JP6520764B2 - Water heater - Google Patents

Description

  The disclosure in this specification relates to a water heater.

  Patent Document 1 discloses a hot water supply device that calculates a target heating heat amount based on past usage results and raises the target heating heat amount hot water for each day in an inexpensive late-night time zone of charge setting. There is.

Patent No. 3807930 gazette

  There are various patterns of pricing depending on the type of power supply contract, and there may be cases where different tariffs are set depending on the unit price of electricity depending on the day. In the water heating apparatus of Patent Document 1, since the hot water is boiled every day, when the electricity rate unit price is different depending on the day, there is a possibility that the cost for boiling the hot water may be high on the day when the electricity rate unit price is high.

  An object to be disclosed is to provide a hot water supply apparatus capable of suppressing the cost of boiling hot water when the electricity rate varies depending on the day.

  Several aspects disclosed in this specification employ different technical means from one another in order to achieve each purpose. Further, the claims and the reference numerals in the parentheses described in this section are an example showing the correspondence with the specific means described in the embodiment described later as one aspect, and the technical scope is limited. is not.

One of the disclosed hot water supply devices is a heating device (50) for boiling hot water using electric power whose electricity unit price is set based on a contract.
With a hot water storage tank (10) for storing hot water,
A control device (80) for controlling the heating device;
Equipped with
The controller is
A determination unit (382f) that determines whether or not there is a day in which the electricity bill unit price is higher than the first day of the predetermined period after the second day of the predetermined period;
If it is determined that the electricity price per unit price is higher than the first day of the predetermined period after the second day of the predetermined period, the heat amount necessary for the second day or later is advanced on the first day Boiling treatment section (382 g) that executes the boiling and boiling up operation.
It is characterized by having.

  According to this disclosure, when there is a day where the electricity rate unit price is higher than the first day of the predetermined period, the hot water supply apparatus accelerates and heats the hot water after the second day on the first day. Therefore, it is possible to avoid boiling on a day when the electricity unit price is higher than that on the first day, so it is possible to suppress the running cost at boiling as compared to the case where boiling operation is performed each day. It becomes possible. Thus, it is possible to provide a hot water supply apparatus capable of suppressing the cost of boiling hot water when the unit price of electricity rates differs depending on the day.

One of the disclosed hot water supply devices is a heating device (50) for boiling hot water using electric power whose electricity unit price is set based on a contract.
With a hot water storage tank (10) for storing hot water,
A control device (80) for controlling the heating device;
Equipped with
The controller is
On the first day of the predetermined period, the heat required for each day of the predetermined period, and on the first day of the predetermined period, the heat required for the second and subsequent days of the predetermined period is brought forward and boiled. A required heat amount calculation unit (82d) for calculating the required heat amount at the time of advance necessary for performing the operation;
A running cost calculation unit (82e) for calculating a first running cost required to boil the required amount of heat each day in a predetermined period and a second running cost required to boil the required amount of heat at the first day of the day;
A determination unit (82f) that determines whether the first running cost is less than the second running cost;
A boiling-up processing unit (82g) that executes the forward boiling heating operation when the determination unit determines that the first running cost is less than the second running cost;
It is characterized by having.

  According to this disclosure, the hot water supply apparatus is more likely to heat water from the second day onward on the first day of the predetermined period rather than when the water is heated for each day in the predetermined period. If the running cost is low, the hot water after the second day will be brought forward and boiled on the first day. Therefore, it is possible to avoid boiling on a day when the electricity unit price is higher than that on the first day, so it is possible to suppress the running cost at boiling as compared to the case where boiling operation is performed each day. It becomes possible. In addition, since the running cost is calculated and determined, it is possible to more accurately suppress the running cost at the time of boiling as compared to the case where the boiling operation is performed on each day. Thus, it is possible to provide a hot water supply apparatus capable of suppressing the cost of boiling hot water when the unit price of electricity rates differs depending on the day.

One of the disclosed hot water supply devices is a heating device (50) for boiling hot water using electric power whose electricity unit price is set based on a contract.
With a hot water storage tank (10) for storing hot water,
A control device (80) for controlling the heating device;
Equipped with
The controller is
In addition to the heat for one day based on the past heat use record and the heat that can be stored in the hot water storage tank, the heat for one day is used after the day after using the heat for one day A period determination unit (582b) for determining an advance period, which is the number of days that can be advanced, when the boiling operation is performed;
The first running cost required when heating the heat required for each day in the advance period, and the case where the heat required for the second and subsequent days of the advance period is brought forward and boiled on the first day of the advance period A running cost calculation unit (582e) for calculating a second running cost
A determination unit (582f) that determines whether the second running cost is less than the first running cost;
A boiling-up processing unit (582 g) that executes the forward boiling heating operation when the determination unit determines that the second running cost is less than the first running cost;
It is characterized by having.

  According to this disclosure, if the hot water supply device calculates the maximum possible forward period from the past heat energy use results and if the forward boiling operation is performed in the period, the running cost is lower than the boiling operation on each day In addition, execute the boiling up operation. Therefore, since it becomes possible to avoid performing boiling on the day when the electricity unit price is higher than the first day of the period, the running cost at the time of boiling is suppressed compared to the case where the boiling operation is performed each day. It becomes possible. Further, since the period is determined from the past usage results and the capacity of the hot water storage tank, it is possible to set an advance period according to the amount of use of hot water by the user. Therefore, even when the unit price of electricity rates differs depending on the day, the boiling cost can be suppressed.

It is a block diagram of the hot-water supply apparatus which concerns on 1st Embodiment. It is a block diagram of a hot-water supply device concerning a 1st embodiment. It is the flowchart which showed the control procedure of 1st Embodiment. It is a chart showing an example of the electricity bill setting concerning a 1st embodiment. It is a chart showing an example of the electricity bill setting concerning a 1st embodiment. It is a chart showing an example of the electricity bill setting concerning a 1st embodiment. It is the flowchart which showed the control procedure of 2nd Embodiment. It is a chart showing an example of electricity bill setting concerning a 2nd embodiment It is a chart showing an example of electricity bill setting concerning a 2nd embodiment It is a chart showing an example of electricity bill setting concerning a 2nd embodiment It is a block diagram of the hot-water supply apparatus which concerns on 3rd Embodiment. It is the flowchart which showed the control procedure of 3rd Embodiment. It is a chart showing an example of the electricity bill setting concerning a 3rd embodiment. It is a chart showing an example of the electricity bill setting concerning a 3rd embodiment. It is the flowchart which showed the control procedure of 4th Embodiment. It is a chart showing an example of the electricity bill setting concerning a 4th embodiment. It is a chart showing an example of the electricity bill setting concerning a 4th embodiment. It is a chart showing an example of the electricity bill setting concerning a 4th embodiment. It is a chart showing an example of the electricity bill setting concerning a 4th embodiment. It is a block diagram of the hot-water supply apparatus which concerns on 5th Embodiment. It is the flowchart which showed the control procedure of 5th Embodiment.

First Embodiment
FIG. 1 is a configuration diagram showing the whole of a hot water storage type hot water supply device 1. The hot water supply device 1 is configured to include a hot water storage tank 10, a heat pump device 50, and a control device 80.

  The hot water storage tank 10 is made of a container made of metal having excellent corrosion resistance, for example, stainless steel. The hot water storage tank 10 has a hollow cylindrical shape, and is formed in a vertically elongated shape in which the axial direction extends in the vertical direction. The hot water storage tank 10 has a heat insulating structure in which the outer surface is covered with a heat insulating material, a vacuum heat insulating structure by a double tank, or the like, so high temperature hot water can be kept warm for a long time. The hot water storage tank 10 stores hot water supplied by the heat pump device 50 (hereinafter referred to as the HP device 50).

  A tank water temperature thermistor 71 is provided in the hot water storage tank 10. A plurality of tank water temperature thermistors 71 are provided dispersed in the height direction of the hot water storage tank 10. The tank water temperature thermistor 71 is a tank temperature detector for detecting the amount of hot water storage and the temperature of the hot water stored in the hot water storage tank 10. The tank water temperature thermistor 71 outputs a temperature signal at each height level in the hot water storage tank 10 to the control device 80.

  A lower opening 10 a is provided below the hot water storage tank 10. The lower opening 10 a is an outlet through which the hot water on the lower side of the hot water storage tank 10 flows out. The lower opening 10 a is an inlet through which tap water flows into the hot water storage tank 10. The tap water flowing into the hot water storage tank 10 is supplied by the water supply pipe 11.

  The inlet pipe 21 a guides the hot water supplied to the lower side of the hot water storage tank 10 that has flowed out from the lower opening 10 a or the tap water supplied by the water supply pipe 11 to the HP device 50. A bypass pipe 21c is connected to the inlet pipe 21a. The bypass piping 21c can lead the hot water on the lower side of the hot water storage tank 10 flowing out from the lower opening 10a or the tap water supplied by the water supply piping 11 to the three-way valve 52 by bypassing the HP device 50 Do.

  The HP device 50 is configured to include a supercritical heat pump cycle that uses carbon dioxide with a low critical temperature as a refrigerant, and a boiling pump 51 that pumps water to the heat pump cycle. According to the supercritical heat pump cycle, hot water having a higher temperature, for example, 85 ° C. to 90 ° C., can be stored in the hot water storage tank 10 than a general heat pump cycle. The HP device 50 is a boiling device for boiling hot water.

  The boiling pump 51 is a motorized water pump disposed in the inlet pipe 21a. The boiling pump 51 pressure-feeds the hot water supplied on the lower side of the hot water storage tank 10 or the tap water supplied by the water supply pipe 11 to the water passage of the water refrigerant heat exchanger. The boiling pump 51 is controlled by a controller 80.

  The heat pump cycle comprises a plurality of refrigeration cycle functional components. The plurality of refrigeration cycle functional components are at least an electric compressor, a water refrigerant heat exchanger, an electric expansion valve, an air heat exchanger, and an accumulator. These refrigeration cycle functional components are connected by a passage through which the refrigerant flows. A blower for blowing air to the air heat exchanger is provided in the vicinity of the air heat exchanger.

  The expansion valve is pressure reducing means for reducing the pressure of the high pressure refrigerant flowing out of the water refrigerant heat exchanger, and the control device 80 electrically controls the valve opening degree. The air heat exchanger evaporates and evaporates the refrigerant decompressed by the expansion valve by heat exchange with the outdoor air blown by the blower, and supplies the gas refrigerant to the compressor. The rotation speed of the blower is controlled by the controller 80 so as to secure the heat exchange performance of the air heat exchanger. The accumulator performs gas-liquid separation of the refrigerant flowing out of the air heat exchanger, causes only the gas phase refrigerant to be sucked into the compressor, and stores excess refrigerant in the cycle.

  The water refrigerant heat exchanger is a heating heat exchanger that heats hot water or tap water pumped by the boiling pump 51 by the high-temperature and high-pressure refrigerant discharged from the discharge port of the compressor. The water-refrigerant heat exchanger has a refrigerant passage for circulating the refrigerant and a water passage for circulating the hot water. The water-refrigerant heat exchanger has, for example, a two-layer structure in which a forming member of the refrigerant passage and a forming member of the water passage are in close contact with each other in a heat exchange manner. The lower opening 10a is connected to the inlet side of the water passage via an inlet pipe 21a. Moreover, one of the inflow / outflow ports of the first joint 22 is connected to the outlet side of the water passage via the outlet pipe 21b. The first joint 22 is a three-way joint having three inlets and outlets.

  The inlet side of the tank side passage 30 a of the bathtub heat exchanger 30 is connected to another inflow / outlet of the first joint 22. One inlet / outlet of the three-way valve 52 is connected to still another inlet / outlet of the first joint 22. A first upper opening 10 b provided on the upper side of the hot water storage tank 10 is connected to another inflow / outlet of the three-way valve 52. The outlet side of the bypass pipe 21 c is connected to still another inflow / outlet of the three-way valve 52.

  The three-way valve 52 is a switching valve that switches the flow path of the hot water. The three-way valve 52 is a flow that connects the lower opening 10a and the first joint 22 via the bypass pipe 21c, and the flow that connects the lower opening 10a and the first upper opening 10b via the outlet pipe 21b. Switch to the road. The three-way valve 52 is controlled by the controller 80.

  The hot water heated by the water refrigerant heat exchanger flows into the hot water storage tank 10 from the first upper opening 10 b of the hot water storage tank 10 via the first joint 22 and the three-way valve 52. Therefore, the temperature distribution of the hot water in the hot water storage tank 10 tends to occur gradually from the upper side to the lower side.

  The second upper opening 10 c is provided at the upper portion of the hot water storage tank 10, and is an outlet from which the high temperature hot water on the upper side out of the hot water within the hot water storage tank 10 flows out. One inflow port of the first mixing valve 53 is connected to the second upper opening 10 c.

  A first intermediate opening 10 d is provided in the middle of the hot water storage tank 10. The first intermediate opening 10 d is an outlet for flowing out the hot water of the intermediate temperature in the middle portion in the vertical direction among the hot water stored in the hot water storage tank 10. The other inlet of the first mixing valve 53 is connected to the first intermediate opening 10d. In addition, the hot-water supply water of intermediate temperature can be paraphrased as middle warm water. A second intermediate opening 10 e is further provided in the middle of the hot water storage tank 10. The second intermediate opening 10 e is an opening through which the hot and cold water that has passed through the tank side passage 30 a of the bathtub heat exchanger 30 flows.

  The first mixing valve 53 adjusts the mixing ratio of the hot water flowing out of the second upper opening 10c to the hot water flowing out of the first intermediate opening 10d, and adjusts the temperature of the hot water flowing downstream. Temperature control valve. The first mixing valve 53 is, for example, a valve body that simultaneously changes the sectional area of the passage through which the hot water from the second upper opening 10c flows and the sectional area of the passage through which the hot water flows from the first intermediate opening 10d. It is comprised by the flow regulating valve which has an electrically-driven actuator which displaces this valve body. The first mixing valve 53 is controlled by the controller 80.

  One outlet of the second mixing valve 54 is connected to the outlet side of the first mixing valve 53. A water supply pipe 11 is connected to the other inlet of the second mixing valve 54. The second mixing valve 54 adjusts the mixing ratio of the hot water flowing out of the first mixing valve 53 and the tap water supplied from the water supply pipe 11 to adjust the temperature of the hot water flowing downstream. It is a valve. The second mixing valve 54 is controlled by the controller 80.

  One inlet / outlet of the second joint 43 disposed in the bathtub side circulation circuit 44 a is connected to the outlet side of the second mixing valve 54 via the on-off valve 55. The second joint 43 is a three-way joint having three inlets and outlets. The on-off valve 55 opens and closes the bathtub pipe 44b connecting the outlet side of the second mixing valve 54 and the bathtub side circulation circuit 44a, and its operation is controlled by a control signal output from the control device 80. Solenoid valve. The hot water flowing out of the second mixing valve 54 is supplied into the bath 60 through the on-off valve 55 and the second joint 43.

  The bathtub side circulation circuit 44a is a water circulation circuit that circulates the hot water in the bathtub 60 that has flowed out of the bathtub 60 between the inside of the bathtub 60 and the bathtub side passage 30b of the bathtub heat exchanger 30. In addition, the hot and cold water in the bathtub 60 which flowed out of the bathtub 60 can be paraphrased as the bath water. A bathtub water pump 57 and a water level sensor 73 are disposed in the bathtub circulation circuit 44a. The bathtub water pump 57 is an electric water pump that sucks in the bathtub water from the bathtub hot water inlet provided at the middle position in the vertical direction of the bathtub 60 and pumps the water to the bathtub side passage 30b. The bathtub water pump 57 is controlled by the controller 80. The water level sensor 73 is provided in the vicinity of the hot water inlet for the bathtub and is a sensor that detects the amount of hot water in the bathtub 60 based on a change in the detected water pressure or the like. The water level sensor 73 outputs the detected water level information to the control device 80.

  The other inlet / outlet of the second joint 43 is connected to the outlet side of the bathtub water pump 57, and the inlet side of the bathtub side passage 30b is connected to the other inlet / outlet of the second joint 43. . The outlet side of the bathtub side passage 30 b is connected to a hot water discharge port for a bathtub disposed on the lower side of the bathtub 60.

  The bathtub heat exchanger 30 has a tank side passage 30a for circulating the hot water flowing out of the first joint 22, and a bathtub side passage 30b for circulating bath water circulating in the bathtub side circulation circuit 44a. The bathtub heat exchanger 30 is a heat exchanger that exchanges heat between the hot water flowing through the tank passage 30a and the bath water flowing through the bathtub passage 30b. Thus, the bathtub heat exchanger 30 exchanges heat between the hot water supplied by the HP device 50 or the hot water in the hot water storage tank 10 and the hot water in the bath 60 to realize the reheating operation, the bath heat recovery operation, etc. .

  At the outlet side of the tank side passage 30a, there is disposed a hot water supply pump 56 for pressure-feeding the hot water flowing out of the tank side passage 30a to the second intermediate opening 10e. The hot water supply pump 56 is an electric water pump whose operation is controlled by the controller 80.

  The operating device 90 includes a switch that can be operated by the user, and a display that displays an operating state. The operating device 90 is, for example, a remote control provided on a wall of a bathroom. The operating device 90 notifies that the forward boiling operation is being performed when the forward boiling operation described below is performed. The operating device 90 displays, for example, that the forward boiling operation is being performed on the display unit, and notifies the user of the execution of the forward boiling operation as visual information. The controller device 90 may notify the user as auditory information that the forward boiling operation is being performed, for example, from a speaker.

  The control device 80 includes, as a main hardware element, a microcomputer provided with a computer readable storage medium. The storage medium is a non-transitory tangible storage medium which stores non-temporarily a predetermined program readable by a computer. The storage medium may be provided by semiconductor memory or a magnetic disk or the like.

  The control device 80 performs a heating operation of heating the hot water by the HP device 50 and storing the hot water in the hot water storage tank 10. The controller 80 operates the HP device 50 to control the three-way valve 52 to connect the first joint 22 and the first upper opening 10b in the boiling operation. Therefore, the hot water discharged from the lower opening 10a or the tap water supplied by the water supply pipe 11 is pressure-fed to the water passage of the water refrigerant heat exchanger by the boiling pump 51, and is heated by heat exchange with the high temperature high pressure refrigerant. Be done. The high-temperature hot water flowing out of the water passage flows into the hot water storage tank 10 from the first upper opening 10 b through the first joint 22 and the three-way valve 52. The boiling operation is performed until the temperature of the hot water on the upper side of the hot water storage tank 10 detected by the tank water temperature thermistor 71 exceeds a reference boiling temperature, for example 90 ° C.

  The control device 80 performs the boiling operation on the day of heating the first day heat amount on the first day of the predetermined period Ta, and adds the second day heat amount on the first day of the predetermined period Ta on the first day Perform any of the following forward boiling operation to accelerate and heat up the amount of heat thereafter. The control device 80 sets the predetermined period Ta set in advance as the maximum advancing period, and determines the advancing period within the range of the predetermined period Ta. In addition, the control apparatus 80 makes the time of the division | segmentation time of 1 day the time of reaching the division | segmentation time of 1 day. The division time of one day is the time when the unit price of electricity is the lowest in one day, for example, the time to reach midnight.

  In the first embodiment, the control device 80 performs the heating control with the predetermined period Ta being two days. Hereinafter, in the description of the first embodiment, the predetermined period Ta is simply referred to as "two days", the first day of the predetermined period Ta is simply "first day", and the second day of the predetermined period Ta is simply "second day". Also described as "eye". At this time, the control device 80 performs a boiling operation on the first day to heat the calorific value on the first day, and adds to the calorific value on the first day on the first day to accelerate the calorific value on the second day to boil. Perform either forward raising or boiling operation.

  In addition to the boiling operation, the control device 80 performs a reheating operation to heat the hot water in the tub 60 with the high temperature water of the hot water storage tank 10, and an addition hot water operation to supply the high temperature water of the hot water storage tank 10 to the tub 60, Each operation mode capable of increasing the bath temperature can be implemented. The control device 80 is capable of reducing the bath temperature, such as a bath heat recovery operation for recovering the heat of hot water in the bath 60 to the hot water in the hot water storage tank 10, and a feed water operation for supplying tap water to the bath 60. The mode can be implemented. The control device 80 can perform an automatic warming operation that maintains the bath temperature at the set target temperature.

  The control device 80 has an interface unit 81 (hereinafter referred to as an I / F unit 81) to which each of the control target devices described above and various sensors are connected, a processing unit 82 for performing various determination processes, a program, and And a storage unit 83 for storing various data.

  Connected to the I / F unit 81 are the devices constituting the HP device 50, the three-way valve 52, the bathtub water pump 57, the hot water pump 56, the first mixing valve 53, the second mixing valve 54, the on-off valve 55, etc. . The I / F unit 81 outputs the control target devices. Further, to the I / F unit 81, a water level sensor 73, a tank water temperature thermistor 71, a bath water temperature sensor 72, an operating device 90, and the like are connected. The I / F unit 81 inputs various signals to the control device 80.

  Storage unit 83 stores data of past usage results of water heating apparatus 1. The use results are, for example, the amount of heat used (the amount of hot water and the temperature of hot water) for the last past one week, the operation mode at the time of performing the boiling operation, and the power consumption thereof. The storage unit 83 stores calendar information. The storage unit 83 stores electricity charge setting information based on a power supply contract with a power supply source. Therefore, the storage unit 83 stores the electricity bill unit price information by the calendar information and the electricity bill setting information.

  The processing unit 82 uses the information acquired from various sensors through the I / F unit 81 and the data stored in the storage unit 83 to perform determination processing and arithmetic processing according to a predetermined program. The processing unit 82 performs a boiling determination process as to which of the boiling operation and the forward boiling operation to be performed on the day. The processing unit 82 carries out a boiling operation on the first day to heat the heat for the first day and a forward boiling operation to heat the heat for the second day on the first day.

  As shown in FIG. 2, the processing unit 82 functions as a functional block, and includes a charge determining unit 82a, a heat quantity predicting unit 82b, a heat radiation predicting unit 82c, a required heat quantity calculating unit 82d, a cost calculating unit 82e, and a judging unit 82f. , A boiling processing unit 82g, and a notification unit 82h.

  The charge determination unit 82 a acquires the electricity charge setting information and the calendar information from the storage unit 83. The charge determination unit 82a determines the electricity charge unit price R for each day in the predetermined period Ta based on the acquired information. Specifically, the charge determination unit 82a specifies the dates of the first day and the second day by the calendar information. The charge determination unit 82a determines the electricity charge unit price R1 on the first day and the electricity charge unit R2 on the second day according to the dates on the first and second days and the charge setting information.

  The heat amount prediction unit 82 b acquires the past heat amount usage results from the storage unit 83. The past heat use results are included in the past use results. The heat quantity prediction unit 82b predicts the estimated use heat quantity Qp of each day in the predetermined period Ta based on the past use results. Specifically, the heat quantity prediction unit 82b calculates the predicted use heat quantity Qp1 on the first day and the predicted use heat quantity Qp2 on the second day, based on the use record. For example, the heat quantity prediction unit 82b sets the use heat quantity of the day having the largest use heat quantity in the past one week as the predicted use heat quantity of each day. Alternatively, the estimated amount of heat used Qp may be the amount of heat obtained by adding the deviation to the average daily amount of heat used for the past week. Alternatively, the heat consumption used on each day of the past one week may be the predicted heat usage Qp1 and Qp2 on the same day of the predetermined period Ta.

  The heat release prediction unit 82c calculates a predicted heat release amount that is predicted to be released from the hot water storage tank 10 in a predetermined period Ta. The heat release prediction unit 82c acquires, for example, measured values of the amount of heat stored in the hot water storage tank 10 immediately after boiling in the past and the amount of heat stored in the hot water storage tank 10 after a predetermined time from boiling. The predicted heat release is calculated from the difference. Alternatively, the heat release prediction unit 82c acquires the unit heat quantity and the heat release amount per unit time of the hot water storage tank 10 stored in advance in the storage unit 83, and the acquired heat release amount, the estimated use heat quantity Qp, and the inside of the hot water storage tank 10 The estimated heat release may be calculated based on the time for which the estimated use heat quantity Qp is stored.

  The required heat amount calculation unit 82d acquires the predicted use heat amount Qp and the predicted heat release amount. The required heat quantity calculation unit 82d calculates the required heat quantity Qe for each day and the heating up operation for each day when boiling is performed each day in a predetermined period Ta based on the predicted use heat quantity Qp and the predicted heat release quantity. Calculate the required heat quantity Qt at the time of moving forward necessary for performing. Hereinafter, the required heat quantity Qe for each day is simply referred to as the required heat quantity Qe, and the required heat quantity Qt during forward driving is also simply referred to as the required heat quantity Qt. Specifically, the required heat amount calculation unit 82d calculates the required heat amount Qe1 required on the first day and the required heat amount Qe2 required on the second day based on the predicted heat use amounts Qp1 and Qp2 and the predicted heat release amount. . Further, the necessary heat amount calculation unit 82d calculates the necessary heat amount Qt in the case of performing the forward boiling boiling operation, based on the predicted use heat amounts Qp1 and Qp2 and the predicted heat release amount.

  The cost calculation unit 82e acquires the electricity unit price R and the necessary heat amounts Qe and Qt. The cost calculation unit 82e calculates a first running cost Ce, which is a running cost when boiling is performed each day, and a second running cost Ct, which is a running cost when performing an accelerated boiling operation. Therefore, the cost calculation unit 82e is a running cost calculation unit. Hereinafter, the first running cost Ce is simply described as the cost Ce, and the second running cost Ct is simply described as the cost Ct. More specifically, the cost calculation unit 82e adds the cost of heating the required heat quantity Qe1 on the first day to the cost of heating the necessary heat quantity Qe2 on the second day, thereby adding the cost Ce. calculate. The cost calculation unit 82e calculates the cost Ct required when the required heat quantity Qt is boiled on the first day. When there is a time zone in which the electricity bill unit price is different in one day, the cost calculation unit 82e calculates the cost using the electricity bill unit price in the time slot having the lowest electricity bill unit price in the day.

  The determination unit 82f acquires the costs Ce and Ct. The determination unit 82f determines whether the cost when the forward boiling operation is performed is lower than the cost when the boiling is performed each day. Specifically, the determination unit 82f acquires the costs Ce and Ct, and determines whether the cost Ct is less than the cost Ce.

  The boiling processing unit 82g acquires the determination result of the determination unit 82f. The boiling processing unit 82g executes either the boiling operation or the forward boiling operation on the first day on the first day. The boiling processing unit 82g executes the boiling operation on the day when the determination unit 82f determines that the cost is lower if the heating operation is performed each day, and the determination unit 82f performs the boiling operation to move it forward. If it is determined that the cost is low, the forward boiling operation is performed. Specifically, the boiling processing unit 82g performs boiling of the necessary heat quantity Qt when the determination unit 82f determines that the cost Ct is lower than the cost Ce. If the determination unit 82f determines that the cost Ct is not lower than the cost Ce, the boiling processing unit 82g performs boiling of the necessary heat quantity Qe1.

  The notification unit 82h acquires the determination result of the determination unit 82f. The notification unit 82h notifies the user that the forward boiling operation is being performed when the determination unit 82f executes the forward boiling operation. The notification unit 82h notifies the user that, for example, the forward boiling operation is being performed by the operation device 90.

  Next, an example of control executed by the control device 80 will be described. The control device 80 determines whether or not to perform the forward boiling operation on the first day. The case of performing the forward boiling operation is a case where the cost increases if the boiling operation is performed every day. Such a situation may occur when the unit price of electricity varies from day to day. For example, when the unit price of electricity is higher on weekends and holidays than on weekdays, if the boiling operation is performed on a daily basis, the boiling cost per unit heat quantity will be higher on weekends and holidays than on weekdays. The control shown in FIG. 3 is implemented to avoid the situation described above. The control shown in FIG. 3 is executed, for example, when the time of the first day reaches the lowest time zone of the electricity bill unit price.

  At step 110, data on the use record is acquired from the storage unit 83, and the process proceeds to step 120. In step 120, the estimated heat consumption Qp1, Qp2 is calculated based on the acquired actual usage data, and the process proceeds to step 130. Steps 110 and 120 correspond to the heat quantity prediction unit 82b.

  In step 130, based on the acquired usage record data, a predicted heat release amount predicted to be released from the hot water storage tank 10 is calculated, and the process proceeds to step 140. Steps 110 and 130 correspond to the heat release prediction unit 82c. In step 140, the required heat quantity Qe1, Qe2, Qt is calculated based on the predicted use heat quantity Qp1, Qp2 and the predicted heat release amount, and the process proceeds to step 150. Step 140 corresponds to the required heat amount calculation unit 82d.

  In step 150, the electricity charge unit price R1 for the first day and the electricity charge unit price R2 for the second day are acquired from the storage unit 83, and the process proceeds to step 160. Step 150 corresponds to the charge determination unit 82a. In step 160, the costs Ce and Ct are calculated from the electricity unit prices R1 and R2 and the required heat amounts Qe1, Qe2 and Qt, and the process proceeds to step 170. Step 160 corresponds to the cost calculation unit 82e.

  In step 170, it is determined whether the cost Ct is less than the cost Ce. Step 170 corresponds to the determination unit 82f. If the determination at step 170 is negative, the process proceeds to step 180. At step 180, control is performed to heat the required heat quantity Qe1. In other words, in step 180, the boiling operation is performed on the day. After the process of step 180 is executed, the flowchart shown in FIG. 3 is ended. If the process of steps 170 and 180 makes it possible to suppress the cost by performing the boiling operation on each day rather than performing the forward boiling operation, the boiling operation can be performed on the day. When the process of step 180 is performed and the flowchart is ended, the heating determination process shown in FIG. 3 is executed again for the new two days on the next day.

  If it is determined in step 170 that the cost Ct is less than the cost Ce, the process proceeds to step 190. In step 190, control for boiling the required heat quantity Qt is performed. In other words, at step 190, the forward heating operation is performed. If the process of steps 170 and 190 makes it possible to suppress costs more than performing boiling up operation on each day, it is possible to execute the boiling up operation on the first day. Each of step 180 and step 190 corresponds to the boiling processing unit 82g. After the process of step 190 is performed, the process proceeds to step 195. In step 195, the controller 90 is informed that the forward boiling operation is being performed. Step 195 corresponds to the notification unit 82h. After the process of step 195 is performed, the flowchart illustrated in FIG. 3 is ended. When the process of step 190 is performed and the flowchart is ended, the heating determination process shown in FIG. 3 is executed again for the new two days on the next day of the second day.

  Next, the process of FIG. 3 will be described using the specific example shown in FIG. 4 to FIG. FIG. 4 is an example in which the electricity bill price on the second day is higher than on the first day. FIG. 5 is an example in which the electricity bill prices on the first and second days are the same. In the example shown in FIG. 4, the electricity charge unit price R1 on the first day is 10 yen / kWh, and the electricity charge unit price R2 on the second day is 15 yen / kWh. When data of actual use is acquired in step 110 and the predicted use heat quantity Qp is calculated in step 120, the predicted use heat quantity Qp1 on the first day is 5 kWh, and the predicted use heat quantity Qp2 on the second day is 5 kWh. When the predicted heat release amount is calculated in step 130, it is 0.1 kWh per kWh per day. In step 140, when the required heat quantity Qe1, Qe2, Qt is calculated from the estimated use heat quantity Qp1, Qp2 and the predicted heat release quantity, the required heat quantity Qe1 is 5.5 kWh, the required heat quantity Qe2 is 5.5 kWh, and the required heat quantity Qet is It is 11.5 kWh. In step 150, the electricity rate unit price R1, R2 is acquired, and in step 160, the costs Ce, Ct are calculated from the required heat amounts Qe1, Qe2, Qt and the electricity rate unit price R1, R2. The cost Ce is obtained from Ce = Qe1 × R1 + Qe2 × R2, and Ce is 137.5 yen. The cost Ct is obtained from Ct = (Qe1 + Qe2) × R1, and Ct is 115 yen. In step 170, since the cost Ct is 115 yen and the cost Ce is 137.5 yen, it is determined that the cost Ct is less than the cost Ce. Therefore, in the case of the example shown in FIG. 4, the process proceeds to step 190, and the forward heating operation is performed to heat the hot water of 11.5 kWh on the first day.

  In the example shown in FIG. 5, the electricity charge unit price R1 on the first day is 10 yen / kWh, and the electricity charge unit price R2 on the second day is 10 yen / kWh. When data of actual use is acquired in step 110 and the predicted use heat quantity Qp is calculated in step 120, the predicted use heat quantity Qp1 on the first day is 5 kWh, and the predicted use heat quantity Qp2 on the second day is 5 kWh. When the predicted heat release amount is calculated in step 130, it is 0.1 kWh per kWh per day. In step 140, when the required heat quantity Qe1, Qe2 and Qt is calculated from the estimated use heat quantity Qp1 and Qp2 and the predicted heat release quantity, the required heat quantity Qe1 is 5.5 kWh, the required heat quantity Qe2 is 5.5 kWh and the required heat quantity Qt is It is 11.5 kWh. In step 150, the electricity rate unit price R1, R2 is acquired, and in step 160, the costs Ce, Ct are calculated from the required heat amounts Qe1, Qe2, Qt and the electricity rate unit price R1, R2. The cost Ce is calculated from Ce = Qe1 × R1 + Qe2 × R2 and is 110 yen. The cost Ct is obtained from Ct = (Qe1 + Qe2) × R1, and Ct is 115 yen. In step 170, since the cost Ct is 115 yen and the cost Ce is 110 yen, it is determined that the cost Ct is not lower than the cost Ce. Therefore, the process proceeds to step 190, the boiling operation is performed on the day, the boiling of hot water for 5.5 kWh is started, and the process proceeds to step 195. In step 195, the notification unit 82h notifies that the forward boiling heating operation is being performed, and the heating determination processing ends.

  FIG. 6 is an example in which the unit price of electricity on the second day differs depending on the time zone. In the example shown in FIG. 6, the electricity charge unit price R1 on the first day is 10 yen / kWh, the electricity charge unit price R2 on the second day is 8 yen kWh from 0 o'clock to 2 o'clock, and 2 o'clock to 23:59 It is 20 yen / kWh until the minute. When data of actual use is acquired in step 110 and the predicted use heat quantity Qp is calculated in step 120, the predicted use heat quantity Qp1 on the first day is 5 kWh, and the predicted use heat quantity Qp2 on the second day is 10 kWh. When the predicted heat release amount is calculated in step 130, it is 0.1 kWh per kWh per day. When the required heat quantity Qe1, Qe2, Qt is calculated from the estimated use heat quantity Qp1 and Qp2 and the predicted heat release quantity in step 140, the required heat quantity Qe1 is 5.5 kWh, the required heat quantity Qe2 is 11 kWh, and the required heat quantity Qt is 17.2. It is 5 kWh. In step 150, the electricity unit prices R1 and R2 are acquired, and in step 160, the costs Ce and Ct are calculated from the required heat amounts Q1, Q2 and Qt and the electricity unit prices R1 and R2. R2a falls below R2b, where R2a is the electricity rate unit price between 0 o'clock and 2 o'clock, and R2a is the electricity rate unit price between 2 o'clock and 23:59. For this reason, when calculating the cost Ce, on the second day, the required amount of heat is boiled between 0 o'clock and 2 o'clock which is the lowest time zone of the electricity bill unit price, and it is boiled up between 0 o'clock and 2 o'clock The remaining amount of heat not present is calculated as boiling between 2 o'clock and 23:59. For example, assuming that the water heating apparatus 1 is capable of boiling 1 kWh per hour, 2 kWh is boiled between 0 o'clock and 2 o'clock, and the remaining 9 kWh is boiled between 2 o'clock and 23:59. Make a raise. Assuming that the heat quantity on boiling point between 0 o'clock and 2 o'clock is Qe2a and the heat quantity on boiling point between 2 o'clock and 23:59 is expressed as Qe2 b, cost Ce is calculated from Ce = Qe1 × R1 + Qe2 a × R2 a + Qe2 b × R2 b, 251 yen It is. The cost Ct is calculated from Ct = (Qe1 + Qe2) × R1 and is 175 yen. In step 170, since the cost Ct is 175 yen and the cost Ce is 251 yen, it is determined that the cost Ct is less than the cost Ce. Therefore, the process proceeds to step 190, and the forward boiling heating operation is performed to start boiling of hot water having a heat quantity of 17.5 kWh, and the process proceeds to step 195. In step 195, the notification unit 82h notifies that the forward boiling heating operation is being performed, and the heating determination processing ends.

  Next, the effect which the hot-water supply apparatus 1 of 1st Embodiment brings about is demonstrated. The water heating apparatus 1 of the first embodiment includes an HP device 50 for boiling hot water, a hot water storage tank 10 for storing hot water, and a control device 80 for controlling the HP device 50. The control device 80 operates the heating energy required to carry out the boiling every two days each day, and the heating energy necessary for the second day to accelerate and heat up the heating energy required for the second day. And a required heat amount calculation unit 82d for calculating the necessary heat amount Qt at the time of advancing at the time of performing the above. The control device 80 calculates the first running cost required to boil the required heat quantity Qe each day for two days and the second running cost required to boil the required heat quantity Qt at the first day on the first day. It has a cost calculation unit 82e. The control device 80 includes a determination unit 82f that determines whether the first running cost is less than the second running cost. The control device 80 includes the boiling processing unit 82g that executes the forward boiling heating operation when the determination unit 82f determines that the first running cost is lower than the second running cost.

  According to this, when the required quantity of heat Qe is boiled for each of two days, the hot water supply device 1 of the first embodiment raises the running cost when running cost is higher than the case of carrying out the forward boiling operation. Driving can be performed. Therefore, since it becomes possible to avoid boiling on a day when the electricity unit price is higher than the first day, it is possible to suppress the boiling cost compared to the case where the boiling operation is performed every day . This makes it possible to suppress the boiling cost when the electricity rate unit price differs depending on the day.

  The control device 80 of the water heating apparatus 1 according to the first embodiment has a heat quantity prediction unit 82b that calculates a predicted heat quantity Qp expected to be used every two days based on past heat quantity usage results. . The control device 80 has a heat radiation prediction unit 82c that calculates a predicted heat radiation amount predicted to be released from the hot water storage tank 10. The necessary heat quantity calculation unit 82d calculates the required heat quantity Qe and the required heat quantity Qt for each forward movement based on the predicted use heat quantity Qp and the predicted heat release quantity.

  According to this, it is possible to calculate the required heat quantity Qe and the required heat quantity Qt for each day from the past use results of the hot water supply device 1. Therefore, it is possible to calculate the required heat quantity Qe and Qt adapted to the actual use of the user, and to suppress waste of the heat quantity.

  The water heating apparatus 1 according to the first embodiment includes a storage unit 83 that stores calendar information and electricity charge setting information. According to this, the calendar information and the electricity charge setting information can be stored in the hot water supply device 1. Therefore, since the heating determination processing can be performed without acquiring information from the outside, calendar information and electricity bill setting information can be acquired without depending on the status of communication with the outside.

  The cost calculation unit 82e of the water heating apparatus 1 according to the first embodiment has the lowest cost Ce required to boil the required heat quantity Qe in the time slot where the electricity bill price on each day is the lowest, and the lowest electricity bill price on the first day. The cost Ct required to boil the required heat quantity Qt in the time zone is calculated. The boiling processing unit 82g executes the accelerated boiling operation during the time zone in which the electricity bill price on the first day is the lowest. According to this, since the boiling operation can be performed in the time slot where the electricity unit price is lowest in one day, it is possible to suppress the cost at the time of boiling.

  The hot-water supply apparatus 1 of 1st Embodiment has the alerting | reporting part 82h which alert | reports execution of a forward boiling heating operation, when performing a forward boiling heating operation. According to this, it is possible to notify the user of the execution of the forward boiling operation when the forward boiling operation is performed.

Second Embodiment
In the second embodiment, a modification of the above-described embodiment will be described. Components in FIG. 7 having the same reference numerals as those in the above-described embodiment can be referred to the description of the above-described embodiment. The second embodiment differs from the first embodiment in that the predetermined period Ta is 3 days.

  In the second embodiment, the control device 80 performs boiling control by setting Ta for a predetermined period for three days. Hereinafter, in the description of the second embodiment, the predetermined period Ta is simply referred to as "three days", the first day of the predetermined period Ta is simply "first day", and the second day of the predetermined period Ta is simply "second day". The third day of the predetermined period Ta is simply referred to as "third day". The control device 80 carries out a boiling operation on the day of boiling the calorific value of the first day on the first day. The control device 80 adds the heat of the first day to the heat of the first day and accelerates the heat of the second day by advancing it for two days, and the heat of the first day at the first day In addition to the minutes, the heat content up to the third day is accelerated and boiled for three days, and the boiling operation for three days is performed. The control device 80 selects and executes one of the day's boiling operation, the two-day advance boiling operation, and the three-day advance boiling operation.

  The charge determination unit 82a determines the electricity charge unit price R3 on the third day in addition to the electricity charge unit prices R1 and R2. The heat quantity prediction unit 82b calculates a predicted use heat quantity Qp3 predicted to be used on the third day in addition to the predicted use heat quantity Qp1 and Qp2. The required heat amount calculation unit 82d calculates the required heat amount Qe3 for the third day in addition to the required heat amounts Qe1 and Qe2 based on the predicted heat amounts Qp1, Qp2 and Qp3 and the predicted heat release amounts. The necessary heat quantity calculation unit 82d is based on the predicted heat quantities Qp1, Qp2 and Qp3 and the predicted heat radiation amount, the required heat quantity Qt2 at the time of advancing for 2 days of advancing boiling up operation, 3 days of advancing boiling up operation Calculate the required heat quantity Qt3 at the time of moving forward when performing.

  The cost calculation unit 82e calculates the cost Ce when boiling is performed on each day. The cost calculation unit 82e boils up the required heat quantity Qt2 on the first day, and calculates the cost Ct2 that is incurred when the required heat quantity Qe3 is boiled on the third day. In other words, the cost calculation unit 82e executes the forward boiling operation for two days on the first day, and calculates the cost Ct2 when the boiling operation is performed on the third day. The cost calculation unit 82e calculates a cost Ct3 required when the required heat quantity Qt3 is boiled on the first day. In other words, the cost calculation unit 82e calculates the cost Ct3 when the forward boiling operation for three days is performed on the first day. When there is a time zone in which the electricity bill unit price is different in one day, the cost calculation unit 82e calculates the cost using the electricity bill unit price in the time slot having the lowest electricity bill unit price in the day.

  The determination unit 82f determines which of the cost Ce, the cost Ct2, and the cost Ct3 is the lowest cost. In other words, the determination unit 82f has a cost in the case of performing the boiling operation every day, a cost in the case of performing the boiling operation on that day on the third day after performing the forward boiling operation for two days, And it is determined which of the costs in the case of performing the forward boiling operation for 3 days is the lowest.

  The boiling processing unit 82 g performs one of the first day boiling operation, the two-day advance boiling operation, and the three-day advance boiling operation on the first day. The boiling processing unit 82g executes the accelerated boiling operation for three days when the determination unit 82f determines that the cost in the case of executing the accelerated boiling operation for three days is the lowest. If the determining unit 82f determines that the cost when the boiling operation is performed on the third day after performing the accelerated boiling operation for two days is two days, the boiling processing unit 82g determines that the cost is the lowest. Execute the forward boiling operation. If the determination unit 82f determines that the cost when the heating operation is performed on each day is the lowest, the heating operation is performed on the first day of the first day.

  Next, an example of control executed by the processing unit 82 according to the second embodiment will be described with reference to FIG. In step 120 b, predicted heat consumption Qp 1, Qp 2, Qp 3 is calculated based on the use record data, and the process proceeds to step 130. In step 130, the predicted heat release amount is calculated, and the process proceeds to step 140b. In step 140b, the necessary heat amounts Qe1, Qe2, Qe3, Qt2, and Qt3 are calculated, and the process proceeds to step 150b. In step 150b, the electricity unit prices R1, R2, R3 are acquired, and the process proceeds to step 160b. In step 160b, the costs Ce, Ct2 and Ct3 are calculated based on the required heat amounts Qe1, Qe2, Qe3, Qt2 and Qt3 and the electricity unit prices R1, R2 and R3, and the process proceeds to step 170b.

  In step 170b, it is determined whether the cost Ce is the minimum among the cost Ce, the cost Ct2, and the cost Ct3. If it is determined at step 171 that the operation is the minimum, the case where the heating operation on the first day is performed is the lowest cost, so the process proceeds to step 180 b. In step 180b, the heating operation on the current day is performed to heat the required heat amount Qe1, and the flowchart of FIG. 7 is ended. When the boiling operation is performed on the day, the heating determination process shown in FIG. 7 is performed again for the new three days the next day.

  If it is determined in step 170 b that the result is negative, the process proceeds to step 171 b. In step 171 b, it is determined whether the cost Ct2 is minimum. If it is determined in step 171b that the operation is the minimum, then the case where the two-day advance boiling operation is performed is the lowest cost, so the process proceeds to step 190b. In step 190 b, the two-day advance boiling operation is started, and the process proceeds to step 195. In step 195, the notification unit 82h notifies that the advance boiling operation for two days is being performed, and the flowchart of FIG. 7 is ended. When the forward boiling operation for two days is performed, the boiling determination process shown in FIG. 7 is performed again for the third day, that is, two days after the second day.

  If NO in step 171b, the cost Ct3 is the minimum cost, and the process proceeds to step 191b. In step 191 b, the forward boiling operation for three days is started, and the process proceeds to step 195. In step 195, the notification unit 82h notifies that the advance boiling operation for three days is being performed, and the flowchart of FIG. 7 is ended. When the forward boiling operation for three days is performed, the boiling determination process shown in FIG. 7 is performed again on the next day of the third day, that is, three days after the third day.

  Next, the process of FIG. 7 will be described using the specific example shown in FIG. 8 to FIG. FIG. 9 shows an example in which the unit price of electricity on the second and third days falls below the first day. FIG. 8 is an example in which the electricity rate unit price on the second and third days is higher than that on the first day. FIG. 10 is an example in which the unit price of electricity on the second day exceeds the first day, and the unit price on the third day is lower than the first day.

  In the example shown in FIG. 8, the electricity charge unit price R1 for the first day is 10 yen / kWh, the electricity charge unit price R2 for the second day is 15 yen / kWh, and the electricity charge unit price R3 for the third day is 15 yen It is / kWh. When the data of the actual use is acquired in step 110 and the predicted use heat quantity Qp is calculated in step 120b, the predicted use heat quantity Qp1 on the first day is 5 kWh, the predicted use heat quantity Qp2 on the second day is 5 kWh, the predicted use on the third day The heat quantity Qp3 is 5 kWh. When the predicted heat release amount is calculated in step 130, it is 0.1 kWh per kWh per day. In step 140b, when the required heat quantity Qe1, Qe2, Qe3, Qt2 and Qt3 is calculated from the predicted use heat quantity Qp1, Qp2, Qp3 and the predicted heat release quantity, the required heat quantity Qe1, Qe2, Qe3 is 5.5 kWh, and the required heat quantity Qt2 is 11.2. The required heat quantity Qt3 is 5 kWh and 18 kWh. In step 150b, the electricity bill per unit price R1, R2 and R3 is acquired, and in step 160b, the costs Ce, Ct2 and Ct3 are calculated from the necessary heat quantities Qe1, Qe2, Qe3, Qet2 and Qte3 and the electricity bill prices R1, R2 and R3. The cost Ce is calculated from Ce = Qe1 × R1 + Qe2 × R2 + Qe3 × R3 and is 220 yen. The cost Ct2 is 197.5 yen, which is obtained from Ct2 = (Qe1 + Qe2) × R1 + Qe3 × R3. The cost Ct3 is obtained from Ct3 = (Qe1 + Qe2 + Qe3) × R1 and is 180 yen. Therefore, in step 170 b, it is determined that the cost Ce is not the minimum, so the process proceeds to step 172. In step 171 b, since it is determined that the cost Ct2 is not the minimum, the process proceeds to step 191 b. In step 191 b, a forward boiling operation for 3 days is performed to heat the hot water of 18 kWh, and the process proceeds to step 195. In step 195, the notification unit 82h notifies that the forward boiling operation is being performed for three days, and the heating determination process is ended.

  In the example shown in FIG. 9, the electricity charge unit price R1 on the first day is 10 yen / kWh, the electricity charge unit price R2 on the second day is 8 yen / kWh, and the electricity charge unit price R3 on the third day is 8 yen It is / kWh. When the data of the actual use is acquired in step 110 and the predicted use heat quantity Qp is calculated in step 120b, the predicted use heat quantity Qp1 on the first day is 5 kWh, the predicted use heat quantity Qp2 on the second day is 5 kWh, the predicted use on the third day The heat quantity Qp3 is 5 kWh. When the predicted heat release amount is calculated in step 130, it is 0.1 kWh per kWh per day. In step 140b, when the required heat quantity Qe1, Qe2, Qe3, Qt2 and Qt3 is calculated from the predicted use heat quantity Qp1, Qp2, Qp3 and the predicted heat release quantity, the required heat quantity Qe1, Qe2, Qe3 is 5.5 kWh, and the required heat quantity Qt2 is 11.2. The required heat quantity Qt3 is 5 kWh and 18 kWh. In step 150b, the electricity bill per unit price R1, R2 and R3 is acquired, and in step 160b, the costs Ce, Ct2 and Ct3 are calculated from the necessary heat quantities Qe1, Qe2, Qe3, Qet2 and Qte3 and the electricity bill prices R1, R2 and R3. The cost Ce is 143 yen, which is determined from Ce = Qe1 × R1 + Qe2 × R2 + Qe3 × R3. The cost Ct2 is obtained from Ct2 = (Qe1 + Qe2) × R1 + Qe3 × R3 and is 159 yen. The cost Ct3 is obtained from Ct3 = (Qe1 + Qe2 + Qe3) × R1 and is 180 yen. Therefore, in step 170b, it is determined that the cost Ce is minimum, so the process proceeds to step 180b. In step 180b, the boiling operation is performed on the current day to heat the hot water of 5.5 kWh on the first day, and the boiling determination process is ended.

  In the example shown in FIG. 10, the electricity charge unit price R1 on the first day is 10 yen / kWh, the electricity charge unit price R2 on the second day is 15 yen / kWh, and the electricity charge unit price R3 on the third day is 7 yen It is / kWh. When the data of the actual use is acquired in step 110 and the predicted use heat quantity Qp is calculated in step 120b, the predicted use heat quantity Qp1 on the first day is 5 kWh, the predicted use heat quantity Qp2 on the second day is 5 kWh, the predicted use on the third day The heat quantity Qp3 is 5 kWh. When the predicted heat release amount is calculated in step 130, it is 0.1 kWh per kWh per day. In step 140b, when the required heat quantity Qe1, Qe2, Qe3, Qt2 and Qt3 is calculated from the predicted use heat quantity Qp1, Qp2, Qp3 and the predicted heat release quantity, the required heat quantity Qe1, Qe2, Qe3 is 5.5 kWh, and the required heat quantity Qt2 is 11.2. The required heat quantity Qt3 is 5 kWh and 18 kWh. In step 150b, the electricity charge unit price R1, R2 and R3 are acquired, and in step 160b, the costs Ce, Ct2 and Ct3 are calculated from the required heat amounts Qe1, Qe2, Qe3, Qt2 and Qt3 and the electricity charge unit prices R1, R2 and R3. The cost Ce is calculated from Ce = Qe1 × R1 + Qe2 × R2 + Qe3 × R3 and is 176 yen. The cost Ct2 is calculated from Ct2 = (Qe1 + Qe2) × R1 + Qe3 × R3 and is 153.5 yen. The cost Ct3 is obtained from Ct3 = (Qe1 + Qe2 + Qe3) × R1 and is 180 yen. Therefore, in step 170 b, it is determined that the cost Ce is not the minimum, so the process proceeds to step 172. In step 171 b, since it is determined that the cost Ct 2 is minimum, the process proceeds to step 190 b. In step 190 b, a two-day advance boiling operation is performed to heat the hot water of 11.5 kWh, and the process proceeds to step 195. In step 195, the notification unit 82h notifies that the advance boiling operation is being performed for two days, and the heating determination processing is ended.

  Next, the effect which the hot-water supply apparatus 1 of 2nd Embodiment brings about is demonstrated. The water heating apparatus 1 of the second embodiment includes an HP device 50 for boiling hot water, a hot water storage tank 10 for storing hot water, and a control device 80 for controlling the HP device 50. The control device 80 moves the heating amount Qe necessary for performing boiling on each day for three days and the heating amount necessary for the second day and onward on the first day to accelerate and raise the boiling point. A necessary heat quantity calculation unit 82d is provided to calculate the required heat quantity Qt at the time of advance necessary for performing the operation. The control device 80 calculates the first running cost required to boil the required heat quantity Qe on each day of three days and the second running cost required to boil the required heat quantity Qt at the first day on the first day. It has a cost calculation unit 82e. The control device 80 includes a determination unit 82f that determines whether the first running cost is less than the second running cost. The control device 80 includes the boiling processing unit 82g that executes the forward boiling heating operation when the determination unit 82f determines that the first running cost is lower than the second running cost.

  According to this, when the required amount of heat Qe is boiled for each of three days, the water heating apparatus 1 of the second embodiment raises the running cost when the running cost is higher than the case of performing the forward boiling operation. Driving can be performed. Therefore, since it becomes possible to avoid boiling on a day when the electricity unit price is higher than the first day, it is possible to suppress the boiling cost compared to the case where the boiling operation is performed every day . This makes it possible to suppress the boiling cost when the electricity rate unit price differs depending on the day. Furthermore, the water heating apparatus 1 according to the second embodiment determines which of the case where the amount of heat up to the second day is advanced and the case where the amount of heat up to the third day is earlier is lower cost, which is lower cost. The forward boiling operation can be performed by the number of days ahead.

Third Embodiment
In the third embodiment, a modification of the above-described embodiment will be described. The third embodiment is different from the above-described embodiment in that it is determined whether there is a day on which the electricity bill unit price is higher than that of the first day.

  In the third embodiment, the control device 80 performs the heating control with the predetermined period Ta being two days. Hereinafter, in the description of the third embodiment, the predetermined period Ta is also simply described as "two days", the first day of the predetermined period Ta is simply "first day", and the second day of the predetermined period Ta is simply "second day". Also described as "eye". At this time, the control device 80 performs a boiling operation on the first day to heat the calorific value on the first day, and adds to the calorific value on the first day on the first day to accelerate the calorific value on the second day to boil. Perform either forward raising or boiling operation.

  As illustrated in FIG. 11, the processing unit 382 includes, as functional blocks, a charge determination unit 382a, a determination unit 382f, a boiling processing unit 382g, and a notification unit 382h. The processing unit 382 corresponds to the processing unit 82 in the first embodiment. The charge determination unit 382a corresponds to the charge determination unit 82a in the first embodiment. The determination unit 382 f acquires data of the electricity charge unit price R. The determination unit 382f determines whether or not the electricity unit price includes a date higher than the boiling determination processing date in the predetermined period Ta. Specifically, it is determined whether the electricity charge unit price R1 is less than the electricity charge unit price R2. When there is a time zone in which the electricity bill unit price differs in one day, the determination unit 382f performs the determination using the electricity bill unit price in the time slot having the lowest electricity bill unit price in the day. The boiling processing unit 382 g executes the accelerated boiling operation when the determination unit 382 f determines that the electricity charge unit price includes a day higher than the electricity charge unit price on the first day in the predetermined period Ta. Specifically, if the determination unit 382f determines that the electricity charge unit price R1 is less than the electricity charge unit price R2, the acceleration heating operation is performed. If the determination unit 382f determines that the electricity charge unit price R1 is not lower than the electricity charge unit price R2, the boiling processing unit 382g executes the heating operation on the same day. The notification unit 382 h corresponds to the notification unit 82 h in the first embodiment.

  Next, an example of control executed by the processing unit 382 of the third embodiment in FIG. 12 will be described. In step 310, the electricity unit prices R1 and R2 are acquired, and the process proceeds to step 320. In step 320, it is determined whether the electricity charge unit price R1 is less than the electricity charge unit price R2. If the determination at step 320 is negative, the process proceeds to step 330. In step 330, the heating operation is performed on the first day, and the flowchart is ended.

  If it is determined in step 320 that the electricity bill price R1 is less than the electricity bill price R2, then the process proceeds to step 340. At step 340, the forward heating operation is performed, and the present flowchart is ended.

  Next, the process of FIG. 12 will be described using the specific example of FIGS. 13 and 14. FIG. 13 is an example in which the unit price of electricity on the second day is higher than that on the first day. FIG. 14 is an example in which the unit price of electricity on the second day is the same as that on the first day. In the example shown in FIG. 13, the electricity charge unit price R1 on the first day is 10 yen / kWh, and the electricity charge unit price R2 on the second day is 15 yen / kWh. In step 310, the electricity rate unit price R1, R2 is acquired, and the process proceeds to step 320. At step 320, the electricity unit price R1 falls below the electricity unit price R2, so the process proceeds to step 340. At step 340, the forward heating operation is performed, and the process proceeds to step 345. In step 345, the notification unit 382h notifies that the forward boiling heating operation is being performed, and the heating determination processing ends.

  In the example shown in FIG. 14, the electricity charge unit price R1 on the first day is 10 yen / kWh, and the electricity charge unit price R2 on the second day is 10 yen / kWh. In step 350, the electricity unit prices R1 and R2 are acquired, and the process proceeds to step 370. At step 370, since the electricity bill price R1 is not lower than the electricity bill price R2, the process proceeds to step 380. In step 380, the heating operation is performed on the day, and the heating determination processing is ended.

  Next, the effect which the hot-water supply apparatus 1 of 3rd Embodiment brings about is demonstrated. The water heating apparatus 1 according to the third embodiment includes a boiling device 50 for boiling hot water, a hot water storage tank 10 for storing hot water, and a control device 80 for controlling the boiling device. The control device 80 includes a determination unit 382 f that determines whether there is a day on which the electricity unit price is higher than the first day on the second day. If the determination unit 382f determines that the electricity charge unit price is higher than the first day on the second day, the control unit 80 causes the heat amount necessary for the second day to be accelerated and boiled on the first day. It has 382 g of boiling processing parts which perform the advance boiling operation to raise.

  According to this, the water heating apparatus 1 of the third embodiment can execute the forward boiling operation when the second day includes a day on which the electricity unit price is higher than the first day. Therefore, since it becomes possible to avoid that boiling is performed on the day whose electricity rate unit price is high, it becomes possible to suppress boiling cost compared with the case where boiling operation is performed on each day. Therefore, even when the unit price of electricity rates differs depending on the day, the boiling cost can be suppressed. The water heater 1 of the third embodiment can suppress the cost particularly when the predetermined period Ta is two days. The water heating apparatus 1 according to the third embodiment performs the heating determination process only with the electricity rate unit price, so that it is possible to perform simpler control.

  Determination unit 382f of water heating apparatus 1 of the third embodiment adopts the electricity unit price in the time slot where the electricity unit price is the lowest on each day, and the electricity unit price is higher than the first day from the second day onwards. Determine if there is a day. If the determination unit 382f determines that the electricity charge unit price is higher than the first day on the second day or later, the boiling processing unit 382g accelerates to a time zone where the electricity charge unit price is the lowest. Run the operation. According to this, since the advance boiling operation can be performed in the time slot where the electricity unit price is lowest in one day, it is possible to suppress the cost at the time of the forward boiling operation.

Fourth Embodiment
In the fourth embodiment, a modification of the above-described embodiment will be described. For the components in FIG. 15 that are assigned the same reference numerals as in the drawings of the above-described embodiment, the description of the third embodiment can be referred to. The fourth embodiment is different from the above-described embodiment in that the predetermined period Ta is 3 days.

  In the fourth embodiment, the control device 80 performs boiling control by setting Ta for a predetermined period for three days. Hereinafter, in the description of the fourth embodiment, the predetermined period Ta is also simply described as "3 days", the first day of the predetermined period Ta is simply "first day", and the second day of the predetermined period Ta is simply "second day". The third day of the predetermined period Ta is simply referred to as "third day". The control device 80 of the fourth embodiment executes the boiling operation on the day of boiling the calorific value of the first day on the first day. The control device 80 adds the heat of the first day to the heat of the first day and accelerates the heat of the second day by advancing it for two days, and the heat of the first day at the first day In addition to the minutes, the heat content up to the third day is accelerated and boiled for three days, and the boiling operation for three days is performed. The control device 80 executes one of the boiling operation on the day, the forward boiling operation for two days, and the forward boiling operation for three days.

  The processing unit 382 according to the fourth embodiment includes, as functional blocks, a charge determination unit 382a, a determination unit 382f, a boiling processing unit 382g, and a notification unit 382h. The processing unit 382 corresponds to the processing unit 82 in the first embodiment. The determining unit 382f determines whether the electricity bill price R1 is less than the electricity bill price R2. Furthermore, the determination unit 382f determines whether the electricity bill price R1 is less than the electricity bill price R3. The boiling processing unit 382 g executes the forward boiling operation when the determination unit 382 f determines that the electricity charge unit price includes a day higher than the first day in the predetermined period Ta. Specifically, if the determination unit 382f determines that the electricity unit price R1 is less than the electricity unit price R2, the acceleration boiling operation is performed. If the determination unit 382f determines that the electricity charge unit price R1 is not lower than the electricity charge unit price R2, the boiling processing unit 382g executes the heating operation on the same day.

  Next, an example of control executed by the processing unit 382 of the fourth embodiment in FIG. 15 will be described. In step 310 b, the electricity unit prices R 1 and R 2 are acquired, and the process proceeds to step 320. If it is determined in step 320 that the electricity unit price R1 is not lower than the electricity unit price R2, the process of step 330 is performed, and the flowchart is ended. If it is determined in step 320 that the electricity charge unit price R1 is less than the electricity charge unit price R2, the process proceeds to step 321.

  In step 321, it is determined whether the electricity charge unit price R1 is less than the electricity charge unit price R3. If it is not determined at step 321, the process proceeds to step 340a. In step 340a, a two-day advance boiling operation is performed, and the process proceeds to step 345a. In step 345a, the notification unit notifies that the advance boiling operation for two days is being performed, and the flowchart shown in FIG. 15 is ended.

  If it is determined in step 321 that the electricity bill price R1 is less than the electricity bill price R3, then the process proceeds to step 340b. In step 340b, a three-day advance boiling operation is performed, and the process proceeds to step 345b. In step 345b, the notification unit notifies that the advance boiling operation for three days is being performed, and the flowchart is ended.

  Next, the process of FIG. 15 will be described using the specific example shown in FIGS. 16 to 19. FIG. 16 is an example in which the electricity rate unit price on the second and third days is higher than that on the first day. FIG. 17 is an example in which the unit price for electricity on the second day is higher than that on the first day, and the unit price for electricity on the third day is the same as that on the first day. FIG. 18 is an example in which the electricity charge unit price on the second day is lower than that on the first day, and the electricity charge unit price on the third day is higher than that on the first day. FIG. 19 is an example in which the electricity charge unit price on the second day is higher than that on the first day, and the electricity charge unit price on the third day is less than the first day.

  In the example shown in FIG. 16, the electricity charge unit price R1 on the first day is 10 yen / kWh, the electricity charge unit price R2 on the second day is 15 yen / kWh, and the electricity charge unit price R3 on the third day is 15 yen It is / kWh. In step 310 b, the electricity unit prices R 1, R 2 and R 3 are obtained, and the process proceeds to step 320. In step 320, since it is determined that the electricity bill price R1 is less than the electricity bill price R2, the process proceeds to step 321. In step 321, since it is determined that the electricity bill price R1 is less than the electricity bill price R3, the process proceeds to step 340b. In step 340b, a three-day advance boiling operation is performed, and the process proceeds to step 345b. In step 345b, the notification unit 382h reports that the forward boiling operation for three days is being performed, and then the boiling determination processing is ended.

  In the example shown in FIG. 17, the electricity charge unit price R1 on the first day is 10 yen / kWh, the electricity charge unit price R2 on the second day is 15 yen / kWh, and the electricity charge unit price R3 on the third day is 10 yen It is / kWh. In step 310 b, the electricity unit prices R 1, R 2 and R 3 are obtained, and the process proceeds to step 320. In step 320, since it is determined that the electricity bill price R1 is less than the electricity bill price R2, the process proceeds to step 321. In step 321, since it is determined that the electricity bill price R1 is not lower than the electricity bill price R3, the process proceeds to step 340a. In step 340a, a two-day advance boiling operation is performed, and the process proceeds to step 345a. In step 345a, the notification unit 382h notifies that the two-day advance boiling heating operation is being performed, and then the boiling determination processing ends.

  In the example shown in FIG. 18, the electricity charge unit price R1 for the first day is 10 yen / kWh, the electricity charge unit price R2 for the second day is 8 yen / kWh, and the electricity charge unit price R3 for the third day is 20 yen It is / kWh. In step 310 b, the electricity unit prices R 1, R 2 and R 3 are obtained, and the process proceeds to step 320. In step 320, since it is determined that the electricity bill price R1 is not lower than the electricity bill price R2, the process proceeds to step 330. In step 330, after the boiling operation is performed on the day, the heating determination processing is ended.

  In the example shown in FIG. 19, the electricity charge unit price R1 for the first day is 10 yen / kWh, the electricity charge unit price R2 for the second day is 15 yen / kWh, and the electricity charge unit price R3 for the third day is 7 yen It is / kWh. In step 310 b, the electricity unit prices R 1, R 2 and R 3 are obtained, and the process proceeds to step 320. In step 320, since it is determined that the electricity bill price R1 is less than the electricity bill price R2, the process proceeds to step 321. In step 321, since it is determined that the electricity bill price R1 is not lower than the electricity bill price R3, the process proceeds to step 340a. In step 340a, a two-day advance boiling operation is performed, and the process proceeds to step 345a. In step 345a, the notification unit 382h notifies that the two-day advance boiling heating operation is being performed, and then the boiling determination processing ends.

  Next, the effect which the hot-water supply apparatus 1 of 4th Embodiment brings about is demonstrated. The water heating apparatus 1 according to the fourth embodiment includes a boiling device 50 for boiling hot water, a hot water storage tank 10 for storing hot water, and a control device 80 for controlling the boiling device. The control device 80 includes a determination unit 382f that determines whether there is a day on which the unit price of electricity rates is higher than that of the first day after the second day. If the determination unit 382f determines that the electricity price per unit price is higher than the first day on the second day, the control device 80 advances the amount of heat necessary for the second day or later on the first day. It has 382 g of boiling process parts which perform the pre-boiling boiling operation which carries out boiling.

  According to this, the hot water supply apparatus 1 of the fourth embodiment can execute the forward boiling operation when the day after the second day includes a day with a higher electricity unit price than the first day. Therefore, since it becomes possible to avoid performing boiling on the day when the electricity unit price is high, the boiling cost can be suppressed as compared with the case where the boiling operation is performed on each day. Therefore, it becomes possible to control the boiling cost when the electricity unit price differs depending on the day. Furthermore, if the electricity charge unit price on the first day is lower than the electricity charge unit price on the second day and is not lower than the electricity charge unit price on the third day, the water heating apparatus 1 of the fourth embodiment If the unit price on the first day falls below the unit price on the second and third days, the heat quantity up to the third day is accelerated. Therefore, when consecutive days where the electricity unit price is higher than the first day are consecutive, it is possible to perform the accelerated boiling operation for the consecutive days. As a result, it is possible to carry out the forward boiling operation at a lower cost during the forward period. The water heating apparatus 1 according to the fourth embodiment performs the heating determination process only with the electricity rate unit price, and thus can perform simpler control.

Fifth Embodiment
In the fifth embodiment, a modification of the above-described embodiment will be described. The fifth embodiment is different from the above-described embodiment in that the advance period is determined according to the amount of heat that can be stored in the hot water storage tank 10 without setting the predetermined period Ta in advance.

  As shown in FIG. 20, the processing unit 582 according to the fifth embodiment is a functional block including a period determination unit 582b, a charge determination unit 582a, a cost calculation unit 582e, a determination unit 582f, and a boiling processing unit 582g. And a notification unit 582 h. The processing unit 582 corresponds to the processing unit 82 in the first embodiment. The notification unit 582 h corresponds to the notification unit 82 h in the first embodiment.

  The period determination unit 582b acquires the past one week usage results. The period determination unit 582b calculates the forward period Tc that can be advanced when the maximum amount of heat that can be stored in the hot water storage tank 10 is boiled, based on the usage results for the past one week and the capacity of the hot water storage tank 10 Do. Hereinafter, the advance period Tc is also simply described as a period Tc. For example, the period determination unit 582b may calculate the necessary heat amount for performing the forward boiling operation from the use results of the past one week for each case where the number of days to forward is increased for each day, and may store it in the hot water storage tank 10. Let Tc be the number of days of advance corresponding to the maximum required heat quantity that can be Note that the upper limit of the period Tc may be set in advance in consideration of heat loss, shorting due to reheating, and the like.

  The charge determination unit 582a acquires the electricity charge setting information, the calendar information, and the information of the period Tc. The charge determination unit 582a identifies the date of each day of the period Tc based on the calendar information, and determines the electricity charge unit price of each day based on the electricity charge setting information.

  The cost calculation unit 582e acquires the electricity charge unit price and the required heat amount of each day. The cost calculation unit 582e calculates the cost Ce when the boiling operation is performed for each day in the period Tc, and the cost Ct when the accelerated boiling operation for the period Tc is performed on the first day of the period Tc. Do. When there is a time zone in which the electricity unit price is different in one day, the cost calculation unit 582e calculates the cost using the electricity unit price in the time zone in which the electricity unit price is lowest in the day.

  Determination unit 582f determines whether cost Ct is less than cost Ce. In other words, the determination unit 582f determines which of the case where the forward boiling operation is performed and the case where the boiling operation is performed for each day is the lower cost.

  The boiling processing unit 582g executes either the forward boiling operation or the daily boiling operation in the period Tc. If the determination unit 582f determines that the cost Ct is lower than the cost Ce, the boiling processing unit 582g executes the forward boiling operation. If the determination unit 582f determines that the cost Ct is not lower than the cost Ce, the boiling processing unit 582g performs the boiling operation on each day. In other words, the boiling processing unit 582g executes the forward boiling operation when the cost is lower for the forward boiling operation, and the cost is lower if the boiling operation is performed each day. Run the boiling operation every day.

  Next, an example of control executed by the processing unit 582 of the fifth embodiment will be described with reference to FIG. In step 510, the usage record is obtained, and the process proceeds to step 515. In step 515, the period Tc is calculated based on the acquired usage record. Steps 510 and 515 correspond to the period determination unit 582b. When the period Tc is calculated in step 515, the process proceeds to step 520.

  In step 520, it is determined whether the period Tc is less than 2 days. In other words, in step 520, it is determined whether or not the forward heating operation is possible. If it is determined in step 520 that the period Tc is less than 2 days, the process proceeds to step 530 because the forward heating operation can not be performed. In step 530, the required heat quantity for the first day is boiled up, and the flowchart is ended. At this time, the next boiling determination process is performed the next day. By the processing of step 302 and step 303, the necessary heat quantity for the first day can be boiled if the forward heating operation can not be performed.

  If it is determined in step 520 that the forward boiling heating operation is possible, the process proceeds to step 540. In step 540, the unit price of electricity charge for each period in the period Tc is acquired, and the process proceeds to step 545. Step 540 proceeds to the charge determination unit 582a. In step 545, the cost Ct and the cost Ce are calculated, and the process proceeds to step 550. Step 540 corresponds to the cost calculation unit 582e. In step 550, it is determined whether the cost Ct is less than the cost Ce. If the determination at step 550 is negative, the process proceeds to step 560. In step 560, each daily heating operation is performed, and the present flowchart is ended. At this time, the next boiling judgment processing is performed the day after the last day of the period Tc.

  If it is determined in step 550 that the cost Ct is less than the cost Ce, the process proceeds to step 570. In step 570, the forward boiling operation is performed, and the process proceeds to step 575. In step 575, the notification unit notifies that the forward boiling heating operation is being performed, and the flowchart ends. At this time, the next boiling judgment processing is performed the day after the last day of the boiling possible period Tc.

  Next, the effect which the hot-water supply apparatus 1 of 5th Embodiment brings about is demonstrated. The water heater 1 of the fifth embodiment includes an HP device 50 for boiling hot water, a hot water storage tank 10 for storing hot water, and a control device 80 for controlling the HP device 50. The control device 80 adds the amount of heat for one day and the amount of heat for one day after the day of using the amount of heat for one day based on the past heat use record and the amount of heat that can be stored in the hot water storage tank 10 It has period deciding part 582b which determines upswing period Tc which is the days which can be slated forward when performing squeezing operation to squeeze forward and boil up. The control device 80 has a running cost calculation unit 582e. The running cost calculation unit 582e performs the first running cost required when heating the heat required for each day in the advance period, and the heat required for the second and subsequent days of the advance period on the first day of the advance period. The second running cost is calculated when it is brought forward and heated. The control device 80 includes a determination unit 582f that determines whether the second running cost is lower than the first running cost. The control device 80 includes the boiling processing unit 582g that executes the forward boiling heating operation when the determination unit 582f determines that the second running cost is lower than the first running cost.

  According to this, when the required amount of heat Qe is boiled for each day of the advancing period Tc, the water heating apparatus 1 of the fifth embodiment raises the boiling point when the running cost becomes higher than when performing the advancing operation. Upper driving can be performed. Therefore, since it becomes possible to avoid boiling on a day when the electricity bill unit price is higher than the first day of the advance period Tc, it is possible to suppress the boiling cost compared to the case of performing the boiling operation every day Is possible. This makes it possible to suppress the boiling cost when the electricity rate unit price differs depending on the day. Therefore, it becomes possible to control the boiling cost when the electricity unit price differs depending on the day. Since the hot water supply apparatus 1 of the fifth embodiment determines the advancing period Tc from the past usage results and the capacity of the hot water storage tank 10, it is possible to set the advancing period according to the amount of heat used by the user. For example, even when the amount of heat used by the user changes due to a change in season, it is possible to set the advance period Tc according to the change in the amount of heat used.

  The cost calculation unit 582e of the water heating apparatus 1 according to the fifth embodiment calculates the cost Ce in the case where the amount of heat required for each day is boiled to the lowest electricity rate unit price on each day in the advance period Tc. Do. The cost calculation unit 582e calculates the cost Ct in the case where the heat required for the second day or later is brought forward and boiled in the time slot where the electricity bill price on the first day is the lowest. The boiling processing unit 582g executes the accelerated boiling operation during the time zone in which the electricity bill price on the first day is the lowest. According to this, since the advance boiling operation can be performed in the time slot where the electricity unit price is lowest in one day, it is possible to suppress the cost at the time of the forward boiling operation.

(Other embodiments)
The disclosure of this specification is not limited to the illustrated embodiments. The disclosure includes the illustrated embodiments and variations based on them by those skilled in the art. For example, the disclosure is not limited to the combination of parts and elements shown in the embodiments, and can be implemented with various modifications. The disclosure can be implemented in various combinations. The disclosure can have additional parts that can be added to the embodiments. The disclosure includes the parts and components of the embodiments omitted. The disclosure includes replacements of parts, components, or combinations between one embodiment and another embodiment. The disclosed technical scope is not limited to the description of the embodiments. The disclosed technical scope is defined by the description of the claims, and should be understood to include all the modifications within the meaning and scope equivalent to the descriptions of the claims.

  The means and / or function provided by the control device 80 can be provided by software stored in a tangible memory device and a computer that executes the software, only software, only hardware, or a combination thereof. For example, if the controller 80 is provided by an electronic circuit that is hardware, it can be provided by a digital circuit or analog circuit that includes multiple logic circuits.

  In the above-described embodiment, the calendar information and the electricity charge setting information are stored in the storage unit 83, but may be acquired by communicating with an external storage unit. For example, calendar information and electricity charge setting information are stored in a storage device of an energy management system such as HEMS, and the control device 80 communicates with the energy management system to acquire calendar information and electricity charge setting information. It may be configured to store.

  In the above-described embodiment, the storage unit 83 stores electricity unit price information in the form of calendar information and electricity charge setting information, but specific information stored in the storage unit 83 is limited to this. I will not. For example, the storage unit 83 may directly store the information of the electricity unit price of each day.

  In the above embodiment, the processing units 82, 382, and 582 have the charge determination units 82a, 382a, and 582a, but may be configured to obtain the electricity unit price of each day by communicating with the outside.

  In the above-described embodiment, the required heat amount calculation unit 82d calculates the required heat amounts Qe and Qt based on the past use results, but may calculate the required heat amounts without using the past use results. For example, the user may set a target temperature for each day, and the required heat amount calculation unit 82d may be configured to calculate the required heat amounts Qe and Qt from the set target temperature.

  In the above-mentioned embodiment, although predetermined period Ta is 2 days or 3 days, you may set four days or more as predetermined period Ta. For example, if the predetermined period is 4 days, the cost of boiling each day, the cost of boiling for 2 days ahead and boiling for the remaining 2 days each day, and 3 days The cost of the case of boiling for the remaining one day and the cost of the case of boiling for four days in advance are calculated to determine which is the lowest cost.

  In the above-mentioned embodiment, when there is a time zone in which the electricity unit price is different in one day, the heating is performed in the time zone in which the electricity unit price is the lowest. At this time, if it is not possible to boil the hot water for the required amount of heat in the time slot where the electricity bill unit price is the lowest, the heating capacity of the HP device 50 is temporarily increased, and the structure is boiled up to the time slot that the electricity bill unit cost is the lowest It may be

1 ... water heating apparatus 10 ... hot water storage tank 50 ... heat pump apparatus (boiling apparatus)
80 ... controller 82d ... necessary heat amount calculation unit 82e, 582e ... cost calculation unit (running cost calculation unit)
82f, 382f, 582f ... determination unit 82g, 382g, 582g ... heating processing unit 582b ... period determination unit

Claims (9)

A boiling apparatus (50) for boiling hot water using electric power whose electricity unit price is set based on a contract;
A hot water storage tank (10) for storing the hot water;
A control device (80) for controlling the boiling device;
Equipped with
The controller is
A determination unit (382f) that determines whether or not there is a day in which the electricity bill unit price is higher than the first day of the predetermined period after the second day of the predetermined period;
If the determination unit determines that the electricity unit price is higher than the first day after the second day, the heat required for the second day or later is advanced on the first day. Boiling treatment section (382 g) that executes the boiling and boiling up operation.
Hot water supply device having. The determination unit adopts the electricity bill unit price in a time zone in which the electricity bill unit cost is the lowest on each day of the predetermined period,
The determination unit determines whether or not there is a day on which the unit price of electricity bill is higher than that of the first day, after the second day.
The time zone in which the electricity bill unit price is the lowest, when the heating unit determines that the electricity bill unit price is higher than the first day on the second day or later. The hot water supply apparatus according to claim 1, wherein the forward boiling operation is performed. A boiling apparatus (50) for boiling hot water using electric power whose electricity unit price is set based on a contract;
A hot water storage tank (10) for storing the hot water;
A control device (80) for controlling the boiling device;
Equipped with
The controller is
The heat required for each day when boiling is performed in a predetermined period, and the heat required for the second and subsequent days of the predetermined period are accelerated and boiled on the first day of the predetermined period. A required heat amount calculation unit (82d) for calculating the required heat amount at the time of advance when the upper operation is performed;
A running cost calculation unit (82e) for calculating a first running cost for boiling the heat required for each day during the predetermined period and a second running cost for boiling the heat required for the advance on the first day )When,
A determination unit (82f) that determines whether the first running cost is less than the second running cost;
A boiling-up processing unit (82g) that executes the forward boiling boiling operation when the determination unit determines that the first running cost is less than the second running cost;
Hot water supply device having. The controller is
A heat quantity prediction unit (82b) that calculates a predicted heat quantity to be used for each day of the predetermined period based on past heat quantity usage results;
A heat release prediction unit (82c) that calculates a predicted heat release amount predicted to be released from the hot water storage tank;
And have
The hot water supply device according to claim 3, wherein the required heat amount calculation unit calculates the required heat amount for each day and the required heat amount at the time of forward driving based on the predicted use heat amount and the predicted heat release amount. The running cost calculation unit adopts the electricity bill unit price in a time zone in which the electricity bill unit price is the lowest on each day.
The running cost calculation unit is configured to generate the first running cost required to boil the required amount of heat for each day in the time zone in which the electricity bill unit price for the day is the lowest during the predetermined period, and the electricity for the first day Calculating the second running cost required to boil up the heat required at the time of advance operation in the time zone in which the unit price of charge is the lowest;
The hot water supply apparatus according to claim 3 or 4, wherein the boiling processing unit executes the forward boiling heating operation in a time zone in which the electricity bill price on the first day is the lowest. A boiling apparatus (50) for boiling hot water using electric power whose electricity unit price is set based on a contract;
A hot water storage tank (10) for storing the hot water;
A control device (80) for controlling the boiling device;
Equipped with
The controller is
In addition to the heat for one day based on the past heat use record and the heat that can be stored in the hot water storage tank, the heat used for the day after the day to use the heat for the one day is accelerated and boiled A period determination unit (582b) for determining an advance period, which is the number of days that can be advanced, when performing an advance boiling operation to raise
The first running cost required when heating the heat required for each day in the advance period, and the heat required for the second day of the advance period on the first day of the advance period A running cost calculation unit (582e) that calculates a second running cost that is incurred when the cost is raised;
A determination unit (582f) that determines whether the second running cost is less than the first running cost;
A boiling-up processing unit (582 g) that executes the forward boiling operation when the determination unit determines that the second running cost is lower than the first running cost;
Hot water supply device having. The running cost calculation unit is configured to generate the first running cost in the case where the amount of heat required for each day is boiled to a time zone where the electricity unit price of each day is the lowest in the forward moving period, and the first day Calculating the second running cost in the case where the heat required for the second day or later is brought forward and boiled in the time zone in which the unit price of electricity is the lowest;
The hot water supply apparatus according to claim 6, wherein the boiling processing unit executes the forward boiling heating operation in a time zone in which the electricity bill price on the first day is the lowest.   The hot water supply device according to any one of claims 1 to 7, wherein the control device has a storage unit (83) that stores information of the electricity bill unit price.   The control device further includes a notification unit (82h, 382h, 582h) for notifying that the forward boiling operation is being performed when the boiling processing unit performs the forward boiling operation. 9. Hot water supply apparatus according to any one of Items 1 to 8.

Images