JP7005700B2 - Firmware provision system, firmware provision system control method and server - Google Patents

Description

The present disclosure relates to a firmware providing system, a control method of the firmware providing system, and a server.

In a power supply system such as a fuel cell system, the constituent devices constituting the power supply system are controlled by control software such as firmware.

Conventionally, the work of updating the control software of the fuel cell system is often carried out by a worker who goes to the installation site and performs it on site. However, if it is necessary for the worker to go to the installation site, even if the control software is improved by the manufacturer, the control software will not be updated to the latest one until the worker goes to the site.

For example, Patent Document 1 discloses an invention for updating control software of a fuel cell system via a network. Further, Patent Document 1 discloses that the control software is updated efficiently and safely by restricting the operation mode of each constituent device during the update of the control software.

Japanese Unexamined Patent Publication No. 2015-185352

Fuel cell systems are required to generate electricity efficiently. Further, the fuel cell system is required to be able to prevent freezing of water such as reformed water and circulating water used internally when installed in a cold region.

The surrounding environment of the fuel cell system, such as air temperature (atmospheric temperature) and atmospheric pressure (atmospheric pressure), varies depending on the location where the fuel cell system is installed. Further, the power generation efficiency of the fuel cell system depends on the temperature, atmospheric pressure, and the like. Therefore, in order to efficiently generate power in the fuel cell system, it is better to control the fuel cell system with firmware and control parameters suitable for the temperature and atmospheric pressure of the installation location.

However, since it is often not known at the time of shipment where the fuel cell system will be installed, the fuel cell device has conventionally been shipped with firmware and control parameters set suitable for the national average temperature and the like. rice field.

An object of the present disclosure made in view of such a point is to provide a firmware providing system capable of efficiently generating power of a power supply system regardless of the installation location, a control method of the firmware providing system, a server and a power supply system. ..

A firmware providing system according to an embodiment of the present disclosure includes a plurality of power supply systems in which each power supply system includes a power supply device and a controller for controlling the power supply device, and the power supply device and the power supply device to the controller via a network. It includes a server that transmits control information of the controller. The server sets priorities according to the temperature of the installation location of the power supply device, and transmits the control information according to the installation location of the power supply device to the controller in the order of the priority order.

A method of controlling a firmware providing system according to an embodiment of the present disclosure is a firmware in a firmware providing system including a plurality of power supply systems and a server in which each power supply system includes a power supply device and a controller for controlling the power supply device. It is a control method of the provided system. In the control method, the server selects control information of the power supply device and the controller according to the installation location of the power supply device, and sets a priority according to the temperature of the installation location of the power supply device. And the step of transmitting the control information to the controller in the order of the set priority.

A server according to an embodiment of the present disclosure includes a communication unit in which each power supply system includes a power supply device and a controller for controlling the power supply device, and a communication unit that communicates with a plurality of power supply systems, and control information of the power supply device and the controller. To the controller via the communication unit. The control unit sets priorities according to the temperature of the installation location of the power supply device, and transmits the control information according to the installation location of the power supply device to the controller in the order of the priority order.

According to the firmware providing system, the control method of the firmware providing system, the server and the power supply system according to the embodiment of the present disclosure, the power generation system can efficiently generate power regardless of the installation location.

It is a figure which shows the schematic structure of the firmware providing system which concerns on one Embodiment of this disclosure. It is a figure explaining the difference of temperature and atmospheric pressure by region. It is a figure which shows an example of the data which the server of FIG. 1 stores. It is a sequence diagram which shows an example of the operation of the firmware providing system which concerns on one Embodiment of this disclosure.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.

FIG. 1 shows a schematic configuration of a firmware providing system 1 according to an embodiment of the present disclosure. The firmware providing system 1 includes a fuel cell system (power supply system) 10, a server 40, a first external server (climate information server) 50, and a second external server (map information server) 60. The fuel cell system 10, the server 40, the first external server 50, and the second external server 60 can transmit and receive information via the network 70.

In FIG. 1, one fuel cell system 10 is connected to the network 70, but this is an example, and a plurality of fuel cell systems 10 may be connected to the network 70.

The fuel cell system 10 receives firmware and control parameters from the server 40 via the network 70.

The firmware is software for controlling the operation of the controller 30 or the fuel cell device 20. There are two types of firmware, one for the controller 30 and one for the fuel cell device 20. The controller 30 determines each component, a sequence of each process when controlling the entire controller 30, and the like based on the firmware for the controller 30. The fuel cell device 20 determines each component, a sequence of each process when controlling the entire fuel cell device 20, and the like, based on the firmware for the fuel cell device 20. The firmware for the controller 30 and the firmware for the fuel cell device 20 are not limited to one, and may be plural.

The control parameters are various parameters for controlling the operation of the controller 30 or the fuel cell device 20. The control parameters include those for the controller 30 and those for the fuel cell device 20. For example, the fuel cell device 20 controls devices such as an air blower in the auxiliary device 22 based on control parameters.

In the following description, information including either one of the firmware and the control parameter or both the firmware and the control parameter is also referred to as "control information".

The fuel cell system 10 includes a fuel cell device (power supply device) 20 and a controller 30 that controls the operation of the fuel cell device 20.

The fuel cell device 20 is, for example, a solid oxide fuel cell device (SOFC: Solid Oxide Fuel Cell) or a solid polymer electrolyte fuel cell device (PEFC: Polymer Electrolyte Fuel Cell). The fuel cell device 20 is installed in a consumer facility such as a store or a residence.

The fuel cell device 20 has different environmental conditions such as air temperature and atmospheric pressure depending on the installation location. For example, in the Japanese map shown in FIG. 2 (a), the temperature tends to be lower in the north and higher in the south. Further, in the map shown in FIG. 2 (b), the place 101 tends to have a low air pressure because the altitude (elevation) is high, and the place 102 tends to have a high air pressure because the altitude is low.

In order to operate the fuel cell device 20 in a state of high power generation efficiency or to extend the life of the components, it is based on the firmware and control parameters according to the environment (temperature, pressure, etc.) of the installation site. The fuel cell device 20 may be operated. For example, since the ratio of the composition of air changes depending on the atmospheric pressure, the flow rate of the air blower in the auxiliary machine 22 may be increased when the altitude of the installation location is high and the atmospheric pressure is low. In order to operate the fuel cell device 20 in a state suitable for the environment of the installation location, when the fuel cell device 20 receives the control information according to the installation location from the controller 30, the fuel cell device 20 updates the control information according to the installation location.

The firmware and control parameters of the fuel cell device 20 can be updated after installation. Therefore, at the time of shipment from the factory, the firmware and control parameters of the fuel cell device 20 may be the initial settings.

The fuel cell device 20 includes a power generation unit 21, an auxiliary device 22, an exhaust heat recovery unit 23, a power conversion unit 24, a communication unit 25, a storage unit 26, and a control unit 27.

The power generation unit 21 includes a cell stack that generates electricity by electrochemically reacting gas and air. The power generation unit 21 uses gas, air, and reformed water mixed in a predetermined ratio according to the control parameters as fuel to generate power. The power generation unit 21 supplies the generated DC power to the power conversion unit 24.

The auxiliary machine 22 is a peripheral device necessary for operating the power generation unit 21. The auxiliary machine 22 includes an air blower, a gas pump, a reformed water pump, a heater and the like. The air blower supplies air to the power generation unit 21 at the flow rate set by the control parameter. The gas pump supplies gas to the power generation unit 21 at the flow rate set by the control parameter. The reformed water pump supplies the reformed water to the power generation unit 21 at the flow rate set by the control parameter. The heater heats the circulating water with an intensity according to the setting of the control parameter. In cold regions, increasing the strength of the heater can prevent the circulating water from freezing.

The waste heat recovery unit 23 recovers the waste heat generated by the power generation in the power generation unit 21. The waste heat recovery unit 23 exchanges the recovered waste heat with the circulating water drawn from the outside to generate hot water.

The power conversion unit 24 converts the DC power supplied from the power generation unit 21 into AC power. The power conversion unit 24 supplies the converted AC power to the load equipment of the consumer facility where the fuel cell device 20 is installed.

The communication unit 25 is connected to the controller 30 by wire or wirelessly. The communication unit 25 transmits / receives data to / from the controller 30. The communication unit 25 receives control information from the controller 30.

The storage unit 26 holds (stores) firmware and control parameters for controlling the operation of the fuel cell device 20.

The control unit 27 includes a processor that controls and manages the entire fuel cell device 20, including each functional block included in the fuel cell device 20. The program executed by the processor may be stored in, for example, a memory included in the control unit 27 or may be stored in the storage unit 26.

When the control unit 27 receives the control information according to the installation location from the controller 30, the control unit 27 updates the control information. When the control unit 27 receives the control information, the control unit 27 may automatically start the update work, or may start the update work after receiving an instruction of the update work from the user.

The controller 30 controls the fuel cell device 20. The controller 30 connects to the server 40 via the network 70. The controller 30 receives (downloads) control information according to the installation location from the server 40. The controller 30 is connected to the fuel cell device 20 by wire or wirelessly. The controller 30 transmits the received control information for the fuel cell device 20 to the fuel cell device 20.

The controller 30 includes a communication unit 31, a storage unit 32, a display unit 33, and a control unit 34.

The communication unit 31 transmits / receives data to / from the server 40 via the network 70. The communication unit 31 receives control information according to the installation location from the server 40. The communication unit 31 is connected to the fuel cell device 20 by wire or wirelessly. The communication unit 31 transmits the control information for the fuel cell device 20 among the control information received from the server 40 to the fuel cell device 20.

The storage unit 32 holds (stores) firmware and control parameters for controlling the operation of the controller 30.

The display unit 33 includes a display device such as a liquid crystal display or an organic EL (Electroluminescence) display. The display unit 33 displays information such as the operating status of the fuel cell device 20. The display unit 33 may include an input device such as a touch sensor and may accept input from the user.

The control unit 34 includes a processor that controls and manages the entire controller 30, including each functional block included in the controller 30. The program executed by the processor may be stored in, for example, a memory included in the control unit 34 or may be stored in the storage unit 32.

When the control unit 34 receives the control information according to the installation location from the server 40, the control information for the controller 30 is stored in the storage unit 32, and the control information for the fuel cell device 20 is transmitted to the fuel cell device 20. When the control unit 34 receives the control information for the controller 30, the control unit 34 updates the control information. When the control unit 34 receives the control information for the controller 30, the control unit 34 may automatically start the update work, or may start the update work after receiving an instruction of the update work from the user. The control unit 34 displays a message such as "Firmware download is complete. Do you want to update?" On the display unit 33, and starts the update work when the user selects to update. You may.

When updating the firmware of the controller 30 or the fuel cell device 20, the control unit 34 stops the operation of the fuel cell device 20 before the updating work, if necessary.

The server 40 transmits firmware and control parameters for controlling the fuel cell device 20 to the controller 30. Further, the server 40 transmits firmware and control parameters for controlling the controller 30 to the controller 30. The server 40 includes a communication unit 41, a storage unit 42, and a control unit 43.

The communication unit 41 transmits / receives data to / from the controller 30, the first external server 50, and the second external server 60 via the network 70. The communication unit 41 transmits control information to the controller 30. The communication unit 41 receives the climate information of the installation location of the fuel cell device 20 from the first external server 50 which is a climate information server. The communication unit 41 receives information such as the altitude of the installation location of the fuel cell device 20 from the second external server 60 which is a map information server.

The storage unit 42 holds (stores) the control information for the fuel cell device 20 and the control information for the controller 30. The storage unit 42 holds various versions of control information according to the installation location of the fuel cell device 20.

The storage unit 42 holds information in which the serial number of the fuel cell device 20 is associated with the installation location of the fuel cell device 20. The installation location information is, for example, an address. For example, when the worker who installed the fuel cell device 20 performs the registration work on the server 40, the storage unit 42 holds information relating the installation location of the fuel cell device 20 to the serial number of the fuel cell device 20. can do.

Further, the storage unit 42 stores a table in which the serial number of the fuel cell device 20 is associated with the installation location of the fuel cell device 20, the firmware and control parameters suitable for the installation location, and the priority for transmitting the firmware. ing. FIG. 3 shows an example of a table stored by the storage unit 42.

In the example shown in FIG. 3, the firmware version for the fuel cell device 20 of the serial number "BBBBBB" installed in Hokkaido is 1.02, and it is installed in "AAAAAA" installed in Tokyo and Kyushu. It is a newer version than the firmware version 1.00 of "CCCCC".

Further, in the example shown in FIG. 3, the control parameters of the fuel cell device 20 installed in Hokkaido are the control parameters of the fuel cell device 20 installed in Tokyo and Kyushu, and the control parameters are "heater control" and "circulating water". It has a different value in "control". In the example shown in FIG. 3, air flow rate, gas flow rate, water flow rate, heater control, and circulating water control are stored as control parameters. The air flow rate is a parameter for setting the flow rate of the air blower of the auxiliary machine 22. The gas flow rate is a parameter for setting the flow rate of the gas pump of the auxiliary machine 22. The water flow rate is a parameter for setting the flow rate of the reformed water pump of the auxiliary machine 22. The heater control is a parameter for setting the strength of the heater of the auxiliary machine 22. The circulating water control is a parameter for controlling the flow rate of the circulating water flowing through the waste heat recovery unit 23.

Further, the priorities shown in FIG. 3 are higher in the order of, for example, S, A, B, and C. The reason for prioritizing is that the firmware has a large amount of data and it is difficult to simultaneously transmit the firmware to all the fuel cell systems 10 managed by the server 40. It takes time to complete the transmission of the firmware from the server 40 to the fuel electrical system 10. Therefore, the firmware is prioritized so that the firmware can be updated in order from the fuel cell system 10 having a high need for updating the firmware. In the example shown in FIG. 3, "S" is a high priority for an installation location where it is better to update the firmware as soon as possible because there is a risk of freezing of circulating water, such as Hokkaido, which is a cold region. Is set.

The control unit 43 includes a processor that controls and manages the entire server 40, including each functional block included in the server 40. The program executed by the processor may be stored in, for example, a memory included in the control unit 43 or may be stored in the storage unit 42.

When the fuel cell device 20 is installed and the installation location of the fuel cell device 20 is stored in the storage unit 42, the control unit 43 acquires the environmental information of the installation location of the fuel cell device 20. Environmental information includes, for example, climate and altitude. The control unit 43 acquires the climate information of the installation location of the fuel cell device 20 from the first external server 50 which is a climate information server. Further, the control unit 43 acquires the altitude information of the installation location of the fuel cell device 20 from the second external server 60 which is a map information server. The control unit 43 estimates the temperature from the climate information and estimates the atmospheric pressure from the altitude information. The control unit 43 selects firmware, control parameters, and priorities suitable for the installation location based on the estimated air temperature and atmospheric pressure, and stores them in the storage unit 42.

For example, the control unit 43 selects a value larger than the value at the time of shipment as the control parameter of the air flow rate for the installation place where the atmospheric pressure is low. As a result, the power generation efficiency of the fuel cell device 20 can be increased, and the life of the power generation unit 21 of the fuel cell device 20 can be extended. Further, the control unit 43 selects, for example, a value larger than the value at the time of shipment as a parameter for heater control for an installation place where the temperature is low. This makes it possible to prevent freezing of water such as circulating water inside the fuel cell device 20.

The control unit 43 transmits control information according to the installation location of the fuel cell device 20 to the controller 30 in the order of priority. After installing the fuel cell device 20, the control unit 43 transmits control information suitable for the installation location to the controller 30 at least once. Further, the control unit 43 may then transmit control information to the controller 30 at predetermined intervals. For example, the control unit 43 may transmit control information suitable for the season to the controller 30 for each season.

The first external server 50 is a climate information server and holds climate information of each place. The first external server 50 transmits / receives data to / from the server 40 via the network 70. When the first external server 50 receives the request for the climate information of the installation location of the fuel cell device 20 from the server 40, the first external server 50 transmits the climate information to the server 40.

The second external server 60 is a map information server and holds map information such as altitudes of various places. The second external server 60 transmits / receives data to / from the server 40 via the network 70. When the second external server 60 receives the request for the altitude information of the installation location of the fuel cell device 20 from the server 40, the second external server 60 transmits the altitude information to the server 40.

Note that FIG. 1 shows a configuration in which two external servers are connected to the network 70 as an example, but this is an example. For example, two or more external servers may disperse and hold climate information or map information. Also, for example, one external server may hold both climate information and map information. Further, for example, the server 40 may hold either one or both of the climate information and the map information.

An example of the operation of the firmware providing system 1 according to the embodiment of the present disclosure will be described with reference to the sequence diagram shown in FIG. The firmware providing system 1 performs the sequence shown in FIG. 4 at least once after the installation of the fuel cell device 20. Further, the firmware providing system 1 may further perform the sequence shown in FIG. 4 at predetermined periods, for example, seasonally.

When the fuel cell device 20 is installed and the installation location of the fuel cell device 20 is stored in the storage unit 42, the server 40 acquires the environmental information of the installation location of the fuel cell device 20. The control unit 43 selects the control information and the priority order suitable for the installation location based on the acquired environmental information (step S101).

The server 40 transmits the selected control information to the controller 30 in order of priority (step S102).

The controller 30 receives the control information (step S103), stores the control information for the controller 30 in the storage unit 32, and transmits the control information for the fuel cell device 20 to the fuel cell device 20 (step S104). The fuel cell device 20 receives the control information for the fuel cell device 20 (step S105).

The controller 30 and the fuel cell device 20 update the control information (steps S106 and S107).

As described above, according to the present embodiment, the server 40 transmits the control information according to the installation location of the fuel cell device 20 to the controller 30. When the controller 30 receives the control information according to the installation location of the fuel cell device 20 and updates the control information, the fuel cell device 20 can operate with the firmware and control parameters suitable for the installation location. .. As a result, the fuel cell device 20 can efficiently generate electricity regardless of the installation location. Further, by operating the fuel cell device 20 with the firmware and control parameters suitable for the installation location, the heater can be controlled with the strength according to the temperature, for example, even if the fuel cell device 20 is installed in a cold region, and the water inside the device can be controlled. Can be prevented from freezing. Further, by operating the fuel cell device 20 with firmware and control parameters suitable for the installation location, for example, deterioration of the life of the cell stack included in the power generation unit 21 can be suppressed. Further, even if the fuel cell device 20 is relocated, the controller 30 receives the control information according to the installation location of the relocation destination of the fuel cell device 20, so that the fuel cell device 20 is irrespective of the installation location of the relocation destination. It can generate electricity efficiently.

Although one embodiment of the present invention has been described with reference to the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and modifications based on the present disclosure. Therefore, it should be noted that these modifications and modifications are included in the scope of the present invention. For example, the functions included in each component and each step can be rearranged so as not to be logically inconsistent, and a plurality of components or steps can be combined or divided into one. Is. Further, although the present invention has been mainly described with respect to the device, the present invention is a method including a step executed by each component of the device, a method executed by a processor included in the device, a program, or a storage medium in which the program is recorded. Can also be realized. It should be understood that these are also included in the scope of the present invention.

In the above-described embodiment, the fuel cell device 20 has been described as an example of the power supply device. However, the fuel cell device 20 may be another power supply device having different appropriate firmware and control parameters depending on the installation location. In this case, the fuel cell system 10 may be another power supply system including a power supply device having different appropriate firmware and control parameters depending on the installation location, and a controller for controlling the power supply device. Examples of other power supply devices include a photovoltaic power generation device and a power storage device.

1 Firmware provision system 10 Fuel cell system (power supply system)
20 Fuel cell device (power supply device)
21 Power generation unit 22 Auxiliary equipment 23 Exhaust heat recovery unit 24 Power conversion unit 25 Communication unit 26 Storage unit 27 Control unit 30 Controller 31 Communication unit 32 Storage unit 33 Display unit 34 Control unit 40 Server 41 Communication unit 42 Storage unit 43 Control unit 50 1st external server (climate information server)
60 Second external server (map information server)
70 network

Claims (8)

A plurality of power supply systems, each of which comprises a power supply and a controller that controls the power supply.
The controller is provided with a power supply unit and a server for transmitting control information of the controller via a network.
The server sets a priority order according to the temperature of the installation location of the power supply device, and transmits the control information according to the installation location of the power supply device to the controller in the order of the priority order. system. In the firmware providing system according to claim 1,
The control information is a firmware providing system including either one of firmware and control parameters, or both firmware and control parameters. In the firmware providing system according to claim 1 or 2.
The server is a firmware providing system that transmits the control information to the controller at predetermined intervals. In the firmware providing system according to any one of claims 1 to 3.
The power supply device and the controller are firmware providing systems in which the control information is initially set at the time of shipment. A plurality of power supply systems, each of which comprises a power supply and a controller that controls the power supply.
A method of controlling a firmware providing system in a firmware providing system including a server.
The server
A step of selecting control information of the power supply device and the controller according to the installation location of the power supply device, and
The step of setting the priority according to the temperature of the place where the power supply is installed, and
A control method of a firmware providing system including a step of transmitting the control information to the controller in the order of the set priority. A communication unit that communicates with a plurality of power supply systems, wherein each power supply system includes a power supply device and a controller that controls the power supply device.
A control unit that transmits control information of the power supply device and the controller to the controller via the communication unit is provided.
The control unit is a server that sets priorities according to the temperature of the installation location of the power supply device, and transmits the control information according to the installation location of the power supply device to the controller in the order of the priority order. In the server according to claim 6,
The control information is a server that includes either one of the firmware and the control parameters, or both the firmware and the control parameters. In the server according to claim 6 or 7.
The control unit is a server that transmits the control information to the controller at predetermined intervals.

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