JP2019126152A - Power management device and program - Google Patents

Abstract

To provide a power management device and a program in which preservation of a storage battery in a state of high SOC is avoided as much as possible in an economy mode and self-supply of power is maintained as much as possible in a green mode.SOLUTION: A power management device 200 comprises: an excessive power predicting unit 2211 for predicting surplus power charged in a first storage battery without being supplied in a first customer facilities; an insufficient power predicting unit 2212 for predicting insufficient power that is a shortage of power consumption that can be supplied to a load in second customer facilities; an interchange power determining unit 2213 for determining interchange power to be supplied from the first customer facilities to the second customer facilities based on surplus power predicted by the excessive power predicting unit and insufficient power predicted by the insufficient power predicting unit; and a power control unit 222 for performing control so as to supply power by the determined interchange power.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a power management apparatus and program.

An operation mode called economy mode and an operation mode called green mode are known as operation modes of the power equipment in a consumer equipped with a storage battery (see, for example, Patent Document 1).
The economy mode is an operation mode in which the storage battery is charged in a predetermined time zone at night when the power rate is low, and the power stored in the storage battery is used for power consumption of the load. Such an economy mode is an operation mode that places importance on economy, since charging is actively performed in a time zone in which the electricity bill is as inexpensive as possible.
In the green mode, among the power generated by the solar cell in the daytime, for example, the storage battery is charged with surplus power that is surplus without being consumed by the load, and the power stored in the storage battery is consumed by the load, for example, at night It is an operation mode used for electricity and electricity sales. Such a green mode is an operation mode in which consideration is given to the natural environment, since the goal is to make it possible for a consumer to self-supply power used as much as possible.

JP, 2013-223316, A

In the economy mode, in order to obtain high economic efficiency, charging of the storage battery is usually performed until power in a predetermined time zone at night is fully charged or nearly fully charged. On the other hand, when the power stored in the storage battery is supplied to the load, the power may not be consumed sufficiently depending on the operating condition of the load. Therefore, the storage battery tends to be stored in a state of high SOC. The storage time is one of the causes of deterioration of the storage battery, but it is known that the degree of deterioration increases as the SOC is higher as the storage state.
On the other hand, in the green mode, the generated power of the solar cell may be reduced due to, for example, the weather, so that often enough electric power may not be stored in the storage battery. In this case, the power stored in the storage battery can not cover the power consumption, and the power generated by the storage battery is insufficient, and as a result, the opportunity to use the commercial power supply increases.

  The present invention has been made in view of such circumstances, and in the economy mode, storage of the storage battery in the high SOC state is avoided as much as possible, and in the green mode, self-sufficiency of power is maintained as much as possible. The purpose is

  One aspect of the present invention for solving the above-mentioned problems is to charge the first storage battery with the power of the commercial power supply in a predetermined charging target time zone and to supply the power charged in the first storage battery to the load. And a power generation apparatus configured to predict a surplus power surplus among the power charged in the first storage battery without being supplied to the first customer facility, and a power generation apparatus for the first customer facility performing the operation; The second consumer facility that operates to charge the second storage battery with the power generated by the second storage battery and supply the power stored in the second storage battery to the load at the second consumer facility. Based on the insufficient power prediction unit that predicts the insufficient power which is the shortage for the power consumption of the possible power, the surplus power predicted by the surplus power prediction unit, and the insufficient power predicted by the shortage power prediction unit , Power including: an interchange power determination unit that determines interchange power to be supplied from the first customer facility to the second consumer facility; and a power control unit that controls power supply by the determined interchange power to be performed It is a management device.

  One embodiment of the present invention operates the computer to charge the first storage battery with the power of the commercial power supply in a predetermined charging target time zone and to supply the power stored in the first storage battery to the load. And a surplus power prediction unit for predicting surplus power which is surplus among the power charged in the first storage battery without being supplied to the first storage battery, and power generated by the power generation apparatus. The power consumption of the electric power that can be supplied to the load at the second customer facility with respect to the second customer facility operating to charge the second storage battery and supply the electric power charged to the second storage battery to the load The first consumer service based on the insufficient power predicting unit that predicts the insufficient power corresponding to the power supply, the surplus power predicted by the surplus power predicting unit, and the insufficient power predicted by the insufficient power predicting unit; Interchange power determining unit for determining the flexibility power supplied to the second customer facility from the electric power supply by the determined power interchanged a program for functioning as a power control unit that controls to be performed.

  According to the present invention, in the economy mode, storage of the storage battery in a high SOC state is avoided as much as possible, and in the green mode, an effect is obtained that self-sufficiency of power is maintained as much as possible.

It is a figure showing an example of whole composition of a power control system in this embodiment. It is a figure which shows an example of the electric equipment with which the consumer facility in this embodiment is equipped. It is a figure which shows the structural example of the power management apparatus in this embodiment. It is a figure which shows the change of SOC of the storage battery in economy mode consumer facility and green mode consumer facility. It is a figure which shows an example of the storage degradation characteristic of a storage battery. It is a flowchart which shows the example of a processing procedure which the electric power management apparatus in this embodiment performs for electric power accommodation between an economy mode consumer facility and a green mode consumer facility.

[Configuration example of power management system]
FIG. 1 shows an example of the overall configuration of a power management system according to an embodiment of the present invention. The power management system in the present embodiment collectively manages power in customer facilities such as homes, commercial facilities, and industrial facilities corresponding to a plurality of consumers in a predetermined area range, for example. Such a power management system corresponds to what is called, for example, a Town Energy Management System (TEMS) or a Community Energy Management System (CEMS).

The power management system of the present embodiment performs power management on electric facilities provided for each of a plurality of customer facilities 10 in a certain area range shown as the power management area 1 in FIG. 1. In addition, the area range corresponding to the power management area 1 may be, for example, one area or a set of a plurality of geographically discrete areas.
The customer facility 10 corresponds to, for example, a house, a commercial facility, or an industrial facility. In addition, the power management area 1 may correspond to, for example, one or more apartment buildings, and each of the customer facilities 10 may be each door of the apartment complex.

The plurality of customer facilities 10 in the power management area 1 shown in the figure include the customer facilities 10 provided with solar cells that are renewable energy. Further, in the plurality of customer facilities 10 in the power management area 1, the customer facilities 10 including a storage battery as one of the electric facilities are included.
Among such customer facilities 10, there may be a customer facility 10 provided with both a solar cell and a storage battery, or there may be a customer facility 10 provided with any one of a solar cell and a storage battery. It is also good.

The commercial power source 2 is branched and supplied to each customer facility 10 in the power management area 1 by being connected to the common distribution network 3. Each customer facility 10 can supply the load with the power supplied from the distribution network 3. As a result, various electrical facilities (devices) as loads are operated.
Further, the customer facility 10 provided with the solar cell can output the generated power of the solar cell to the distribution network 3.
In addition, in the customer facility 10 including the storage battery, the storage battery can be charged (charged) by receiving the power supply from the distribution network 3. In addition, in the customer facility 10 including the storage battery and the solar battery, the storage battery can be charged with the generated power of the solar battery.

  Further, the position of the customer facility may not be limited to the same area as other customer facilities similarly managed as long as the power management system is configured to manage. That is, the power management system is registered as a customer facility under its own management, and if it can transmit and receive information to be managed using the network 300, a plurality of customer facilities registered in each of the discrete areas It may be a collection of In this case, the common distribution network 3 is a collection of power supply lines in the area connected to each of the customer premises 10.

  Further, the power management system 200 is provided in the power management system of the present embodiment. The power management apparatus 200 executes power control on the electric equipment in each customer facility 10 belonging to the power management area 1. For this purpose, the power management apparatus 200 in FIG. 1 is connected to be able to mutually communicate with each of the customer facilities 10 via the network 300. Thereby, the power management apparatus 200 can control the electrical installation in each customer facility 10.

Further, in the power management system of the present embodiment, the power management apparatus 200 classifies the customer facility 10 into one of the economy mode (EM) customer group GP1 and the green mode (GM) customer group GP2. Manage.
Therefore, the consumer is notified to the power management apparatus 200 which one of the economy mode and the green mode is set for the operation mode of the customer facility 10 to which the consumer corresponds. In the present embodiment, the consumer may arbitrarily determine which operation mode is to be set in the economy mode or the green mode.
Further, for the notification of the operation mode, for example, the customer may transmit notification information to the power management apparatus 200 by communication via a network using a terminal such as a personal computer or a smartphone.
The power management apparatus 200 manages the operation mode of the customer facility 10 so as to be classified into either the economy mode or the green mode in response to the notification of the operation mode from the customer.
By classifying the customer facilities 10 in this manner, the power management apparatus 200 sets either the economy mode customer facility group GP1 or the green mode customer facility group GP2 for the customer facilities 10 in the power management area 1. It can be managed as belonging.
In the following description, the consumer facility 10 whose operation mode is the economy mode is described as the economy mode consumer facility (an example of the first consumer facility) and the operation mode is the green mode (the second consumer facility). The consumer facility 10 may be described as a green mode consumer facility.

[Example of electrical equipment at customer premises]
Next, with reference to FIG. 2, an example of the electrical installation with which one customer facility 10 is provided will be described.
The customer facility 10 shown in the figure includes a solar cell 101, a power conditioner 102, a storage battery 103, an inverter 104, a power path switching unit 105, a load 106, and a facility-by-facility control unit 107 as electrical equipment.

The solar cell 101 is one of power generation devices using renewable energy, and converts light energy into electric power by the photovoltaic effect. The solar cell 101 converts sunlight into electric power by being installed at a place where sunlight can be efficiently received, such as the roof of the customer facility 10, for example.
The power conditioner 102 (an example of a power control device) controls and outputs the power generated by the solar cell 101. At this time, the power conditioner 102 converts direct current power output from the solar cell 101 into alternating current.

  The storage battery 103 stores the power input for charging, and discharges and outputs the stored power. For example, a lithium ion battery can be adopted as the storage battery 103.

The inverter 104 is provided corresponding to each of the plurality of storage batteries 103, and performs AC to DC conversion of power for charging the storage battery 103 or DC to AC conversion of power output by the storage battery 103 by discharging. That is, the inverter 104 performs bidirectional conversion of the power input / output to / from the storage battery 103.
Specifically, when the storage battery 103 is charged, AC power for charging is supplied from the commercial power supply 2 or the power conditioner 102 to the inverter 104 via the power path switching unit 105. The inverter 104 converts the alternating current power thus supplied into direct current, and supplies the direct current to the storage battery 103.
Further, when the storage battery 103 is discharged, direct-current power is output from the storage battery 103. The inverter 104 converts the direct current power output from the storage battery 103 into alternating current, and supplies the alternating current power to the power path switching unit 105.

The power path switching unit 105 switches the power path according to the control of the facility-based control unit 107. At this time, the facility control unit 107 can control the power path switching unit 105 in accordance with an instruction from the power management apparatus 200.
According to the above control, the power path switching unit 105 can form a power path so as to supply the commercial power source 2 to the load 106 in the same customer facility 10.

  Further, the power path switching unit 105 can form a power path so as to supply the power (generated power) generated by the solar cell 101 from the power conditioner 102 to the load 106 in the same customer facility 10.

  Further, the power path switching unit 105 forms a power path so as to charge the storage battery 103 via the inverter 104 with the power supplied from one or both of the commercial power supply 2 and the solar cell 101 in the same customer facility 10. Can.

  Further, the power path switching unit 105 can form a power path so as to supply the power output from the storage battery 103 by discharging in the same customer facility 10 to the load 106 via the inverter 104.

Furthermore, the power path switching unit 105 can form a power path so as to supply power generated by the solar cell 101 to storage batteries in another customer facility 10 via, for example, the distribution network 3.
In addition, the power path switching unit 105 can form a power path so as to supply the power output by the discharge of the storage battery 103 to the load 106 in another customer facility 10.

  Note that the power path switching unit 105 in the figure is a part configured to generate a power path according to control. However, the power path switching unit 105 may be, for example, merely a connection point of the power path of the power conditioner 102, the inverter 104, and the load 106.

  The load 106 collectively indicates devices, facilities, and the like that consume power in order for the customer facility 10 to operate.

  The facility-by-facility control unit 107 controls the electrical facilities (all or part of the solar battery 101, the power conditioner 102, the storage battery 103, the inverter 104, the power path switching unit 105, and the load 106) in the customer facility 10.

  The power management apparatus 200 previously shown in FIG. 1 executes power control on electrical facilities in the entire customer facility 10 belonging to the power management area 1. For this purpose, the power management apparatus 200 is connected to each of the facility-specific control units 107 in the customer facility 10 so as to be able to communicate with each other via the network 300. Thus, the facility-based control unit 107 can control the electrical facilities under its control according to the control of the power management apparatus 200.

  Note that, for example, the facility control unit 107 may be omitted, and the power management apparatus 200 may directly control the electric equipment such as the storage battery 103 in each customer facility 10. However, as in the present embodiment, by providing the power management apparatus 200 and the facility-by-facility control unit 107, the control of the entire power management area 1 and the customer facility 10 can be hierarchically structured. The complication of control of the management apparatus 200 can be avoided.

Also, as described above, in some of the customer facilities 10 in the power management area 1, for example, a solar power generation system (solar cell 101 and power conditioner 102), a storage battery system (storage battery 103 and inverter 104) There may be things that do not have
In the case of a customer facility 10 not equipped with a solar power generation system, it is not classified as a green mode customer facility. Moreover, in the case of the customer facility 10 not equipped with the storage battery system, it is not classified as either the economy mode customer facility or the green mode customer facility.

  In the power management system of the present embodiment, the customer facility 10 provided with the solar power generation system can reverse power flow to the power distribution network 3 by grid interconnection. Depending on such a reverse power flow, for example, surplus power that can not be consumed by the load 106 or the like in the customer facility 10 can be supplied (interchanged) to another customer facility 10 that is short of power. That is, in the power management system according to the present embodiment, it is possible to exchange (receive) power among the customer facilities 10.

[Configuration Example of Power Management Device]
Next, a configuration example of the power management apparatus 200 will be described with reference to FIG. The power management apparatus 200 includes a network interface unit 201, a control unit 202, and a storage unit 203.

  The network interface unit 201 communicates with the facility control unit 107 of each customer facility 10 via the network 300.

The control unit 202 executes various controls in the power management apparatus 200. The function as the control unit 202 is realized by the CPU (Central Processing Unit) included in the power management apparatus 200 executing a program.
The control unit 202 in the figure includes an operation planning unit 221 and a power control unit 222.

The operation planning unit 221 formulates an operation plan for a predetermined unit period. The operation plan is a plan defined for the operation of each electrical installation in the customer facility 10 in a predetermined unit period in the future. The unit period in which the operation plan is formulated in the present embodiment is, for example, one day (24 hours).
In the operation plan of the present embodiment, a plan for exchanging power from the economy mode consumer facility to the green mode consumer facility is included. To this end, the operation planning unit 221 includes a surplus power prediction unit 2211, a power shortage prediction unit 2212, and an interchanged power determination unit 2213.

  The surplus power prediction unit 2211 predicts surplus power for the economy mode consumer facility (an example of a first consumer facility). The surplus power is power that is surplus among the power charged in the storage battery 103 (an example of the first storage battery) included in the economy mode customer facility, without being consumed in the economy mode customer facility.

  The power shortage prediction unit 2212 predicts the power shortage for the green mode consumer facility (an example of a second consumer facility). The power shortage is a shortage of power consumption of the power that can be supplied to the load 106 at the green mode consumer facility. Among the power that can be supplied to the load 106 at the green mode consumer facility, the power generated by the solar cell 101 and the power stored in the storage battery 103 (an example of the second storage battery) are included.

  Flexible power determination unit 2213 supplies the economy mode consumer facility to green mode consumer facility based on the surplus power predicted by surplus power predictor 2211 and the shortage power predicted by shortage power predictor 2212 ( Determine the power to be interchanged (interchangeable power). The interchange power determination unit 2213 may determine, for example, the amount of power to be interchanged in a divided period in which a unit period of one day is divided by a predetermined time (for example, 30 minutes) as the interchange power.

  The power control unit 222 controls the operation of the electrical equipment in each customer facility 10 in accordance with the operation plan determined by the operation plan unit 221. In such power control, the power control unit 222 controls so that supply of power by the interchanged power determined by the interchanged power determination unit 2213 is performed.

The storage unit 203 stores various types of information used by the control unit 202. The storage unit 203 in the figure includes a customer facility information storage unit 231, a performance information storage unit 232, and an operation plan information storage unit 233.
The customer facility information storage unit 231 stores information on each customer facility 10. The customer facility information includes operation mode information. The operation mode information is information indicating whether the customer facility 10 is in the operation mode by the economy mode consumer facility or the green mode consumer facility.
The performance information storage unit 232 stores information (performance information) indicating the performance regarding the past operation of the electrical installation in each customer facility 10.
The operation plan information storage unit 233 stores operation plan information indicating the operation plan formulated by the operation plan unit 221. The power control unit 222 performs control such that operation according to the operation plan indicated by the operation plan information stored in the operation plan information storage unit 233 is performed in each customer facility 10.

[Summary of power interchange in this embodiment]
An outline of power interchange in the present embodiment will be described.
FIG. 4A shows a change in SOC (State Of Charge) of storage battery 103 in one day for a certain economy mode consumer facility.
In the figure, the storage battery 103 is charged using a commercial power source in a charging target time zone including a period from time t1 to time t2 corresponding to midnight, and the charging target time zone ends at time t2. It is fully charged at this stage. Furthermore, in the case of the same figure, the power consumption of the load 106 is covered by the power stored in the storage battery 103 after time t3 in the time zone when a certain time has elapsed from time t2 and the morning becomes . Thus, the SOC of storage battery 103 is reduced according to the power consumption of load 106 after time t3.

  That is, in the economy mode, the storage battery 103 is charged with the commercial power supply in a predetermined time slot (charge target time slot) in which the electricity charge is set low in one day. Further, since the commercial power supply is stably supplied, it is possible to set the storage battery 103 to a fully charged state as shown in the figure. Then, after the storage battery is charged, the storage battery 103 is discharged so that the power consumed by the load 106 is covered by the power stored in the storage battery 103.

  In such economy mode, the power of the commercial power supply is charged to the storage battery 103 during a cheap time zone of the utility power charge, and the load 106 is consumed by the power stored in the storage battery 103 during a time zone where the electricity charge is not cheap. I will try to get the power as much as possible. As a result, in the economy mode consumer facility, it is possible to reduce the purchase cost of the commercial power source. In other words, the economy mode has the advantage of high economy.

Moreover, FIG. 4 (B) has shown the change of SOC of the storage battery 103 in one day about a certain one green mode consumer facility.
In the example of the figure, the SOC decreases because power is supplied from the storage battery 103 to the load 106 before time t11 at night, and the SOC reaches "0" at time t11. Then, in response to the start of sunshine in the morning, the solar cell 101 starts power generation from a certain time, and the power generated by the solar cell 101 is supplied to the load 106. Then, from time t12, in response to the generated power of the solar cell 101 becoming higher than the consumed power of the load 106, surplus power starts to be generated in the green mode consumer facility for the generated power. As a result, the SOC rises after time t12. After that, although the surplus power of the generated power is lost according to the sunset, the power consumed by the load 106 is increased. As a result, in the same drawing, the SOC decreases from time t13.

  That is, in the green mode, the storage battery 103 is charged with the surplus power during a time zone in which surplus power is generated from the solar cell. Then, the storage battery 103 is discharged so that the power consumed by the load 106 is covered by the power charged in the storage battery 103.

  In such a green mode, the power of the load 106 is covered by the power generated at the customer facility as much as possible. In the economy mode, for example, only when the power consumption of the load 106 can not be covered by the generated power of the solar cell 101 or the power stored in the storage battery 103 and a shortage of power occurs, for example, the supply of commercial power is received. ing. That is, the green mode consumer facility reduces the use of the commercial power supply as much as possible by using the power generated by itself in the same manner as the power consumed by itself, thereby achieving self-sufficiency of power. In this respect, the green mode has the advantage of contributing to the natural environment.

However, the economy mode and the green mode have the following disadvantages, respectively.
First, in the economy mode, the storage battery 103 is charged until it is fully charged. In addition, for example, in the economy mode, in a situation where the power consumption of the load 106 is small, the discharge from the storage battery 103 is also suppressed. That is, in the economy mode, the time during which storage of the storage battery 103 in the high SOC state tends to be long.
One of the causes of deterioration of the storage battery 103 is storage time. The degree of deterioration due to such storage increases as the SOC increases.

FIG. 5 shows an example of the storage deterioration characteristic of the storage battery according to such an SOC. In the figure, the horizontal axis is the elapsed days (storage time), and the vertical axis is the deterioration rate. Further, line L1 indicates the deterioration characteristic of storage battery 103 when stored at a state of 100% SOC under a predetermined temperature condition. Further, line L2 indicates the deterioration characteristic of storage battery 103 when stored at a 50% SOC state under the same temperature conditions as in the case of line L1.
As can be seen from the line L1 and the line L2 in the figure, it can be seen that the degree of deterioration according to the passage of days becomes larger as the SOC becomes higher.
That is, in the economy mode, the storage battery 103 has a disadvantage that the storage time in the high SOC state is likely to be deteriorated due to an increase in time.

Next, in the green mode, for example, in a situation where the amount of sunshine is small, the power generated by the solar cell 101 is small, so the surplus power generated in the green mode consumer facility is also small. In this case, since the power stored in the storage battery 103 is also small, the SOC is low. As described above, in the green mode, the opportunity for storage of the storage battery 103 at a high SOC is less than that in the economy mode, and deterioration due to storage at a high SOC state is also less likely to occur.
However, in the green mode, as described above, the SOC tends to be low due to the weather or the like. Therefore, especially at the time when the power consumption of the load 106 is high, all the power stored in the storage battery 103 (an example of the power that can be supplied to the load 106 at the green mode consumer facility) in the state with high power consumption is consumed. , SOC tends to be "0". In such a state, the power stored in the storage battery 103 can not cover the power consumption. That is, in the green mode, there is a disadvantage that the power consumption of the load 106 in the green mode consumer facility is likely to be short for the power to be supplied by itself.

When the above economy mode and green mode are compared, high SOC status is maintained in economy mode consumer facilities in a certain time zone, but insufficient power occurs in green mode consumer facilities It may be in the state of
Therefore, in the power management area 1, the power management apparatus 200 of this embodiment supplies the surplus power generated in the economy mode customer facility to the green mode customer facility in which the power shortage is generated. Thus, control is performed such that power interchange is performed.
By performing such power interchange, the power stored in storage battery 103 can be reduced in the economy mode consumer facility, and therefore storage of storage battery 103 in a high SOC state can be suppressed. . Further, in the green mode consumer facility, it is possible to obtain power according to the shortage power without using the commercial power source by the power interchange from the economy mode consumer facility.

[Example of procedure]
FIG. 6 is a flow chart showing an example of a processing procedure executed by the power management apparatus 200 in the present embodiment for power interchange between the economy mode consumer facility and the green mode consumer facility. The process shown in FIG. 6 is executed by the power management apparatus 200 as part of a process for developing an operation plan for the next unit period (one day), for example.

Step S101: In the power management apparatus 200, the surplus power prediction unit 2211 predicts surplus power generated in a unit period to be predicted for each economy mode customer facility.
The surplus power prediction unit 2211 predicts surplus power as follows, corresponding to one economy mode consumer facility.
That is, the surplus power prediction unit 2211 acquires the past power consumption record of the economy mode consumer facility to be predicted from the past record information stored in the past record information storage unit 232. The surplus power prediction unit 2211 predicts the power consumption in the unit period to be predicted, using the acquired past power consumption results. At this time, the surplus power prediction unit 2211 may predict power consumption for each divided period in which unit periods to be predicted are divided into fixed time periods.
In addition, the surplus power prediction unit 2211 acquires, for example, from the customer facility information storage unit 231, specification information indicating the specifications (including the chargeable capacity, the rating, and the like) of the storage battery 103 provided in the economy mode customer facility to be predicted. . Based on the acquired specification information, surplus power prediction unit 2211 calculates the power (nighttime stored power) accumulated in storage battery 103 by charging in the target time zone for charging in the economy mode consumer facility to be predicted. .
The surplus power prediction unit 2211 calculates surplus power generated in the unit period to be predicted, based on the difference between the predicted power consumption and the calculated nighttime stored power. The calculation result of such surplus power is the prediction result of the surplus power in step S101.

Step S102: In addition, the power shortage prediction unit 2212 predicts the power shortage generated in the unit period to be predicted, for each green mode consumer facility.
The power shortage prediction unit 2212 predicts the power shortage as follows, corresponding to one green mode consumer facility.
That is, the insufficient power prediction unit 2212 acquires weather information from, for example, a server that provides the weather information via the network. In addition, the power shortage prediction unit 2212 acquires, from the actual result information storage unit 232, the actual result information of the green mode consumer facility to be predicted. The insufficient power prediction unit 2212 acquires the generated power of the solar cell 101 under the same or similar weather as indicated by the weather information acquired in the current season from the acquired performance information. The insufficient power prediction unit 2212 predicts the generated power of the solar cell 101 in the unit period to be predicted, based on the acquired generated power. The insufficient power prediction unit 2212 predicts the accumulated power of the storage battery 103 in the unit period to be predicted, based on the predicted generated power.
In addition, the power shortage prediction unit 2212 predicts the power consumption of the green mode consumer facility in the unit period to be predicted.
The power shortage prediction unit 2212 predicts the power shortage in the green mode consumer facility based on the predicted accumulated power of the storage battery 103 and the predicted power consumption. The power shortage prediction unit 2212 predicts the power shortage for each divided period in which unit periods to be predicted are divided into fixed time periods.

Step S103: The accommodation power determination unit 2213 formulates an accommodation plan based on the surplus power for each economy customer facility predicted at step S101 and the shortage power for each green mode customer facility predicted at step S102. Do. The accommodation plan has contents that define which amount of power is to be reversely flowed (sendered) from which economy customer facility for each divided period in the unit period to be predicted.
In step S102, it is predicted which electric energy will cause the shortage of power in which green mode consumer facility in each divided period in the unit period to be predicted. In accordance with the prediction result of the power shortage and the surplus power generated in the economy customer facility, the power consumption determining unit 2213 performs the green mode customer facility generating the power shortage for each division period. In contrast, it is determined from which of the economy mode consumer facilities generating surplus power how much power should be supplied. In this way, the interchanging power determination unit 2213 formulates an interchange plan.

  Step S104: The interchange power determination unit 2213 reflects the interchange plan formulated at step S103 in the operation plan.

The power control unit 222 controls the operation of the electrical installation in each customer facility 10 in accordance with the operation plan in which the accommodation plan is reflected as described above. As a result, accommodation of surplus power from the economy mode consumer facility is realized by compensating for the shortage of power in the green mode consumer facility according to the accommodation plan.
As a result, in the economy mode consumer facility, power stored in storage battery 103 without being used by load 106 can be discharged. Thereby, storage of the storage battery 103 in the high SOC state is avoided as much as possible.
In addition, in the Green mode consumer facility, self-sufficiency of power will be maintained as much as possible. Further, in the green mode consumer facility, for example, it is possible to store in the storage battery 103 the surplus power not consumed by the load 106 among the transmitted power. For example, in the green mode, it is likely that the storage battery 103 can not be charged due to a bad weather or the like, so the operation rate of the storage battery 103 tends to be low. It is also possible to increase the operation rate of the storage battery 103 by charging the storage battery 103 with the power accommodated as described above in the green mode consumer facility. In addition, in the green mode consumer facility, the purchase (consumption) of the expensive commercial power source 2 can be suppressed in the daytime time zone, and instead power purchased from the economy mode consumer facility can be purchased, thereby reducing the power cost. It is also possible to

  In addition, in the accommodation plan formulated in step S103 described above, for example, storage battery 103 in a state in which the SOC is maintained at a maximum in the period from time t2 to t3 in FIG. Plans may also be developed to discharge the The discharged power is supplied to a predetermined green mode consumer facility in which the power shortage occurs at the same time.

  In the power management system of the present embodiment, for example, the following operation can be performed for power interchange from the economy mode consumer facility to the green mode consumer facility. That is, for example, after the business operator operating the power management apparatus 200 purchases the power supplied from the economy mode consumer facility to the green mode consumer facility, the green mode consumer facility pays according to the power supply. Can be used as an operation.

  Note that the program for realizing the function as the above-described power management apparatus 200 is recorded in a computer-readable recording medium, and the computer system reads the program recorded in the recording medium and executes the program. Processing as the power management apparatus 200 may be performed. Here, "to read and execute the program recorded on the recording medium into the computer system" includes installing the program on the computer system. The “computer system” mentioned here includes an OS and hardware such as peripheral devices. Also, the “computer system” may include a plurality of computer devices connected via a network including communication lines such as the Internet, WAN, LAN, and dedicated lines. The term "computer-readable recording medium" refers to a storage medium such as a flexible disk, a magneto-optical disk, a ROM, a portable medium such as a ROM or a CD-ROM, or a hard disk built in a computer system. As described above, the recording medium storing the program may be a non-transitory recording medium such as a CD-ROM. The recording medium also includes a recording medium provided internally or externally accessible from the distribution server for distributing 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 executable in 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. Note that the program may be divided into a plurality of parts, and the configuration may be such that the terminal device integrates after being downloaded at different timings, or the distribution server that distributes each of the divided programs may be different. Furthermore, "computer-readable recording medium" holds a program for a certain period of time, such as a volatile memory (RAM) in a computer system serving as a server or a client when the program is transmitted via a network. We shall include things. Further, the program may be for realizing a part of the functions described above. Furthermore, it may be a so-called difference file (difference program) that can realize the above-described functions in combination with a program already recorded in the computer system.

Reference Signs List 1 power management area, 2 commercial power supply, 3 distribution network, 10 consumer facility, 101 solar battery, 102 power conditioner, 103 storage battery, 104 inverter, 105 power path switching unit, 106 load, 107 facility control unit, 200 power Management device, 201 network interface unit, 202 control unit, 203 storage unit, 221 operation plan unit, 222 power control unit, 231 consumer facility information storage unit, 232 performance information storage unit, 233 operation plan information storage unit, 300 network, 2211 surplus power prediction unit, 2212 shortage power prediction unit, 2213 interchange power determination unit

Claims (3)

The first storage battery for the first customer facility operating to charge the first storage battery with the power of the commercial power supply and supply the load with the power stored in the first storage battery in a predetermined charging target time zone A surplus power prediction unit that predicts surplus power surplus without being supplied from the first customer facility among the charged power;
Regarding the second customer facility that operates so as to charge the second storage battery with the power generated by the power generation apparatus and supply the load with the power stored in the second storage battery, the load at the second customer facility A power shortage prediction unit that predicts the power shortage that is a shortage of the power consumption of the power that can be supplied to the
Based on the surplus power predicted by the surplus power prediction unit and the shortage power predicted by the shortage power prediction unit, the adapted power to be supplied from the first customer facility to the second customer facility is determined. The interchange power determination unit,
And a power control unit configured to perform control to supply power by the determined interchanged power. The surplus power prediction unit predicts surplus power for each of a plurality of first customer facilities,
The power shortage prediction unit predicts power shortage for each of a plurality of second customer premises,
The interchanged power determination unit includes surplus power for each of a plurality of first consumer facilities predicted by the surplus power prediction unit, and shortage power for each of a plurality of second consumer facilities predicted by the insufficient power prediction unit. The power management device according to claim 1, wherein the interchanging power to be supplied to the plurality of second consumer facilities from each of the plurality of first consumer facilities is determined based on the condition (5). Computer,
The first storage battery for the first customer facility operating to charge the first storage battery with the power of the commercial power supply and supply the load with the power stored in the first storage battery in a predetermined charging target time zone A surplus power prediction unit which predicts surplus power surplus without being supplied from the first customer facility among the charged power;
Regarding the second customer facility that operates so as to charge the second storage battery with the power generated by the power generation apparatus and supply the load with the power stored in the second storage battery, the load at the second customer facility The power shortage forecasting unit predicts the power shortage that is the shortage for the power consumption of the power that can be supplied to the
Based on the surplus power predicted by the surplus power prediction unit and the shortage power predicted by the shortage power prediction unit, the adapted power to be supplied from the first customer facility to the second customer facility is determined. Flexible power determination unit,
A program for functioning as a power control unit that controls to supply power by determined interchange power.

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