JP2004183938A - Hot-water supply system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot-water supply system capable of easily and surely performing the maintenance and inspections of the control device of a device or equipment forming the hot-water supply system. <P>SOLUTION: This hot-water supply system comprises a hot-water supply device 1 and a kitchen remote controller 2 connected to the hot-water supply system so as to be communicated with each other. The device 1 stores product specific information such as a serial number of a product, name of a microcomputer substrate, and stamped name on the microcomputer in an EEPROM 104. The controller 2 stores the product specific information of the remote controller in an EEPROM 206. The device 1 integrates times passed from the start of energization to record a use time. When the controller 2 is connected to the device 1, the device 1 acquires the product specific information of the controller 2 through communications, calculates the connection time thereof when in use, and stores the information together with identification codes in the EEPROM 104. By storing the product specific information including the versions of the device 1 and the controller 2 forming the hot-water supply system, the maintenance and inspections of these microcomputers can be easily and surely performed. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention includes a water heater and optional equipment such as a remote controller and a floor heating device communicably connected to the water heater, and performs predetermined functions by exchanging data between the water heater and the optional equipment. It relates to a hot water supply system.
[0002]
[Prior art]
A hot water supply device is, for example, a facility that supplies hot water by heating water passing through a heat exchanger with heat of a combustor. In recent years, a hot water supply device has been provided with, for example, a remote controller, an instant hot water supply device, a solar heat utilization device, and a floor heating system. Various hot water supply systems using hot water have been commercialized by combining various optional devices that perform predetermined functions when connected to a hot water supply device, such as a panel and a hot water heater. Such a hot water supply system is constructed by combining a desired device and equipment from a variety of hot water supply apparatuses and optional equipment supplied by a user, and therefore, in general, from the viewpoint of system construction easiness, expandability, etc. A hot water supply device and an optional device are communicably connected to each other, and required data is exchanged between a control device (microcomputer) in the hot water device and a control device (microcomputer) in the optional device to construct a software system. It is configured as follows.
[0003]
The hot water supply system is used for a long period of time by replacing some devices or devices of the system or replacing internal components of the devices and devices (for example, circuit components such as sensors and boards on which circuit components are mounted). Therefore, conventionally, a technology for recording a usage history, a repair history, and the like of a hot water supply system has been proposed so that maintenance and inspection work can be performed efficiently and reliably at the time of maintenance or repair.
[0004]
For example, Japanese Patent Application Laid-Open No. Hei 10-213348 discloses that, in addition to storing cumulative data relating to usage history such as the usage time and the number of times of use of main components of a hot water supply apparatus, parts such as a fan motor for hot water supply are used for maintenance. A heating device has been proposed in which when replacement is performed, cumulative data (use time) from the start of use of the replacement part is recorded by an input operation of a maintenance worker, and the cumulative data can be displayed at the time of maintenance or repair. I have.
[0005]
JP-A-8-327061 discloses a data holding system including a gas meter, a gas appliance, and a remote controller, in which the gas meter, the gas appliance, and the remote controller are provided with an EEPROM (Electrically-Erasable and Programmable ROM), respectively. (E.g., integrated gas flow rate for gas meters, control data according to the installation environment for gas appliances, address information for the remote controller, etc.), and communicate with each other at regular intervals to 2. Description of the Related Art Data retention systems that exchange unique information and hold (back up) each other's unique information have been proposed.
[0006]
[Patent Document 1]
JP-A-10-213348
[Patent Document 2]
JP-A-8-327061
[0007]
[Problems to be solved by the invention]
By the way, a hot water supply device and optional equipment for a hot water supply system are manufactured as components for constructing a system by software by exchanging data with each other through communication. Versions may differ due to hardware or software improvements. For this reason, even if the hot water supply systems are configured of the same model, they may be different from each other due to a difference in the version of the control device in terms of software. In addition, by replacing the control device with a different version of the control device by maintenance and inspection, a different hot water supply system may be obtained in terms of software.
[0008]
For example, when replacing a mechanical part such as a combustor for maintenance or repair, it is sufficient to manage the failure history based on the unique information such as the serial number of the combustor. When replacing a component such as a control device or a board on which the control device is mounted, manage the failure history with unique information such as the serial number of the component.If a component with a different version is replaced, that information is not reflected In some cases, the failure history cannot be used effectively.
[0009]
For example, when replacing a board on which a control device is mounted (hereinafter referred to as a microcomputer board) as a countermeasure against failure, if the failure was eliminated by replacing the board with a different version of the microcomputer board, the cause of the failure was due to the contents of the version upgrade. Although it is conceivable, it is impossible to estimate the cause of the failure because the difference between the versions of the microcomputer boards cannot be known from the unique information alone. If the same version of the microcomputer board was replaced in a short period of time, but the failure persists, it can be estimated that the cause of the failure is other than that of the microcomputer board. As a result, the ineffective operation of replacing the board and determining whether the failure can be resolved is repeated.
[0010]
Incidentally, in the technology for recording the use history and the repair history of the hot water supply apparatus described in Japanese Patent Application Laid-Open No. H10-213348, parts are classified by code (classified into components), and the usage time of the parts is classified for each classified part. Is recorded, and only the failure history of the components of the hot water supply device is known, but the failure history (failure cause and use time) specific to the component used for each component is not known. Further, since there is no mention of a component such as a microcomputer board having a different version even if the component specific information is the same, the above-mentioned problem and a technology capable of solving the problem are not suggested.
[0011]
Also, the technology described in Japanese Patent Application Laid-Open No. H8-327061 is a technology for backing up information unique to a device or device between devices or devices constituting a system. Since the information is not included, it does not suggest the above-mentioned problem and the technology that can solve the problem.
[0012]
The present invention has been proposed in view of the above points, and provides a hot water supply system capable of easily and surely performing maintenance and inspection of a control device of a device or a device constituting a hot water supply system.
[0013]
[Means for Solving the Problems]
According to the present invention, a hot water supply device having first storage means for storing product specifying information for specifying a product and a water supply device communicably connected to the hot water supply device, wherein product specifying information for specifying the product are stored. A hot water supply system comprising at least one optional device having a second storage means, and performing a predetermined function by exchanging data between the hot water supply device and the optional device, provided in the hot water supply device. When the optional device is connected, an information obtaining unit that communicates with the optional device at a predetermined timing to obtain product specifying information of the optional device stored in the second storage unit; When the optional device is connected to the hot water supply device, when the optional device is connected to the hot water supply device, the time when the optional device is connected to the hot water supply device is determined based on the start of using the hot water supply device Identifying means, and storage control means provided in the water heater and storing, in the first storage means, product specifying information acquired by the information acquiring means and information on the connection timing identified by the connection timing identifying means. (Claim 1).
[0014]
The product specifying information includes at least information unique to the product and version information of a control unit for controlling the product in general (claim 2). The information unique to the product includes an ID code, And at least one of a product number, and the version information includes at least one of a name capable of identifying the version information of the control board of the unit including the control board and a microcomputer stamped name (claim 3). The optional device includes a remote control device for remotely controlling the hot water supply device.
[0015]
Further, the connection time specifying means includes an integration means for integrating an energization time from the start of use of the water heater, and a connection time based on the energization time accumulated by the integration means when the optional device is connected. May be specified (claim 5). Further, the first and second storage means may be constituted by a nonvolatile memory.
[0016]
Further, according to the present invention, in the hot water supply system according to any one of claims 1 to 6, the hot water supply device communicates with the optional device at a predetermined timing to store information stored in the first storage means. Further, a transfer means for transferring the data to the second storage means of the optional device is further provided. The predetermined timing may be a timing when the power of the water heater is turned off (claim 8).
[0017]
According to the present invention, when an optional device such as a remote control device is connected to the hot water supply device and the hot water supply system is configured, the hot water supply device communicates with the optional device at a predetermined timing and stores the second storage of the optional device. Product identification information for identifying the product of the optional device stored in the means (for example, product specific information such as ID code, manufacturing date and product number, and version information of the control board of a unit having a control board are stored. Acquire an identifiable name and a version name information such as a microcomputer seal name (a name that can identify software version information of the microcomputer). Further, the hot water supply device specifies the time when the optional device is connected based on the start of use of the hot water supply device. For example, the hot water supply device accumulates the energization time from the start of use of the hot water supply device, and specifies the connection time of the optional device in the integrated time. When the water heater and the optional equipment are connected at the same time, the connection time of the optional equipment is at the time when the integrated time is zero, and when the optional equipment is added when the water heater is energized for N hours, the option is added. The connection time of the device is the time point of the integration time N. Then, the hot water supply device stores the product specifying information of the optional device and the information of the connection time in the first storage means.
[0018]
Since the product specific information of the optional equipment and the information on the connection time are stored centrally in the water heater, the information such as the product specific information and the usage time of the optional equipment at the time of maintenance and repair of the trouble is stored in the installation location of the optional equipment. You can easily get from the water heater without going to. Further, even when the control device of the optional device is replaced due to a failure of unknown cause, the control device can be specified by the version information, so that it is possible to easily estimate whether or not the cause of the failure is in the control device. Further, when there is a defect in the control device, it is possible to quickly determine whether or not the control device needs to be replaced by checking the version information at the time of maintenance.
[0019]
Further, according to the present invention, when, for example, the power of the hot water supply device is turned off, communication with the optional device is performed, and the information stored in the first storage device is transferred to the second storage device of the optional device. . That is, backup information of the information stored in the first storage unit of the hot water supply device is stored in the second storage unit. Therefore, when the power of the water heater is turned off due to a failure and the water heater is replaced, the new water heater communicates with the optional device at a predetermined timing and is stored in the second storage means of the optional device. The stored backup information is stored in the first storage means of the hot water supply apparatus, so that the system information stored in the first storage means of the replaced hot water supply apparatus can be easily restored to the first storage means of the new hot water supply apparatus. Can be done.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
A hot water supply system according to the present invention will be described by taking a hot water supply system including a hot water supply device and a bath remote controller as an example.
[0021]
As shown in FIG. 1, the present invention includes a control device including a microcomputer (hereinafter referred to as a microcomputer), and a water heater A whose operation is controlled by the microcomputer m1 includes a microcomputer m2. One or more optional devices B1 to B4 whose operations are controlled by m2 are communicably connected, and the microcomputer m1 of the hot water supply device A and the microcomputer m2 of the optional devices B1 to B4 communicate data with each other to exchange data with each other. The present invention is applied to a hot water supply system that performs a predetermined function by a device, and is not limited to a hot water supply system including a hot water supply device and a bath remote controller.
[0022]
When the hot water supply device has a general hot water supply function and a bath function, the kitchen remote control and the bath remote control are indispensable components for the hot water supply device, but the optional device according to the present embodiment is not essential for the hot water supply device. This includes not only optional devices for adding additional functions but also those which are indispensable components for the water heater such as the above-mentioned bath remote controller and kitchen remote controller.
[0023]
Hot water supply device A may be provided with at least one of a hot water filling function for a bathtub, a reheating function, and a hot water heating function in addition to the general hot water supply function. When water heater A has a combustor as a heat source for generating hot water, the fuel in the combustor may be gas or oil. Further, the heat source of the hot water supply device A may be a combustor, and may be an electric heater or a CO ₂ Various other types of heat sources such as a heat pump may be used.
[0024]
The hot water supply device A includes, for example, a hot water supply device that reheats hot water cooled by a hot water supply pipe to realize instant hot water supply to a hot water tap, a solar heat utilization device that supplies hot water in cooperation with a hot water supply device using solar heat, a floor, Floor heating panel for building a heating system, hot water heater for building an indoor heating system, hot water dryer for building a bathroom drying system, remote control with intercom for expanding intercom function, TV / radio for extending TV / radio viewing function Various optional devices B such as a remote controller with a receiver can be connected.
[0025]
FIG. 2 is a block diagram of a hot water supply system including a hot water supply device and a bath remote controller, which is one embodiment of the hot water supply system according to the present invention.
[0026]
The hot water supply device 1 includes a combustor disposed in a water supply path and a control device for controlling combustion of the combustor, and transmits heat generated in the combustor to water flowing through a water supply pipe to supply hot water having a predetermined temperature. It is supplied to hot water supply places such as kitchens and baths. Hot water supply device 1 is arranged, for example, outside a bathroom in a house.
[0027]
The bath remote controller 2 is provided on the inner wall of the bathroom, and remotely controls the hot water supply operation of the water heater 1 from the bathroom. The hot water supply device 1 and the bath remote controller 2 are connected by a communication line 3 composed of a two-core wire. Driving power (DC power supply) is supplied from the hot water supply device 1 to the bath remote controller 2 via the communication line 3 and the hot water supply device 1 Necessary data is exchanged between the remote controller 2 and the bath remote controller 2. For data communication, for example, an AM modulated wave obtained by AM-modulating a predetermined carrier by an ASK (Amplitude Shift Keying) method (an AM modulated wave in which 0, 1 of digital data is replaced with or without a predetermined carrier) is provided on a communication line. This is performed by superimposing on the supplied DC power supply.
[0028]
Hot water supply apparatus 1 includes control unit 101, communication unit 102, storage unit 103, EEPROM 104, and power supply unit 105. Further, the hot water supply apparatus 1 is provided with sensors such as a water amount sensor 106, a tapping temperature sensor 107, a water level sensor 108, and a frame rod 109 for acquiring data necessary for controlling the hot water supply operation. Actuators such as an electromagnetic valve 110, a gas proportional valve 111, a blower fan 112, and a sparker 113 for controlling the operation are provided.
[0029]
The control unit 101 centrally controls the operation of the entire hot water supply apparatus (data communication and hot water supply operation with a remote controller and other optional devices), and is a central processing unit of a one-chip microcomputer mainly including a ROM and a RAM. It is composed of Control unit 101 controls the operation of the entire hot water supply apparatus by executing a control program stored in the ROM of storage unit 103. The control unit 101 includes an energization time integration unit 101a that integrates the energization time after the hot water supply apparatus 1 is installed in the user's house and the energization is started from the power supply unit 105. Each time the main power supply is repeatedly turned on / off, the power-on time integration unit 101a integrates the power-on time from the on to off, and adds the integrated value to the integrated value of the previous power-on time to thereby supply power from the start of power supply. Integrate the time. This energization time is stored in the EEPROM 104.
[0030]
As a method of integrating the energization time, the integration time may be renewedly recorded in the EEPROM 104 at predetermined time intervals during energization. This method has an advantage that the power supply does not require a cutoff detection circuit.
[0031]
The communication unit 102 controls data communication with the bath remote controller 2. The communication unit 102 includes a carrier generation circuit that generates a predetermined carrier, a modulation circuit that AM-modulates the carrier with the data input from the control unit 101 by the ASK method, and superimposes the AM modulation wave on a DC power supply input from the power supply unit 105. Further, it has an output circuit for outputting to the bath remote controller 2 via the communication line 3 and a demodulation circuit for demodulating data from the AM modulated wave transmitted from the bath remote controller 2 via the communication line 3.
[0032]
The storage unit 103 stores data necessary for the control operation of the control unit 101. The storage unit 103 is composed of a RAM and a ROM of a one-chip microcomputer, and the ROM stores a control program of the control unit 101 and default data necessary for executing the control program. The RAM provides a work area for the control unit 101 to execute the control program, and temporarily stores the control program read from the ROM and various data generated by executing the control program. .
[0033]
The EEPROM 104 is a non-volatile memory that stores information for specifying a product of the hot water supply device 1, information on a product use time (power-on time), a repair history, and the like. More specifically, information for specifying a product of the hot water supply device 1 and a microcomputer mounted on the hot water supply device 1 (hereinafter, referred to as product specifying information) is stored in the EEPROM 104 by the power supply time integration unit 101a. The information on the history of repairs such as the current supply time (time actually used) of the hot water supply apparatus 1 and the replacement of a microcomputer or a board on which the microcomputer is mounted (hereinafter referred to as a microcomputer board) is stored.
[0034]
In the present embodiment, when a component (load) in each connected device in the hot water supply system is repaired or replaced, the code number of the repaired or replaced component is manually input by a maintenance worker from an operation unit of a remote controller. Then, when the microcomputer board of each connected device in the hot water supply system is replaced, the repair history information stored in the EEPROM 104 of the old microcomputer board is automatically transferred to the EEPROM 104 of the new microcomputer board and stored therein by communication. The repair history information referred to here includes repair information manually input by a maintenance worker during such repair work and repair information carried over when the microcomputer board is replaced.
[0035]
The product specifying information includes product-specific information of the hot water supply device 1 and version information of a microcomputer that controls and controls the product. The product-specific information is, for example, the ID code (such as the product serial number) of the hot water supply device 1 and the date of manufacture. The version information includes the name of a unit having a control board (microcomputer board) mounted on the hot water supply device 1 (hereinafter referred to as a relay case set name), the name of a microcomputer stamp (the software of the microcomputer mounted on the microcomputer board). Information that can be specified up to the version). The product specifying information can specify when and what model the hot water supply device 1 was manufactured, and which version of the control software operates. Therefore, even when a repair is performed in which the microcomputer board is replaced with a microcomputer board of a different version, the history of the repair contents can be known.
[0036]
Further, as will be described later, the bath remote controller 2 also stores the product specifying information of the bath remote controller 2 and the information such as the use time and the repair history, so that the bath remote controller 2 is connected to the hot water supply device 1, and When constructed, the hot water supply apparatus 1 acquires the product specifying information of the bath remote controller 2 through communication with the bath remote controller 2 and stores the information in the EEPROM 104. Water heater 1 also specifies the time at which bath remote controller 2 is connected, based on the power-on time of water heater 1, and stores information on the connection time and information on the usage time of bath remote controller 2 in EEPROM 104. Further, when the bath remote controller 2 is repaired, information on the repair history is also stored in the EEPROM 104.
[0037]
When the bath remote controller 2 is replaced, the new bath remote controller 2 is connected to the hot water supply device 1, and the information stored in the EEPROM 206 from the new bath remote control 2 is transferred to the hot water supply device 1 and stored in the EEPROM 104. The transfer time may be used as repair history information at the time of repair.
[0038]
When the hot water supply device 1 and the bath remote controller 2 are installed at the same time, for example, the energization time of the hot water supply device 1 is 0 hour. If the bath remote controller 2 is replaced when the first power supply time is 500 hours, the use time 500 becomes information on the connection timing of the bath remote controller 2.
[0039]
As described above, the hot water supply system according to the present embodiment collectively stores the product identification information, the usage time, and the repair history information of the hot water supply device main body and the optional equipment included in the hot water supply system in the EEPROM 104 of the hot water supply device 1. For example, an identification code as shown in FIG. 3 is attached to the main body and various optional devices, and product identification information (ID code, date of manufacture, (Relay case set name, microcomputer seal name, etc.), usage time, and repair history information are stored.
[0040]
In FIG. 3, “XX intercom” is a remote controller installed in XX having an intercom function. The “XX heart rate remote controller” is a XX remote controller having a function of measuring and displaying the heart rate of a bather during bathing. “XX TV remote control” is a remote control installed in XX having a TV reception function. Although not shown in FIG. 3, other optional devices such as a hot water supply device, a solar heat utilization device, a floor heating panel, a hot water heater, and a bathroom dryer are also provided with identification codes.
[0041]
4A shows information stored in the EEPROM 104 when the product of the water heater 1 is shipped, and FIG. 4B shows the information stored in the EEPROM 104 after the bath remote controller 2 is connected to the water heater 1 and the water heater system is configured. 4 shows stored information.
[0042]
The storage area of the EEPROM 104 is divided into a plurality of areas A1, A2,..., And an ID code (manufacturing number, etc.), manufacturing date, relay case set name and microcomputer Product identification information including a seal name is stored. When the hot water supply system is configured, the product identification information including the ID code (serial number) of the bath remote controller 2, the date of manufacture, the name of the relay case set, and the name of the microcomputer seal is stored in the second storage area A2 as the identification code "11". Is stored together with. In each storage area, storage areas B1 and B2 are provided below the storage area of the product specifying information, and information such as usage time and failure history is stored in these storage areas B1 and B2. When an optional device is newly connected, product specifying information of the optional device is sequentially stored in the second storage area and thereafter in the same manner as in the second storage area A2.
[0043]
Storing product identification information, usage time, and repair history information in the memory in the hot water supply system in this way enables efficient and reliable failure diagnosis and repair during maintenance and repair of the hot water supply system. To do that. That is, by confirming the stored contents, (1) determining whether or not the optional equipment including the hot water supply device 1 has been replaced, (2) when the optional equipment has been replaced, specifying the replacement time, and (3) hot water supply. Confirmation of replacement history of device 1 and optional equipment, (4) Confirmation of connection history of each control unit and connection of each microcomputer software version (combination history at each time) in the entire hot water supply system, and (5) Confirmation of overall hot water supply system When each control unit is replaced, it is possible to specify the replacement time and (6) the connection time of the newly added optional equipment, etc. This is because an appropriate version of the microcomputer board can be easily determined.
[0044]
For example, when a malfunction occurs after the optional equipment is newly installed in the hot water supply system, it can be easily estimated that the cause of the malfunction is the newly installed optional equipment. Also, by checking the replacement history, if the failure has not been resolved even though it has been replaced with the same version of the microcomputer board or a different version of the microcomputer board since the failure occurred, the cause of the failure is the microcomputer board. It can be estimated that it is in a part other than the above, and appropriate failure diagnosis can be performed. Information such as a replacement history and a repair history is displayed on the display unit 204 of the remote control device 2 so that a service person can confirm the information.
[0045]
In addition, the reason why the EEPROM 104 of the hot water supply device 1 collectively stores all the product identification information, the usage time, and the repair history information of the elements constituting the hot water supply system is that the repair is performed by replacing the microcomputer board of the hot water supply device 1. In this case, the management of such information is facilitated by collectively transferring information such as product identification information and repair history of the entire hot water supply system to the microcomputer board after replacement.
[0046]
In addition, in a hot water supply system, optional equipment is often provided at a location distant from the hot water supply device (indoors and outdoors, and a place where a plurality of rooms are dispersed even indoors). It is often performed at the location of the hot water supply device 1. Usually, a service person connects a personal computer for maintenance, a remote control, or a dedicated failure diagnosis device or the like to the hot water supply device 1 by communication and stores the product stored in the EEPROM 104 of the hot water supply device 1. Information such as specific information and repair history is read out and displayed on the display unit to check the contents.By centrally managing information such as product specific information and repair history of the entire hot water supply system, This is because there is an effect that the labor for collecting such information can be reduced.
[0047]
The power supply unit 105 includes, for example, a switching power supply, and generates a drive power supply (DC voltage power supply) for each circuit in the water heater 1 and each circuit in the bath remote controller 2 from, for example, an AC power supply of 100 V.
[0048]
The water amount sensor 106 is a sensor that detects the amount of water flowing into the heat exchanger. Hot water temperature sensor 107 is a sensor that detects the temperature of hot water flowing out of the heat exchanger. The water level sensor 108 is a sensor that detects the water level in the bathtub. In the present embodiment, the water level sensor 108 detects the water level of the bathtub because the hot water supply apparatus 1 has a bath function. For example, when the hot water supply apparatus 1 has a hot water heating function, the water level sensor 108 A sensor 108 detects the water level in the heating hot water tank. The frame rod 109 detects ignition or misfire of the gas burner. The detection signals output from these sensors are input to the control unit 101.
[0049]
The solenoid valve 110 and the gas proportional valve 111 are valves that control the amount of gas supplied to the combustor that generates heat to be transmitted to the heat exchanger. The blower fan 112 is a blower that controls the amount of air supplied to the combustor. The sparker 113 ignites a gas burner of the combustor. The operation of the solenoid valves 110 to 110 is controlled by the control unit 101.
[0050]
The hot water supply operation in the hot water supply apparatus 1 will be briefly described. When a user opens a hot water tap (not shown), the water supply amount is detected by a water amount sensor 106, and the control unit 101 opens the hot water tap according to the detection signal. The combustion operation of the combustor is started when the plug is recognized and the flow rate is detected to be equal to or more than the predetermined flow rate. That is, the control unit 101 opens the electromagnetic valve 110 and sets the gas proportional valve 111 to a predetermined opening to supply gas to the burner of the combustor, while driving the blower fan 112 to supply air to the combustion chamber. Then, the burner is ignited by the sparker 113 to start combustion.
[0051]
The water that has flowed into the heat exchanger is heated by the combustion of the combustor, turned into hot water, and flows out to the hot water tap. The temperature of hot water flowing out of the heat exchanger is detected by hot water temperature sensor 107, and a detection signal is input to control section 101. The control unit 101 controls the combustion of the combustor based on the hot water supply temperature set by the user and the hot water temperature sensor 107, and keeps the temperature at which hot water is discharged from the hot water tap at the set temperature.
[0052]
Next, the bath remote controller 2 includes a control unit 201, a communication unit 202, an operation unit 203, a display unit 204, a storage unit 205, and an EEPROM 206. The control unit 201 centrally controls the operation of the entire remote controller (data communication between the water heaters, display operation, and the like), and is mainly configured by a microcomputer. The control unit 201 controls the operation of the entire remote controller by executing a control program stored in the ROM of the storage unit 205.
[0053]
The operation unit 203 is mainly for inputting operation information of remote control for the water heater 1. The operation unit 203 converts operation buttons such as operation on / off, hot water supply temperature, setting of bath water temperature and bath water level, setting of automatic bath operation mode, and operation of these operation buttons into electric signals, and converts the operation into electric signals. The switch to be input to is mainly used. The operation buttons are provided on an operation panel of the bath remote controller 2.
[0054]
The display unit 204 displays information such as the operation content of the operation unit 203 and the operation state of the water heater 1. The display unit 204 includes, for example, a liquid crystal display or a fluorescent display tube, and is provided on an operation panel of the bath remote controller 2 like the operation buttons.
[0055]
FIG. 5 is a diagram illustrating an example of an operation panel of the bath remote controller 2. The operation panel 4 has a horizontally long rectangular shape, and an operation button 401 for operating on / off is provided at a right end portion, and a liquid crystal display 402 indicating a hot water supply temperature and a bath temperature is provided at a central portion. Operation buttons 403a and 403b for setting a hot water supply temperature, a bath temperature, and the like are provided on the right side of the liquid crystal display 402, and an automatic bath operation mode (bath temperature and water temperature set at the bottom of the liquid crystal display 402). And an operation button 405 for instructing a follow-up operation.
[0056]
The operation button 403a is an operation button for increasing the hot water supply temperature, bath temperature setting value, and the like. For example, in the case of hot water temperature setting, each time the operation button 403a is pressed, the set value of the hot water temperature rises by one degree. On the other hand, the operation button 403b is an operation button for lowering the set values of the hot water supply temperature, the bath temperature, and the like. For example, in the case of setting the hot water supply temperature, the set value of the hot water supply temperature decreases by one degree each time the operation button 403b is pressed. When the operation buttons 403a and 403b are kept pressed for a predetermined time or more, the set value of the hot water supply temperature can be continuously increased or decreased by one degree at a predetermined pitch in a predetermined temperature range.
[0057]
The operation button 401 is an operation button that alternately switches between operation ON and operation OFF each time the button is pressed. The on / off state of the operation button 401 can be determined by turning on and off the liquid crystal display 402. That is, when the operation is turned on, the hot water supply temperature and the bath temperature are displayed on the liquid crystal display 402, and when the operation is turned off, the display is not displayed. The bath automatic button 404 is an operation button that alternately switches on and off the automatic operation mode each time the button is pressed. When the bath automatic button 404 is turned on, the LED 404a at the top of the button turns on, so that the on state can be recognized. Further, when the chasing button 405 is turned on, the LED 405a at the top of the button 405 is lit, so that the on state can be recognized.
[0058]
Returning to FIG. 2, the storage unit 205 stores data necessary for the control operation of the control unit 201. The storage unit 205 includes a RAM and a ROM, and the ROM stores a control program of the control unit 205, default data necessary for executing the control program, and the like. The RAM provides a work area for the control unit 201 to execute the control program, and the control program read from the ROM and various data generated by executing the control program (set hot water supply temperature). Etc.) temporarily.
[0059]
Communication section 202 controls data communication with hot water supply apparatus 1. The communication unit 202 includes a carrier generation circuit that generates a predetermined carrier, a modulation circuit that modulates a carrier using digital data input from the control unit 202 by the ASK method, and an AM modulation wave to the water heater 1 via the communication line 3. It has an output circuit for outputting, a power supply separation circuit for separating the drive power from the AM modulation wave transmitted from the water heater 1 via the communication line 3, a demodulation circuit for demodulating data from the AM modulation wave, and the like.
[0060]
The EEPROM 206 is a non-volatile memory that stores product identification information (ID code, manufacturing date, relay case set name, microcomputer seal name) of the bath remote controller 2. When the main power supply of the hot water supply device 1 is turned off, the power supply may be turned off in order to replace the microcomputer board of the hot water supply device 1. Therefore, the data of the EEPROM 104 is not lost from the hot water supply system. The data is transferred to the bath remote controller 2 by communication and temporarily saved in the EEPROM 206. The storage contents of the data in the EEPROM 206 at this time are the same as the storage contents shown in FIG.
[0061]
Next, information management such as product identification information of the hot water supply system in the hot water supply apparatus 1 will be described with reference to FIGS.
[0062]
6 and 7 are flowcharts showing a processing procedure of information management such as product identification information of the hot water supply system of the hot water supply apparatus 1. The flowchart shows a processing procedure from when the hot water supply device 1 is installed, the power is turned on, and the power supply is started to when the power supply is turned off and the power supply is stopped. FIG. 8 is a diagram showing an example of the timing at which the microcomputer boards (controllers) of the water heater 1 and the bath remote controller 2 are replaced.
[0063]
When the hot water supply device 1 is installed and the power is turned on (see timing A in FIG. 8), timing of the energization time is started (S1). Subsequently, the connection state of the optional device is confirmed (S2). This confirmation is performed by performing data communication with each connection terminal and confirming the presence or absence of a response signal. In this embodiment, since only the bath remote controller 2 is connected, the connection of the bath remote controller 2 is confirmed by a response signal from the bath remote controller 2.
[0064]
Subsequently, a request signal for product identification information of the optional device is transmitted from the hot water supply device 1 to the optional device whose connection has been confirmed (S3). In the present embodiment, a request signal for product identification information is transmitted from water heater 1 to bath remote controller 2. When the product specifying information is transmitted from the optional device in response to the transmission request (S4: YES), the connection time Ta of the optional device is calculated based on the integrated value of the energizing time of the hot water supply device 1, and the optional device is connected. Is calculated (S5, S6). In the present embodiment, as shown in FIG. 8, the bath remote controller 2 is first connected to the hot water supply device 1 to install the hot water supply system. Therefore, the connection timing Ta of the bath remote controller 2 that is an optional device is “0”. .
[0065]
The use time Tdo of the bath remote controller 2 is calculated by subtracting the integrated value Ta of the energizing time indicating the connection time from the integrated value Tc of the current energizing time. Since Ta = Tc at the time of connection, the use time Tdo becomes “0” (Tdo = Tc−Ta). Then, the product specifying information of the bath remote controller 2 and the information of the connection time and the use time acquired by the communication are stored in the EEPROM 104 (S7). Subsequently, it is determined whether or not the storage processing of the product specifying information or the like has been completed for all the optional devices (S8), and if not completed (S8: NO), the process returns to step S3, and the product returns to the next optional device. Acquisition of specific information, calculation of connection time and use time, and storage processing of these information in the EEPROM 104 are performed (S3 to S7). Then, when the storage processing of the product specifying information or the like is completed for all the optional devices (S8: YES), the process proceeds to step S9. In the present embodiment, since the only option device is the bath remote controller 2, the process proceeds to step S9 without returning to step S3.
[0066]
In step S9, the timer for periodically checking the connection state of the optional device is started to measure a predetermined time t. When the predetermined time t has elapsed (S10: YES), the optional device for which connection has been confirmed is sent to the optional device. Then, a request signal for product specification information of the option device is transmitted (S11). When the product specifying information is transmitted from the optional device in response to the transmission request (S12: YES), the use time Tdo of the optional device is calculated based on the integrated value Tc of the energizing time of the hot water supply device 1 (S13). The calculation result is rewritten with the calculated usage time Tdo of the usage time Td of the optional device stored in the EEPROM 104 (S14). That is, the use time Tdo of the optional device is updated. Note that the usage time is calculated by subtracting the integrated value Ta of the energization time indicating the connection time (this data is stored in the EEPROM 104) from the integrated value Tc of the current energization time.
[0067]
On the other hand, if there is no response to the transmission request for the product specifying information within the predetermined time (S12: NO), it is determined that the connection of the optional device has been released, and the process skips steps S13 and S14 and proceeds to step S15. . As a result, when the option device is replaced, the product identification information from the connection to the disconnection of the product before replacement, the connection time, and the usage time information are recorded in the EEPROM 104.
[0068]
Subsequently, it is determined whether or not the storage processing of the product specifying information or the like has been completed for all the optional devices (S15). If not (S15: NO), the process returns to step S11 to use the next optional device. The time is calculated and the process of storing the time in the EEPROM 104 is performed (S11 to S14). Then, when the use time updating process is completed for all the optional devices (S15: YES), the process proceeds to step S16. In the present embodiment, since the only option device is the bath remote controller 2, the process proceeds to step S16 without returning to step S11.
[0069]
When the process proceeds to step S16, it is confirmed whether or not an optional device is newly connected (S16). If an optional device is newly connected (S16: YES), a request signal for product specifying information of the optional device is transmitted to the optional device (S17). When the product specifying information is transmitted from the optional device in response to the transmission request (S18: YES), the connection time Ta of the optional device is calculated based on the integrated value Tc of the energizing time of the hot water supply device 1, and the option time is calculated. The device usage time Tdo is calculated (S19, S20). Then, the product specifying information, connection time, and usage time information of the additional optional device acquired by the communication are additionally stored in the EEPROM 104 (S21).
[0070]
Subsequently, it is determined whether or not the reception processing of the product identification information or the like has been completed for all the added optional devices (S22). If not completed (S22: NO), the process returns to step S17, and the next addition is performed. Acquisition of product identification information, calculation of connection time and use time, and additional storage processing of such information in the EEPROM 104 are performed for the optional device (S17 to S21). Then, when the storage processing of the product specifying information or the like is completed for all the added optional devices (S22: YES), the process proceeds to step S23, and it is confirmed whether or not the power is turned off. If it is determined in step S16 that the optional device is not newly connected (S16: NO), the process proceeds to step S23, and it is determined whether the power has been turned off.
[0071]
If the power has not been turned off in step S23 (S23: NO), the process returns to step S9 to determine whether or not the connection state of the connected optional device is continued. The process of updating the usage time of the device and the process of confirming the additional connection of the optional device are repeated at a predetermined cycle (loop of S9 to S23).
[0072]
If the power has been turned off in step S23 (S23: YES), integrated value Tc of the energization time of water heater 1 is calculated and stored in EEPROM 104 (S24). Subsequently, after the data stored in the EEPROM 104 is transmitted to a predetermined optional device by communication and stored in the EEPROM 206 of the optional device (S25), a predetermined power-off process is performed (S26), and an information management process is performed. To end. In the process of step S25, since the power supply may be turned off in order to replace the microcomputer board by the water heater 1 for repair, the data stored in the EEPROM 104 can be stored in the EEPROM of the replaced microcomputer board. Then, it is temporarily evacuated.
[0073]
The contents of the processing procedure of FIGS. 6 and 7 will be described by taking as an example the timing at which the microcomputer boards (controllers) of the water heater 1 and the bath remote controller 2 shown in FIG. 8 are replaced. 2 is installed, and when the power of the hot water supply device 1 is turned on, first, the timing of the energization time of the hot water supply device 1 is started, and the connection of the bath remote controller 2 is confirmed. Subsequently, the product specifying information of the bath remote controller 2 is transferred from the bath remote controller 2 to the hot water supply device 1 by communication, and stored in the EEPROM 104 in the hot water supply device 1. Further, information on the connection time and usage time of the bath remote controller 2 is calculated and stored in the EEPROM 104 together with the product specifying information.
[0074]
Thereafter, the hot-water supply apparatus 1 periodically checks the connection state of the bath remote controller 2, and every time it is confirmed, determines the power-on time Tdo from the power-on time Tc at that time and the power-on time Ta indicating the connection time stored in the EEPROM 104. The calculated time Tdo is stored in the EEPROM 104 in an updated manner. Hot water supply device 1 also determines whether an optional device has been added. In the example of FIG. 8, since there is no addition of optional equipment, the processing of checking the connection of the bath remote controller 2 and updating the use time Tdo is continued until the timing B.
[0075]
Then, at the timing B, when the connection between the water heater 1 and the bath remote controller 2 is released in order to replace the components including the microcomputer board of the bath remote controller 2 or the entirety due to a failure, the water heater 1 starts the regular bath operation. Since the disconnection state of the bath remote controller 2 can be known by confirming the connection of the remote controller 2, the process of updating the usage time of the bath remote controller 2 is stopped, and the product identification information, connection time, and usage of the bath remote controller 2 before replacement are stored in the EEPROM 104. Time information will be saved. In addition, the hot water supply device 1 checks the connection of the bath remote controller 2 ′ after the replacement, and when the bath remote controller 2 ′ is connected, obtains the product specifying information on the new bath remote controller 2 ′, and at the same time, the connection time and usage time. Is calculated and additionally stored in the EEPROM 104. As a result, the replacement history of the bath remote controller 2 is recorded in the EEPROM 104. Then, the bath remote controller 2 'after the replacement is also subjected to the process of periodically confirming the connection and updating the usage time similarly to the bath remote controller 2 before the replacement.
[0076]
Thereafter, at time C, when the power of the water heater 1 is turned off in order to replace parts or the whole including the microcomputer board of the water heater 1 due to a failure, the product identification information stored in the EEPROM 104 of the water heater 1 Is transferred to the bath remote controller 2 ′ and stored in the EEPROM 206. When the repaired hot water supply device 1 'is connected to the bath remote control 2' and the power of the hot water supply device 1 'is turned on, the flow of FIGS. 6 and 7 is executed, so that the hot water supply device 1' is newly energized. Time measurement is started, and the data stored in the EEPROM 206 is transferred from the bath remote controller 2 'to the EEPROM 104 of the water heater 1'.
[0077]
Therefore, the product specifying information of the hot water supply device and the bath remote controller, the connection time, the use time, and the information of the failure history are taken over by the hot water supply device of the hot water supply system and recorded. Note that the failure history may include an error code (data for identifying the content of an abnormality stored in each EEPROM when an abnormality is detected), in addition to the exchange history of each microcomputer board.
[0078]
If the hot water supply unit 1 is replaced, data relating to the life of the hot water supply unit 1 (such as the cumulative number of times of burning, the cumulative burning time, and the cumulative energizing time of the hot water supply unit) are not inherited and become zero. The data on product identification information and connection time of each device is carried over. When only the microcomputer board of the water heater 1 is replaced, the data on the life of the water heater 1 stored in the EEPROM 104 of the old microcomputer board is transferred to the EEPROM 104 'of the new microcomputer board as described above.
[0079]
When the microcomputer of the water heater 1 is reset, it is determined whether or not the connected optional device is changed during the power reset according to the flowchart shown in FIG. 9. New recording of the product specifying information and the like is performed for the changed optional device.
[0080]
That is, when the control unit 101 of the water heater 1 is activated after the power supply is reset, a request signal for the product specifying information of the optional device is sent to the optional device corresponding to the product specifying information stored in the EEPROM 104. Is transmitted (S30). When the product specifying information is transmitted from the optional device in response to the transmission request (S31: YES), the received device specifying information is compared with the product specifying information stored in the EEPROM 104, and the optional device (particularly, the microcomputer board) is compared. It is determined whether or not it has been replaced (S32).
[0081]
If the optional device (especially the microcomputer board) has not been replaced (S33: NO), the process immediately returns. If the optional device (especially the microcomputer board) has been replaced (S33: YES), the new product identification information received. Is additionally stored in the EEPROM 104 with an identification code. At this time, the integrated value Tc of the current energization time stored in the EEPROM 104 is recorded as the connection time, the usage time is calculated again on the basis of the power reset, the calculation result is recorded (S34), and the process returns. .
[0082]
In the above-described embodiment, when performing repair for replacing the microcomputer board of the hot water supply apparatus 1, information stored in the EEPROM 104 mounted on the replaced microcomputer board is temporarily stored in a predetermined optional device (in this embodiment, the bath remote controller 2). 3) When the new microcomputer board is mounted on the water heater 1, the information saved from the optional device is transferred to the EEPROM 206 and stored in the EEPROM 104 'mounted on the new microcomputer board. A new microcomputer board for replacement is connected to the hot water supply device 1 via a communication line (two-core wire), and communication is performed between the microcomputer mounted on the new microcomputer board and the microcomputer mounted on the replaced microcomputer board. The information stored in the EEPROM 104 mounted on the microcomputer board to be replaced The data may be stored in the EEPROM 104 'mounted on a new microcomputer board.
[0083]
That is, as shown in the flowchart of FIG. 10, when a replacement microcomputer board is connected to the hot water supply apparatus 1 via the communication line 3, the microcomputer mounted on the microcomputer board (hereinafter referred to as a new microcomputer board). The control unit 101 ′ communicates with the control unit 101 of the microcomputer mounted on the microcomputer of the microcomputer board to be replaced (hereinafter referred to as an old microcomputer board) mounted on the hot water supply apparatus 1, and performs the communication between both microcomputer boards. Is confirmed (S40).
[0084]
When the connection between the two microcomputer boards is confirmed (S40: YES), the control unit 101 'of the new microcomputer board requests the control unit 101 of the old microcomputer board to transfer the information stored in the EEPROM 104 (S41). Each time information stored in the EEPROM 104 is transmitted from the control unit 101 of the microcomputer board, the information is sequentially stored in the EEPROM 104 'of the new microcomputer board (loop of S42 to S44).
[0085]
Each time the information stored in the EEPROM 104 is transmitted from the control unit 101 of the old microcomputer board, the information is sequentially stored in the EEPROM 104 'of the new microcomputer board. When the transfer of all information is completed (S44: YES), Is completed.
[0086]
FIG. 11 is a diagram showing an example of data stored in the EEPROM 104 'of the new microcomputer board.
[0087]
As shown in the figure, the storage area A1 at the head of the EEPROM 104 'stores product identification information (ID code, manufacturing date, relay case set name, main stamp name) of the new microcomputer board, usage time Tc, and other history information. Is stored. The product identification information of the microcomputer board transferred from the old microcomputer board, the accumulated energization time Tc, and other history information are stored in a storage area A1 ′ below the storage area A1, and the product identification of optional equipment such as the bath remote controller 2 is performed. The information, the usage time Tdo, and other history information are stored in the storage area A2 below the storage area A1 '.
[0088]
After the replacement of the microcomputer board, the integrated value of the energizing time Tc stored in the area B1 'in the storage area A1' is not updated, and the integrated value of the energizing time Tc stored in the area B1 in the storage area A1 is updated. You. Since the integrated value of the energization time Tc stored in the area B1 'is not updated, it is possible to know the replacement time of the old microcomputer board from the energization time Tc. When the microcomputer board is further replaced, the storage area of the EEPROM 104 "of the new microcomputer board is added to the storage areas A1 and A1 'relating to the hot water supply device 1, and the information relating to the latest microcomputer board is stored in the storage area A1. , The information on the second microcomputer board is stored in the storage area A1 ', and the information on the first microcomputer board is stored in the storage area A1 ". Information about the microcomputer board is stored.
[0089]
The usage time of the replaced old microcomputer board of the hot water supply device 1 can be calculated using the energization time Tc stored in the areas B1 ′ and B1 ″ of the storage areas A1 ′ and A1 ″. That is, when the microcomputer board replaced twice before is the first mounted microcomputer board, the integrated value of the energization time Tc stored in the area B1 ″ of the storage area A1 ″ becomes the usage time, and the usage time of the microcomputer board replaced last time is used. The time is calculated from the integrated value of the energizing time Tc stored in the area B1 'of the storage area A1' to the integrated value of the energizing time Tc stored in the area B1 "of the storage area A1" (the use time of the microcomputer board of the last two-time replacement). Is calculated by subtracting Note that the usage time calculated in this manner may be stored in the areas B1 ′ and B1 ″.
[0090]
According to this method, there is no need to provide a save area for information in the EEPROM 206 of the optional device, so that there is an advantage that the EEPROM 206 can be reduced in size and cost.
[0091]
As described above, the hot water supply system including the hot water supply device 1 and the bath remote controller 2 according to the present embodiment provides a product including the information for specifying the products of the hot water supply device 1 and the bath remote controller 2 and the information for specifying the version of the microcomputer board. The specific information is stored, and when the hot water supply system is configured, the product specific information of the bath remote control 2 is stored in the EEPROM 104 of the hot water supply device 1 collectively. Even when a repair is performed such that the microcomputer board is replaced due to a failure, the repair history can be preferably left.
[0092]
In addition, even in the case of performing repair for replacing a microcomputer board due to an unknown problem, the inconvenience of replacing a microcomputer board of the same version many times can be avoided based on the version information. If the defective version is known, the countermeasure can be taken promptly by checking the version of the microcomputer board of the failed device or device.
[0093]
Further, since the product specifying information of the apparatus and the equipment constituting the hot water supply system can be acquired at the position of the hot water supply apparatus 1, the labor for maintenance work and trouble repair is reduced, and the work efficiency is improved.
[0094]
When the microcomputer board or the like of the water heater 1 is replaced, the data stored in the EEPROM 104 of the water heater 1 is temporarily evacuated to the EEPROM 206 of the bath remote controller 2, and the data is saved to the EEPROM 104 of the microcomputer board of the water heater 1 after the replacement. Since the data is restored, the change history information is saved for all of the changed configurations from the first configuration of the hot water supply system to the subsequent configuration, and the product identification information and the history information can be used effectively.
[0095]
In the above embodiment, when the power of the water heater 1 is turned off, the data of the EEPROM 104 is temporarily saved in the EEPROM 206 of the bath remote controller 2. However, for example, when a failure is detected in the water heater 1 or the like. Alternatively, the data in the EEPROM 104 may be temporarily saved in the EEPROM 206 of the bath remote controller 2 at a predetermined timing when the microcomputer board may be replaced.
[0096]
Further, the hot water supply device of the hot water supply system according to the present invention may be a single-function hot water device having a function of filling a bath tub, a function of reheating a bath, and a function of heating with hot water, in addition to a single-function hot water supply device.
[0097]
【The invention's effect】
As described above, according to the first to sixth aspects of the invention, the product specifying information for specifying the product is stored in each of the hot water supply device and the optional device, and the optional device is connected to the hot water supply device. And the water heater obtains the product specifying information of the optional device from the optional device by communication, specifies the connection time of the optional device to the water heater, and stores the product specifying information and the information of the connecting time. Therefore, at the time of maintenance or repair, information such as the product identification information of the optional device and the use period can be easily obtained from the water heater without going to the installation position of the optional device. Further, even when the control device of the optional device is replaced due to a failure of unknown cause, the control device can be specified by the version information, so that it is possible to easily estimate whether or not the cause of the failure is in the control device. Further, when there is a defect in the control device, it is possible to quickly determine whether or not the control device needs to be replaced by checking the version information at the time of maintenance.
[0098]
According to the seventh and eighth aspects of the invention, when the hot water supply device is turned off, for example, the hot water supply device communicates with the optional device to transmit the information stored in the first storage means. Since the backup is transferred to the second storage means of the optional device and the backup is made, even if the hot water supply device is replaced, the new hot water supply device can easily recover the system information by acquiring the backup information from the optional device. Can be done.
[Brief description of the drawings]
FIG. 1 is a diagram showing a basic configuration example of a hot water supply system to which the present invention is applied.
FIG. 2 is a block diagram of a hot water supply system including a hot water supply device and a bath remote controller, which is one embodiment of the hot water supply system according to the present invention.
FIG. 3 is a diagram illustrating an example of an identification code.
FIG. 4 is a diagram showing an example of data stored in an EEPROM.
FIG. 5 is a diagram showing an example of an operation panel of a bath remote controller.
FIG. 6 is a flowchart showing a processing procedure of information management such as product identification information of a hot water supply system of the hot water supply apparatus.
FIG. 7 is a flowchart showing a processing procedure of information management such as product identification information of a hot water supply system of the hot water supply apparatus.
FIG. 8 is a diagram showing an example of a timing at which the microcomputer boards (controllers) of the water heater and the bath remote controller are respectively exchanged.
FIG. 9 is a flowchart showing a processing procedure of information management such as product identification information of the hot water supply system when the microcomputer of the water heater is reset.
FIG. 10 is a flowchart showing a processing procedure for transferring information stored in an EEPROM between microcomputer boards.
FIG. 11 is a diagram illustrating an example of data such as product identification information of a hot water supply system stored in an EEPROM of the replaced microcomputer board when the microcomputer board of the water heater is replaced.
[Explanation of symbols]
1 Hot water supply device
101 control unit (information acquisition means, connection time specifying means, storage control means, transfer means)
101a energization time integration section (integration means)
102 communication unit (information acquisition means)
103 storage unit
104 EEPROM (first storage means)
105 Power supply unit
2 bath remote control
201 control unit
202 Communication unit
203 Operation unit
204 Display
205 storage unit
206 EEPROM (second storage means)
3 Communication line (double core line)
4 Operation panel
401 operation button
402 liquid crystal display
403a, 403b Temperature and other setting buttons
404 Automatic bath button
405 Chasing button

Claims (8)

A hot water supply device having first storage means for storing product specifying information for specifying a product, and a second hot water supply device communicably connected to the hot water supply device and storing product specifying information for specifying the product. A hot water supply system comprising at least one optional device provided with a storage unit and performing a predetermined function by exchanging data between the hot water supply device and the optional device,
Information acquisition provided in the hot water supply device and communicating with the optional device at a predetermined timing when the optional device is connected to acquire product specifying information of the optional device stored in the second storage means. Means,
Provided in the water heater, when the optional device is connected, connection time specifying means for specifying the connection time of the optional device to the water heater based on the start of use of the water heater,
A storage control unit provided in the hot water supply device and storing, in the first storage unit, the product identification information acquired by the information acquisition unit and the information of the connection timing identified by the connection timing identification unit;
A hot water supply system comprising: 2. The hot water supply system according to claim 1, wherein the product specifying information includes at least information unique to the product and version information of a control unit that performs overall control of the product. 3. The information unique to the product includes at least one of an ID code, a date of manufacture, and a product number, and the version information includes a name and a microcomputer marking that can identify the version information of the control board of the unit including the control board. The hot water supply system according to claim 2, wherein the hot water supply system includes at least one of names. The hot water supply device according to any one of claims 1 to 3, wherein the optional device includes a remote control device that remotely controls the hot water supply device. The connection time specifying means includes an integrating means for integrating an energizing time from the start of use of the hot water supply apparatus, and specifies a connection time based on the energizing time accumulated by the integrating means when the optional device is connected. The hot water supply system according to claim 1, wherein the hot water supply system is used. The hot water supply system according to claim 1, wherein the first and second storage units are nonvolatile memories. 7. The hot water supply system according to claim 1, wherein the hot water supply device communicates with the optional device at a predetermined timing, and transmits information stored in the first storage unit to the second device of the optional device. 8. A hot water supply system further comprising a transfer means for transferring the data to the storage means. The hot water supply system according to claim 7, wherein the predetermined timing is a timing at which a power supply of the hot water supply device is turned off.

Images