JP6692729B2 - Firmware providing system, firmware providing system control method, and power supply system - Google Patents

Description

  The present invention relates to a firmware providing system, a firmware providing system control method, and a power supply system.

  It is desirable to provide the firmware of the electric device according to the version upgrade of the firmware to the electric device that realizes a desired function by the firmware. Therefore, in the electric device having the communication function, the firmware of the electric device is updated in accordance with the version upgrade of the firmware by downloading the firmware from the external server to the electric device.

  On the other hand, the size of the firmware of the electric device is increasing as the function of the electric device is enhanced. Therefore, when a plurality of electric devices try to download the firmware from the server at the same time, the load on the server may increase and the server may go down. Therefore, in order to avoid such a situation, an update system including a home communication device (BroadBand Router) that stores firmware and a management server that manages the firmware of the home communication device is disclosed (Patent Document 1).

JP2012-118914A

  In the update system described in Patent Document 1, it is necessary to provide a management server in addition to the providing server that provides the firmware. Therefore, providing the management server may increase the cost.

  Furthermore, the download and update of the firmware of the power supply device such as the fuel cell device and the controller that controls the power supply device must be completed without fail. However, in the update system described in Patent Document 1, when the download of the firmware of the home communication device is interrupted halfway and completed incompletely, how to provide the firmware of the home communication device thereafter It is not mentioned.

  An object of the present invention made in view of such a point is to provide a firmware providing system that efficiently downloads and updates the firmware of a power supply device and a controller, a control method of the firmware providing system, and a power supply system.

  A firmware providing system according to an embodiment of the present invention includes a server that provides firmware to a plurality of power supply devices and control devices respectively corresponding to the plurality of power supply devices via a network. The server allocates the first date and time when each of the control devices downloads the firmware from the server to the control device so as not to exceed the data capacity of the server that can be broadcast. Further, the server transmits schedule information including the first date and time to each of the control devices. Each of the control devices includes a communication unit that communicates with the server via the network, and a control unit. The control unit acquires the schedule information from the server via the communication unit, and further downloads the firmware from the server at the first date and time.

  A control method of a firmware providing system according to an embodiment of the present invention is a control method of a firmware providing system including a plurality of power supply devices and a server that provides firmware of a control device corresponding to each power supply device. The control method of the firmware providing system is configured such that the server controls the first date and time when the control device downloads the firmware from the server so as not to exceed a data capacity that can be broadcast by the server. Assign to each device. Further, in the control method of the firmware providing system, the server transmits schedule information including the first date and time to each of the control devices. In addition, in the control method of the firmware providing system, each of the control devices acquires the schedule information from the server. Furthermore, in the control method of the firmware providing system, each of the control devices downloads the firmware from the server at the first date and time.

  A power supply system according to an embodiment of the present invention includes a server that provides firmware to a plurality of power supply devices and control devices respectively corresponding to the plurality of power supply devices via a network, a plurality of power supply devices, and the plurality of power supplies. And a control device corresponding to each device. The server allocates the first date and time when each of the control devices downloads the firmware from the server to the control device so as not to exceed the data capacity of the server that can be broadcast. Further, the server transmits schedule information including the first date and time to each of the control devices. Each of the control devices includes a communication unit that communicates with the server via the network, and a control unit. The control unit acquires the schedule information from the server via the communication unit. Further, the control unit downloads the firmware from the server at the first date and time.

  According to the firmware providing system, the control method of the firmware providing system, and the power supply system according to the embodiment of the present invention, it is possible to efficiently download and update the firmware of the power supply device and the controller.

It is a figure which shows schematic structure of the firmware provision system which concerns on the 1st Embodiment of this invention. FIG. 5 is a sequence diagram showing an example of an operation when acquiring schedule information in the firmware providing system according to the first embodiment of the present invention. FIG. 6 is a sequence diagram showing an example of an operation when downloading firmware in the firmware providing system according to the first embodiment of the present invention. FIG. 6 is a sequence diagram showing an example of an operation when updating firmware in the firmware providing system according to the first embodiment of the present invention. It is a figure which shows schematic structure of the firmware provision system which concerns on the 2nd Embodiment of this invention. FIG. 9 is a sequence diagram showing an example of an operation when setting a download start time and an end time in the firmware providing system according to the second embodiment of the present invention. It is a figure which shows an example of the start time and end time of the download of the controller set by the server. It is a sequence diagram which shows an example of operation | movement at the time of downloading firmware in the firmware provision system which concerns on the 2nd Embodiment of this invention. It is a figure which shows an example of the firmware which each controller hold | maintains, when download is complete | finished. FIG. 11 is a sequence diagram showing an example of an operation when complementing each other with insufficient firmware between controllers in the firmware providing system according to the second embodiment of the present invention.

  Embodiments according to the present invention will be described below with reference to the drawings. In the following description, the “power supply device” in the claims will be described as a “fuel cell device”, but the “power supply device” may be any device that includes a controller (control device) that can communicate with the power supply device. It may be other than the fuel cell device, and may be, for example, a power storage device, a solar power generation device, a gas power generator, or the like.

(First embodiment)
FIG. 1 shows a schematic configuration of a firmware providing system 1 according to the first embodiment of the present invention. The firmware providing system 1 includes a server 10, a plurality of terminal devices, fuel cell devices (power supply devices) 30-1 to 30-n, and controllers (control devices) 40-1 to 40-n. The fuel cell devices 30-1 to 30-n and the controllers 40-1 to 40-n are installed in the same or different customer facilities, respectively. In addition, the plurality of terminal devices are terminal devices used by a user who uses the fuel cell device installed for each different customer facility. In the example of FIG. 1, among the plurality of terminal devices, the fuel cell device is used. Only the terminal device 20 of the user who uses 30-1 is shown.

  The server 10 is connected to the terminal device 20 and the controllers 40-1 to 40-n via the network 100 and the routers 50-1 to 50-n. The server 10 provides the latest firmware to the controllers 40-1 to 40-n corresponding to the fuel cell devices 30-1 to 30-n and the fuel cell devices 30-1 to 30-n, respectively. The latest firmware is provided from the server 10 to the fuel cell devices 30-1 to 30-n via the corresponding controllers 40-1 to 40-n.

  In addition, the server 10 manages a schedule for updating the firmware of the fuel cell devices 30-1 to 30-n and the controllers 40-1 to 40-n. The schedule includes the first dates and times A-1 to A-n at which the controllers 40-1 to 40-n execute the downloading of the latest firmware from the server 10, respectively. In addition, the schedule includes the second dates and times B-1 to B-n at which the controllers 40-1 to 40-n each execute the firmware update.

  Regarding schedule management, the server 10 allocates the first dates A-1 to A-n to the controllers 40-1 to 40-n, respectively, so as not to exceed the data capacity of the server 10 that can be simultaneously transmitted. The first dates A-1 to A-n include the dates when the controllers 40-1 to 40-n execute the download. For example, the server 10 disperses the dates on which the controllers 40-1 to 40-n execute the download of the firmware so that the data capacity that can be simultaneously transmitted by the server 10 is not exceeded.

  At the first date and time A-1 to A-n, the start time, which is the time when each of the controllers 40-1 to 40-n starts downloading the firmware, and each of the controllers 40-1 to 40-n, The end time, which is the time when the download ends, is included. The server 10 sets, for example, the download start time and the download end time of each of the controllers 40-1 to 40-n to a time zone in which the generated power of each of the fuel cell devices 30-1 to 30-n is relatively small. You may. For example, in a consumer facility where the power consumption at night is smaller than the power consumption at daytime, when the fuel cell device 30-1 is performing load following operation, the power generated at night by the fuel cell device 30-1 is , Smaller than the daytime generated power of the fuel cell device 30-1. Therefore, in this case, in the server 10, the controller 40-1 can set the start time and the end time of the firmware download to the night time zone. The server 10 requests the controller 40-1 for the state information of the fuel cell device 30-1 to acquire the information of the generated power of the fuel cell device 30-1 from the controller 40-1.

  Regarding schedule management, the server 10 uses the second date / time B- based on the date / time designated for each fuel cell device 30-1 to 30-n by the user of each fuel cell device 30-1 to 30-n, for example. 1 to B-n are set respectively. The server 10 acquires the date and time designated for each of the fuel cell devices 30-1 to 30-n from the terminal device used by the user via the network 100. For example, the server 10 acquires the date and time designated by the user of the fuel cell device 30-1 from the terminal device 20 via the network 100.

  In addition, the server 10 acquires the schedule information request from the controllers 40-1 to 40-n via the routers 50-1 to 50-n and the network 100, respectively. The server 10 transmits the schedule information to the controller that has transmitted the request for the schedule information. The schedule information includes, for example, the first date and time assigned to the controller to which the schedule information is transmitted, the second date and time set as the date and time when the controller updates the firmware, and the version information of the firmware of the controller and the like. included. For example, the schedule information transmitted from the server 10 to the controller 40-1 includes the first date / time A-1, the second date / time B-1, the firmware version information of the controller 40-1 and the fuel cell device 30-1. Etc. are included.

  The terminal device 20 is a terminal used by a user who uses the fuel cell device 30-1. The terminal device 20 is connected to the server 10 via the network 100. The user uses the terminal device 20 to specify the date and time when the firmware update processing of the fuel cell device 30-1 and the like can be executed, and sends the date and time to the server 10.

  Here, it is necessary to stop the operation of the fuel cell device 30-1 during the firmware update process of the fuel cell device 30-1. Further, the fuel cell device 30-1 may require a long time, for example, about 12 hours, when the operation is stopped. This is because in the fuel cell device 30-1, the operating temperature is high, and when the operation is stopped, the power generation cell is deteriorated due to thermal stress unless the power generation cell is cooled for a sufficient time. This is because there is a risk. Therefore, even if the firmware update process itself of the fuel cell device 30-1 is completed in about several minutes, it is necessary to stop the operation of the fuel cell device 30-1, and as a result, the fuel cell device 30-1 is stopped. The firmware update processing of 30-1 requires a long time. During this time, the customer facility in which the fuel cell device 30-1 is installed cannot receive the power supply from the fuel cell device 30-1. Therefore, in the present embodiment, the user previously designates a date and time when the operation of the fuel cell device 30-1 can be stopped, that is, a date and time when the firmware update process of the fuel cell device 30-1 can be executed, and The device 20 is used to transmit to the server 10. For example, when the consumer facility is a store, the user designates a closed day of the store as the date and time when the firmware update process of the fuel cell device 30-1 can be executed.

  Next, the fuel cell devices 30-1 to 30-n and the controllers 40-1 to 40-n will be described by taking the fuel cell device 30-1 and the controller 40-1 as an example. Note that, hereinafter, the fuel cell device 30-1 will be referred to as “fuel cell device 30”, and the controller 40-1 will be referred to as “controller 40”. Further, the router 50-1 is referred to as "router 50". Further, hereinafter, the first date and time A-1 will be simply referred to as “first date and time”, and the “second date and time B-1” will be simply referred to as “second date and time”.

  The fuel cell device 30 is, for example, a solid oxide fuel cell device (SOFC: Solid Oxide Fuel Cell) or a polymer electrolyte fuel cell device (PEFC: Polymer Electrolyte Fuel Cell). The fuel cell device 30 is installed in a customer facility such as a store. The fuel cell device 30 includes a power generation unit 31, a power conversion unit 32, a communication unit 33, a storage unit 34, and a control unit 35.

  The power generation unit 31 generates power by an electrochemical reaction of fuel (for example, gas, air, and reforming water mixed at a predetermined ratio). The power generation unit 31 supplies the generated DC power to the power conversion unit 32.

  The power conversion unit 32 converts the DC power supplied from the power generation unit 31 into AC power. The power conversion unit 32 supplies the converted AC power to a load device or the like of a customer facility in which the fuel cell device 30 is installed.

  The communication unit 33 communicates with the controller 40 via, for example, a cable.

  The storage unit 34 holds (stores) firmware for realizing each function of the fuel cell device 30. The firmware held in the storage unit 34 is updated to the latest version as the firmware version is updated.

  The control unit 35 is a processor or the like that controls and manages the entire fuel cell device 30. The control unit 35 controls the power conversion unit 32, for example.

  Further, the control unit 35 executes a firmware update process of the fuel cell device 30 based on an instruction from the controller 40. Details of this processing will be described in <Processing when updating firmware> below.

  The controller 40 controls the operation of the fuel cell device 30. The controller 40 is connected to the server 10 via the router 50 and the network 100. Further, the controller 40 is connected to the fuel cell device 30 via, for example, a cable.

  Here, since the controller 40 is connected to the router 50, it can be connected to the server 10 via the network 100 (therefore, the controller 40 is assigned an IP address for connecting to the network 100). .). On the other hand, since the fuel cell device 30 is not connected to the router 50, it cannot be connected to the network 100 (therefore, no IP address is assigned to the fuel cell device 30). Therefore, in the present embodiment, the controller 40 downloads the firmware of the controller 40 itself and the firmware of the fuel cell device 30 from the server 10.

  The controller 40 includes a communication unit 41, a storage unit 42, a display unit 43, and a control unit 44.

  The communication unit 41 communicates with the server 10 via the router 50 and the network 100. The communication unit 41 also communicates with the fuel cell device 30 via, for example, a cable.

  The storage unit 42 holds firmware for realizing each function of the controller 40. The firmware held in the storage unit 42 is updated to the latest version as the firmware version is updated.

  The display unit 43 displays schedule information and the like. The display unit 43 includes, for example, a touch sensor and the like.

  The control unit 44 is a processor or the like that controls and manages the entire controller 40. The control unit 44 downloads and updates the firmware of the controller 40 and the fuel cell device 30 based on the schedule information from the server 10. These processes will be described in <Process for obtaining schedule information>, <Process for downloading firmware> and <Process for updating firmware> below.

<Process when acquiring schedule information>
The process of the control unit 44 when acquiring the schedule information from the server 10 will be described below with reference to FIG. In the firmware providing system 1, the processes of steps S101 to S107 shown in FIG. 2 are performed regularly (for example, about once a day).

  The control unit 44 of the controller 40 transmits a request for schedule information to the server 10 from the communication unit 41 via the router 50 and the network 100 (step S101). When the server 10 acquires the schedule information request from the controller 40, the server 10 transmits the schedule information to the controller 40 (step S102).

  Note that the schedule information has a smaller data capacity than the firmware. Therefore, even if a plurality of controllers download the schedule information from the server at the same timing, it is unlikely that the load on the server 10 increases and the server 10 goes down. Therefore, the controller 40 can acquire the schedule information from the server 10 at an arbitrary timing.

  When the control unit 44 of the controller 40 acquires the schedule information transmitted from the server 10 via the network 100 and the router 50 via the communication unit 41, the control unit 44 analyzes the acquired schedule information (step S103).

  The control unit 44 determines whether there is at least one update of the firmware of the fuel cell device 30 and the controller 40 based on the analyzed schedule information (step S104). For example, the control unit 44 compares the schedule information analyzed in the process of step S103 this time with the schedule information analyzed in the process of step S103 of the previous time to determine whether the schedule information is changed.

  When determining that there is at least one update of the firmware of the fuel cell device 30 and the controller 40 (step S104: Yes), the control unit 44 proceeds to the process of step S105. On the other hand, when the control unit 44 determines that all the firmware of the fuel cell device 30 and the controller 40 has not been updated (step S104: No), the process ends.

  In the process of step S105, the control unit 44 determines whether the schedule information analyzed in the process of step S103 is changed. For example, the control unit 44 compares the schedule information analyzed in the process of step S103 this time with the schedule information analyzed in the process of step S103 of the previous time to determine whether the schedule information is changed.

  By regularly performing the processing of steps S101 to S105 in this way, even if the schedule information is changed on the server 10 side that manages the schedule, the controller 40 side can promptly grasp the change of the schedule information. it can.

  When the control unit 44 determines that the schedule information is not changed (step S105: No), the process proceeds to step S106. On the other hand, when it is determined that the schedule information is changed (step S105: Yes), the control unit 44 proceeds to the process of step S107.

  In the process of step S106, the control unit 44 causes the display unit 43 to display the schedule information and presents it to the user. For example, the control unit 44 will start updating on the day of “XXXXX year XX month XX. The updated controller version is ○○. Also, the updated fuel cell device version is △△. Is displayed on the display unit 43.

  In the process of step S107, the control unit 44 causes the display unit 43 to display the changed schedule information and presents it to the user.

  By regularly performing the processing of steps S101 to S107 in this manner, the schedule information is presented to the user via the display unit 43 regularly (for example, every day) until the update is started. As a result, even if the user does not have the habit of frequently looking at the display unit 43, the possibility of the user visually recognizing the display unit 43 increases before the update is started. Therefore, it is possible to prevent a situation in which the firmware is updated without the user's knowledge.

  In the processes of steps S106 and S107, the control unit 44 may cause the display unit 43 to display a content asking whether the user approves the firmware update. In this case, when the control unit 44 receives a response from the user to approve the firmware update via, for example, the input unit of the controller 40, the control unit 44 performs steps S201 and subsequent steps shown in FIGS. You may make it perform a process.

<Process when downloading firmware>
Next, the processing of the control unit 44 when downloading the firmware will be described with reference to FIG.

  The control unit 44 of the controller 40 transmits a request for the latest firmware from the communication unit 41 to the server 10 via the router 50 and the network 100 at the first date and time when the firmware is downloaded (step S201). When the server 10 acquires the latest firmware request from the controller 40, the server 10 transmits the latest firmware to the controller 40 via the network 100 and the router 50 (step S202).

  The control unit 44 of the controller 40 acquires the latest firmware from the communication unit 41 from the server 10 via the network 100 and the router 50. Then, the control unit 44 holds the latest firmware acquired in the storage unit 42 until the second date and time when the firmware is updated (step S203).

  According to the processing of steps S201 to S203, in the present embodiment, the controller 40 downloads the firmware from the server 10 at the first date and time preset by the server 10. Further, in the present embodiment, the server 10 assigns the first date and time to each controller so as not to exceed the data capacity of the server 10 that can be simultaneously transmitted. As a result, in the present embodiment, it is possible to prevent a situation in which a plurality of controllers try to download the firmware from the server 10 at the same time, the load on the server 10 increases, and the server 10 goes down.

  Here, in the present embodiment, the controller 40 collectively downloads the firmware of the controller 40 itself and the firmware of the fuel cell device 30 from the server 10. Thereby, in the present embodiment, communication traffic can be reduced. Furthermore, in the present embodiment, security can be improved by not connecting the fuel cell device 30 directly to the network 100.

<Process when updating firmware>
Next, the processing of the fuel cell device 30 and the controller 40 when updating the firmware will be described with reference to FIG. In the following, the firmware of both the fuel cell device 30 and the controller 40 will be updated.

  When the second date and time for executing the firmware update comes, the control unit 44 of the controller 40 causes the display unit 43 to display that the firmware update is to be started, and presents it to the user (step S301). The control unit 44 causes the display unit 43 to display, for example, “Firmware update will start. The updated controller version is XX. Also, the updated fuel cell device version is Δ △”. ..

  Next, the control unit 44 executes a firmware update process for the controller 40 (step S302). At this time, the control unit 44 may switch the display, which is displayed on the display unit 43 in the process of step S301, to start the update of the firmware to the display that the firmware is being updated. In this case, the control unit 44 switches the display to the content such as "Firmware is being updated."

  When the firmware update processing of the controller 40 is completed, the control unit 44 of the controller 40 transmits an operation stop request to the fuel cell device 30 via the communication unit 41 (step S303). In the fuel cell device 30, when the control unit 35 acquires the operation stop request from the controller 40 via the communication unit 33, the control unit 35 executes the operation stop process of the fuel cell device (step S304). When the operation stop process of the fuel cell device 30 is completed, the control unit 35 notifies the controller 40 via the communication unit 33 that the operation stop process of the fuel cell device 30 is completed (step S305).

  When the control unit 44 of the controller 40 acquires from the fuel cell device 30 via the communication unit 41 that the operation stop processing of the fuel cell device 30 has been completed, the control unit 44 informs the fuel cell device 30 of the latest state of the fuel cell device 30. The firmware is transmitted via the communication unit 41 (step S306).

  In the fuel cell device 30, when the control unit 35 acquires the latest firmware from the controller 40 via the communication unit 33, the control unit 35 executes the update process of the fuel cell device 30 (step S307). When the updating process of the firmware of the fuel cell device 30 is completed, the control unit 35 transmits the fact that the updating process is completed to the controller 40 via the communication unit 33 (step S308).

  When the control unit 44 of the controller 40 acquires from the fuel cell device 30 via the communication unit 41 that the update processing of the fuel cell device 30 has been completed, the control unit 44 causes the display unit 43 to display that the update processing has been completed, It is presented to the user (step S309). The control unit 44 causes the display unit 43 to display, for example, “Update is completed”.

  In the process of step S301, the control unit 44 causes the display unit 43 to display a content asking whether or not the user approves the start of the firmware update, instead of starting the firmware update. May be. In this case, the control unit 44 is configured to execute the processing of step S302 and subsequent steps when a user approves the start of the firmware update via the touch sensor or the like of the display unit 43. Good.

  Further, when only the firmware of the fuel cell device 30 is updated, the process of step S302 need not be performed. Further, when only the firmware of the controller 40 is updated, the processes of steps S303 to S308 need not be performed.

  Further, in the processing of steps S301 to S309, the firmware of the controller 40 is updated before the firmware of the fuel cell device 30, but the firmware of the controller 40 may be updated first. ..

  As described above, in the present embodiment, the controller 40 downloads the firmware from the server 10 at the first date and time preset by the server 10. Further, in the present embodiment, the server 10 assigns the first date and time to each controller so as not to exceed the data capacity of the server 10 that can be simultaneously transmitted. As a result, in the present embodiment, it is possible to prevent a situation in which a plurality of controllers try to download the firmware from the server 10 at the same time, the load on the server 10 increases, and the server 10 goes down. Therefore, in this embodiment, the firmware of the fuel cell device 30 and the controller 40 can be efficiently downloaded and updated. Further, in the present embodiment, the server 10 that provides the firmware allocates the first date and time to each controller without providing another server dedicated to management, thereby preventing an increase in the load on the server 10. Therefore, the processing according to the present embodiment can be realized without increasing the cost.

  Further, in the present embodiment, the controller 40 downloads and updates the firmware of the fuel cell device 30 and the controller 40 according to the schedule set by the server 10. In other words, the controller 40 need not set the firmware schedule. Therefore, the processing according to the present embodiment can be realized without adding an advanced function for setting a schedule to the controller 40. Therefore, the processing according to the present embodiment can be realized at low cost.

  In addition, in the present embodiment, the controller 40 automatically stops the operation of the fuel cell device 30 and updates the firmware of the fuel cell device 30 according to the set schedule. Therefore, in the present embodiment, it is not necessary to dispatch maintenance personnel to the customer facility in order to update the firmware of the fuel cell device 30. Thereby, in the present embodiment, the firmware of the fuel cell device 30 and the controller 40 can be downloaded and updated more efficiently.

(Second embodiment)
Next, a second embodiment will be described. In the first embodiment, a method of efficiently downloading and updating firmware in a plurality of fuel cell devices and a plurality of controllers respectively installed in the same or different consumer facilities has been described. In the second embodiment, in a plurality of fuel cell devices installed in the same customer facility and set in a parent device or a child device, and in a plurality of controllers set in the parent device or the child device, firmware download and A method for efficiently updating will be described. The differences from the first embodiment will be mainly described below. The same components as those according to the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

  FIG. 5 shows a schematic configuration of the firmware providing system 2 according to the second embodiment of the present invention. The firmware providing system 2 includes a server 10, a terminal device 20, fuel cell devices 30A, 30B and 30C, controllers 40A, 40B and 40C, and routers 50A, 50B and 50C. The fuel cell devices 30A to 30C are installed in the same customer facility and perform a linked operation. Among the plurality of fuel cell devices that perform the linked operation, one of them is set as the parent device, and the other is set as the child device. In the present embodiment, it is assumed that the fuel cell device 30A is set as a parent device and the fuel cell devices 30B and 30C are set as child devices. Further, in the controllers 40A to 40C, the controller 40A corresponding to the parent fuel cell device 30A is set as the parent device, and the controllers 40B and 40C corresponding to the fuel cell devices 30B and 30C are set as the child devices, respectively. I shall.

  Although the firmware providing system 2 including the three fuel cell devices 30A to 30C and the three controllers 40A to 40C is illustrated in FIG. 5, the number of fuel cell devices and controllers is not limited to this. The number may be two, or four or more.

  The server 10 transmits a request for the status information of the fuel cell device 30A to the controller 40A via the network 100. As a response to this request, the server 10 acquires the status information of the fuel cell device 30A from the controller 40A via the network 100. The state information of the fuel cell device 30A includes, for example, the value of the generated power of the fuel cell device 30A and the fact that the fuel cell device 30A is in the connected operation. The server 10 periodically requests the controller 40A for the status information of the fuel cell device 30A, for example, at intervals of several seconds. Further, the server 10 similarly acquires the state information of the fuel cell devices 30B and 30C from the controllers 40B and 40C, respectively.

  Further, the server 10 sets the start time and the end time of the firmware download included in the first date and time in each of the controllers 40A to 40C based on the state information of the fuel cell devices 30A to 30C. Details of this processing will be described in <Processing for setting start time and set time> below.

  The fuel cell device 30A, which is the parent device, performs power generation and the like under the control of the controller 40A, which is the parent device. The fuel cell device 30A, which is the parent device, operates as a base power source in the fuel cell devices 30A to 30C that perform the linked operation, for example. The fuel cell device 30A includes a power generation unit 31A, a power conversion unit 32A, a communication unit 33A, a storage unit 34A, and a control unit 35A. The power generation unit 31A, the power conversion unit 32A, the communication unit 33A, the storage unit 34A, and the control unit 35A are similar to the power generation unit 31, the power conversion unit 32, the communication unit 33, the storage unit 34, and the control unit 35 illustrated in FIG. 1, respectively. The function of can be realized.

  The fuel cell device 30B, which is a child device, performs power generation and the like under the control of the controller 40B, which is a child device. The fuel cell device 30C, which is a child device, performs power generation and the like under the control of the controller 40C, which is a child device. The fuel cell devices 30B and 30C, which are slave units, perform load following operation, for example. The fuel cell device 30B includes a power generation unit 31B, a power conversion unit 32B, a communication unit 33B, a storage unit 34B, and a control unit 35B. The power generation unit 31B, the power conversion unit 32B, the communication unit 33B, the storage unit 34B, and the control unit 35B are similar to the power generation unit 31, the power conversion unit 32, the communication unit 33, the storage unit 34, and the control unit 35 illustrated in FIG. 1, respectively. The function of can be realized. Further, the fuel cell device 30C includes a power generation unit 31C, a power conversion unit 32C, a communication unit 33C, a storage unit 34C, and a control unit 35C. The power generation unit 31C, the power conversion unit 32C, the communication unit 33C, the storage unit 34C, and the control unit 35C are similar to the power generation unit 31, the power conversion unit 32, the communication unit 33, the storage unit 34, and the control unit 35 illustrated in FIG. 1, respectively. The function of can be realized.

  The controller 40A, which is the parent device, controls the operation of the fuel cell device 30A corresponding to its own device. Further, the controller 40A controls the controllers 40B and 40C that are slaves. The controller 40A includes a communication unit 41A, a storage unit 42A, a display unit 43A, and a control unit 44A. The communication unit 41A, the storage unit 42A, the display unit 43A, and the control unit 44A can realize the same functions as the communication unit 41, the storage unit 42, the display unit 43, and the control unit 44 illustrated in FIG. 1, respectively. The differences will be mainly described below.

  The communication unit 41A communicates with the server 10 via the router 50A and the network 100. Further, the communication unit 41A is renewed with the controller 40B via the routers 50A and 50B, and communicates with the controller 50C via the routers 50A and 50C.

  The control unit 44A acquires, via the communication unit 41A, the request for the state information of the fuel cell device 30A transmitted from the server 10 via the network 100 and the router 50A. Then, the control unit 44A transmits the state information of the fuel cell device 30A from the communication unit 41A to the server 10 via the network 100 and the router 50A.

  Further, when the control unit 44A acquires the schedule information from the server 10, the control unit 44A analyzes the acquired schedule information and detects the start time and the end time of the download of the own device. Further, the control unit 44A acquires the download start time and the download end time of the controllers 40B and 40C from the communication units 41 from the controllers 40B and 40C, which are slave units, via the router 50A and the like.

  Further, the control unit 44A downloads the firmware from the server 10 via the network 100, the router 50A, and the communication unit 41A in a predetermined order when the download start time of the own device is reached. The predetermined order will be described later.

  In addition, the control unit 44A determines the firmware that has not been downloaded based on the firmware that has been downloaded by the device itself and the firmware that has been downloaded by the child device notified by the child device that has completed the download execution process. To detect. Further, the control unit 44A detects the child device that executes the next download based on the download start time of the controllers 40B and 40C acquired from the controllers 40B and 40C in advance. The control unit 44 instructs, via the router 50 or the like, to the child device which executes the next download, to download the detected firmware for which the download is not completed. Details of this processing will be described in <Processing when downloading firmware> below.

  When all of the control unit 44A and the controllers 40A to 40C finish the download execution process, the slave unit that holds the firmware that is not held by the own device is detected. The control unit 44 detects a child device that holds the firmware that the parent device does not have, based on the firmware that has been downloaded by the device itself and the firmware that has been downloaded by the child device that is notified from the child device. To do. The control unit 44 requests the detected slave unit to transmit the firmware that the master unit does not hold, via the router 50A or the like. Further, the control unit 44A detects the firmware that is not held by the controller that is the child device, based on the firmware that has been downloaded by the child device that is notified from the controllers 40B and 40C that are the child devices. Further, the control unit 44 transmits the detected firmware to the controller, which is a child device that does not hold the detected firmware, via the router 50A or the like. Details of this processing will be described in <Processing when complementing firmware> below.

  The controller 40B, which is a child device, controls the operation of the fuel cell device 30B corresponding to its own device, under the control of the controller 40A, which is a parent device. The controller 40B includes a communication unit 41B, a storage unit 42B, a display unit 43B, and a control unit 44B. The communication unit 41B, the storage unit 42B, the display unit 43B, and the control unit 44B can realize the same functions as the communication unit 41, the storage unit 42, the display unit 43, and the control unit 44 illustrated in FIG. 1, respectively. The differences will be mainly described below.

  The communication unit 41B communicates with the server 10 via the router 50B and the network 100. Further, the communication unit 41B communicates with the controller 40A via the routers 50B and 50A and communicates with the controller 50C via the routers 50B and 50C.

  When the control unit 44B acquires the schedule information from the server 10, the control unit 44B analyzes the acquired schedule information and detects the start time and the end time of the download of the own device. Further, the control unit 44B notifies the start time and the end time of the download of the controller 40B from the communication unit 41B via the routers 50B and 50A to the controller 40A which is the parent device.

  Further, the control unit 44B receives an instruction from the controller 40A, which is the parent device, via the routers 50A and 50B to download the firmware, which has been detected by the parent device and has not been downloaded. In this case, when the download start time of the self device is reached, the control unit 44B downloads the uncompleted firmware from the server 10 via the communication unit 41B in a predetermined order. Further, when the download execution process of the own device is completed, the control unit 44B notifies the controller 40A, which is the parent device, of the firmware that has been downloaded by the own device, via the routers 50B and 50A. Details of this processing will be described in <Processing When Downloading Firmware>.

  Further, when the control unit 44B receives a request from the controller 40A, which is the master device, to transmit the firmware that is not held by the master device, the control unit 44B sends the firmware from the communication unit 41B to the controller 40A via the routers 50B and 50A. Send. Further, when the control unit 44B acquires the firmware from the master controller 40A, the control unit 44B causes the storage unit 42B to hold the firmware. Details of this processing will be described in <Processing when complementing firmware> below.

  The controller 40C, which is a child device, controls the operation of the fuel cell device 30C corresponding to its own device, under the control of the controller 40A, which is a parent device. The controller 40C includes a communication unit 41C, a storage unit 42C, a display unit 43C, and a control unit 44C. The communication unit 41C, the storage unit 42C, the display unit 43C, and the control unit 44C can realize the same functions as the communication unit 41, the storage unit 42, the display unit 43, and the control unit 44 illustrated in FIG. 1, respectively. The differences will be mainly described below.

  The communication unit 41C communicates with the server 10 via the router 50C and the network 100. Further, the communication unit 41C communicates with the controller 40A via the routers 50C and 50A, and communicates with the controller 50B via the routers 50C and 50B.

  The processing of the control unit 44C is the same as the processing of the control unit 44B, so description thereof will be omitted.

<Process when setting start time and set time>
Hereinafter, an example of the process of the server 10 when setting the download start time and the download end time of the controllers 40A to 40C will be described with reference to FIG.

  First, the server 10 determines whether or not a plurality of fuel cell devices installed in the same customer facility are operating in a linked manner (step S401). The server 10 determines that the fuel cell devices 30A to 30C are performing the linked operation when, for example, the state information acquired from the controller 40A includes that the linked operation is being performed.

  When the server 10 determines that the plurality of fuel cell devices installed in the same customer facility are performing the linked operation (step S401: Yes), the process proceeds to step S402. On the other hand, when the server 10 determines that the plurality of fuel cell devices installed in the same customer facility are not performing the linked operation (step S401: No), the process ends.

  In the process of step S402, the server 10 calculates the time when each of the controllers 40A to 40C downloads (hereinafter, referred to as "download time"). The server 10 calculates the download time based on the total capacity of the firmware, the communication speed between the controller and the server 10, and the number of controllers. For example, the server 10 determines the time (hereinafter referred to as “first time”) required when all the firmware is downloaded by only one controller based on the total capacity of the firmware and the communication speed between the controller and the server 10. calculate. Further, the server 10 calculates the download time by dividing the first time by the number of controllers. For example, when the first time is 30 minutes and the number of controllers is 3, the download time is calculated as 10 minutes.

  In the process of step S403, the server 10 determines whether or not all the generated power of the plurality of fuel cell devices that are performing the linked operation change with time. For example, the server 10 refers to the state information of the fuel cell devices 30A to 30C acquired from the controllers 40A to 40C, and determines whether or not all the generated power of the fuel cell devices 30A to 30C fluctuates with respect to time. To do. Here, when all of the fuel cell devices 30A to 30C are performing the load following operation, all of the generated power of the fuel cell devices 30A to 30C fluctuates with respect to time. On the other hand, when any one of the fuel cell devices 30A to 30C is operating as the base power source, the generated power of the fuel cell device operating as the base power source is constant with respect to time, so that the fuel cell devices 30A to 30C are operated. Any one of the generated power of 30C does not change with time. Therefore, when all of the fuel cell devices 30A to 30C are performing the load following operation, the server 10 determines that all of the generated power of the fuel cell devices 30A to 30C are changing with time. On the other hand, when any one of the fuel cell devices 30A to 30C is operating as the base power source, the server 10 does not determine that all of the generated power of the fuel cell devices 30A to 30C has changed with time.

  When the server 10 determines that all the generated power of the plurality of fuel cell devices that are performing the linked operation change with time (step S403: Yes), the process proceeds to step S404. On the other hand, when the server 10 does not determine that all the generated power of the plurality of fuel cell devices that are performing the linked operation change with time (step S403: No), the process proceeds to step S406. Therefore, when all the fuel cell devices are performing the load following operation, the server 10 proceeds to the processing of steps S404 and S405. On the other hand, when the plurality of fuel cell devices that are performing the linked operation include the fuel cell device that is operating as the base power source, the server 10 proceeds to steps S406, S407, and S408.

  In the process of step S404, the server 10 sets the time period during which the generated power becomes smaller than the first predetermined value in each of the fuel cell devices in which the generated power fluctuates with time, that is, in the fuel cell device performing the load following operation. To extract. For example, in a consumer facility where the power consumption at night is smaller than the power consumption at daytime, when the fuel cell device is performing load following operation, the generated power at night of the fuel cell device is the fuel cell device. It is smaller than the power generated during the day. Therefore, in this case, the night time period is extracted by the process of step S404.

  In the process of step S405, the server 10 sets the download start time and end time of the controllers 40A to 40C, respectively, based on the download time calculated in the process of step S402 and the time period extracted in the process of step S404. .. Hereinafter, as an example of this processing, an example of setting the download start time and end time of the controller 40A will be described.

  For example, the server 10 calculates the download time as 10 minutes in the process of step S402, and extracts the night time period as the time period in which the generated power of the fuel cell device 30A becomes smaller than the first predetermined value in the process of step S404. It is assumed that In this case, the server 10 sets the download start time and end time of the controller 40A so that the time between the start time and the end time is 10 minutes in the nighttime time zone extracted in the process of step S404. To do.

  By the processes of steps S404 and S405, when all the fuel cell devices are performing the load following operation, the download start time and the end time of all the controllers are set in the time zone in which the generated power of the fuel cell devices becomes small. Is set. Generally, when the generated power of the fuel cell device increases, the processing amount of the controller that controls the fuel cell device increases, and when the generated power of the fuel cell device decreases, the processing amount of the controller that controls the fuel cell device decreases. To do. Therefore, in the present embodiment, the firmware download can be efficiently performed by setting the download start time and the download end time in the time zone in which the processing amount of the controller is relatively reduced.

  In the process of step S406, similarly to the process of step S404, the server 10 determines that the generated power is the first predetermined power in the fuel cell device in which the generated power varies with time, that is, the fuel cell device performing the load following operation. The time zone that is smaller than the value is extracted.

  In the process of step S407, a time period in which the generated power is larger than the second predetermined value is extracted in all the fuel cell devices in which the generated power fluctuates with time, that is, the fuel cell devices performing the load following operation. For example, in a customer facility where the power consumption during the daytime is higher than the power consumption during the nighttime, when the fuel cell device is performing load following operation, the power generated during the daytime by the fuel cell device is the fuel cell device. It will be larger than the power generated at night. Therefore, in this case, the daytime period is extracted by the process of step S407.

  In the process of step S408, the server 10 sets the download start time and end time of the controllers 40A to 40C, respectively, based on the download time calculated in the process of step S402 and the time zone calculated in the processes of steps S406 and S407. Set. Hereinafter, an example of this processing will be described. In the following, it is assumed that the fuel cell device 30A operates as a base power source and the fuel cell devices 30B and 30C perform load following operation.

  First, an example of setting the download start time and end time of the controllers 40B and 40C will be described. For example, the server 10 calculates the download time as 10 minutes in the process of step S402, and the night time period as the time period in which the generated power of the fuel cell devices 30B and 30C becomes smaller than the first predetermined value in the process of step S406. Are extracted respectively. In this case, the server 10 sets the download start time of the controller 40B and the download start time of the controller 40B so that the time between the start time and the end time is 10 minutes in the nighttime time zone extracted for the fuel cell device 30B in the process of step S406. Set the end time. Similarly, the server 10 sets the download start time of the controller 40C and the download start time of the controller 40C so that the time between the start time and the end time is 10 minutes in the nighttime time zone extracted for the fuel cell device 30C in the process of step 406. Set the end time.

  Next, an example of setting the download start time and end time of the controller 40A will be described. For example, the server 10 calculates the download time as 10 minutes in the process of step S402, and in the process of step S407, the generated power of the fuel cell devices 30B and 30C is larger than the second predetermined value and the daytime time period is set as the time period. It is assumed that each is extracted. In this case, the server 10 starts the download of the controller 40A so that the time between the start time and the end time is 10 minutes in the daytime time zone extracted for the fuel cell devices 30B and 30C in the process of step S407. Set the time and end time.

  FIG. 7 shows an example of download start times and end times of the controllers 40A to 40C set by the server 10. Note that the “date” shown in FIG. 7 is the date included in the first date and time when the download is executed, and as described in the first embodiment, for example, is distributed and assigned to each of the controllers 40A to 40C. ing.

  By the processes of steps S406 and S408, the download start time of the controller that controls the fuel cell device performing the load following operation in the time zone in which the generated power of the fuel cell device performing the load following operation becomes small. And the end time are set. As described above, in general, as the generated power of the fuel cell device decreases, the processing amount of the controller that controls the fuel cell device decreases. Therefore, in the controller that controls the fuel cell device that is performing the load following operation, the download start time and end time are set in a time zone in which the processing amount of the controller is relatively reduced. As a result, in this embodiment, the firmware can be downloaded efficiently.

  Further, by the processing of steps S407 and S408, the download start time and the download start time of the controller that controls the fuel cell device operating as the base power supply during the time period when the generated power of the fuel cell device performing the load following operation becomes high. The end time is set. As a result, even if the operation of the fuel cell device of the base power supply is stopped due to some communication accident during downloading of the controller that controls the fuel cell device of the base power supply, the operation of the fuel cell device performing the load following operation is performed. Is continued with a large amount of generated power. Therefore, even if such a situation occurs, in the present embodiment, it is possible to stably supply power to the customer facility.

  When setting the download start time and end time for the controllers 40A to 40C, the server 10 sets the download start time and end time of the parent device to be lower than the download start time and end time of the slave device. You may set so that it may become early time. This is to execute <Processing when downloading firmware> described later. In this case, in the “date” shown in FIG. 7, the server 10 sets the date of the controller 40A to an earlier date than the dates of the controllers 40B to 40C. At this time, in the process according to the first embodiment, for example, when the date of the controller 40B is set to an earlier date than the date of the controller 40A, the server 10 determines the date of the controller 40A and the date of the controller 40B. You may change the dates.

  Further, when the process shown in FIGS. 8 and 10 described later is not executed, the server 10 may set the download time to the first time in the process of step S402.

  Here, the start time and the end time of the download are included in the schedule information transmitted from the server 10 to the controllers 40A to 40C, respectively. Therefore, for example, the control unit 44A of the controller 40A can detect the download start time and end time of the own device by the process of step S103 shown in FIG. In the second embodiment, when the control unit 44B of the controller 40B, which is a child device, detects the download start time and end time of the self device, the control unit 44B sets the start time and end time of the self device download to the master device. The controller 40A is notified via a router 50A or the like. The same applies to the controller 40C, which is a child device.

<Process when downloading firmware>
Hereinafter, an example of the operation of the controllers 40A to 40C when downloading the latest firmware from the server 10 will be described with reference to FIG. First, the firmware of the fuel cell device and the controller will be briefly described.

  There are multiple types of firmware for the fuel cell device and the controller. In the following description, it is assumed that there are a total of 6 types, that is, 2 types of firmware for controlling the fuel cell device and 4 types of firmware for controlling the controller. The two types of firmware of the fuel cell device are, for example, firmware for controlling the fuel cell included in the fuel cell device and firmware for controlling the power conversion device included in the fuel cell device. The four types of firmware of the controller are, for example, boot loader firmware, kernel firmware, file system firmware, and application firmware. Generally, the two types of firmware for controlling the fuel cell device have a smaller data capacity than the four types of firmware for controlling the controller (note that the fuel cell device is controlled during the update time). The two types of firmware for doing so are longer than the four types of firmware for controlling the controller.) Therefore, when the six types of firmware of the fuel cell device and the controller are downloaded from the server 10, the two types of firmware of the fuel cell device are downloaded before the four types of firmware of the controller. In other words, when the six types of firmware of the fuel cell device and the controller are downloaded from the server 10, the firmware is downloaded in a predetermined order. Therefore, in the following, the six types of firmware downloaded from the server 10 will be referred to as firmware 1, 2, 3, 4, 5, and 6, and these six types of firmware will be the predetermined firmware 1, 2, 3, 4, 5, 6. It shall be downloaded in order. Further, the download start time and end time of the controllers 40A to 40C are assumed to be the times shown in FIG.

  The control unit 44 of the controller 40A transmits the latest firmware request from the communication unit 41A to the server 10 via the router 50A and the network 100 when a predetermined time has passed before the download start time of the controller 40A (step S501). .. When the server 10 acquires the latest firmware request from the controller 40A, it starts from the download start time (August 9, 2016 12:00) to the end time (August 9, 2016 12:10) of the download of the controller 40A. Meanwhile, the latest firmware is continuously transmitted to the controller 40A (step S502). As a result, the firmware 10 is transmitted from the server 10 to the controller 40A. The control unit 44A of the controller 40A discards the firmware 3 when the end time comes during the download of the firmware 3 and the download of the firmware 3 is not completed.

  When the control unit 44A of the controller 40A acquires the firmware 1 and 2 transmitted from the server 10 via the network 100 and the router 50A via the communication unit 41A, it stores the acquired firmware 1 and 2 in the storage unit 42A ( Step S503).

  Through the processing of steps S501 to S503, the firmware 10 is downloaded from the server 10 in the predetermined order (firmware 1 and 2) to the controller 40A which is the parent device.

  The control unit 44A of the controller 40A detects that the download of the firmware 3 to 6 is incomplete based on the firmware 1 and 2 that have been downloaded by the own device. Further, the control unit 44A specifies that the child device to be next downloaded is the controller 40B based on the download start time and the download end time of the controllers 40B and 40C acquired from the controllers 40B and 40C in advance. Therefore, the control unit 44A transmits an instruction from the communication unit 41A via the routers 50A and 50B to the controller 40B to download the firmware of firmware 3 and later (step S504). The control unit 44B of the controller 40B acquires, via the communication unit 41B, an instruction to download the firmware of firmware 3 or later transmitted from the controller 40A via the routers 50A and 50B.

  The control unit 44B of the controller 40B transmits the latest firmware request from the communication unit 41B to the server 10 via the router 50B and the network 100 when a predetermined time has passed before the download start time of the controller 40B (step S505). .. At this time, the control unit 44B requests the firmware after firmware 3 among the latest firmware 1 to 6 based on the instruction acquired in the process of step S504. When the server 10 acquires this request, the firmware 3 is downloaded between the start time (23:00, August 10, 2016) and the end time (23:10, August 10, 2016) of the download of the controller 40B. Continue to send subsequent firmware. As a result, the firmware 3 to 5 is transmitted from the server 10 to the controller 40B. The control unit 44B of the controller 40B discards the firmware 6 when the end time comes during the download of the firmware 6 and the download of the firmware 6 is not completed.

  When the control unit 44B of the controller 40B acquires the firmware 3 to 5 transmitted from the server 10 via the network 100 and the router 50B via the communication unit 41B, it stores the acquired firmware 3 to 5 in the storage unit 42B ( Step S507).

  Through the processes of steps S504 to S507, the firmware 3 to 5 not downloaded by the parent device is downloaded from the server 10 to the controller 40B, which is a child device, in a predetermined order (firmware 3, 4, 5). It

  The control unit 44B of the controller 40B transmits a notification that the download of the firmware 3 to 5 is completed to the controller 40A from the communication unit 41B via the routers 50B and 50A (step S508). The control unit 44A of the controller 40A acquires, via the communication unit 41A, the fact that the download of the firmware 3 to 5 by the controller 40B, which is transmitted from the controller 40B via the routers 50B and 50A, is completed.

  Through the process of step S508, the control unit 44 of the controller 40A, which is the parent device, can detect that the controller 40B holds the firmware 3 to 5 and the firmware 6 is not yet downloaded. ..

  The control unit 44A of the controller 40A determines that the firmware whose download has not been completed is firmware based on the fact that the download of the firmware 1 and 2 that has been completed by the device itself and the download of the firmware 3 to 5 obtained from the controller 40B have been completed. 6 is detected. Further, the control unit 44A specifies that the child device to execute the next download is the controller 40C based on the download start time and the download end time of the controllers 40B and 40C acquired from the controllers 40B and 40C in advance. Therefore, the control unit 44A of the controller 40A transmits an instruction to download the firmware 6 from the communication unit 41A to the controller 40C via the routers 50A and 50C (step S509). The control unit 44C of the controller 40C acquires, via the communication unit 41C, an instruction to download the firmware 6 transmitted from the controller 40A via the routers 50A and 50C.

  The control unit 44C of the controller 40C transmits the request for the latest firmware 6 from the communication unit 41C to the server 10 via the router 50C and the network 100 when the predetermined time comes before the download start time of the controller 40C (step S510). .. When the server 10 acquires this request, the firmware 6 is downloaded between the start time (23:40 on August 11, 2016) and the end time (23:50 on August 12, 2016) of the controller 40C. Keep sending. As a result, the firmware 6 is transmitted from the server 10 to the controller 40B.

  When the control unit 44C of the controller 40C acquires the firmware 6 transmitted from the server 10 via the network 100 and the router 50C via the communication unit 41C, it stores the acquired firmware 6 in the storage unit 42C (step S512).

  Through the processes of steps S509 to S512, the firmware 6 which is not downloaded by the controllers 40A and 40B is downloaded from the server 10 to the controller 40C which is a child device.

  The control unit 44C of the controller 40C transmits the fact that the download of the firmware 6 is completed to the controller 40A from the communication unit 41C via the routers 50C and 50A (step S513). The control unit 44A of the controller 40A acquires, via the communication unit 41A, the fact that the download of the firmware 6 by the controller 40C, which is transmitted from the controller 40C via the routers 50C and 50A, is completed.

  Through the process of step S513 as described above, the control unit 44 of the controller 40A, which is the master device, can detect that the controller 40C holds the firmware 6 and that the download of the firmware 1 to 6 is all completed. ..

  FIG. 9 shows the firmware 1 to 6 held by the controllers 40A to 40C by the processing of steps S501 to S513, respectively. In this way, by combining the firmware held in each of the controllers 40A to 40C, all the firmware 1 to 6 can be prepared. Furthermore, in the present embodiment, the controllers 40A to 40C complement each other with the missing firmware, so that the controllers 40A to 40C can hold all the firmware 1 to 6. This process will be described below.

<Process when complementing firmware>
Hereinafter, an example of the operation of complementing each other with missing firmware among the controllers 40A to 40C will be described with reference to FIG. Note that the controller 40A, which is the parent device, detects that the controller 40B holds the firmware 3 to 5 but the controller 40B does not hold the firmware 1, 2, and 6 by the processing of step S508. .. By the process of step S513, the controller 40A, which is the parent device, detects that the controller 40C holds the firmware 6, but the controller 40C does not hold the firmware 1 to 5.

  The control unit 44A of the controller 40A transmits a request for firmware 3 to 5 to the controller 40B from the communication unit 41A via the routers 50A and 50B (step S601). Upon acquisition of this request, the control unit 44A of the controller 40B transmits the firmware 3 to 5 held in the storage unit 42B to the controller 40A from the communication unit 41B via the routers 50B and 50A (step S602).

  When the control unit 44A of the controller 40A acquires the firmware 3 to 5 transmitted from the controller 40B via the routers 50B and 50A via the communication unit 41A, the acquired firmware 3 to 5 is retained in the storage unit 42A (step S603).

  The control unit 44A of the controller 40A transmits the request for the firmware 6 to the controller 40C from the communication unit 41A via the routers 50A and 50B (step S604). Upon acquisition of this request, the control unit 44C of the controller 40C sends the firmware 6 held in the storage unit 42C from the communication unit 41C to the controller 40A via the routers 50C and 50A (step S605).

  When the control unit 44A of the controller 40A acquires the firmware 6 transmitted from the controller 40C via the routers 50C and 50A via the communication unit 41A, it stores the acquired firmware 6 in the storage unit 42A (step S606).

  By such processing of steps S601 to S606, the controller 40A can acquire all of the firmware 1 to 6 even when the firmware download is interrupted and ended incompletely.

  The control unit 44A of the controller 40A sends the firmware 1, 2, and 6 stored in the storage unit 42A to the controller 40B from the communication unit 41A via the routers 50A and 50B (step S607).

  When the control unit 44B of the controller 40B acquires the firmware 1, 2, 6 transmitted from the controller 40A via the routers 50A, 50B via the communication unit 41B, the acquired firmware 1, 2, 6 is stored in the storage unit 42B. It is held (step S608).

  By such processing of steps S607 and S608, the controller 40B can acquire all of the firmware 1 to 6 even when the firmware download is interrupted and completed incompletely.

  The control unit 44A of the controller 40A transmits the firmware 1 to 5 stored in the storage unit 42A to the controller 40C from the communication unit 41A via the routers 50A and 50C (step S609).

  When the control unit 44C of the controller 40C acquires the firmware 1 to 5 transmitted from the controller 40A via the routers 50A and 50C via the communication unit 41C, it stores the acquired firmware 1 to 5 in the storage unit 42C (step S610).

  By such processing of steps S609 and S610, the controller 40C can acquire all of the firmware 1 to 6 even when the firmware download is interrupted and ended incompletely.

  Other configurations and effects of the firmware providing system 2 according to the second embodiment are similar to those of the firmware providing system 1 according to the first embodiment.

  Although one embodiment of the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various variations and modifications based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention. For example, the functions and the like included in each constituent unit and each step can be rearranged so as not to logically contradict, and a plurality of constituent units and steps can be combined or divided into one. Is. Further, although one embodiment of the present invention has been described focusing on the apparatus, the present invention can be implemented as a method executed by a processor included in the apparatus, a program, or a storage medium recording the program. It should be understood that these are also included in the scope of the invention.

1, 2 Firmware providing system 10 Server 20 Terminal device 30-1 to 30-n, 30A, 30B, 30C Fuel cell device (power supply device)
31, 31A, 31B, 31C Power generation section 32, 32A, 32B, 32C Power conversion section 33, 33A, 33B, 33C Communication section 34, 34A, 34B, 34C Storage section 35, 35A, 35B, 35C Control section 40-1 to 40-1 40-n, 40A, 40B, 40C controller (control device)
41, 41A, 41B, 41C communication unit 42, 42A, 42B, 42C storage unit 43, 43A, 43B, 43C display unit 44, 44A, 44B, 44C control unit 50-1 to 50-n, 50A, 50B, 50C router 100 networks

Claims (14)

A firmware providing system comprising: a server that provides firmware to a plurality of power supply devices and control devices respectively corresponding to the plurality of power supply devices via a network,
The server allocates the first date and time at which each of the control devices downloads the firmware from the server to the control device so as not to exceed the data capacity that can be transmitted by the server. Sending schedule information including one date and time to each of the control devices,
Each of the control devices is
A communication unit that communicates with the server via the network;
A firmware providing system, comprising: a control unit that acquires the schedule information from the server via the communication unit, and further downloads the firmware from the server at the first date and time. In the firmware providing system according to claim 1,
The server sets a second date and time to update the firmware of the power supply device and the control device based on the date and time specified for each power supply device,
The schedule information further includes the second date and time,
The communication unit communicates with the power supply device,
The control unit updates the firmware of the control device to the latest firmware at the second date and time, and further transfers the firmware of the power supply device to the power supply device at the second date and time via the communication unit. A firmware providing system that causes the power supply device to update firmware. In the firmware providing system according to claim 1 or 2,
Each of the control devices further includes a display unit,
The firmware providing system, wherein the control unit causes the display unit to display the schedule information. The firmware providing system according to any one of claims 1 to 3,
The firmware providing system, wherein the control unit periodically acquires the schedule information from the server. The firmware providing system according to any one of claims 1 to 4,
The firmware providing system, wherein the power supply device is a fuel cell device. The firmware providing system according to any one of claims 1 to 5,
A firmware providing system, wherein the server distributes the date of executing the download included in the first date and time to each of the control devices. The firmware providing system according to any one of claims 1 to 6,
The server requests each of the control devices to transmit status information of the power supply device corresponding to the control device,
When the control device acquires a request for the status information of the power supply device from the server, the status information of the power supply device corresponding to the control device is transmitted to the server,
The server acquires status information of each of the power supply devices corresponding to the plurality of control devices from the plurality of control devices,
The server is installed in the same customer facility, and in the plurality of power supply devices that are performing a linked operation, all generated power of the plurality of power supply devices that are performing the linked operation is based on the state information. Judge whether it fluctuates with time,
When the server determines that all the generated power of the plurality of power supply devices performing the linked operation is fluctuating with respect to time, it corresponds to the total capacity of the firmware and the plurality of power supply devices, respectively. The download time is calculated based on the communication speed between each of the control devices and the server and the number of the control devices, and the download time and the power generated by the plurality of power supply devices are equal to a first predetermined value. Based on the time period smaller than, set the download start time and end time of each of the control device,
The firmware providing system, wherein the start time and end time of the download are included in the first date and time. In the firmware providing system according to claim 7,
When the server does not determine, based on the state information, that all the generated power of the plurality of power supply devices performing the linked operation is fluctuating with respect to time, the power generation of the plurality of power supply devices is performed. In a part of the power supply device whose electric power fluctuates with respect to time, based on the download time and a time zone in which the generated power of the part of the power supply device becomes smaller than a first predetermined value, A download start time and an end time of each control device corresponding to the power supply device are set, and further, the download time and a time period during which the power generated by the one power supply device is larger than a second predetermined value are set. A firmware providing system for setting download start time and end time of each control device corresponding to a power supply device other than the one unit based on the above. In the firmware providing system according to claim 7 or 8,
The server is installed in the same consumer facility, and when the download start time and end time are set for a plurality of the control devices set as a master unit or a slave unit, the control device of the master unit is A firmware providing system, wherein the start time and the end time of the download are set to be earlier than the start time and the end time of the download of the control device which is a slave unit. In the firmware providing system according to claim 9,
The communication unit of the control device, which is a parent device, and the communication unit of the control device, which is a child device, communicate with each other via a router,
When the control unit of the control device which is the slave device acquires the schedule information from the server, the start time and the end time of the download of the self device included in the schedule information are set to the control device which is the master device and the router. Notify via
The control unit of the control device, which is the parent device, downloads the firmware from the server via the communication unit in a predetermined order at the start time of the download of the own device,
The control unit of the control device, which is the master device, has not completed the download based on the firmware that has been downloaded by the self device and the firmware that has been downloaded by the slave device that is notified from the control device that is the slave device. The firmware that detects the firmware is detected, and based on the download start time and end time of the slave device acquired in advance from the slave device, the slave device that executes the next download is detected, and the slave device that executes the download next detects the firmware. Instructing the control device via the router to download the firmware for which the detected download is incomplete,
When the control unit of the control device, which is the slave device, receives an instruction from the control device, which is the master device, to download the firmware for which the download detected by the master device is not completed, A firmware providing system, which downloads, when the start time arrives, the firmware that has not been downloaded from the server via the communication unit in a predetermined order. The firmware providing system according to claim 10 ,
The control unit of the control device, which is the master device, determines that the master device is based on the firmware that has been downloaded by the self device and the firmware that has been downloaded by the slave device that is notified from the control device that is the slave device. Detects a child device that holds the firmware that it does not hold, and further requests the detected child device to transmit the firmware that the parent device does not hold via the router,
When the control unit of the control device, which is a slave device, receives a request from the control device, which is the master device, to transmit the firmware that the master device does not have, the control unit of the master device is notified of the firmware. A firmware providing system that transmits via a router. The firmware providing system according to claim 11,
The control unit of the control device, which is the master device, uses the firmware that the control device, which is the slave device, does not hold, based on the firmware downloaded by the slave device that is notified from the control device that is the slave device. Detected, and transmits the detected firmware to the control device, which is the slave, via the router,
The firmware providing system, wherein the control unit of the control device, which is a child device, retains the firmware in a storage unit of its own device when the firmware is acquired from the control device that is a parent device. A control method for a firmware providing system, comprising: a plurality of power supply devices and a server that provides firmware for a control device corresponding to each power supply device,
By the server,
The first date and time when the control device downloads the firmware from the server is assigned to each of the control devices so as not to exceed the data capacity that can be transmitted by the server.
Transmitting schedule information including the first date and time to each of the control devices,
By each said control device,
Obtaining the schedule information from the server,
A method of controlling a firmware providing system, wherein the firmware is downloaded from the server at the first date and time. A server that provides firmware to a plurality of power supply devices and control devices respectively corresponding to the plurality of power supply devices via a network;
Multiple power supplies,
A control device corresponding to each of the plurality of power supply devices,
The server allocates the first date and time at which each of the control devices downloads the firmware from the server to the control device so as not to exceed the data capacity that can be transmitted by the server. Sending schedule information including one date and time to each of the control devices,
Each of the control devices is
A communication unit that communicates with the server via the network;
A power supply system comprising: a control unit that acquires the schedule information from the server via the communication unit, and further downloads the firmware from the server at the first date and time.

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