged from each of the plurality of supply consumer facilities to one receiving consumer facility is accommodated among the plurality of supply consumer facilities to the supply consumer facility. It is determined so that the amount of power (unused power) that is reversely flowed to the system is the same (equal).
As a specific example, when the charge-corresponding surplus electric energy is generated as in the division period T4 of FIG. 14, for the consumer facility A11, 1 kWh of the charge-corresponding surplus electric energy of 2 kWh is the consumer facility B12. Set as the amount of effective interchange power to In this case, the storage battery 104 of the consumer facility A11 in the division period T4 is set with a charging power of 3 kW. As a result, in the consumer facility A11, an unused electric energy of 1 kWh is generated in the division period T4.
Further, for the consumer facility A12, the effective interchange power amount to the consumer facility B12 is set to 0 kWh out of the surplus electric energy corresponding to charging of 1 kWh. In this case, the storage battery 104 of the consumer facility A12 in the division period T4 is set to have a charging power of 0 kW. In this case, in the consumer facility A12, in the division period T4, 1 kWh of unused electric power is generated in which the reverse current flows but is not accommodated in the receiving consumer facility.
That is, in the above example, when the electric power is interchanged in the division period T4, the amount of unused electric power is the same between the consumer facilities A11 and A12 at 1 kWh.

<Fourth Embodiment>
Next, the fourth embodiment will be described. In the third embodiment described above, in determining the effective interchangeable electric energy, the charge electric energy of the receiving consumer facility or the chargeable surplus electric energy of the supply consumer facility is equally divided. On the other hand, the power management device 300 of the present embodiment distributes the charge power amount based on the ratio of the total amount of charge-corresponding surplus power between the supply consumer facilities in the past fixed period in determining the effective interchange power amount. To do. Further, the power management device 300 of the present embodiment distributes the chargeable surplus power based on the ratio of the total rechargeable capacity of the storage battery 104 between the receiving consumer facilities in the past fixed period in determining the effective interchange power amount. To do.

FIG. 18 shows an example in which the chargeable surplus power on the supply consumer facility side is equal to or greater than the rechargeable capacity on the receiving consumer facility side as an example of determining the effective interchange power amount in the present embodiment. In the figure, the result of the same power interchange result (GA11-13, GA12-13, GB11-13, GB12-13) as in FIG. 14 is shown.
Based on the result of the power interchange shown in the figure, the effective power interchange power determination unit 325 of the power management device 300 changes from the consumer facilities A11 and A12 to the consumer facility B12 in the division period T4 as follows. Determine the effective interchangeable power amount that is assumed to be accommodated.

First, the effective power interchange power determination unit 325 generated for each of the consumer facilities A11 and A12 in the past fixed period by using the information of the power management record in the past fixed period stored in the power management record storage unit 333. Calculate the total amount of surplus power for charging.
The past fixed period here is not particularly limited, but for example, the past one year, the past one month, the past one week, etc. may be set starting from the current date and time. Further, the fixed period in the past may be one day in the past, for example, yesterday. Further, the past fixed period may be a certain division period in the past, for example, the immediately preceding division period.

Next, the effective interchange power determination unit 325 calculates the ratio of the total amount of chargeable surplus power of the consumer facility A11 to the total amount of chargeable surplus power of the consumer facility A12. As a specific example, in the case of the figure, the ratio of the total amount of surplus electricity for charging of the consumer facility A11 to the total amount of surplus electricity for charging of the consumer facility A12 (ratio of total surplus electricity) is "2: It was "1".
The effective interchange power determination unit 325 distributes the charge power amount W36 charged to the storage battery 104 of the consumer facility B12 in the division period T4 by the distribution ratio according to the total surplus power amount ratio calculated as described above.
That is, the effective interchange power determination unit 325 distributes the charge power amount W36 to 2/3 kWh and 1/3 kWh according to the ratio of 2: 1. In the effective interchange power determination unit 325, of the charging electric energy W36 of 1 kWh, 2/3 kWh is the electric energy accommodated from the consumer facility A11, and 1/3 kWh is the electric energy accommodated from the consumer facility A12. To determine that.
In accordance with such a determination result, the effective interchange power determination unit 325 determines that the power amount W351 of 2/3 kWh is the effective interchange power amount for the consumer facility B12 with respect to the chargeable surplus electric energy W35 of 2 kWh in the division period T4. Yes, it is determined that the electric energy W352 of (1 + 1/3) kWh is an inflexible excess electric energy.
Further, in the effective interchange power determination unit 325, regarding the charge-corresponding surplus electric energy W34 of 1 kWh in the division period T4, the electric energy W341 of 1/3 kWh is the effective interchange power amount for the consumer facility B12, which is 2/3 kWh. It is determined that the electric energy W342 is an inflexible excess electric energy.

As described above, in the present embodiment, when the chargeable surplus electric energy on the supply consumer facility side is equal to or greater than the rechargeable capacity on the receiving consumer facility side, the total amount of chargeable surplus electric energy for each supply consumer facility The amount of effective interchange power is determined by distributing the charging power at the receiving consumer facility based on the ratio of. As a result, the effective interchangeable electric energy can be appropriately determined between the supply consumer facilities according to the surplus electric energy for charging.

Further, FIG. 19 shows an example in which the rechargeable capacity of the receiving consumer facility side is larger than the chargeable surplus power of the supplying consumer facility side as an example of determining the effective interchange power amount in the present embodiment. ing. In the figure, the same power interchange results as in FIG. 15 (GA11-14, GA12-14, GB11-14, GB12-14) are shown.
Based on the result of the power interchange shown in the figure, the effective power interchange power determination unit 325 of the power management device 300 changes from the consumer facility A12 to the consumer facilities B11 and B12 in the division period T4 as follows. Determine the effective interchangeable power amount that is assumed to be accommodated.

In this case, the effective interchange power determination unit 325 uses the information of the power management record for the past fixed period stored in the power management record storage unit 333 to store the storage batteries for each of the consumer facilities B11 and B12 in the past fixed period. The total amount of rechargeable capacity generated in 104 is calculated.
Next, the effective interchange power determination unit 325 calculates the ratio between the total rechargeable capacity of the consumer facility B11 and the total rechargeable capacity of the consumer facility B12. As a specific example, in the case of the figure, the ratio of the total rechargeable capacity of the consumer facility B11 to the total rechargeable capacity of the consumer facility B12 (ratio of total rechargeable capacity) is "3: 1". there were.
The effective interchange power determination unit 325 distributes the chargeable surplus electric energy W34 of the consumer facility A12 in the division period T4 by the distribution ratio according to the rechargeable capacity ratio calculated as described above.
That is, the effective interchange power determination unit 325 in this case distributes the chargeable surplus electric energy W34 to 3/4 kWh and 1/4 kWh according to the ratio of 3: 1. In the effective interchange power determination unit 325, of the 1 kWh chargeable surplus electric energy W34, 3/4 kWh is the effective interchange power amount for the consumer facility B11, and 1/4 kWh is the effective interchange power amount for the consumer facility B12. To determine that.
In accordance with such a determination result, the effective interchange power determination unit 325 accommodates 3/4 kWh of electric energy W342 from the consumer facility A12 out of the charging electric energy of 2 kWh consumer facility B11 in the division period T4. It is determined that the effective interchangeable electric energy is derived from the remaining (1 + 1/4) kWh of electric energy other than the effective interchangeable electric energy such as the purchase of electric power from the system (commercial power supply line DL).
Further, in the effective interchange power determination unit 325, 1/4 kWh of the electric energy W341 of the charge electric energy of the consumer facility B12 of 1 kWh in the division period T4 is the effective interchange power amount accommodated from the consumer facility A12. , It is determined that the remaining 3/4 kWh of electric energy is derived from other than the effective interchangeable electric energy.

As described above, in the present embodiment, when the rechargeable capacity of the receiving consumer facility side is larger than the chargeable surplus power of the supplying consumer facility side, the total rechargeable capacity of each receiving consumer facility side is large. The amount of effective power interchanged at the receiving consumer facility is determined by distributing the rechargeable capacity at the supplying consumer facility based on the ratio of. As a result, it is possible to appropriately determine the effective interchangeable electric energy that is assumed to have been accommodated from the supply consumer facility according to the rechargeable capacity of the storage battery 104 between the receiving consumer facilities.

With reference to the flowchart of FIG. 20, an example of a processing procedure executed by the power management device 300 of the present embodiment in relation to the determination of the effective interchange power (effective interchange power amount) will be described. The configuration of the power management device 300 of this embodiment may be the same as that shown in FIG.

Step S401: In the power management device 300, the effective interchange power determination unit 325 stores the power management record for a certain period in the past, which is the target of determining the effective interchange power amount, in the power management record storage. Obtained from unit 333. In this case as well, as in the case of the processing procedure example of FIG. 17, in step S401, the case where the power management record for a predetermined unit period is acquired as the power management record for a certain period is taken as an example.

Step S402: The effective interchange power determination unit 325 selects one division period in the unit period as the determination target (target division period) of the effective accommodation power.

Step S403: The effective power interchange power determination unit 325 sets the consumer facility 100 as either the supply consumer facility or the receiving consumer facility in the target classification period based on the power management results of the classification period selected in step S402. Classify into. Then, the effective interchange power determination unit 325 determines whether or not the chargeable surplus power on the supply consumer facility side is equal to or greater than the rechargeable capacity on the receiving consumer facility side during the target classification period.

Step S404: When it is determined in step S403 that the chargeable surplus power on the supply consumer facility side is equal to or greater than the rechargeable capacity on the receiving consumer facility side, the effective interchange power determination unit 325 executes the following processing. .. That is, the effective interchange power determination unit 325 calculates the total amount of surplus power for charging for each supply consumer facility in the past fixed period (unit period).
Step S405: Next, the effective interchange power determination unit 325 calculates the ratio of the total amount of chargeable surplus power for each supply consumer facility (total surplus power ratio) calculated in step S404. Then, the effective interchange power determination unit 325 distributes the charge power amount of the receiving consumer facility by the distribution ratio based on the calculated total surplus power amount ratio. At this time, when there are a plurality of receiving consumer facilities, the effective interchange power determination unit 325 may distribute, for example, the total value of the charging electric energy of the plurality of receiving consumer facilities.

Step S406: The effective interchange power determination unit 325 allocates each of the charging power amounts distributed in step S405 to each of the corresponding supply consumer facilities. The effective interchange power determination unit 325 determines the charge power amount distributed and allocated in this way as the effective interchange power amount interchanged from each of the supply consumer facilities to the receiving consumer facility during the target classification period.

Step S407: When it is determined in step S403 that the chargeable surplus power on the supply consumer facility side is less than the rechargeable capacity on the receiving consumer facility side, the effective interchange power determination unit 325 executes the following processing. To do.
That is, the effective interchange power determination unit 325 calculates the total amount of chargeable capacity for each recipient facility in the past fixed period (unit period).
Step S408: Next, the effective interchange power determination unit 325 calculates the ratio of the total rechargeable capacity for each recipient facility (total rechargeable capacity ratio) calculated in step S407. Then, the effective interchange power determination unit 325 distributes the chargeable surplus power amount of the supply consumer facility by the distribution ratio based on the calculated total rechargeable capacity ratio. At this time, when there are a plurality of supply consumer facilities, the effective interchange power determination unit 325 may distribute, for example, the total value of the chargeable surplus power of the plurality of supply consumer facilities.

Step S409: The effective interchange power determination unit 325 allocates each of the chargeable surplus powers distributed in step S408 to each of the corresponding consumer facilities. The effective interchange power determination unit 325 determines the charge-corresponding surplus electric energy thus distributed and allocated as the effective interchange power amount interchanged from the supply consumer facility to the receiving consumer facility during the target classification period. ..

Step S410: After the process of step S406 or after the process of step S409, the effective interchange power determination unit 325 determines whether or not the process of determining the effective interchange power amount has been completed for all the division periods.
If there is still a division period that is not subject to the process of determining the effective interchange power amount, the process is returned to step S402.

Step S411: When the process of determining the effective interchangeable power amount for all the division periods is completed, the effective interchangeable power determination unit 325 reflects the determination result of the effective interchangeable power amount so far corresponding to the target unit period. Generates power breakdown information. The effective interchange power determination unit 325 stores the generated power breakdown information in the power breakdown information storage unit 334.

<Modified example of the fourth embodiment>
In the fourth embodiment described above, when power is interchanged from a plurality of supply consumer facilities to one receiving consumer facility, it is based on the total amount of surplus power for charging for each supply consumer facility in the past fixed period. The distribution ratio of the interchangeable electric energy was determined for each of multiple supply and demand facilities.
However, as a modification of the fourth embodiment, the effective interchange power determination unit 325 is based on the total amount of demand-corresponding surplus power for each of a plurality of supply consumer facilities in the past fixed period, instead of the charge-corresponding surplus power amount. The amount of power interchanged by a plurality of supply and demand facilities may be determined by the distribution ratio. In this case, the distribution ratio may be set so that the supply consumer facility having a larger total amount of surplus electricity corresponding to demand has a larger amount of effective interchanged electric energy.
Alternatively, the effective interchange power determination unit 325 may determine the interchange power amount of the plurality of supply consumer facilities by the distribution ratio based on the total amount of the effective interchange power amount for each of the plurality of supply consumer facilities in the past fixed period. .. In this case, the distribution ratio may be set so that the larger the total amount of effective interchanged power is, the larger the amount of effectively accommodated power in this power interchange is.
Alternatively, the effective interchange power determination unit 325 determines the total amount of unused power for each of the plurality of supply consumer facilities in the past fixed period with respect to the amount of power interchanged from the plurality of supply consumer facilities to one receiving consumer facility. It may be determined by the distribution ratio based on. In this case, the effective interchange power determination unit 325 may set the distribution ratio so that the supply consumer facility having a larger amount of unused power has a larger amount of effective interchange power. On the contrary, the effective interchange power determination unit 325 may set the distribution ratio so that the effective interchange power amount is smaller as the supply consumer facility has a larger amount of unused power.
Alternatively, when the effective interchange power determination unit 325 accommodates power from a plurality of supply consumer facilities to one receiving consumer facility, the charge-corresponding surplus electric energy, the demand-corresponding surplus electric energy, or the effective interchange in a certain period in the past. The distribution ratio for the amount of unused electric power may be determined so that the larger the total amount of electric power is, the larger the amount of unused electric power is. In this case, the supply consumer facility of 1 accommodates the electric energy obtained by subtracting the unused electric energy from the chargeable surplus electric energy to the receiving consumer facility.

<Other modifications>
The configuration relating to the determination of the effective interchange power amount according to the third embodiment and the fourth embodiment may be executed under the state where the power interchange is performed. For example, the effective flexible power determination unit 325 calculates the amount of power that can be accommodated for the next classification period in the current classification period, and determines the charging power of each consumer facility based on the calculation result. Good.

The configuration relating to the determination of the effective interchange power amount according to the third embodiment or the fourth embodiment may be applied to the configuration of power interchange between consumer facilities other than the first embodiment and the second embodiment. For example, the configuration relating to the determination of the effective interchange power amount according to the third embodiment or the fourth embodiment can be applied to the following configuration of power interchange. That is, in the power management area, the power management server accepts the application from the customer who wants to accommodate the electric power and the application from the customer who wants to receive the power interchange. Then, based on the application, the power management device determines the reverse power flow power amount for each desired customer to be accommodated and the charging power for each desired customer to be accommodated in a predetermined period, and the determined reverse power flow power amount is determined. And control each consumer's equipment so that charging power can be obtained. Even under the configuration of the power interchange performed in this way, it is possible to determine the effective interchange power amount according to the third embodiment or the fourth embodiment with respect to the result of the power interchange.

In determining the effective interchangeable power amount according to the third embodiment or the fourth embodiment, the power interchanged from the supply consumer facility to the receiving consumer facility is only the power charged in the storage battery of the receiving consumer facility. Instead, it may be the demand power including the power consumed by the load at the same time.

The program for realizing the functions of the power management device 300 and the like described above is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read by the computer system and executed. The processing as the power management device 300 or the like may be performed. Here, "loading a computer system a program recorded on a recording medium and executing it" includes installing the program in the computer system. The term "computer system" as used herein includes hardware such as an OS and peripheral devices. Further, the "computer system" may include a plurality of computer devices connected via a network including a communication line such as the Internet, WAN, LAN, and a dedicated line. Further, the "computer-readable recording medium" refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, or a CD-ROM, or a storage device such as a hard disk built in a computer system. As described above, the recording medium in which the program is stored may be a non-transient recording medium such as a CD-ROM. The recording medium also includes an internal or external recording medium that can be accessed from the distribution server to distribute the program. The code of the program stored in the recording medium of the distribution server may be different from the code of the program in a format that can be executed by the terminal device. That is, the format stored in the distribution server does not matter as long as it can be downloaded from the distribution server and installed in a form that can be executed by the terminal device. The program may be divided into a plurality of parts, downloaded at different timings, and then combined by the terminal device, or the distribution server that distributes each of the divided programs may be different. Furthermore, a "computer-readable recording medium" is a volatile memory (RAM) inside a computer system that serves as a server or client when a program is transmitted via a network, and holds the program for a certain period of time. It shall include things. Further, the above program may be for realizing a part of the above-mentioned functions. Further, a so-called difference file (difference program) may be used, which can realize the above-mentioned functions in combination with a program already recorded in the computer system.

1 power management system, 10 power management area, 100 consumer facility, 101 power measurement unit, 103 power generation device, 104 storage battery, 105 load, 106 communication modem, 200 facility power management device, 300 power management device, 301 communication unit, 302 Control unit, 303 Storage unit, 321 Demand response surplus power acquisition unit, 322 Consumer facility classification unit, 323 Power control planning unit, 324 Power control unit, 325 Effective power interchange power determination unit, 331 Consumer facility information storage unit, 332 Power control plan storage unit, 333 Power management record storage unit, 334 Power breakdown information storage unit

Claims (9)

The surplus power of the supply consumer facility is interchanged with the receiving consumer facility between the supply consumer facility that reverse-flows the surplus power that is surplus in-house and the receiving consumer facility that causes the demand power to flow forward. It is a power management device that manages power according to the controlled area.
A power management device equipped with an effective interchange power determination unit that determines the effective interchange power that is assumed to have been used as the demand power of the receiving consumer facility among the surplus power that has been reverse-flowed for each supply consumer facility. The effective interchange power determination unit is
1 The power management device described in. The effective interchange power determination unit is
As a result of accommodating the power demand of one or more predetermined consumer facilities from each of the plurality of supply consumer facilities, the surplus power that is not interchanged in each of the plurality of supply consumer facilities is the same. The power management device according to claim 1, wherein the effective interchange power for each of a plurality of supply consumer facilities is determined. The effective interchange power determination unit is
The power demand of one or more predetermined consumer facilities is distributed by the distribution ratio set for each of the plurality of supply consumer facilities based on the total amount of surplus power in the past fixed period for each of the plurality of supply consumer facilities. The power management device according to claim 1, wherein each of the distributed powers is used as the effective interchange power of the corresponding supply consumer facility. The effective interchange power determination unit is
As a result of accommodating the power demand of one or more predetermined consumer facilities from each of the plurality of supply consumer facilities, the ratio of the surplus power that is not interchanged in each of the plurality of supply consumer facilities is a plurality of supplies. The power management device according to claim 1, wherein the effective interchange power for each of the plurality of supply consumer facilities is determined so as to correspond to the ratio of the total amount of surplus power for each customer facility in the past fixed period. The effective interchange power determination unit is
Each of the surplus electric power of one supply consumer facility is equally divided from the one supply consumer facility to each of the plurality of recipient facilities in response to each of the plurality of recipient facilities. The power management device according to any one of claims 1 to 5, which is an effective interchangeable power. The effective interchange power determination unit is
With the distribution ratio set for each of the plurality of recipient facilities based on the total amount of free capacity of the storage battery in the past fixed period for each of the plurality of recipient facilities, the surplus power of one supply consumer facility can be obtained from the plurality of supply consumer facilities. The power management device according to any one of claims 1 to 5, wherein each of the electric power distributed corresponding to each receiving consumer facility is an effective interchanged power accommodated for each corresponding receiving consumer facility. The surplus power of the supply consumer facility is interchanged with the receiving consumer facility between the supply consumer facility that reverse-flows the surplus power in-house and the receiving consumer facility that causes the demand power to flow forward. It is a power management method in a power management device that manages power according to the controlled area.
A power management method including an effective interchange power determination step for determining the effective interchange power that is assumed to be used as the demand power of the receiving consumer facility among the surplus power that has been reverse-flowed for each supply consumer facility. The surplus power of the supply consumer facility is interchanged with the receiving consumer facility between the supply consumer facility that reverse-flows the surplus power in-house and the receiving consumer facility that causes the demand power to flow forward. A computer as a power management device that manages power according to the controlled area,
A program for each supply consumer facility to function as an effective interchange power determination unit that determines the effective interchange power that is assumed to have been used as the demand power of the receiving consumer facility among the surplus power that has been reverse-flowed.

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