JP7474368B2 - Power management system, power management server, control device, and power management method - Google Patents

Description

This disclosure relates to a power management system, a power management server, a control device, and a power management method.

In recent years, in order to maintain the balance between power supply and demand in the power grid, a technology has become known in which an electric utility that supplies power to a consumer facility communicates with a control device that controls the power equipment at the consumer facility to manage the power consumption at the consumer facility. For example, Patent Document 1 discloses a demand response request server that communicates with the consumer facility and issues a demand response request so that the electric utility can reduce the power consumption of the consumer facility.

JP 2017-027448 A

However, when the number of control devices to be managed or the frequency of communication with the control devices increases, there is a risk that processing will be concentrated at specific times in the server that communicates with the control devices and manages the power consumption of consumer facilities, causing a temporary increase in the processing load of the server. Therefore, there is a need for further improvements in the usefulness of technology that communicates with consumer facilities and manages the power consumption of consumer equipment.

In light of these circumstances, the purpose of this disclosure is to provide a power management system, a power management server, a control device, and a power management method that communicates with consumer facilities to improve the usefulness of technology for managing consumer power consumption.

An energy management system according to an embodiment of the present disclosure includes a control device that controls an electric power device, and a power management server capable of communicating with the control device. When the power management server determines that the control device is a target of a demand response request during a demand response period, the power management server transmits a first message request to the control device, the first message request specifying a first transmission timing as the timing for transmitting a message during the demand response period. When the control device receives the first message request, the control device transmits a message to the power management server at the first transmission timing during the demand response period.

The power management server according to one embodiment of the present disclosure is capable of communicating with a control device that controls power equipment. When the power management server determines that the control device is a target for a demand response request during a demand response period, the power management server transmits a message request to the control device that specifies the timing of transmitting a message during the demand response period.

A control device according to an embodiment of the present disclosure is capable of communicating with a power management server and controls power equipment. When the control device receives a message request from the power management server specifying a message transmission timing during a demand response period, the control device transmits a message to the power management server at the transmission timing during the demand response period.

A power management method according to an embodiment of the present disclosure is a power management method for a power management system including a control device that controls power equipment and a power management server capable of communicating with the control device. The power management method includes a step in which, when it is determined that the control device is a target of a demand response request during a demand response period, the power management server transmits to the control device a message request that specifies a timing for transmitting a message during the demand response period. The power management method includes a step in which, when the control device receives the message request, the control device transmits a message to the power management server at the transmission timing during the demand response period.

The power management system, power management server, control device, and power management method according to one embodiment of the present disclosure improve the usefulness of the technology that communicates with consumer facilities and manages the consumer's power consumption.

1 is a schematic configuration diagram illustrating a power management system according to an embodiment. 2 is a block diagram showing a configuration of a power management server according to an embodiment; FIG. FIG. 11 is a diagram illustrating information included in transmission timing according to an embodiment. FIG. 2 illustrates multiple transmission timings according to an embodiment. FIG. 2 is a block diagram showing a configuration of a control device according to an embodiment. FIG. 4 is a flow diagram showing a process flow of a power management server according to an embodiment. FIG. 4 is a flow chart showing a process flow of a control device according to an embodiment.

The power management system, power management server, control device, and power management method according to an embodiment of the present disclosure will be described below with reference to the drawings. In the descriptions of the drawings, the same or similar parts are denoted by the same or similar reference numerals.

However, it should be noted that the drawings are schematic and the ratios of the dimensions may differ from the actual ones. Therefore, the specific dimensions should be determined with reference to the explanation below. Furthermore, the drawings may contain parts where the dimensional relationships or ratios differ from one another.

(Power Management System)
A power management system according to an embodiment of the present disclosure will be described below.

1 is a schematic diagram showing an example of a power management system 1 according to an embodiment of the present disclosure. In FIG. 1, the power management system 1 includes a power management server 10 and a plurality of control devices 20A, 20B, and 20C. The power management server 10 is a server managed by an electric power company such as a power generation company, a power transmission and distribution company, a retail company, or an aggregator. The power management server 10 includes one or a plurality of information processing devices such as server devices that can communicate with each other. The control devices 20A, 20B, and 20C are, for example, home energy management systems (HEMS) installed in consumer facilities, but are not limited thereto, and may be any information processing devices that control electric power devices installed in consumer facilities. Hereinafter, when the control devices 20A, 20B, and 20C are not particularly distinguished from each other, they will be simply referred to as the control devices 20. Each of the control devices 20 is connected to the power management server 10 so as to be able to communicate with each other via a network 40 including, for example, the Internet. For ease of explanation, FIG. 1 shows one power management server 10 and three control devices 20, but the power management system 1 may include any number of power management servers 10 and control devices 20.

Each of the control devices 20A, 20B, and 20C is connected to each of the power devices 30A, 30B, and 30C installed in the customer facility so as to be able to communicate with them. Each of the power devices 30A, 30B, and 30C is, for example, a load or a distributed power source, but is not limited thereto. In FIG. 1, the power devices 30A and 30B are connected to the power system 2A so as to be able to conduct electricity. The power device 30C is connected to the power system 2B so as to be able to conduct electricity. As a result, each of the power devices 30A, 30B, and 30C is supplied with power from the power system 2A or 2B, or discharges power to the power system 2A or 2B. Hereinafter, when the power devices 30A, 30B, and 30C are not particularly distinguished from each other, they are collectively referred to simply as the power devices 30. Hereinafter, when the power systems 2A and 2B are not particularly distinguished from each other, they are collectively referred to simply as the power system 2. For ease of explanation, in FIG. 1, one power device 30 is connected to each control device 20, but any number of power devices 30 may be connected to the control device 20. Also, in FIG. 1, an example is shown in which each of the power devices 30 is connected to one of two power systems 2 managed by different electric power companies, but the power devices 30 may be connected to any power system 2. For example, the multiple power devices 30 may all be connected to the same power system 2, or all be connected to different power systems 2.

In the power management system 1, the power management server 10 transmits and receives messages to and from the control device 20 to manage the power consumption of consumers. The power management system 1 is used, for example, for demand response (DR), which manages the power consumption of consumers based on a request from an electric utility company in order to maintain the power supply and demand balance of the power system 2. In such a case, the power management server 10 transmits a message including control commands for the power equipment 30 to the control device 20 installed in the consumer facility, for example. On the other hand, the power management server 10 receives a message including information such as the power consumption and operating state of the power equipment 30 from the control device 20 in order to grasp the power consumption situation of the consumer. The power management server 10 may perform so-called feedback control, in which the control command to be transmitted to the control device 20 is modified based on the information received from the control device 20 in order to improve the accuracy of controlling the power consumption of the consumer.

The control device 20 transmits information measured at a specific timing, such as every hour or every minute, to the power management server 10. The power management server 10 is required to receive information measured by the control device 20 with low delay from the measurement in order to improve the accuracy of feedback control. For this reason, the power management server 10 may concentrate message reception from the control device 20 at a specific timing. In particular, when the number of control devices 20 connected to the power management server 10 increases, the reception of messages from the control device 20 may concentrate at a specific timing, and the processing load on the power management server 10 may temporarily increase. In addition, when the frequency of transmission of information from the control device 20 increases, the reception of messages from the control device 20 may concentrate at a specific timing, and the processing load on the power management server 10 may temporarily increase. For this reason, the power management server 10 transmits a message request to the control device 20 specifying the timing of message transmission during a period in which communication with the control device 20 increases, such as a demand response period. When the transmission timing is specified in the received message request, the control device 20 transmits a message to the power management server 10 at the specified transmission timing during that period. In this way, in the power management system 1, the timing at which the control device 20 sends messages to the power management server 10 can be controlled so that they are not concentrated at a specific time. This reduces the likelihood that the processing load on the power management server 10 will temporarily increase. This improves the usefulness of the technology that allows electric utilities to communicate with consumer facilities and manage the power consumption of consumers.

Next, each component of the power management system 1 will be described in detail.

(Power Management Server Configuration)
The configuration of the power management server 10 in the power management system 1 will be described in detail with reference to Fig. 2. Fig. 2 is a block diagram showing the configuration of the power management server 10 according to an embodiment of the present disclosure. As shown in Fig. 2, the power management server 10 includes a server communication unit 11, a server storage unit 12, a server output unit 13, and a server control unit 14. The server communication unit 11, the server storage unit 12, the server output unit 13, and the server control unit 14 are connected to each other so as to be able to communicate with each other via wire or wirelessly.

The server communication unit 11 includes a communication module connected to the network 40. The communication module is compatible with communication standards such as, but not limited to, a wired LAN (Local Area Network) or a wireless LAN, and may be compatible with any communication standard. In this embodiment, the power management server 10 is connected to a network 40 such as the Internet or a dedicated line via the server communication unit 11. This enables the power management server 10 to communicate with the control device 20.

The communication between the power management server 10 and the control device 20 may be realized according to any protocol. For example, a protocol conforming to Open ADR is used as the protocol, but is not limited to this, and a protocol conforming to a standard protocol such as ECHONET Lite, SEP (Smart Energy Profile), or KNX may be used as the protocol. In addition, a unique dedicated protocol may be used as the protocol.

The server memory unit 12 includes one or more memories. Each memory included in the server memory unit 12 may function, for example, as a main memory device, an auxiliary memory device, or a cache memory. The server memory unit 12 stores any information used in the operation of the power management server 10. The server memory unit 12 may be a volatile memory device or a non-volatile memory device. For example, the server memory unit 12 may store system programs, application programs, databases, etc. The information stored in the server memory unit 12 may be updatable, for example, with information obtained from the network 40 via the server communication unit 11.

The server memory unit 12 may store, for example, information about the control device 20. The information about the control device 20 may include information about the device type, information about the electric utility, and information about the control target. The information about the device type may include, for example, the manufacturer, model, or model number of the control device 20. The information about the electric utility may include, for example, information about an electric utility with which a consumer has a contract, or an electric utility such as a power generation business, a power transmission and distribution business, a retail business, or an aggregator that supplies power to the consumer facility in which the control device 20 is installed, such as an electric utility with which a consumer has a contract, or an electric power district that includes the consumer facility. The information about the control target may include, for example, the type, power consumption, or number of electric power equipment 30 controlled by the control device 20.

The server output unit 13 outputs information in the form of sound, vibration, image, or the like. The server output unit 13 may include at least one of a speaker, a vibrator, a display device, and the like. The server output unit 13 may output information such as the amount and frequency of messages received from the communicatively connected control device 20, or the processing load of the power management server 10.

The server control unit 14 includes one or more processors. The server control unit 14 may be configured with a processor such as a CPU (Central Processing Unit) that executes a program that defines a control procedure, or a dedicated processor specialized for specific processing. The server control unit 14 may control the server communication unit 11, the server storage unit 12, and the server output unit 13 described above in order to realize their functions.

The following describes the processing of the power management server 10, which is realized by the server control unit 14 controlling each function of the power management server 10. The power management server 10 communicates with the control device 20 that is communicatively connected. The power management server 10 transmits a message request to the control device 20, requesting that a message be sent. The message request transmitted from the power management server 10 may include any information.

The power management server 10 may transmit to the control device 20 a message request that specifies the timing of message transmission during a period in which a specific event is implemented. The transmission timing may be, for example, a timing repeated at a specific interval, but is not limited to this. This allows the power management server 10 to cause the control device 20 to transmit a message at the specified transmission timing during a period in which a specific event is implemented. The period in which a specific event is implemented may be, for example, a demand response period in which the above-mentioned demand response is implemented. In the following, the specific event is described as a demand response, but is not limited to this. In addition, the demand response may be, for example, an automated demand response (ADR) in which power equipment is automatically controlled by the control device 20 or the like, or a manual demand response (MDR) in which power equipment is controlled through human operation.

The power management server 10 may transmit a message request in which the transmission timing is specified by at least a time interval and an offset period. FIG. 3 is a diagram showing information included in the transmission timing according to an embodiment of the present disclosure. The offset period is a period during which the transmission of a message is permitted based on a point in time repeated at a predetermined time interval. The offset period may be a period from one point in time repeated at a predetermined time interval to the next point in time, and may be arbitrarily determined. For example, as shown in FIG. 3, the power management server 10 transmits a message request in which a time interval t and an offset period X are specified as the transmission timing. In this way, the power management server 10 may cause the control device 20 to transmit a message for each offset period X1 to X5 specified based on the points in time T1 to T5 repeated at the time interval t. The transmission timing is not limited to the time interval and offset period for transmitting the message, and may include any information specifying the timing for transmitting the message, such as a start time, an end time, a duration, and a number of repetitions.

The power management server 10 may specify the transmission timing for each control device 20 that transmits a message request. Alternatively, the power management server 10 may specify the transmission timing for each group of control devices 20 determined based on a predetermined condition.

For example, the specified condition may be a condition as to whether or not the control device 20 is the target of a demand response request during the demand response period. In such a case, the power management server 10 determines whether or not the control device 20 is the target of a demand response request. For example, the power management server 10 may determine whether or not the control device 20 is the target of a demand response request by receiving information about the control device 20 to be controlled from an information processing device of the electric utility requesting the demand response. Hereinafter, the demand response period is also referred to as a DR period, and a demand response request is also referred to as a DR request.

When the power management server 10 determines that the control device 20 is the target of a DR request in the DR period, the power management server 10 may transmit to the control device 20 a message request that specifies a first transmission timing as the timing for transmitting a message in the DR period. Also, when the power management server 10 determines that the control device 20 is not the target of a DR request in the DR period, the power management server 10 may transmit to the control device 20 a message request that specifies a second transmission timing as the timing for transmitting a message in the DR period.

4 is a diagram showing a plurality of transmission timings according to an embodiment of the present disclosure. As shown in FIG. 4, the power management server 10 may specify a first transmission timing by a time interval t and an offset period X for the control device 20 that is the target of the DR request. Also, the power management server 10 may specify a second transmission timing by a time interval t and an offset period Y for the control device 20 that is not the target of the DR request. As shown in FIG. 4, by shifting the offset period X of the control device 20 that is the target of the DR request from the offset period Y of the control device 20 that is not the target, the load of the message reception process from the control device 20 in the power management server 10 can be distributed. Also, the power management server 10 can prioritize processing of messages from the control device 20 that is the target of the DR request by setting the transmission timing of the control device 20 that is the target of the DR request to be earlier than the transmission timing of the other control devices 20. As a result, even if a delay occurs in the processing related to message reception from a control device 20 that is not the target of the DR request in the power management server 10 during the DR period, if the processing related to message reception from the control device 20 that is the target of the DR request has already been completed, the impact on power reduction control in the demand response can be reduced. The period specified by the first transmission timing and the period specified by the second transmission timing may be different periods that do not overlap, or may be periods that partially overlap.

The method by which the power management server 10 determines whether the control device 20 is the target of the DR request in the DR period is not limited to the above example. For example, when the power management server 10 receives a request for the amount of power reduction in the demand response from the information processing device of the electric utility requesting the demand response, the power management server 10 may narrow down the combination of control devices 20 that satisfy the requested amount of power reduction from among the control devices 20, and then determine whether the control device 20 is the target of the DR request in the DR period. Specifically, the power management server 10 compares the amount of power reduction requested in the demand response with the total amount of power reduction possible, which is the sum of the amount of power reduction possible in the power devices 30 controlled by the control devices 20 that are communicably connected. If the total amount of power reduction possible is greater than the requested amount of power reduction, the power management server 10 may select the control device 20 to be the target of the DR request based on a predetermined condition. For example, the predetermined condition may be a condition that prioritizes the power devices 30 that are the control targets of the control device 20 that consume less power. The specified condition may be to prioritize electric power equipment 30, such as a storage battery, that is the control target of the control device 20, that has a small degree of degradation. Alternatively, the specified condition may be to prioritize electric power equipment 30, such as a storage battery, that is the control target of the control device 20, that has a small fluctuation in the amount of power consumption. This can reduce the error between the amount of power that can be reduced and the amount of power that is actually reduced based on the DR request.

The power management server 10 may determine whether the control device 20 is the target of the DR request based on information about the control device 20, including the above-mentioned information on the device type, information on the electric utility, and information on the control target. For example, the power management server 10 may determine that a control device 20 of a specific manufacturer and a specific model number is the target of the DR request based on the information on the device type. The power management server 10 may determine that a control device 20 in a power district where demand response is implemented is the target of the DR request based on information on the electric utility. The power management server 10 may determine that a control device 20 whose controlled power equipment 30 includes a storage battery is the target of the DR request based on information on the control target. Alternatively, the power management server 10 may determine that a control device 20 of a specific manufacturer is the target of the DR request among the control devices 20 in a power district where demand response is implemented, based on information on the device type and information on the electric utility.

When the power management server 10 determines that multiple control devices 20 are the targets of the DR request, the power management server 10 may transmit a message request specifying the same transmission timing to the multiple control devices 20. When the power management server 10 determines that multiple control devices 20 are the targets of the DR request, the power management server 10 may transmit a message request specifying a different transmission timing to each of the multiple control devices 20. Alternatively, when the power management server 10 determines that multiple control devices 20 are the targets of the DR request, the power management server 10 may transmit a message request specifying a different transmission timing to each of the multiple control devices 20. For example, the multiple control devices 20 that are the targets of the DR request may be divided into multiple groups of control devices 20, and a different transmission timing may be specified for each group. This allows the power management server 10 to transmit messages to the power management server 10 for control devices 20 that are the targets of an event such as a demand response, without concentrating the messages at a specific timing.

(Configuration of the control device)
The configuration of the control device 20 in the power management system 1 will be described in detail with reference to Fig. 5. Fig. 5 is a block diagram showing the configuration of the control device 20 according to an embodiment of the present disclosure. As shown in Fig. 5, the control device 20 includes a communication unit 21, a storage unit 22, a measurement unit 23, an output unit 24, and a control unit 25. The communication unit 21, the storage unit 22, the measurement unit 23, the output unit 24, and the control unit 25 are connected to each other so as to be able to communicate with each other via wire or wirelessly.

The communication unit 21 includes a communication module. The communication unit 21 may include a first communication module connected to the network 40 and a second communication module connected to the power equipment 30 installed in the customer facility. Each of the first communication module and the second communication module corresponds to a communication standard such as, for example, a wired LAN, a wireless LAN, or a short-range wireless communication standard such as ZigBee (registered trademark), but is not limited to these and may correspond to any communication standard. As a result, the control device 20 is connected to the network 40 via the communication unit 21 and is capable of communicating with the power management server 10. The control device 20 is also capable of communicating with the power equipment 30 via the communication unit 21. The first communication module and the second communication module may correspond to the same communication standard, or may correspond to different communication standards.

The communication between the power management server 10 and the control device 20, and the communication between the control device 20 and the power equipment 30 may be realized according to any protocol. For example, a protocol conforming to the above-mentioned Open ADR may be used for the communication between the power management server 10 and the control device 20. Furthermore, a protocol conforming to ECHONET Lite may be used for the communication between the control device 20 and the power equipment 30. The communication between the power management server 10 and the control device 20, and the communication between the control device 20 and the power equipment 30 may conform to the same protocol, or may conform to different protocols. The protocol is not limited to Open ADR and ECHONET Lite, and may be a protocol conforming to a standard protocol such as SEP or KNX. Furthermore, a unique dedicated protocol may be used as the protocol.

The storage unit 22 includes one or more memories. Each memory included in the storage unit 22 may function, for example, as a main storage device, an auxiliary storage device, or a cache memory. The storage unit 22 stores any information used in the operation of the control device 20. The storage unit 22 may be a volatile storage device or a non-volatile storage device. For example, the storage unit 22 may store a system program, an application program, a database, and the like. The information stored in the storage unit 22 may be updatable, for example, with information acquired from the network 40 via the communication unit 21. The storage unit 22 may store, for example, information related to the power management server 10 that is communicatively connected, and information related to the power equipment 30 to be controlled.

The measurement unit 23 includes one or more sensors. The measurement unit 23 is, for example, a voltage sensor or a current sensor. However, the measurement unit 23 is not limited to these, and may include any sensor, such as a temperature sensor, that acquires information used to determine the power consumption or operating state of the electric power equipment 30 controlled by the control device 20. The measurement unit 23 may be, for example, a smart meter. The measurement unit 23 may be provided for each electric power equipment 30 controlled by the control device 20, or may be provided for multiple electric power equipment 30 so as to acquire information of multiple electric power equipment 30 collectively.

The output unit 24 outputs information in the form of sound, vibration, image, or the like. The output unit 24 may include at least one of a speaker, a vibrator, a display device, and the like. The output unit 24 may output, for example, information contained in a message request received from the power management server 10, or information contained in a transmission timing specified in the message request.

The control unit 25 includes one or more processors. The control unit 25 may be configured with a processor such as a CPU (Central Processing Unit) that executes a program that defines a control procedure, or a dedicated processor specialized for specific processing. The control unit 25 may control the communication unit 21, the memory unit 22, the measurement unit 23, and the output unit 24 described above in order to realize their functions. The control unit 25 may have a clock function that keeps track of the current time, which is used when sending a message at the sending timing specified in the message request.

The following describes the processing of the control device 20, which is realized by controlling each function of the control device 20 by the control unit 25. The control device 20 controls the electric power equipment 30. The electric power equipment 30 may include at least one of a load and a distributed power source, for example. The load is an equipment that consumes electric power supplied from the electric power system 2, such as an air conditioner, a lighting equipment, or a heat pump. The distributed power source is an equipment that can supply electric power to the electric power system 2, such as a storage battery, a solar cell, or a fuel cell. The control device 20 controls the electric power equipment 30 by communicating with the electric power equipment 30 via the communication unit 21. The control of the electric power equipment 30 by the control device 20 may be, for example, setting or changing the operating state of the electric power equipment 30, or acquiring information indicating the power consumption or operating state of the electric power equipment 30.

The control device 20 receives a message request from the power management server 10. The control device 20 transmits a message to the power management server 10 based on the message request received from the power management server 10. The message transmitted from the control device 20 may include any information.

When the control device 20 receives a message request from the power management server 10 specifying a message transmission timing during a period in which a specific event is implemented, the control device 20 transmits a message to the power management server 10 at the specified transmission timing during that period. The period in which a specific event is implemented may be, for example, the DR period described above. When the control device 20 receives a message request from the power management server 10, the control device 20 determines whether or not a message transmission timing is specified in the message request. For example, when the control device 20 receives a first message request specifying a first transmission timing as the message transmission timing during the DR period, the control device 20 may transmit a message to the power management server 10 at the first transmission timing during the DR period. Alternatively, when the control device 20 receives a second message request specifying a second transmission timing as the message transmission timing during the DR period, the control device 20 may transmit a message to the power management server 10 at the second transmission timing during the DR period.

As described above, the power management server 10 may transmit a message request in which the transmission timing is specified by at least the time interval t and the offset period X. When the control device 20 receives a message request in which the time interval t and the offset period X are specified, the control device 20 may transmit a message to the power management server 10 for each offset period X based on a point in time that is repeated at the time interval t during the DR period.

If the transmission timing is not specified in the message request received from the power management server 10, the control device 20 may transmit the message at any transmission timing. For example, if the transmission timing is not specified in the received message request, the control device 20 may continue to transmit the message to the power management server 10 at the transmission timing before the message request was received. Alternatively, the control device 20 may transmit the message to the power management server 10 at a transmission timing that is pre-stored as the transmission timing during normal times other than the DR period.

The message sent from the control device 20 to the power management server 10 may include, for example, information regarding power consumption by the power equipment 30 controlled by the control device 20. In such a case, the control device 20 may generate a message to be sent to the power management server 10 based on information regarding power consumption acquired by communicating with the power equipment 30, or information acquired by the measurement unit 23, as described above. The control device 20 can update the information stored in the power management server 10 by sending a message to the power management server 10 during the DR period.

(Power Management Method in Power Management System)
A power management method implemented in the power management system 1 will be described in detail with reference to Fig. 6 and Fig. 7. Fig. 6 is a flow diagram showing a flow of a process implemented by the power management server 10 in the power management system 1 according to an embodiment of the present disclosure. In the description of this process, an example will be described in which the power management server 10 specifies a transmission timing at which the control device 20 transmits a message during the DR period.

Step S101: The power management server 10 determines whether the control device 20 is the target of a DR request during the DR period.

Step S102: If it is determined that the control device 20 is the target of the DR request (Step S101-Yes), the power management server 10 transmits to the control device 20 a first message request that specifies a first transmission timing as the timing for transmitting a message during the DR period. If a protocol compliant with Open ADR is used for communication between the power management server 10 and the control device 20, an "oadrCreateReport" may be transmitted as the message request. The transmission timing may be specified by at least a time interval and an offset period. When an "oadrCreateReport" is transmitted as the message request, for example, a "reportBackDuration" element may be used to specify the time interval, and a "Tolerance" element may be used to specify the offset period.

Step S103: If it is determined that the control device 20 is not the target of the DR request (step S101-No), the power management server 10 sends a second message request to the control device 20, specifying a second transmission timing as the message transmission timing during the DR period.

Figure 7 is a flow diagram showing the flow of processing performed by the control device 20 in the power management system 1 according to an embodiment of the present disclosure. In the explanation of this processing, an example will be explained in which the power management server 10 specifies the timing of sending a message during the DR period for the control device 20.

Step S201: The control device 20 receives a message request from the power management server 10, specifying the timing for sending a message during the DR period.

Step S202: The control device 20 determines whether the message request received from the power management server 10 specifies the timing for sending a message during the DR period.

Step S203: If a transmission timing is specified in the received message request (step S202-Yes), the control device 20 transmits a message to the power management server 10 at the specified transmission timing during the DR period. If a protocol compliant with Open ADR is used for communication between the power management server 10 and the control device 20, for example, an "oadrUpdateReport" may be transmitted as the message.

Step S204: If the received message request does not specify a transmission timing (step S202-No), the control device 20 transmits the message at any transmission timing. For example, the control device 20 may continue to transmit the message at the transmission timing before the message request was received. Alternatively, the control device 20 may transmit the message at the transmission timing stored as the normal transmission timing.

As described above, the power management system 1 according to the present embodiment includes a control device 20 that controls the power equipment 30, and a power management server 10 that can communicate with the control device 20. When the power management server 10 determines that the control device 20 is a target of a demand response request during a demand response period, the power management server 10 transmits a first message request to the control device 20, specifying a first transmission timing as the transmission timing of a message during the demand response period. When the control device 20 receives the first message request, the control device 20 transmits a message to the power management server 10 at the first transmission timing during the demand response period. According to this configuration, in the power management system 1, the power management server 10 can transmit messages to the control device 20 without concentrating messages at a specific timing. This can distribute the processing load in the power management server 10 and reduce the likelihood of a temporary increase in the processing load. Therefore, the usefulness of the technology in which an electric utility communicates with a consumer facility to manage the power consumption of consumers is improved. Furthermore, by reducing the peak processing load in the power management server 10, the processing capacity required of the server device and the like that constitute the power management server 10 can be reduced.

In the power management system 1 according to this embodiment, the power management server 10 may transmit a first message request in which the first transmission timing is specified by at least a time interval and an offset period. When the control device 20 receives the first message request, the control device 20 may transmit a message to the power management server 10 for each offset period based on a point in time repeated at time intervals during a demand response period. With this configuration, the power management server 10 can distribute the load of message reception processing from the control device 20 by changing the time interval and offset specified in the message request. This improves the usefulness of the technology in which an electric utility communicates with consumer facilities to manage the power consumption of consumers.

In the power management system 1 according to the present embodiment, when the power management server 10 determines that the control device 20 is not the target of the demand response request, the power management server 10 may transmit a second message request to the control device 20, specifying a second transmission timing as the transmission timing of the message during the demand response period. When the control device 20 receives the second message request, the control device 20 may transmit a message to the power management server 10 at the second transmission timing during the demand response period. With this configuration, the load of the message reception process from the control device 20 on the power management server 10 can be distributed. In addition, the power management server 10 can prioritize processing of the message from the control device 20 that is the target of the DR request by having the control device 20 that is the target of the DR request transmit a message at an earlier timing than the transmission timing of the other control devices 20. This can reduce the impact on the demand response caused by the delay in the processing of the power management server 10 during the demand response period in the power management system 1.

In the power management system 1 according to this embodiment, the control device 20 transmits a message including information regarding power consumption by the power equipment 30 controlled by the control device 20. With this configuration, the power management server 10 can efficiently acquire information from the control device 20 to grasp the power consumption of consumers when the electric utility manages the power consumption of the consumers. This improves the usefulness of the technology that allows the electric utility to manage the power consumption of consumers by communicating with consumer facilities.

The power management server 10 according to this embodiment is capable of communicating with the control device 20 that controls the power equipment 30. When the power management server 10 determines that the control device 20 is the target of a demand response request during the demand response period, the power management server 10 transmits to the control device 20 a message request that specifies the timing of message transmission during the demand response period. With this configuration, the power management server 10 can cause the control device 20 to transmit messages without concentrating them at a specific timing. This can distribute the processing load on the power management server 10 and reduce the likelihood of a temporary increase in the processing load. This improves the usefulness of the technology in which an electric utility communicates with consumer facilities to manage the power consumption of consumers.

The control device 20 according to this embodiment is capable of communicating with the power management server 10 and controls the power equipment 30. When the control device 20 receives a message request from the power management server 10 specifying the timing of message transmission during the demand response period, the control device 20 transmits a message to the power management server 10 at the transmission timing during the demand response period. With this configuration, the control device 20 can transmit messages to the power management server 10 without concentrating messages at a specific timing. This can distribute the processing load on the power management server 10 and reduce the likelihood of a temporary increase in the processing load. This improves the usefulness of the technology in which an electric utility communicates with consumer facilities to manage the power consumption of consumers.

The power management method according to the present embodiment is a power management method for a power management system 1 including a control device 20 that controls power devices 30 and a power management server 10 that can communicate with the control device 20. The power management method includes a step in which, when the power management server 10 determines that the control device 20 is a target of a demand response request during a demand response period, the power management server 10 transmits a message request to the control device 20 specifying a timing for transmitting the message during the demand response period. The power management method includes a step in which, when the control device 20 receives the message request, the control device 20 transmits a message to the power management server 10 at a transmission timing during the demand response period. According to this configuration, in the power management system 1, the power management server 10 can cause the control device 20 to transmit messages without concentrating them at a specific timing. This can distribute the processing load in the power management server 10 and reduce the likelihood of a temporary increase in the processing load. Therefore, the usefulness of the technology in which an electric utility manages the power consumption of consumers by communicating with consumer facilities is improved.

The above-described embodiments have been described as representative examples, but it will be apparent to those skilled in the art that many modifications and substitutions can be made within the spirit and scope of the present disclosure. Therefore, the present disclosure should not be interpreted as being limited by the above-described embodiments, and various modifications or changes are possible without departing from the scope of the claims. For example, the functions included in each means or step can be rearranged so as not to cause logical inconsistencies, and multiple means or steps can be combined into one or divided.

For example, in the above-described embodiment, the control device 20 is described as being a HEMS, but this is not limited thereto. The control device 20 may be any control device that controls the electric power equipment 30 installed in the customer facility. For example, the control device 20 may be a Building Energy Management System (BEMS) that controls the electric power equipment 30 installed in a building or the like. Alternatively, the control device 20 may be a Battery Management System (BMS) that controls a power storage device as the electric power equipment 30. Furthermore, the control device 20 may be a control device incorporated in the electric power equipment 30 such as a load and a distributed power source.

In addition, for example, in the above embodiment, the period during which a specified event is implemented is described as a demand response period during which demand response is implemented, but this is not limited to the above. The period during which a specified event is implemented may be a period during which any event is implemented that involves the transmission of a message from the control device 20 to the power management server 10. In such a case, in the above description, demand response should be interpreted as any event.

In addition, for example, in the above-described embodiment, the control device 20 has been described as being configured as an information processing device installed in the consumer facility, but this is not limited to the above. The control device 20 may be configured such that all or part of its processing and functions are provided via the network 40 by a group of information processing devices configured of a plurality of information processing devices, such as a cloud server or a blockchain. Similarly, the power management server 10 may be configured such that all or part of its processing and functions are provided via the network 40 by a group of information processing devices. In such a case, the control device 20 and the power management server 10 may be considered to include a group of information processing devices, such as a cloud server or a blockchain.

Reference Signs List 1 Power management system 2 Power system 10 Power management server 11 Server communication unit 12 Server storage unit 13 Server control unit 14 Server control unit 20 Control device 21 Communication unit 22 Storage unit 23 Measurement unit 24 Output unit 25 Control unit 30 Power device 40 Network

Claims (8)

A power management system including a control device that controls power equipment and a power management server that can communicate with the control device,
when it is determined that the control device is a target of a demand response request in a demand response period, the power management server transmits to the control device a first message request, the first message request specifying a first transmission timing as a transmission timing of a message in the demand response period by at least a time interval and an offset period;
A power management system in which, when the control device receives the first message request, it transmits a message to the power management server during the offset period based on a point in time that is repeated at the time interval during the demand response period. when it is determined that the control device is not a target of the demand response request, the power management server transmits to the control device a second message request that specifies a second transmission timing as a message transmission timing during the demand response period;
The power management system according to claim 1 , wherein, when the control device receives the second message request, the control device transmits a message to the power management server at the second transmission timing during the demand response period. The power management system according to claim 1 or 2, wherein the control device transmits the message including information regarding power consumption by the power device controlled by the control device. A power management server capable of communicating with a control device that controls power equipment,
When it is determined that the control device is a target of a demand response request during a demand response period, a message request is transmitted to the control device, the message request specifying a transmission timing of a message during the demand response period by at least a time interval and an offset period;
A power management server that, when the control device receives a first message request, causes the power management server to transmit a message during the offset period based on a point in time that is repeated at the time interval during the demand response period. A control device capable of communicating with a power management server and controlling power equipment,
A control device that, when receiving a message request from the power management server in which the timing of transmitting a message during a demand response period is specified by at least a time interval and an offset period, transmits a message to the power management server during the offset period based on a point in time that is repeated at the time interval during the demand response period. A power management method for a power management system including a control device that controls power equipment and a power management server that can communicate with the control device,
a step of transmitting a message request to the control device when the power management server determines that the control device is a target of a demand response request during a demand response period, the message request specifying a message transmission timing during the demand response period by at least a time interval and an offset period;
When the control device receives the message request, the control device transmits a message to the power management server during the offset period based on a point in time that is repeated at the time interval during the demand response period;
23. A power management method comprising: A power management system including a control device that controls power equipment and a power management server that can communicate with the control device,
when it is determined that the control device is a target of a demand response request in a demand response period, the power management server transmits to the control device a first message request that specifies a first transmission timing as a transmission timing of a message in the demand response period;
When the control device receives the first message request, the control device transmits a message to the power management server at the first transmission timing during the demand response period;
when it is determined that the control device is not a target of the demand response request, the power management server transmits to the control device a second message request that specifies a second transmission timing as a transmission timing of a message during the demand response period;
When the control device receives the second message request, the control device transmits a message to the power management server at the second transmission timing during the demand response period. A power management system including a control device that controls power equipment and a power management server that can communicate with the control device,
The power management server includes:
Selecting targets for a demand response request during a demand response period based on predetermined conditions;
When it is determined that the control device is a target of the demand response request in the demand response period, a first message request is transmitted to the control device, the first message request specifying a first transmission timing as a transmission timing of a message in the demand response period;
When the control device receives the first message request, the control device transmits a message to the power management server at the first transmission timing during the demand response period;
A power management system, wherein the predetermined condition includes giving priority to an electric device that is the control target of the control device and that has small fluctuations in power consumption.

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