JP6555524B2 - Power management system, information device, and program - Google Patents

Description

  The present invention relates to a power management system, an information device, and a program.

  Conventionally, there is a system for determining an operation schedule of equipment in a customer facility (see, for example, Patent Document 1). In this system, a HEMS (Home Energy Management System) device obtains a power outage scheduled period information, power storage information, power generation information, and power consumption information from the outside, and determines an operation schedule in the power outage period. And a controller adjusts the generated electric power of a solar power generation device according to the control command received from the HEMS apparatus.

JP 2012-228043 A

  However, in the above-described conventional system, when the operation of the HEMS device is stopped due to a problem, the control of the solar power generation device by the controller is also stopped. Therefore, there has been a demand for a system that can continue the control of the solar power generation device even when the HEMS device stops operating.

  The present invention has been made in view of the above reasons, and an object thereof is to provide a power management system, an information device, and a program capable of continuing control of a power generation device even when a malfunction occurs in the system. It is in.

The power management system of the present invention includes a first device and a second device configured to be able to communicate with each other, and the first device acquires first control information including control contents of the power generation device in a first period. An acquisition unit, a first storage unit that stores the first control information, and second control information including control content of the power generation device in a second period based on the first control information are created, and the second control information Is transmitted to the second device, and the second device is stored in the second storage unit that stores the second control information received from the first device, and the second storage unit. a control unit for controlling the power generating apparatus based on the second control information, the second period is included in the first period, and Ri period shorter der than the first period, the first 1 control information is a control content of the power generator in a unit period. The second control information is one or more schedule data included in the first control information. The second control information includes one or more schedule data included in the first control information. It is characterized by being configured .

An information device according to the present invention is based on an acquisition unit that acquires first control information including control content of a power generation device in a first period, a first storage unit that stores the first control information, and the first control information. An information processing unit that creates second control information including control content of the power generation device in the second period and transmits the second control information, and the second period is included in the first period, and Ri period shorter der than the first period, the first control information includes scheduling data is the control content of the power generator in a unit time, a plurality of successive time series over the first time period The second control information is composed of one or more schedule data included in the first control information .

The program of the present invention includes a computer that obtains first control information including control content of the power generation device in the first period, and control content of the power generation device in the second period based on the first control information. The second control information is created and functions as an information processing unit that transmits the second control information, and the second period is included in the first period and is shorter than the first period , The first control information includes schedule data that is control content of the power generation device in a unit period, and is configured by a plurality of schedule data that continues in time series over the first period, and the second control information The information is composed of one or more schedule data included in the first control information .

  As described above, the power management system according to the present invention has an effect that the control of the power generation device can be continued even when a malfunction occurs in the system.

  In addition, the information device of the present invention has an effect that the control of the power generation device can be continued even when a problem occurs in the system.

  In addition, the program of the present invention has an effect that the control of the power generation device can be continued even when a problem occurs in the system.

It is a block diagram which shows the structure of the power management system of embodiment. It is a flowchart which shows the operation | movement at the time of starting of the monitor apparatus of embodiment. It is a communication sequence which shows the transmission process of the 2nd control information of embodiment. It is explanatory drawing which shows the 2nd control information with the past schedule of embodiment. It is explanatory drawing which shows a process when there exists the past schedule of embodiment. It is explanatory drawing which shows the 2nd control information with the empty schedule of embodiment. It is explanatory drawing which shows a process when there exists an empty schedule of embodiment. It is explanatory drawing which shows the process at the time of a day span of embodiment. It is a flowchart which shows the operation | movement at the time of the regular communication of embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments relate to a power management system, an information device, and a program that use control information including control details of the power generation device.

(Embodiment)
FIG. 1 shows a configuration of a power management system 100 of this embodiment combined with a power distribution system. The power distribution system includes the distribution board 3 and the solar power generation device 40 as main components, and supplies power to the load 9. The power management system 100 includes the monitor device 1 (first device) and the measurement unit 2 (second device) as main components, and controls the solar power generation device 40. The solar power generation device 40 includes a power conversion device 4 and a solar cell 5. In FIG. 1, a solid line between components indicates a power path, and an alternate long and short dash line between components indicates a communication path. Moreover, although this embodiment demonstrates the form which applied the power distribution system to the detached dwelling unit, it cannot be overemphasized that a power distribution system may be applied to customer facilities, such as an apartment house, a business office, an office, a store.

  The distribution board 3 is supplied with AC power (commercial power) from the commercial power supply 8 via the power system L <b> 1 and supplied with AC power from the power converter 4. The distribution board 3 includes a branching portion 31 including a main breaker, a plurality of branch breakers, a switch, and the like. The distribution board 3 supplies AC power to the load 9 through a plurality of branch circuits L2 branched on the respective load sides of the plurality of branch breakers. Note that the load 9 in FIG. 1 is an electrical device such as an illumination device, an air conditioner, or an information device connected to the branch circuit L2.

  In addition, the distribution board 3 includes a current measuring unit 32. The current measuring unit 32 measures the current of each part in the distribution board 3 (for example, the total current, the branch current for each branch circuit L2, the power generation current of the solar power generation device 40 described later), and the like. Measurement data can be generated. The current measurement unit 32 periodically generates measurement data, and generates measurement data at intervals of 1 minute, for example. Then, the current measurement unit 32 periodically transmits measurement data to the measurement unit 2. The data transmission path between the current measurement unit 32 and the measurement unit 2 may be either wired or wireless. Further, the current measuring unit 32 may be configured to be provided outside the distribution board 3.

  The power conversion device 4 converts the DC power output from the solar cell 5 into AC power (generated power) and supplies it to the power system L <b> 1 through the distribution board 3. The power conversion device 4 has a function of adjusting the frequency and output voltage of the generated power to be output so that the grid connection with the power system L1 is possible. The generated power supplied to the power system L1 is supplied from the distribution board 3 to the load 9 through the branch circuit L2. Surplus power that is not consumed by the load 9 is sold in reverse power flow through the power system L1.

  In the present embodiment, the power conversion device 4 and the solar battery 5 constitute a solar power generation device 40, and the solar power generation device 40 corresponds to the power generation device. In addition, the power generation device may be another power generation device such as a wind power generation device or a storage battery device, and may further use a plurality of power generation devices.

  Then, the power management system 100 controls the power conversion device 4 to generate power of the solar power generation device 40 by controlling the power conversion device 4 and the so-called “visualization” function for notifying the user of the power usage status and power generation status in the customer facility. And a power management function for controlling the operation.

  The power management system 100 includes a monitor device 1 and a measurement unit 2. The monitor device 1 corresponds to an information device, and includes a first communication unit 11, a display unit 12, an acquisition unit 13, a first storage unit 14, an information processing unit 15, and a clock unit 16. The measurement unit 2 includes a second communication unit 21, a power calculation unit 22, an information management unit 23, a second storage unit 24, and a control unit 25.

  First, the “visualization” function of the power management system 100 will be described.

  In the measurement unit 2, the power calculation unit 22 acquires measurement data from the current measurement unit 32. And the electric power calculation part 22 produces | generates electric power data, such as total electric power data and the branch electric power for every branch circuit L2, based on the measurement data of the electric current of each said part. Furthermore, the power calculation unit 22 can also create power data such as the amount of power sold and the amount of power purchased.

  The first communication unit 11 of the monitor device 1 and the second communication unit 21 of the measurement unit 2 function as a communication interface that communicates between the monitor device 1 and the measurement unit 2. In this embodiment, the 1st communication part 11 and the 2nd communication part 21 are performing radio | wireless communication, and specific low power radio | wireless is used for radio | wireless communication, for example. Note that the wireless communication specifications used by the first communication unit 11 and the second communication unit 21 may be appropriately selected from a wireless local area network (LAN), Bluetooth (registered trademark), and the like. Moreover, the 1st communication part 11 and the 2nd communication part 21 may perform wired communication, and the specification of wired communication is suitably selected from wired LAN, power line carrier communication, etc.

  Then, the power calculation unit 22 of the measurement unit 2 transmits power data to the monitor device 1 via the second communication unit 21.

  In the monitor device 1, the display unit 12 is configured by a liquid crystal screen, for example, and receives power data via the first communication unit 11 and displays each data. The user can know the usage status, power generation status, power purchase status, power sale status, etc. of the customer facility by looking at the display unit 12.

  Next, the power management function of the power management system 100 will be described.

  The acquisition unit 13 of the monitor device 1 is connected via a router 6 to a wide area network 200 including the external Internet. The acquiring unit 13 can communicate with the server 300 on the wide area network 200. The server 300 is managed by an electric power company or an aggregator. The power company or aggregator causes the server 300 to transmit various requests, information, and the like from the server 300 to the customer facility based on the commercial power supply / demand balance of the power system L1.

  Here, it has been proposed that an electric power company, an aggregator, or the like (hereinafter referred to as a power manager) requests the customer facility to suppress the output of the solar power generation device 40. For example, when the supply and demand balance of commercial power in the power system L1 is predicted to increase as compared with the power demand, the power manager requests the customer facility to suppress the output of the solar power generation device 40. .

  Specifically, the power manager notifies the content of output suppression by transmitting schedule data (control content) regarding power generation suppression of the solar power generation device 40 from the server 300 to the customer facility. The schedule data is data for each day, and each piece of output suppression instruction value and suppression period information is associated with the target day. That is, schedule data shows the control content of the solar power generation device 40 for every day which is a unit period.

  The acquisition unit 13 periodically acquires schedule data related to power generation suppression for a predetermined number of days from the server 300 and stores the schedule data for the predetermined number of days in the first storage unit 14. At this time, the expiration date is set by the server 300 in the schedule data for the predetermined number of days acquired by the acquisition unit 13. This expiration date is set, for example, by the next scheduled date when the acquisition unit 13 acquires schedule data from the server 300.

  In the present embodiment, schedule data for 400 days is stored in the first storage unit 14, and the schedule data for 400 days is referred to as first control information. In the present embodiment, the first storage unit 14 is a ROM (Read Only Memory) or a nonvolatile RAM (Random Access Memory), and is stored in the first storage unit 14 when the monitor device 1 is powered off. The data that is stored is not erased.

  The clock unit 16 has a clock function that counts the current time (including date and time in addition to time). The clock unit 16 can set clock information such as the current time by accessing an NTP (Network Time Protocol) server on the wide area network 200 and inquiring about the current time. The information processing unit 15 can determine the expiration date of the schedule data stored in the first storage unit 14 with reference to the clock information of the clock unit 16.

  And the information processing part 15 can extract the 2nd control information comprised from the 1st-multiple days schedule data from the 1st control information stored in the 1st memory | storage part 14. FIG. The information processing unit 15 transmits the second control information to the measurement unit 2 via the first communication unit 11. In the measurement unit 2, the information management unit 23 stores the received second control information in the second storage unit 24. In the present embodiment, the second storage unit 24 is a volatile RAM, and the data stored in the second storage unit 24 is erased when the measurement unit 2 is powered off.

  The control unit 25 of the measurement unit 2 is configured to be able to communicate with the power conversion device 4. As a communication protocol used for communication between the measurement unit 2 and the power conversion device 4, for example, a Modbus (registered trademark) standard or the like is used. In addition, the specific communication protocol is not limited for the communication protocol used for communication between the measurement unit 2 and the power converter device 4. And the control part 25 refers to the 2nd control information stored in the 2nd memory | storage part 24, adjusts operation | movement of the power converter device 4 based on today's schedule data, and suppresses the output of the solar power generation device 40 Take control.

  Moreover, when the some solar power generation device 40 is provided, the control part 25 hold | maintains the data of each power generation capacity (maximum capacity | capacitance which can be generated) of the some solar power generation device 40 previously. And the control part 25 divides | segments an output suppression instruction | indication value according to each electric power generation capacity | capacitance based on today's schedule data, and allocates an output suppression instruction | indication value to each of the some solar power generation device 40. FIG. That is, the schedule data transmitted from the server 300 is the entire output suppression instruction value requested to the customer facility. And the control part 25 divides | segments the whole output suppression instruction | indication value according to each power generation capacity of the several photovoltaic power generation apparatus 40 based on today's schedule data, and the divided | segmented output suppression instruction | indication value is made into several solar Each of the photovoltaic power generation devices 40 is individually assigned. And the control part 25 adjusts operation | movement of each power converter device 4 of the several photovoltaic power generation apparatus 40 separately, and performs output suppression control.

  FIG. 2 is a flowchart showing the operation when the monitor device 1 is started up.

  When the monitor device 1 is activated (S1), the information processing unit 15 determines the presence / absence of clock information in the clock unit 16 (S2). If there is no clock information, the clock unit 16 accesses the NTP server and sets clock information such as the current time (S3). When there is clock information in step S2 or when clock information is set in step S3, the information processing unit 15 determines whether or not the first control information stored in the first storage unit 14 is within the expiration date. Is determined (S4). Specifically, the information processing unit 15 compares the expiration date set in the first control information with the clock information to determine whether the first control information is within the expiration date.

  When the information processing unit 15 determines that the first control information is not valid, the information processing unit 15 instructs the acquisition unit 13 to acquire a full schedule (schedule data for 400 days from today). The acquisition unit 13 accesses the server 300, acquires the full schedule, deletes the first control information (schedule data for 400 days) that is not valid, and sets the full schedule as new first control information. 1 is stored in the storage unit 14 (S5). That is, the first control information in the first storage unit 14 is updated to the latest contents.

  Alternatively, an expiration date may be individually set for each of a plurality of schedule data constituting the second control information. In this case, when the information processing unit 15 determines that one or more schedule data is out of the expiration date, the information processing unit 15 acquires the same number of new schedule data as the schedule data that is out of the expiration date. Instruct. The acquisition unit 13 accesses the server 300 to acquire new schedule data, delete old schedule data that is outside the expiration date, and store the new schedule data in the first storage unit 14.

  The information processing unit 15 extracts schedule data for 15 days (maximum number of days) from today from the first control information composed of 400 days of schedule data, and the schedule data for 15 days is second As control information, it transmits to the measurement unit 2 via the 1st communication part 11 (S6).

  The communication sequence of FIG. 3 shows the transmission process of the 2nd control information performed by step S6. In step S6, schedule data for 15 days, which is the maximum number of days that can be held by the measurement unit 2, is transmitted as second control information.

  First, the information processing unit 15 of the monitor device 1 transmits a power data request P1 to the measurement unit 2. In the measurement unit 2, the power calculation unit 22 sends back power data response P <b> 2 to the monitor device 1, thereby transmitting power data to the monitor device 1. Note that the transmission processing of the power data request P1 and the power data response P2 may be omitted.

  Then, the information processing unit 15 transmits a setting request X11 including today's schedule data to the measurement unit 2. In the measurement unit 2 that has received the setting request X11, the information management unit 23 stores today's schedule data in the second storage unit 24 and returns a setting response X21 to the monitor device 1.

  Next, the information processing unit 15 transmits a PCS (Power Control System) information request Y <b> 11 to the measurement unit 2. In the measurement unit 2 that has received the PCS information request Y11, the information management unit 23 generates PCS information including the storage status of the second control information in the second storage unit 24, and the information management unit 23 includes the PCS information including the PCS information. A response Y21 is returned to the monitor device 1. In addition to the storage status of the second control information, the PCS information includes information such as the power generation capacity of the photovoltaic power generation apparatus 40, the power generation amount (instantaneous value, integrated value), and the output suppression status according to the currently executing schedule. It is.

  The information processing unit 15 of the monitoring device 1 confirms that today's schedule data is stored in the second storage unit 24 based on the received PCS information, and then sends a setting request X12 including the next day's schedule data to the measurement unit. 2 to send. In the measurement unit 2 that has received the setting request X12, the information management unit 23 stores the next day's schedule data in the second storage unit 24, and returns a setting response X22 to the monitor device 1.

  Next, the information processing unit 15 transmits a PCS information request Y12 to the measurement unit 2. In the measurement unit 2 that has received the PCS information request Y12, the information management unit 23 generates PCS information and returns a PCS information response Y22 including the PCS information to the monitor device 1.

  The information processing unit 15 of the monitor device 1 confirms that the schedule data for the next day is stored in the second storage unit 24 based on the received PCS information, and then the setting requests X13 and X14 including the schedule data for the day after tomorrow. ,. . . Each of X115 is sequentially transmitted to the measurement unit 2.

  Setting requests X13, X14,. . . In the measurement unit 2 that has received each of X115, the information management unit 23 stores the schedule data for the day after tomorrow in the second storage unit 24, and the setting responses X23, X24,. . . X215 is returned to the monitor device 1 respectively.

  The information processing unit 15 then sends the PCS information requests Y13, Y14,. . . Y115 is transmitted to the measurement unit 2 respectively. PCS information request Y13, Y14,. . . In the measurement unit 2 that has received each of Y115, the information management unit 23 generates PCS information, and the information management unit 23 includes PCS information responses Y23, Y24,. . . Y215 is returned to the monitor device 1 respectively. Based on the received PCS information, the information processing unit 15 of the monitor device 1 can confirm that schedule data for the day after tomorrow is stored in the second storage unit 24.

  As a result, schedule data for 15 days from today is stored in the second storage unit 24 of the measurement unit 2 as the second control information. If the information processing unit 15 of the monitor device 1 determines that the storage of the schedule data in the second storage unit 24 has failed based on the received PCS information, it resends the schedule data (setting request). Then re-execute the above procedure.

  The measurement unit 2 appropriately acquires clock information of the clock unit 16 of the monitor device 1 in communication exchanged with the monitor device 1 and maintains the clock information by an internal clock or the like. And the control part 25 of the measurement unit 2 adjusts operation | movement of the power converter device 4 based on today's schedule data, and performs output suppression control of the solar power generation device 40. FIG. And also in each day after the next day, the control part 25 adjusts operation | movement of the power converter device 4 of each day based on each schedule data after the next day, and performs output suppression control of the solar power generation device 40. FIG.

  In step S4, when the information processing unit 15 determines that the first control information is within the expiration date, the information processing unit 15 transmits a PCS information request and acquires the PCS information from the measurement unit 2 (S7). . The PCS information includes the storage status of the second control information in the second storage unit 24, and the information processing unit 15 stores the schedule data stored in the second storage unit 24 based on the received PCS information. The state of (second control information) can be known.

  Then, the information processing unit 15 determines whether there is a date in which schedule data is not stored in 15 days from today as a storage status of the second control information in the second storage unit 24 (whether there is an empty schedule). (S8). This vacant schedule occurs when a malfunction such as a communication failure between the monitor device 1 and the measurement unit 2 or a power failure of the monitor device 1 due to a power failure or the like occurs. Specifically, when the above-described problem occurs when the schedule data is transmitted from the monitor device 1 to the measurement unit 2 in the initial state (the state in which no schedule data is stored in the second storage unit 24). It occurs in such as.

  When there is no empty schedule, the information processing unit 15 determines whether past (before yesterday) schedule data is stored as the storage status of the second control information in the second storage unit 24 (whether there is a past schedule). ) Is determined (S9). This past schedule occurs when a failure such as a communication failure between the monitor device 1 and the measurement unit 2 or a power failure of the monitor device 1 due to a power failure occurs.

  When there is a past schedule, the information processing unit 15 transmits the same number of new schedule data as the number of past schedules as second control information (S10). Upon receiving new schedule data, the information management unit 23 stores the new schedule data in the second storage unit 24 and deletes the past schedule from the second storage unit 24. If there is no past schedule, the information processing section 15 ends this process.

  For example, as shown in FIG. 4, schedule data for 15 days from May 11 to May 25 is stored in the second storage unit 24, and for 3 days from May 11 to May 13. Suppose that the schedule data is a past schedule. In this case, the information processing unit 15 transmits the schedule data for May 26 to May 28 as new schedule data for three days. These new schedule data are the schedule data for 3 days following the last date (in this case, May 25) of the schedule data stored in the second storage unit 24.

  Specifically, as illustrated in FIG. 5, the information processing unit 15 transmits a setting request X120 including schedule data for May 26 to the measurement unit 2. In the measurement unit 2 that has received the setting request X120, the information management unit 23 stores the May 26 schedule data in the second storage unit 24, and the May 11 schedule data that is the oldest past schedule at the present time is stored. Delete from the second storage unit 24. Thereafter, the information management unit 23 returns a setting response X220 to the monitor device 1.

  Next, the information processing unit 15 transmits a PCS information request Y120 to the measurement unit 2. In the measurement unit 2 that has received the PCS information request Y120, the information management unit 23 generates PCS information, and the information management unit 23 returns a PCS information response Y220 including the PCS information to the monitor device 1. The information processing unit 15 of the monitor device 1 can confirm that the schedule data for May 26 is stored in the second storage unit 24 based on the received PCS information.

  Thereafter, the information processing unit 15 transmits a setting request X121 including schedule data for May 27, and a setting request X122 including schedule data for May 28, respectively, as described above. The information management unit 23 stores the schedule data for May 27 and 28 in the second storage unit 24 and deletes the schedule data for May 12 and 13 as the past schedule from the second storage unit 24. To do. Thereafter, the information management unit 23 returns setting responses X221 and X222 to the monitor device 1, respectively. Further, similarly to the above, the information processing unit 15 transmits the PCS information requests Y121 and Y122, and receives the PCS information responses Y221 and Y222 returned from the measurement unit 2.

  As a result, since the measurement unit 2 can update the schedule data and delete the past schedule, the measurement unit 2 can hold the latest schedule data for a maximum of 15 days by effectively using the resources of the second storage unit 24.

  In step S8, when there is an empty schedule, the information processing unit 15 executes a transmission process (S11) according to the past schedule and a transmission process (S12) according to the empty schedule in this order.

  Since the transmission process according to the past schedule in step S11 is the same as the transmission process according to the past schedule in step S9, description thereof is omitted.

  Next, the transmission process according to the empty schedule in step S12 will be described.

  For example, as shown in FIG. 6, schedule data for 13 days from May 14 to May 26 is stored in the second storage unit 24, and May 27, May following May 26 Assume that an empty schedule for two days has occurred on the 28th. In FIG. 6, the vacant schedule is represented by “FFFF”. And the information processing part 15 transmits the schedule data of the date corresponding to an empty schedule as new schedule data for 2 days. In this case, schedule data for May 27 and May 28 are transmitted.

  Specifically, as illustrated in FIG. 7, the information processing unit 15 transmits a setting request X 130 including schedule data for May 27 to the measurement unit 2. In the measurement unit 2 that has received the setting request X130, the information management unit 23 stores the schedule data for May 27 in the second storage unit 24. Thereafter, the information management unit 23 returns a setting response X230 to the monitor device 1.

  Next, the information processing unit 15 transmits a PCS information request Y130 to the measurement unit 2. In the measurement unit 2 that has received the PCS information request Y130, the information management unit 23 generates PCS information, and the information management unit 23 returns a PCS information response Y230 including the PCS information to the monitor device 1. The information processing unit 15 of the monitor device 1 can confirm that the schedule data for May 27 has been stored in the second storage unit 24 based on the received PCS information.

  Next, the information processing unit 15 transmits a setting request X131 including the May 28 schedule data in the same manner as described above. The information management unit 23 stores the schedule data for May 28 in the second storage unit 24. Thereafter, the information management unit 23 returns a setting response X231 to the monitor device 1. Further, the information processing unit 15 transmits the PCS information request Y131 and receives the PCS information response Y231 returned from the measurement unit 2 as described above.

  As a result, when the number of data, which is the number of daily schedule data (control contents) stored in the second storage unit 24, is less than 15, the measurement unit 2 acquires the second control information acquired from the monitor device 1. (Schedule data) is stored in the second storage unit 24. Therefore, since the measurement unit 2 can eliminate the empty schedule, the latest schedule data for a maximum of 15 days can be held by effectively using the resources of the second storage unit 24.

  As described above, the monitor device 1 acquires schedule data for 400 days from the server 300 if the expiration date of the first control information stored in the first storage unit 14 has passed at the time of startup. The latest first control information is held. Then, the monitor device 1 extracts the second control information from the latest first control information and transmits it to the measurement unit 2. Furthermore, the monitor device 1 detects a past schedule and an empty schedule of the second control information in the second storage unit 24 of the measurement unit 2 and transmits new schedule data to the measurement unit 2. Therefore, the monitor device 1 can update the second control information held by the measurement unit 2 to the latest information at the time of activation.

  After the monitor device 1 is activated and executes the processing according to the flowchart of FIG. 2, when the daily fixed time (for example, 1 am) is reached, the information processing unit 15 of the monitor device 1 schedules for a new day. Data is transmitted as second control information.

  Specifically, it is assumed that schedule data for May 14 to May 28 is stored in the second storage unit 24. In this case, when it is 1:00 am on May 15 (when straddling), the information processing unit 15 of the monitor device 1 sends a setting request X140 including schedule data for May 29 to the measurement unit 2 as shown in FIG. Send to. In the measurement unit 2 that has received the setting request X140, the information management unit 23 stores the schedule data for May 29 in the second storage unit 24, and the schedule data for May 14 with the oldest date stored in the second storage unit. Delete from 24. Then, the information management unit 23 returns a setting response X240 to the monitor device 1.

  Next, the information processing unit 15 transmits a PCS information request Y140 to the measurement unit 2. In the measurement unit 2 that has received the PCS information request Y140, the information management unit 23 generates PCS information, and the information management unit 23 returns a PCS information response Y240 including the PCS information to the monitor device 1. The information processing unit 15 of the monitor device 1 can confirm that the schedule data for May 29 has been stored in the second storage unit 24 based on the received PCS information.

  As a result, new schedule data is added to the second storage unit 24 of the measurement unit 2 every day and the past schedule is deleted, so that the second control information can always be maintained in the latest state.

  Next, FIG. 9 is a flowchart showing the operation of the monitor device 1 during operation.

  The operating monitoring apparatus 1 performs regular communication for periodically acquiring PCS information from the measurement unit 2 (S21). For example, the information processing unit 15 of the monitor device 1 periodically transmits a PCS information request and receives a PCS information response from the measurement unit 2 to acquire PCS information. In this regular communication, the information processing unit 15 stores the number of empty schedules as the second control information storage status in the second storage unit 24 while overwriting and updating for each regular communication based on the PCS information.

  Next, the information processing unit 15 determines whether the measurement unit 2 is restarted (S22). Specifically, when the measurement unit 2 is powered off due to a power failure or the like, the schedule data (second control information) transmitted from the monitor device 1 during this power interruption period is stored in the second storage unit 24 of the measurement unit 2. Not stored. In addition, since the second storage unit 24 is a volatile RAM, all schedule data stored in the second storage unit 24 is erased when the power of the measurement unit 2 is turned off. Therefore, the information processing unit 15 determines whether or not the number of empty schedules based on the PCS information acquired in the current periodic communication is less than the number of empty schedules based on the PCS information acquired in the previous periodic communication.

  Then, if the number of current empty schedules is equal to or greater than the number of previous empty schedules, the information processing unit 15 determines that the measurement unit 2 is not restarted and stores the number of current empty schedules. (S23).

  In addition, if the number of current empty schedules is less than the previous number of empty schedules, the information processing unit 15 determines that the measurement unit 2 has been restarted, and further stores the number of current empty schedules. deep. Thereafter, the information processing unit 15 performs a transmission process according to the empty schedule and the past schedule by executing the same processes as steps S4 to S12 in FIG.

  Therefore, even when the measurement unit 2 is restarted during the operation of the monitor device 1, the second control information held by the measurement unit 2 is updated and the second control information is maintained in the latest state. be able to.

  As described above, the monitor device 1 acquires schedule data for 400 days from the server 300 and holds it as first control information. And the monitor apparatus 1 can produce the 2nd control information comprised by the schedule data for 1 day-several days from 1st control information. The monitor device 1 transmits this second control information to the measurement unit 2. In the measurement unit 2, the received second control information is stored in the second storage unit 24, and the output suppression control of the solar power generation device 40 is executed based on the second control information that is schedule data for 15 days. .

  Therefore, even when the communication between the monitoring device 1 and the measurement unit 2 is interrupted, the measurement unit 2 is capable of receiving sunlight for a maximum of 15 days based on the schedule data for 15 days that it holds. The output suppression control of the power generator 40 can be continued. Factors that interrupt communication between the monitor device 1 and the measurement unit 2 include stoppage of power supply to the monitor device 1 (such as disconnection of an outlet plug) and failure of the monitor device 1.

  The monitor device 1 can store schedule data for 400 days, but the number of days for storing the schedule data may be other than 400 days. Moreover, although the measurement unit 2 can store the schedule data for 15 days, the number of days for storing the schedule data may be other than 15 days.

  The power management system 100 described above includes a monitor device 1 (first device) and a measurement unit 2 (second device) configured to be able to communicate with each other.

  The monitor device 1 includes an acquisition unit 13, a first storage unit 14, and an information processing unit 15. The acquisition part 13 acquires the 1st control information containing the control content of the solar power generation device 40 (power generation device) in a 1st period (for example, 400 days). The first storage unit 14 stores first control information. The information processing unit 15 creates second control information including the control content of the solar power generation device 40 in the second period based on the first control information, and transmits the second control information to the measurement unit 2.

  The measurement unit 2 includes a second storage unit 24 and a control unit 25. The second storage unit 24 stores the second control information received from the monitor device 1. The control unit 25 controls the solar power generation device 40 based on the second control information stored in the second storage unit 24.

  The second period is included in the first period and is shorter than the first period.

  Therefore, even if the power management system 100 is a case where the communication between the monitor device 1 and the measurement unit 2 is interrupted, the measurement unit 2 uses the second control information held by the photovoltaic power generation system. The output suppression control of the device 40 can be continued. That is, the power management system 100 can continue to control the power generation device such as the solar power generation device 40 even when a problem occurs in the system.

  Moreover, it is preferable that the monitor device 1 includes a first communication unit 11 having a function of performing wireless communication, and the measurement unit 2 includes a second communication unit 21 having a function of performing wireless communication.

  In this case, even when a failure occurs in the wireless communication between the monitor device 1 and the measurement unit 2, the control of the power generation device such as the solar power generation device 40 is continued.

  Moreover, it is preferable that 1st control information is comprised by the several schedule data which contain the schedule data which are the control content of the solar power generation device 40 in a unit period, and continue in time series over a 1st period. The second control information is preferably composed of one or more schedule data included in the first control information.

  In this case, the power management system 100 can execute control such as output suppression on each day for the solar power generation device 40.

  The second storage unit 24 can store a predetermined number (for example, 15 days) of schedule data. When the number of data, which is the number of schedule data stored in the second storage unit 24, is less than the predetermined number, new schedule data is stored in the second storage unit 24 so that the number of data becomes the predetermined number. It is preferable.

  Therefore, since the measurement unit 2 can eliminate the empty schedule, it can hold a predetermined number of the latest control contents (schedule data) by effectively using the resources of the second storage unit 24.

  Further, the information processing unit 15 determines whether or not the number of data is less than the predetermined number. If the number of data is less than the predetermined number, the schedule data is transmitted to the measurement unit 2 so that the number of data becomes the predetermined number. It is preferable to do.

  Therefore, since the monitor device 1 can eliminate the empty schedule, it can hold a predetermined number of the latest control contents (schedule data) by effectively using the resources of the second storage unit 24.

  Moreover, it is preferable that the monitor device 1 further includes a clock unit 16 that measures the current time. Then, when the monitor device 1 is activated, the information processing unit 15 deletes, from the first storage unit 14, schedule data whose current time is outside the expiration date from among a plurality of schedule data constituting the first control information.

  Therefore, the monitor device 1 can update the first control information to the latest control content (schedule data) at the time of activation.

The monitor device 1 (information device) described above includes an acquisition unit 13, a first storage unit 14, and an information processing unit 15. The acquisition part 13 acquires the 1st control information containing the control content of the solar power generation device 40 (power generation device) in a 1st period (for example, 400 days). The first storage unit 14 stores first control information. The information processing unit 15 creates second control information including the control content of the solar power generation device 40 in the second period based on the first control information, and transmits the second control information. The second period is a period that is included in the first period and shorter than the first period. Therefore, the monitor apparatus 1 can measure even if the communication with the measurement unit 2 is interrupted. The unit 2 can continue the output suppression control of the solar power generation device 40 based on the second control information held. That is, the monitor device 1 can continue the control of the power generation device such as the solar power generation device 40 even when a problem occurs in the system.

  The monitor device 1 is equipped with a computer, and the functions of the monitor device 1 described above are realized by the computer executing a program. The computer is mainly composed of a device having a processor for executing a program, an interface device for transferring data to and from another apparatus, and a storage device for storing data. Prepare as. A device provided with a processor may be a CPU (Central Processing Unit) or MPU (Micro Processing Unit) which is a separate body from the semiconductor memory, or a microcomputer integrally including a semiconductor memory. As a storage device, a storage device having a short access time such as a semiconductor memory and a large-capacity storage device such as a hard disk device are used in combination.

  As a program providing form, a computer-readable ROM (Read Only Memory), a form stored in advance in a recording medium such as an optical disk, a form supplied to the recording medium via a wide-area communication network including the Internet, etc. There is.

  The above-described program causes a computer to function as the acquisition unit 13 and the information processing unit 15. The acquisition part 13 acquires the 1st control information containing the control content of the solar power generation device 40 (power generation device) in a 1st period. The information processing unit 15 creates second control information including the control content of the solar power generation device 40 in the second period based on the first control information, and transmits the second control information. The second period is included in the first period and is shorter than the first period.

  Therefore, by executing this program, it is possible to continue the control of the power generation device such as the solar power generation device 40 even when a problem occurs in the system.

  Moreover, the measurement unit 2 is also equipped with a computer, and the function of the measurement unit 2 described above is realized by the computer executing a program.

  The second storage unit 24 may use a nonvolatile RAM or ROM in addition to the volatile RAM.

  Further, the configuration and operation of the above-described embodiment can be applied to the above-described program, and the same effect as described above can be obtained.

  Moreover, each part of the 1st communication part 11, the acquisition part 13, the 1st memory | storage part 14, the information processing part 15, and the clock part 16 is provided in one monitor apparatus 1 in a consumer facility as mentioned above. However, it may be distributed to a plurality of devices. For example, each part may be provided in a server on the network, or a cloud computer system may constitute each part. Furthermore, a plurality of apparatuses in the customer facility may be provided with each part dispersed.

  Furthermore, each part of the 2nd communication part 21, the information management part 23, the 2nd memory | storage part 24, and the control part 25 may be similarly distributed over several apparatuses.

  The above-described embodiment is an example of the present invention. For this reason, the present invention is not limited to the above-described embodiment, and various modifications can be made depending on the design and the like as long as the technical idea according to the present invention is not deviated from this embodiment. Of course, it is possible to change.

1 Monitor device (first device) (information device)
DESCRIPTION OF SYMBOLS 11 1st communication part 12 Display part 13 Acquisition part 14 1st memory | storage part 15 Information processing part 16 Clock part 2 Measurement unit 2 (2nd apparatus)
DESCRIPTION OF SYMBOLS 21 2nd communication part 22 Power calculation part 23 Information management part 24 2nd memory | storage part 25 Control part 3 Distribution board 4 Power converter device 5 Solar cell 9 Load 40 Solar power generation device (power generation device)
100 power management system 200 wide area network 300 server

Claims (7)

A first device and a second device configured to communicate with each other;
The first device is based on an acquisition unit that acquires first control information including control details of the power generation device in a first period, a first storage unit that stores the first control information, and a first control information. Creating second control information including control contents of the power generation device in two periods, and having an information processing unit for transmitting the second control information to the second device;
The second device controls the power generation device based on a second storage unit that stores the second control information received from the first device, and the second control information stored in the second storage unit. Having a control unit,
The second period is included in the first period, and Ri period shorter der than the first period,
The first control information includes schedule data that is control content of the power generation device in a unit period, and is configured by a plurality of schedule data that is continuous in time series over the first period,
The power management system, wherein the second control information includes one or more schedule data included in the first control information .   2. The power according to claim 1, wherein the first device includes a first communication unit having a function of performing wireless communication, and the second device includes a second communication unit having a function of performing wireless communication. Management system. The second storage unit can store a predetermined number of schedule data, and if the number of schedule data stored in the second storage unit is less than the predetermined number, the number of data is The power management system according to claim 1 or 2, wherein new schedule data is stored in the second storage unit so as to be a predetermined number. The information processing unit determines whether the number of data is less than the predetermined number. If the number of data is less than the predetermined number, the information processing unit sets the schedule data so that the number of data becomes the predetermined number. The power management system according to claim 3, wherein the power management system transmits to the second device. The first device further includes a clock unit for measuring the current time,
  At the time of starting up the first device, the information processing unit deletes, from the first storage unit, schedule data whose current time is outside the expiration date among a plurality of schedule data constituting the first control information.
  The power management system according to claim 1, wherein the power management system is a power management system. An acquisition unit for acquiring first control information including control contents of the power generation device in the first period;
  A first storage unit for storing the first control information;
  An information processing unit that creates second control information including control content of the power generation device in a second period based on the first control information, and transmits the second control information;
  The second period is included in the first period and is shorter than the first period.
  The first control information includes schedule data that is control content of the power generation device in a unit period, and is configured by a plurality of schedule data that is continuous in time series over the first period,
  The second control information is composed of one or more schedule data included in the first control information.
  An information device characterized by that. Computer
  An acquisition unit for acquiring first control information including control contents of the power generation device in the first period;
  And creating second control information including the control content of the power generation device in the second period based on the first control information, and functioning as an information processing unit that transmits the second control information,
  The second period is included in the first period and is shorter than the first period,
  The first control information includes schedule data that is control content of the power generation device in a unit period, and is configured by a plurality of schedule data that is continuous in time series over the first period,
  The second control information is composed of one or more schedule data included in the first control information.
  A program characterized by that.

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