JPWO2020003379A1 - Maintenance system, maintenance board, and data writing method - Google Patents

Abstract

An electronic board, a maintenance board that is replaceable with the electronic board, a data management device that manages the firmware written on the maintenance board, and the firmware is written on the maintenance board and is retained on the electronic board. The maintenance board is provided with a data rewriting device that transfers the stored information to the maintenance board. The maintenance board receives and stores the information based on the power supply from the data rewriting apparatus, and the power is supplied from the data rewriting apparatus. The firmware is received based on the data, the firmware is stored based on power supplied from the device, the data rewriting device reads the information from the electronic board, and the firmware is updated based on the information to the data management device. And writes the information and the firmware on the maintenance board.

Description

The present invention relates to a maintenance system for equipment that operates based on firmware, a maintenance board, and a data writing method.

Since industrial equipment such as air conditioning equipment is intended for commercial use, it is necessary to take prompt action in case of failure. In the case of a failure related to an electric component, it may be possible to deal with it by replacing it with a maintenance board. In general, an electronic board is designed so as to be compatible with a plurality of products, and a predetermined firmware (a program for board operation) is written to perform an operation corresponding to a target product specification.

As a background art in this technical field, there is a technology disclosed in Patent Document 1. In Patent Document 1, the server device transmits the maintenance program associated with the identification data to the mobile phone device by acquiring the identification data of the maintenance compatible device from the mobile phone, and performs maintenance on a new board after replacement. It describes how to incorporate the program.

JP, 2009-89020, A

However, with the method disclosed in Patent Document 1, the maintenance program can be written in a new board after replacement, but the information of the original device that has failed cannot be transferred to the new board after replacement. It was

The present invention has been made in view of the above circumstances, and an object thereof is to write firmware to a maintenance board that is replaced with an electronic board, and to transfer information held in the electronic board to the maintenance board. It is an object of the present invention to provide a maintenance system, a maintenance board, and a data writing method that can perform

In order to achieve the above object, a maintenance system according to a first aspect is a data management device that manages firmware written on a maintenance board that is replaceable with an electronic board, and writes the firmware on the maintenance board. , A data rewriting device for transferring the predetermined information held in the electronic board to the maintenance board.

According to the present invention, it is possible to write firmware on a maintenance board that is replaced with an electronic board and transfer information held in the electronic board to the maintenance board.

FIG. 1 is a block diagram showing the configuration of a maintenance system before and after substrate replacement according to the first embodiment. FIG. 2 is a block diagram showing a configuration example of the air conditioner of FIG. FIG. 3 is a block diagram showing a configuration example of the data rewriting device of FIG. FIG. 4 is a block diagram showing a configuration example of the air conditioner data management device of FIG. FIG. 5 is a diagram showing a configuration example of the device information of FIG. FIG. 6 is a diagram showing a data reading sequence from the air conditioner board of FIG. FIG. 7 is a diagram showing a data writing sequence to the air conditioner maintenance board of FIG. FIG. 8 is a flowchart showing the operation of the data rewriting device of FIG. 1 at the time of reading data. FIG. 9 is a flowchart showing the operation of the data rewriting device of FIG. 1 at the time of writing data. FIG. 10 is a flowchart showing the operation when the air conditioner of FIG. 1 fails. FIG. 11 is a flowchart showing the operation of the air conditioner of FIG. 1 when exchanging a board. FIG. 12 is a diagram showing a data reading sequence from the air conditioner board of the maintenance system according to the second embodiment. FIG. 13 is a diagram showing a data write sequence to the air conditioner maintenance board of the maintenance system according to the second embodiment. FIG. 14 is a diagram showing a data write sequence to the air conditioner data management device of the maintenance system according to the second embodiment. FIG. 15 is a block diagram showing a configuration example of an air conditioner of the maintenance system according to the third embodiment. FIG. 16 is a block diagram showing a configuration example of the data rewriting device of the maintenance system according to the third embodiment. FIG. 17 is a diagram showing a data write sequence to the air conditioner maintenance board of the maintenance system according to the third embodiment.

Embodiments will be described with reference to the drawings. It should be noted that the embodiments described below do not limit the invention according to the claims, and all of the elements and combinations described in the embodiments are essential to the solution means of the invention. Not necessarily.

FIG. 1 is a block diagram showing the configuration of a maintenance system before and after substrate replacement according to the first embodiment.
In FIG. 1, the maintenance system includes an air conditioner (hereinafter referred to as an air conditioner) 11, an air conditioner maintenance board 12, a data rewriting device 13, and an air conditioner data management device 14. The air conditioner 11 includes an air conditioner board 17. The air conditioner board 17 can be replaced with the air conditioner maintenance board 12. The air conditioner board 17 and the air conditioner maintenance board 12 are electronic boards having the same configuration. The air conditioner board 17 holds firmware 17A and device information 17B. The firmware 17A is a program for operating the air conditioner board 17. The device information 17B is information about the air conditioner 11. The device information 17B can include, for example, information unique to the air conditioner 11, control information of the air conditioner 11, and operation information of the air conditioner 11.

The air conditioner data management device 14 manages the firmware 12A written on the air conditioner maintenance board 12. The air conditioner data management device 14 is, for example, a server.

The data rewriting device 13 writes the firmware 12A in the air conditioner maintenance board 12, and transfers the device information 17B held in the air conditioner board 17 to the air conditioner maintenance board 12 as the device information 12B. The data rewriting device 13 is, for example, a mobile terminal such as a smartphone that can be connected to a mobile communication network. The data rewriting device 13 can transmit and receive data to and from the air conditioner board 17 and the air conditioner maintenance board 12 by the short-range wireless communication 15. The short-distance wireless communication 15 is, for example, wireless communication such as NFC (Near Field Communication) (registered trademark), Bluetooth (registered trademark), or IEEE 802.11. The data rewrite device 13 and the air conditioner data management device 14 are connected via a communication network 16. The communication network 16 is, for example, a mobile communication network or the Internet.

The processor on the air conditioner board 17 controls the air conditioner 11 by executing the firmware 17A. At this time, the processor on the air conditioner board 17 can update the device information 17B according to the operating status of the air conditioner 11.

When the air conditioner 11 fails, the air conditioner board 17 is replaced with the air conditioner maintenance board 12 to repair the air conditioner 11. At this time, the data rewriting device 13 reads the device information 17B from the air conditioner board 17 (P1), acquires the firmware 12A from the air conditioner data management device 14 based on the device information 17B (P2), and responds to the device information 17B. The device information 12B and the firmware 12A to be written are written on the air conditioner maintenance board 12 (P3, P4).

The air conditioner maintenance board 12 receives the device information 12B corresponding to the device information 17B from the data rewriting device 13 and stores it (P3). Further, the air conditioner maintenance board 12 receives and stores the firmware 12A from the data rewriting device 13 (P4).

Thus, the air conditioner maintenance board 12 can store the device information 12B corresponding to the device information 17B held on the electronic board and the firmware 12A that operates based on the device information 12B. Therefore, even if the air conditioner 11 fails, the firmware 12A corresponding to the air conditioner 11 can be incorporated into the air conditioner maintenance board 12 without fail, and the burden of maintenance work can be reduced. It is possible to cause the air conditioner 11 before the failure to execute the firmware 12A while matching the state.

FIG. 2 is a block diagram showing a configuration example of the air conditioner of FIG.
In FIG. 2, the air conditioner 11 includes an air conditioner board 17, a load 22 and a power supply 23. The load 22 is a fan, a compressor, or the like. The power supply 23 supplies electric power to the air conditioner board 17 and the load 22. The air conditioner board 17 includes power supply blocks 20A and 21A.

The power supply block 20A includes a control unit 201, a main storage unit 203, storage units 202 and 204, and a communication unit 205. The control unit 201 is hardware that controls the operation control of the air conditioner 11. The control unit 201 is, for example, a microcomputer. The main storage unit 203 can store a program being executed by the control unit 201 and can provide a work area for the control unit 201 to execute the program. The main storage unit 203 is, for example, a semiconductor memory such as an SRAM (Static Random Access Memory) or a DRAM (Dynamic Random Access Memory). The storage unit 202 is a non-volatile storage device having a large storage capacity. The storage unit 202 is, for example, a FLASH-ROM. The storage unit 202 holds the firmware 17A. The storage unit 204 is a non-volatile storage device that has a longer life than the storage unit 202. The storage unit 204 is, for example, an EEPROM (Electrically Erasable Programmable Read Only Memory). The communication unit 205 communicates with other air conditioners.

The power supply block 21A includes a control unit 211, a storage unit 212, and a communication unit 213. The power supply block 21A can be operated by the induced electromotive force generated by the electromagnetic waves from the data rewriting device 13 without the power supply from the power supply 23. The power supply block 21A can be composed of, for example, an NFC tag.

The control unit 211 is hardware that controls data communication and reading/writing. The control unit 211 is, for example, a logic circuit. The storage unit 212 is a non-volatile storage device that stores data. The storage unit 212 is, for example, a FeRAM (Ferroelectric Random Access Memory). The storage unit 212 holds the device information 17B. The device information 17B may also be stored in the storage unit 204. The communication unit 213 performs near field communication. The communication unit 213 can communicate with the electromotive force induced by the electromagnetic waves from the data rewriting device 13.

When power is supplied from the power supply 23, the control unit 201 reads the firmware 17A from the storage unit 202 and loads it in the main storage unit 203. Then, the control unit 201 controls the operation of the air conditioner 11 by executing the expanded firmware 17A. Further, the control unit 201 reads and writes air conditioner data in the storage unit 204, and reads and writes air conditioner data in the storage unit 212 via the control unit 211. At this time, the control unit 201 refers to the device information 17B stored in the storage unit 212 and controls the operation of the air conditioner 11. The control unit 201 also updates the device information 17B based on the operating status of the air conditioner 11. The operating status of the air conditioner 11 is, for example, the operating time of the air conditioner 11.

The communication unit 213 also communicates with the data rewriting device 13. Then, the control unit 211 reads and writes the data in the storage unit 212 based on the request from the data rewriting device 13. Further, the control unit 211 reads and writes the data in the storage unit 212 based on the request from the control unit 201.

FIG. 3 is a block diagram showing a configuration example of the data rewriting device of FIG.
3, the data rewriting device 13 includes a control unit 31, a main storage unit 32, storage units 33 and 34, and communication units 35 and 36.

The control unit 31 is hardware that controls the operation of the data rewriting device 13. The control unit 31 is, for example, a microcomputer. The main storage unit 32 can store a program being executed by the control unit 31 and can provide a work area for the control unit 31 to execute the program. The main storage unit 32 is, for example, a semiconductor memory such as SRAM or DRAM. The storage unit 33 is a non-volatile storage device having a large storage capacity. The storage unit 33 is, for example, a FLASH-ROM. The storage unit 33 holds the rewriting program 33A. The storage unit 34 is a portable non-volatile storage device. The storage unit 34 is removable from the data rewriting device 13. The storage unit 34 is, for example, an SD card or a USB memory. The communication unit 35 communicates via the communication network 16. The communication unit 36 performs near field communication 15 such as NFC.

The control unit 31 reads the rewriting program 33A from the storage unit 33 and loads it in the main storage unit 32. Then, the control unit 31 controls the operation of the data rewriting device 13 by executing the expanded rewriting program 33A. At this time, the control unit 31 transmits and receives data to and from the air conditioner board 17 and the air conditioner maintenance board 12 by performing the short-range wireless communication 15 via the communication unit 36. In addition, the control unit 31 communicates with the air conditioner data management device 14 by communicating via the communication unit 35.

In an environment in which the communication by the communication unit 35 is possible, the control unit 31 can send and receive data to and from the air conditioner data management device 14 via the communication network 16. In an environment where communication by the communication unit 35 is impossible, the control unit 31 can exchange data with the air conditioner data management device 14 by reading and writing data with the storage unit 34. ..

FIG. 4 is a block diagram showing a configuration example of the air conditioner data management device of FIG.
In FIG. 4, the air conditioner data management device 14 includes a control unit 41, a main storage unit 42, a communication unit 43, an air conditioner data storage unit 44, and a storage unit 45.

The control unit 41 is hardware that controls the operation control of the air conditioner data management device 14. The control unit 41 is, for example, a microcomputer. The main storage unit 42 can store a program being executed by the control unit 41, or can be provided with a work area for the control unit 41 to execute the program. The main storage unit 42 is, for example, a semiconductor memory such as SRAM or DRAM. The air conditioner data storage unit 44 is a non-volatile storage device having a large storage capacity. The air conditioner data storage unit 44 is, for example, a hard disk device or an SSD (Solid State Drive). The air conditioner data storage unit 44 stores the firmware 441 of the air conditioner 11 and the air conditioner installation information 442. The air conditioner installation information 442 can hold a failure flag indicating a failure of the air conditioner 11, in addition to the information on the installation position of the air conditioner 11. Further, the air conditioner installation information 442 can also hold the device information 17B of the air conditioner 11. The storage unit 45 is a portable non-volatile storage device. The storage unit 45 can be attached to and detached from the air conditioner data management device 14. The storage unit 45 is, for example, an SD card or a USB memory. The communication unit 43 communicates via the communication network 16. At this time, the control unit 41 communicates with the data rewriting device 13 by performing communication via the communication unit 43.

The control unit 41 can send and receive data to and from the data rewriting device 13 via the communication network 16 in an environment in which the communication by the communication unit 43 is possible. In an environment where communication by the communication unit 43 is impossible, the control unit 41 can exchange data with the data rewriting device 13 by reading and writing data with the storage unit 45.

FIG. 5 is a diagram showing a configuration example of the device information of FIG.
In FIG. 5, device information 17B is an ID that indicates an individual value for each air conditioner board 17, a device type of the air conditioner 11, a device number that is a serial number of the air conditioner 11, and fan control that is control information for each device type. The parameters F1 and F2, the actuator parameters A1 and A2, the cumulative operating time of the air conditioner 11, the number of error occurrences, the firmware version recorded in the storage unit 202, and the like are included.

A reading attribute can be set for each piece of information, and an ID is recorded in a non-rewritable area. The fan control parameters F1 and F2 and the actuator parameters A1 and A2 can be designated for each device type, device number, and device type of the air conditioner 11. The fan control parameters F1 and F2 and the actuator parameters A1 and A2 are control information and need only be written once at the first time and are recorded, for example, at the time of product shipment. The cumulative operating time and the number of error occurrences are regularly updated when the air conditioner is operating.

FIG. 6 is a diagram showing a data reading sequence from the air conditioner board of FIG.
In FIG. 6, the control unit 201 appropriately updates the cumulative operating time, the number of error occurrences, and the like in the device information 17B stored in the storage unit 212 while the air conditioner 11 is operating (S601).

Next, it is assumed that the air conditioner 11 has failed (S602). At this time, the state of the air conditioner 11 before the failure is recorded in the device information 17B. When the air conditioner 11 breaks down, the maintenance staff moves to the installation place of the air conditioner 11 with the air conditioner maintenance board 12 and the data rewriting device 13.

Next, the data rewriting device 13 communicates with the power supply block 21A of the air conditioner 11 (S603). Next, the power supply block 21A of the air conditioner 11 operates by the induced electromotive force of the data rewriting device 13 and responds to the data rewriting device 13 (S604). At this time, the power supply block 21A operates by the induced electromotive force of the data rewriting device 13, and thus can respond to the data rewriting device 13 even when power cannot be supplied from the power supply 23 due to a failure of the air conditioner 11.

Next, the data rewriting device 13 inquires of the power supply block 21A about the ID of the air conditioner board 17 stored in the storage unit 212 (S605). Next, the power supply block 21A returns the ID of the air conditioner board 17 to the data rewriting device 13 (S606).

Next, the data rewrite device 13 transmits the ID of the air conditioner board 17 to the air conditioner data management device 14 (S607). At this time, it is possible to notify the air conditioner data management device 14 that the air conditioner 11 having the ID of the air conditioner board 17 has failed. Next, the air conditioner data management device 14 changes the state of the air conditioner 11 corresponding to the received ID in the air conditioner installation information 442 recorded in the air conditioner data storage unit 44 to a failure state (S608). .. Next, the air conditioner data management device 14 responds to the data rewriting device 13 that the state of the air conditioner 11 has been changed (S609).

Next, the data rewriting device 13 inquires of the power supply block 21A about the device information 17B stored in the storage unit 212 (S610). Next, the power supply block 21A responds with the device information 17B to the data rewriting device 13 (S611).

Next, the data rewrite device 13 notifies the air conditioner data management device 14 of the device information 17B acquired from the power supply block 21A (S612). Next, the air conditioner data management device 14 updates the device information 17B of the corresponding air conditioner 11 of the air conditioner installation information 442 corresponding to the ID acquired in S607 (S613). Next, the air conditioner data management device 14 responds to the data rewriting device 13 that the device information 17B has been updated (S614).

As described above, the data rewriting device 13 reads the device information 17B of the failed air conditioner 11 by performing communication among the failed air conditioner 11, the data rewriting device 13, and the air conditioner data management device 14, and the air conditioner data is read. The air conditioner installation information 442 managed by the management device 14 can be updated, and the air conditioner data management device 14 can centrally manage the failure state of the air conditioner 11. Further, the power supply block 21A of the air conditioner 11 can be operated by the induced electromotive force using the electromagnetic wave transmitted by the data rewrite device 13, and the data rewrite device 13 can operate even if the air conditioner 11 does not operate due to a failure. The information 17B can be read.

FIG. 7 is a diagram showing a data writing sequence to the air conditioner maintenance board of FIG.
In FIG. 7, the air conditioner maintenance board 12 includes power supply blocks 20B and 21B. The power supply blocks 20B and 21B can be configured similarly to the power supply blocks 20A and 21A of the air conditioner board 17 of FIG. 2, respectively.

The data rewriting device 13 is communicatively connected to the power supply block 21B of the air conditioner maintenance board 12 (S621). Next, the power supply block 21B of the air conditioner maintenance board 12 operates by the induced electromotive force of the data rewriting device 13 and responds to the data rewriting device 13 (S622).

Next, the data rewriting device 13 inquires of the power supply block 21B about the ID of the air conditioner maintenance board 12 (S623). Next, the power supply block 21B of the air conditioner maintenance board 12 returns the ID of the air conditioner maintenance board 12 to the data rewriting device 13 (S624).

Next, the data rewriting device 13 transmits the ID of the air conditioner maintenance board 12 to the air conditioner data management device 14 (S625). At this time, the air conditioner data management device 14 can be notified that the data rewriting device 13 is to be replaced with the air conditioner maintenance board 12 having the ID acquired. Next, the air conditioner data management device 14 changes the device information of the air conditioner corresponding to the ID of the air conditioner board 17 acquired in S607 of FIG. 6 to the ID of the air conditioner maintenance board 12 acquired in S625. Is performed (S626). Next, the air conditioner data management device 14 responds to the data rewriting device 13 that the ID binding has been changed (S627).

Next, the data rewriting device 13 writes the device information 17B of the air conditioner board 17 acquired in S611 of FIG. 6 as device information 12B in the storage unit of the power supply block 21B of the air conditioner maintenance board 12 (S628). Next, the power supply block 21B responds to the data rewriting device 13 that the device information 12B has been written (S629).

Next, the data rewriting device 13 inquires of the air conditioner data management device 14 about the firmware corresponding to the device type recorded in the device information 17B of the air conditioner board 17 acquired in S611 of FIG. 6 (S630). Next, the air conditioner data management device 14 responds to the data rewriting device 13 with the latest firmware and version number corresponding to the device type (S631).

Next, the air conditioner maintenance board 12 is replaced with the air conditioner board 17 of the failed air conditioner 11, incorporated into the air conditioner 11, and energized (S632). Next, the air conditioner maintenance board 12 is initially activated (S633). At the time of initial activation, the power supply block 20B reads the device information 12B from the storage unit of the power supply block 21B (S634), and operates according to the device information 12B.

Next, the data rewriting device 13 transmits the firmware 12A acquired in S631 to the power supply block 21B of the air conditioner maintenance board 12. The power supply block 21B of the air conditioner maintenance board 12 receives the firmware 12A via the communication unit of the power supply block 21B and transmits it from the control unit of the power supply block 21B to the control unit of the power supply block 20B (S635).

Next, the control unit of the power supply block 20B records the firmware 12A received from the power supply block 21B in the storage unit of the power supply block 20B (S636). Next, the control unit of the power supply block 20B restarts when the reception of the firmware 12A is completed (S637).

After the restart, the control unit of the power supply block 20B updates the device information 12B including the version number of the firmware 12A via the control unit of the power supply block 21B (S638). Next, the data rewriting device 13 inquires the device information 12B stored in the storage unit of the power supply block 21B (S639). Next, the power supply block 21B returns the device information 12B to the data rewriting device 13 (S640).

Next, the data rewriting device 13 notifies the air conditioner data management device 14 of the device information 12B acquired from the power supply block 21B (S641). Next, the air conditioner data management device 14 updates the device information 12B of the corresponding air conditioner 11 of the air conditioner installation information 442 corresponding to the ID of the air conditioner maintenance board 12 acquired in S625 (S642). Next, the air conditioner data management device 14 responds to the data rewriting device 13 that the device information 12B has been updated (S643).

As described above, the device information 17B of the failed air conditioner 11 can be handed over to the replaced air conditioner maintenance board 12. The power supply block 21B of the air conditioner maintenance board 12 operates by an induced electromotive force using the electromagnetic wave transmitted by the data rewriting device 13, so that the device information is not supplied even when the air conditioner maintenance board 12 is not powered. 12B can be written. By taking over the device information 17B of the failed air conditioner 11 as the device information 12B to the air conditioner maintenance board 12, the air conditioner 11 is operated under the same conditions as before the failure according to the device model and control information recorded in the device information 12B. Can be made.

FIG. 8 is a flowchart showing the operation of the data rewriting device of FIG. 1 at the time of reading data.
In FIG. 8, the data rewriting device 13 is communicatively connected to the power supply block 21A of the air conditioner board 17 (S701).

Next, the data rewriting device 13 confirms whether or not the response of the air conditioner board 17 is the target device (S702). Whether or not the device is a target device can be confirmed, for example, by matching the communication protocols. When the data rewriting device 13 determines in S702 that the device is the target device, the data rewriting device 13 queries the power supply block 21A for the ID of the air conditioner board 17 (S703).

Next, the data rewriting device 13 confirms whether the ID received from the power supply block 21A is a predetermined ID that is managed in advance (S704). When the data rewriting device 13 determines in S704 that the ID is correct, the data rewriting device 13 notifies the air conditioner data management device 14 that the air conditioner 11 having the corresponding ID has failed (S705). Next, the data rewriting device 13 inquires of the power supply block 21A about the device information 17B of the air conditioner 11 (S706).

Next, the data rewriting device 13 confirms whether the device information 17B acquired from the power supply block 21A is correct (S707). For example, the data rewriting device 13 confirms by CRC (Cyclic Redundancy Check) or the like whether or not the content of the device information 17B is correct. On the other hand, if the correct information cannot be received in S702, S704, or S707, an error notification is given to the display screen (not shown) of the data rewriting device 13, and the process ends (S708).

FIG. 9 is a flowchart showing the operation of the data rewriting device of FIG. 1 at the time of writing data.
In FIG. 9, the data rewriting device 13 is communicatively connected to the power supply block 21B of the air conditioner maintenance board 12 (S710).

Next, the data rewriting device 13 confirms whether or not the response of the air conditioner maintenance board 12 is the target device (S711). Whether or not the device is a target device can be confirmed, for example, by matching the communication protocols. When the data rewriting device 13 determines that the device is the target device in S711, the data rewriting device 13 inquires of the power supply block 21B about the ID of the air conditioner maintenance board 12 (S712).

Next, the data rewriting device 13 confirms whether the ID received from the power supply block 21B is a predetermined ID managed in advance (S713). When the data rewriting device 13 determines in S713 that the ID is correct, the data rewriting device 13 notifies the air conditioner data management device 14 that the air conditioning maintenance board 12 having the corresponding ID will be replaced (S714). Next, the data rewriting device 13 writes the device information 17B acquired in S706 of FIG. 8 as the device information 12B in the storage unit of the power supply block 21B of the air conditioner maintenance board 12 (S715).

Next, the data rewriting device 13 inquires of the air conditioner data management device 14 about the firmware 12A corresponding to the device type recorded in the device information 17B acquired in S706 (S716). Next, the data rewriting device 13 transmits the firmware 12A acquired in S631 of FIG. 7 to the air conditioner maintenance board 12 (S717).

Next, when the transmission of the firmware 12A is completed and the air conditioner 11 incorporating the air conditioner maintenance board 12 is restarted, the data rewrite device 13 inquires of the power supply block 21B for the device information 12B of the air conditioner 11 (S718). ). Next, the data rewriting device 13 confirms whether the device information 12B acquired from the power supply block 21B is correct. For example, the data rewriting device 13 confirms by CRC or the like whether the content of the device information 12B is correct.

If the data rewriting device 13 determines in S719 that the device information 12B is correct, the data rewriting device 13 notifies the air conditioner data management device 14 of the device information 12B acquired from the power supply block 21B (S720). On the other hand, if the correct information cannot be received in S711, S713, or S719, an error notification is given on the display screen (not shown) of the data rewriting device 13, and the process is ended (S721).

FIG. 10 is a flowchart showing the operation when the air conditioner of FIG. 1 fails.
In FIG. 10, the air conditioner 11 performs a normal operation (S801). Next, the control unit 201 of FIG. 2 determines whether or not a failure of the air conditioner 11 has occurred (S802). When the failure of the air conditioner 11 has not occurred, the control unit 201 confirms whether it is the update timing of the device information 17B (S803).

In the case of the update timing of the device information 17B, the control unit 201 updates the accumulated operating time and the number of error occurrences of the device information 17B recorded in the storage unit 212 via the control unit 211 (S804), and returns to S801.

On the other hand, when it is not the update timing of the device information 17B, the control unit 201 confirms whether an error such as a communication error has occurred (S805). If there is no error, the process returns to S801. If there is an error, the process proceeds to S804.

When a failure of the air conditioner 11 occurs in S802, the air conditioner 11 stops its operation (S806). Next, the power supply block 21A of the air conditioner 11 communicates with the data rewrite device 13 and receives an inquiry about the ID of the air conditioner board 17 from the data rewrite device 13 (S807).

Next, the power supply block 21A confirms whether or not the transmission of the data rewriting device 13 is the target device (S808). Whether or not the device is a target device can be confirmed, for example, by matching the communication protocols. If the transmission of the data rewriting device 13 is not the target device, the process ends.

On the other hand, if the transmission of the data rewriting device 13 is the target device, the power supply block 21A returns the ID of the air conditioner board 17 to the data rewriting device 13 (S809). Next, the power supply block 21A responds to the inquiry of the device information 17B from the data rewriting device 13 (S810).

FIG. 11 is a flowchart showing the operation of the air conditioner of FIG. 1 when exchanging a board.
In FIG. 11, the air conditioner maintenance board 12 is replaced with the air conditioner board 17 of the air conditioner 11 that has failed, is incorporated into the air conditioner 11, is energized, and then is initialized (S820). Next, the control unit of the power supply block 20B reads the device information 12B from the storage unit of the power supply block 21B (S821).

Next, the control unit of the power supply block 20B operates according to the control information recorded in the read device information 12B (S822). Next, the control unit of the power supply block 20B receives the firmware from the data rewriting device 13 via the power supply block 21B (S823).

Next, the control unit of the power supply block 20B determines whether the firmware received from the data rewriting device 13 needs to be updated newer than the currently recorded firmware (S824). If the firmware update is unnecessary, the process proceeds to S830. On the other hand, if the firmware needs to be updated, the firmware is received from the data rewriting device 13 (S825).

Next, the control unit of the power supply block 20B determines whether the reception of the firmware is completed (S826). If the reception of the firmware has not been completed, the process returns to S825. On the other hand, when the reception of the firmware is completed, the power supply block 20B is restarted (S827).

After restarting the power supply block 20B, the control unit of the power supply block 20B reads the device information 12B from the storage unit of the power supply block 21B (S828). Next, the control unit of the power supply block 20B operates according to the control information recorded in the read device information 12B (S829).

Next, the control unit of the power supply block 20B updates the device information 12B including the version number of the firmware, for example (S830). Next, the power supply block 21B receives an inquiry about the device information 12B stored in the storage unit of the power supply block 21B from the data rewriting device 13 (S831). Next, the power supply block 21B returns the device information 12B to the data rewriting device 13 (S832).

In the second embodiment below, regarding the data rewriting device 13, a method of exchanging boards in an area not connected to a mobile communication network will be described. The maintenance system of the second embodiment can be configured similarly to the maintenance system of the first embodiment.

FIG. 12 is a diagram showing a data reading sequence from the air conditioner board of the maintenance system according to the second embodiment.
In FIG. 12, the data rewriting device 13 inquires about the device type based on the installation information of the failed air conditioner 11 (S901). At this time, when the maintenance staff is notified of the failure of the air conditioner 11, he/she can hear the installation information of the failed air conditioner 11. Then, the maintenance staff can input the installation information of the failed air conditioner 11 into the data rewriting device 13. Next, the air conditioner data management device 14 responds to the data rewriting device 13 with model information corresponding to the installation information of the air conditioner 11 (S902).

Next, the data rewriting device 13 inquires of the air conditioner data management device 14 about the firmware corresponding to the acquired model information (S903). Next, the air conditioner data management device 14 responds to the data rewriting device 13 with the latest firmware and version number corresponding to the model information (S904).

The data rewriting device 13 may use the storage unit 34 of FIG. 3 and the storage unit 45 of FIG. 4 in order to acquire the firmware from the air conditioner data management device 14. An SD card can be used as the storage unit 34 of FIG. 3 and the storage unit 45 of FIG. At this time, the SD card is attached to the air conditioner data management device 14, and the firmware is written to the SD card. Next, the SD card with the written firmware can be removed from the air conditioner data management device 14, the SD card can be attached to the data rewriting device 13, and the firmware can be written from the SD card to the data rewriting device 13.

Next, the maintenance staff carries the air conditioner maintenance board 12 and the data rewriting device 13 to the installation location of the air conditioner 11. Next, the data rewriting device 13 communicates with the power supply block 21A of the air conditioner 11 (S905). Next, the power supply block 21A of the air conditioner 11 operates by the induced electromotive force of the data rewriting device 13 and responds to the data rewriting device 13 (S906).

Next, the data rewriting device 13 inquires of the power supply block 21A about the ID of the air conditioner board 17 stored in the storage unit 212 of the power supply block 21A (S907). Next, the power supply block 21A returns the ID of the air conditioner board 17 to the data rewriting device 13 (S908).

Next, the data rewriting device 13 inquires of the power supply block 21A about the device information 17B stored in the storage unit 212 (S909). Next, the power supply block 21A responds with the device information 17B to the data rewriting device 13 (S910).

FIG. 13 is a diagram showing a data write sequence to the air conditioner maintenance board of the maintenance system according to the second embodiment.
In FIG. 13, the data rewriting device 13 is communicatively connected to the power supply block 21B of the air conditioner maintenance board 12 (S920). Next, the power supply block 21B of the air conditioner maintenance board 12 operates by the induced electromotive force of the data rewriting device 13 and responds to the data rewriting device 13 (S921).

Next, the data rewriting device 13 inquires of the power supply block 21B about the ID of the air conditioner maintenance board 12 (S922). Next, the power supply block 21B of the air conditioner maintenance board 12 returns the ID of the air conditioner maintenance board 12 to the data rewriting device 13 (S923).

Next, the data rewriting device 13 writes the device information 17B of the air conditioner board 17 acquired in S910 of FIG. 12 as device information 12B in the storage unit of the power supply block 21B of the air conditioner maintenance board 12 (S924). Next, the power supply block 21B responds to the data rewriting device 13 that the device information 12B has been written (S925).

Next, the air conditioner maintenance board 12 is replaced with the air conditioner board 17 of the failed air conditioner 11 and incorporated in the air conditioner 11 to be energized (S926). Next, the air conditioner maintenance board 12 is initially activated (S927). At the time of initial startup, the power supply block 20B reads the device information 12B from the storage unit of the power supply block 21B (S928), and operates according to the device information 12B.

Next, the data rewriting device 13 transmits the firmware 12A acquired in S904 of FIG. 12 to the power supply block 21B of the air conditioner maintenance board 12. The power supply block 21B of the air conditioner maintenance board 12 receives the firmware 12A via the communication unit of the power supply block 21B and transmits it from the control unit of the power supply block 21B to the control unit of the power supply block 20B (S929).

Next, the control unit of the power supply block 20B records the firmware 12A received from the power supply block 21B in the storage unit of the power supply block 20B (S930). Next, the control unit of the power supply block 20B restarts when the reception of the firmware 12A is completed (S931).

After the restart, the control unit of the power supply block 20B updates the device information 12B including the version number of the firmware 12A via the control unit of the power supply block 21B (S932). Next, the data rewriting device 13 inquires the device information 12B stored in the storage unit of the power supply block 21B (S933). Next, the power supply block 21B returns the device information 12B to the data rewriting device 13 (S934).

FIG. 14 is a diagram showing a data write sequence to the air conditioner data management device of the maintenance system according to the second embodiment. Note that the process of FIG. 14 is performed after the board replacement work of the air conditioner 11 by performing the processes of S609, S613, S626, and S642 of FIG.

14, the data rewrite device 13 notifies the air conditioner data management device 14 that the air conditioner having the ID acquired in S908 of FIG. 12 has failed (S950). Next, the air conditioner data management device 14 changes the state of the air conditioner 11 corresponding to the received ID in the air conditioner installation information 442 recorded in the air conditioner data storage unit 44 to a failure state (S951). .. Next, the air conditioner data management device 14 responds to the data rewriting device 13 that the state of the air conditioner 11 has been changed (S952).

Next, the data rewrite device 13 notifies the air conditioner data management device 14 of the device information 17B acquired in S910 of FIG. 12 (S953). Next, the air conditioner data management device 14 updates the device information 17B of the corresponding air conditioner 11 of the air conditioner installation information 442 corresponding to the ID acquired in S950 (S954). Next, the air conditioner data management device 14 responds to the data rewriting device 13 that the device information 17B has been updated (S955).

Next, the data rewrite device 13 notifies the air conditioner data management device 14 that the air conditioning maintenance board 12 having the ID acquired in S923 of FIG. 13 has been replaced (S956). Next, the air conditioner data management device 14 changes the device information of the air conditioner 11 corresponding to the ID of the air conditioner board 17 acquired in S950 to be associated with the ID of the air conditioner maintenance board 12 acquired in S956. (S957). Next, the air conditioner data management device 14 responds to the data rewriting device 13 that the ID binding has been changed (S958).

Next, the data rewrite device 13 notifies the air conditioner data management device 14 of the device information 12B acquired in S934 of FIG. 13 (S959). Next, the air conditioner data management device 14 updates the device information 12B of the corresponding air conditioner 11 of the air conditioner installation information 442 corresponding to the ID of the air conditioner maintenance board 12 acquired in S956 (S960). Next, the air conditioner data management device 14 responds to the data rewriting device 13 that the device information 12B has been updated (S961).

FIG. 15 is a block diagram showing a configuration example of an air conditioner of the maintenance system according to the third embodiment.
The air conditioner 11 of FIG. 15 includes an air conditioner board 117 instead of the air conditioner board 17 of FIG. The air conditioner board 117 includes power supply blocks 20C and 21A. The power supply block 20C has a communication unit 214 added to the power supply block 20A of FIG. The communication unit 214 performs short-range wireless communication such as Bluetooth. The communication unit 213 operates by induced electromotive force using electromagnetic waves, whereas the communication unit 214 operates by electric power supplied from the power source 23. The communication unit 214 is capable of higher speed communication than the communication unit 213.

FIG. 16 is a block diagram showing a configuration example of the data rewriting device of the maintenance system according to the third embodiment.
The data rewriting device 113 of FIG. 16 has a communication unit 37 added to the data rewriting device 13 of FIG. The communication unit 37 performs short-range wireless communication such as Bluetooth. The communication unit 37 is capable of higher speed communication than the communication unit 36.

FIG. 17 is a diagram showing a data write sequence to the air conditioner maintenance board of the maintenance system according to the third embodiment. When reading data from the air conditioner board 117 in FIG. 15, the air conditioner board 117 and the data rewriting device 113 perform the same processing as the processing in FIG. 6. On the other hand, when data is written to the air conditioner maintenance board 112 that is replaced with the air conditioner board 117 of FIG. 15, the air conditioner maintenance board 112 and the data rewriting device 113 perform the processing of FIG. 17 below.

In FIG. 17, the air conditioner maintenance board 112 includes power supply blocks 20D and 21B. The power supply block 20D can be configured similarly to the power supply block 20C of the air conditioner board 117 in FIG.

The power supply block 20D executes the process of S635A instead of S635 of FIG. The power supply block 20D executes the same processes as the power supply block 20B of FIG. 7 except for S635A.

The data rewriting device 13 transmits the firmware 12A acquired in S631 to the power supply block 20D of the air conditioner maintenance board 112 (S635A). Next, the control unit of the power supply block 20D of the air conditioner maintenance board 112 records the firmware 12A received from the data rewriting device 13 in the storage unit of the power supply block 20D (S636).

As described above, the data rewriting device 13 can write the firmware 12A in the power supply block 20D of the air conditioner maintenance board 112 without passing through the power supply block 21B. Therefore, the data rewriting device 13 can speed up the writing of the firmware 12A as compared with the writing method of the firmware 12A of FIG.

In the above-described embodiment, the method for writing data on the board used for the air conditioner has been described as an example, but the method may be applied to the method for writing data on the board used for the water heater, or for other electronic devices. It may be applied to the data writing method of the substrate used.

11 air conditioner, 12 air conditioner maintenance board, 13 data rewriting device, 14 air conditioner data management device, 15 short-range wireless communication, 16 communication network

Claims (12)

A data management device that manages the firmware written on the maintenance board that is replaceable with the electronic board,
A maintenance system comprising a data rewriting device for writing the firmware in the maintenance board and transferring predetermined information held in the electronic board to the maintenance board. The maintenance system according to claim 1, wherein the predetermined information is information regarding a device on which the electronic board is mounted. The maintenance board is
Receiving and storing the information based on power supply from the data rewriting device,
Receiving the firmware based on the power supply from the data rewriting device,
The maintenance system according to claim 2, wherein the firmware is stored based on power supply from the device. The data rewriting device,
Reading the information from the electronic board,
Acquiring the firmware from the data management device based on the information,
The maintenance system according to claim 2, wherein the information and the firmware are written on the maintenance board. The maintenance system according to claim 2, wherein the device is an air conditioner or a water heater. Stores predetermined information held on the replaceable electronic board,
A maintenance board that stores firmware that operates based on the predetermined information. The maintenance board according to claim 6, wherein the predetermined information is information regarding a device on which the electronic board is mounted. Storing the information based on the power supply from the transmitting side of the information,
The maintenance board according to claim 7, wherein the firmware is stored based on power supply from the device. Receiving the firmware based on the power supply from the sender of the information,
The maintenance board according to claim 7, wherein the firmware is stored based on power supply from the device. The maintenance board according to claim 7, wherein the device is an air conditioner or a water heater. A data writing method using a mobile terminal,
The mobile terminal is
Reading predetermined information held on the electronic board from the electronic board,
Writing the predetermined information on a maintenance board that is replaced with the electronic board,
A data writing method for writing firmware operating on the basis of the predetermined information to the maintenance board. The mobile terminal is
Based on power supply from the mobile terminal to the electronic board, the predetermined information is read from the electronic board,
The data writing method according to claim 11, wherein the predetermined information is written on the maintenance board based on power supply from the portable terminal to the maintenance board.

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