JP2014039352A - Energy management apparatus, energy management system, and energy management method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an energy management apparatus, an energy management system, and an energy management method which can utilize information more effectively which is acquired in a system for controlling and managing an energy demand state.SOLUTION: From power information on three elements consisting of power generated in a power generation facility, charge/discharge power in a power storage facility, and power consumption of a load 19, power information on two elements is acquired. The energy management apparatus has a control section for calculating power information on one element after excluding the two elements from the power information on the three elements in a self-sustaining operation state, on the basis of the power information on the two elements.

Description

  The present invention relates to an energy management device, an energy management system, and an energy management method.

  2. Description of the Related Art In recent years, as an example of an energy management device provided for each power consumer, a technology for controlling load devices and distributed power sources provided for the power consumer by a power management device (for example, HEMS: Home Energy Management System) is known. (See Patent Document 1). The power management device acquires changes over time of various power amounts such as the power consumption of load devices controlled or monitored by the power management device, the amount of power generated by distributed power sources, and the amount of power supplied from commercial power sources. Can be stored.

JP 2003-309928 A

  Further, in order to make more effective use of information on various electric energy acquired by the energy management device, further detailed studies have been required.

  Accordingly, an object of the present invention made in view of such circumstances is an energy management device, an energy management system, and an energy management method capable of more effectively utilizing information acquired in a system for controlling and managing energy supply and demand. Is to provide.

In order to solve the above problems, an energy management device according to the present invention provides:
Of the three elements of power information consisting of the generated power of the power generation facility, the charge / discharge power of the storage facility, and the power consumption of the load, the power information of any two elements is acquired, and the self-sustained operation state based on the power information of the two elements And a control unit that calculates power information of one element excluding the two elements of the power information of the three elements.

Moreover, the energy management apparatus according to the present invention includes:
The control unit calculates power information of the generated power of the power generation facility in a self-sustaining operation state based on power information of charge / discharge power of the power storage facility and power consumption of the load.

Moreover, the energy management apparatus according to the present invention includes:
The control unit is configured to generate power of the power generation facility when the power generation facility and the power storage facility cannot simultaneously supply power to the load from both sides and the power storage facility is in a discharged state during the self-sustained operation. The power is set to 0.

Moreover, the energy management apparatus according to the present invention includes:
The control unit sets the generated power of the power generation facility equal to the power consumption of the load when the power storage facility is in a standby state during a self-sustaining operation.

Moreover, the energy management apparatus according to the present invention includes:
The control unit generates power of the power generation facility when the power generation facility and the power storage facility cannot supply power simultaneously to the load from both sides and the power storage facility is in a charged state during the self-sustained operation. The power is the sum of the power consumption of the load and the charging power of the power storage facility.

Moreover, the energy management apparatus according to the present invention includes:
The control unit is capable of simultaneously supplying power to the load from both the power generation facility and the power storage facility during self-sustained operation, and when the power storage facility is in a discharged state, the generated power of the power generation facility Is the difference between the power consumption of the load and the discharge power of the power storage facility.

Moreover, the energy management apparatus according to the present invention includes:
It further has a communication unit capable of acquiring information indicating whether or not it has a configuration that enables simultaneous output to the load from the power generation facility and the power storage facility,
The control unit performs calculation according to whether or not simultaneous output to the load is possible based on information received by the communication unit.

Moreover, the energy management system according to the present invention includes:
Power generation facilities, storage facilities and loads;
Of the three elements of power information consisting of the generated power of the power generation equipment, the charge / discharge power of the power storage equipment and the power consumption of the pre-determined load, obtain power information of any two elements, and based on the power information of the two elements In the self-sustained operation state, a control unit that calculates power information of one element excluding the two elements among the power information of the three elements is provided.

The energy management method according to the present invention includes:
Obtaining power information of any two elements among the power information of the three elements consisting of the generated power of the power generation facility, the charge / discharge power of the power storage facility and the power consumption of the load;
Based on the power information of the two elements, a step of calculating power information of one element excluding the two elements out of the power information of the three elements in the self-sustaining operation state is included.

  According to the energy management device, energy management system, and energy management method of the present invention configured as described above, information acquired in a system that controls and manages the energy supply and demand state can be used more effectively.

It is a functional block diagram which shows schematic structure of the energy management system which concerns on one Embodiment of this invention. It is a functional block diagram which shows schematic structure of the energy management apparatus in FIG. It is a flowchart which shows operation | movement of the energy management system which concerns on one Embodiment of this invention. It is a flowchart which shows the operation | movement concerning calculation of the generated electric power by the energy management system which concerns on one Embodiment of this invention.

  Embodiments of the present invention will be described below.

(Embodiment)
First, the energy management system according to the first embodiment will be described. The energy management system according to this embodiment includes, in addition to power supplied from a commercial power system, a solar battery that supplies power by, for example, solar power generation as a power generation facility, and a power storage facility that can charge and discharge power A storage battery can be provided. The power generation facility is not limited to the solar cell, and may be various power generation systems such as a fuel cell system including a fuel cell such as a SOFC (Solid Oxide Fuel Cell). In the present embodiment described below, the power generation facility includes a solar battery, and the power storage facility includes a storage battery such as a lithium ion battery or a nickel metal hydride battery.

  FIG. 1 is a functional block diagram illustrating a schematic configuration of an energy management system according to the present embodiment. As shown in FIG. 1, an energy management system 10 according to the present embodiment includes a communication terminal 11, an energy management device 12, a smart meter 13, a solar battery power conditioner 14a, a storage battery power conditioner 14b, a solar battery 15, and a storage battery. 16 is comprised.

  In FIG. 1, a solid line connecting each functional block represents a flow of electric power. Moreover, in FIG. 1, the broken line which connects each functional block represents the flow of the control signal or the information communicated. The communication indicated by the broken line may be wired communication or wireless communication.

  Various systems can be employed for communication of control signals and information. For example, for communication between the energy management device 12, the communication terminal 11, the smart meter 13, the solar battery power conditioner 14a, and the storage battery power conditioner 14b, communication using a short-range communication method such as ZigBee (registered trademark) is adopted. be able to. In addition, various communication media such as infrared communication and power line communication (PLC) can be used for communication between the energy management device 12 and the general load 18 and the specific load 19. In addition, on lower layers such as the physical layer suitable for each communication, various protocols such as ZigBee SEP2.0 (Smart Energy Profile2.0), ECHONET Lite (registered trademark), etc. are defined. It may be operated.

  In addition to the electric power supplied from the commercial power supply system 50, the energy management system 10 supplies the electric power generated by the solar battery 15 and the electric power discharged from the electric power charged in the storage battery 16 to the general load 18 and the specific load 19. It can be supplied.

  The communication terminal 11 can display the information acquired from the energy management device 12 and the energy management state. The communication terminal 11 can be various terminals such as a mobile terminal, a personal computer (PC), a notebook personal computer, or a tablet terminal installed with application software.

  The communication terminal 11 can include, for example, a liquid crystal display (LCD) or an organic EL display, and can display information acquired from the energy management device 12 as a numerical value or a graph image.

  The communication terminal 11 includes a touch panel, for example, and can detect an operation that the user directly touches with a finger or the like. Moreover, the communication terminal 11 can be provided with an operation means of a type having a physical key. Control unique to the present embodiment of the communication terminal 11 will be described later.

  The communication terminal 11 performs wireless communication with the energy management device 12, for example. That is, the communication terminal 11 transmits a control signal and / or information to the energy management device 12 and receives a control signal and / or information from the energy management device 12.

  The energy management device 12 controls and manages the power of each device in the energy management system 10 shown in FIG. Details of the configuration of the energy management device 12 will be described later.

  The smart meter 13 is connected to the commercial power supply system 50 and measures electric power (purchasing power) supplied from the commercial power supply system 50. The smart meter 13 is also connected to the distribution board 17 to measure the power generated by the solar battery 15 and sold from the solar battery power conditioner 14a to the power company via the distribution board 17. The smart meter 13 can transmit the measured power to the energy management device 12.

  In addition, the smart meter 13 can receive information such as prediction about power from a system EMS (Energy Management System) 60. Here, the system EMS 60 is a facility that performs various predictions and controls related to electric power, and is generally installed in an electric power company, for example. As the system EMS 60, for example, one constituting an MDMS (meter data management system) can be adopted. This system EMS 60 has a database 61 that stores information on various types of power, and can also collect and store information on the results measured by the smart meter 13. The system EMS 60 can be connected to a network 70 such as the Internet.

  The solar battery power conditioner 14a and the storage battery power conditioner 14b convert DC power supplied from the solar battery 15 and storage battery 16 to AC power, respectively. The solar battery power conditioner 14 a and the storage battery power conditioner 14 b supply the converted AC power to the general load 18 and the specific load 19 via the distribution board 17. Further, the solar battery power conditioner 14 a can also sell the converted AC power to the power company via the distribution board 17 when there is surplus in the power generated by the solar battery 15. In addition, the storage battery power conditioner 14 b can convert AC power supplied from the commercial power supply system 50 into DC power for charging the storage battery 16.

  The solar cell power conditioner 14a can transmit information on the generated power of the solar cell 15 to the energy management device 12 in a message format that is predetermined in the protocol to be used. The storage battery power conditioner 14b can transmit information on the charge / discharge power of the storage battery 16 to the energy management device 12 in a message format predetermined in the protocol to be used.

  The solar cell 15 generates power using sunlight. The solar cell 15 converts sunlight energy into DC power. In this embodiment, the solar cell 15 assumes a mode in which, for example, a solar panel is installed on the roof of a house and power is generated using sunlight. However, in the present invention, the solar cell 15 is an example, and any solar cell 15 can be adopted as long as it can convert natural energy into electric power.

  As described above, the electric power generated by the solar cell 15 can be supplied to the general load 18 and the specific load 19 and / or sold to an electric power company after being converted into alternating current by the solar cell power conditioner 14a. . Further, the power generated by the solar battery 15 can be supplied to the storage battery 16 and charged, and further, a configuration in which the power is supplied to the general load 18 and the specific load 19 in a direct current state may be used.

  The storage battery 16 can supply electric power by discharging the electric power charged in the storage battery. The storage battery 16 can be charged with electric power supplied from the commercial power supply system 50 or the solar battery 15. As shown in FIG. 1, the electric power discharged from the storage battery 16 can also be supplied to the general load 18 and the specific load 19.

  The storage battery 16 always constitutes one of three states: a discharged state in which charged power is discharged, a standby state in which neither charging nor discharging is performed, or a charged state in which power is charged. The storage battery 16 can transmit to the energy management apparatus 12 which state is among the three states by communication. Moreover, the storage battery 16 can detect the power failure of a system | strain and can transmit to the energy management apparatus 12 by communication.

  The distribution board 17 distributes the supplied power to the general load 18.

  In FIG. 1, the general load 18 connected to the energy management system 10 can be an arbitrary number. These general loads 18 are various electric appliances, such as a television, an air conditioner, and a refrigerator, for example.

  The specific load 19 is, for example, lighting, TV (television receiver), refrigerator, electric fan, charging of mobile terminals such as mobile phones, communication devices such as routers, personal computers (PCs), and various load devices such as HEMS. Can do. That is, it is possible to receive power supply from the storage battery 16 and the solar battery 15 even during a power failure.

  Next, the energy management apparatus 12 according to the present embodiment will be further described.

  FIG. 2 is a functional block diagram showing a schematic configuration of the energy management device 12 according to the present embodiment. The energy management device 12 is, for example, a HEMS, and includes a communication unit 23, a control unit 24, and an acquisition unit 26.

  The communication unit 23 is an interface, for example, and includes a control signal from the control unit 24 between the communication terminal 11, the smart meter 13, the solar battery power conditioner 14 a, the storage battery power conditioner 14 b, the general load 18, and the specific load 19. Send and receive various information.

For example, the communication unit 23 can receive, from the smart meter 13, power information for power purchase from the commercial power supply system 50 and / or power information for power sale to the commercial power supply system 50. Furthermore, the communication unit 23 can receive information such as demand response (DR) from an electric power company or the like via the smart meter 13. In addition, the communication unit 23 is connected to the general load via the branch branched from the solar battery power conditioner 14a and the storage battery power conditioner 14b to the solar battery 15, the storage battery 16, and the commercial power supply system 50 by the distribution board 17. The power information supplied to 18 and the specific load 19 can be acquired via sensors provided in each branch. Moreover, the communication part 23 can receive the generated electric power information which the solar cell 15 generated from the solar cell power conditioner 14a. The communication unit 23 can also directly receive power information (that is, charging power information) charged in the storage battery 16 from the storage battery power conditioner 14b. The communication unit 23 can also directly receive power consumption information from the general load 18 and the specific load 19. In addition, the communication unit 23 can acquire various information from the network 70. The communication unit 23 can also communicate with the communication terminal 11.
Communication with each of the devices is performed in a predetermined message format in accordance with various protocols.

  Further, the communication unit 23 can acquire a control signal from the communication terminal 11, and the communication unit 23 can transmit information indicating the state of power control and management in the energy management system 10 to the communication terminal 11.

  Based on various information received by the communication unit 23, the control unit 24 generates a control signal for controlling the power of each device in the energy management system 10 and / or information to be transmitted to the communication terminal 11.

  The control unit 24 has a database 25 for storing various collected information. The database 25 can be configured by an arbitrary memory device or the like, and may be connected to the outside of the energy management device 12 or may be built in the energy management device 12. The acquisition unit 26 reads and writes information from and to the database 25 under the control of the control unit 24.

  The control unit 24 acquires information acquired by the communication unit 23, for example, the power purchased from the commercial power supply system 50, the power sold to the commercial power supply system 50, the power generated by the solar battery 15, and the charge / discharge power of the storage battery 16. The power information such as the power consumption of the general load 18 and the specific load 19 can be stored in the database 25.

  Here, the connection at the time of a system power failure in the energy management system 10 will be described. At the time of a power failure when the power supply from the commercial power supply system 50 is stopped, the solar battery power conditioner 14a independently outputs the electric power generated by the solar battery 15, and the storage battery 16 and / or the specified power via the storage battery power conditioner 14b. Supply to load 19. Further, the storage battery power conditioner 14 b supplies only the specific load 19 with the power discharged from the storage battery 16. Such a connection configuration is referred to as “AC link connection”.

  The energy management device 12 receives the system power outage information from the storage battery 16, receives the system power outage information from the solar battery 15, and the measured voltage at the main of the distribution board 17 is 0. The operation can be determined. When the energy management device 12 receives the system power outage information or detects that the measured voltage at the trunk of the distribution board 17 is 0, the energy management device 12 disconnects the storage battery power conditioner 14b and the solar battery power conditioner 14a from the system. Then, a control signal based on a predetermined message format in the protocol being used may be transmitted so as to switch to “AC link connection”. In this case, the storage battery power conditioner 14b and the solar battery power conditioner 14a switch to “AC link connection” after receiving the control signal. When the switching is completed, a signal indicating the completion is transmitted to the control unit 24 of the energy management device 12. Send to. When it is determined that the control unit 24 of the energy management apparatus 12 is switched to “AC link connection” and is operating independently, the control unit 24 calculates power information during the AC link operation. Can do.

  Here, an example of a method for calculating the generated power of the solar cell 15 performed by the control unit 24 of the energy management device 12 at the time of a system power failure (self-sustaining operation and AC link connection) will be described. A case will be described as an example where supply of the generated power of the solar battery 15 and supply of the discharge power of the storage battery 16 cannot be performed simultaneously with respect to the specific load 19.

  The communication unit 23 of the energy management device 12 receives charge / discharge power of the storage battery 16 and power consumption of the specific load 19. In addition, the communication unit 23 receives which of the three states the storage battery 16 is in.

  The control unit 24 sets the generated power of the solar battery 15 to 0 when the storage battery 16 is in a discharged state at the time of a system power failure (self-sustained operation and AC link connection). That is, the control unit 24 calculates electric power on the assumption that no electric power is supplied from the solar cell 15. In addition, when the storage battery 16 is in a standby state during a system power failure, the control unit 24 sets the generated power of the solar battery 15 to a value equal to the power consumption of the specific load 19. That is, the control unit 24 calculates the power assuming that the generated power of the solar cell 15 is supplied only to the specific load 19. In addition, when the storage battery 16 is in a charged state, the control unit 24 sets the generated power of the solar battery 15 to the total value of the power consumption of the specific load 19 and the charge power of the storage battery 16. That is, the control unit 24 calculates the power on the assumption that the generated power of the solar battery 15 is supplied to the specific load 19 and further surplus power is supplied to the storage battery 16.

  Although the calculation method of the generated power of the solar cell 15 has been described above, the present invention is not limited to this, and other power may be calculated. For example, it is also possible to calculate the power consumption of the specific load 19 at the time of a system power failure (self-sustaining operation and AC link connection) based on the generated power of the solar battery 15 and the charge / discharge power of the storage battery 16. That is, the control unit 24 sets the power consumption of the specific load 19 to a value equal to the discharge power of the storage battery 16 when the storage battery 16 is in a discharged state. In addition, the control unit 24 sets the power consumption of the specific load 19 as the generated power of the solar battery 15 when the storage battery 16 is in a standby state. In addition, when the storage battery 16 is in a charged state, the control unit 24 sets the power consumption of the specific load 19 to a value obtained by subtracting the charging power of the storage battery 16 from the generated power of the solar battery 15.

  That is, the control unit 24 of the energy management device 12 acquires power information of any two elements among the three elements of power information including the generated power of the solar battery 15, the charge / discharge power of the storage battery 16, and the power consumption of the specific load 19. Then, based on the power information of the two elements, the power information of one element excluding the two elements out of the power information of the three elements is calculated.

  Next, in the energy management system 10 according to the embodiment of the present invention, the energy management device 12 receives the charge / discharge power of the storage battery 16 and the power consumption of the specific load 19 and calculates the generated power of the solar battery 15. Will be described with reference to the flowchart shown in FIG.

  First, the energy management device 12 completes switching in response to the switching instruction after the control unit 24 instructs the storage battery power conditioner 14b or the solar battery power conditioner 14a to switch to independent operation and AC link connection (step S1). Receive the message. Thereafter, the communication unit 23 of the energy management device 12 receives information on various types of power (charge / discharge power of the storage battery 16 and power consumption of the specific load 19) (step S2). Next, the communication unit 23 receives from the storage battery 16 a message indicating a status indicating which of the three states the storage battery 16 is in (step S3).

  Subsequently, the control unit 24 of the energy management device 12 calculates the generated power of the solar cell 15 based on the received information on the various powers (step S4). Calculation of the generated power in step S4 will be described with reference to the flowchart shown in FIG.

  First, the control unit 24 of the energy management device 12 determines the state of the storage battery 16 based on the information received from the storage battery 16 (step S41). Depending on the state of the storage battery 16, the process proceeds to step S42 to step S44, respectively.

  When the storage battery 16 is in a discharged state, the control unit 24 sets the generated power of the solar battery 15 to 0 (step S42). Then, the process ends.

  On the other hand, when the storage battery 16 is in a standby state, the generated power of the solar battery 15 is set to a value equal to the power consumption of the specific load 19 (step S43). Then, the process ends.

  On the other hand, when the storage battery 16 is in a charged state, the control unit 24 sets the generated power of the solar battery 15 to the total value of the power consumption of the specific load 19 and the charge power of the storage battery 16 (step S44). Then, the process ends. After any one of steps S42 to S44 is completed, the process proceeds to step S5 in FIG.

  Subsequently, the control unit 24 stores the calculated power information in the database 25 (step S5).

  Subsequently, the communication terminal 11 transmits a power information request signal conforming to a message format defined in a protocol used between the communication terminal 11 and the energy management apparatus 12 to the energy management apparatus 12 by a user operation. (Step S6).

  Subsequently, the control unit 24 of the energy management apparatus 12 requests power information from the database 25 in response to a request from the communication terminal 11, and acquires the power information from the database 25 (step S7).

  Subsequently, the control unit 24 transmits power information in a prescribed format to the communication terminal 11 via the communication unit 23 (step S8). And the communication terminal 11 displays electric power information as a numerical value or graph information corresponding to the acquired information on a liquid crystal display etc. (step S9).

  Here, the calculation of the power generated by the solar cell 15 can be performed by the communication terminal 11 based on various types of power information acquired via the energy management device 12 without being performed by the energy management device 12. The information transmitted from the energy management device 12 to the communication terminal 11 is different between the case where the energy management device 12 calculates the generated power and the case where the communication terminal 11 calculates the generated power. Specifically, in the former case, graph information or imaged information is transmitted in a form conforming to a message format defined in the protocol used, and in the latter case, numerical information is transmitted. Thus, the latter case is useful for traffic because the transmitted information is simple and has a small capacity, but in the former case, a general-purpose communication terminal that is not equipped with a calculation processing program. However, both have excellent merits such as being able to become the communication terminal 11.

  Thus, according to this embodiment, the power information of the generated power of the solar battery 15, the charge / discharge power of the storage battery 16, and the power consumption of the specific load 19 can be displayed on the communication terminal 11 even during a system power failure. That is, the remaining one piece of power information can be calculated based on any two pieces of power information among the generated power of the solar battery 15, the charge / discharge power of the storage battery 16, and the power consumption of the specific load 19. Therefore, the present invention is particularly effective when, for example, the accuracy of any one of the power information of the solar battery 15, the charge / discharge power of the storage battery 16 and the power consumption of the specific load 19 is low or cannot be obtained. It is.

  Here, in the previous embodiment, the case where power supply from the solar cell 15 to the specific load 19 is impossible during the power supply from the storage battery 16 to the specific load 19 has been described. It is possible that the power supply from the solar cell 15 to the specific load 19 is possible even during the power supply to.

  As an embodiment in this case, while the storage battery power conditioner 14 b is in an autonomous operation and AC link connection state, the power from the solar battery 15 is supplied to the specific load 19 while the power from the storage battery 16 is also supplied to the specific load 19 at the same time. For example, in step 1 of FIG. 3 (when discriminating AC link switching), the energy management device 12 acquires information on whether or not the configuration of simultaneous supply that can be supplied is obtained from the storage battery power conditioner 14b. You may do it. The message indicating the presence / absence of such a simultaneous supply configuration also conforms to the format defined by the protocol in use. Based on this, the energy management device 12 determines whether or not the storage battery power conditioner 14b has a simultaneous supply configuration.

  Next, when it is determined that the energy management device 12 does not have a configuration of simultaneous supply in a state of independent operation and AC link connection, the description is omitted because it is the same as the embodiment described above, Since there is a slight difference when there is a simultaneous supply configuration, explanation will be given.

  That is, when the storage battery 16 is in a discharged state and there is no simultaneous supply configuration, the specific load 19 is not supplied with the generated power from the solar cell, but there is a configuration for simultaneous discharge power supply of the storage battery 16. In this case, the specific load 19 can be supplied with power generated from the solar cell. Therefore, when the storage battery 16 is in a discharged state and has a simultaneous supply configuration, the energy management device 12 can calculate the generated power of the solar battery 15 based on the difference between the power consumption of the specific load 19 and the discharge power of the storage battery 16. .

  Moreover, the solar battery power conditioner 14a and the storage battery power conditioner 14b can be configured as one power conditioner system.

  In addition, the example in which power is supplied by AC from the storage battery power conditioner 14b and the solar battery power conditioner 14a to the specific load 19 during the independent operation has been described.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various variations and modifications based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, the functions included in each means, each step, etc. can be rearranged so that there is no logical contradiction, and a plurality of means, steps, etc. can be combined into one or divided. .

DESCRIPTION OF SYMBOLS 10 Energy management system 11 Communication terminal 12 Energy management apparatus 13 Smart meter 14a Solar battery power conditioner 14b Storage battery power conditioner 15 Solar battery 16 Storage battery 17 Distribution board 18 General load 19 Specific load 23 Communication part 24 Control part 25 Database 26 Acquisition 50 commercial power system 60 system EMS
61 database 70 network

Claims (9)

Of the three elements of power information consisting of the generated power of the power generation facility, the charge / discharge power of the storage facility, and the power consumption of the load, the power information of any two elements is acquired, and the self-sustained operation state based on the power information of the two elements An energy management apparatus comprising: a control unit that calculates power information of one element excluding the two elements of the power information of the three elements.   The said control part calculates the electric power information of the electric power generation of the said electric power generation equipment in a self-sustaining operation state based on the electric power information of the charging / discharging electric power of the said electrical storage equipment, and the electric power consumption of the said load, The electric power information of the said electric power generation equipment is characterized by the above-mentioned. The energy management device described in 1.   The control unit is configured to generate power of the power generation facility when the power generation facility and the power storage facility cannot simultaneously supply power to the load from both sides and the power storage facility is in a discharged state during the self-sustained operation. The energy management apparatus according to claim 2, wherein the power is set to zero.   3. The energy management according to claim 2, wherein the control unit sets the generated power of the power generation facility equal to the power consumption of the load when the power storage facility is in a standby state during the independent operation. apparatus.   The control unit generates power of the power generation facility when the power generation facility and the power storage facility cannot supply power simultaneously to the load from both sides and the power storage facility is in a charged state during the self-sustained operation. The energy management apparatus according to claim 2, wherein the power is a sum of power consumption of the load and charging power of the power storage facility.   The control unit is capable of simultaneously supplying power to the load from both the power generation facility and the power storage facility during self-sustained operation, and when the power storage facility is in a discharged state, the generated power of the power generation facility The energy management device according to claim 2, wherein the difference is a difference between the power consumption of the load and the discharge power of the power storage facility. It further has a communication unit capable of acquiring information indicating whether or not it has a configuration that enables simultaneous output to the load from the power generation facility and the power storage facility,
The energy management according to any one of claims 1 to 6, wherein the control unit performs a calculation according to whether simultaneous output to the load is possible or not based on information received by the communication unit. apparatus. Power generation facilities, storage facilities and loads;
Of the power information of the three elements consisting of the generated power of the power generation equipment, the charge / discharge power of the power storage equipment and the power consumption of the load, obtain power information of any two elements, based on the power information of the two elements, An energy management system comprising: a control unit that calculates power information of one element excluding the two elements among the power information of the three elements in a self-sustaining operation state. Obtaining power information of any two elements among the power information of the three elements consisting of the generated power of the power generation facility, the charge / discharge power of the power storage facility and the power consumption of the load;
An energy management method, comprising: calculating power information of one element excluding the two elements out of the power information of the three elements in a self-sustaining operation state based on the power information of the two elements.

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