JP5533013B2 - Fuel cell system - Google Patents

Description

  The present invention relates to a fuel cell system that stores operation data.

  A conventional fuel cell system detects a power load and a heat load (hot water consumption) in a user's home for each time zone, for example, continuously detects for one week, and stores a power load prediction unit and a hot water consumption prediction unit. Are stored and averaged to predict the power load model pattern for each time zone and the hot water consumption model pattern for each time zone. Each model pattern is also stored in the storage unit. In addition, even if there is a power failure, the storage unit is configured with a non-volatile memory so that there is no loss of data due to a power failure or the like. 1).

JP 2005-38676 A

  However, in the fuel cell system equipped with the conventional learning function, the system data history must be accumulated. There is a method of using a non-volatile memory as an accumulating means. However, when accumulating in the non-volatile memory, there is a restriction on the number of times of writing, so the life of writing can be extended by limiting the number of accesses. For this purpose, there is a method of temporarily storing data in a small-capacity RAM when writing to a nonvolatile memory. However, this method has a problem that data on the RAM is lost when a power failure occurs.

  To solve this problem, there is a method that uses a large-capacity RAM to back up the RAM with a battery. In this method, when the board is replaced during maintenance, the power is input to the board for the first time after the replacement. However, if the RAM data is not initialized, there is a problem that a malfunction occurs due to an indefinite value of the RAM. This is because the RAM cannot be initialized because the data history is accumulated when the power is turned on for the second time and thereafter.

  In view of the above-described conventional problems, an object of the present invention is to provide a fuel cell system with improved certainty of initializing data in a storage element of a new substrate when the substrate is replaced.

In order to achieve the above object, a fuel cell system according to a first aspect of the present invention includes a fuel cell device including a memory element, a battery that backs up the memory element, and a microcomputer on a substrate, and the fuel cell apparatus and network. A management device that is connected to manage the fuel cell device, and the management device stores the rewritable power-on frequency storage unit that stores the number of times of power-on for each fuel cell device and the power-on frequency storage unit. Operating means for rewriting the number of times the power is turned on, and the microcomputer of the new board replaced with a fuel cell device in which the number of times the power is turned on is stored in the power-on number storage means is the board When power is turned on after replacement, it knows that the number of times of power-on is 0 through communication with the management device, and initializes data in the storage element Serial management device to be configured with the power containing the number of times stored in the power supply entering the number storage means to send a signal to increase once.

  Thereby, when replacing | exchanging a board | substrate, the certainty of implementing the initialization of the memory | storage element data of a new board | substrate can be improved.

  According to the present invention, when replacing a substrate, it is possible to increase the certainty of initializing data in a storage element of a new substrate.

1 is a schematic configuration diagram of a fuel cell system according to Embodiment 1 of the present invention. A flowchart showing a procedure for initializing a memory element in the fuel cell system of the same embodiment Schematic configuration diagram of a fuel cell system in Embodiment 2 of the present invention A flowchart showing a procedure for initializing a memory element in the fuel cell system of the same embodiment Schematic configuration diagram of a fuel cell system in Embodiment 3 of the present invention A flowchart showing a procedure for initializing a memory element in the fuel cell system of the same embodiment Schematic configuration diagram of a fuel cell system in Embodiment 4 of the present invention

  According to a first aspect of the present invention, a circuit board includes a storage element, a battery that backs up the storage element, a button that informs an initial input time, and a microcomputer. This is a fuel cell system that initializes data.

  In the above configuration, the operator who replaced the substrate of the fuel cell system operates the button of the replaced new substrate. Then, the microcomputer detects that the button on the new board has been operated and initializes the data in the storage element.

  Therefore, as long as the operator who replaced the substrate of the fuel cell system observes the rule (procedure) of operating the button of the replaced new substrate, the data of the storage element of the new substrate will be initialized, When replacing the substrate, it is possible to increase the certainty of performing the initialization of the storage element data of the new substrate.

  According to a second aspect of the present invention, there is provided a storage element, a battery for backing up the storage element, a microcomputer, an input unit connected to the microcomputer and operable by a user or a serviceman, and a display connected to the microcomputer for display. The microcomputer is a fuel cell system that initializes data in the storage element when a predetermined operation is performed at the input unit.

  In the above configuration, the operator who has replaced the substrate of the fuel cell system performs a predetermined operation at the input portion of the replaced new substrate. Then, the microcomputer detects that a predetermined operation has been performed at the input portion of the new board, and initializes the data in the storage element.

  Therefore, as long as the operator who replaced the substrate of the fuel cell system observes the rule (procedure) that the predetermined operation is performed at the input unit of the replaced new substrate, the data of the storage element of the new substrate is initialized. In other words, when replacing the substrate, it is possible to increase the certainty of initializing the data of the storage element of the new substrate.

  According to a third aspect of the present invention, the substrate includes a storage element, a battery that backs up the storage element, a microcomputer, and an external storage device for storing the number of times the power is turned on connected to the microcomputer through a connection terminal. The microcomputer confirms the number of times the power is turned on stored in the external storage device every time the power is turned on and increases the number of times the power is turned on stored in the external storage device by one, and the confirmed number of times of power on is zero Then, the fuel cell system initializes the data of the storage element.

  In the above configuration, before the replacement, the number of times the external storage device of the new substrate for replacement is turned on is set to zero. An operator replaces an old board with a new board with the power of the fuel cell system turned off, and then turns on the fuel cell system. Then, the microcomputer confirms the number of power-on times stored in the external storage device after startup. Then, the microcomputer detects that the power-on count stored in the external storage device is zero, initializes the data in the storage element, and increases the power-on count stored in the external storage device by one.

  The microcomputer checks the number of power-on times stored in the external storage device every time the fuel cell system is turned on. If the number of power-on times stored in the external storage device is one or more times, the microcomputer The number of power-on times stored in the external storage device is increased by one without initializing the data.

  Therefore, as long as the rules (procedures) for connecting an external storage device that has been stored with the number of power-ons to the new board for replacement are kept, the data in the storage elements on the new board must be initialized. Thus, when replacing the substrate, it is possible to increase the certainty that the storage element data of the new substrate is initialized.

  According to a fourth aspect of the present invention, there is provided a fuel cell device including a memory element, a battery that backs up the memory element as a battery, and a microcomputer on a substrate, and a management device that is connected to the fuel cell device through a network and manages the fuel cell device. And the management device operates when rewriting the number of times of turning on the power stored in the number of times of turning on the power stored in the number of times of turning on the power stored in the power-on number of times storage unit. The microcomputer of the new board replaced by the fuel cell device stored in the power-on count storage means as the number of times of power-on, and when the power is turned on after the board replacement, The number of times of power-on is known by communication, and the data of the storage element is initialized and the number of times of power-on is stored in the management device Storing said power entering the number was a fuel cell system to send a signal to increase once.

  In the above configuration, the microcomputer of the new board replaced with the fuel cell device whose power-on count storage means stores 0 times in the power-on count storage means, when the power is turned on after the board replacement, the number of times the power is turned on by communication with the management device Is zero, and the data in the storage element is initialized, and a signal is sent to the management device to increase the number of times of power-on stored in the number-of-power-on storage means. Then, the management device increases the power-on count of the power-on count storage means corresponding to the fuel cell device that has sent a signal to increase the power-on count by one.

  Therefore, as long as the management device observes the rule (procedure) that the number of power-on times of the power-on number storage means corresponding to the fuel cell device whose substrate is to be replaced in advance is maintained, the initial data of the storage elements on the new substrate Therefore, when replacing the substrate, it is possible to improve the certainty of initializing the data of the storage element of the new substrate.

  Embodiments of a fuel cell system according to the present invention will be described below with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 is a schematic configuration diagram of a fuel cell system according to Embodiment 1 of the present invention. As shown in FIG. 1, the fuel cell system 120 of the present embodiment includes a storage element 101 composed of a RAM, a battery 103 that backs up the storage element 101, a button 104 that informs the initial input, and a button 104 that is operated. Then, the board 121 having the microcomputer 102 set to initialize the data of the storage element 101 is provided, and the board 121 is connected to the FC controller 105 that controls the fuel cell system 120.

  FIG. 2 is a flowchart showing the initialization procedure of the storage element 101 in the fuel cell system 120 of the present embodiment. Hereinafter, the initialization procedure of the storage element 101 in the fuel cell system of the present embodiment will be described with reference to FIGS. 1 and 2.

  When replacing the substrate 121 in the maintenance of the fuel cell system 120, the operator replaces the old substrate 121 with the new substrate 121 with the power of the fuel cell system 120 turned off (S101), and then the fuel cell system. The power of 120 is turned on (S102), and after the microcomputer 102 of the new board 121 is activated, the button 104 is operated (S103). Then, the microcomputer 102 detects that the button 102 of the new board 121 has been operated, and initializes the data in the storage element 101 (S104).

  As described above, the fuel cell system 120 according to the present embodiment includes the memory element 101, the battery 103 that backs up the memory element 101, the button 104 that notifies the initial input, and the microcomputer 102 on the substrate 121. 102 is configured to initialize the data in the storage element 101 when the button 104 is operated. Therefore, an operator who has replaced the substrate 121 of the fuel cell system 120 can operate the button 104 of the new substrate 121 that has been replaced. As long as the rules (procedures) for operating are maintained, the data of the storage element 101 of the new substrate 121 is initialized. When the substrate 121 is replaced, the initial data of the storage element 101 of the new substrate 121 is changed. It is possible to improve the certainty of implementing the conversion.

  Note that it is preferable to display a button urging the user to operate after replacing the substrate 121 near the button 102 or the button 102.

(Embodiment 2)
FIG. 3 is a schematic configuration diagram of a fuel cell system according to Embodiment 2 of the present invention. In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 3, the fuel cell system 120 of the present embodiment includes a storage element 101 composed of a RAM, a battery 103 that backs up the storage element 101 as a battery, a microcomputer 102, and a microcomputer 102 connected to a user or service person. Has a substrate 121 provided with an input unit 106 capable of performing an input operation and a display unit 107 connected to the microcomputer 102 and performing a display for supporting the input of the input unit 106, and the substrate 121 controls the fuel cell system 120. It is connected to the FC control device 105. Note that the microcomputer 102 is set to initialize data in the storage element 101 when a predetermined operation is performed at the input unit 106.

  FIG. 4 is a flowchart showing the initialization procedure of the storage element 101 in the fuel cell system 120 of the present embodiment. Hereinafter, the initialization procedure of the storage element 101 in the fuel cell system of the present embodiment will be described with reference to FIGS. 3 and 4.

  In this embodiment, the input unit is composed of 0-9 numeric keys and # key, and the predetermined operation is to hold down the # key for 10 seconds on the top screen.

  When replacing the substrate 121 in the maintenance of the fuel cell system 120, the operator replaces the old substrate 121 with the new substrate 121 with the power of the fuel cell system 120 turned off (S201), and then the fuel cell system. 120 is turned on (S202) and the microcomputer 102 of the new board 121 is activated. Then, the input unit 106 is operated while viewing the display on the display unit 107, and the # key is pressed and held for 10 seconds on the top screen ( S203). Then, the microcomputer 102 detects that the # key has been pressed for 10 seconds on the top screen, and initializes the data in the storage element 101 (S204).

  As described above, the fuel cell system 120 according to the present embodiment includes the storage element 101, the battery 103 that backs up the storage element 101, the microcomputer 102, and the microcomputer 102. An input unit 106 composed of a numeric key -9 and a # key, and a display unit 107 connected to the microcomputer 102 and performing display for supporting the input of the input unit 106 are provided on the substrate 121. Is configured to initialize the data in the storage element 101 when the operation is performed (pressing the # key for 10 seconds on the top screen), the operator who has replaced the substrate 121 of the fuel cell system 120 can replace it. As long as the rules (procedures) for performing a predetermined operation with the input unit 106 of the new substrate 121 are kept, the storage of the new substrate 121 is performed. Results in the initialization of the data of the child 101 is performed, when replacing the substrate 121, it is possible to increase the certainty that performs initialization of the data in the storage device 101 of the new substrate 121.

  The input unit 106 may be displayed on the display unit 107 or may be independent of the input unit 106. In this embodiment, an example of a combination of a screen displayed on the display unit 107 and an operation is shown. However, the operation on the input unit 106 may be performed regardless of the display screen of the display unit 107.

(Embodiment 3)
FIG. 5 is a schematic configuration diagram of a fuel cell system according to Embodiment 3 of the present invention. In the present embodiment, the same components as those in the first embodiment or the second embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 5, the fuel cell system 120 according to the present embodiment includes a memory element 101 composed of a RAM, a battery 103 that backs up the memory element 101, a microcomputer 102, and a connection terminal 122 connected to the microcomputer 102. The substrate 121 includes an external storage device 108 for storing the number of times the power supply can be connected. The substrate 121 is connected to the FC control device 105 that controls the fuel cell system 120. The microcomputer 102 checks the number of times of power-on stored in the external storage device 102 every time the power of the fuel cell system 120 is turned on, and confirms that the number of times of power-on is zero, When the number of times of power-on stored in the external storage device 108 is increased by 1 and the number of times of power-on is confirmed to be 1 or more, the data in the storage element 101 is not initialized and the external storage device The number of power-on times stored in 108 is set to be increased by one.

  FIG. 6 is a flowchart showing a procedure for initializing the storage element 101 in the fuel cell system 120 of the present embodiment. Hereinafter, the initialization procedure of the memory element 101 in the fuel cell system of the present embodiment will be described with reference to FIGS. 5 and 6.

  First, the number of times the external storage device 108 of the new board 121 for replacement is turned on is set to 0 in advance (S301). The operator replaces the old substrate 121 with the new substrate 121 with the power of the fuel cell system 120 turned off (S302), and then turns on the fuel cell system 120 (S303). Then, the microcomputer 102 confirms the number of power-on times stored in the external storage device 102 after activation. The microcomputer 102 detects that the number of power-on times stored in the external storage device 102 is 0 (S305), initializes the data in the storage element 101 (S306), and stores the data in the external storage device 102. The number of times the power is turned on is increased by 1 (S307).

  The microcomputer 102 checks the number of times of power-on stored in the external storage device 102 every time the fuel cell system 120 is turned on, and if the number of times of power-on stored in the external storage device 102 is one or more times. The number of power-on times stored in the external storage device 108 is increased by one without initializing the data in the storage element 101.

  As described above, the fuel cell system 120 according to the present embodiment includes the memory element 101, the battery 103 that backs up the memory element 101, the microcomputer 102, and the number of times the power is turned on connected to the microcomputer 102 via the connection terminal 122. An external storage device 108 for storage is provided on the board 121, and the microcomputer 102 checks the number of times the power is turned on stored in the external storage device 108 every time the power is turned on, and determines the number of times the power is turned on stored in the external storage device 108. If it is increased by 1 and the confirmed number of times of power-on is 0, the data in the storage element 101 is initialized, so the new board 121 for replacement stores the number of times of power-on as 0. As long as the rule (procedure) for connecting the external storage device 108 is observed, the data of the storage element 101 of the new substrate 121 is initialized. Will be, when replacing the substrate 121, it is possible to increase the certainty that performs initialization of the data in the storage device 101 of the new substrate 121.

  The operation of setting the number of times the external storage device 108 of the new replacement board 121 is turned on to zero is connected to the replacement of the new board 121 of the external storage device 108 that has been stored in advance as the number of times of power-on. Even if it is connected to the terminal 122, the external storage device 108 in which the number of times of power-on is stored as 0 in advance may be connected to the new substrate 121 for replacement.

(Embodiment 4)
FIG. 7 is a schematic configuration diagram of a fuel cell system according to Embodiment 4 of the present invention. In the present embodiment, the same components as those in the first to third embodiments are denoted by the same reference numerals, and detailed description thereof is omitted.

  As shown in FIG. 7, the fuel cell system according to the present embodiment includes a memory cell 101 composed of a RAM, a battery 103 that backs up the memory element 101 as a battery, and a fuel cell device 120 a that includes a microcomputer 102 on a substrate 121. A management device 110 that is connected to the fuel cell device 120a via the network 109 and manages the fuel cell device 120a. The management device 110 stores a rewritable power-on count storage unit that stores the power-on count for each fuel cell device 120a. 111 and operating means 112 operated when rewriting the power-on count stored in the power-on count storage means 111, and the substrate 121 is connected to the FC control apparatus 105 that controls the fuel cell apparatus 120a. . Then, the microcomputer 102 of the new board 121 exchanged with the fuel cell device 120a stored in the power-on number storage means 111 with the number of times of power-on is 0. When the power is turned on after the board 121 is exchanged, the microcomputer 102 communicates with the management apparatus 110. To know that the number of times of power-on is zero, initialize the data in the storage element 101 and send a signal to the management device 110 to increase the number of times of power-on stored in the power-on number of times storage means 111 by one. It is configured.

  The operator inputs a unique number to each fuel cell device 120a and 0 as the number of times of power on to the number of times of power on storage 111 using the operation unit 112 in the management device 110 before replacing the substrate 121. After the substrate 121 is replaced, the fuel cell device 120a is powered on, and after the microcomputer 102 is activated, the microcomputer 102 accesses the management device 110 via the network 109 and transmits a unique number to the management device 110. The management device 110 to which the unique number is sent transmits the number of times the fuel cell device 120a is turned on to the fuel cell device 120a. The fuel cell device 120a receives the number of times of power-on, and initializes the memory element 101 if the number of times of power-on is zero.

  In the above configuration, the microcomputer 102 of the new board 121 replaced with the fuel cell apparatus 120a stored in the power-on number storage means 111 with the number of times of power-on stored in the power-on number storage means 111 is connected to the management apparatus 110 when the power is turned on after the board 121 is replaced. As a result of this communication, it is known that the number of power-on times is zero, and the data in the storage element 101 is initialized and a signal is sent to the management device 110 to increase the number of power-on times stored in the power-on number memory means 111 by one. send. Then, the management device 110 increases the power-on count of the power-on count storage unit 111 corresponding to the fuel cell device 120a that has sent a signal to increase the power-on count by one.

  Therefore, as long as the management device 110 observes the rule (procedure) that the power-on count storage means 111 corresponding to the fuel cell device 120a for exchanging the substrate 121 is set to 0 in advance, the memory of the new substrate 121 is stored. Initialization of the data of the element 101 is performed, and when the substrate 121 is replaced, the certainty of initializing the data of the storage element 101 of the new substrate 121 can be improved.

  In the fuel cell system of the present invention, when replacing a substrate, it is possible to improve the certainty of initializing the data of the storage element of the new substrate. Suitable for fuel cell systems that store data. In addition, the present invention is not limited to a fuel cell system, and since the device life is as long as about 10 years or more, there is a possibility of replacing the substrate before the device life, and history data is stored in a storage element that requires battery backup. It can also be applied to existing systems.

DESCRIPTION OF SYMBOLS 101 Memory element 102 Microcomputer 103 Battery 104 Button 106 Input part 107 Display part 108 External storage device 109 Internet 110 Management apparatus 111 Power-on frequency storage means 112 Operation means 120 Fuel cell system 120a Fuel cell apparatus 121 Substrate 122 Connection terminal

Claims (1)

A storage element; a battery that backs up the storage element; a fuel cell device that includes a microcomputer on a substrate; and a management device that is connected to the fuel cell device via a network and manages the fuel cell device. The apparatus includes a rewritable power-on number storage unit that stores the number of times of power-on for each fuel cell device, and an operation unit that operates when rewriting the number of times of power-on stored in the power-on number storage unit. The microcomputer of the new board replaced with the fuel cell device stored in the power-on number storage means as the number of times of power-on is 0. When the power is turned on after the board replacement, the number of times the power is turned on by communication with the management device Before the data stored in the power-on count storage means is initialized for the management device. The fuel cell system to send a signal to increase the power entering number once.

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