JP6180638B2 - Data processing apparatus, energy management system, data processing method and program - Google Patents

Description

  The present invention relates to a data processing device, an energy management system, a data processing method, and a program.

  A HEMS (Home Energy Management System) that manages energy by measuring power consumed in a house is known. In HEMS, for example, an energy balance in a house is presented to the user. Thereby, the user can efficiently operate the electric device installed in the house.

  In recent years, there has been an increasing interest in housing with a power storage system. A power storage system is a system that efficiently operates power stored in a power storage device. In a house equipped with a power storage system, even if power supply from the commercial power system is stopped, the power stored in the power storage device can be used. In addition, when the electricity charge is reduced at night or the like, the electricity cost can be saved by storing power in the power storage device at night.

  When the HEMS and the power storage system communicate with each other and are configured integrally, the power storage system can notify the HEMS of charge / discharge power of the power storage device. Thereby, HEMS can present an energy balance including charging / discharging electric power of an electrical storage apparatus with respect to a user. Moreover, the electrical storage system can also notify HEMS of the measurement result obtained using the technique which measures the charge amount of a storage battery (for example, refer patent document 1). Thereby, the user can grasp | ascertain the electric power currently stored in the electrical storage apparatus with the energy balance.

JP2012-210130A

  However, when the HEMS and the power storage system are independent and cannot communicate with each other, the HEMS cannot obtain information on the charge / discharge power of the power storage device from the power storage system. For this reason, presentation of the energy balance by HEMS may become difficult.

  The present invention has been made in view of the above circumstances, and an object thereof is to enable presentation of an energy balance.

  In order to achieve the above object, a data processing device of the present invention is provided by an AC power supplied to a power storage device via a first power line connected to a power storage device having a storage battery, or from a power storage device via a first power line. A first acquisition unit that acquires a measurement value of output AC power and a power line that is different from the first power line and that measures AC power output from the power storage device via a second power line connected to the power storage device A second acquisition unit that acquires the value, a calculation unit that calculates charge / discharge power of the power storage device based on the measurement values acquired by the first acquisition unit and the second acquisition unit, and the charging unit that is calculated by the calculation unit An output unit that outputs display data for displaying power information related to the discharge power.

  According to the present invention, display data for displaying power information related to charge / discharge power of a power storage device is output. As a result, the energy balance can be presented.

It is a figure which shows the structure of the energy management system which concerns on Embodiment 1. FIG. It is a figure which shows the structure of an electrical storage apparatus. It is a figure which shows the hardware constitutions of a data processor. It is a figure which shows the functional structure of a data processor. It is a flowchart which shows charging / discharging electric power calculation processing. It is a flowchart which shows an estimation process. It is a figure which shows the 1st example of the screen which displays an energy balance. It is a figure which shows the 2nd example of the screen which displays an energy balance. It is a figure which shows the reference example of the screen which displays an energy balance. 6 is a diagram showing a connection relationship of power lines according to Embodiment 2. FIG. It is a figure which shows the functional structure of a data processor. It is a figure which shows the structure of an electrical storage apparatus. It is a 1st figure for demonstrating estimation of the charging rate based on transition of the integrated value of charging / discharging electric power. It is a 2nd figure for demonstrating estimation of the charging rate based on transition of the integrated value of charging / discharging electric power.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

Embodiment 1 FIG.
FIG. 1 shows a configuration of energy management system 100 in house H1 according to the first embodiment. As shown in FIG. 1, the house H1 includes an energy management system 100 for monitoring an energy balance in the house H1, a power storage system 400 for storing and using electric power, a power generation device 60 for generating power, and a distribution of the house H1. An electrical panel 70 and electrical devices 81, 82, and 83 that operate by consuming electric power are installed. In addition, the electric power from the commercial power supply 90 is supplied to the house H1. Further, a thick solid line in FIG. 1 indicates a power line.

  The energy management system 100 is a system that presents the energy balance of the house H1 to the user U1 by measuring power. The energy management system 100 includes a data processing device 10 that processes data related to power, a measuring device 20 that measures power, and a terminal 30 that is used by a user U1.

  The data processing device 10, the measurement device 20, and the terminal 30 are all connected to each other via the home network NW. The home network NW is a LAN (Local Area Network) for communicating according to a communication protocol such as ECHONET Lite, for example. Each of the data processing device 10, the measuring device 20, and the terminal 30 communicates with each other via the home network NW by transmitting and receiving signals according to this communication protocol.

  The data processing device 10 is a computer that processes the data transmitted from the measurement device 20 and transmits the processing result to the terminal 30. Note that the data processing apparatus 10 may control a device connected to the home network NW based on the result of processing the data. In addition, the data processing apparatus 10 is connected to a wide area network outside the house, and the user U1 checks the energy balance of the house H1 from outside the house, or operates a device connected to the home network NW from outside the house. May serve as a home gateway.

  The measuring device 20 uses the current transformers (CT, Current Transformer) 21, 22, 23, and 24 attached to the power lines L1, L2, L3, and L4 to generate electric power supplied through the power lines L1 to L4. It is a measuring instrument to measure. The current transformers 21, 23, 24 are installed in the distribution board 70.

  Power line L <b> 1 is connected to power storage device 40 in order to store power in power storage device 40 of power storage system 400. AC power is supplied to the power storage device 40 from the commercial power supply 90 via the power line L1. Further, AC power is supplied from the power storage device 40 to the electric devices 81, 82, etc. via the power line L1.

  The power line L2 is an electric wire connected to the power storage device 40 in order to use the power stored in the power storage device 40. From the power storage device 40, AC power is supplied to the electrical device 83 and the like via the power line L2. The power line L <b> 3 is an electric wire for supplying AC power generated by the power generation device 60 to the power storage device 40.

  The power line L4 is an electric wire for supplying electric power from the commercial power supply 90 to the house H1. The electric power supplied from the commercial power supply 90 is distributed to the power storage system 400, the electric devices 81, 82, 83, and the like. In addition, the electric power generated by the power generation device 60 may be supplied to the commercial power supply 90 side via the power line L4.

  The measurement apparatus 20 notifies the data processing apparatus 10 of the measured power value by responding to the request from the data processing apparatus 10.

  The terminal 30 is an information processing terminal such as a tablet terminal carried by the user U1, for example. The terminal 30 notifies the data processing apparatus 10 of the information input from the user U1 via the home network NW. In addition, the terminal 30 presents the energy balance of the house H1 to the user U1 based on the data transmitted from the data processing device 10. The terminal 30 according to the present embodiment is connected to the data processing device 10 via the home network NW, but may be connected to the data processing device 10 via, for example, a mobile communication network.

  The power storage system 400 is a system that stores power in the power storage device 40 and operates the stored power. The power storage system 400 according to the present embodiment is not connected to the energy management system 100. That is, the power storage system 400 is not connected to the home network NW via a communication line. The power storage system 400 includes a stationary power storage device 40 that stores electric power, and a power storage controller 50 that controls the power storage device 40.

  The power storage device 40 stores the power supplied from the power generation device 60 and the commercial power supply 90. The power storage device 40 supplies the stored power to the electric devices 81 and 82 as necessary. For example, the power storage device 40 supplies the stored electric power to the electric devices 81 and 82 during the day when the electricity charge is high.

  In addition, the power storage device 40 supplies at least one of the power from the commercial power supply 90 and the stored power to the electrical device 83. The power storage device 40 supplies the stored power to the electrical device 83 when the power supply from the commercial power supply 90 is stopped (at the time of a power failure). That is, at the time of a power failure, the electric devices 81 and 82 stop operating, but the electric device 83 continues operating with the electric power stored in the power storage device 40.

  FIG. 2 schematically shows a configuration example of the power storage device 40. As shown in FIG. 2, the power storage device 40 is provided with a terminal 41 connected to the power line L1, a terminal 42 connected to the power line L2, and a terminal 43 connected to the power line L3. The power storage device 40 includes a storage battery 44 that stores electric power, a charging circuit 45 for charging the storage battery 44, a discharging circuit 46 for discharging the storage battery 44, a control circuit 47 that controls the charging circuit 45 and the discharging circuit 46, and An AC-DC converter 48 is included.

  The storage battery 44 is a secondary battery that stores the power supplied to the power storage device 40, and is, for example, a lead storage battery, a lithium ion battery, or a nickel hydride storage battery. When direct-current power is input to the storage battery 44, the storage battery 44 is charged. Further, the storage battery 44 is discharged by outputting DC power. The rated capacity of the storage battery 44 is predetermined, for example, 5 kWh. The charging rate (SOC, State of Charge) when electric energy corresponding to the rated capacity of the storage battery 44 is charged is 100%, and the amount of charge is equal to the rated capacity. Further, the charge rate when all the electric power stored in the storage battery 44 is discharged is 0%, and the charge amount becomes zero.

  The charging circuit 45 converts AC power supplied from the power generation device 60 and the commercial power supply 90 into DC power. The charging circuit 45 converts the converted DC power voltage into a voltage suitable for charging the storage battery 44. However, the charging circuit 45 includes a switching element that is turned on or off in accordance with a command from the control circuit 47, and supplies power to the storage battery 44 to charge the storage battery 44 when the switching element is on. . In FIG. 2, a switch is disposed outside the charging circuit 45 in order to explain the function of the switching element. In addition, when the charging circuit 45 converts electric power, a part of electric power is lost.

  The discharge circuit 46 converts the voltage of the DC power supplied from the storage battery 44 into a voltage suitable for power supply in the house H1. Then, the discharge circuit 46 converts DC power into AC power and outputs it to the terminal 42. The discharge circuit 46 may output power to the terminal 41. In addition, the discharge circuit 46 generates DC power having a voltage suitable for the control circuit 47 and outputs it to the control circuit 47. However, the discharge circuit 46 has a switching element that is turned on or off in accordance with a command from the control circuit 47, and outputs power when the switching element is on. In FIG. 2, a switch is disposed outside the discharge circuit 46 in order to explain the function of the switching element. In addition, when the discharge circuit 46 converts electric power, a part of electric power is lost.

  The control circuit 47 is a circuit that determines whether to cause the charging circuit 45 and the discharging circuit 46 to perform power conversion in accordance with an instruction from the power storage controller 50. The control circuit 47 controls the charging circuit 45 and the discharging circuit 46 to adjust the charge amount of the storage battery 44 or to discharge the storage battery 44 when the commercial power supply 90 is powered off. Further, the control circuit 47 calculates the charge rate and charge amount of the storage battery 44 based on the voltage or current detected by the charging circuit 45 and the discharging circuit 46 and notifies the storage controller 50 of the calculation result.

  The AC-DC converter 48 converts AC power supplied from the power generation device 60 and the commercial power supply 90 into DC power and supplies the DC power to the control circuit 47. When the AC-DC converter 48 converts power, a part of the power is lost.

  Returning to FIG. 1, the power storage controller 50 is a computer that instructs the power storage device 40 to start or stop charging / discharging based on information previously input by the user U1. Further, the power storage controller 50 notifies the user U1 of the charge rate and charge amount of the storage battery 44 notified from the control circuit 47 of the power storage device 40.

  The power generation device 60 is a device that generates power using sunlight, for example, and is installed on the roof of the house H1. The power generation device 60 includes, for example, a polycrystalline silicon solar panel and a power conditioner that converts DC power generated by the solar panel into AC power.

  A breaker 71 is installed on the distribution board 70. When the value of the electric power supplied from the commercial power supply 90 exceeds the capacity of the breaker 71, the breaker 71 cuts off the supply of electric power from the commercial power supply 90. The capacity of the breaker 71 is determined, for example, when the user U1 makes a contract with an electric power company. The breaker 71 may be an earth leakage breaker.

  Each of the electric devices 81 to 83 is, for example, a television receiver, an air conditioner, a cooking device, and an electric water heater. Each of the electric devices 81 to 83 may be connected to the home network NW.

  Next, the configuration of the data processing device 10 will be described. FIG. 3 shows a hardware configuration of the data processing apparatus 10. As illustrated in FIG. 3, the data processing device 10 includes a processor 11, a main storage unit 12, an auxiliary storage unit 13, a communication unit 14, an input unit 15, and an output unit 16. The main storage unit 12, auxiliary storage unit 13, communication unit 14, input unit 15, and output unit 16 are all connected to the processor 11 via the internal bus 17.

  The processor 11 is composed of, for example, a CPU (Central Processing Unit). The processor 11 executes a process described later by executing the program P1 stored in the auxiliary storage unit 13.

  The main storage unit 12 is composed of, for example, a RAM (Random Access Memory). The main storage unit 12 loads the program P1 from the auxiliary storage unit 13. The main storage unit 12 is used as a work area for the processor 11.

  The auxiliary storage unit 13 includes a nonvolatile memory such as a hard disk or a flash memory. The auxiliary storage unit 13 stores various data used for the processing of the processor 11 in addition to the program P1. The auxiliary storage unit 13 supplies data used by the processor 11 to the processor 11 according to an instruction from the processor 11 and stores the data supplied from the processor 11.

  The communication unit 14 includes a communication interface for communicating via the home network NW. The communication unit 14 receives a signal via the home network NW and outputs data included in this signal to the processor 11. Moreover, the communication part 14 transmits the signal containing the data output from the processor 11 to the measuring device 20 or the terminal 30 via the home network NW, for example.

  The input unit 15 includes, for example, an input key and a capacitance type pointing device. The input unit 15 acquires information input by the user U1 and notifies the processor 11 of the acquired information. The input unit 15 is used, for example, to input parameter values used for processing of the processor 11.

  The output unit 16 includes, for example, an LCD (Liquid Crystal Display) and a speaker. The output unit 16 presents various information to the user U1 in accordance with instructions from the processor 11. The output unit 16 according to the present embodiment is formed integrally with a pointing device that constitutes the input unit 15 to constitute a touch screen.

  The data processing apparatus 10 exhibits various functions by having the above configuration. FIG. 4 shows a functional configuration of the data processing apparatus 10. As illustrated in FIG. 4, the data processing device 10 includes an acquisition unit 101 that acquires a measurement value of power measured by the measurement device 20, an input reception unit 102 that receives an input from the user U1, and a power storage for the user U1. An inquiry unit 103 that inquires about the state of the device 40; a calculation unit 104 that calculates charge / discharge power of the power storage device 40; an estimation unit 105 that estimates the power stored in the power storage device 40; an output unit 106 that outputs data; It has the display part 107 which displays information with respect to the user U1.

  The acquiring unit 101 acquires the measured power value from the measuring device 20 by repeatedly requesting the measuring device 20 to transmit the measured power value. This request is made periodically, for example, at a cycle of 1 second. The acquisition unit 101 is realized mainly by the cooperation of the processor 11 and the communication unit 14.

  The input receiving unit 102 receives input information input by the user U1. The input receiving unit 102 is realized mainly by the cooperation of the processor 11 and the input unit 15. When input information is input to the terminal 30 by the user U1, the input receiving unit 102 is realized by the cooperation of the processor 11 and the communication unit 14.

  The input information received by the input receiving unit 102 includes, for example, an upper limit value of power supplied from the commercial power supply 90 to the house H1. This upper limit value may be the capacity of the breaker 71 or may be another upper limit value designated by the user U1. For example, the upper limit value may be a value (peak cut power) specified by the user U1 with respect to the energy management system 100 in order to suppress power consumed in the house H1.

  The input information may include information related to the power storage system 400. For example, the input information includes the rated capacity of the storage battery 44, the start time and end time of charging at night, etc., the start time and end time of discharge during the day, etc., the discharge mode information (discharge priority, peak cut) of the power storage device 40, In addition, the charging rate or the charging amount of the storage battery 44 that is secured at the minimum in the event of a power failure of the commercial power supply 90 may be included. Further, the input information may include information regarding the form of power generation by the power generation device 60.

  The inquiry unit 103 inquires of the user U1 about the charge rate or the charge amount of the storage battery 44 displayed on the storage controller 50. When the inquiry indicating the charge rate or the charge amount of the storage battery 44 is obtained from the user U1, the inquiry unit 103 notifies the estimation unit 105 of the charge rate or the charge amount indicated by this answer. The inquiry unit 103 is realized mainly by the cooperation of the processor 11, the input unit 15, and the output unit 16. When making an inquiry to the user U <b> 1 via the terminal 30, the inquiry unit 103 is realized by the cooperation of the processor 11 and the communication unit 14.

  Calculation unit 104 calculates charge / discharge power of power storage device 40 based on the measurement value acquired by acquisition unit 101. The calculation unit 104 is mainly realized by the processor 11.

  The estimation unit 105 estimates the charge rate or charge amount of the storage battery 44 based on the input information received by the input reception unit 102 and the integrated value of charge / discharge power calculated by the calculation unit 104. The estimation unit 105 is mainly realized by the processor 11.

  The output unit 106 displays the display data for displaying the charge / discharge power calculated by the calculation unit 104 and the power information related to the charging rate or the charge amount estimated by the estimation unit 105, the display unit 107 and the home network NW. To the terminal 30. The output unit 106 is mainly realized by the processor 11 and the communication unit 14.

  The display unit 107 displays the energy balance of the house H1 as power information to the user U1 based on the display data output by the output unit 106. The display unit 107 is mainly realized by the output unit 16.

  Next, the charge / discharge power calculation process and the estimation process executed by the data processing device 10 will be described in detail with reference to FIGS. Each of the charge / discharge power calculation process and the estimation process starts in parallel when the data processing apparatus 10 is turned on.

  As shown in FIG. 5, in the charge / discharge power calculation process, the calculation unit 104 substitutes zero for Eb (step S1). Eb is a variable indicating the charge / discharge power amount of the power storage device 40.

  Next, the acquisition unit 101 acquires a measurement value from the measurement device 20 (step S2). Specifically, the acquisition unit 101 measures the measured value Pi of power supplied to the power storage device 40 via the power line L1, the measured value Po of power output from the power storage device 40 via the power line L2, and A measured value Pp of power supplied to the power storage device 40 via the power line L3 is acquired.

  However, when the measured value Pi is positive, the magnitude of the measured value Pi indicates the magnitude of power supplied from the commercial power supply 90 to the power storage device 40 via the power line L1. Further, when the measured value Pi is negative, the magnitude of the measured value Pi indicates the magnitude of power output from the power storage device 40 via the power line L1. The sign of the measured value Pi is positive when electric power is input to the power storage device 40. In the present embodiment, the measured values Po and Pp are both positive values.

  Next, calculation unit 104 calculates charge / discharge power Pb of power storage device 40 (step S3). In detail, the calculation part 104 calculates the charging / discharging electric power Pb by performing the calculation shown by the following formula | equation (1).

  Pb = Pi−Po + Pp (1)

  As can be seen from the above equation (1), the magnitude of the charge / discharge power Pb is equal to the power input to the power storage device 40 or the power output from the power storage device 40. Further, the positive / negative sign of the charge / discharge power Pb is positive when power is input to the power storage device 40 and is negative when power is output from the power storage device 40. As described above, the calculation unit 104 calculates the power input to the power storage device 40 or the power output from the power storage device 40 as the charge / discharge power Pb of the power storage device 40. That is, when the charge / discharge power Pb is positive, the magnitude of the charge / discharge power Pb means the magnitude of the charge power, and when the charge / discharge power Pb is negative, the magnitude of the charge / discharge power Pb is the magnitude of the discharge power. It means size.

  Note that power loss by the charging circuit 45 and the discharging circuit 46 and power consumption by the control circuit 47 occur inside the power storage device 40. For this reason, the charge / discharge power Pb does not always coincide completely with the charge / discharge power of the storage battery 44. However, the charge / discharge power Pb is highly correlated with the charge / discharge power of the storage battery 44. Therefore, as will be described later, it is possible to present to the user U1 a somewhat accurate energy balance using the charge / discharge power Pb.

  Next, the calculation part 104 integrates charging / discharging electric power Pb (step S4). Specifically, the calculation unit 104 integrates the charge / discharge power Pb by an arithmetic expression of Eb = Eb + Pb · T. However, T means a cycle in which measurement value acquisition (step S2) is executed. T according to the present embodiment is 1/3600 [h] (= 1 [s]).

  Next, the calculation unit 104 determines whether or not the integration in step S4 has been executed a predetermined number of times (step S5). This number is, for example, 3600 times. Eb when the integration is executed 3600 times means the charge / discharge power amount of the power storage device 40 in one hour (= 3600 seconds). When Eb is positive, the magnitude of Eb means the magnitude of the charging electric energy, and when Eb is negative, the magnitude of Eb means the electric energy for discharging.

  When it is determined that the integration has not been performed a predetermined number of times (step S5; No), the calculation unit 104 repeats the processes after step S2.

  On the other hand, when it is determined that the integration has been performed a predetermined number of times (step S5; Yes), the calculation unit 104 determines whether Eb is smaller than 0−α (step S6). α is a predetermined positive threshold value.

  When it determines with Eb being smaller than 0- (alpha) (step S6; Yes), the calculation part 104 judges that the storage battery 44 is discharging (step S7). Thereby, it is avoided that it is determined that the storage battery 44 is being discharged when Eb is in the vicinity of zero. Therefore, the determination that the storage battery 44 is being discharged can be ensured in consideration of an error included in Eb calculated as the charge / discharge power amount of the power storage device 40. Thereafter, the calculation unit 104 repeats the processes after step S1.

  On the other hand, when it is determined that Eb is not smaller than 0−α (step S6; No), the calculation unit 104 determines whether Eb is larger than 0 + α (step S8).

  When it is determined that Eb is greater than 0 + α (step S8; Yes), the calculation unit 104 determines that the storage battery 44 is being charged (step S9). Thereby, it is avoided that it is determined that the storage battery 44 is being charged when Eb is in the vicinity of zero. Therefore, the determination that the storage battery 44 is being charged can be ensured in consideration of the error included in Eb calculated as the charge / discharge power amount of the power storage device 40. Thereafter, the calculation unit 104 repeats the processes after step S1.

  On the other hand, when it is determined that Eb is not greater than 0 + α (step S8; No), the calculation unit 104 determines that the storage battery 44 is on standby (step S10). That is, the calculation unit 104 determines that the storage battery 44 is not charged or discharged. Thereafter, the calculation unit 104 repeats the processes after step S1.

  Thereby, the calculation unit 104 calculates the charge / discharge power amount of the power storage device 40 in the past hour (steps S2 to S5) and determines the state of the storage battery 44 (steps S7, S9, and S10) every hour. Will be executed.

  Next, the estimation process executed by the data processing device 10 will be described. As shown in FIG. 6, in the estimation process, the input receiving unit 102 receives input information input from the user U1 (step S21).

  Next, the estimation part 105 determines whether the storage battery 44 is charging (step S22). Specifically, the estimation unit 105 determines whether or not the calculation unit 104 determines that the storage battery 44 is being charged.

  When it determines with the storage battery 44 being charging (step S22; Yes), the estimation part 105 repeats the process after step S22. Thus, the estimation unit 105 waits until the calculation unit 104 determines that the storage battery 44 is not being charged.

  On the other hand, when it determines with the storage battery 44 not charging (step S22; No), the estimation part 105 determines whether charging completion conditions are satisfy | filled (step S23). The charging completion condition means a condition for determining that the charging of the storage battery 44 is completed and the charging rate is 100%. The charging completion condition according to the present embodiment is that all the first to third conditions are satisfied.

  The first condition is that the length of time that is determined by the calculation unit 104 that the storage battery 44 is not charged or discharged exceeds a predetermined length. In other words, the time during which neither the storage battery 44 is charged nor discharged is continued for a predetermined length. The predetermined length of time is, for example, 3 hours. If it is determined that the storage battery 44 is being charged or discharged at least once in the past three hours, the first condition is not satisfied.

  The second condition is that the current time does not belong to the time when charging is prohibited in the power storage system 400. The success or failure of the second condition is determined based on the input information received by the input receiving unit 102.

  The third condition is that the difference between the measured value of power supplied from the commercial power supply 90 to the house H1 and the upper limit value of this power is equal to or greater than a preset value. That is, the power that can be supplied from the commercial power supply 90 is secured to some extent.

  The establishment of all of the first to third conditions means that charging is not performed even though the storage battery 44 can be charged.

  When it is determined that the charging completion condition is satisfied (step S23; Yes), the inquiry unit 103 inquires of the user U1 whether or not the charging is completed (step S24). Specifically, the inquiry unit 103 inquires of the user U1 whether or not the charge rate of the storage battery 44 is displayed on the power storage controller 50 as 100%. For example, the inquiry unit 103 displays an inquiry “Is the power storage system indicated that charging is complete and fully charged?” And a “Yes” button and a “No” button for answering this inquiry. Display on the touch screen.

  Next, the estimation unit 105 determines whether or not there is a charge completion reply from the user U1 in response to the inquiry in step S24 (step S25). If an answer indicating that charging has not been completed is obtained, and if an answer is not obtained for a certain period of time, the estimation unit 105 determines that there is no answer indicating completion of charging.

  When it determines with there being a reply of charge completion (step S25; Yes), the estimation part 105 estimates that the storage battery 44 is a full charge state (step S26). Specifically, the estimation unit 105 estimates that the charging rate of the storage battery 44 is 100%, and estimates that the charge amount of the storage battery 44 is equal to the rated capacity. Note that the estimation unit 105 may estimate only one of the charge rate and the charge amount.

  Next, the output unit 106 outputs display data indicating that the storage battery 44 is fully charged to the display unit 107 and the terminal 30 (step S27). In this display data, for example, the calculation unit 104 calculates that the charge level in five stages is “5”, the charging rate and the charging amount of the storage battery 44, and whether the storage battery 44 is charged or discharged. The charge / discharge power Pb and Eb indicating the charge / discharge power amount are included. Thereafter, the data processing apparatus 10 repeats the processes after step S22.

  FIG. 7 shows an example of a screen generated from the display data output in step S27. As shown in FIG. 7, an icon D40 indicating the amount of charge of the storage battery 44 in five stages and texts D41, D60, D80, and D90 are displayed on the screen generated from the display data.

  The text D41 indicates the value of Eb, which is the amount of charge / discharge power, and whether the storage battery 44 is in a charging, discharging or standby state. The text D60 indicates the amount of power generated by the power generation device 60. The text D80 indicates the amount of power consumed by the electric devices 81-83. Text D90 indicates the amount of power supplied from commercial power supply 90. The amount of power indicated by the texts D60 and D90 is calculated by integrating the measured values output from the measuring device 20. Further, the electric energy indicated by the text D80 is calculated from the electric energy indicated by the texts D41, D60, D90.

  Returning to FIG. 6, when it is determined in step S23 that the charging completion condition is not satisfied (step S23; No) and when it is determined in step S25 that there is no answer of charging completion (step S25; No), the estimation unit 105 Estimates the current state of the storage battery 44 (step S28). Specifically, the estimation unit 105 integrates the charge / discharge power amount (Eb) calculated by the calculation unit 104 after the storage battery 44 is determined to be fully charged to the rated capacity of the storage battery 44. Thus, the charge rate and the charge amount of the storage battery 44 are estimated.

  Next, the output unit 106 outputs display data indicating the current state of the storage battery 44 to the display unit 107 and the terminal 30 (step S29). The charge level included in the display data is calculated based on the charge rate. Thereafter, the data processing apparatus 10 repeats the processes after step S22.

  FIG. 8 shows an example of a screen generated from the display data output in step S29. In the example shown in FIG. 8, the icon D40 indicates that the charging rate of the storage battery 44 is about 60%.

  As described above, data processing device 10 according to the present embodiment calculates charge / discharge power of power storage device 40 and outputs display data for displaying power information related to charge / discharge power. As a result, as shown in FIGS. 7 and 8, a certain amount of energy balance is presented to the user U1.

  If the data processing device 10 does not calculate the charge / discharge power of the power storage device 40, the data processing device 10 is based on the measured value of the power supplied from the commercial power supply 90 and the measured value of the power generated by the power generator 60. The amount of power consumption in H1 is calculated. FIG. 9 shows a reference example of the energy balance displayed in this case.

  In the example shown in FIG. 9, the amount of discharged power of the power storage device 40 is actually consumed in the house H1, but the amount of discharged power is unknown (0 kWh). The power consumption is always displayed as 0 kWh. For this reason, an incorrect energy balance will be presented to the user U1.

  However, the data processing device 10 according to the present embodiment can calculate the amount of power consumed in the house H1 to some degree by calculating the amount of charge / discharge power of the power storage device 40. As a result, the user U1 can grasp the energy balance in the house H1 and use energy efficiently.

  Further, the data processing device 10 according to the present embodiment includes an estimation unit 105 that estimates the charge rate or the charge amount of the storage battery 44. Thereby, it becomes possible to present the charging rate or the charging amount estimated by the estimating unit 105 together with the energy balance.

  In particular, the estimation unit 105 estimates that the storage battery 44 is in a fully charged state when the charging completion condition is satisfied. This makes it possible to accurately estimate the charge rate or charge amount of the storage battery 44.

  Further, the estimation unit 105 estimates the charge rate or the charge amount based on the answer when the inquiry unit 103 obtains an answer indicating the charge rate or the charge amount of the storage battery 44 in the fully charged state from the user U1. To do. Thereby, the estimation result of a charge rate or charge amount can be made reliable.

Embodiment 2. FIG.
Next, the second embodiment will be described focusing on the differences from the first embodiment. In addition, about the structure which is the same as that of the said Embodiment 1, or equivalent, while using an equivalent code | symbol, the description is abbreviate | omitted or simplified.

  Data processing apparatus 10 according to the present embodiment is different from that according to Embodiment 1 in that the method for calculating the charge / discharge power of power storage device 40 is determined by the selection of user U1. The data processing device 10 according to the present embodiment is different from that according to the first embodiment in that charge / discharge power is calculated based on the power consumption in the power storage device 40.

  As shown in FIG. 10, power line L <b> 3 according to the present embodiment is not connected to power storage device 40. As can be seen from FIG. 10, the charge / discharge power of the power storage device 40 is calculated from the measured value of the power supplied via the power lines L1 and L2. However, the energy management system 100 cannot communicate with the power storage system 400, and therefore cannot select a measurement value to be used for calculating the charge / discharge power of the power storage device 40.

  FIG. 11 shows a functional configuration of the data processing apparatus 10 according to the present embodiment. As shown in FIG. 11, the data processing apparatus 10 includes a selection receiving unit 108. The selection receiving unit 108 presents candidates for power lines connected to the power storage device 40 to the user U1. And the selection reception part 108 receives the selection information input by the user U1. This selection information is information indicating the power line selected by the user U1 from the power line candidates. In the example illustrated in FIG. 10, the selection information is information indicating the power lines L1 and L2. The selection receiving unit 108 is realized mainly by the cooperation of the processor 11, the input unit 15, and the output unit 16. When the user U1 inputs selection information to the terminal 30, the selection receiving unit 108 is realized by the cooperation of the processor 11 and the communication unit 14.

  FIG. 12 shows a configuration of power storage device 40 according to the present embodiment. As shown in FIG. 12, the measuring device 20 measures the power consumed by the control circuit 47 using the current transformer 25. The measurement result of the power consumption is notified to the data processing device 10 as the measurement value Pz.

  Returning to FIG. 11, the acquisition unit 101 according to the present embodiment acquires the measurement value Pz. Moreover, the calculation part 104 calculates the charging / discharging electric power Pb of the electrical storage apparatus 40 by performing the calculation shown by the following formula | equation (2).

  Pb = Pi-Po-Pz (2)

  As described above, the selection receiving unit 108 according to the present embodiment has received selection information indicating the power line selected by the user U1. Then, calculation unit 104 calculates charge / discharge power of power storage device 40 based on measured values Pi and Po of power supplied via power lines L1 and L2 indicated by the selection information. Thereby, it is avoided to calculate the charge / discharge power based on the measured value Pp of the generated power by the power generator 60. That is, calculation corresponding to the power line actually connected to power storage device 40 can be performed.

  In the present embodiment, the charge / discharge power Pb is calculated after the power consumed by the control circuit 47 of the power storage device 40 is reduced. Thereby, the charge / discharge power Pb can be calculated more accurately.

  In the present embodiment, the data processing apparatus 10 obtains the measured value Pz using the current transformer 25, but is not limited thereto. For example, when the input from the user U1 indicates that the storage battery 44 is not charged or discharged, the estimation unit 105 uses the charge / discharge power Pb calculated by the calculation unit 104 as the consumption of the power storage device 40. The power Py may be estimated. This power consumption Py is substantially equal to the measured value Pz.

  For example, the estimation unit 105 touches a question “whether the power storage device is charging or discharging?” And a “Yes” button and a “No” button for answering this question. To display. And the estimation part 105 substitutes the value of charging / discharging electric power Pb when the user's U1 finger | toe touches the "Yes" button to power consumption Py.

  Thereafter, the calculation unit 104 may calculate the charge / discharge power Pb by reducing the power consumption Py, similarly to the equation (2). In addition, the calculation unit 104 may estimate the charging rate of the storage battery 44 after the estimation unit 105 subtracts the power consumption Py from the charge / discharge power Pb without changing the arithmetic expression.

  As mentioned above, although embodiment of this invention was described, this invention is not limited by the said embodiment.

  The inquiry by the inquiry unit 103 may be performed at a timing different from step S24 in FIG. For example, when the charging rate of the storage battery 44 estimated by the estimation unit 105 becomes equal to or less than the threshold, the inquiry unit 103 displays a message notifying that the remaining amount of the storage battery 44 has decreased, and the storage controller The user U1 may be inquired about the charge rate or the charge amount displayed by 50. Then, when an answer from the user U1 indicating the charging rate or the charging amount is obtained in response to this inquiry, the estimating unit 105 determines the estimated charging rate or the charging amount as the charging rate or the charging amount indicated by the answer. You may correct to.

  Further, when it is determined that the charging rate of the storage battery 44 is equal to or less than the threshold and charging is possible, the inquiry unit 103 displays a message recommending charging to the user U1 and is displayed by the power storage controller 50. The user U1 may be inquired about the charging rate or the charged amount.

  Although the data processing apparatus 10 was installed in the house H1, it is not limited to this. For example, the data processing device 10 may be a server device connected to the home network NW via the Internet.

  Although the estimation part 105 estimated the charging rate and charge amount of the storage battery 44 on the basis of charge completion conditions, it is not limited to this.

  For example, when the integrated value of the charge / discharge power of the power storage device 40 changes as shown in FIG. 13, the value E1 in FIG. 13 corresponds to the amount of charge of the fully charged storage battery 44, and the value E2 Corresponds to the amount of charge when the charging rate is 0%. Therefore, at time T1 when the integrated value reaches the minimum value (value E2) in the past transition a predetermined number of times, the estimation unit 105 may estimate that the charging rate of the storage battery 44 is 0%. In addition, at time T2 when the integrated value reaches the maximum value (value E1) in the past transition a predetermined number of times, the estimation unit 105 may estimate that the storage battery 44 is in a fully charged state.

  In addition, when the rated capacity (value E3) of the storage battery 44 is given, as shown in FIG. 14, when the integrated value of the charge / discharge power of the power storage device 40 changes in a range corresponding to the value E3, It is considered that the minimum value in the range corresponds to a charging rate of 0%, and the maximum value in the range corresponds to a charging rate of 100%.

  Although the electric power supplied via each of the power lines L1 to L4 is measured by the measuring device 40, it may be measured by a separate device. For example, the device for measuring the power supplied via the power line L1 may be a device different from the device for measuring the power supplied via the power line L2.

  The functions of the data processing apparatus 10 according to the above-described embodiment can be realized by dedicated hardware or by a normal computer system.

  For example, the program P1 stored in the auxiliary storage unit 13 is stored in a computer-readable recording medium such as a flexible disk, a CD-ROM (Compact Disk Read-Only Memory), a DVD (Digital Versatile Disk), and distributed. By installing the program P1 in the computer, a device that executes the above-described processing can be configured.

  Further, the program P1 may be stored in a disk device or the like included in a server device on a communication network such as the Internet, and may be downloaded onto a computer, for example, superimposed on a carrier wave.

  The above-described processing can also be achieved by starting and executing the program P1 while transferring it through the communication network.

  Furthermore, the above-described processing can also be achieved by executing all or part of the program P1 on the server device and executing the program P1 while the computer transmits / receives information related to the processing via the communication network. .

  Note that when the above functions are realized by sharing an OS (Operating System) or when the functions are realized by cooperation between the OS and an application, only the part other than the OS may be stored in a medium and distributed. Alternatively, it may be downloaded to a computer.

  The means for realizing the functions of the data processing apparatus 10 is not limited to software, and a part or all of the means may be realized by dedicated hardware (circuit or the like).

  Various embodiments and modifications can be made to the present invention without departing from the broad spirit and scope of the present invention. The above-described embodiments are for explaining the present invention and do not limit the scope of the present invention. In other words, the scope of the present invention is shown not by the embodiments but by the claims. Various modifications within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

  The present invention is applicable to a system for efficiently using energy.

  DESCRIPTION OF SYMBOLS 100 Energy management system, 10 Data processing apparatus, 11 Processor, 12 Main memory part, 13 Auxiliary memory part, 14 Communication part, 15 Input part, 16 Output part, 17 Internal bus, 101 Acquisition part, 102 Input reception part, 103 Inquiry Unit, 104 calculation unit, 105 estimation unit, 106 output unit, 107 display unit, 108 selection receiving unit, 20 measuring device, 21, 22, 23, 24, 25 current transformer, 30 terminal, 400 power storage system, 40 power storage device 41, 42, 43 terminals, 44 storage battery, 45 charging circuit, 46 discharging circuit, 47 control circuit, 48 AC-DC converter, 50 power storage controller, 60 power generator, 70 distribution board, 71 breaker, 80 distribution board, 81, 82, 83 Electrical equipment, 90 Commercial power , D40 icons, D41, D60, D80, D90 text, H1 housing, L1, L2, L3, L4 the power line, NW home network, P1 programs, U1 user.

Claims (11)

First to obtain AC power supplied to the power storage device via a first power line connected to a power storage device having a storage battery or AC power output from the power storage device via the first power line An acquisition unit;
A second acquisition unit that is a power line different from the first power line and acquires a measured value of AC power output from the power storage device via a second power line connected to the power storage device;
A calculation unit that calculates charge / discharge power of the power storage device based on the measurement values acquired by the first acquisition unit and the second acquisition unit;
A data processing apparatus comprising: an output unit that outputs display data for displaying power information related to charge / discharge power calculated by the calculation unit. A third acquisition unit that acquires a measurement value of the generated power supplied from the power generation device to the power storage device via a third power line that is different from any of the first power line and the second power line;
The data according to claim 1, wherein the calculation unit calculates charge / discharge power of the power storage device based on measurement values acquired by the first acquisition unit, the second acquisition unit, and the third acquisition unit. Processing equipment. An input receiving unit that receives input information input by the user;
An estimation unit that estimates a charge rate or a charge amount of the storage battery based on the input information and an integrated value of charge / discharge power calculated by the calculation unit;
The data processing apparatus according to claim 1, wherein the output unit outputs display data for displaying power information related to a charging rate or a charge amount estimated by the estimation unit. A fourth acquisition unit that acquires a measurement value of power supplied from a commercial power source to the house where the power storage device is installed;
The first power line is connected to the power storage device to supply power from the commercial power source to the storage battery,
The input information includes information indicating an upper limit value of power supplied from the commercial power source to the house,
The calculation unit determines whether the storage battery is charged or discharged according to the calculated charge / discharge power,
In the estimation unit, the difference between the measured value acquired by the fourth acquisition unit and the upper limit value is equal to or larger than a preset value, and the storage unit is charged or discharged by the calculation unit. The data processing apparatus according to claim 3, wherein the storage battery is estimated to be in a fully charged state when a length of time determined not to exceed a predetermined length. An inquiry unit that inquires the user about the charge rate or the charge amount of the storage battery;
The said estimation part estimates the charge rate or charge amount of the said storage battery based on the said answer, when the reply which shows the charge rate or charge amount of the said storage battery is obtained from the user by the said inquiry part. Or the data processing apparatus of 4.   The estimation unit estimates the charging power calculated by the calculation unit as power consumption of the power storage device when it is indicated that charging or discharging of the storage battery is not performed by an input from a user. Item 6. The data processing device according to any one of Items 3 to 5. Further comprising a selection receiving unit that presents to the user power line candidates connected to the power storage device and receives selection information indicating the power lines selected by the user from the presented candidates;
The said calculation part calculates the charging / discharging electric power of the said electrical storage apparatus based on the measured value of the electric power supplied via the electric power line shown by the said selection information. Data processing device. A fifth acquisition unit that acquires a measurement value of power consumed by a circuit included in the power storage device;
The data processing device according to claim 1, wherein the calculation unit further calculates charge / discharge power of the power storage device based on the measurement value acquired by the fifth acquisition unit. A first measuring device for measuring AC power supplied to the power storage device via a first power line connected to a power storage device having a storage battery, or AC power output from the power storage device via the first power line; ,
A second measurement device that is a power line different from the first power line and measures AC power output from the power storage device via a second power line connected to the power storage device;
The display data for displaying the electric power information regarding the charging / discharging electric power of the said electrical storage apparatus are output based on the measured value of the alternating current power measured by the said 1st measuring device and the said 2nd measuring device. A data processing device according to any one of
A terminal for displaying the power information based on display data output from the data processing device;
Energy management system with The first acquisition unit measures AC power supplied to the power storage device via a first power line connected to a power storage device having a storage battery, or AC power output from the power storage device via the first power line. Get the value
The second acquisition unit is a power line different from the first power line, and acquires a measured value of AC power output from the power storage device via a second power line connected to the power storage device;
The calculation unit calculates charge / discharge power of the power storage device based on the measurement values acquired by the first acquisition unit and the second acquisition unit,
The data processing method in which an output part outputs the display data for displaying the electric power information regarding the charging / discharging electric power calculated by the said calculation part. Computer
First to obtain AC power supplied to the power storage device via a first power line connected to a power storage device having a storage battery or AC power output from the power storage device via the first power line Acquisition means,
A second acquisition unit that is a power line different from the first power line, and acquires a measured value of AC power output from the power storage device via a second power line connected to the power storage device;
Calculation means for calculating charge / discharge power of the power storage device based on the measurement values acquired by the first acquisition means and the second acquisition means;
A program for functioning as output means for outputting display data for displaying power information related to charge / discharge power calculated by the calculation means.

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