JP7503962B2 - Water heater control device, water heater system, water heater control method and program - Google Patents

Description

This disclosure relates to a water heater control device, a water heater system, a water heater control method, and a program.

A storage-type hot water supply system has been proposed that uses surplus electricity generated by a solar power generation system during the day to heat water, and electricity supplied from a power grid at night to heat water (see, for example, Patent Document 1).

JP 2017-223410 A

In the case of the storage-type water heater device described in Patent Document 1, if the power supply from the grid power source is cut off due to a power outage, it is necessary to boil water using only the power generated by the solar power generation device. In this case, it is required to operate the storage-type water heater so that there is no shortage of power supplied to electrical equipment other than the storage-type water heater.

This disclosure has been made in consideration of the above-mentioned reasons, and aims to provide a water heater control device, a water heater system, a water heater control method, and a program that can prevent hot water shortages while preventing a shortage of power supplied to other electrical devices during a power outage.

In order to achieve the above object, the water heater control device according to the present disclosure includes:
A hot water heater control device that controls a hot water heater that has a hot water storage tank and boils hot water using electricity generated by a power generation facility, electricity supplied from a power system, or electricity stored in a power storage device, and stores the hot water in the hot water storage tank,
a power acquisition unit that acquires power information indicating power supplied from the power grid;
a power generation amount acquiring unit that acquires power generation amount information indicating an amount of power generated by the power generation facility;
a power storage amount acquiring unit that acquires power storage amount information indicating a storage amount of electricity stored in the power storage device;
a power supply state determination unit that determines whether or not the power supplied from the power system has been interrupted based on the power information;
The water heater is provided with a command unit that, when the power supply status determination unit determines that the power supplied from the system power supply has been cut off, commands the water heater to operate in an operating mode in which the water heater continuously boils a small amount of hot water, depending on the amount of power generation indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information.

According to the present disclosure, the power supply status determination unit determines whether the power supplied from the grid power supply has been cut off based on power information indicating the power supplied from the grid power supply, and when the power supply status determination unit determines that the power supplied from the grid power supply has been cut off, the command unit commands the water heater to operate in an operation mode in which the amount of hot water continuously boiled by the water heater is small, according to the amount of power generated indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information. This makes it possible to reduce the power consumption per boiling operation by the amount of hot water continuously boiled by the water heater during a power outage, thereby suppressing a shortage of power supplied to electrical devices other than the water heater, and furthermore, since the water heater continues to boil hot water even during a power outage, it is possible to suppress the occurrence of running out of hot water.

FIG. 1 is a schematic configuration diagram of a hot water supply system according to a first embodiment of the present disclosure. Schematic configuration diagram of a water heater according to a first embodiment A block diagram showing a hardware configuration of a hot water supply system according to a first embodiment. A block diagram showing a functional configuration of a water heater according to a first embodiment. FIG. 1 is a block diagram showing a functional configuration of a water heater control device according to a first embodiment. FIG. 1A is a diagram showing an example of information stored in a power generation amount history storage unit according to the first embodiment; FIG. 1B is a diagram showing an example of information stored in a weather forecast storage unit according to the first embodiment; FIG. 1 is a diagram showing an example of information stored in a hot water usage history storage unit according to the first embodiment; A sequence diagram showing an example of an operation of the hot water supply system according to the first embodiment. A sequence diagram showing an example of an operation of the hot water supply system according to the first embodiment. FIG. 1A is a diagram showing an example of an operation screen image displayed on a display unit of a terminal device according to a first embodiment; FIG. 1B is a diagram showing another example of an operation screen image displayed on a display unit of a terminal device according to a first embodiment; A sequence diagram showing an example of an operation of the hot water supply system according to the first embodiment. A sequence diagram showing an example of an operation of the hot water supply system according to the first embodiment. A sequence diagram showing an example of an operation of the hot water supply system according to the first embodiment. A flowchart showing an example of a flow of a water heater control process executed by a water heater control device according to the first embodiment. A flowchart showing an example of a flow of a water heater control process executed by a water heater control device according to the first embodiment. 1A and 1B are diagrams showing an image of the boiling start water volume and the target water volume in a water heater control device according to a first embodiment; FIG. 1A shows the boiling start water volume and the target water volume calculated based on a history of past water usage; FIG. 1B shows the boiling start water volume and the target water volume when the amount of power generated by the power generation facility is equal to or greater than a reference amount of power generation; and FIG. 1C shows the boiling start water volume and the target water volume when the amount of power stored in the power storage device is equal to or greater than a reference amount of power storage. A flowchart showing an example of a flow of a water heater control process executed by a water heater control device according to the first embodiment. A block diagram showing a functional configuration of a water heater control device according to a second embodiment. FIG. 13 is a diagram showing an example of information stored in a boiling power consumption storage unit according to the second embodiment; A flowchart showing an example of a flow of a water heater control process executed by a water heater control device according to a second embodiment. 13A and 13B show a transition of power consumption of a water heater according to a second embodiment, in which FIG. 13A shows a case where the amount of power generation is equal to or greater than the reference amount of power generation, and FIG. 13B shows a case where the amount of power generation is equal to or less than the reference amount of power generation. A flowchart showing an example of a flow of a water heater control process executed by a water heater control device according to a second embodiment. A block diagram showing a functional configuration of a water heater control device according to a third embodiment. A flowchart showing an example of a flow of a water heater control process executed by a water heater control device according to a third embodiment. Schematic configuration diagram of a water heater according to embodiment 4 A block diagram showing a functional configuration of a water heater according to a fourth embodiment. A block diagram showing a functional configuration of a water heater control device according to a fourth embodiment. A flowchart showing an example of a flow of a valve opening/closing control process executed by a water heater control device according to a fourth embodiment. FIG. 13 is a diagram showing an example of an operation screen image displayed on a display unit of a terminal device according to a fourth embodiment; FIG. 11 is a block diagram showing a functional configuration of a water heater control device according to a modified example. FIG. 13 is a diagram showing an example of an operation screen image displayed on a display unit of a terminal device according to a modified example. FIG. 13 is a diagram showing an example of an operation screen image displayed on a display unit of a terminal device according to a modified example. FIG. 11 is a block diagram showing a functional configuration of a water heater control device according to a modified example. FIG. 13 is a diagram showing an example of an operation screen image displayed on a display unit of a terminal device according to a modified example. FIG. 13 is a diagram showing an example of an operation screen image displayed on a display unit of a terminal device according to a modified example. FIG. 1A is a diagram showing an example of an operation screen image displayed on a display unit of a terminal device according to a modified example, and FIG. 1B is a diagram showing another example of an operation screen image displayed on a display unit of a terminal device according to a modified example. A flowchart showing an example of a flow of a water heater control process executed by a water heater control device according to a modified example.

Below, the hot water supply system according to each embodiment of the present disclosure will be described with reference to the drawings.

(Embodiment 1)
The hot water supply system according to the present embodiment includes a water heater having a hot water storage tank, which boils hot water using power generated by a power generation facility, power supplied from a power grid, or electricity stored in a power storage device, and stores the boiled water in the hot water storage tank, a water heater control device that controls the water heater, and a terminal device. The water heater control device includes a power acquisition unit that acquires power information indicating the power supplied from the power grid, a power generation amount acquisition unit that acquires power generation amount information indicating the amount of power generated by the power generation facility, and a power storage amount acquisition unit that acquires power storage amount information indicating the amount of electricity stored in the power storage device. The water heater control device also includes a power supply state determination unit that determines whether or not the power supplied from the power grid has been cut off based on the power information, and a command unit that commands the operation mode of the water heater. Here, when the power supply state determination unit determines that the power supplied from the power grid has been cut off, the command unit commands the water heater to operate in an operation mode in which the amount of hot water continuously boiled by the water heater is small, according to the power generation amount indicated by the power generation amount information and the power storage amount indicated by the power storage amount information.

1, the hot water supply system according to this embodiment includes a water heater 3 that boils water, a water heater control device 1 that controls the water heater 3, and a terminal device 5 that displays an operation screen image including information received from the water heater control device 1. This hot water supply system is installed in a building in which a power generation facility 22, a power storage device 23, a power conditioner 4, electrical equipment 11 other than the water heater 3, a distribution board 6 that supplies power supplied from a system power supply 21 or the power conditioner 4 to the water heater 3 and the electrical equipment 11, and a power measurement device 7 are installed. In addition, the water heater control device 1, the power conditioner 4, and the power measurement device 7 are capable of communicating with each other via a local network NW2 installed in the building.

In addition, the building is provided with a router 9 capable of communicating with the water heater control device 1, the power conditioner 4, and the power measuring device 7 via a local network NW2. The local network NW2 is a wireless LAN (Local Area Network) or a wired LAN. The router 9 is, for example, a broadband router, and is connected to a wide area network NW1 such as the Internet. The terminal device 5 is capable of communicating with the water heater control device 1 via the wide area network NW1 and the local network NW2. The water heater control device 1 is also capable of communicating with the power generation amount management server 8 and the weather server 10 via the wide area network NW1 and the local network NW2. The power generation amount management server 8 accumulates information on the amount of power generated at the power generation facility 22 that is periodically transmitted from the water heater control device 1. The power generation amount management server 8 transmits power generation amount history information indicating the history of the amount of power generated at the power generation facility 22 to the water heater control device 1 in response to a request from the water heater control device 1. The weather server 10 transmits weather forecast information indicating future weather forecasts to the water heater control device 1 in response to a request from the water heater control device 1.

The system power supply 21 is provided by an electric power company and supplies AC power to the distribution board 6 via power line D21. The power generation equipment 22 has, for example, a solar panel that generates power from sunlight, which is natural energy, and outputs DC power to the power conditioner 4. The power storage device 23 has, for example, a battery pack composed of multiple lithium-ion battery cells.

The power conditioner 4 is connected to the power generation equipment 22 via the power line D22, connected to the storage device 23 via the power line D23, and connected to the distribution board 6 via the power line D6. The power conditioner 4 has a bidirectional inverter (not shown) that converts DC power supplied from the power generation equipment 22 or the storage device 23 into AC power and outputs it to the distribution board 6, or converts AC power supplied from the distribution board 6 into DC power and outputs it to the storage device 23. The power conditioner 4 also has a power generation amount measurement unit (not shown) that has a voltmeter that measures a voltage reflecting the output voltage of the power generation equipment 22 and measures the amount of power generated by the power generation equipment 22 based on the measured voltage, and a storage amount measurement unit (not shown) that has a voltmeter that measures a voltage reflecting the output voltage of the storage device 23 and measures the amount of storage in the storage device 23 based on the measured voltage.

The distribution board 6 branches and supplies AC power supplied from the system power supply 21 or the power conditioner 4 to the water heater 3 and the electrical equipment 11 via power lines D3 and D11. The power measurement device 7 is a so-called smart meter, and periodically and repeatedly measures the AC power supplied from the system power supply 21 to the distribution board 6 via the power line D21, and the power supplied from the distribution board 6 to the water heater 3 and the electrical equipment 11 via the power lines D3 and D11. The power measurement device 7 generates power information each time it measures each power, and transmits it to the water heater control device 1 via the local network NW2.

2, the hot water heater 3 is a hot water storage type hot water heater having a hot water storage tank 31, a heat pump unit 32, and a controller 33, and the heat pump unit 32 boils water stored in the hot water storage tank 31. The heat pump unit 32 has an evaporator 321, a compressor 322, an expansion valve 324, a heat exchanger 323, a compressor 322, an expansion valve 324, and a control board 325 that controls the compressor 322, which constitute a heat pump. Here, water sent from the hot water storage tank 31 to the heat exchanger 323 by the pump 313 is heated in the heat exchanger 323 and returned to the hot water storage tank 31. Then, hot water is supplied to the bathroom or kitchen in the building from the hot water outlet pipe PI1 provided in the hot water storage tank 31, and tap water is supplied to the hot water storage tank 31 from the water supply pipe PI2. The water heater 3 also has a hot water usage measurement unit 311 that is provided on the hot water outlet pipe PI1 of the hot water storage tank 31 and measures the hot water usage amount, which is the amount of hot water discharged from the hot water storage tank 31 per unit time, and a hot water storage amount measurement unit 312 that measures the amount of hot water stored in the hot water storage tank 31. The hot water usage measurement unit 311 is connected to the controller 33 via a communication line (not shown) and periodically outputs hot water usage information indicating the measured amount of hot water usage to the controller 33. The hot water storage amount measurement unit 312 is also connected to the controller 33 via a communication line (not shown) and periodically outputs hot water storage amount information indicating the measured amount of hot water storage to the controller 33. The water heater 3 also has temperature sensors 313a, 313b, 313c, 313d, and 313e that detect the water temperature in each section when the hot water storage tank 31 is divided into multiple sections in the height direction.

3, the controller 33 includes a CPU (Central Processing Unit) 301, a main memory unit 302 such as a RAM (Random Access Memory), an auxiliary memory unit 303 having a ROM (Read Only Memory) and a readable/writable non-volatile memory, a communication interface 310 connected to the control board 325 of the heat pump unit 32 via a communication line (not shown), and a bus 309 connecting these to each other. Here, the CPU 301 loads the program stored in the auxiliary memory unit 303 into the main memory unit 302 and executes it, thereby functioning as a schedule receiving unit 331, a heat pump control unit 332, a command information receiving unit 333, a water heater information transmitting unit 334, a hot water usage history generating unit 335, a hot water usage amount acquiring unit 336, a hot water storage amount acquiring unit 337, and a hot water storage temperature acquiring unit 338, as shown in FIG. 4, the auxiliary memory unit 303 shown in FIG. 3 has a hot water usage history memory unit 342 that stores the amount of hot water used, a hot water storage amount/temperature memory unit 343 that stores hot water storage amount information indicating the amount of hot water stored and hot water storage temperature information indicating the temperature of the stored hot water, a schedule memory unit 344 that stores schedule information indicating the operation schedule of the water heater 3, and an operation time/power consumption memory unit 345. The operation time/power consumption memory unit 345 stores operation time information indicating the time when water heating is performed and water heating power consumption information indicating the power consumed by the heat pump unit 32 during water heating. The water heating power consumption information is stored in advance in the operation time/power consumption memory unit 345.

When the schedule receiving unit 331 receives schedule information transmitted from the water heater control device 1, it stores the received schedule information in the schedule memory unit 344. When the command information receiving unit 333 receives power outage mode switching command information, boiling start command information, or normal mode switching command information from the water heater control device 1, it outputs the received various information to the heat pump control unit 332. In addition, when the command information receiving unit 333 receives operating time information from the water heater control device 1, it stores the received operating time information in the operating time/power consumption memory unit 345.

The heat pump control unit 332 operates in two operation modes: normal mode and power outage mode. When operating in normal mode, the heat pump control unit 332 controls the operation of the heat pump of the heat pump unit 32 by outputting control information to the control board 325 according to the operation schedule indicated by the schedule information stored in the schedule storage unit 344. On the other hand, when operating in power outage mode, the heat pump control unit 332 acquires the operation time information and the boiling power consumption information stored in the operation time/power consumption storage unit 345. Then, when the heat pump control unit 332 receives boiling start command information from the command information receiving unit 333, it performs boiling of hot water for the time indicated by the operation time information with the power indicated by the boiling power consumption information. Also, when the heat pump control unit 332 operates in normal mode, when power outage mode switching command information is input from the command information receiving unit 333, it switches the operation mode to the power outage mode. Furthermore, when operating in power outage mode, the heat pump control unit 332 operates the heat pump unit 32 when it receives an operation to operate the heat pump unit 32 manually by the user.

The hot water temperature acquisition unit 338 generates hot water temperature information corresponding to the acquired detection signal each time it acquires a detection signal indicating the hot water temperature detected by each of the temperature sensors 313a, 313b, 313c, 313d, and 313e. The hot water temperature acquisition unit 338 then stores the generated hot water temperature information in the hot water volume/temperature storage unit 343 in chronological order in association with category identification information identifying the category corresponding to each of the temperature sensors 313a, 313b, 313c, 313d, and 313e. The hot water usage acquisition unit 336 stores the acquired hot water volume information in the hot water usage history storage unit 342 in association with time information indicating the time at which the hot water volume information measured by the timekeeping unit was acquired each time it acquires hot water volume information from the hot water usage measurement unit 311. The hot water volume acquisition unit 337 stores the acquired hot water volume information in the hot water volume/temperature storage unit 343 each time it acquires hot water volume information from the hot water volume measurement unit 312. When the hot water usage history generating unit 335 receives hot water heater information request information described later from the hot water heater control device 1, it acquires hot water usage information from the hot water usage history storage unit 342 from the most recent time when the hot water heater information request information was received to the present time and the corresponding time information, and generates hot water usage history information including the acquired hot water usage information and time information. The hot water usage history generating unit 335 then notifies the hot water heater information transmitting unit 334 of the generated hot water usage history information. When the hot water heater information transmitting unit 334 receives hot water heater information request information from the hot water heater control device 1, it transmits the hot water usage history information generated by the hot water usage history generating unit 335 and the hot water storage volume information and hot water storage temperature information stored in the hot water storage volume/temperature storage unit 343 to the hot water heater control device 1.

Returning to FIG. 1, the electrical equipment 11 is, for example, an air conditioner, a lighting device, a floor heating system, a refrigerator, an induction heating (IH) cooker, a television, etc. The electrical equipment 11 operates by receiving AC power from the distribution board 6.

The power generation management server 8 has a storage (not shown), a control unit (not shown) that controls the entire power generation management server 8, and a communication interface (not shown) connected to the wide area network NW1. The storage stores information indicating the history of the amount of power generated by the power generation facility 22 in association with actual weather information for the area in which the building in which the water heater 3 controlled by the corresponding water heater control device 1 is installed. The power generation management server 8 periodically receives power generation information indicating the amount of power generated by the power generation facility 22 from the water heater control device 1, and accumulates the received power generation information in the storage each time the power generation information is received in association with actual weather information for the area in which the building in which the water heater 3 is installed is located at the time of reception. In addition, when the power generation management server 8 receives power generation history request information from the water heater control device 1 requesting the power generation management server 8 to transmit power generation history information to the water heater control device 1, the power generation management server 8 extracts water heater identification information that identifies the water heater 3 or the water heater control device 1 included in the power generation history request information. Next, the power generation management server 8 identifies the power generation information and weather record information that correspond to the extracted water heater identification information from the power generation information and weather record information stored in the storage, and generates power generation history information using the identified power generation information and weather record information. The power generation management server 8 then transmits the generated power generation history information to the water heater control device 1.

The weather server 10 has a storage (not shown), a control unit (not shown) that controls the entire weather server 10, and a communication interface (not shown) connected to the wide area network NW1. The storage stores weather forecast information indicating future weather forecasts for each region. The weather forecast information includes at least information indicating future weather. When the weather server 10 receives weather forecast request information from the water heater control device 1 requesting the weather server 10 to transmit weather forecast information to the water heater control device 1, the weather server 10 extracts regional information indicating the target region contained in the weather forecast request information. Next, the weather server 10 identifies, from the weather forecast information stored in the storage, weather forecast information for the region indicated by the extracted regional information. The weather server 10 then transmits the identified weather forecast information to the water heater control device 1.

The terminal device 5 is, for example, a smartphone, and as shown in FIG. 3, is a display device including a CPU 501, a main memory unit 502, an auxiliary memory unit 503, a display unit 504, a wide area communication unit 506, and a bus 509 connecting each unit. The terminal device 5 corresponds to an external device to the water heater control device 1. The main memory unit 502 is a volatile memory used as a working area for the CPU 501. The auxiliary memory unit 503 is a non-volatile memory such as a semiconductor flash memory, and stores programs for realizing various functions of the terminal device 5. The display unit 504 is a liquid crystal display, an organic EL (Electro-luminescence) display, or the like, and outputs various information input from the CPU 501. The wide area communication unit 506 has an interface for connecting to the wide area network NW1.

The CPU 501 reads out the program stored in the auxiliary storage unit 503 into the main storage unit 502 and executes it, thereby functioning as an alarm information receiving unit 511 and a display control unit 512, as shown in FIG. 5. The auxiliary storage unit 503 shown in FIG. 3 also has an operation screen memory unit 531 that stores image information for generating an operation screen image including the alarm information received from the water heater control device 1, as shown in FIG. 5. When the alarm information receiving unit 511 receives the alarm information transmitted from the water heater control device 1, it notifies the display control unit 512 of the received alarm information. When the display control unit 512 is notified of the alarm information from the alarm information receiving unit 511, it acquires image information from the operation screen memory unit 531, and generates an operation screen image including the alarm information related to the water heater 3 based on the alarm information and the acquired image information, and displays it on the display unit 504.

Returning to FIG. 3, the water heater control device 1 is, for example, a HEMS (Home Energy Management System) controller, and includes a CPU 101, a main memory unit 102, an auxiliary memory unit 103, a wide area communication unit 106 connected to a wide area network NW1, a local communication unit 107 connected to a local network NW2, a clock unit 108, and a bus 109 that interconnects these. The main memory unit 102 is a volatile memory used as a working area for the CPU 101. The auxiliary memory unit 103 is a non-volatile memory such as a semiconductor flash memory, and stores programs for implementing various functions of the water heater control device 1. The local communication unit 107 communicates with the power measurement device 7 via the local network. The clock unit 108 functions as an RTC (Real Time Clock) that keeps track of the current date and time.

The CPU 101 reads out and executes the programs stored in the auxiliary memory unit 103 into the main memory unit 102, and thereby functions as a power acquisition unit 111, a power generation amount acquisition unit 112, a power generation amount transmission unit 113, a stored power amount acquisition unit 114, a water heater information acquisition unit 115, a power generation amount history acquisition unit 116, a power generation amount prediction unit 117, a power supply state determination unit 118, a starting hot water amount target hot water amount setting unit 119, a hot water amount used prediction unit 120, a boiling hot water amount calculation unit 121, a command unit 122, a schedule generation unit 123, a schedule transmission unit 124, an alarm unit 125 and a weather forecast acquisition unit 126, as shown in FIG. 5. In addition, the auxiliary memory unit 103 shown in FIG. 3 includes a power generation amount history memory unit 131, a weather forecast memory unit 132, a hot water usage amount history memory unit 133, a hot water storage amount/temperature memory unit 134, a power supply state memory unit 135, a starting hot water amount target hot water amount memory unit 136, a power generation amount prediction memory unit 137, and a schedule memory unit 138, as shown in FIG. 5.

As shown in FIG. 6(A), the power generation amount history storage unit 131 stores power generation amount information indicating the amount of power generation at the power generation equipment 22 at the present time and in the past, and weather performance information indicating the performance of weather conditions, in association with a plurality of time periods set in advance at the present time and in the past. As shown in FIG. 6(B), the weather forecast storage unit 132 stores weather forecast information indicating the forecast of future weather conditions from the present time in association with a plurality of time periods set in advance. As shown in FIG. 7, the hot water usage history storage unit 133 stores the performance value of the hot water usage indicating the amount of hot water used in the building per day in the past in association with information indicating the date of use. Returning to FIG. 5, the hot water storage amount/temperature storage unit 134 stores the hot water storage amount information and the hot water storage temperature information included in the hot water heater information most recently acquired by the hot water heater information acquisition unit 115. The power generation prediction memory unit 137 stores information indicating the start and end of a power generation period during which the predicted future power generation amount of the power generation facility 22 will be equal to or greater than a preset power generation amount threshold, based on the power generation amount history information stored in the power generation amount history memory unit 131 and the weather forecast information stored in the weather forecast memory unit 132.

The power supply status storage unit 135 stores power failure flag information indicating whether or not the power supply from the power grid 21 to the distribution board 6 has been cut off. The start hot water volume target hot water volume storage unit 136 stores boiling start hot water volume information and target hot water volume information. Here, the boiling start hot water volume information indicates the amount of hot water stored in the hot water storage tank 31 when the power supply from the power grid 21 is cut off, that is, when the hot water heater 3 starts boiling hot water during operation in the power failure automatic boiling mode in which the hot water heater 3 automatically boils hot water during a power failure. In addition, the target hot water volume information indicates the target amount of hot water to be stored in the hot water storage tank 31 by starting boiling hot water during operation in the power failure automatic boiling mode in which the hot water heater 3 automatically boils hot water during a power failure. In addition, the power supply status storage unit 135 stores power generation volume flag information indicating whether or not the amount of power generated by the power generation facility 22 is equal to or greater than a preset reference power generation volume, and power storage volume flag information indicating whether or not the amount of power stored in the power storage device 23 is equal to or greater than a preset reference power storage volume. The schedule memory unit 138 stores schedule information including information indicating the start time of boiling water and information indicating the end time of boiling water when the water heater 3 is operating in normal mode.

The weather forecast acquisition unit 126 acquires weather forecast information indicating future weather conditions in the area where the building in which the water heater 3 is installed is located from the weather server 10. The weather forecast acquisition unit 126 acquires weather forecast information transmitted from the weather server 10 by transmitting to the weather server 10 weather forecast request information requesting the weather server 10 to transmit weather forecast information. Here, the weather forecast information indicates a forecast of the weather every hour for a preset period of time in the future from the present time, for example, up to 24 hours from the present time. The weather forecast acquisition unit 126 then stores the acquired weather forecast information in the weather forecast storage unit 132.

The power acquisition unit 111 acquires power information indicating the power supplied from the system power source 21 to the distribution board 6 from the power metering device 7. When the power acquisition unit 111 determines that a preset system power acquisition time has arrived based on the date and time measured by the clock unit 108, it acquires the power information transmitted from the power metering device 7 by transmitting power request information to the power metering device 7 requesting the power metering device 7 to transmit power information. The power acquisition unit 111 then notifies the power status determination unit 118 of the acquired power information.

The power generation amount acquisition unit 112 acquires power generation amount information indicating the amount of power generated in the power generation facility 22 from the power conditioner 4. The power generation amount acquisition unit 112 acquires the power generation amount information transmitted from the power conditioner 4 by transmitting power generation amount request information requesting the power conditioner 4 to transmit the power generation amount information to the power conditioner 4. The power generation amount acquisition unit 112 then notifies the power supply state determination unit 118 and the power generation amount transmission unit 113 of the acquired power generation amount information. The power generation amount transmission unit 113 transmits the power generation amount information notified by the power generation amount acquisition unit 112 to the power generation amount management server 8. The stored power amount acquisition unit 114 acquires stored power amount information indicating the amount of stored power in the storage device 23 from the power conditioner 4. The stored power amount acquisition unit 114 acquires stored power amount information transmitted from the power conditioner 4 by transmitting stored power amount request information requesting the power conditioner 4 to transmit stored power amount information to the power conditioner 4. The stored power amount acquisition unit 114 then notifies the acquired stored power amount information to the power supply status determination unit 118.

The power generation amount history acquisition unit 116 acquires the power generation amount history information transmitted from the power generation amount management server 8 by transmitting power generation amount history request information requesting the power generation amount management server 8 to transmit the power generation amount history information to the power generation amount management server 8. The power generation amount history acquisition unit 116 then stores the acquired power generation amount history information in the power generation amount history storage unit 131. The power generation amount prediction unit 117 predicts the transition of the power generation amount in the power generation facility 22 in a future preset period based on the weather forecast information stored in the weather forecast storage unit 132 and the power generation amount history information stored in the power generation amount history storage unit 131. The power generation amount prediction unit 117 then identifies the power generation period of the power generation facility 22 from the predicted transition of the power generation amount. Here, the power generation amount prediction unit 117 identifies the start and end of the power generation period in which the power generation amount is equal to or greater than the preset power generation amount threshold from the predicted future transition of the power generation amount of the power generation facility 22, and stores information indicating the start and end of the identified power generation period in the power generation amount prediction storage unit 137.

The power supply state determination unit 118 determines whether the power supply from the system power source 21 to the distribution board 6 has been cut off based on the power information notified from the power acquisition unit 111. When the state in which the power supplied from the system power source 21 to the distribution board 6 at the time of acquiring the system power continues to be less than the preset power threshold for a preset power outage determination reference number of times, the power supply state determination unit 118 determines that the power supply from the system power source 21 to the distribution board 6 has been cut off, that is, a power outage has occurred. On the other hand, when the state in which the power supplied from the system power source 21 to the distribution board 6 at the time of acquiring the system power continues to be less than the preset power threshold for a number of times less than the power outage determination reference number described above, and then the power supplied from the system power source 21 to the distribution board 6 again becomes equal to or greater than the power threshold, the power supply state determination unit 118 determines that a power outage has not occurred as a sudden cutoff of the power supply from the system power source 21 to the distribution board 6. Furthermore, the power supply state determination unit 118 determines whether the power generation amount indicated by the power generation amount information notified from the power generation amount acquisition unit 112 is equal to or greater than the aforementioned reference power generation amount, and when it is determined that the power generation amount indicated by the power generation amount information is equal to or greater than the reference power generation amount, stores power generation amount flag information indicating that the power generation amount of the power generation facility 22 is equal to or greater than the reference power generation amount in the power supply state storage unit 135. Here, the power supply state determination unit 118 may regard the power generation amount of the power generation facility 22 as being equal to or greater than the reference power generation amount when the power generation amount of the power generation facility 22 suddenly drops below the reference power generation amount due to the influence of clouds or the like. For example, the power supply state determination unit 118 may determine that the power generation amount of the power generation facility 22 is equal to or greater than the reference power generation amount when the state of being less than the reference power generation amount continues for a preset time, for example, less than five minutes. Furthermore, the power supply state determination unit 118 determines whether the stored energy amount indicated by the stored energy amount information notified by the stored energy amount acquisition unit 114 is equal to or greater than the aforementioned reference stored energy amount, and if it determines that the stored energy amount indicated by the stored energy amount information is equal to or greater than the reference stored energy amount, it stores stored energy amount flag information indicating that the power generation amount of the power generation equipment 22 is equal to or greater than the reference power generation amount in the power supply state storage unit 135.

The water heater information acquisition unit 115 acquires water heater information from the water heater 3, including hot water usage history information indicating the history of the amount of hot water used by the water heater 3, hot water storage volume information indicating the current amount of hot water storage in the water heater 3, and hot water storage temperature information indicating the current hot water storage temperature in the water heater 3. The water heater information acquisition unit 115 acquires the water heater information transmitted from the water heater 3 by transmitting to the water heater 3 water heater information request information requesting the water heater 3 to transmit the above-mentioned water heater information. The water heater information acquisition unit 115 then stores the hot water usage history information included in the acquired water heater information in the hot water usage history storage unit 133, and stores the hot water storage volume information and hot water storage temperature information included in the acquired water heater information in the hot water storage volume/temperature storage unit 134.

At a preset schedule generation time, the hot water usage prediction unit 120 predicts the amount of hot water usage in the building in which the water heater 3 is installed until the next schedule generation time based on the hot water usage history information stored in the hot water usage history memory unit 133. Specifically, the hot water usage prediction unit 120 calculates the maximum amount of hot water usage or the average amount of hot water usage in the past two weeks, for example, as the predicted amount of hot water usage. The hot water usage prediction unit 120 notifies the boiling hot water volume calculation unit and the starting hot water volume target hot water volume setting unit 119 of information indicating the calculated predicted amount of hot water usage.

The time determination unit 127 acquires a power generation period during which power is generated by the power generation facility 22 specified based on the transition of the power generation amount. Specifically, the time determination unit 127 acquires information indicating the start and end of a power generation period during which the future power generation amount of the power generation facility 22 stored in the power generation amount prediction storage unit 137 will be equal to or greater than a preset power generation amount threshold. The time determination unit 127 then calculates the remaining power generation time from the power outage determination time when the power supply state determination unit 118 determines that the power supplied from the system power supply 21 has been cut off to the end of the power generation period, and determines whether the calculated remaining power generation time is equal to or greater than a preset first reference time. The time determination unit 127 also calculates a power generation waiting time from the power outage determination time when the power supply state determination unit 118 determines that the power supplied from the system power supply 21 has been cut off to the start of the power generation period, and determines whether the calculated power generation waiting time is equal to or greater than a preset second reference time.

The start water volume target water volume setting unit 119 sets the start water volume, which is the amount of water stored in the hot water storage tank 31 when water heating starts during operation in the power failure automatic water heating mode, and the target water volume to be stored in the hot water storage tank 31 by starting water heating, based on the predicted water usage volume notified by the water usage volume prediction unit 120. Here, the start water volume is set to a water volume within a range of, for example, 10% to 20% of the capacity of the hot water storage tank 31, and the target water volume is set to a water volume within a range of, for example, 80% to 90% of the capacity of the hot water storage tank 31. The start water volume target water volume setting unit 119 stores the start water volume information indicating the aforementioned start water volume and the target water volume information indicating the aforementioned target water volume in the start water volume target water volume storage unit 136. When the power supply status determination unit 118 determines that the power supplied from the system power supply 21 has been cut off, the start hot water volume target hot water volume setting unit 119 updates the boiling start hot water volume and the target hot water volume based on the amount of power generated by the power generation facility 22 and the amount of power stored in the power storage device 23. Specifically, when the power supply status determination unit 118 determines that the amount of power generated by the power generation facility 22 is equal to or greater than a preset reference power generation volume and the time determination unit 127 determines that the time from the aforementioned power outage determination to the end of the aforementioned power generation period is equal to or greater than a preset first reference time, the start hot water volume target hot water volume setting unit 119 increases the boiling start hot water volume and the target hot water volume so that the difference between the boiling start hot water volume and the target hot water volume becomes the preset first reference hot water volume. In addition, when the power supply state determination unit 118 determines that the amount of power generated by the power generation equipment 22 is less than the reference amount of power generation, or when the time determination unit 127 determines that the remaining power generation time from the time of the power outage determination to the end of the power generation period is less than a first reference time, if the amount of stored power in the power storage device 23 is equal to or greater than a predetermined reference amount of stored power and the time from the time of the power outage determination to the start of the power generation period is equal to or less than a predetermined second reference time, the start water volume target water volume setting unit 119 reduces the amount of water to start boiling and the target water volume so that the difference between the amount of water to start boiling and the target water volume becomes the predetermined second reference water volume.

The hot water boiling amount calculation unit 121 calculates the amount of hot water to be boiled by the water heater 3 by the next schedule generation time based on the hot water amount indicated by the hot water amount information stored in the hot water amount/temperature storage unit 134 and the hot water temperature indicated by the hot water temperature information, and the predicted hot water usage indicated by the information indicating the predicted hot water usage notified by the hot water usage prediction unit 120. In addition, when the hot water boiling amount calculation unit 121 is notified of power outage mode switching notification information notifying that power outage mode switching command information has been sent to the water heater 3 from the command unit 122 to command the water heater 3 to operate in power outage mode, the hot water boiling amount calculation unit 121 determines whether the hot water amount indicated by the hot water amount information stored in the hot water amount/temperature storage unit 134 has reached the amount of hot water indicated by the hot water boiling start amount information. Then, when the boiling hot water volume calculation unit 121 determines that the amount of stored hot water indicated by the stored hot water volume information has reached the amount of hot water indicated by the boiling start hot water volume information, it refers to the target hot water volume information stored in the start hot water volume target hot water volume memory unit 136 and calculates the amount of hot water that should be boiled by the water heater 3 to store the target amount of hot water in the hot water storage tank 31. The boiling hot water volume calculation unit 121 then notifies the command unit 122 of the boiling hot water volume information indicating the calculated amount of hot water. Here, the boiling hot water volume calculation unit 121 performs the calculation using, for example, the relational expression shown in the following formula (1).

Here, X indicates the amount of hot water to be boiled, ρt indicates the density of water at the preset target temperature Tt, Vt indicates the preset target amount of hot water storage, and ct is the specific heat of water at the target temperature Tt. Furthermore, Tk (k = 1, 2, ..., 5) indicate the temperatures detected by the temperature sensors 313a, 313b, 313c, 313d, and 313e, respectively, ρk indicates the density of water at temperature Tk, and ck indicates the specific heat of water at temperature Tk. Furthermore, Vk indicates the amount of hot water storage in the section corresponding to each of the temperature sensors 313a, 313b, 313c, 313d, and 313e in the hot water storage tank 31. The boiled hot water amount calculation unit 121 then notifies the schedule generation unit 123 of boiled hot water amount information indicating the calculated amount of hot water to be boiled.

The schedule generation unit 123 calculates the required operation time of the water heater 3 based on the hot water volume information notified from the hot water volume calculation unit 121 at the schedule generation time, and generates an operation schedule for the water heater 3 until the next schedule generation time using the calculated required operation time. The schedule generation unit 123 generates an operation schedule so that the operation time of the water heater 3 is a preset night time period, for example, a time period from 11pm to 7am the following day. For example, when the required operation time is 4 hours, the schedule generation unit 123 generates an operation schedule so that the operation time of the water heater 3 is from 4am to 7am. The schedule generation unit 123 stores schedule information indicating the generated operation schedule in the schedule storage unit 138. The schedule transmission unit 124 transmits the schedule information stored in the schedule storage unit 138 to the water heater 3.

When the power supply state determination unit 118 determines that the power supplied from the grid power supply 21 has been cut off by referring to the power failure flag information stored in the power supply state storage unit 135, the command unit 122 commands the water heater 3 to operate in an operation mode in which the amount of hot water continuously boiled by the water heater 3 is small, according to the amount of power generated by the power generation equipment 22 indicated by the power generation amount information and the amount of power stored in the power storage device 23 indicated by the power storage amount information. When the power supplied from the grid power supply 21 is cut off, the command unit 122 transmits power failure mode switching command information to the water heater 3, which commands the water heater 3 to switch its operation mode to a power failure mode. At this time, the command unit 122 notifies the above-mentioned power failure mode switching notification information to the boiled hot water amount calculation unit 121. Furthermore, when the command unit 122 is notified of the boiled hot water amount information from the boiled hot water amount calculation unit 121, the command unit 122 calculates the operation time of the water heater 3 based on the notified amount of boiled hot water. Here, the command unit 122 calculates the product of, for example, the amount of hot water to be boiled and a conversion coefficient that is preset for converting the amount of hot water to be boiled into the amount of power required by the water heater 3, and calculates the operating time by dividing the calculated product by the water heater 3's power consumption for boiling per unit time. Then, when the amount of hot water stored in the hot water storage tank 31 reaches the amount of hot water to start boiling, the command unit 122 transmits boiling start command information and operating time information to the water heater 3. On the other hand, when the power supplied from the system power supply 21 is restored, the command unit 122 transmits normal mode switching command information to the water heater 3 to command the water heater 3 to switch the operating mode from the power outage mode to the normal mode.

When the power supplied from the system power source 21 to the distribution board 6 remains below a preset power threshold for a preset reference period or longer, the notification unit 125 generates power outage notification information to notify the user that a power outage has occurred and transmits it to the terminal device 5. On the other hand, when the power supplied from the system power source 21 to the distribution board 6 remains below the power threshold for a reference period or longer and then the power supplied from the system power source 21 to the distribution board 6 becomes equal to or greater than the power threshold, the notification unit 125 generates recovery notification information to notify the user that the power supplied from the system power source 21 has been restored and transmits it to the terminal device 5.

Next, the operation of the hot water supply system according to this embodiment will be described with reference to FIG. 8 to FIG. 12. Here, it will be described assuming that the hot water supply unit 3 is initially operating in normal mode. First, as shown in FIG. 8, when a preset schedule generation time arrives, hot water supply unit information request information that requests the hot water supply unit 3 to transmit hot water supply unit information is transmitted from the hot water supply unit control device 1 to the hot water supply unit 3 (step S1). On the other hand, when the hot water supply unit 3 receives the hot water supply unit information request information, the hot water supply unit 3 generates hot water supply unit information including hot water usage history information, hot water storage volume information, and hot water storage temperature information (step S2). Next, the generated hot water supply unit information is transmitted from the hot water supply unit 3 to the hot water supply unit control device 1 (step S3). At this time, the hot water supply unit control device 1 stores the hot water usage history information included in the received hot water supply unit information in the hot water usage history storage unit 133, and stores the hot water storage volume information and the hot water storage temperature information in the hot water storage volume/temperature storage unit 134.

Next, the water heater control device 1 predicts the amount of hot water to be used in the building in which the water heater 3 is installed until the next schedule generation time based on the hot water usage history information stored in the hot water usage history memory unit 133 (step S4). After that, the water heater control device 1 sets the boiling start hot water volume Ws and the target hot water volume Wf during operation in the power failure automatic boiling mode based on the predicted hot water usage (step S5). Here, the water heater control device 1 stores the boiling start hot water volume information indicating the set boiling start hot water volume Ws and the target hot water volume information indicating the target hot water volume Wf in the start hot water volume target hot water volume memory unit 136. Next, the water heater control device 1 calculates the amount of hot water to be boiled by the water heater 3 based on the hot water storage volume indicated by the hot water storage volume information, the hot water storage temperature indicated by the hot water storage temperature information, and the predicted hot water usage indicated by the predicted hot water usage information (step S6). The water heater control device 1 then calculates the required operation time of the water heater 3 based on the calculated amount of hot water to be heated, and generates an operation schedule for the water heater 3 until the next schedule generation time using the calculated required operation time (step S7). At this time, the water heater control device 1 stores schedule information indicating the generated operation schedule in the schedule storage unit 138. Next, the schedule information stored in the schedule storage unit 138 is transmitted from the water heater control device 1 to the water heater 3 (step S8). Meanwhile, when the water heater 3 receives the schedule information, it operates based on the received schedule information (step S9).

When the preset grid power acquisition time arrives, power request information requesting the power measuring device 7 to transmit power information is transmitted from the water heater control device 1 to the power measuring device 7 (step S10). On the other hand, when the power measuring device 7 receives the power request information, it generates power information indicating the power supplied from the grid power source 21 to the distribution board 6 (step S11). Next, the generated power information is transmitted from the power measuring device 7 to the water heater control device 1 (step S12). After that, as shown in FIG. 9, the water heater control device 1 determines based on the power information that the power Pp supplied from the grid power source 21 to the distribution board 6 is less than the preset power threshold Ppth for a preset reference period or more (step S13). In this case, power failure notification information informing the user that the power supplied from the grid power source 21 to the distribution board 6 has been cut off is transmitted from the water heater control device 1 to the terminal device 5 (step S14). On the other hand, when the terminal device 5 receives the power failure notification information, it displays the received power failure notification information on the display unit 504 (step S15). At this time, the terminal device 5 displays, on the display unit 504, an operation screen image GA11 including message information M11 for notifying the user that a power outage has occurred, as shown in FIG. 10(A), for example.

Returning to FIG. 9, next, power failure mode switching command information instructing the water heater 3 to switch the operation mode to the power failure mode is transmitted from the water heater control device 1 to the water heater 3 (step S16). Meanwhile, when the water heater 3 receives the power failure mode switching command information, it sets the operation mode to the power failure mode (step S17). Next, power generation amount request information requesting the power conditioner 4 to transmit power generation amount information is transmitted from the water heater control device 1 to the power conditioner 4 (step S18). Meanwhile, when the power conditioner 4 receives the power generation amount request information, it generates power generation amount information indicating the power generated in the power generation facility 22 (step S19). Then, the generated power generation amount information is transmitted from the power conditioner 4 to the water heater control device 1 (step S20). Next, power generation amount history request information requesting the power generation amount management server 8 to transmit power generation amount history information is transmitted from the water heater control device 1 to the power generation amount management server 8 (step S21). On the other hand, when the power generation amount management server 8 receives the power generation amount history request information, it identifies the power generation amount information and the weather record information corresponding to the water heater identification information for identifying the water heater 3 or the water heater control device 1 included in the power generation amount history request information, and generates the power generation amount history information using the identified power generation amount information and the weather record information (step S22). Next, the generated power generation amount history information is transmitted from the power generation amount management server 8 to the water heater control device 1 (step S23). Here, when the water heater control device 1 receives the power generation amount history information, it stores the received power generation amount history information in the power generation amount history storage unit 131. Then, weather forecast request information requesting the weather server 10 to transmit weather forecast information is transmitted from the water heater control device 1 to the weather server 10 (step S24). On the other hand, when the weather forecast request information is received, the weather server 10 identifies the weather forecast information corresponding to the received weather forecast request information (step S25). Next, the identified weather forecast information is transmitted from the weather server 10 to the water heater control device 1 (step S26). Here, when the water heater control device 1 receives weather forecast information, it stores the received weather forecast information in the weather forecast storage unit 132.

Then, the water heater control device 1 predicts the trend in the amount of power generated by the power generation facility 22 for a preset future period based on the weather forecast information stored in the weather forecast storage unit 132 and the power generation history information stored in the power generation history storage unit 131. The power generation prediction unit 117 then identifies the power generation period of the power generation facility 22 from the predicted trend in the amount of power generated (step S27). Here, the power generation prediction unit 117 identifies the power generation period during which the amount of power generated by the power generation facility 22 is equal to or greater than the preset power generation threshold. The power generation prediction unit 117 then stores information indicating the start and end of the identified power generation period in the power generation prediction storage unit 137.

After that, as shown in FIG. 11, the water heater control device 1 calculates the remaining power generation time dTrf from the time of power failure determination when the power supply state determination unit 118 determines that the power supplied from the system power supply 21 has been cut off to the end of the power generation period (step S28). Next, the water heater control device 1 determines that the power generation amount Pg of the power generation equipment 22 is equal to or greater than the preset power generation amount threshold Pgth and the remaining power generation time dTrf is equal to or greater than the first reference time dTrfth (step S29). In this case, the water heater control device 1 updates the boiling start water volume Ws and the target water volume Wf by increasing the boiling start water volume Ws and the target water volume Wf so that the difference between the boiling start water volume Ws and the target water volume Wf becomes the first reference water volume (step S30). Next, when the preset water heater information acquisition time arrives, the water heater information request information described above is transmitted from the water heater control device 1 to the water heater 3 (step S31). On the other hand, when the water heater 3 receives the water heater information request information, it generates water heater information including hot water usage history information, hot water storage amount information, and hot water storage temperature information (step S32). The generated water heater information is then transmitted from the water heater 3 to the water heater control device 1 (step S33). At this time, the water heater control device 1 stores the hot water storage amount information and hot water storage temperature information included in the received water heater information in the hot water storage amount/temperature memory unit 134.

Next, when the water heater control device 1 determines that the amount of hot water stored in the hot water storage amount/temperature memory unit 134 based on the hot water temperature information has reached the hot water boiling start amount Ws (step S34), it calculates the amount of hot water to be boiled to store the target amount of hot water Wf in the hot water storage tank 31 of the water heater 3 (step S35). Next, the water heater control device 1 calculates the operation time of the water heater 3 based on the calculated amount of hot water to be boiled (step S36). After that, the water heater control device 1 transmits boiling start command information and operation time information indicating the calculated operation time to the water heater 3 (step S37). Meanwhile, when the water heater 3 receives the boiling start command information, it starts boiling (step S38). Here, after starting boiling, the water heater 3 performs boiling for the operation time indicated by the operation time information stored in the operation time/power consumption memory unit 345.

Furthermore, after the above-mentioned step S28, the water heater control device 1 determines that the power generation amount Pg of the power generation equipment 22 is less than the preset power generation amount threshold Pgth, or the remaining power generation time dTrf is less than the first reference time dTrfth, as shown in FIG. 12 (step S39). In this case, the water heater control device 1 calculates the power generation waiting time dTrs from the time of the above-mentioned power outage determination to the start of the next power generation period (step S40). Next, the water heater control device 1 determines that the storage amount Pba of the power storage device 23 is equal to or greater than the preset storage amount threshold Pbath and the power generation waiting time dTrs is equal to or less than the second reference time dTrsth (step S41). In this case, the water heater control device 1 updates the boiling start water volume Ws and the target water volume Wf by decreasing the boiling start water volume Ws and the target water volume Wf so that the difference between the boiling start water volume Ws and the target water volume Wf becomes the second reference water volume (step S42).

Furthermore, suppose that after step S40, the water heater control device 1 determines that the storage amount Pba of the power storage device 23 is less than the storage amount threshold Pbath, or that the power generation waiting time dTrs is longer than the second reference time dTrsth (step S43). In this case, when the water heater 3 receives a boiling start operation from the user to manually start boiling, the water heater 3 starts boiling (step S44).

After that, when the time to obtain grid power arrives again, the above-mentioned power request information is transmitted from the water heater control device 1 to the power measurement device 7 (step S45). On the other hand, when the power measurement device 7 receives the power request information, it generates power information indicating the power supplied from the grid power source 21 to the distribution board 6 (step S46). Next, the generated power information is transmitted from the power measurement device 7 to the water heater control device 1 (step S47). Next, as shown in FIG. 13, it is assumed that the water heater control device 1 determines based on the power information that the power Pp supplied from the grid power source 21 to the distribution board 6 has become equal to or greater than the preset power threshold Ppth (step S48). In this case, the water heater control device 1 transmits restoration notification information to the terminal device 5 to notify the user that the power supplied from the grid power source 21 to the distribution board 6 has been restored (step S49). On the other hand, when the terminal device 5 receives the restoration notification information, it displays the received restoration notification information on the display unit 504 (step S50). At this time, the terminal device 5 displays, on the display unit 504, an operation screen image GA12 including message information M12 for notifying the user that power supplied from the system power supply 21 has been restored, as shown in FIG. 10(B), for example.

Returning to FIG. 13, next, the above-mentioned normal mode switching command information is transmitted from the water heater control device 1 to the water heater 3 (step S51). Meanwhile, upon receiving the normal mode switching command information, the water heater 3 sets the operation mode to the normal mode (step S52). Thereafter, the water heater 3 again starts operating according to the schedule information stored in the schedule memory unit 344.

Next, the water heater control process executed by the water heater control device 1 according to this embodiment will be described with reference to Figs. 14 to 16. This water heater control process is started when power is applied to the water heater control device 1. First, as shown in Fig. 14, the water heater information acquisition unit 115 determines whether or not the schedule generation time has arrived (step S101). If the water heater information acquisition unit 115 determines that the schedule generation time has not yet arrived (step S101: No), the process of step S108 described below is executed. On the other hand, if the water heater information acquisition unit 115 determines that the schedule generation time has arrived (step S101: Yes), it transmits water heater information request information to the water heater 3 (step S102). Then, the water heater information acquisition unit 115 acquires the water heater information transmitted from the water heater 3 in response to the water heater information request information, stores the hot water usage history information included in the acquired water heater information in the hot water usage history storage unit 133, and stores the hot water storage volume information and hot water storage temperature information included in the acquired water heater information in the hot water storage volume/temperature storage unit 134 (step S103).

Next, the hot water usage prediction unit 120 predicts the amount of hot water usage in the building in which the water heater 3 is installed until the next schedule generation time based on the hot water usage history information stored in the hot water usage history memory unit 133 at a preset schedule generation time (step S104). At this time, the hot water usage prediction unit 120 notifies the start hot water usage target hot water usage setting unit 119 of information indicating the predicted hot water usage obtained by the prediction. Next, the start hot water usage target hot water usage setting unit 119 sets the boiling start hot water usage Ws, which is the amount of hot water stored in the hot water storage tank 31 when boiling of hot water starts during operation in the power failure automatic boiling mode, and the target hot water usage Wf to be stored in the hot water storage tank 31 by starting boiling of hot water, based on the information indicating the predicted hot water usage notified from the hot water usage prediction unit 120 (step S105). Here, the start water volume target water volume setting unit 119 stores the boiling start water volume information indicating the set boiling start water volume Ws and the target water volume information indicating the target water volume Wf in the start water volume target water volume memory unit 136.

Then, the hot water boiling amount calculation unit 121 calculates the amount of hot water to be boiled by the water heater 3 by the next schedule generation time based on the hot water amount indicated by the hot water amount information stored in the hot water amount/temperature storage unit 134 and the hot water temperature indicated by the hot water temperature information, and the predicted hot water usage indicated by the information indicating the predicted hot water usage notified by the hot water usage prediction unit 120 (step S106). Next, the schedule generation unit 123 calculates the required operation time of the water heater 3 based on the hot water boiling amount calculated by the hot water boiling amount calculation unit 121, and generates schedule information indicating the operation schedule of the water heater 3 until the next schedule generation time using the calculated required operation time. Then, the schedule transmission unit 124 transmits the schedule information generated by the schedule generation unit 123 to the water heater 3 (step S107).

Next, the power acquisition unit 111 determines whether the grid power acquisition time has arrived (step S108). If the power acquisition unit 111 determines that the grid power acquisition time has not yet arrived (step S108: No), the process of step S101 is executed again. On the other hand, if the power acquisition unit 111 determines that the grid power acquisition time has arrived (step S108: Yes), it transmits power request information requesting the transmission of power information indicating the power supplied from the grid power source 21 to the distribution board 6 to the power measuring device 7 (step S109). Then, the power acquisition unit 111 acquires the power information from the power measuring device 7 (step S110). Here, the power acquisition unit 111 notifies the power status determination unit 118 of the acquired power information. Then, the power status determination unit 118 determines whether the power Pp supplied from the grid power source 21 to the distribution board 6 is less than a preset power threshold Ppth based on the power information notified from the power acquisition unit 111 (step S111). When the power supply state determination unit 118 determines that the power Pp supplied from the system power source 21 to the distribution board 6 is less than the power threshold Ppth (step S111: Yes), the power supply state determination unit 118 increments the count value Cs of the power failure determination counter by 1 (step S112). Next, the power supply state determination unit 118 determines whether the count value Cs of the power failure determination counter is equal to or greater than the preset count threshold Csth (step S113). When the power supply state determination unit 118 determines that the count value Cs is less than the count threshold Csth (step S113: No), the process of step S108 is executed again. On the other hand, when the power supply state determination unit 118 determines that the count value Cs is equal to or greater than the count threshold Csth (step S113: Yes), it is determined that the state in which the power Pp supplied from the system power source 21 to the distribution board 6 is less than the preset power threshold Ppth has continued for a preset reference time or more. If the time required to execute the series of processes from step S108 to S113 is 1 minute, the count threshold Csth is set to "10". In this case, the reference time is 10 minutes. The notification unit 125 then generates power outage notification information and transmits it to the terminal device 5 (step S114). Next, the power supply status determination unit 118 sets the power outage flag information stored in the power supply status storage unit 135 to flag information "Fps1" indicating a power outage (step S115).

When the power supply state determination unit 118 determines that the power Pp supplied from the system power source 21 to the distribution board 6 is equal to or greater than the power threshold Ppth (step S111: No), it resets the count value Cs of the power failure determination counter to "0" (step S116). After that, the power supply state determination unit 118 determines whether the power failure flag information stored in the power supply state storage unit 135 is set to the flag information "Fps1" (step S117). When the power supply state determination unit 118 determines that the power failure flag information stored in the power supply state storage unit 135 is set to the flag information "Fps0" indicating that power is being supplied from the system power source 21 (step S117: No), the process of step S120 described later is executed as is. On the other hand, it is assumed that the power supply state determination unit 118 determines that the power failure flag information stored in the power supply state storage unit 135 is set to the flag information "Fps1" (step S117: Yes). In this case, the notification unit 125 generates recovery notification information and transmits it to the terminal device 5 (step S118). Next, the power supply state determination unit 118 sets the power failure flag information stored in the power supply state storage unit 135 to the above-mentioned flag information "Fps0" (step S119). Next, the command unit 122 transmits normal mode switching command information to the water heater 3 (step S120). At this time, the water heater 3 switches the operation mode to the normal mode.

After that, as shown in FIG. 15, the command unit 122 determines whether the power failure flag information stored in the power supply state storage unit 135 is set to the flag information "Fps1" (step S121). When the command unit 122 determines that the power failure flag information is set to the flag information "Fps0" (step S121: No), the process of step S101 is executed again. On the other hand, when the command unit 122 determines that the power failure flag information is set to the flag information "Fps1" (step S121: Yes), it transmits power failure mode switching command information to the water heater 3 (step S122). At this time, the command unit 122 notifies the boiling water amount calculation unit 121 of the power failure mode switching notification information described above. Then, when the water heater 3 receives the power failure mode switching command information, it sets the operation mode to the power failure mode. Next, the power generation amount acquisition unit 112 transmits the power generation amount request information to the power conditioner 4 (step S123). As a result, the power generation amount acquisition unit 112 acquires the power generation amount information transmitted from the power conditioner 4 (step S124). Here, the power generation amount acquisition unit 112 notifies the power supply state determination unit 118 of the acquired power generation amount information.

Next, the power generation amount history acquisition unit 116 transmits the power generation amount history request information to the power generation amount management server 8 (step S125). As a result, the power generation amount history acquisition unit 116 acquires the power generation amount history information from the power generation amount management server 8 and stores the acquired power generation amount history information in the power generation amount history storage unit 131 (step S126). Next, the weather forecast acquisition unit 126 transmits the weather forecast request information to the weather server 10 (step S127). As a result, the weather forecast acquisition unit 126 acquires weather forecast information from the weather server 10 and stores the acquired weather forecast information in the weather forecast storage unit 132 (step S128). After that, the power generation amount prediction unit 117 predicts the transition of the power generation amount in the power generation facility 22 in a future preset period based on the weather forecast information stored in the weather forecast storage unit 132 and the power generation amount history information stored in the power generation amount history storage unit 131 (step S129). Next, the power generation amount prediction unit 117 identifies a power generation period of the power generation facility 22 from the transition of the predicted power generation amount (step S130). Here, the power generation amount prediction unit 117 identifies a power generation period during which the power generation amount of the power generation facility 22 is equal to or greater than a preset power generation amount threshold. In addition, the power generation amount prediction unit 117 stores information indicating the start and end of the identified power generation period in the power generation amount prediction storage unit 137.

Next, the time determination unit 127 refers to the information indicating the end of the power generation period stored in the power generation amount prediction storage unit 137 and calculates the remaining power generation time dTrf from the time of the power outage determination when the power supply state determination unit 118 determines that the power supplied from the grid power supply 21 has been cut off to the end of the power generation period (step S131). After that, the power supply state determination unit 118 determines whether the power generation amount Pg of the power generation facility 22 is equal to or greater than the power generation amount threshold Pgth, and the time determination unit 127 determines whether the remaining power generation time dTrf is equal to or greater than the first reference time dTrfth (step S132). If the power supply state determination unit 118 determines that the power generation amount Pg of the power generation facility 22 is less than the power generation amount threshold Pgth, or if the time determination unit 127 determines that the remaining power generation time dTrf is less than the first reference time dTrfth (step S132: No), the process of step 134 described later is executed. On the other hand, suppose that the power supply state determination unit 118 determines that the power generation amount Pg of the power generation equipment 22 is equal to or greater than the power generation amount threshold Pgth, and the time determination unit 127 determines that the remaining power generation time dTrf is equal to or greater than the first reference time dTrfth (step S132: Yes). In this case, the start water volume target water volume setting unit 119 updates the water volume Ws to start boiling and the target water volume Wf by increasing the water volume Ws to start boiling and the target water volume Wf so that the difference between the water volume Ws to start boiling and the target water volume Wf becomes the first reference water volume (step S133). Here, the water volume Ws to start boiling and the target water volume Wf are increased from the state as shown in FIG. 16(A), for example, so that the difference between them becomes the first reference water volume dWsf1, as shown in FIG. 16(B). Here, the first reference water volume dWsf1 is set to be equal to the water volume that the water heater 3 can boil in one hour, for example.

Returning to FIG. 15, the process of step S137 described later is then executed. Also, in step S132, the power supply state determination unit 118 determines that the power generation amount Pg of the power generation equipment 22 is less than the power generation amount threshold Pgth, or the time determination unit 127 determines that the remaining power generation time dTrf is less than the first reference time dTrfth (step S132: No). In this case, as shown in FIG. 17, the time determination unit 127 calculates the power generation waiting time dTrs from the time of the power failure determination by the power supply state determination unit 118 to the start of the next power generation period (step S134). Then, the power supply state determination unit 118 determines whether the storage amount Pba of the power storage device 23 is equal to or greater than the preset storage amount threshold Pbath, and the time determination unit 127 determines whether the power generation waiting time dTrs is equal to or less than the second reference time dTrsth (step S135). Here, it is assumed that the power supply state determination unit 118 has determined that the power storage amount Pba of the power storage device 23 is less than the power storage amount threshold Pbath, or the time determination unit 127 has determined that the power generation waiting time dTrs is longer than the second reference time dTrsth (step S135: No). In this case, the process of step S101 is executed again.

On the other hand, suppose that the power supply state determination unit 118 determines that the storage amount Pba of the power storage device 23 is equal to or greater than the preset storage amount threshold Pbath, and the time determination unit 127 determines that the power generation waiting time dTrs is equal to or less than the second reference time dTrsth (step S135: Yes). In this case, the start water volume target water volume setting unit 119 updates the water volume Ws to start boiling and the target water volume Wf by decreasing the water volume Ws to start boiling and the target water volume Wf so that the difference between the water volume Ws to start boiling and the target water volume Wf becomes the second reference water volume (step S136). Here, the water volume Ws to start boiling and the target water volume Wf are decreased so that the difference between them becomes the second reference water volume dWsf2, as shown in FIG. 16(C), for example. Here, the second reference water volume dWsf2 is set to be equal to, for example, the amount of water used in one shower (e.g., 80 L) or the amount of water required to fill a bathtub (e.g., 180 L).

Returning to FIG. 17, the water heater information acquisition unit 115 next determines whether or not the pre-set water heater information acquisition time has arrived (step S137). Here, if the water heater information acquisition unit 115 determines that the water heater information acquisition time has not yet arrived (step S137: No), the process of step S101 is executed again. On the other hand, if the water heater information acquisition unit 115 determines that the water heater information acquisition time has arrived (step S137: Yes), it transmits water heater information request information to the water heater 3 (step S138). Then, the water heater information acquisition unit 115 acquires the water heater information transmitted from the water heater 3 in response to the water heater information request information, stores the hot water usage history information included in the acquired water heater information in the hot water usage history storage unit 133, and stores the hot water storage volume information and hot water storage temperature information included in the acquired water heater information in the hot water storage volume/temperature storage unit 134 (step S139). Next, the boiling hot water amount calculation unit 121 judges whether the amount of hot water stored in the hot water storage tank 31 indicated by the hot water amount information stored in the hot water storage amount/temperature storage unit 134 has reached the boiling start hot water amount Ws indicated by the boiling start hot water amount information (step S140). If the boiling hot water amount calculation unit 121 judges that the amount of hot water stored in the hot water storage tank 31 has not reached the boiling start hot water amount Ws (step S140: No), the process of step S101 is executed again. On the other hand, it is assumed that the boiling hot water amount calculation unit 121 judges that the amount of hot water stored in the hot water storage tank 31 has reached the boiling start hot water amount Ws (step S140: Yes). In this case, the boiling hot water amount calculation unit 121 judges whether the power outage flag information stored in the power supply state storage unit 135 is set to the flag information "Fps1" (step S141). If the boiling hot water volume calculation unit 121 determines that the power outage flag information is set to flag information "Fps0" (step S141: No), the process of step S101 is executed again. On the other hand, if the boiling hot water volume calculation unit 121 determines that the power outage flag information is set to flag information "Fps1" (step S141: Yes), the boiling hot water volume calculation unit 121 refers to the target hot water volume information stored in the start hot water volume target hot water volume storage unit 136 and calculates the amount of boiling hot water that should be boiled by the water heater 3 to store the target amount of hot water in the hot water storage tank 31 (step S142).

Then, the command unit 122 calculates the operation time of the water heater 3 based on the amount of hot water to be boiled calculated by the hot water amount calculation unit 121 (step S143). Next, the command unit 122 transmits boiling start command information and operation time information indicating the calculated operation time to the water heater 3 (step S144). At this time, when the water heater 3 receives the boiling start command information, it starts boiling, and performs boiling for the operation time indicated by the aforementioned operation time information from the start of boiling. Next, the processing of step S101 is executed again.

As described above, according to the water heater control device 1 of this embodiment, the power supply state determination unit 118 determines whether the power supplied from the system power supply 21 has been cut off based on the power information indicating the power supplied from the system power supply 21. Then, when the power supply state determination unit 118 determines that the power supplied from the system power supply 21 has been cut off, the command unit 122 commands the water heater 3 to operate in an operation mode in which the amount of hot water continuously boiled by the water heater 3 is small, according to the amount of power generation indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information. This makes it possible to reduce the power consumption per boiling operation by the amount of hot water continuously boiled by the water heater 3 during a power outage, thereby suppressing a shortage of power supplied to electrical equipment 11 other than the water heater 3, and furthermore, since the water heater 3 continues to boil hot water even during a power outage, it is possible to suppress the occurrence of a hot water shortage.

The start hot water volume target hot water volume setting unit 119 according to this embodiment sets the hot water volume to start boiling and the target hot water volume based on hot water volume history information indicating the history of the past hot water volumes used, and when the power status determination unit 118 determines that the power supplied from the grid power source 21 has been cut off, updates the hot water volume to start boiling and the target hot water volume based on the amount of power generated by the power generation equipment 22 and the amount of power stored in the power storage device 23. Specifically, when the amount of power generated by the power generation equipment 22 is equal to or greater than the reference power generation amount and the remaining power generation time from the time of the power outage determination to the end of the power generation period is equal to or greater than the first reference time, the start hot water volume target hot water volume setting unit 119 increases the hot water volume to start boiling and the target hot water volume so that the difference between the hot water volume to start boiling and the target hot water volume becomes the first reference hot water volume. This makes it possible to increase the frequency of hot water boiling by the water heater 3 during the power generation period of the power generation equipment 22, so that a sufficient amount of hot water can be secured for use even during a power outage.

Furthermore, in the present embodiment, when the power supply state determination unit 118 determines that the power supplied from the grid power supply 21 has been cut off, if the amount of power generated by the power generation facility 22 is less than the reference power generation amount or the remaining power generation time is less than the first reference time, and if the amount of power stored in the power storage device 23 is equal to or greater than the reference power storage amount and the power generation waiting time from the time of the power outage determination to the start of the next power generation period is equal to or less than the second reference time, the start hot water volume target hot water volume setting unit 119 reduces the start hot water volume and the target hot water volume so that the difference between the start hot water volume and the target hot water volume becomes the second reference hot water volume. As a result, when power generation by the power generation facility 22 is expected in the near future, the hot water can be boiled by the water heater 3 using electricity supplied from the power storage device 23, and the electricity stored in the power storage device 23 can be used efficiently.

(Embodiment 2)
The water heater control device according to this embodiment differs from embodiment 1 in that it includes a water heater power consumption setting unit that sets the water heater power consumption consumed when boiling hot water based on the amount of power generated by the power generation equipment and the amount of power stored in the power storage device when the power supply state determination unit determines that the power supplied from the grid power supply has been cut off. Then, when the power supply state determination unit determines that the power supplied from the grid power supply has been cut off, the command unit commands the water heater to operate in an operation mode in which the water heater boils hot water at a speed slower than the water heater boiling speed when power is supplied from the grid power supply, based on the amount of power generated indicated by the power generation amount information and the amount of power stored indicated by the power storage amount information.

The hardware configuration of the hot water supply system according to this embodiment is the same as the hardware configuration described in embodiment 1. The functional configuration of the controller 33 and the terminal device 5 of the hot water supply device 3 according to this embodiment is also the same as that of embodiment 1. In the following description of this embodiment, the same components as those of embodiment 1 are described using the same reference numerals as appropriate. When the command information receiving unit 333 of the controller 33 receives boiling power consumption information indicating the set power consumption during the boiling operation of the hot water supply device 3 from the hot water supply device control device 1, the command information receiving unit 333 notifies the heat pump control unit 332 of the received boiling power consumption information. Furthermore, when operating in the power failure automatic boiling mode, the heat pump control unit 332 operates the heat pump unit 32 so that the power consumption of the hot water supply device 3 becomes the set power consumption indicated by the boiling power consumption information input from the command information receiving unit 333.

As shown in Fig. 18, the CPU 101 of the water heater control device 2001 reads out the programs stored in the auxiliary memory unit 103 into the main memory unit 102 and executes them, thereby functioning as a power acquisition unit 111, a power generation amount acquisition unit 112, a power generation amount transmission unit 113, a stored power amount acquisition unit 114, a water heater information acquisition unit 115, a power generation amount history acquisition unit 116, a power generation amount prediction unit 117, a power supply state determination unit 118, a starting hot water amount target hot water amount setting unit 2119, a hot water usage prediction unit 120, a hot water boiling amount calculation unit 121, a command unit 2122, a schedule generation unit 123, a schedule transmission unit 124, an alarm unit 125, a weather forecast acquisition unit 126 and a hot water boiling power consumption setting unit 2125. Note that in Fig. 18, the same components as those in embodiment 1 are given the same reference numerals as those in Fig. 5. As shown in FIG. 18, the auxiliary memory unit 103 of the water heater control device 2001 includes a power generation history memory unit 131, a weather forecast memory unit 132, a hot water usage history memory unit 133, a hot water storage volume/temperature memory unit 134, a power supply status memory unit 135, a starting hot water volume target memory unit 136, a power generation forecast memory unit 137, a schedule memory unit 138, and a boiling power consumption memory unit 2136.

As shown in FIG. 19, for example, the boiling power consumption memory unit 2136 stores boiling power consumption information indicating the power consumption in the water heater 3 corresponding to each of the ranges of the remaining power generation time dTrf of multiple types (three types in FIG. 19) set in advance, in association with the information indicating the range of the remaining power generation time dTrf. In FIG. 19, "Pb1" and "Pb2" correspond to the first boiling power consumption in the water heater 3 when power is supplied from the system power source 21. The relationship of dTrfth1<dTrfth2 and C1>C2 is established. Here, C1 and C2 are set to, for example, "0.8" and "0.6". Furthermore, Pb1×C1 corresponds to the second boiling power consumption smaller than the first boiling power consumption, and Pb1×C2 corresponds to the third boiling power consumption smaller than the second boiling power consumption. In addition, the water heating power consumption memory unit 2136 stores water heating power consumption information indicating the power consumption of the water heater 3 corresponding to each of multiple preset ranges of the power generation waiting time dTrs (three ranges in FIG. 19), in association with information indicating the range of the power generation waiting time dTrs. In FIG. 19, the relationship dTrsth1<dTrsth2 and C3>C4 is established. Here, C3 and C4 are set to, for example, "0.8" and "0.6".

The start water volume target water volume setting unit 2119 sets the water volume to start boiling and the target water volume when operating in power failure automatic boiling mode, based on the predicted water volume to be used notified by the water volume usage prediction unit 120. The start water volume target water volume setting unit 2119 then stores boiling start water volume information indicating the water volume to start boiling and target water volume information indicating the target water volume in the start water volume target water volume memory unit 136.

When the power supply state determination unit 118 determines that the power supplied from the grid power supply 21 has been cut off, the water heating power consumption setting unit 2125 sets the water heating power consumption, which is the power consumption consumed by the water heater 3 when boiling water, to the water heating power consumption corresponding to the water heating speed of the water heater 3 according to the amount of power generated by the power generation facility 22 and the amount of power stored in the power storage device 23. Here, when the amount of power generated by the power generation facility 22 is equal to or greater than the reference amount of power generation, the water heating power consumption setting unit 2125 refers to the water heating power consumption information stored in the water heating power consumption storage unit 2136 and sets the water heating power consumption according to the length of the remaining power generation time from the time of power outage determination to the end of the power generation period calculated by the time determination unit 127. When the remaining power generation time from the time of power outage determination to the end of the power generation period is equal to or greater than a third reference time set in advance and less than a fourth reference time longer than the third reference time, the water heating power consumption setting unit 2125 sets the water heating power consumption to a second water heating power consumption smaller than the first water heating power consumption when power is supplied from the grid power supply. Then, when the remaining power generation time is equal to or longer than the fourth reference time, the water heating power consumption setting unit 2125 sets the water heating power consumption to the third water heating power consumption, which is smaller than the second water heating power consumption. Here, the speed at which the water heater 3 heats up becomes slower as the magnitude of the water heating power consumption becomes smaller. Therefore, the water heating speed of the water heater 3 when the water heating power consumption setting unit 2125 sets the water heating power consumption to the second water heating power consumption or the third water heating power consumption is slower than the water heating speed when the water heating power consumption setting unit 2125 sets the water heating power consumption to the first water heating power consumption. Furthermore, when the amount of power generated by the power generation facility 22 is less than the reference power generation amount, or the length of the period from the power outage determination time to the end of the power generation period is less than the first reference time, and the amount of power stored in the power storage device 23 is equal to or greater than a preset reference amount of power storage, the water boiling power consumption setting unit 2125 refers to the water boiling power consumption information stored in the water boiling power consumption memory unit 2136 and sets the water boiling power consumption according to the length of the power generation waiting time from the power outage determination time to the start of the power generation period calculated by the time determination unit 127. Then, the water boiling power consumption setting unit 2125 notifies the command unit 2122 of the water boiling power consumption information indicating the set water boiling power consumption.

When the power supply state determination unit 118 determines that the power supplied from the grid power supply 21 has been cut off by referring to the power failure flag information stored in the power supply state storage unit 135, the command unit 2122 commands the water heater 3 to operate in an operation mode in which the water heating speed of the water heater 3 is slower than the water heating speed when power is supplied from the grid power supply 21, according to the amount of power generated by the power generation facility 22 indicated by the power generation amount information and the amount of power stored in the power storage device 23 indicated by the power storage amount information. Specifically, the command unit 2122 commands the water heater 3 to operate with a water heating power consumption according to the amount of power generated by the power generation facility 22 indicated by the power generation amount information and the amount of power stored in the power storage device 23 indicated by the power storage amount information. When the power supplied from the grid power supply 21 is cut off, the command unit 2122 transmits water heating power consumption information to the water heater 3 together with power failure mode switching command information.

Next, the water heater control process executed by the water heater control device 2001 according to this embodiment will be described with reference to FIG. 20 to FIG. 22. In FIG. 20 and FIG. 22, the same processes as those in the first embodiment are denoted by the same reference numerals as those in FIG. 14, FIG. 15, and FIG. 17. First, a series of processes from step S101 to S130 is executed. Then, after the process of step S130 is executed, the power supply state determination unit 118 determines whether the power generation amount Pg of the power generation facility 22 is equal to or greater than the power generation amount threshold Pgth (step S2101). Here, if the power supply state determination unit 118 determines that the power generation amount Pg of the power generation facility 22 is less than the power generation amount threshold Pgth (step S2101: No), the process of step 2104 described later is executed. On the other hand, it is assumed that the power supply state determination unit 118 determines that the power generation amount Pg of the power generation facility 22 is equal to or greater than the power generation amount threshold Pgth (step S2101: Yes). In this case, the time determination unit 127 refers to the information indicating the end of the power generation period stored in the power generation amount prediction storage unit 137, and calculates the remaining power generation time dTrf from the power outage determination time when the power supply state determination unit 118 determines that the power supplied from the grid power supply 21 has been cut off to the end of the power generation period (step S2102). Next, the boiling power consumption setting unit 2125 refers to the boiling power consumption information stored in the boiling power consumption storage unit 2136, and sets the boiling power consumption according to the length of the remaining power generation time dTrf from the power outage determination time to the end of the power generation period calculated by the time determination unit 127 (step S2103). Here, it is assumed that the boiling power consumption storage unit 2136 stores boiling power consumption information and remaining power generation time information in association with each other, for example, as shown in FIG. 19. Then, as shown in FIG. 21A, for example, when the remaining power generation period Trf[1] from the power failure determination time T1 to the end of the power generation period Tf is less than the remaining power generation time threshold dTrfth1, the boiling power consumption setting unit 2125 sets the boiling power consumption to Pb1×C1, which is smaller than Pb1, when the remaining power generation period Trf[2] from the power failure determination time T2 to the end of the power generation period Tf is equal to or greater than the time dTrfth1 and less than the time dTrfth2. Furthermore, when the remaining power generation period Trf[2] from the power failure determination time T2 to the end of the power generation period Tf is equal to or greater than the time dTrfth2, the boiling power consumption setting unit 2125 sets the boiling power consumption to Pb1×C2, which is smaller than Pb1×C1. In addition, the boiling power consumption setting unit 2125 notifies the command unit 2122 of boiling power consumption information indicating the set boiling power consumption.

20, it is assumed that in step S2101, the power supply state determination unit 118 determines that the power generation amount Pg of the power generation facility 22 is less than the power generation amount threshold Pgth (step S2101: No). In this case, as shown in FIG. 22, the power supply state determination unit 118 determines whether the storage amount Pba of the power storage device 23 is equal to or greater than the preset storage amount threshold Pbath (step S2104). Here, it is assumed that the power supply state determination unit 118 determines that the storage amount Pba of the power storage device 23 is equal to or greater than the preset storage amount threshold Pbath (step S2104: Yes). In this case, the time determination unit 127 calculates the power generation waiting time dTrs from the time when the power supply state determination unit 118 determines that there is a power outage to the start of the next power generation period (step S2105). Thereafter, the boiling power consumption setting unit 2125 refers to the boiling power consumption information stored in the boiling power consumption storage unit 2136 and sets the boiling power consumption according to the length of the power generation waiting time dTrs from the time of power failure determination to the start of the next power generation period calculated by the time determination unit 127 (step S2106). Here, it is assumed that the boiling power consumption storage unit 2136 stores boiling power consumption information and remaining power generation time information in association with each other, for example, as shown in FIG. 19. Then, the boiling power consumption setting unit 2125 sets the boiling power consumption to Pb2 when the remaining power generation period Trs[1] from the time of power failure determination T1 to the start of the next power generation period Ts is less than the remaining power generation time threshold dTrsth1, for example, as shown in FIG. 21(B). Furthermore, when the power generation waiting period Trf[2] from the power outage determination time T2 to the start time Ts of the next power generation period is equal to or longer than the time dTrsth1 and shorter than the time dTrsth2, the water boiling power consumption setting unit 2125 sets the water boiling power consumption to Pb2×C3, which is smaller than Pb2. Furthermore, when the remaining power generation period Trs[3] from the power outage determination time T3 to the start time Ts of the next power generation period is equal to or longer than the time dTrsth3, the water boiling power consumption setting unit 2125 sets the water boiling power consumption to Pb2×C4, which is smaller than Pb2×C3. Furthermore, the water boiling power consumption setting unit 2125 notifies the command unit 2122 of water boiling power consumption information indicating the set water boiling power consumption.

Returning to FIG. 22, next, the processing from step S137 onwards is executed. Also, in step S2104, it is assumed that the power supply state determination unit 118 determines that the storage amount Pba of the power storage device 23 is less than the preset storage amount threshold Pbath (step S2104: No). In this case, the processing of step S101 is executed as is.

As described above, according to the water heater control device 2001 of this embodiment, when the power supply state determination unit 118 determines that the power supplied from the grid power supply 21 has been cut off, the water heater power consumption setting unit 2125 sets the water heater power consumption consumed when the water heater 3 boils water based on the amount of power generated by the power generation facility 22 and the amount of power stored in the power storage device 23. Here, the water heater power consumption setting unit 2125 sets the water heater power consumption so that the power consumption by the water heater 3 decreases the longer the remaining power generation time or the power generation waiting time. This makes it possible to prevent a shortage of power supplied to electrical equipment 11 other than the water heater 3, and prevents the occurrence of a hot water shortage because the water heater 3 continues to boil water during the power generation period during a power outage.

(Embodiment 3)
The water heater control device of this embodiment differs from embodiment 1 in that the power supply state determination unit determines whether the power consumption of electrical equipment other than the water heater is greater than or equal to a predetermined power consumption threshold, and if the command unit determines that the power consumption of electrical equipment other than the water heater is greater than or equal to the power consumption threshold, it commands the water heater to operate in an operating mode in which the water heater can only be operated manually.

The hardware configuration of the hot water supply system according to this embodiment is the same as the hardware configuration described in embodiment 1. The functional configuration of the controller 33 and the terminal device 5 of the hot water supply device 3 according to this embodiment is also the same as that of embodiment 1. In the following description of this embodiment, the same components as those of embodiment 1 will be described using the same reference numerals as appropriate. As shown in FIG. 23, the CPU 101 of the hot water supply device control device 3001 reads the program stored in the auxiliary storage unit 103 into the main storage unit 102 and executes it, thereby functioning as a power acquisition unit 3111, a power generation amount acquisition unit 112, a power generation amount transmission unit 113, a storage amount acquisition unit 114, a hot water supply device information acquisition unit 115, a power generation amount history acquisition unit 116, a power generation amount prediction unit 117, a power supply state determination unit 3118, a starting hot water amount target hot water amount setting unit 119, a hot water amount used prediction unit 120, a hot water amount calculation unit 121, a command unit 3122, a schedule generation unit 123, a schedule transmission unit 124, a notification unit 125, and a weather forecast acquisition unit 126. In addition, in Fig. 22, the same components as those in the first embodiment are given the same reference numerals as those in Fig. 5. As shown in Fig. 23, the auxiliary memory unit 103 of the water heater control device 2001 has a power generation amount history memory unit 131, a weather forecast memory unit 132, a hot water usage amount history memory unit 133, a hot water storage amount/temperature memory unit 134, a power supply state memory unit 135, a starting hot water amount target hot water amount memory unit 136, a power generation amount prediction memory unit 137, a schedule memory unit 138, and a power consumption threshold memory unit 3137.

The power consumption threshold memory unit 3137 stores power consumption threshold information indicating a power consumption threshold preset for the power consumption of electrical appliances 11 other than the water heater 3 that is the criterion for switching the water heater 3 to power failure manual heating mode.

The power acquisition unit 3111 acquires from the power measurement device 7 power grid information indicating the power supplied from the power grid 21 to the distribution board 6, as well as power consumption information indicating the power supplied from the distribution board 6 to the electrical device 11, i.e., the power consumption information indicating the power consumption in the electrical device 11. When the power acquisition unit 3111 determines that a preset grid power acquisition time has arrived based on the date and time measured by the clock unit 108, the power acquisition unit 3111 acquires the grid power information and power consumption information transmitted from the power measurement device 7 by transmitting power request information to the power measurement device 7 requesting the transmission of grid power information and power consumption information to the power measurement device 7. The power acquisition unit 3111 then notifies the power supply status determination unit 3118 of the acquired grid power information and power consumption information.

The power supply state determination unit 3118 determines whether or not the power supply from the power grid 21 to the distribution board 6 has been cut off based on the power grid information notified by the power acquisition unit 111. The power supply state determination unit 118 also compares the power consumption threshold indicated by the power consumption threshold information stored in the power consumption threshold storage unit 3137 with the power consumption in the electrical device 11 indicated by the power consumption information notified by the power acquisition unit 111, and determines whether or not the power consumption in the electrical device 11 is equal to or greater than the power consumption threshold.

When the power supply state determination unit 118 determines that the power consumption of the electrical device 11 is equal to or greater than the power consumption threshold, the command unit 3122 avoids sending a command to start boiling water to the water heater 3.

Next, the operation schedule generation process executed by the hot water supply control device 3001 according to this embodiment will be described with reference to FIG. 24. In FIG. 24, the same processes as those in the first embodiment are denoted by the same reference numerals as those in FIG. 14, FIG. 15, and FIG. 17. First, a series of processes from steps S101 to S108 are executed, and when the power acquisition unit 111 determines that the time for acquiring grid power has arrived (step S108: Yes), it transmits power request information requesting the transmission of the grid power information and power consumption information to the power measurement device 7 (step S109). Then, the power acquisition unit 111 acquires the grid power information and power consumption information from the power measurement device 7 (step S110). Next, a series of processes from steps S111 to S121 are executed, and it is assumed that the power generation amount acquisition unit 112 determines that the power failure flag information is set to the flag information "Fps1" (step S121: Yes). In this case, the power supply state determination unit 3118 determines whether the power consumption Pe of the electrical device 11 indicated by the power consumption information is equal to or greater than the power consumption threshold Peth1 (step S3101). If the power supply state determination unit 3118 determines that the power consumption Pe is less than the power consumption threshold Peth1 (step S3101: No), the process proceeds to step S122 and thereafter. On the other hand, if the power supply state determination unit 3118 determines that the power consumption Pe is equal to or greater than the power consumption threshold Peth1 (step S3101: Yes), the process proceeds to step S101 again.

However, when the power supplied from the grid power supply 21 is cut off, if the water heater 3 is operated when the power consumption of the electrical equipment 11 other than the water heater 3 is equal to or greater than a preset power consumption threshold, there is a risk that the power supply capacity of the entire power generation equipment 22 and the power storage device 23 will be exceeded. In response to this, according to the water heater control device 3001 of this embodiment, the power acquisition unit 3111 acquires power consumption information indicating the power consumption of the electrical equipment 11 other than the water heater 3, and the power supply state determination unit 3118 determines whether the power consumption Pe indicated by the power consumption information is equal to or greater than the power consumption threshold Peth1. Then, when the command unit 3122 determines that the power consumption Pe is equal to or greater than the power consumption threshold Peth1, it commands the water heater 3 to operate in an operation mode in which the water heater 3 can only be operated manually, i.e., the power failure manual heating mode. This prevents the power consumption of the water heater 3 and the electrical equipment 11 from exceeding the power supply capacity of the entire power generation equipment 22 and the power storage device 23, thereby preventing excessive loads from occurring on the power generation equipment 22 and the power storage device 23.

(Embodiment 4)
The water heater according to this embodiment differs from the water heater according to the first embodiment in that it has a drain pipe communicating with the inside of the hot water storage tank for discharging hot water stored in the hot water storage tank to the outside of the hot water storage tank, an opening/closing valve inserted in the drain pipe, and a valve control unit for controlling the opening/closing valve. The water heater control device according to this embodiment also differs in that it has a water heater information acquisition unit for acquiring water heater information including stored hot water temperature information indicating the temperature of hot water stored in the hot water storage tank. The command unit according to this embodiment transmits, when the power supply state determination unit determines that the power supplied from the system power supply has been cut off, close command information to the water heater that commands the opening/closing valve to be in a closed state when the hot water temperature indicated by the stored hot water temperature information is equal to or higher than a preset reference temperature, and transmits open command information to the water heater that commands the opening/closing valve to be in an open state when the hot water temperature indicated by the stored hot water temperature information is lower than the reference temperature. On the other hand, when the valve control unit of the water heater receives close command information from the water heater control device, it maintains the opening and closing valve in a closed state, and when it receives open command information from the water heater control device, it maintains the opening and closing valve in an open state.

25, the water heater 4003 according to this embodiment has a drain pipe PI3 that communicates with the hot water storage tank 31 and drains the hot water stored in the hot water storage tank 31 out of the hot water storage tank 31, an opening and closing valve V51 inserted in the drain pipe PI3, and a water intake valve V52 provided at the tip of the drain pipe PI3. The opening and closing valve V51 opens and closes in response to a control signal input from the controller 4033. In FIG. 24, the same components as those in the water heater 3 according to the first embodiment are denoted by the same reference numerals as those in FIG. 2. The controller 4033 has the same hardware configuration as that in the first embodiment as shown in FIG. 3, and the opening and closing valve V51 is communicably connected to the communication interface 310. Here, the CPU 301 loads the program stored in the auxiliary storage unit 303 into the main storage unit 302 and executes it, thereby functioning as a schedule receiving unit 331, a heat pump control unit 332, a command information receiving unit 333, a water heater information transmitting unit 4334, a hot water usage history generating unit 335, a hot water usage acquisition unit 336, a hot water storage volume acquisition unit 337, a hot water storage temperature acquisition unit 338, a valve control unit 4339, and an operating state acquisition unit 4351, as shown in FIG. 26. Note that in FIG. 26, the same components as those in the first embodiment are given the same reference numerals as in FIG. 4. Also, the auxiliary storage unit 303 shown in FIG. 3 has a hot water usage history storage unit 342, a hot water storage volume/temperature storage unit 343, a schedule storage unit 344, and an operating time/power consumption storage unit 345, as shown in FIG. 26.

When the valve control unit 4339 receives the close command information transmitted from the water heater control device, it outputs a control signal to the open/close valve V51 to maintain the open/close valve V51 in a closed state. On the other hand, when the valve control unit 4339 receives the open command information transmitted from the water heater control device, it outputs a control signal to the open/close valve V51 to maintain the open/close valve V51 in an open state. When the heat pump control unit 332 stops the heat pump unit 32, the operation state acquisition unit 4351 generates stop notification information and notifies the water heater information transmission unit 4334, and when the heat pump control unit 332 operates the heat pump unit 32, it generates operation notification information and notifies the water heater information transmission unit 4334. Then, when the water heater information transmission unit 4334 is notified of the stop notification information or operation notification information from the operation state acquisition unit 4351, it generates water heater information including the notified stop notification information or operation notification information and transmits it to the water heater control device 4001.

The terminal device 4005 according to the present embodiment includes the CPU 501, main memory 502, auxiliary memory 503, display 504, wide area communication 506, and bus 509 as shown in FIG. 3, as well as the input unit 505 shown in FIG. 27. The input unit 505 is, for example, a transparent touch pad arranged on top of the display 504, and receives various operation information according to the user's operation and outputs the received operation information to the CPU 501. The CPU 501 reads out the program stored in the auxiliary memory 503 into the main memory 502 and executes it, thereby functioning as the notification information receiving unit 511, the display control unit 512, the reception unit 513, and the command information transmitting unit 514 as shown in FIG. 27. Note that the same reference numerals as those in FIG. 5 are used for the components in FIG. 27 that are the same as those in the first embodiment. The reception unit 513 receives the operation by the user via the input unit 505, and notifies the command information transmitting unit 514 of the operation information indicating the received operation content. The command information transmission unit 514 converts the operation information notified by the reception unit 513 into command information and transmits it to the water heater control device 4001.

The hardware configuration of the water heater control device according to this embodiment is the same as the hardware configuration described in embodiment 1 as shown in FIG. 3. As shown in FIG. 27, the CPU 101 of the water heater control device 4001 reads the program stored in the auxiliary memory unit 103 into the main memory unit 102 and executes it, thereby functioning as the power acquisition unit 111, the power generation amount acquisition unit 112, the power generation amount transmission unit 113, the stored power amount acquisition unit 114, the water heater information acquisition unit 4115, the power generation amount history acquisition unit 116, the power generation amount prediction unit 117, the power state determination unit 118, the starting hot water amount target hot water amount setting unit 119, the hot water usage prediction unit 120, the boiling hot water amount calculation unit 121, the command unit 4122, the schedule generation unit 123, the schedule transmission unit 124, the notification unit 4125, the weather forecast acquisition unit 126, and the usable hot water amount calculation unit 4128. Note that in FIG. 27, the same components as those in embodiment 1 are given the same reference numerals as those in FIG. 5. 27, the auxiliary memory unit 103 of the water heater control device 2001 includes a power generation amount history memory unit 131, a weather forecast memory unit 132, a hot water usage amount history memory unit 133, a hot water storage amount/temperature memory unit 134, a power supply state memory unit 135, a starting hot water amount target hot water amount memory unit 136, a power generation amount prediction memory unit 137, a schedule memory unit 138, and an operation state memory unit 4140. The operation state memory unit 4140 stores stop notification information or operation notification information included in the water heater information transmitted from the water heater 3.

The water heater information acquisition unit 4115 acquires water heater information including hot water usage history information, hot water storage amount information, hot water storage temperature information, as well as stop notification information or operation notification information from the water heater 3. The water heater information acquisition unit 4115 stores the stop notification information or operation notification information included in the water heater information in the operation status storage unit 4140.

The usable hot water volume calculation unit 4128 calculates the amount of hot water stored in the hot water storage tank 31 that is available to the user and whose temperature is equal to or lower than a preset reference temperature Th5, based on the hot water volume information and hot water temperature information stored in the hot water volume/temperature memory unit 134. Here, the reference temperature Th5 is set to, for example, 40°C. The usable hot water volume calculation unit 4128 then notifies the command unit 4122 and the notification unit 4125 of usable hot water volume information indicating the calculated amount of hot water. When the command information acquisition unit 4129 acquires command information sent from the terminal device 5, it notifies the command unit 4122 of the acquired command information.

When the power supplied from the power grid 21 to the distribution board 6 remains below the power threshold for a predetermined reference period or longer, the notification unit 4125 transmits the power outage notification information and the available hot water volume information notified by the available hot water volume calculation unit 4128 to the terminal device 4005.

When the command information acquisition unit 4129 acquires valve open command information from the terminal device 4005, the command unit 4122 transmits the valve open command information to the water heater 4003. In addition, after transmitting the valve open command information to the water heater 3, if the command unit 4122 determines that the water heater 3 is in an operating state, it transmits valve close command information to the water heater 4003.

Next, the valve opening/closing control process executed by the water heater control device 4001 according to this embodiment will be described with reference to FIG. 28 and FIG. 29. This valve opening/closing control process is executed in parallel with the water heater control process described in the first embodiment, for example. First, the usable hot water amount calculation unit 4128 refers to the information stored in the operation state storage unit 4140 to determine whether the water heater 3 is in a stopped state (step S401). Here, if the operation state storage unit 4140 stores stop notification information, the usable hot water amount calculation unit 4128 determines that the water heater 3 is in a stopped state. Here, as long as the usable hot water amount calculation unit 4128 determines that the water heater 3 is in an operating state (step S401: No), the process of step S401 is repeatedly executed. On the other hand, it is assumed that the usable hot water amount calculation unit 4128 determines that the water heater 3 is in a stopped state (step S401: Yes). In this case, the usable hot water volume calculation unit 4128 calculates the amount of hot water stored in the hot water storage tank 31 that is usable by the user and whose temperature is equal to or lower than the preset reference temperature Th5, based on the hot water volume information and hot water temperature information stored in the hot water volume/temperature storage unit 134 (step S402).

Next, the notification unit 4125 determines whether the amount of hot water Wt available to the user at a temperature equal to or lower than the reference temperature Th5 is equal to or greater than a preset reference amount of hot water Wtth5 (step S403). If the notification unit 4125 determines that the amount of hot water Wt is less than the reference amount of hot water Wtth5 (step S403: No), the process of step S401 is executed again. On the other hand, if the notification unit 4125 determines that the amount of hot water Wt is equal to or greater than the reference amount of hot water Wtth5 (step S403: Yes), it transmits available amount of hot water information indicating the amount of hot water Wt to the terminal device 4005 (step S404).

At this time, when the terminal device 4005 receives the available hot water volume information along with the power outage notification information, it causes the display unit 504 to display an operation screen image GA41 including message information M41 for notifying the user that a power outage has occurred, message information M42 for notifying the user of the available hot water volume, and button images K41 and K42, as shown in FIG. 29, for example.

Returning to FIG. 28, the command information acquisition unit 4129 then determines whether or not it has acquired valve open command information from the terminal device 4005 after transmitting the available hot water volume information to the terminal device 4005 (step S405). Here, assume that the user touches a portion of the input unit 505 corresponding to the button image K41 displayed as "YES" while the operation screen image GA41 as shown in FIG. 29 is displayed on the display unit 504 of the terminal device 4005. In this case, the command information transmission unit 514 of the terminal device 4005 transmits valve open command information to the hot water heater control device 4001, which commands the opening and closing valve V51 to be in an open state. On the other hand, assume that the user touches a portion of the input unit 505 corresponding to the button image K42 displayed as "No". In this case, the command information transmission unit 514 of the terminal device 4005 transmits valve close command information to the hot water heater control device 4001, which commands the opening and closing valve V51 to be maintained in a closed state.

Returning to FIG. 28, when the command information acquisition unit 4129 determines that it has acquired valve close command information from the terminal device 4005 (step S405: No), the process of step S401 is executed again. On the other hand, when the command information acquisition unit 4129 determines that it has acquired valve open command information from the terminal device 4005 (step S405: Yes), the command unit 4122 transmits the valve open command information to the water heater 4003 (step S406). At this time, when the valve control unit 4339 of the water heater 4003 receives the valve open command information from the water heater control device 4001, it outputs a control signal to the opening and closing valve V51 to open the opening and closing valve V51, thereby opening the opening and closing valve V51.

Then, the usable hot water amount calculation unit 4128 judges whether the temperature Th (313e) detected by the temperature sensor 313e (see FIG. 25) in the hot water storage tank 31 is equal to or higher than the reference temperature Th5 (step S407). Here, if the usable hot water amount calculation unit 4128 judges that the temperature Th (313e) is equal to or higher than the reference temperature Th5 (step S407: Yes), the processing of step S409 described later is executed. On the other hand, if the usable hot water amount calculation unit 4128 judges that the temperature Th (313e) is lower than the reference temperature Th5 (step S407: No), the command unit 4122 judges whether the water heater 3 is in a stopped state by referring to the information stored in the operation status storage unit 4140 (step S408). Then, if the command unit 4122 judges that the water heater 3 is in a stopped state (step S408: Yes), the processing of step S407 is executed again. On the other hand, when the command unit 4122 determines that the water heater 3 is in an operating state (step S408: No), it transmits valve close command information to the water heater 4003 (step S409). At this time, when the valve control unit 4339 of the water heater 4003 receives the valve close command information from the water heater control device 4001, it outputs a control signal to the opening and closing valve V51 to close the opening and closing valve V51, thereby closing the opening and closing valve V51. Next, the processing of step S401 is executed again.

As described above, according to the water heater control device 4001 of this embodiment, when there is hot water in the hot water storage tank 31 whose temperature is equal to or lower than the reference temperature Th5, the command unit 4122 transmits valve open command information to the water heater 4003. As a result, in the water heater 4003, the opening/closing valve V51 is maintained in a closed state unless there is hot water in the hot water storage tank 31 whose temperature is equal to or lower than the reference temperature Th5, so that it is possible to prevent a user from getting scalded when using the hot water stored in the hot water storage tank 31 as water for daily use during a water outage, for example.

Although the embodiment of the present disclosure has been described above, the present disclosure is not limited to the above-mentioned embodiment. For example, the water heater control device may transmit information indicating the actual value and predicted value of the amount of power generated by the power generation facility 22, the actual value and predicted value of the power consumption of the electrical appliances 11 other than the water heater 3, and the time period during which surplus power is generated that allows the water heater 3 to heat up the hot water to the terminal device 5. For example, as shown in FIG. 30, the water heater control device 5001 according to this modified example includes a power consumption history storage unit 5138, a power consumption prediction unit 5126, a power consumption prediction storage unit 5139, a power generation prediction unit 5117, a power generation prediction storage unit 5137, and a surplus power prediction unit 5127. Note that in FIG. 30, the same components as those in the first embodiment are denoted by the same reference numerals as those in FIG. 5. The power consumption history storage unit 5138 stores power consumption history information indicating the history of power consumption of the electrical appliances 11 other than the water heater 3. The power generation prediction storage unit 5137 stores information indicating the start and end of a power generation period in which the future power generation amount of the power generation facility 22 will be equal to or greater than a preset power generation amount threshold, and stores, in chronological order, predicted power generation amount information indicating the transition of the power generation amount of the power generation facility 22 during a preset future period. The power consumption prediction storage unit 5139 stores, in chronological order, predicted power consumption information indicating the transition of the power consumption of the electrical appliance 11 during a preset future period.

The power acquisition unit 5111 acquires from the power measurement device 7 power grid information indicating the power supplied from the power grid 21 to the distribution board 6, as well as power consumption information indicating the power consumption in the electrical device 11 supplied from the distribution board 6 to the electrical device 11. The power acquisition unit 5111 then notifies the power supply state determination unit 118 of the acquired power grid information, and generates power consumption history information from the acquired power consumption information and past power consumption information and stores it in the power consumption history storage unit 5138. The power consumption prediction unit 5126 predicts the transition of power consumption in the electrical device 11 in a future preset period based on the power consumption information stored in the power consumption history storage unit 5138. The power consumption prediction unit 5126 then stores the predicted power consumption information indicating the transition of power consumption in the electrical device 11 in a future preset period in the power consumption prediction storage unit 5139. The power generation prediction unit 5117 predicts the change in the amount of power generated by the power generation facility 22 over a preset future period, and stores predicted power generation information indicating the change in the amount of power generated over a preset future period obtained by the prediction in the power generation prediction storage unit 5137. The surplus power prediction unit 5127 predicts a time period during which water heating is possible when the surplus power is equal to or greater than the power consumption for boiling water by the water heater 3, based on the predicted power generation information stored in the power generation prediction storage unit 5137 and the predicted power consumption information stored in the power consumption prediction storage unit 5139. The surplus power acquisition unit 5127 then notifies the notification unit 5125 of information indicating the predicted time period during which water heating is possible.

When the power status determination unit 118 determines that the power supplied from the system power source 21 to the distribution board 6 has been cut off, the notification unit 5125 acquires power generation history information indicating the past actual power generation amount of the power generation equipment 22 from the power generation history storage unit 131, and acquires power consumption history information indicating the past actual power consumption of the electrical appliances 11 other than the water heater 3 from the power consumption history storage unit 5138. The notification unit 5125 also acquires predicted power generation information from the power generation prediction storage unit 5137, and acquires predicted power consumption information from the power consumption prediction storage unit 5139. The notification unit 5125 then transmits to the terminal device 5 the power generation history information, power consumption history information, predicted power generation information, and predicted power consumption information, together with the power outage notification information, and information indicating the time period during which water heating is possible, which is notified by the surplus power prediction unit 5127.

Meanwhile, in the terminal device 5, when the notification information receiving unit 511 receives from the water heater control device 5001 power failure notification information, power generation history information, power consumption history information, predicted power generation information, predicted power consumption information, and information indicating the time period during which water heating is possible, the display control unit 512 causes the display unit 504 to display an operation screen image GA51, for example, as shown in FIG. 31. The operation screen image GA51 includes a graph image showing the actual and predicted values of the power generation amount in the power generation equipment 22 and the actual and predicted values of the power consumption in the electrical appliances 11 other than the water heater 3. The operation screen image GA51 also includes message information M51 indicating the time period during which water heating is possible.

According to this configuration, the display unit 504 of the terminal device 5 displays information indicating the predicted and actual power generation amounts of the power generation equipment 22, information indicating the predicted and actual power consumption amounts of the electrical appliances 11 other than the water heater 3, and information notifying the time periods during which water can be boiled. By referring to the display unit 504 of the terminal device 5, the user can easily ascertain the time periods that are suitable for boiling water using the water heater 3.

In the first embodiment, an example has been described in which, when the terminal device 5 receives power outage notification information from the water heater control device 1, the display unit 504 displays an operation screen image GA11 including message information M11 for notifying the user that a power outage has occurred, as shown in FIG. 10(A), for example. However, the operation screen image that the terminal device 5 displays on the display unit 504 when it receives power outage notification information is not limited to this. When the terminal device 5 receives power outage notification information from the water heater control device 1, the display unit 504 may display, for example, an operation screen image GA13 including message information M13 for notifying the user of the operation schedule of the water heater 3 during the power outage, together with message information M11 for notifying the user that a power outage has occurred, as shown in FIG. 32.

In the first embodiment, the hot water heater control device may have a function of transmitting at least one of the power storage amount information indicating the power storage amount of the power storage device 23, the hot water storage amount information indicating the hot water storage amount of the hot water stored in the hot water storage tank 31 of the hot water heater 3, and the hot water storage temperature information indicating the hot water storage temperature to the terminal device 5. For example, as in the hot water heater control device 6001 shown in FIG. 33, when the power storage amount acquisition unit 6114 acquires the power storage amount information from the power conditioner 4, the acquired power storage amount information may be notified to the power supply state determination unit 118 and the notification unit 6125. Then, the notification unit 6125 may acquire the hot water storage amount information stored in the hot water storage amount/temperature storage unit 134, and transmit the acquired hot water storage amount information and the power storage amount information notified by the power storage amount acquisition unit 6114 to the terminal device 5.

On the other hand, in the terminal device 5, when the notification information receiving unit 511 receives the hot water storage amount information and the power storage amount information from the water heater control device 6001, the display control unit 512 causes the display unit 504 to display an operation screen image GA61, for example, as shown in FIG. 34. The operation screen image GA61 includes an icon image GA621 representing the hot water storage amount of the water heater 3, and an icon image GA622 representing the power storage amount of the power storage device 23. Here, the display control unit 512 sets the display mode of each icon image GA621, GA622 based on the received hot water storage amount information and power storage amount information. In addition, the operation screen image GA61 includes message information M61 for notifying the user that a power outage has occurred, and message information M62 for encouraging the use of hot water stored in the hot water storage tank 31. Furthermore, the operation screen image GA61 includes message information M63 that notifies the user of the remaining amount of hot water stored in the hot water storage tank 31, and message information M64 that notifies the user of the amount of electricity stored in the electricity storage device 23.

The notification unit 6125 of the water heater control device 6001 may also acquire the hot water storage amount information and hot water temperature information stored in the hot water storage amount/temperature storage unit 134, and transmit the acquired hot water storage amount information and hot water temperature information to the terminal device 5. In this case, when the notification information receiving unit 511 in the terminal device 5 receives the hot water storage amount information and hot water temperature information from the water heater control device 6001, the display control unit 512 may display an operation screen image GA52, for example, as shown in FIG. 35, on the display unit 504. The operation screen image GA52 includes an icon image GA521 representing the hot water storage amount and hot water temperature of the water heater 3. Here, the display control unit 512 sets the display mode of the icon image GA521 based on the received hot water storage amount information and hot water temperature information. The operation screen image GA52 also includes message information M51 for notifying the user that a power outage has occurred, and message information M52 for encouraging the user to use the hot water stored in the hot water storage tank 31.

Furthermore, the notification unit 6125 of the water heater control device 6001 may transmit to the terminal device 5 power storage amount information indicating the power storage amount of the power storage device 23 and operation status information indicating the operation status of the water heater 3. In this case, when the notification information receiving unit 511 in the terminal device 5 receives the power storage amount information and operation status information from the water heater control device 6001, the display control unit 512 may display, for example, operation screen images GA62 and GA63 as shown in FIG. 36(A) or FIG. 36(B) on the display unit 504. Here, when the power storage amount of the power storage device 23 exceeds 90% of the full charge and the water heater 3 is in a stopped state, for example, the terminal device 5 displays, on the display unit 504, an operation screen image GA62 including message information M67 prompting the water heater 3 to operate as shown in FIG. 36(A). The operation screen image GA62 includes message information M65 for notifying the user that a power outage has occurred, and message information M66 for notifying the user of the amount of electricity stored in the power storage device 23 and the operating state of the water heater 3. On the other hand, when the amount of electricity stored in the power storage device 23 is 20% or less of the full charge amount and the water heater 3 is in an operating state, the terminal device 5 displays on the display unit 504 an operation screen image GA63 including message information M69 as shown in Fig. 36(B) that prompts the user to stop the water heater 3. The operation screen image GA63 also includes message information M65 for notifying the user that a power outage has occurred, and message information M68 for notifying the user of the amount of electricity stored in the power storage device 23 and the operating state of the water heater 3. In addition, the amount of stored power in the power storage device 23, which is the criterion for the terminal device 5 to determine whether to display on the display unit 504 the operation screen image GA62 or GA63 including the message information M67 or M69, may be set in advance or may be freely set by the user.

With these configurations, the user can grasp the amount or temperature of hot water stored in the hot water storage tank 31 of the water heater 3, the amount of electricity stored in the electricity storage device 23, etc. via the terminal device 5, so that the water heater 3 can be operated more appropriately during a power outage.

In the first embodiment, an example was described in which, when the power supply from the power grid 21 to the distribution board 6 is cut off, the command unit 122 transmits boiling start command information to the water heater 3 according to the amount of hot water stored in the hot water storage tank 31 of the water heater 3. However, this is not limited to this, and for example, the command unit 122 may avoid transmitting boiling start command information until the power supply from the power grid 21 to the distribution board 6 is restored after transmitting power outage mode switching command information to the water heater 3. In addition, when the power generation amount management server 8 does not accumulate a sufficient amount of power generation amount information indicating the actual amount of power generation of the power generation facility 22 to predict the power generation amount, the command unit 122 may similarly avoid transmitting boiling start command information. In these cases, the amount of power stored in the power storage device 23 can be secured for a longer period of time, thereby reducing the probability of power shortages occurring when the power outage state is prolonged.

In the fourth embodiment, an example has been described in which the opening/closing valve V51 is maintained in a closed state when the water heater 4003 is operating. However, this is not limited to the above, and for example, the hot water supply control device 4001 may open the opening/closing valve V51 when the hot water amount Wt available to the user at a temperature equal to or lower than the reference temperature Th5 is equal to or higher than a preset reference hot water amount Wtth5, even if the water heater 4003 is operating. In this case, in the valve opening/closing control process shown in FIG. 28, step S401 is not executed, and the process may be started from step S402. Then, when the usable hot water amount calculation unit 4128 determines in step S407 that the use temperature Th (313e) is equal to or higher than the reference temperature Th5 (step S407: Yes), the process of step S409 is executed, and as long as it determines that the temperature Th (313e) is lower than the reference temperature Th5 (step S407: No), the process of step S407 is repeatedly executed.

According to this configuration, regardless of the operating state of the water heater 4003, if the temperature of the hot water stored in the hot water storage tank 31 of the water heater 4003 that is located near the opening/closing valve V51 is lower than the reference temperature Th5, that hot water can be used, so the hot water stored in the hot water storage tank 31 can be used effectively.

In the fourth embodiment, the hot water supply control device 4001 may update the target hot water volume and the hot water volume to start boiling depending on whether or not the device 4001 receives valve open command information from the terminal device 4005.

Here, the hot water supply control process executed by the hot water supply control device 4001 according to this modified example will be described with reference to FIG. 37. Note that in FIG. 37, the same processes as those in the first embodiment are given the same reference numerals as those in FIG. 14. First, a series of processes from steps S101 to S113 are executed, and in step S113, the power supply status determination unit 118 determines that the count value Cs is equal to or greater than the count threshold value Csth (step S113: Yes). In this case, the notification unit 125 generates and transmits usable hot water volume information together with power outage notification information to the terminal device 5 (step S701). Next, the power supply status determination unit 118 sets the power outage flag information stored in the power supply status storage unit 135 to flag information "Fps1" indicating that a power outage has occurred (step S115).

Next, the command information acquisition unit 4129 determines whether or not the valve open command information has been acquired from the terminal device 4005 (step S702). Here, it is assumed that, in a state where the operation screen image GA41 as shown in FIG. 29 is displayed on the display unit 504 of the terminal device 4005, the user touches a portion of the input unit 505 corresponding to the button image K41 displayed with "YES". In this case, the command information transmission unit 514 of the terminal device 4005 transmits the valve open command information described in the fourth embodiment to the water heater control device 4001. Here, if the command information acquisition unit 4129 determines that the valve open command information cannot be acquired from the terminal device 4005 during the preset waiting time (step S702: No), the process of step S121 shown in FIG. 15 is executed as it is. On the other hand, it is assumed that the command information acquisition unit 4129 determines that the valve open command information transmitted from the terminal device 4005 has been acquired (step S702: Yes).

In this case, the command information acquisition unit 4129 notifies the start target hot water volume setting unit 119 of the valve open command information. On the other hand, when the start target hot water volume setting unit 119 is notified of the pulsation start command information, it compares the target hot water volume Wf indicated by the target hot water volume information stored in the start hot water volume target hot water volume storage unit 136 with the previously set domestic water securing mode target hot water volume WfU. Here, if the start target hot water volume setting unit 119 determines that the target hot water volume Wf is equal to or less than the domestic water securing mode target hot water volume WfU (S703: No), the processing of step S705 described below is executed. On the other hand, if the start target hot water volume setting unit 119 determines that the target hot water volume Wf is greater than the domestic water securing mode target hot water volume WfU (S703: Yes), it updates the target hot water volume information indicating the target hot water volume Wf stored in the start hot water volume target hot water volume storage unit 136 to the value of the domestic water securing mode target hot water volume WfU (step S704). Here, the target hot water volume WfU for the domestic water conservation mode is set to, for example, 70% of the capacity of the hot water tank 31. This keeps some of the water in the hot water tank 31 from being boiled.

After that, the start target hot water volume setting unit 119 compares the boiling start hot water volume Ws indicated by the boiling start hot water volume information stored in the start hot water volume target hot water volume memory unit 136 with the preset domestic water securing mode boiling start hot water volume WsU. Here, if the start target hot water volume setting unit 119 determines that the boiling start hot water volume Ws is equal to or less than the domestic water securing mode boiling start hot water volume WsU (S705: No), the process of step S121 shown in FIG. 15 is executed as is. On the other hand, if the start target hot water volume setting unit 119 determines that the boiling start hot water volume Ws is greater than the domestic water securing mode boiling start hot water volume WsU (S705: Yes), the start target hot water volume setting unit 119 updates the boiling start hot water volume information indicating the boiling start hot water volume Ws stored in the start hot water volume target hot water volume memory unit 136 to the value of the domestic water securing mode boiling start hot water volume WsU (step S706). Here, the water supply mode boiling start water volume WsU is set to a water volume smaller than the water supply mode target water volume WfU, for example, set to 60% of the capacity of the hot water storage tank 31. Next, the process from step S121 shown in FIG. 15 is executed.

With this configuration, for example, during a water outage, some of the water stored in the hot water tank 31 can be maintained in an unboiled state, so the water stored in the hot water tank 31 can be effectively used as water for daily life.

In each embodiment, an example has been described in which the power generation amount acquisition unit 112 acquires the amount of power generated by the power generation facility 22 from the power conditioner 4, but this is not limited thereto, and the amount of power generated may be acquired from, for example, the power measurement device 7. In this case, the power measurement device 7 may calculate the amount of power generated by the power generation facility 22 by measuring the AC current flowing through the power line that is used by the power conditioner 4 to convert the DC supplied from the power generation facility 22 to AC and then output to the distribution board 6.

In each embodiment, an example has been described in which the time determination unit 127 identifies a period during which the future power generation amount of the power generation facility 22 will be equal to or greater than a preset power generation amount threshold as the power generation period. However, this is not limited to this, and the time determination unit 127 may, for example, acquire information indicating the sunrise time to the sunset time from the weather server 10, and identify the period from the sunrise time to the sunset time as the power generation period.

In each embodiment, the display device, i.e., the external device, is described as being a smartphone, but this is not limited thereto, and the display device may be other devices such as a television, a personal computer, etc.

The various functions of the water heater control devices 1, 2001, 3001, 4001, 5001, and 6001 according to the present disclosure may be realized by software, firmware, or a combination of software and firmware. In this case, the software or firmware may be written as a program, and the program may be stored and distributed on a computer-readable recording medium such as a flexible disk, a CD-ROM (Compact Disc Read Only Memory), a DVD (Digital Versatile Disc), or an MO (Magneto-Optical Disc), and the program may be read and installed on a computer to configure a computer capable of realizing each of the above-mentioned functions. In addition, when each function is realized by sharing the work between an OS (Operating System) and an application, or by cooperation between an OS and an application, only the parts other than the OS may be stored on the recording medium.

Furthermore, each program can be superimposed on a carrier wave and distributed over a network. For example, the program can be posted on a bulletin board (BBS, Bulletin Board System) on the network and distributed over the network. These programs can then be started and run under the control of the OS in the same way as other application programs, thereby enabling the above-mentioned processing to be performed.

This disclosure is suitable as a hot water supply system equipped with a hot water heater that operates by receiving power supply from a power generation facility and a power storage device.

1,2001,3001,4001,5001,6001 Water heater control device, 3,4003 Water heater, 4 Power conditioner, 5,4005 Terminal device, 6 Distribution board, 7 Power measurement device, 8 Power generation management server, 9 Router, 10 Weather server, 11 Electrical equipment, 21 System power source, 22 Power generation equipment, 23 Power storage device, 31 Hot water storage tank, 32 Heat pump unit, 33,4033 Controller, 101,301,501 CPU, 102,302,502 Main memory unit, 103,303,503 Auxiliary memory unit, 106,506 Wide area communication unit, 107,307 Local communication unit, 108,308 Timer unit, 109,309,509 Bus, 111,3111 Power acquisition unit, 112 Power generation amount acquisition unit, 113 Power generation amount transmission unit, 114 Storage amount acquisition unit, 115, 4115 Water heater information acquisition unit, 116 Power generation amount history acquisition unit, 117 Power generation amount prediction unit, 118, 3118 Power supply state determination unit, 119, 2119 Starting hot water amount target hot water amount setting unit, 120 Hot water usage prediction unit, 121 Boiling hot water amount calculation unit, 122, 2122, 3122 Command unit, 123 Schedule generation unit, 124 Schedule transmission unit, 125 Notification unit, 126 Weather forecast acquisition unit, 127 Time determination unit, 131 Power generation amount history storage unit, 132 Weather forecast storage unit, 133, 342 Hot water usage history storage unit, 134, 343 Hot water storage amount/temperature storage unit, 135 Power supply state storage unit, 136 Starting hot water volume target hot water volume memory unit, 345 Operation time/power consumption memory unit, 137 Power generation amount prediction memory unit, 138, 344 Schedule memory unit, 310 Communication interface, 311 Hot water usage amount measurement unit, 312 Hot water storage amount measurement unit, 313 Pump, 313a, 313b, 313c, 313d, 313e Temperature sensor, 321 Evaporator, 322 Compressor, 323 Heat exchanger, 324 Expansion valve, 325 Control board, 331 Schedule receiving unit, 332 Heat pump control unit, 333: Command information receiving unit, 334 Water heater information transmitting unit, 335 Hot water usage amount history generating unit, 336 Hot water usage amount acquisition unit, 337 Hot water storage amount acquisition unit, 338 Hot water storage temperature acquisition unit, 504 Display unit, 505 Input unit, 511 Notification information receiving unit, 512 Display control unit, 513 Reception unit, 514 Command information transmission unit, 531 Operation screen memory unit, 2125 Heating power consumption setting unit, 2136 Heating power consumption memory unit, D3, D6, D11, D21, D22, D23: Power line, dTrfth: First reference time, dTrsth: Second reference time, NW1 Wide area network, NW2 Local network, PI1: Hot water outlet pipe, PI2: Water supply pipe, PI3: Drain pipe

Claims (20)

A hot water heater control device that controls a hot water heater that has a hot water storage tank and boils hot water using electricity generated by a power generation facility, electricity supplied from a power system, or electricity stored in a power storage device, and stores the hot water in the hot water storage tank,
a power acquisition unit that acquires power information indicating power supplied from the power grid;
a power generation amount acquiring unit that acquires power generation amount information indicating an amount of power generated by the power generation facility;
a power storage amount acquiring unit that acquires power storage amount information indicating a storage amount of electricity stored in the power storage device;
a power supply state determination unit that determines whether or not the power supplied from the power system has been interrupted based on the power information;
and a command unit that, when it is determined by the power supply state determination unit that the power supplied from the grid power supply has been cut off, commands the water heater to operate in an operation mode in which the amount of hot water continuously boiled by the water heater is small, the operation mode being in accordance with the amount of power generation indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information.
Water heater control device. a start water volume and target water volume setting unit that sets a start water volume, which is the amount of hot water stored in the hot water storage tank when hot water heating starts, and a target water volume to be stored in the hot water storage tank by starting hot water heating, based on hot water volume history information indicating a history of past hot water usage, and updates the start water volume and target water volume based on the amount of power generated and the amount of stored power when the power source status determination unit determines that the power supplied from the system power source has been cut off;
The water heater control device according to claim 1 . A power generation amount prediction unit that predicts a change in the amount of power generated by the power generation facility is further provided.
When the power supply state determination unit determines that the power supplied from the system power supply has been cut off, if the amount of power generated is equal to or greater than a predetermined reference amount of power generated and if the remaining power generation time from the time of power outage determination at which the power supply state determination unit determines that the power supplied from the system power supply has been cut off to the end of a power generation period during which power is generated by the power generation equipment identified based on the change in the amount of power generated is equal to or greater than a predetermined first reference time, the start hot water volume setting unit increases the amount of hot water generated at the start of boiling and the target amount of hot water so that the difference between the amount of hot water generated at the start of boiling and the target amount of hot water becomes a predetermined first reference amount of hot water.
The water heater control device according to claim 2. When the power supply state determination unit determines that the power supplied from the system power supply has been cut off, if the amount of power generation is less than a predetermined reference amount of power generation or the remaining power generation time is less than the first reference time, and if the amount of stored power is equal to or greater than a predetermined reference amount of stored power and the time from the time of the power outage determination to the start of the power generation period is equal to or less than a predetermined second reference time, the start hot water volume target hot water volume setting unit reduces the amount of hot water to start boiling and the target amount of hot water so that the difference between the amount of hot water to start boiling and the target amount of hot water becomes a predetermined second reference amount of hot water.
The water heater control device according to claim 3. A hot water heater control device that controls a hot water heater that has a hot water storage tank and boils hot water using electricity generated by a power generation facility, electricity supplied from a power system, or electricity stored in a power storage device, and stores the hot water in the hot water storage tank,
a power acquisition unit that acquires power information indicating power supplied from the power grid;
a power generation amount acquiring unit that acquires power generation amount information indicating an amount of power generated by the power generation facility;
a power storage amount acquiring unit that acquires power storage amount information indicating a storage amount of electricity stored in the power storage device;
a power supply state determination unit that determines whether or not the power supplied from the power system has been interrupted based on the power information;
and a command unit that, when it is determined by the power supply state determination unit that the power supplied from the grid power supply has been cut off, commands the water heater to operate in an operation mode in which the water heater heats up at a speed slower than the water heater heats up when power is supplied from the grid power supply, according to the amount of power generated indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information.
Water heater control device. and a water heating power consumption setting unit that sets the water heating power consumption consumed by the water heater when the water heater heats up water to a water heating power consumption corresponding to the water heating speed of the water heater according to the amount of generated electricity and the amount of stored electricity when the power supply state determination unit determines that the power supplied from the system power supply has been cut off.
The water heater control device according to claim 5. A power generation amount prediction unit that predicts a change in the amount of power generated by the power generation facility is further provided.
When the power supply state determination unit determines that the power supplied from the grid power supply has been cut off, if the remaining power generation time from the power outage determination time at which the power supply state determination unit determines that the power supplied from the grid power supply has been cut off to the end of a power generation period in which power is generated by the power generation equipment specified based on the change in the amount of power generated is equal to or longer than a predetermined third reference time and shorter than a fourth reference time longer than the third reference time, the water boiling power consumption setting unit sets the water boiling power consumption to a second water boiling power consumption that is smaller than the first water boiling power consumption when power is being supplied from the grid power supply.
The water heater control device according to claim 6. When the power supply state determination unit determines that the power supplied from the grid power supply has been cut off, if the remaining power generation time is equal to or longer than the fourth reference time, the water-heating power consumption setting unit sets the water-heating power consumption to a third water-heating power consumption that is smaller than the second water-heating power consumption.
The water heater control device according to claim 7. The power acquisition unit further acquires power consumption information indicating power consumption of electrical appliances other than the water heater,
The power supply state determination unit further determines whether or not the power consumption indicated by the power consumption information is equal to or greater than a preset power consumption threshold value;
The command unit further commands the water heater to operate in an operation mode in which the water heater can be operated only manually when it determines that the power consumption is equal to or greater than the power consumption threshold value.
The water heater control device according to any one of claims 1 to 8. a water heater information acquisition unit that acquires water heater information including hot water storage amount information indicating the amount of hot water stored in the hot water storage tank;
The power supply state determination unit determines that the power supplied from the power grid has been cut off, and when the power supply state determination unit determines that the power supply state has been cut off, the power supply state determination unit transmits power failure notification information to an external device, the hot water storage amount information, and the electricity storage amount information.
The water heater control device according to any one of claims 1 to 9. a water heater having a hot water storage tank, which boils hot water using electricity generated by a power generation facility, electricity supplied from a power grid, or electricity stored in a power storage device, and stores the hot water in the hot water storage tank;
A hot water supply system including a hot water supply device that controls the hot water supply device,
The hot water heater control device includes:
a power acquisition unit that acquires power information indicating power supplied from the power grid;
a power generation amount acquiring unit that acquires power generation amount information indicating an amount of power generated by the power generation facility;
a power storage amount acquiring unit that acquires power storage amount information indicating a storage amount of electricity stored in the power storage device;
a power supply state determination unit that determines whether or not the power supplied from the power system has been interrupted based on the power information;
and a command unit that, when it is determined by the power supply state determination unit that the power supplied from the system power supply has been cut off, commands the water heater to operate in an operation mode in which the amount of hot water continuously boiled by the water heater is small, the operation mode being in accordance with the amount of power generation indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information.
Hot water system. a water heater having a hot water storage tank, which boils hot water using electricity generated by a power generation facility, electricity supplied from a power grid, or electricity stored in a power storage device, and stores the hot water in the hot water storage tank;
A hot water supply system including a hot water supply device that controls the hot water supply device,
The hot water heater control device includes:
a power acquisition unit that acquires power information indicating power supplied from the power grid;
a power generation amount acquiring unit that acquires power generation amount information indicating an amount of power generated by the power generation facility;
a power storage amount acquiring unit that acquires power storage amount information indicating a storage amount of electricity stored in the power storage device;
a power supply state determination unit that determines whether or not the power supplied from the power system has been interrupted based on the power information;
and a command unit that, when it is determined by the power supply state determination unit that the power supplied from the grid power supply has been cut off, commands the water heater to operate in an operation mode in which the water heater heats up at a speed slower than the water heater heats up when power is supplied from the grid power supply, according to the amount of power generated indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information.
Hot water system. Further comprising a display device,
The hot water heater control device includes:
a water heater information acquisition unit that acquires water heater information including hot water storage amount information indicating the amount of hot water stored in the hot water storage tank;
When the power supply state determination unit determines that the power supplied from the system power supply has been cut off, the power supply state determination unit transmits power failure notification information that notifies the display device that the power supplied from the system power supply has been cut off and the hot water storage amount information to the display device.
When the display device receives the power failure notification information and the hot water storage amount information from the hot water heater control device, the display device displays information notifying a user that a power failure has occurred based on the power failure notification information, and displays information indicating the hot water storage amount indicated by the hot water storage amount information.
The hot water supply system according to claim 11 or 12. The notification unit further transmits the stored power amount information to the display device when the power supply state determination unit determines that the power supplied from the system power supply has been interrupted.
When the display device receives the stored power amount information from the hot water heater control device, the display device displays information indicating the stored power amount indicated by the stored power amount information.
The hot water system according to claim 13. The hot water heater information further includes hot water temperature information indicating the temperature of the hot water stored in the hot water storage tank,
The notification unit further transmits the hot water temperature information to the display device when the power supply state determination unit determines that the power supplied from the system power supply has been cut off.
When the display device receives the stored hot water temperature information from the hot water heater control device, the display device displays information indicating the hot water temperature indicated by the stored hot water temperature information.
The hot water system according to claim 13. The water heater comprises:
A drain pipe communicating with the hot water storage tank for discharging the hot water stored in the hot water storage tank to the outside of the hot water storage tank;
An opening and closing valve inserted in the drain pipe;
A valve control unit that controls the opening and closing valve,
The hot water heater control device includes:
The hot water supply device further includes a hot water supply information acquisition unit that acquires hot water supply information including hot water temperature information indicating a temperature of the hot water stored in the hot water storage tank,
When the power supply state determination unit determines that the power supplied from the system power supply has been cut off, the command unit transmits close command information to the water heater to command the opening/closing valve to be closed when the hot water temperature indicated by the hot water storage temperature information is equal to or higher than a preset reference temperature, and transmits open command information to the water heater to command the opening/closing valve to be opened when the hot water temperature indicated by the hot water storage temperature information is lower than the reference temperature;
The valve control unit maintains the opening and closing valve in a closed state when receiving the close command information from the water heater control device, and maintains the opening and closing valve in an open state when receiving the open command information from the water heater control device.
16. The hot water supply system according to any one of claims 11 to 15. A step in which the water heater control device acquires power information indicating power supplied from a grid power supply;
The water heater control device acquires power generation amount information indicating the amount of power generated by the power generation facility;
The hot water supply control device acquires stored electricity amount information indicating an amount of electricity stored in a power storage device;
A step in which the water heater control device determines whether or not power supplied from the system power supply has been interrupted based on the power information;
and when the water heater control device determines that the power supplied from the system power source has been cut off, the water heater control device instructs a water heater having a hot water storage tank, which boils hot water using the power generated by the power generation facility, the power supplied from the system power source, or the electricity stored in the power storage device, and stores the hot water in the hot water storage tank, to operate in an operating mode in which the amount of hot water continuously boiled by the water heater is small, according to the amount of power generated indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information.
A water heater control method. A step in which the water heater control device acquires power information indicating power supplied from a grid power supply;
The water heater control device acquires power generation amount information indicating the amount of power generated by the power generation facility;
The hot water supply control device acquires stored electricity amount information indicating an amount of electricity stored in a power storage device;
A step in which the water heater control device determines whether or not power supplied from the system power supply has been interrupted based on the power information;
and when the water heater control device determines that the power supplied from the system power source has been cut off, the water heater control device instructs a water heater having a hot water storage tank, which boils hot water using power generated by the power generation facility, power supplied from the system power source, or electricity stored in the power storage device, to operate in an operation mode in which the hot water boiling speed of the water heater is slower than the hot water boiling speed when power is supplied from the system power source, according to the amount of power generated indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information.
A water heater control method. Computer,
a power acquisition unit that acquires power information indicating power supplied from a power grid;
a power generation amount acquiring unit that acquires power generation amount information indicating the amount of power generated by the power generation facility;
a stored electricity amount acquiring unit that acquires stored electricity amount information indicating the amount of electricity stored in the electricity storage device;
a power supply state determination unit that determines whether or not the power supplied from the system power supply has been interrupted based on the power information;
a command unit that, when it is determined by the power supply state determination unit that the power supplied from the system power supply has been cut off, commands a water heater that has a hot water storage tank and boils hot water using the power generated by the power generation facility, the power supplied from the system power supply, or the electricity stored in the power storage device, and stores the hot water in the hot water storage tank, to operate in an operation mode in which the amount of hot water continuously boiled by the water heater is small, according to the amount of power generated indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information;
A program to function as a Computer,
a power acquisition unit that acquires power information indicating power supplied from a power grid;
a power generation amount acquiring unit that acquires power generation amount information indicating the amount of power generated by the power generation facility;
a stored electricity amount acquiring unit that acquires stored electricity amount information indicating the amount of electricity stored in the electricity storage device;
a power supply state determination unit that determines whether or not the power supplied from the power system has been interrupted based on the power information;
a command unit that, when it is determined by the power supply state determination unit that the power supplied from the system power supply has been cut off, commands a water heater having a hot water storage tank, which boils hot water using power generated by the power generation facility, power supplied from the system power supply, or electricity stored in the power storage device, and stores the hot water in the hot water storage tank, to operate in an operation mode in which the hot water boiling speed of the water heater is slower than the hot water boiling speed when power is supplied from the system power supply, in accordance with the amount of power generation indicated by the power generation amount information and the amount of stored power indicated by the stored power amount information;
A program to function as a

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