JP2018166391A - Power management device, terminal device, power management method, power management program, and management method for user element information - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve appropriate adjustment of electric power corresponding to a simultaneous equal-amount against a planned value, even when a new user facility is joined, according to a power management area in which a plurality of user' facilities exist.SOLUTION: The present invention comprises an acquisition part which acquires user element information showing an element of a user at a user's facility in a power management area; a user's facility classification part which executes classification to belong to at least any one of a first user's facility group and a second user's facility group, on the basis of a tendency of the usability of electric power defined according to the acquired user element information.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power management device, a terminal device, a power management method, a power management program, and a user element information management method.

  Under the plan value simultaneous amount system, the electric power company submits a power supply plan for power generation (reverse power flow) and demand (forward power flow) to the general power transmission and distribution business. It is required to be the same amount at the same time. In this case, if an imbalance occurs where the actual value is excessive or deficient with respect to the planned value, costs will be incurred for the adjustment of imbalance on the general transmission / distribution company side. Settlement corresponding to imbalance (imbalance settlement) is performed with general power transmission and distribution companies.

  As an electric utility, it is necessary to adjust the power so that payment by imbalance settlement does not occur. Therefore, the following power management apparatus is known. That is, the power management apparatus calculates the sum of the value obtained by multiplying the power value procured from the renewable energy power generation facility by the first price coefficient and the value obtained by multiplying the power value procured from other power generation facilities by the second price coefficient. The third price factor is multiplied by the power value of the difference obtained by subtracting the actual power value procured from the renewable energy power generation facility from the procurement function that is the function and the planned power value procured from the renewable energy power generation facility Based on the imbalance function that is a function, the ratio of the power value procured from the renewable energy power generation facility is obtained (see, for example, Patent Document 1).

JP 2015-230544 A

For example, a power management system called a TEMS (Town Energy Management System) or a CEMS (Community Energy Management System) that performs power control on a plurality of customer facilities in a predetermined power management area is known. For example, when an electric power company manages such a power management system, the electric power company may contract with a general power transmission and distribution company for a plan value simultaneous amount system in units of power management areas. In this case, since a power supply plan corresponding to the entire power management area is formulated, it is required to realize the same amount of plan values in the power management area.
However, Patent Document 1 merely describes a configuration for obtaining a ratio of electric power values procured from a renewable energy power generation facility by taking a single solar power generation facility as an example. For this reason, depending on the technique described in Patent Document 1, the adjustment corresponding to the same amount of the plan value is appropriately performed in response to the generated power and the variation in the demand power among a plurality of customer facilities in the power management area. It is difficult. In addition, as a customer facility in the power management area, there may be a customer facility that is newly managed as a user newly joins as a consumer in the power management area. For this reason, it is desirable to perform power management in consideration of the customer facility as a new management target.

  The present invention has been made in view of such circumstances, and even when a new customer facility joins a power management area in which a plurality of customer facilities exist, the planned value can be shared simultaneously. The purpose is to appropriately adjust the power corresponding to the amount.

  In order to solve the above-described problem, the present invention is defined based on an acquisition unit that acquires user element information representing an element of a user of a customer facility in a power management area, and the acquired user element information. A customer facility classification unit that performs classification so as to belong to at least one of the first consumer facility group and the second consumer facility group based on the power usage tendency.

  Further, according to the present invention, the acquisition unit acquires user element information representing an element of a customer facility user in the power management area, and the customer facility classification unit is based on the acquired user element information. This is a power management method for performing classification so as to belong to at least one of the first consumer facility group and the second consumer facility group based on the determined power usage tendency.

  In addition, the present invention provides an acquisition step of acquiring, in a computer, user element information that represents an element of a user of a customer facility in a power management area, and an electric power usage tendency determined based on the acquired user element information. Is a power management program for executing a consumer facility classification step of performing classification so as to belong to at least one of the first consumer facility group and the second consumer facility group.

  In addition, the present invention provides an acquisition unit that acquires user element information representing an element of a user of a customer facility in a power management area, and the acquired user element information is determined based on the user element information. And a transmission unit that transmits to the power management apparatus that performs classification so as to belong to at least one of the first customer facility group and the second customer facility group based on the usage tendency.

  Further, the present invention provides an element of a user of a customer facility in a power management area obtained as an answer to a questionnaire performed when the acquisition unit is subscribed to the power management area or when the usage status is changed. The user element information to be expressed is acquired, and the transfer unit converts the acquired user element information into at least a first consumer facility group and a second consumer based on the power usage tendency determined based on the user element information. This is a management method of user element information transferred to a power management apparatus that performs classification so as to belong to any one of facility groups.

  As described above, according to the present invention, even when a new customer facility joins in correspondence to a power management area where a plurality of customer facilities exist, the user elements of the customer facility It was categorized into groups according to the power usage tendency determined based on the information. Thereby, for each group, it is possible to appropriately adjust the power corresponding to the same amount of the planned value according to the power usage tendency.

It is a figure which shows the structural example of the power management system in 1st Embodiment. It is a figure which shows the structural example of the electric equipment about the consumer facility in 1st Embodiment. It is a figure which shows the structural example of the controller in a customer facility in 1st Embodiment. It is a figure which shows the structural example of the power management apparatus in 1st Embodiment. It is a flowchart which shows the example of a process sequence which the power management apparatus in 1st Embodiment performs in relation to simultaneous plan amount control. It is a flowchart which shows an example of the customer facility classification | category process which the power management apparatus in 1st Embodiment performs. It is a flowchart which shows the example of a process sequence which the power management apparatus in 2nd Embodiment performs as a power generation plan corresponding | compatible group consumer facility power control. It is a flowchart which shows the example of a process sequence which the power management apparatus in 2nd Embodiment performs as a consumer plan electric power control in a demand plan corresponding group. It is a schematic block diagram showing an example of a structure of the terminal device in 3rd Embodiment. It is a figure which shows an example of the questionnaire information displayed on the display screen of a terminal device. It is a figure explaining the power consumption in a consumer. It is a figure explaining the power consumption in a consumer. It is a figure showing the power consumption pattern explaining the relationship between the power consumption for every time slot | zone, and a threshold value.

<First Embodiment>
FIG. 1 shows an example of the overall configuration of a power management system in the present embodiment. The power management system according to the present embodiment collectively manages power in customer facilities such as houses, commercial facilities, and industrial facilities corresponding to a plurality of customer facilities in a predetermined region. Such a power management system corresponds to, for example, TEMS (Town Energy Management System), CEMS (Community Energy Management System), and the like.

The power management system according to the present embodiment performs power management for the electrical equipment for each customer facility 100 in a certain range of area shown as the power management area 10 in FIG. The customer facility 100 corresponds to, for example, a house, a commercial facility, or an industrial facility.
Moreover, in this embodiment, the case where the new customer facility 100a joins with respect to each customer facility 100 which exists in the power management area 10 is also considered. As a case where a new customer facility 100a joins, for example, there is a case where a customer facility 100a such as a facility, a building, a public facility, or a general household is newly installed in the power management area. When the customer facility 100a is newly provided as a customer facility, or already installed as a customer facility, since there is no user, no one uses it and only the facility is installed. A new user may start using this customer facility. As described above, in the present embodiment, the customer facility 100a that joins the power management area 10 can also perform various types of control as a power management target. Moreover, in the following description, when it is not necessary to distinguish between the customer facility 100 and the customer facility 100a, the customer facility 100 may be simply referred to.
In addition, the area | region which the power management area 10 of this embodiment respond | corresponds may be formed by one area range, and may be formed by the some area range geographically dispersed.

In the present embodiment, the customer facility 100 includes a power generation device that generates power using a solar battery, and a storage battery. Further, the customer facility 100 may be provided with either a solar battery or a storage battery. Further, the customer facility 100 may be provided with neither a solar battery nor a storage battery.
The power generator and the storage battery provided in the customer facility 100 are grid-connected to the commercial power source. Accordingly, the customer facility 100 including the power generation device or the storage battery causes the power generated by the power generation device to be output or the power output from the storage battery due to the discharge to the power system (distribution network) of the commercial power source to flow backward. Power can be sold through.

  For example, the power management area 10 of the present embodiment has a contract corresponding to the plan value simultaneous amount system with a general power transmission and distribution company. That is, the operator of the power management area 10 formulates a power supply plan as the power management area 10 every predetermined unit planned time (for example, 30 minutes), and sends the formulated power reception plan to the general power transmission and distribution company. hand in. In addition, when the actual power supply in the power management area 10 is excessive or insufficient (imbalance) with respect to the power supply plan, the settlement corresponding to the imbalance between the electric power company and the general power transmission and distribution company. (Imbalance settlement) is performed.

The power reception plan in the present embodiment includes a power generation plan and a demand plan. The power generation plan is a plan value for the power management area 10 as a whole for the power to be reversely flowed through the distribution network. The demand plan is a plan value for the power management area 10 as a whole for power purchased from the distribution network in a forward current.
Under the plan value simultaneous amount system to which this embodiment corresponds, it is required that the results are achieved as planned for each of the power generation plan and the demand plan. That is, in the plan value simultaneous equal amount system to which this embodiment corresponds, it is required that the actual power flow reversely flowing from the power management area 10 is not excessive or deficient with respect to the power generation plan. It is required that there is no excess or deficiency in the actual power supply that receives the power flow.
In the present embodiment, the generated power refers to power that is caused to flow backward in the distribution network. In addition, demand power refers to power that flows forward from the distribution network.

In addition, the customer facility 100 in the power management area 10 of the present embodiment is classified so as to belong to any one of the three groups of the power generation plan corresponding group GP1, the demand plan corresponding group GP2, and the intermediate group GP3. Such group classification is performed by the power management apparatus 300.
The power generation plan correspondence group GP1 is a set of customer facilities 100 controlled to achieve the power generation plan.
The demand plan corresponding group GP2 is a set of customer facilities 100 controlled to achieve the demand plan.
The intermediate group GP3 is a set of customer facilities 100 that are controlled so that the power difference between the reverse power flow and the forward power flow is equal to or less than a certain value, that is, the generated power and the demand power are equal.

  In the present embodiment, even when a new customer facility 100a joins, the power management apparatus 300 generates power according to the customer facility 100a at a predetermined stage of joining the power management area 10. By classifying into any one of the plan corresponding group GP1, the demand plan corresponding group GP2, and the intermediate group GP3, the group can belong to any of these three existing groups.

  As described above, the customer facility 100 includes a power generator and a storage battery, a solar cell and a storage battery, and a solar facility and a storage battery. There is. Among these, the customer facility 100 that is not provided with either a solar battery or a storage battery may be included in the demand plan corresponding group GP2. For the customer facility 100 that is not provided with either a solar battery or a storage battery, adjustment by charging / discharging operation of the storage battery cannot be performed. Then, what is necessary is just to enable it to compensate for the excess and deficiency with respect to the supply-and-demand plan which arises by the customer facility 100 which neither a solar cell nor a storage battery equips with the other customer facility 100 provided with a storage battery in the demand plan corresponding group GP2.

  In the present embodiment, the customer facility 100 belonging to the power generation plan corresponding group GP1 is the customer facility 100 classified as having a large amount of generated power. In addition, the customer facility 100 belonging to the demand plan corresponding group GP2 is the customer facility 100 classified as one with less generated power. In addition, the customer facility 100 belonging to the intermediate group GP3 is a customer facility 100 classified as a balance between generated power and demand power.

  The customer facility 100 can communicate with the power management apparatus 300 by being connected to the network NW.

  The power management apparatus 300 performs power control for the electrical equipment in the entire customer facility 100 belonging to the power management area 10. For this reason, the power management apparatus 300 of the figure is connected so as to be able to communicate with each of the customer facilities 100 via the network NW. Thereby, the power management apparatus 300 can control the operation | movement of the electric equipment with which the customer facility 100 is provided.

  FIG. 2 shows a configuration example of electrical equipment in the customer facility 100. The customer facility 100 in the figure includes a power meter 101, a distribution board 102, a power generation device 103, a storage battery 104, a load 105, a communication modem 106, and a customer facility controller 200. That is, this figure shows an example of a customer facility 100 that includes both a power generation device and a storage battery.

The power meter 101 measures demand power and generated power. That is, the power meter 101 measures received power. The received power is, for example, a difference between demand power and generated power.
In the customer facility 100, the power supplied to the distribution board 102 from the commercial power line DL on the general power transmission / distribution company side is the demand power. On the other hand, the power output from the power generation device 103 or the storage battery 104 and supplied from the distribution board 102 to the commercial power supply line DL via the power meter is generated power. When the forward current corresponding to the demand power is set to the forward direction, the received power is measured as a positive value if the generated power corresponding to the reverse tide is small compared to the demand power corresponding to the forward power. If the generated power is large, the received power is measured as a negative value.

  The distribution board 102 distributes and supplies the power supplied from the commercial power source to the storage battery 104, the load 105, and the like. Moreover, the distribution board 102 can output the electric power output from the power generator 103 to the commercial power supply line DL via the power meter 101 for reverse power flow.

  The power generation apparatus 103 is a facility that generates power by receiving sunlight. 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, and converts the electric power obtained by the electric power generation into alternating current by the PCS and outputs it.

The electric power generated by the power generation apparatus 103 can be supplied as a power source for the load 105. Further, the power generated by the power generation apparatus 103 can be charged in the storage battery 104.
In addition, the power generated by the power generation apparatus 103 can be reversely flowed by being output from the distribution board 102 via the power meter 101 to the commercial power supply line DL.

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

The storage battery 104 can be charged by inputting commercial power supplied through the distribution board 102. In addition, the storage battery 104 can be charged by inputting power generated by the power generation device 103.
Further, the storage battery 104 can supply the stored power as a power source for the load 105. Moreover, the storage battery 104 can be made to reverse-flow by outputting the accumulate | stored electric power to the commercial power supply line DL via the power meter 101 from the distribution board 102. FIG.

The load 105 collectively indicates predetermined devices and facilities that consume power for their own operation in the customer facility 100. It should be noted that the types and number of devices and equipment as loads included in each customer facility 100 may be different.
The load 105 can operate by inputting commercial power supplied from the distribution board 102. Further, the load 105 can operate by inputting power generated by the power generation device 103. Further, the load 105 can operate by inputting the power output from the storage battery 104.

  The communication modem 106 communicates with the power management apparatus 300 via the network NW.

The customer facility controller 200 controls electrical facilities (the power generation device 103, the storage battery 104, the load 105, the communication modem 106, and the like) in the customer facility 100.
Further, the customer facility controller 200 can input information on power consumption measured by the power meter 101, and can use the input power consumption information for various controls.

  FIG. 3 shows a configuration example of the customer facility controller 200 provided in the customer facility 100. The customer facility controller 200 shown in FIG. 1 includes an external communication interface 201, an external correspondence transceiver 202, an institution communication interface 203, an institution correspondence transceiver 204, a power collection unit 205, a control unit 206, and a storage unit 207.

The external communication interface 201 performs communication via the network NW via the communication modem 106, for example.
The external compatible transmission / reception unit 202 uses the external communication interface 201 to control data transmission / reception via the network NW.

The in-facility communication interface 203 communicates with electrical equipment and the like in the customer facility 100 in which the in-facility communication interface 203 is provided.
The in-facility correspondence transmission / reception unit 204 controls transmission / reception of data to / from the electrical equipment in the customer facility 100 via the in-facility communication interface 203.

  The power collection unit 205 collects power-related information in the customer facility. For example, the power collecting unit 205 can collect received power information measured by the power meter 101. The power collecting unit 205 may collect power generated by the power generation device, remaining amount (accumulated power) or charge / discharge power of the storage battery 104, load power (power consumption) due to the load 105, and the like.

  The control unit 206 executes various controls corresponding to functions as the customer facility controller 200. The control unit 206 transmits information on the generated power and the demand power collected by the power collection unit 205 to the power management apparatus 300.

Note that the power meter 101 may be a smart meter, for example, which may transmit information on the measured received power to the power management apparatus 300 via the communication line NL via the network NW. In this case, it is not necessary for the power collection unit 205 to collect the received power measured by the power meter 101.
The storage unit 207 stores various types of information used by the control unit 206.

  FIG. 4 shows a configuration example of the power management apparatus 300. The power management apparatus 300 in the figure includes a communication unit 301, a control unit 302, and a storage unit 303.

  The communication unit 301 communicates with the customer facility controller 200 in the customer facility 100 via the network NW.

The control unit 302 controls the operation of the electrical equipment of each customer facility 100 in the power management area 10. The control unit 302 of this embodiment includes an acquisition unit 320, a customer facility classification unit 321, and a power control unit 322.
The acquisition unit 320 acquires user element information representing the user element of the customer facility in the power management area. Moreover, when acquiring the user element information, the acquisition unit 320 can acquire the energy element information that represents the energy equipment used in the customer facility. The case where the energy device information is information different from the user element information has been described. However, the energy device information may be included in one piece of information in the user element information.

The user element information includes information including at least one of the number of users in the customer facility, the number of people in a predetermined age group, gender, and life pattern. As the number of users, for example, when the customer facility is a general house, it is the number of family members who use (resident) the house, or the number of workers and non-workers in the family, If the customer facility is a facility, if the facility is a commercial facility, the number of users who are likely to use the commercial facility, and if the customer facility is a building, the building will be used. When the number of users and the customer facility are public facilities, the number of users who are likely to use the public facilities can be used.
Examples of the predetermined age group include children and elderly people. Whether the user is a worker or not, if the user is a worker, work, work at home, self-employed, use a customer facility, the frequency of work (for example, work in a week) Such as the number of times) can be used.

The energy device information is information regarding whether or not a storage battery installed in a newly added customer facility 100a is installed, whether or not a solar power generation device is installed, and the installed load. For example, when a storage battery is installed, information indicating the capacity of the storage battery may be included, and when a solar power generation device is installed, information indicating the power generation capacity may be included. Also good.
The acquisition unit 320 obtains the result of the questionnaire regarding the user element information, which is performed for the user (or the administrator) of the customer facility 100a to newly join, with respect to the user element information. When 300 operators are input through an input device such as a keyboard or a mouse, user element information based on a questionnaire result obtained through the input device is acquired.

The customer facility classification unit 321 includes, for a plurality of customer facilities in the power management area 10, a power generation plan corresponding group GP1 (an example of a first customer facility group) and a demand plan corresponding group GP2 (an example of a second customer facility group). ) And the intermediate group GP3 (an example of a third customer facility group).
Moreover, the customer facility classification | category part 321 classifies a group for every fixed time. Specifically, the customer facility classification unit 321 performs group classification for each unit planned time (for example, 30 minutes).
In addition, when the user element information is acquired by the acquisition unit 320, the customer facility classification unit 321 is based on the power usage tendency determined based on the acquired user element information. Classification is performed so as to belong to either the customer facility group or the second customer facility group.

The power control unit 322 controls the power equipment in the customer facility 100 belonging to the power generation plan corresponding group GP1 so that the power generation plan formulated corresponding to the power management area 10 is achieved.
In addition, the power control unit 322 controls power equipment in the customer facility 100 belonging to the demand plan corresponding group GP2 so that the demand plan formulated corresponding to the power management area 10 is achieved.
In addition, the power control unit 322 controls the power equipment in the customer facility 100 belonging to the intermediate group so that the difference in power between the forward flow and the reverse flow as the intermediate group is equal to or less than a certain level.

  The storage unit 303 stores information used by the control unit 302 in power management. The storage unit 303 of the present embodiment stores power generation plan information 331, demand plan information 332, customer facility basic information 333, and customer facility classification information 334.

  The power generation plan information 331 is information indicating the power generated by the formulated power generation plan. The demand plan information 332 is information indicating power demand according to the formulated demand plan.

The customer facility basic information 333 includes basic information for each customer facility 100 in the power management area 10. The customer facility basic information corresponding to one customer facility 100 includes a customer facility ID that uniquely indicates the corresponding customer facility 100, a power facility provided in the corresponding customer facility 100, and a corresponding customer facility 100. Includes information such as the address of the controller 200 in the customer facility.
For each customer facility 100, the customer facility classification information 334 indicates which group of the power generation plan corresponding group GP1, the demand plan corresponding group GP2, and the intermediate group GP3 is classified by the customer facility classification unit 321. It is the information shown. Specifically, the customer facility classification information 334 is information in which a group ID indicating a classified group is associated with each customer facility ID, for example.

  The power management apparatus 300 of the present embodiment having the above-described configuration is configured to achieve both the power generation plan and the demand plan formulated corresponding to the power management area 10 (simultaneous planned value simultaneous control). ). With reference to the flowcharts of FIGS. 5, 6, and 7, an example of a processing procedure executed by the power management apparatus 300 according to the present embodiment in association with the plan value simultaneous amount control is described.

In FIG. 5, the customer facility classification unit 321 waits until the adjustment start time is reached (step S101—NO). Under the simultaneous plan value simultaneous amount system to which this embodiment corresponds, for example, the generated power and the demand power are totaled every unit planning time of 30 minutes, and the power generation plan for each unit planning time is calculated based on the totaled result. Develop a demand plan. The adjustment start time corresponds to the timing at which the unit plan time is started.
When the adjustment start time is reached (step S101—YES), the customer facility classification unit 321 executes customer facility classification processing (step S102).

The flowchart of FIG. 6 shows an example of the customer facility classification process as step S102.
The customer facility classification unit 321 determines whether or not the user element information has been acquired by the acquisition unit 320 (step S200). When the user element information is not acquired, that is, when the customer facility 100 already belonging to the power management area 10 is classified (step S200-NO), the customer facility classification unit 321 The received power for each customer facility 100 in the management area 10 is acquired (step S201).
At this time, the customer facility classification unit 321 transmits a received power request to the customer facility controller 200 for each customer facility 100. In response to receiving the received power request, the customer facility controller 200 transmits the received power information input from the power meter 101 to the power management apparatus 300 by the power collecting unit 205. The customer facility classification unit 321 acquires information on received power transmitted from the customer facility controller 200 of each customer facility 100 in this way.

As described above, when the forward flow corresponding to the demand power is set to the positive direction, if the generated power is small with respect to the demand power, the received power shows a positive value, and if the generated power is large with respect to the demand power, The received power shows a negative value. That is, in this case, the larger the received power value is, the larger the demand power is, and the smaller the received power value is, the more the generated power is.
Therefore, the customer facility classification unit 321 executes the following classification process based on the received power (step S202). In other words, the customer facility classification unit 321 assumes that the customer facility 100 in the power management area 10 has a large amount of generated power with respect to the demand power and a lot of demand power with respect to the generated power. Then, the generated power and the demand power are classified so as to correspond to any one of the three types (ie, the absolute value of the received power is equal to or less than a certain value). The customer facility classification unit 321 causes the customer facility 100 classified as having a large amount of generated power relative to the demand power to belong to the power generation plan corresponding group GP1. Moreover, the customer facility classification | category part 321 makes the customer facility 100 classified as a thing with much demand power with respect to generated power belong to the demand plan corresponding | compatible group GP2. Moreover, the customer facility classification | category part 321 makes the customer facility 100 classified as what the generated power and demand power have balanced belong to intermediate | middle group GP3.
The customer facility classification unit 321 is not particularly limited as an algorithm for classifying the customer facility 100 into any one of the three groups as described above. For example, the customer facility classification unit 321 may perform classification based on the threshold value of received power set for each of the three groups. Alternatively, the customer facility classification unit 321 may perform classification by a classification algorithm using machine learning.

  As a guideline, the absolute value of the difference between the average of the actual demand power and the average of the actual generated power in the previous unit planning time is about 2/3 of the PCS rating. The customer facilities 100 that are less than or equal to about ½ can be classified as belonging to the intermediate group GP3. Alternatively, a customer facility 100 whose absolute value of the difference between the actual power demand and the actual power generation in the previous unit planned time is less than the PCS rating or about 2/3 or less is assigned to the intermediate group GP3. Can be classified as belonging.

The customer facility classification unit 321 stores the classification result obtained by the classification process in step S202 so as to update the customer facility classification information 334 (step S203).
On the other hand, when the user element information is acquired, that is, when the customer facility 100a newly joins the customer facility 100 that already belongs to the power management area 10 (step S200-YES), the demand The house facility classification unit 321 specifies the power usage tendency according to the user element information acquired by the acquisition unit 320 (step S251), and classifies the customer facility 100a (step S252).

User element information is acquired when user element information or energy equipment information entered on a paper questionnaire is acquired, and an answer corresponding to the contents of the questionnaire is input via the terminal device. In some cases, the information is acquired by receiving information from the terminal device.
In addition, when acquiring the user element information, if energy device information is acquired together with the user element information, the power usage tendency is specified using the user element information and the energy device information. For example, there are three usage tendencies: one where the generated power is larger than the demand power, one where the demand power is larger than the generated power, and one where the generated power and the demand power are balanced.

  More specifically, for example, the customer facility classification unit 321 performs classification based on the following rules (1) to (6). This rule may be stored in advance as rule information in a storage area inside the customer facility classification unit 321 or may be stored as rule information in the storage unit 303 and referred to.

(1) The customers are divided into a plurality of groups according to the number of family members and owned energy devices, and imbalance reduction control is performed for each group.
For example, when the customer facility 100a is a general house, it is classified into one of the groups based on the number of family members as users and the owned energy equipment represented by the energy equipment information. For example, when the number of family members is larger than a predetermined number, it is assumed that the family is a large family, and the power usage tendency is estimated as “high power consumption”, and is classified into the demand plan corresponding group GP2, and the number of family members is predetermined. If the number is less than the number, it is assumed that the family is a small family, and the power usage tendency is estimated as “low power consumption” and is classified into the power generation plan corresponding group GP1 or the intermediate group GP3. Here, even if it is determined to be a large family, if there is a storage battery or solar power generation device as an owned energy device, the power usage tendency is estimated as “low power consumption” When it is classified into the power generation plan corresponding group GP1 and only one of the storage battery and the solar power generation device is owned, the power usage tendency is estimated as “the generated power and the demand power are balanced” Then, it is classified into the intermediate group GP3.

(2) Dividing consumers into a plurality of groups according to the number of children and owned energy devices, and performing imbalance reduction control for each group.
For example, if the number of children under the age of a family is greater than a certain number (for example, 2 or more), the power usage tendency is estimated as “high power consumption”, and the demand plan When the number of children under the predetermined age is less than the predetermined number (for example, 1 or 0), the power usage tendency is estimated as “low power consumption” and the power generation is estimated. It classifies into plan correspondence group GP1 or intermediate group GP3. Here, as the age under the predetermined age, for example, an age such as under 6 years old (not attending school) or under 3 years old (not attending a nursery school or the like) can be used. Such a child under a predetermined age is highly likely to stay at home with the parent even during the daytime, and is considered to consume a certain amount of power even during the daytime. Therefore, when the number of children under the predetermined age is larger than the predetermined number, it is possible to estimate that the power usage tendency is “high power consumption”.

  Here, even if it is determined that the number of children under the predetermined age is greater than the predetermined number, if there are storage batteries or solar power generation devices as owned energy devices, Is estimated to be “low power consumption” and classified into the power generation plan corresponding group GP1, and only one of the storage battery and the solar power generation device is owned, the power utilization tendency is “generated power Can be classified into the intermediate group GP3.

(3) Dividing consumers into a plurality of groups according to the number of elderly people and owned energy devices, and performing imbalance reduction control for each group. For example, among the number of family members, the number of users over a predetermined age is a predetermined number. If the number is larger (for example, two or more), the power usage tendency is estimated as “power consumption is high”, and is classified into the demand plan corresponding group GP2, and the number of users over a predetermined age is a predetermined number. If it is less (for example, one or zero), the power usage tendency is estimated as “low power consumption” and classified into the power generation plan corresponding group GP1 or the intermediate group GP3. Here, as the predetermined age or older, for example, an age such as 70 years old can be used. Such a user is considered to be less likely to go out than a user under 70 years of age, and therefore, will consume a certain amount of power in the house even during the daytime. Therefore, when the number of users older than the predetermined age is larger than the predetermined number, it is possible to estimate that the power usage tendency is “high power consumption”.

  Here, even if it is determined that the number of users older than the predetermined age is greater than the predetermined number, if there is a storage battery or solar power generation device as the owned energy device, the use of power When the propensity is estimated to be “low power consumption” and classified into the power generation plan corresponding group GP1, and only one of the storage battery and the solar power generation device is owned, It can also be classified into the intermediate group GP3 by estimating that “the power and the demand power are balanced”.

(4) Dividing consumers into a plurality of groups according to the number of workers and owned energy equipment, and performing imbalance reduction control for each group. For example, when the number of workers among the number of family members is greater than a predetermined number (for example, 2 If the number of workers is less than a predetermined number (for example, the number of workers is estimated to be “low power consumption”) and classified into the power generation plan corresponding group GP1 or the intermediate group GP3. 1 person or 0 person) is estimated that the power usage tendency is “high power consumption”, and is classified into the demand plan corresponding group GP2.

Here, since there is a high possibility that a customer who has more than a predetermined number of workers is out for work during the day, it is considered that electric power is not consumed during the day. On the other hand, it is considered that consumers who have a smaller number of workers than the predetermined number consume a certain amount of power because they are likely to stay at home during the day. Therefore, it is possible to estimate the power usage tendency based on the number of workers.
Here, even if it is determined that the number of workers is less than the predetermined number, if there are storage batteries or solar power generation devices as owned energy equipment, When it is estimated that the consumption is low and is classified into the power generation plan corresponding group GP1, and only one of the storage battery and the solar power generation device is owned, the power utilization ratio is “generated power and demand power”. Can be classified into the intermediate group GP3.

(5) Dividing into multiple groups according to the work style (working at home, at home, self-employed, working hours, working frequency, etc.) and energy equipment owned by the consumers in (4) above, and imbalance reduction control for each group I do.
For example, when the number of workers is recognized according to the rule of (4) above, it is estimated whether there is a possibility that even a worker is at home according to the life pattern according to the working style of the worker. . For example, if all of the family members are workers, and the working style of any user is self-employed, there is a high possibility of being at home during the day. The utilization tendency is estimated as “power consumption is large”, and is classified into the demand plan corresponding group GP2. In addition, even if any user is working at a company, if the frequency of work is low (for example, a work style that only works once or twice a week), the power utilization tendency is “power consumption is reduced. It is estimated as “many” and classified into the demand plan corresponding group GP2.

In addition, if the work style is a form in which any user works according to the time of day, for example, the form of working at night or early morning, it is likely that the user is at home during the day and the power usage Are estimated as “the power consumption is large” and classified into the demand plan corresponding group GP2.
On the other hand, if the work style is any user who is working at the company and working normally (working on the go during the day), the power usage tendency is estimated as “low power consumption” and power generation It classifies into plan correspondence group GP1.
Also in the case of (5), if there is a storage battery or a solar power generation device as an owned energy device, depending on the case where only one of the storage battery and the solar power generation device is owned, It can also be classified into these groups.

(6) For each consumer component and energy device information of (1) to (5) above, the power consumption (amount) and the generated power (amount) as a reference are set in advance, and by machine learning It is also possible to calculate the demand power (amount) and generated power (amount) of the customer, classify the customer facility 100a into any group based on the result, and perform imbalance reduction control for each group.
(7) Even if the customer facility 100a is classified based on the above (1) to (6), there is a change in the number of family members or a change in the life pattern in the customer facility 100a. In some cases (starting work, leaving work, working hours changed, etc.), obtain user element information related to the change and regroup it based on the user element information It is possible to perform imbalance reduction control for each group that has been reorganized.

In this way, the customer facility classification unit 321 converts the customer facility 100a into the power generation plan corresponding group GP1, the demand plan corresponding group GP2, and the intermediate group GP3 based on the usage tendency specified according to the user element information. Belong to one of them. Here, when user element information regarding a plurality of customer facilities 100a is obtained, the customer facilities 100a are grouped among the customer facilities 100a having similar power usage tendencies, and the three of these customer facilities 100a are grouped. It can also belong to one of the groups.
Then, the customer facility classification unit 321 stores the classification result obtained by the classification process in step S252 so as to be added to or updated in the customer facility classification information 334 (step S203).

  Returning to FIG. After the customer facility classification process in step S102, the power control unit 322 performs power generation plan corresponding group target power control (step S103), demand plan corresponding group target power control (step S104), and intermediate group target power control (step S105). ).

As the power generation plan corresponding group target power control in step S103, the power control unit 322 performs control so that, for example, a power generation plan formulated corresponding to the current unit planned time is achieved. For this purpose, the power control unit 322 acquires information on received power from the customer facility 100 belonging to the power generation plan corresponding group GP1 every predetermined time (for example, several minutes). The power control unit 322 determines the difference (reception difference) between the generated power value (actual generated power value) obtained based on the acquired received power and the generated power value (plan generated power value) indicated in the power generation plan. Is calculated. The power control unit 322 controls the charging / discharging operation of the storage battery 104 in the customer facility 100 belonging to the power generation plan corresponding group GP1 so that the calculated reception difference is eliminated.
That is, when the actual generated power value tends to be larger than the planned generated power value with respect to the calculated reception difference, the power control unit 322 stores the storage battery 104 in all or some of the customer facilities 100 of the power generation plan corresponding group GP1. The power generated by the power generation device 103 is charged. As a result, the actual generated power value can be suppressed and can be made equal to the planned generated power value.

On the other hand, when the actual generated power value tends to be smaller than the planned generated power value with respect to the calculated reception difference, the power control unit 322 stores the storage battery 104 in all or some of the customer facilities 100 of the power generation plan corresponding group GP1. Execute discharge to increase the generated power. As a result, the actual generated power value can be increased to be equal to the planned generated power value.
In addition, in controlling the charging / discharging operation of the storage battery 104 as described above, the power control unit 322 instructs the customer facility controller 200 in the customer facility 100 to control the charging / discharging operation of the storage battery 104.

Moreover, as the demand plan corresponding group target power control in step S104, the power control unit 322 performs control so that, for example, a demand plan formulated corresponding to the current unit planned time is achieved. For this reason, the power control unit 322 acquires information on received power from the customer facility 100 belonging to the demand plan corresponding group GP2 every predetermined time (for example, several minutes). The power control unit 322 determines the difference (reception difference) between the demand power value (actual demand power value) obtained based on the acquired received power and the demand power value (planned demand power value) indicated in the demand plan. Is calculated.
The power control unit 322 controls the charging / discharging operation of the storage battery 104 in the customer facility 100 belonging to the demand plan corresponding group GP2 so that the calculated receipt difference is eliminated.
That is, when the actual demand power value tends to be larger than the planned demand power value with respect to the calculated receipt difference, the power control unit 322 stores the storage battery 104 in all or some of the customer facilities 100 in the demand plan corresponding group GP2. Do not charge or discharge. Thereby, the charging power to the storage battery 104 is reduced, the actual demand power value is suppressed, and can be made equal to the planned demand power value.
On the other hand, when the actual demand power value tends to be smaller than the planned demand power value with respect to the calculated receipt difference, the power control unit 322 stores the storage battery 104 in all or some of the customer facilities 100 in the demand plan corresponding group GP2. Execute charging and increase power demand. As a result, the actual demand power value can be increased to be equal to the planned demand power value.

Further, as the intermediate group target power control in step S105, the power control unit 322 performs control so that the absolute value of the received power is equal to or less than a certain value for the entire intermediate group. Specifically, in the present embodiment, it is only necessary to perform control so that the received power becomes a control target value.
In the following description, a case where the control target value for received power is zero is taken as an example.
As a specific example of the control for this, for example, the power control unit 322 acquires information on received power from each customer facility 100 belonging to the intermediate group GP3 every predetermined time (for example, several minutes). The power control unit 322 controls the charge / discharge operation of the storage battery 104 so that the acquired absolute value of the received power becomes zero for each customer facility 100 belonging to the intermediate group GP3.
That is, when the demand power tends to be larger than the generated power, the storage battery 104 is not charged or discharged. Thereby, the charging power to the storage battery 104 is reduced, the demand power is suppressed, and the received power can be brought close to zero.

On the other hand, when the generated power tends to be larger than the demand power, if the actual demand power value tends to be smaller than the planned demand power value with respect to the calculated receipt difference, the storage battery 104 is charged. , Increase power demand. Thereby, demand power can be increased with respect to generated power, and received power can be made close to zero.
Such control is realized by the power control unit 322 instructing the customer facility controller 200 of the customer facility 100 to cause the customer facility controller 200 to perform the charge / discharge operation of the storage battery 104. .
In addition, it is good also as a value which gave the offset with respect to the normal value about the control target value of received electric power according to having become the state where the difference of generated electric power and demand electric power becomes large. That is, as a specific example, assuming that the control target value in normal times is 0 kW and the demand power is larger than the generated power, an offset value corresponding to the generated power is given. The received power may be easily brought close to zero by controlling the generated power of .5 kW as the control target value. Further, when the offset value is given in this way, in order to efficiently operate so as not to reverse from the offset side, the PCS of the storage battery 104 is intermittently at the maximum rating so that the generated power offset value is set from 0 kw. May be operated.

When power control as these steps S103, S104, and S105 is being executed, the power control unit 322 determines whether or not the unit planning time started in response to step S101 has ended (step S106). . The power control unit 322 continues the power control of steps S103, S104, and S105 as long as the unit planning time has not ended (step S106—NO).
When the unit plan time ends (step S106—YES), the processing shown in FIG.

  Thus, in this embodiment, after the classification of a group is updated according to the electric power state in each customer facility 100 for every unit plan time, the electric power control corresponding to every group is performed. Thereby, in the power management area 10 of the present embodiment, control corresponding to the same amount of plan values can be realized and the formulated power generation plan and demand plan can be achieved.

Here, the same amount control of this embodiment is also possible, for example, by classifying the customer facility 100 in the power management area 10 into two groups, a power generation plan corresponding group GP1 and a demand plan corresponding group GP2. .
However, especially when the customer facility 100 is a low-voltage one such as a general household, the influence of fluctuations in the output of the power generation device 103 due to the weather and time zone is large, and the power consumed in the customer facility 100 is also various. Of home appliances (air conditioners, cooking utensils, dryers, etc.) vary greatly.
Furthermore, in one customer facility 100, when the power output from the power generation device 103 and the total power consumption are close to each other, for example, in a unit planned time of 30 minutes, the power output from the power generation device 103 is performed for a few minutes. Since the power to be generated is larger than the total power consumption, reverse power flow is performed, but the total power consumption is larger than the power output from the power generator 103 for the next several minutes, and power is purchased by forward power flow. Is likely to occur. In addition, the difference between the generated power in the reverse power flow and the demand power in the forward power flow is small.

  In such a situation, it may be difficult to control the charging / discharging operation of the storage battery 104 and perform power control corresponding to the power generation plan corresponding group GP1 or the demand plan corresponding group GP2 in accordance with the entire situation. For example, as a result of controlling the generated power to be 2 kW corresponding to a slight error with respect to the planned value, it is likely that the actual result will be a demand of 1 kW. In such a state, for example, not only readjustment in the power generation plan correspondence group GP1, but also readjustment on the demand plan correspondence group GP2 side may be necessary depending on the case, and the control becomes complicated. .

Therefore, in the present embodiment, an intermediate group GP3 is provided in addition to the power generation plan corresponding group GP1 and the demand plan corresponding group GP2. The intermediate group GP3 includes the customer facility 100 in which the power output from the power generation apparatus 103 and the total power consumption are close as described above.
In addition, the intermediate group GP3 is controlled so that the absolute value of the difference between the generated power and the demand power is always zero. For this purpose, it is only necessary to control the customer facility 100 so that the power output from the power generation device 103 is equal to the total power consumption, and such control is easy.
In addition, since the power generation plan corresponding group GP1 in this case can be a set of customer facilities 100 in which the amount of generated power is significant with respect to the demand power, the generated power of the power generation plan corresponding group GP1 is defined as a power generation plan. It becomes easy to control to be equivalent. Similarly, since the demand plan corresponding group GP2 in this case can be a set of customer facilities 100 in which the amount of demand power is remarkable with respect to the generated power, the demand power of the demand plan corresponding group GP2 can be used as the demand plan. It becomes easy to control so that it becomes the same amount.
In other words, in the present embodiment, by providing the intermediate group GP3, it is possible to easily realize the simultaneous plan value and amount control corresponding to each of the power generation plan and the demand plan.

In the above-described embodiment, the group classification performed by the customer facility classification unit 321 has been described with respect to a case where it is performed at regular time intervals. You may make it perform in the case of at least any one of the division | segmentation by time, and the division | segmentation by (c) generated imbalance amount.
(A) When performing at the time of a family structure change, the customer facility classification | category part 321 classifies again about the consumer, when there is a change of a number of persons, or an attribute change. For example, when a child under a certain age reaches a certain age from a certain age or when a child who reaches a certain age grows up and becomes a worker as a member of society When a person retires from home during the day, a part-time housewife may become a full-time housewife.
(B) When performing based on the division by time, the customer facility classification unit 321 may perform classification again when a predetermined time is reached or when the season changes. As for the case where the predetermined time is reached, for example, 10:00 am on the day when the year changes (the commuting time may change due to the change of work place, and the home time may change), the first day of every month By setting a timing at which the lifestyle may change in the consumer, such as noon (can be periodically reclassified), it is possible to reclassify according to the timing.
(C) When performing based on the division | segmentation by the generated imbalance amount, the consumer facility classification | category part 321 can perform a reclassification when a reference value, a cumulative amount, the average amount of a fixed period, etc. are exceeded. When the reference value is used, the customer facility classification unit 321 stores a reference value for the imbalance amount in advance, and performs reclassification when an imbalance exceeding the reference value occurs. When the accumulated amount is used, the customer facility classification unit 321 calculates the accumulation of the imbalance amount, and performs reclassification when the accumulated value becomes equal to or greater than a predetermined accumulated value (reference value). When using an average amount for a certain period, the customer facility classification unit 321 calculates an imbalance amount per unit time of the imbalance amount for a certain period as an average value, and this average value is a predetermined value (reference value). ) If it becomes above, reclassify.

Second Embodiment
Next, the second embodiment will be described. In the case of the previous first embodiment, for the power generation plan corresponding group GP1, the power management device 300 monitors the power state of the customer facility 100 belonging to the power generation plan corresponding group GP1, and the power generation plan is achieved. The charge / discharge operation of at least some of the customer facilities 100 in the power generation plan correspondence group GP1 was controlled. Similarly, for the demand plan corresponding group GP2, the power management apparatus 300 monitors the power state of the customer facility 100 belonging to the demand plan corresponding group GP2, and the demand plan corresponding group GP2 The charging / discharging operation of at least some of the customer facilities 100 was controlled.

  On the other hand, in the present embodiment, the power management apparatus 300 sets a control target value for the generated power to each of the customer facilities 100 belonging to the power generation plan corresponding group GP1 so that the power generation plan is achieved. Set. The customer facility controller 200 in the customer facility 100 controls the charging / discharging operation of the storage battery 104 so that the generated power is in accordance with the instructed control target value.

  Similarly, the power management apparatus 300 sets a control target value for demand power for each of the customer facilities 100 belonging to the demand plan corresponding group GP2 so that the demand plan is achieved. The customer facility controller 200 in the customer facility 100 controls the charging / discharging operation of the storage battery 104 so that the power demand is in accordance with the instructed control target value.

  For the intermediate group GP3, as in the first embodiment, for example, the customer facility controller 200 in each customer facility 100 has a difference between the generated power and the demand power of zero according to an instruction from the power management apparatus 300. The charge / discharge operation of the storage battery 104 is controlled so that

  The overall flow of processing executed by the power management apparatus 300 in the present embodiment for simultaneous control of the planned value is the same as in FIG. In addition, the power management apparatus 300 executes the processing shown in the flowchart of FIG. 7 below as the power generation plan corresponding group target power control in step S103, and shows the demand plan corresponding group target power control in step S104 in the flowchart of FIG. Execute the process.

First, the power generation plan corresponding group target power control shown in FIG. 7 will be described. The power control unit 322 acquires the power generation plan corresponding to the current unit planned time started in response to Step S101 from the power generation plan information 331 stored in the storage unit 303 (Step S301).
In addition, the power control unit 322 acquires actual generated power and actual demand power corresponding to the current time for each customer facility 100 belonging to the power generation plan corresponding group GP1 (step S302).

The power control unit 322 is based on the power generation plan acquired in step S301, the actual generated power corresponding to the current time for each customer facility 100 belonging to the power generation plan corresponding group GP1 acquired in step S302, and the actual demand power. A control target value for the generated power for each customer facility 100 is determined (step S303).
The power control unit 322 transmits the control target value determined for each customer facility 100 in step S303 to the corresponding customer facility 100 (step S304).
In response to the reception of the control target value, the customer facility controller 200 of each customer facility 100 belonging to the power generation plan corresponding group GP1 performs charge / discharge control of the storage battery 104 so that the generated power becomes the control target value. As a result, the planned value simultaneous amount control corresponding to the power generation plan as the power management area 10 is executed.

In addition, the process of the same figure may be performed once corresponding to every unit plan time, and may be performed for every fixed time which further divided the unit plan time.
In step S302, a predicted value of generated power and demand power in a period to be controlled may be acquired, and in step S303, a control target value may be determined based on the predicted value.

Next, the demand plan corresponding group target power control shown in FIG. 8 will be described. The power control unit 322 acquires a demand plan corresponding to the current unit planned time started corresponding to step S101 from the demand plan information 332 stored in the storage unit 303 (step S401).
In addition, the power control unit 322 acquires the actual generated power and the actual demand power corresponding to the current time for each customer facility 100 belonging to the demand plan corresponding group GP2 (step S402).

The power control unit 322 is based on the demand plan acquired in step S401 and the actual generated power and the actual demand power corresponding to the current time for each customer facility 100 belonging to the power generation plan corresponding group GP1 acquired in step S402. A control target value for power demand for each customer facility 100 is determined (step S403).
The power control unit 322 transmits the control target value determined for each customer facility 100 in step S403 to the corresponding customer facility 100 (step S404).
In response to receiving the control target value, the customer facility controller 200 of each customer facility 100 belonging to the demand plan corresponding group GP2 performs charge / discharge control of the storage battery 104 so that the demand power becomes the control target value. As a result, the plan value simultaneous amount control corresponding to the demand plan as the power management area 10 is executed.

Note that the processing in the figure may be performed once corresponding to each unit planned time as in the processing in FIG. 7, or is performed at regular time intervals that further divide the unit planned time. It may be a thing.
In step S402, the power control unit 322 acquires predicted values of generated power and demand power during the period to be controlled, and in step S403, determines a control target value based on the predicted value. Good.

  In the above embodiment, the case where the power generation apparatus 103 includes a solar battery is taken as an example. However, for example, the power generation apparatus 103 may be a power generation apparatus that generates power using renewable energy, such as wind power generation or geothermal power generation.

Next, a third embodiment will be described.
In the first and second embodiments, a case has been described in which a written questionnaire is mainly given to a user of a newly-added customer facility 100a. However, in the second embodiment, the questionnaire is a terminal. A case of inputting via the device will be described.
FIG. 9 is a schematic block diagram illustrating an example of a configuration of a terminal device according to the second embodiment.
In the terminal device 500, the communication unit 501 has a function of communicating with an external device. For example, the external device is the power management apparatus 300 according to the first embodiment, and receives questionnaire information that is transmitted from the power management apparatus 300 and serves as a questionnaire for inputting user element information.
The storage unit 502 stores the questionnaire information received by the communication unit 501.
The display unit 503 is a display panel, for example, and displays various types of information. For example, the display unit 503 reads out questionnaire information received and stored in the storage unit 502, displays the questionnaire information on the screen of the display panel, and displays various types of information according to input operations on the terminal device 500.

The user element information input unit 504 is an answer to the questionnaire information displayed on the display unit 503, and accepts user input of user element information representing the user element of the customer facility in the power management area.
The energy device information input unit 505 is an answer to the questionnaire information displayed on the display unit 503. The energy device information input unit 505 is the presence or type of energy device provided in the customer facility 100a, the rating of the energy device (power storage amount, power generation amount, power consumption). The user input of energy device information which is information such as
The user element information input unit 504 and the energy device information input unit 505 may be configured by a keyboard or a mouse, and the display unit 503, the user element information input unit 504, and the energy device information input unit 505 are touch panels. It may be configured.
The control unit 506 controls each unit in the terminal device 500. For example, when the response to the questionnaire information is input and it is determined that the transmission button on the screen is pressed, the control unit 506 transmits the user element information input from the user element information input unit 504 to the communication unit 501. To the power management apparatus 300. When the energy device information is input from the energy device information input unit 505, the control unit 506 transmits the energy device information to the power management apparatus 300 together with the user element information. Thereby, user element information and energy device information are acquired by the acquisition unit 320 of the power management apparatus 300.

  In addition, the control unit 506 stores the input user element information and energy device information in the storage unit 502, and causes the display unit 503 to display when a read instruction from the user is input from a touch panel or the like. . When there is a change in the user element information or the energy device information, the user can input the changed information from the user element information input unit 504 or the energy device information input unit 505. In response to this input, the control unit 506 transmits the changed information (user element information and energy device information) to the power management apparatus 300 via the communication unit 501.

  FIG. 10 is a diagram illustrating an example of questionnaire information displayed on the display screen of the terminal device. The questionnaire information is provided with an input field (symbol a) for inputting the number of people who are occupying the target customers to be surveyed. By inputting the number of persons in this input field, attribute input for the number of persons is entered. A column (symbol b) is displayed. In this figure symbol b, the case where the number of persons is input as four is illustrated, and the head of household, family (1), family (2), family (3), family ( As 4), there are provided input fields for gender, age, and occupation. By inputting in this input field, it is possible to grasp the configuration, attributes, etc. of the consumer by a questionnaire.

  In addition, a questionnaire column for asking questions about energy devices installed in the consumer is displayed on the lower side of the screen displayed as questionnaire information. Here, as the energy equipment, "solar battery" indicating a solar power generation device, "household storage battery" indicating a storage battery, "household fuel cell" indicating a fuel cell, "hot water storage water heater", "electric water heater" You can select one of them, including those that you do not have. In addition, when an energy device is selected, an input field for answering the capacity is also provided. In addition, a questionnaire column is provided for answering energy devices that may be introduced in the future as energy devices. If there is an answer indicating that there is an energy device that may be introduced in the future, it can be reclassified as needed.

Next, FIG.11 and FIG.12 is a figure explaining the electric power consumption in a consumer. 11 (a) to 11 (c) and FIGS. 12 (d) to 12 (f) are graphs showing the power consumption state when the number of users and attributes in the customer facility are different, and the vertical axis is the vertical axis. Power consumption, horizontal axis is time.
FIG. 11A shows the power consumption per hour in a day when the number of users in the customer facility is two and the attributes are office workers and full-time housewives. In such a consumer, when the solar power generation device is installed as an energy device, it can be classified into a power generation plan group.
In FIG. 11B, the number of users in the customer facility is four, and the attributes are office workers, full-time housewives, children (large (predetermined age)), and children (small (predetermined age)). )) Represents the power consumption per hour in one day. In such a consumer, since there is a certain amount of power consumption, when energy equipment is not installed, it is classified into a demand plan group. On the other hand, when photovoltaic power generation devices and storage batteries are installed as energy devices, they are classified into demand planning groups at the peak of power consumption at midnight, morning, daytime, and night, and are classified into power generation planning groups during the day. Is done.
FIG. 11 (c) shows that the number of users in the customer facility is four, and the attributes are office workers, part-time housewives, children (large (predetermined age)) and children (small (under predetermined age)). )) Represents the power consumption per hour in one day. In such customers, when solar power generation devices and storage batteries are installed as energy devices, they are classified into demand plan groups at peak hours of morning and night power consumption, and during the day, power generation plan groups are categorized.

FIG. 12A shows that the number of users in the customer facility is five, and the attributes are office workers, part-time housewives, children (large (predetermined age)), and children (large (predetermined age or older)). )), And represents the power consumption per hour in a day in the case of a child (small (under a predetermined age)).
FIG. 12B shows that the number of users in the customer facility is four, and the attributes are self-employed, full-time housewife, child (large (predetermined age)), child (small (under predetermined age)) )) Represents the power consumption per hour in one day.
FIG. 12 (c) shows that the number of users in the customer facility is 6, and the attributes are office workers, full-time housewives, children (large (predetermined age)), and children (small (under predetermined age)). )), An hourly power consumption for one day in the case of an elderly person or an elderly person.

  In the consumers as shown in FIGS. 12 (a) to 12 (c), when the solar power generation device and the storage battery are installed as energy devices, the capacity of the energy devices is taken into consideration, and the demand planning group is mainly used. If the power generation amount is larger than the power consumption during the day, the power generation plan group can be classified.

  The customer facilities having the power consumption patterns in FIGS. 11A to 11C and FIGS. 12A to 12C may be classified using threshold values. FIG. 13 is a diagram illustrating a power consumption pattern for explaining the relationship between the power consumption and the threshold value for each time period. In this figure, the vertical axis represents power consumption, and the horizontal axis represents the time zone.

FIG. 13A shows that the number of users in the customer facility is four, and the attributes are office workers, full-time housewives, children (large (predetermined age)), and children (small (under predetermined age)). )), It represents the power consumption for each time slot of the day. In FIG. 13B, the number of users in the customer facility is 4, and the attribute is the power consumption for each time zone in the case of a company employee, full-time housewife, elderly person, elderly person. Represents.
FIG. 13 (c) shows that the number of users in the customer facility is four, and its attributes are office workers, part-time housewives, children (large (predetermined age)), and children (small (under predetermined age)). )), It represents the power consumption for each time slot of the day. FIG. 13 (d) shows that the number of users in the customer facility is 7, and the attributes are office workers, full-time housewives, children (large (predetermined age)), and children (large (predetermined age or older)). )), Children (small (under a predetermined age)), elderly people, and elderly people, it represents the power consumption for each time period of the day.
In FIGS. 13A to 13D, a threshold value (for example, 4000 Wh / 6h) is set.

  By using the power consumption pattern and the threshold shown in FIG. 13 as described above, a threshold for power consumption (amount) by time zone is set, and the time zone in which the power consumption is higher than the threshold is classified into a demand plan group. The time zone in which the power consumption is less than the threshold may be classified into the power generation plan group. For example, in a customer facility with a power consumption pattern as shown in FIG. 13A, the time zone from 6 o'clock to 12 o'clock and the time zone from 18 o'clock to 24 o'clock are classified into demand plan groups, In other time zones, it is classified as a power generation plan group. Further, in the customer facility having the power consumption pattern as shown in FIGS. 13B and 13D, the time zone from 6 o'clock to 24 o'clock is classified into the demand plan group, and other time zones Is classified as a power generation planning group. In the customer facility having the power consumption pattern as shown in FIG. 13 (c), the time zone from 18:00 to 24:00 is classified into the demand plan group, and the other time zones are classified into the power generation plan group. The

According to the embodiment described above, it is possible to easily group new customers who have no past data according to the power utilization tendency using the user element information. Moreover, such customer grouping can be simplified.
Moreover, according to embodiment described above, grouping can be changed organically according to the fluctuation | variation of the component of a consumer.
In addition, according to the embodiment described above, since the customer facilities having similar power usage tendencies are classified into the same group, imbalance reduction control can be efficiently performed for a certain consumer group. .

  Note that a program for realizing the functions as the power management device 300, the customer facility controller 200, the terminal device 500, and the like is recorded on a computer-readable recording medium, and the program recorded on the recording medium is recorded. The processing as the above-described power management apparatus 300, the customer facility controller 200, and the like may be performed by being read and executed by a computer system. Here, “loading and executing a program recorded on a recording medium into a computer system” includes installing the program in the computer system. The “computer system” here includes an OS and hardware such as 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 dedicated line. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated 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 inside or outside that is accessible from the distribution server in order 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 that can be executed by the terminal device. That is, the format stored in the distribution server is not limited 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, downloaded at different timings, and combined in the terminal device, or the distribution server that distributes each of the divided programs may be different. Furthermore, the “computer-readable recording medium” holds a program for a certain period of time, such as a volatile memory (RAM) inside a computer system that becomes a server or a client when the program is transmitted via a network. Including things. The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

DESCRIPTION OF SYMBOLS 10 Power management area, 100 Customer facility, 101 Electric power meter, 102 Distribution board, 103 Power generation device, 104 Storage battery, 105 Load, 106 Communication modem, 200 Customer facility controller, 201 External communication interface, 202 External transmission / reception unit , 203 Intra-facility communication interface, 204 In-facility compatible transceiver, 205 Power collection unit, 206 Control unit, 207 Storage unit, 300 Power management device, 301 Communication unit, 302 Control unit, 303 Storage unit, 320 Acquisition unit, 321 Demand House facility classification unit, 322 Power control unit, 331 Power generation plan information, 332 Demand plan information, 333 Customer facility basic information, 334 Customer facility classification information, 500 terminal device, 501 communication unit, 502 storage unit, 503 display unit, 504 User element information input section, 50 5 Energy equipment information input unit, 506 Control unit

Claims (17)

An acquisition unit for acquiring user element information representing an element of a user of a customer facility in a power management area;
A consumer that performs classification so as to belong to at least one of the first consumer facility group and the second consumer facility group based on the power usage tendency determined based on the acquired user element information. A facility classification department;
A power management device. The acquisition unit acquires energy device information representing the energy device used in the customer facility and the user element information,
The power management apparatus according to claim 1, wherein the customer facility classification unit performs the classification based on a usage tendency determined based on the user element information and the energy device information. The user element information is information including at least one of the number of users in the customer facility, the number of people in a predetermined age group, gender, and life pattern. Power management device. The power management apparatus according to claim 3, wherein the number of users includes the number of workers. The power management apparatus according to claim 4, wherein the life pattern is determined according to a working pattern of the worker. The said acquisition part acquires the user element information of the user who subscribes as a user of a consumer facility in the said power management area from the outside of the said power management area. The power management device described in 1. The electric power according to any one of claims 2 to 6, wherein the energy device is information regarding an installation status for at least one of a power generation device and a power storage device in the customer facility. Management device. The power facility in the customer facility belonging to the first consumer facility group is controlled so that the power generation plan formulated in correspondence with the power management area is achieved, and formulated in correspondence with the power management area. The electric power of any one of Claims 1-7 provided with the electric power control part which controls the electric power equipment in the consumer facility which belongs to the said 2nd consumer facility group so that a demand plan may be achieved. Management device. The customer facility classification unit
Classifying the plurality of customer facilities so as to belong to any one of the first customer facility group, the second customer facility group, and the third customer facility group;
The power control unit
The power equipment in the customer facility belonging to the third consumer facility group is controlled so that the difference in power between the forward flow and the reverse flow as the third consumer facility group is equal to or less than a certain level. The power management apparatus according to claim 8. The customer facility classification unit
Of the plurality of consumer facilities, a consumer facility classified as having a large amount of generated power belongs to the first consumer facility group, and a customer facility classified as having a large amount of demand power is the second The power management apparatus according to any one of claims 1 to 9, wherein the power management apparatus is made to belong to a customer facility group. The customer facility classification unit
11. The customer facility classified as a balance between generated power and demand power among the plurality of customer facilities belongs to the third consumer facility group. 11. Power management device. The power management apparatus according to any one of claims 1 to 11, wherein the customer facility classification unit performs the classification at regular intervals. The power control unit
Control charging / discharging of the storage battery in the customer facility belonging to the first customer facility group so that the power generation plan is achieved, and demand belonging to the second customer facility group so that the demand plan is achieved The power management apparatus according to any one of claims 1 to 12, which controls charging / discharging of a storage battery in a home facility. The acquisition unit acquires user element information representing an element of a customer facility user in the power management area,
The consumer facility classification unit belongs to at least one of the first consumer facility group and the second consumer facility group based on the power usage tendency determined based on the acquired user element information. Classification of power management methods. On the computer,
An acquisition step of acquiring user element information representing an element of a user of a customer facility in a power management area;
A consumer that performs classification so as to belong to at least one of the first consumer facility group and the second consumer facility group based on the power usage tendency determined based on the acquired user element information. Facility classification step,
Power management program for running An acquisition unit for acquiring user element information representing an element of a user of a customer facility in a power management area;
The acquired user element information is classified so as to belong to at least one of the first consumer facility group and the second consumer facility group based on the power usage tendency determined based on the user element information. A transmission unit for transmitting to a power management apparatus that performs
A terminal device. User element information representing the user element of the customer facility in the power management area, obtained as an answer to a questionnaire conducted when the acquisition unit is subscribed to the power management area or when the usage status is changed. Acquired,
The transfer unit transfers the acquired user element information to at least one of the first consumer facility group and the second consumer facility group based on the power usage tendency determined based on the user element information. A method of managing user element information that is transferred to a power management apparatus that performs classification to belong.

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