WO2019077684A1

WO2019077684A1 - Hot water supply device

Info

Publication number: WO2019077684A1
Application number: PCT/JP2017/037570
Authority: WO
Inventors: 赳弘古谷野
Original assignee: 三菱電機株式会社
Priority date: 2017-10-17
Filing date: 2017-10-17
Publication date: 2019-04-25
Also published as: JP6887518B2; JPWO2019077684A1

Abstract

A hot water supply device comprises a hot water storage tank, a heat exchanger that transfers heat between hot water in the hot water storage tank and hot water in a bathtub, a bathtub circulation route that connects the bathtub and the heat exchanger, a bathtub circulation pump that is provided in the bathtub circulation route, a hot water circulation route that connects the hot water storage tank and the heat exchanger, a tank circulation pump that is provided in the hot water circulation route, and a control device that controls operation of the bathtub circulation pump and the tank circulation pump, wherein the control device has a bathtub heat recovery operation in which the bathtub circulation pump and the tank circulation pump are driven and the heat of the bathtub hot water is recovered to the hot water storage tank, and a bathtub cleaning operation in which the bathtub circulation pump is driven to circulate the bathtub hot water. The control device implements both the bathtub heat recovery operation and the bathtub cleaning operation before the bathtub hot water is drained.

Description

Water heater

The present invention relates to a hot water supply apparatus provided with a hot water storage tank.

In recent years, the hot water supply apparatus has become highly functional, and has not only a function of merely generating hot water but also a function of adjusting a hot water supply temperature to an appropriate temperature and a function of filling a bath with an appropriate amount of water.
In addition, the hot water in the bath can be transported to the water heater using a pump, and heat exchange can be performed with the hot water generated by the hot water system, so that the hot water in the bath can be driven away or the heat can be recovered. Water heaters have also emerged.
As such, Patent Document 1 discloses hot water supply that reduces energy consumption by heat exchange between hot water in a bath and hot water in a hot water storage tank provided in a hot water supply device, and heat recovery is improved to improve system efficiency. An apparatus is disclosed.

Furthermore, there is also a hot water supply device having a function of transporting hot water in a pipe connecting a bathtub and a hot water supply device by a pump, circulating hot water of the bathtub, and cleaning the bathtub.
As such, Patent Document 2 discloses a hot water supply device capable of cleaning the bath by circulating hot and cold water in the bath.

Patent No. 5126432 JP, 2016-48130, A

The techniques described in Patent Document 1 and Patent Document 2 are premised on using a common configuration such as a pump originally provided in the hot water supply apparatus. Therefore, in the techniques described in Patent Document 1 and Patent Document 2, the operations of the common configuration may interfere with each other. That is, in patent document 1, when the operation | movement of a common structure mutually interferes, there existed a problem that the reduction effect of a desired energy consumption was not acquired. Moreover, in patent document 2, when the operation | movement of common structure mutually interferes, there existed a problem that a desired cleaning effect was not acquired.

The present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a hot water supply apparatus designed to optimize the bathtub heat recovery operation and the bathtub cleaning operation.

A water heater according to the present invention comprises a hot water storage tank, a heat exchanger for exchanging heat between hot and cold water in the hot water storage tank and hot and cold water in a bathtub, a bathtub circulation path connecting the bathtub and the heat exchanger, and the bathtub circulation path. The operation of the bathtub circulation pump provided in the tank, the hot water circulation path connecting the hot water storage tank and the heat exchanger, the tank circulation pump provided in the hot water circulation path, the bathtub circulation pump and the tank circulation pump A control device for controlling, the control device driving the bathtub circulation pump and the tank circulation pump, and recovering the heat of the hot and cold water of the bathtub into the hot and cold water of the hot water storage tank; And a bathtub washing operation for driving a bathtub circulation pump and circulating hot water in the bathtub, and before the hot water in the bathtub is drained, the bathtub heat recovery operation and the bathtub washing operation It is intended to implement one.

Since the hot water supply apparatus according to the present invention performs both the bathtub heat recovery operation and the bathtub cleaning operation before the hot and cold water in the bathtub is drained, it is possible to optimize the control of the bathtub heat recovery operation and the bathtub cleaning operation. it can.

It is a schematic block diagram which shows an example of a structure of the hot-water supply apparatus based on embodiment of this invention. It is a block diagram which shows the hardware constitutions of the control apparatus of the hot-water supply apparatus based on embodiment of this invention. It is a functional block diagram which shows the function structure of the control apparatus of the hot-water supply apparatus based on embodiment of this invention. It is a schematic block diagram explaining the bathtub heat recovery driving | operation which the hot-water supply apparatus which concerns on embodiment of this invention performs. It is a schematic block diagram explaining the bathtub washing | cleaning operation which the hot-water supply apparatus which concerns on embodiment of this invention performs. It is a schematic block diagram explaining the reheating operation which the hot-water supply apparatus which concerns on embodiment of this invention performs. It is the flowchart which showed an example of the control flow for performing the bathtub heat recovery operation and the bathtub cleaning operation of the hot-water supply device according to the embodiment of the present invention. It is the flowchart which showed an example of the control flow in the case of giving priority to the bathtub cleaning effect of the hot-water supply apparatus which concerns on embodiment of this invention. It is the flowchart which showed an example of the control flow in case at least one of drainage and rinse of a hot-water supply device concerning an embodiment of the invention is not carried out immediately. It is the flowchart which showed an example of the control flow in the case of giving priority to the reduction effect of the energy consumption of the hot-water supply apparatus which concerns on embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In each of the drawings used in the present embodiment, the same reference numeral is attached to the common element. Further, the present invention is not limited to the embodiments described below, and can be variously modified without departing from the spirit of the present invention. In the present embodiment, "hot water" generally refers to hot water and cold water. Further, the hot and cold water in the bathtub 200 means hot and cold water stored in the bathtub 200, and the hot and cold water in the hot water storage tank 120 means hot and cold water stored in the hot water storage tank 120.

FIG. 1: is a schematic block diagram which shows an example of a structure of the hot-water supply apparatus 100 which concerns on embodiment of this invention. The configuration of the hot water supply apparatus 100 will be described based on FIG. 1. In FIG. 1, the bathtub 200 connected to the hot water supply apparatus 100 is also illustrated.

Hot water supply apparatus 100 supplies hot water at a temperature desired by the user to hot water supply terminal 140. In FIG. 1, as an example of the water heating apparatus 100, a heat pump water heating apparatus for boiling hot and cold water by the heat pump unit 110 is illustrated. The hot water supply terminal 140 is a faucet set in a kitchen or a bathroom or the like, or a shower head or the like. In the present embodiment, the case where the hot water supplying apparatus 100 heats the low temperature water supplied from the water supply end 150 and supplies the hot water to the hot water supply terminal 140 will be described as an example. The hot and cold water generated by the hot water supply apparatus 100 is also used for hot water supply to the bathtub 200.

As shown in FIG. 1, the hot water supply apparatus 100 includes a control device 160, a hot water storage tank 120, and a heat pump unit 110.
Hot water supply apparatus 100 also includes a heat exchanger 133, a bathtub circulation path 130, and a hot water circulation path 180.

Control device 160 centrally controls the overall operation of water heating apparatus 100. Specifically, control device 160 is communicably connected to an external terminal (not shown) such as a hot water supply remote control, and controls the operation of each part of hot water supply apparatus 100 according to the content of the user operation received by the external terminal. Further, control device 160 causes the external terminal to display the operation state of water heating apparatus 100, the operation screen, and the like. Details of the control device 160 will be described later.

The hot water storage tank 120 stores hot and cold water. The hot water storage tank 120 is formed of metal such as stainless steel or resin. A heat insulating material (not shown) is disposed outside the hot water storage tank 120. Thereby, the hot water storage tank 120 can keep the stored hot water warm for a long time.

The hot water storage tank 120 is connected at its lower portion to a water supply pipe 151 communicating with the water supply end 150, and is supplied with low-temperature water from the lower portion. Further, the hot water storage tank 120 is connected by a hot water circulation path 180 communicating with the heat pump unit 110 at the lower part, and is connected with the hot water circulation path 180 communicating with the heat pump unit 110 via the first high temperature water pipe 51 and the second high temperature water pipe 52 at the upper part. Connected As a result, the low-temperature water flowing out of the lower part of the hot water storage tank 120 passes through the heat exchanger in the heat pump unit 110 to become high-temperature hot water and is returned to the upper part of the hot water storage tank 120. Such circulation forms a heating circuit.

The first high-temperature water pipe 51 connects the upper portion of the hot water storage tank 120 and the pipe 55. The pipe 55 is a pipe that connects the second four-way valve 124 and the temperature control unit 60 described later. The pipe 55 constitutes a part of the hot water circulation path 180.
The second high temperature water pipe 52 connects the upper portion of the hot water storage tank 120 and the pipe 56. The pipe 56 is a pipe that connects the second four-way valve 124 and the heat exchanger 133. The pipe 56 constitutes a part of the hot water circulation path 180. Further, the second high temperature water pipe 52 is provided with a check valve 53 which allows the flow of hot and cold water in only one direction.

The heat pump unit 110 is a heat source that heats the low temperature water supplied via the hot water storage tank 120. The heat pump unit 110 includes a heat pump using carbon dioxide or HFC (hydrofluorocarbon) as a refrigerant. That is, the heat pump unit 110 includes a compressor, a first heat exchanger that exchanges heat between the refrigerant and the hot water, an expansion valve, a second heat exchanger that exchanges heat between the outside air and the refrigerant, a blower, and a temperature A sensor, a control board, etc. are provided as a configuration. The compressor, the first heat exchanger, the expansion valve, and the second heat exchanger are annularly connected by piping to form a refrigeration cycle circuit for circulating the refrigerant. The refrigeration cycle circuit is also referred to as a refrigerant circuit.

The bathtub circulation path 130 connects the hot water supply device 100 to the bathtub 200. The bathtub circulation path 130 has a bathtub return pipe 134 and a bathtub forward pipe 135. Further, the bathtub return pipe 134 is provided with a bathtub circulation pump 131 for circulating the hot and cold water of the bathtub 200. Therefore, hot water can be circulated between the hot water supply apparatus 100 and the bathtub 200 by driving the bathtub circulation pump 131. The hot and cold water of the bathtub 200 flows into the hot water supply apparatus 100 via the bathtub return pipe 134. The hot and cold water of the hot water supply apparatus 100 flows into the bathtub 200 through the bathtub forward piping 135.
The bathtub circulation pump 131 may be provided in the bathtub forward pipe 135. Further, the operation of the bathtub circulation pump 131 is controlled by the control device 160.

The bathtub return pipe 134 of the bathtub circulation path 130 is provided with a heat exchanger 133 for exchanging heat between the hot and cold water of the bathtub 200 and the hot and cold water of the hot water storage tank 120.

Hot water supply apparatus 100 connects hot water storage tank 120 with heat pump unit 110 and heat exchanger 133 via hot water circulation path 180. In the hot and cold water circulation path 180, a tank circulation pump 121 for conveying the hot and cold water of the hot water storage tank 120 to the heat pump unit 110 and the heat exchanger 133 is provided. In addition, in the hot water circulation path 180, a three-way valve 122, a first four-way valve 123, and a second four-way valve 124 are provided. Therefore, the flow of hot and cold water can be changed according to the purpose by driving the tank circulation pump 121, switching the three-way valve 122, switching the first four-way valve 123, and switching the second four-way valve 124. Further, a check valve 197 is installed on the outflow side of the heat exchanger 133 of the hot water circulation path 180.

The tank circulation pump 121 may be provided in the hot water circulation path 180, and the installation position is not particularly limited. The operation of the tank circulation pump 121 is controlled by the controller 160.
The three-way valve 122 switches the flow path of hot and cold water, and includes a first port a1, a second port b1, and a third port c1. The first port a1 is connected to the lower portion of the hot water storage tank 120. The second port b1 is connected to the heat pump unit 110. The third port c1 is connected to the heat exchanger 133. Also, the operation of the three-way valve 122 is controlled by the controller 160.

The first four-way valve 123 is for switching the flow path of hot and cold water, and includes a first port a2, a second port b2, a third port c2, and a fourth port d2. The first port a2 is connected to a second port b3 of a second four-way valve 124 described later. The second port b2 is connected to the heat pump unit 110. The third port c2 is connected to the lower portion of the hot water storage tank 120. The fourth port d 2 is connected between the three-way valve 122 and the heat pump unit 110. Further, the operation of the first four-way valve 123 is controlled by the controller 160.

The second four-way valve 124 switches the flow path of hot and cold water, and includes a first port a3, a second port b3, a third port c3, and a fourth port d3. The first port a3 is connected to the heat exchanger 133. The second port b 3 is connected to the first port a 2 of the first four-way valve 123. The third port c3 is connected to the side center of the hot water storage tank 120. The fourth port d 3 is connected to the upper portion of the hot water storage tank 120 and the hot water supply terminal 140. Also, the operation of the second four-way valve 124 is controlled by the controller 160.

The temperature control unit 60 constitutes a part of the hot water circulation path 180, and mixes hot water of the hot water storage tank 120 with city water, that is, low temperature hot water supplied from the water supply end 150, Adjust the temperature of the The temperature control unit 60 also adjusts the temperature of hot and cold water supplied to the hot water supply terminal 140 and the bathtub 200.
The temperature control unit 60 includes a check valve 61, a check valve 62, a three-way valve 63, a three-way valve 64, a three-way valve 65, and a two-way valve 66.

The check valve 61 is provided in the pipe 55 and allows the flow of hot and cold water only from the side of the hot water storage tank 120 in the direction of the temperature control unit 60. The pipe 55 is branched into a pipe 31 and a pipe 32 downstream of the check valve 61.
The three-way valve 63 is connected to the pipe 31 and the pipe 140A connected to the hot water supply terminal 140, and switches the flow of hot and cold water.
The three-way valve 64 is connected to a pipe 150A connected to the pipe 32 and the water supply end 150, and switches the flow of hot and cold water.

The three-way valve 65 is connected to the pipe 140A and the pipe 33, and switches the flow of hot and cold water.
The check valve 62 is provided in the pipe 33 and allows the flow of hot and cold water only in the direction of the three-way valve 63 or the three-way valve 64 from the three-way valve 65 side. The pipe 33 is connected to the pipe 31 and the pipe 32 at the downstream side of the check valve 62.
The two-way valve 66 is provided between the three-way valve 64 and the bath 200, and is controlled to open and close so that the hot and cold water from the temperature control unit 60 is not supplied to the bath 200 or not.

Tank circulation pump 121 and bathtub circulation pump 131 are provided with an inverter circuit, and the flow rate at the time of transporting hot and cold water can be changed by changing the driving rotational speed according to the control value instructed from control device 160. it can.

The configuration of hot water supply apparatus 100 has been schematically described above. Hereinafter, the configuration of control device 160 of water heating apparatus 100 will be described in detail. FIG. 2 is a block diagram showing a hardware configuration of control device 160 of water heating apparatus 100.

As shown in FIG. 2, the control device 160 includes a CPU 161, a communication interface 162, a ROM 163, a RAM 164, and a secondary storage device 165. The CPU 161, the communication interface 162, the ROM 163, the RAM 164, and the secondary storage device 165 are mutually connected via the bus 166. The CPU is a Central Processing Unit. The ROM is a read only memory. The RAM is a Random Access Memory.

The CPU 161 centrally controls the control device 160. Details of the functions implemented by the CPU 161 will be described later.
The communication interface 162 is configured to include a NIC for performing wired communication or wireless communication. The communication interface 162 is communicably connected to the control board and driver of the external terminal. Further, the communication interface 162 is communicably connected to the control substrate and the drive device of the heat pump unit 110. The driving device is a device that includes a motor, a gear, and the like, and drives the tank circulation pump 121, the bathtub circulation pump 131, and the like. The NIC is a Network Interface Card controller.

Control device 160 receives a user operation from an external terminal via communication interface 162, and causes the external terminal to display at least one of the operating state and the operation screen of water heating apparatus 100 via communication interface 162. Further, the control device 160 transmits a control signal to the control substrate of the heat pump unit 110 to control a compressor, an expansion valve, a blower, etc. or transmits a control signal to a drive device to transmit a tank circulation pump 121 and a bathtub. It controls the circulation pump 131 and the like.

The ROM 163 stores a plurality of firmware, data used when executing the plurality of firmware, and the like.
The RAM 164 is used as a work area of the CPU 161.

The secondary storage device 165 is composed of a readable / writable non-volatile semiconductor memory such as an EEPROM or a flash memory, or a hard disk drive. The secondary storage device 165 stores programs for controlling the operation of the hot water supply apparatus 100, data used when executing these programs, and the like. The data used at the time of execution of the program includes data indicating the operation mode of the hot water supply apparatus 100 and control of the tank circulation pump 121 and the bathtub circulation pump 131 corresponding to the operation mode.
The EEPROM is Electrically Erasable Programmable Read-Only Memory.

FIG. 3 is a functional block diagram showing a functional configuration of control device 160 of water heating apparatus 100.
As shown in FIG. 3, the control device 160 functionally includes a user interface unit 167, an apparatus state acquisition unit 168, an apparatus control unit 169, and an operation mode execution unit 170. Each function unit of the user interface unit 167, the device state acquisition unit 168, the device control unit 169, and the operation mode execution unit 170 executes one or more programs stored in the secondary storage device 165 by the CPU 161. Is realized by

The user interface unit 167 performs user interface processing via an external terminal. That is, the user interface unit 167 receives a user operation via the external terminal. Further, the user interface unit 167 transmits information to be presented to the user to the external terminal, and causes the external terminal to display the information. The user interface unit 167 also functions as a reception unit and a specification reception unit. Moreover, the information etc. which show the driving | running state of the hot-water supply apparatus 100 are contained as information for showing a user.

The device state acquiring unit 168 acquires data such as the operating state and the measured temperature from the heat pump unit 110 at predetermined time intervals, such as 30 seconds, and acquires data indicating the driving state of the circulation pump or the like from the drive device. The circulation pumps are the tank circulation pump 121 and the bathtub circulation pump 131.

Device control unit 169 controls the overall operation of water heating apparatus 100 according to a user operation via an external terminal.

The operation mode execution unit 170 reads out the control of the heat pump unit 110 and the circulation pump corresponding to the operation mode selected by the user operation via the external terminal from the secondary storage device 165, and sends the read out control to the device control unit 169. Run it.

<The bathtub heat recovery operation of water heating apparatus 100>
Next, the operation of the hot water supply apparatus 100 will be described. FIG. 4: is a schematic block diagram explaining the bathtub heat recovery operation | movement which the hot-water supply apparatus 100 performs. A bathtub heat recovery operation performed by the water heating apparatus 100 will be described based on FIG. 4. In FIG. 4, the flow of hot and cold water is indicated by thick arrows.

During the bathtub heat recovery operation, the bathtub circulation pump 131, the tank circulation pump 121, the three-way valve 122, the first four-way valve 123, and the second four-way valve 124 are controlled as follows.
The bathtub circulation pump 131 is driven at a preset rotational speed. The tank circulation pump 121 is driven at a preset rotational speed. The three-way valve 122 is controlled such that hot water flows from the first port a1 to the second port b1. The first four-way valve 123 is controlled such that hot and cold water flows from the fourth port d2 to the first port a2. The second four-way valve 124 is controlled such that hot water flows from the second port b3 to the first port a3. That is, the three-way valve 122, the first four-way valve 123, and the second four-way valve 124 are switched to connect the lower portion of the hot water storage tank 120 and the heat exchanger 133.

First, the flow of hot and cold water in the bathtub circulation path 130 will be described.
It is assumed that hot water is stored in the tub 200. By driving the bathtub circulation pump 131, hot water circulates in the bathtub circulation path 130. When the bathtub circulation pump 131 is driven, the hot and cold water of the bathtub 200 flows out of the bathtub 200 through the bathtub return pipe 134. The hot and cold water flowing out of the bath 200 is pressurized by the bath circulation pump 131 and sent to the heat exchanger 133. In the heat exchanger 133, heat is exchanged between the hot water flowing through the hot water circulation path 180 and the hot water flowing through the bath circulation path 130. The heat-exchanged water then returns to the bathtub 200 again via the bathtub forward piping 135.

Next, the flow of hot and cold water in the hot and cold water circulation path 180 will be described.
By driving the tank circulation pump 121, the hot water circulates in the hot water circulation path 180. When the tank circulation pump 121 is driven, the hot and cold water of the hot water storage tank 120 flows out from the lower part of the hot water storage tank 120. Hot and cold water flowing out of the hot water storage tank 120 is boosted by the tank circulation pump 121 via the three-way valve 122. The hot and cold water pressurized by the tank circulation pump 121 then travels through the first four-way valve 123 and the second four-way valve 124 and is sent to the heat exchanger 133. In the heat exchanger 133, heat is exchanged between the hot water flowing through the hot water circulation path 180 and the hot water flowing through the bath circulation path 130. The heat-exchanged hot and cold water then passes through the check valve 197 and returns to the middle stage of the hot water storage tank 120.

When the three-way valve 122, the first four-way valve 123, and the second four-way valve 124 are open in one particular direction, they are not open in the other direction.
Further, a check valve 197 is installed on the outflow side of the heat exchanger 133 of the hot water / water circulation path 180 to prevent backflow of hot water to the heat exchanger 133.

As described above, by circulating the hot water, the heat exchanger 133 exchanges heat between the hot water of the bath 200 and the hot water of the hot water storage tank 120. Therefore, when the temperature of the hot and cold water of the bathtub 200 is higher than the temperature of the hot and cold water stored in the lower part of the hot water storage tank 120, the heat of the hot and cold water of the bathtub 200 can be recovered to the hot water of the hot water storage tank 120.

<Tub cleaning operation of water heater 100>
FIG. 5: is a schematic block diagram explaining the bathtub cleaning operation which the hot-water supply apparatus 100 performs. The bathtub cleaning operation performed by the hot water supply apparatus 100 will be described based on FIG. 5. In FIG. 5, the flow of hot and cold water is indicated by thick arrows.

During the bathtub cleaning operation, the bathtub circulation pump 131, the tank circulation pump 121, the three-way valve 122, the first four-way valve 123, and the second four-way valve 124 are controlled as follows.
The bathtub circulation pump 131 is driven at a preset rotational speed. The tank circulation pump 121 is stopped. That is, hot water does not circulate in the hot water circulation path 180 during the bathtub cleaning operation.

It is assumed that hot water is stored in the tub 200. By driving the bathtub circulation pump 131, hot water circulates in the bathtub circulation path 130. When the bathtub circulation pump 131 is driven, the hot and cold water of the bathtub 200 flows out of the bathtub 200 through the bathtub return pipe 134. The hot and cold water flowing out of the bath 200 is pressurized by the bath circulation pump 131 and sent to the heat exchanger 133. The hot and cold water sent to the heat exchanger 133 is returned to the hot tub 200 again via the hot tub passing pipe 135 without heat exchange with hot water flowing through the hot water circulation path 180.

By so doing, the hot and cold water of the bathtub 200 can be circulated to the bathtub circulation path 130. Here, when at least one of a bubble and an additive that enhances the cleaning effect is added to the hot and cold water of the bath 200, the cleaning liquid having the cleaning effect can be circulated in the bath 200 together with the hot and cold water. In this way, the cleaning effect of the bathtub 200 is enhanced. However, when the cleaning liquid is left in the bath 200 after the bath cleaning operation is finished, there is a possibility that the stains removed from the bath 200 may adhere to the bath 200 again. If the bathtub 200 does not have a special function such as automatic drainage or automatic rinsing, it is preferable that the user perform drainage and / or rinsing immediately after the completion of washing, in order to enhance the cleaning effect.

Bubbles and additives, including additives, shall be referred to as additives.
In addition, the additive may be filled in advance in the hot water supply apparatus 100, and the additive may be added if necessary. Alternatively, the additive may be introduced each time by the user.
In addition, when calling it "drainage", at least one of drainage and a rinse shall be included.

The control method of the bathtub heat recovery operation and the bathtub cleaning operation differs depending on whether the user using the hot water supply apparatus 100 prioritizes suppression of consumed energy or priority to cleansing. Hereinafter, control methods of the bathtub heat recovery operation and the bathtub cleaning operation will be described.
In the following description, when priority is given to reducing energy consumption, it may be referred to as priority when reducing the energy consumption. Moreover, the case where priority is given to washing may be referred to as the case where priority is given to the washing effect of the bathtub 200.

<Control method when priority is given to energy consumption suppression>
First, a control method in the case of prioritizing energy consumption suppression will be described.
In order to realize a high reduction effect of energy consumption, it is necessary to suppress the power consumption of the hot water supply apparatus 100. If a large amount of heat can be recovered from the hot and cold water of the bathtub 200 in the bathtub heat recovery operation, the amount of boiling of the hot and cold water in the hot and cold water circulation path 180 can be reduced.

The amount of heat recovery during the bathtub heat recovery operation increases as the temperature of the bath 200 increases. The temperature of the bath 200 is generally higher than the ambient temperature. Therefore, by leaving the hot water in the bath 200 for a long time, the temperature of the hot water will decrease with the passage of time. Therefore, if the bathtub heat recovery operation is performed without leaving the hot and cold water of the bathtub 200 for a long time, a high reduction effect of consumed energy can be expected.

Moreover, the temperature of the hot and cold water of the bathtub 200 will fall by implementing a bathtub heat recovery driving | operation. Furthermore, as described above, the temperature of the hot and cold water of the bathtub 200 is also lowered by leaving the hot and cold water of the bathtub 200 for a long time. When the temperature of the hot and cold water of the bathtub 200 is lower than the temperature of the hot and cold water of the hot water storage tank 120, when the bathtub heat recovery operation is continued, the heat storage amount in the hot water storage tank 120 decreases and the boiling amount increases. Therefore, the power consumption of water heating apparatus 100 is increased. Therefore, when the temperature of the hot and cold water of the bathtub 200 is lower than the temperature of the hot and cold water of the hot water storage tank 120, the process of reducing the consumption energy is more effective if the bath heat recovery operation is ended.

When the bath cleaning operation is performed, although the additive is added to the hot water of the bath 200, the function of the heat exchanger 133 at the time of the bathtub heat recovery operation may be reduced and the heat recovery amount may be reduced due to the nature of the additive. In this case, if the additive is not added to the bathtub 200 during the bathtub heat recovery operation, the operation to reduce the consumed energy is more effective. That is, in this case, the effect of reducing energy consumption can be enhanced by not simultaneously performing the bathtub heat recovery operation and the bathtub cleaning operation.

Further, as a method of enhancing the reduction effect of the consumed energy of the hot water supply apparatus 100, there is a method of reducing the driving time of the bathtub circulation pump 131 and reducing the power consumption. Both the bathtub heat recovery operation and the bathtub cleaning operation require the operation of the bathtub circulation pump 131. Therefore, by simultaneously performing the bathtub heat recovery operation and the bathtub cleaning operation, the driving time of the bathtub circulation pump 131 can be shortened, the power consumption can be suppressed, and the reduction effect of the energy consumption can be enhanced.

In addition, when the additive required for the bathtub cleaning operation has a surfactant effect, the flow path resistance of the bathtub circulation path 130 is reduced, and the power consumption of the bathtub circulation pump 131 can be suppressed at the same circulation flow rate. Thereby, the reduction effect of energy consumption can be heightened compared with the case where a bathtub heat recovery operation is implemented independently.

<Control method when priority is given to cleaning>
Next, a control method in the case where priority is given to cleaning will be described.
When the bathtub cleaning operation is performed, the higher the temperature of the bath 200, the higher the cleaning effect. Therefore, when performing the bathtub cleaning operation, the hot water of the bathtub 200 is raised in temperature using the hot water stored in the hot water storage tank 120 once in the reheating operation. By performing the bathtub cleaning operation after the reheating operation, the temperature of the hot and cold water of the bathtub 200 can be raised, and the cleaning effect can be enhanced. The reheating operation will be described below with reference to FIG.

Further, as a method of enhancing the cleaning effect, there is a method of draining the cleaning liquid immediately after the bath cleaning operation in order to prevent the re-adhesion of the dirt. However, drainage is left to the user's execution timing when the bathtub 200 does not have a special function such as automatic drainage or automatic rinsing. Therefore, if the user's habit is to execute drainage after a long period of time since the last bath use, such as the evening after the day of bath use, the tub cleaning operation may be postponed to that point. By doing this, drainage is performed immediately after the bathtub cleaning operation, and the cleaning effect can be enhanced.

FIG. 6 is a schematic configuration view illustrating the reheating operation performed by the hot water supply apparatus 100. The reheating operation performed by the hot water supply apparatus 100 will be described based on FIG. In FIG. 6, the flow of hot and cold water is indicated by thick arrows.

During the reheating operation, the bathtub circulation pump 131, the tank circulation pump 121, the three-way valve 122, the first four-way valve 123, and the second four-way valve 124 are controlled as follows.
The bathtub circulation pump 131 is driven at a preset rotational speed. The tank circulation pump 121 is driven at a preset rotational speed. The first four-way valve 123 is controlled such that hot and cold water flows from the fourth port d2 to the third port c2. That is, the first four-way valve 123 is switched to connect the lower portion of the hot water storage tank 120 and the heat exchanger 133. The second four-way valve 124 is controlled such that hot and cold water flows from the fourth port d3 to the first port a3. That is, the second four-way valve 124 is switched to connect the upper portion of the hot water storage tank 120 and the heat exchanger 133.

First, the flow of hot and cold water in the bathtub circulation path 130 will be described.
It is assumed that hot water is stored in the tub 200. By driving the bathtub circulation pump 131, hot water circulates in the bathtub circulation path 130. When the bathtub circulation pump 131 is driven, the hot and cold water of the bathtub 200 flows out of the bathtub 200 through the bathtub return pipe 134. The hot and cold water flowing out of the bath 200 is pressurized by the bath circulation pump 131 and sent to the heat exchanger 133. In the heat exchanger 133, heat is exchanged between the hot water flowing through the hot water circulation path 180 and the hot water flowing through the bath circulation path 130. At this time, the hot and cold water flowing through the bathtub circulation path 130 is heated. The heated water then returns to the bathtub 200 again via the bathtub forward piping 135.

Next, the flow of hot and cold water in the hot and cold water circulation path 180 will be described.
By driving the tank circulation pump 121, the hot water circulates in the hot water circulation path 180. When the tank circulation pump 121 is driven, the hot and cold water of the hot water storage tank 120 flows out from the top of the hot water storage tank 120. Hot and cold water flowing out of the upper portion of the hot water storage tank 120 is sent to the heat exchanger 133 via the second four-way valve 124. In the heat exchanger 133, heat is exchanged between the hot water flowing through the hot water circulation path 180 and the hot water flowing through the bath circulation path 130. The heat-exchanged hot and cold water then passes through the check valve 197 and returns to the middle stage of the hot water storage tank 120.

When the three-way valve 122, the first four-way valve 123, and the second four-way valve 124 are open in one particular direction, they are not open in the other direction.

<Control judgment flow>
Based on the above contents, a control flow for implementing the bathtub heat recovery operation and the bathtub cleaning operation according to the user's needs will be described using flowcharts shown in FIGS. 7 to 10. FIG. 7 is a flow chart showing an example of a control flow for performing a bathtub heat recovery operation and a bathtub cleaning operation of the hot water supply apparatus 100. FIG. 8 is a flow chart showing an example of a control flow in the case where priority is given to the bathtub cleaning effect of water heating apparatus 100. FIG. 9 is a flow chart showing an example of a control flow when at least one of drainage and rinsing of water heating apparatus 100 is not performed immediately. FIG. 10 is a flow chart showing an example of a control flow in the case where priority is given to the reduction effect of the consumed energy of the hot water supply apparatus 100. The control flow shown in FIGS. 7 to 10 is executed by the control device 160.

First, the control flow will be described with reference to FIG. The present control starts from step S001. The start timing is assumed to be when the user enters a bathtub heat recovery execution request from the external terminal or when a predetermined time has come.

Thereafter, the process proceeds to step S002, and if the bathtub cleaning operation is currently performed, it is determined whether drainage can be performed in a short time, for example, 30 minutes to 1 hour.
It is assumed that the time of drainage, which is the basis of the determination, is previously input by the user from the external terminal.
Note that the control device 160 may learn the time of drainage from the past use results.

If drainage is to be performed immediately, the process proceeds to step S 003, where it is determined whether the user gives priority to reducing the energy consumption of the hot water supply apparatus 100 or gives priority to bath cleaning. Note that the user inputs that priority is given to either the reduction of energy consumption or the bathtub cleaning via an external terminal (not shown) such as a hot water supply remote control.

In addition, the case where drainage is not immediately implemented in step S002 will be described later.

If the user gives priority to the reduction effect of the consumed energy of the hot water supply apparatus 100, the process proceeds to step S004. In step S 004, it is determined whether the additive used for the bathtub cleaning operation reduces the heat transfer performance of the heat exchanger 133.
If it is determined in step S 004 that the heat transfer performance is to be reduced, the process proceeds to step S 007 and step S 008 without adding the additive, and the bathtub circulation pump 131 and the tank circulation pump 121 are driven.
The flow of the hot and cold water in the hot and cold water circulation path 180 at this time is the same as the bathtub heat recovery operation shown in FIG. 4. Thereby, highly efficient heat recovery operation can be performed without reducing the heat transfer performance of the heat exchanger 133.

A case where the user gives priority to the bathtub cleaning effect in step S003 will be described later.

If it is determined in step S 004 that the heat transfer performance is not to be reduced, the process proceeds to step S 005, where it is determined whether the pump input can be suppressed by adding the additive.
If it is determined in step S005 that the pump input can be suppressed, the process proceeds to step S006, and the additive is introduced. Thereafter, the process proceeds to step S 007 and step S 008 to drive the bathtub circulation pump 131 and the tank circulation pump 121.

The flow of the hot and cold water in the hot and cold water circulation path 180 at this time is the same as the bathtub heat recovery operation shown in FIG. 4. Thereby, a pump input can be suppressed and highly efficient heat recovery operation can be implemented. In addition, since the bathtub circulation pump 131 is driven with the additive added, the bathtub heat recovery operation and the bathtub cleaning operation can be performed simultaneously, and the bathtub circulation pump 131 is driven compared to the case where both operations are performed separately. Time can be reduced. As a result, the reduction effect of energy consumption will increase.

If it is determined in step S005 that there is no effect of suppressing the pump input, the process proceeds to step S007 and step S008 without adding the additive, and the bathtub circulation pump 131 and the tank circulation pump 121 are driven.
The flow of the hot and cold water in the hot and cold water circulation path 180 at this time is the same as the bathtub heat recovery operation shown in FIG. 4.

In step S 009, the temperature of the hot water of the bathtub 200 and the temperature of the hot water of the hot water storage tank 120 are compared.
When the temperature of the hot and cold water of the bathtub 200 is higher than the temperature of the hot and cold water of the hot water storage tank 120, the operation of the bathtub circulation pump 131 and the tank circulation pump 121 is continued because the amount of heat that can be recovered to the bathtub 200 still remains.
When the temperature of the hot water of the hot water storage tank 120 becomes higher than the temperature of the hot water of the bathtub 200, the process proceeds to step S010, the tank circulation pump 121 is stopped, and the bathtub heat recovery operation is ended.
Therefore, the control of the bathtub heat recovery operation and the bathtub cleaning operation can be optimized without using a special device or the like.

In step S011, it is determined whether the additive has already been added to the bathtub 200.
If it is determined that the additive has been added, sufficient cleaning has been performed by driving the bathtub circulation pump 131 so far, and the bathtub circulation pump 131 is stopped in step S035, and the bathtub cleaning operation is ended. .
If it is determined that the additive has not been added yet, the additive is added in step S012, and the bathtub circulation pump 131 is driven for a predetermined time in step S013, and the bathtub cleaning operation is performed. Thereafter, the bathtub circulation pump 131 is stopped in step S035, and the bathtub cleaning operation is ended.

After the bathtub cleaning operation is finished, the process proceeds to step S041, and drainage is performed.
Thereafter, in step S042, a series of flows are completed.

Next, a control flow in the case where the user does not prioritize the reduction effect of consumed energy, that is, prioritizes the bathtub cleaning effect in step S003 illustrated in FIG. 7 will be described using FIG. 8.

If the user prioritizes the bathtub cleaning effect, the process proceeds from step S003 to step S014, where the additive is introduced into the bathtub 200. Thereafter, the process proceeds to step S015, step S016, the bathtub circulation pump 131 is driven, and the bathtub cleaning operation is performed. At this time, the tank circulation pump 121 is not driven. Therefore, heat is not recovered from the hot water stored in the bathtub 200 to the hot water of the hot water storage tank 120, and the bathtub cleaning operation may be performed while maintaining the temperature of the hot and cold water circulating in the bathtub circulation path 130 high. it can. This will enhance the bath cleaning effect.

After driving the bathtub circulation pump 131 for a predetermined time in step S016, the tank circulation pump 121 is driven in step S017 to carry out a bathtub heat recovery operation. The flow of the hot and cold water in the hot and cold water circulation path 180 at this time is the same as the bathtub heat recovery operation shown in FIG. 4.

In step S018, the temperature of the hot water of the bathtub 200 and the temperature of the hot water of the hot water storage tank 120 are compared.
When the temperature of the hot and cold water of the bathtub 200 is higher than the temperature of the hot and cold water of the hot water storage tank 120, the operation of the bathtub circulation pump 131 and the tank circulation pump 121 is continued because the amount of heat that can be recovered to the bathtub 200 still remains.
When the temperature of the hot water of the hot water storage tank 120 becomes higher than the temperature of the hot water of the bathtub 200, the process proceeds to step S019 and step S035, the tank circulation pump 121 and the bathtub circulation pump 131 are stopped, and the bathtub heat recovery operation and the bathtub cleaning operation Finish.

After the end of the bathtub heat recovery operation and the bathtub cleaning operation, the process proceeds to step S041, and drainage is performed.
Thereafter, in step S042, a series of flows are completed.

Next, a control flow in the case where drainage is not immediately implemented in step S002 shown in FIG. 7 will be described using FIG.

If drainage is not performed immediately, the process proceeds from step S002 to step S020, where it is determined whether the additive used for the bathtub cleaning operation reduces the heat transfer performance of the heat exchanger 133.
If it is determined in step S020 that the heat transfer performance is to be reduced, the process proceeds to step S023 and step S024 without adding the additive, and the bathtub circulation pump 131 and the tank circulation pump 121 are driven.
The flow of the hot and cold water in the hot and cold water circulation path 180 at this time is the same as the bathtub heat recovery operation shown in FIG. 4. Thereby, highly efficient heat recovery operation can be performed without reducing the heat transfer performance of the heat exchanger 133.

If it is determined in step S020 that the heat transfer performance is not to be reduced, the process proceeds to step S021, where it is determined whether the pump input can be suppressed by adding the additive.
If it is determined in step S021 that the pump input can be suppressed, the process proceeds to step S022, and the additive is introduced. Thereafter, the process proceeds to step S 023 and step S 024 to drive the bathtub circulation pump 131 and the tank circulation pump 121.

If it is determined in step S021 that there is no effect of suppressing the pump input, the process proceeds to step S023 and step S024 without adding the additive, and the bathtub circulation pump 131 and the tank circulation pump 121 are driven.
The flow of the hot and cold water in the hot and cold water circulation path 180 at this time is the same as the bathtub heat recovery operation shown in FIG. 4.

In step S025, the temperature of the hot water of the bathtub 200 and the temperature of the hot water of the hot water storage tank 120 are compared.
When the temperature of the hot and cold water of the bathtub 200 is higher than the temperature of the hot and cold water of the hot water storage tank 120, the operation of the bathtub circulation pump 131 and the tank circulation pump 121 is continued because the amount of heat that can be recovered to the bathtub 200 still remains.
When the temperature of the hot water of the hot water storage tank 120 becomes higher than the temperature of the hot water of the bathtub 200, the process proceeds to step S026, the tank circulation pump 121 is stopped, and the bathtub heat recovery operation is ended.

After the bathtub cleaning operation is finished, the process proceeds to step S027, and it is determined whether the user prioritizes the reduction effect of the consumed energy of the hot water supply apparatus 100 or prioritizes the bathtub cleaning effect. If the user does not prioritize the reduction effect of consumed energy, that is, prioritizes the bathtub cleaning effect, the process proceeds to step S 028 and step S 029 to stop the bathtub circulation pump 131 and wait until drainage is performed.

A case where the user gives priority to the reduction effect of energy consumption in step S027 will be described later.

After waiting at step S029, the process proceeds to step S030 and step S031, and the bathtub circulation pump 131 and the tank circulation pump 121 are driven to carry out the reheating operation.
The flow of the hot and cold water in the hot and cold water circulation path 180 at this time is similar to the reheating operation shown in FIG. Thereby, the temperature of the hot and cold water of the bathtub 200 rises again, and the bathtub cleaning can be performed at a temperature suitable for the bathtub cleaning.
In addition, since the hot water storage tank 120 is kept warm by the heat insulating material, heat is once recovered to the hot water of the hot water storage tank 120 rather than leaving hot water in the bath 200 for a long time. By supplying the heat, the amount of heat radiation can be suppressed.

In step S 032, it is determined whether the additive has already been added to the bathtub 200.
If it is determined that the additive has been added, sufficient cleaning has been performed by driving the bathtub circulation pump 131 so far, and the bathtub circulation pump 131 is stopped in step S035, and the bathtub cleaning operation is ended. .
If it is determined that the additive has not been added yet, the additive is added in step S033, and the bathtub circulation pump 131 is driven for a predetermined time in step S034 to carry out a bathtub cleaning operation. Thereafter, the bathtub circulation pump 131 is stopped in step S035, and the bathtub cleaning operation is ended.

Finally, the control flow in the case where the user gives priority to the reduction effect of energy consumption in step S027 shown in FIG. 9 will be described using FIG.

When the user gives priority to the reduction effect of the consumed energy of the hot water supply apparatus 100, it is determined in step S036 whether the additive has already been added to the bathtub 200.
If it is determined that the additive has been added, it is determined that sufficient cleaning has been performed by the driving of the bathtub circulation pump 131 so far, the bathtub circulation pump 131 is stopped in step S039, and the bathtub cleaning operation is ended. .
If it is determined that the additive has not been added yet, the additive is added in step S037, and the bathtub circulation pump 131 is driven for a predetermined time in step S038 to carry out a bathtub cleaning operation. Thereafter, the bathtub circulation pump 131 is stopped in step S039, and the bathtub cleaning operation is ended.

In step S040, the process waits until the time when drainage is performed.
After waiting in step S041, drainage is carried out.
Thereafter, in step S042, a series of flows are completed.

As described above, according to the control flow shown in FIGS. 7 to 10, the bathtub heat recovery operation and the bathtub cleaning operation can be performed according to the user's request.

As described above, since the hot water supply apparatus 100 performs both the bathtub heat recovery operation and the bathtub cleaning operation before the hot and cold water of the bathtub 200 is drained, the control of the bathtub heat recovery operation and the bathtub cleaning operation is optimized. It becomes possible.

The hot water supply apparatus 100 changes the driving order of the bathtub circulation pump 131 and the tank circulation pump 121 by selecting the case where the control device 160 gives priority to suppression of consumed energy or gives priority to washing. Therefore, according to the hot water supply apparatus 100, the operation which gives priority to suppression of the consumption energy which a user requests | requires or the operation which gives priority to cleaning can be implemented.

When the control device 160 selects the case where priority is given to suppressing consumption energy, the hot water supply apparatus 100 performs a bathtub heat recovery operation, and then stops the tank circulation pump 121 and drives the bathtub circulation pump 131. continue. Therefore, according to the hot water supply apparatus 100, the suppression operation of the consumption energy according to a user's request can be implemented.

When the control device 160 is selected to prioritize cleaning, the hot water supply apparatus 100 performs the bathtub cleaning operation, and then drives the tank circulation pump 121 to perform the bathtub heat recovery operation, and then the tank The circulation pump 121 and the bathtub circulation pump 131 are stopped. Therefore, according to the hot water supply apparatus 100, the operation which prioritized the cleaning according to the user's request can be performed.

Hot water supply apparatus 100 performs the reheating operation when control device 160 performs the bathtub heat recovery operation before the hot and cold water of bathtub 200 is drained and the case where priority is given to cleaning thereafter, and then performs the reheating operation, and thereafter , Conduct a bathtub cleaning operation. Therefore, according to the hot water supply apparatus 100, the bathtub cleaning can be performed at a temperature suitable for the bathtub cleaning.

The water heater 100 performs the bathtub heat recovery operation after the control device 160 stops the bathtub cleaning operation, and then performs the bathtub cleaning operation again. Therefore, according to the hot water supply apparatus 100, the heat release amount can be suppressed by recovering the heat of the hot and cold water of the bath tub 200 once into the hot and cold water of the hot water storage tank 120 and supplying the heat to the hot and cold water of the bath tub 200 thereafter.

In the water heating apparatus 100, the control device 160 stops the tank circulation pump 121 and the bathtub circulation pump 131 before performing the refueling operation, and then drives the tank circulation pump 121 and the bathtub circulation pump 131 again. Carry out driving. Therefore, according to the hot water supply apparatus 100, the consumption of energy can be reduced without driving the tank circulation pump 121 and the bathtub circulation pump 131 before the reheating operation.

In the water heating apparatus 100, the control device 160 determines the stop of the tank circulation pump 121 based on the differential temperature between the temperature of the hot water of the hot water storage tank 120 and the temperature of the hot water of the bathtub 200. Therefore, according to the hot water supply apparatus 100, it is possible to optimize control of the bathtub heat recovery operation and the bathtub cleaning operation without using a special device.

Since the water heating apparatus 100 is charged with the additive before performing the bathtub cleaning operation, it is possible to enhance the cleaning effect in the bathtub cleaning operation.

Although the embodiment of the present invention has been described, the present invention is not limited to the contents described in the embodiment, and various modifications and applications are possible without departing from the scope of the present invention. In the above embodiment, although the case where the water heating apparatus 100 is a heat pump water heating apparatus using the heat pump unit 110 as a heat source has been described as an example, the water heating apparatus 100 is a water heating apparatus using an electric heater or gas combustion as a heat source It is also good.

31 piping, 32 piping, 33 piping, 51 first high temperature water pipe, 52 second high temperature water pipe, 53 check valve, 55 piping, 56 piping, 60 temperature control unit, 61 check valve, 62 check valve, 63 three-way valve , 64 three-way valve, 65 three-way valve, 66 two-way valve, 100 water heater, 110 heat pump unit, 120 hot water storage tank, 121 tank circulation pump, 122 three-way valve, 123 first four-way valve, 124 second four-way valve, 130 bathtub circulation Route, 131 bathtub circulation pump, 133 heat exchanger, 134 bathtub return piping, 135 bathtub forward piping, 140 hot water supply terminal, 140A piping, 150 water supply end, 150A piping, 151 water supply pipe, 160 controller, 161 CPU, 162 communication interface , 163 ROM, 164 RAM, 165 secondary notes Device, 166 bus, 167 user interface unit, 168 equipment state acquisition unit, 169 equipment control unit, 170 operation mode execution unit, 180 hot water circulation path, 197 check valve, 200 bathtub, a1 first port, a2 first port, a3 first port, b1 second port, b2 second port, b3 second port, c1 third port, c2 third port, c3 third port, d2 fourth port, d3 fourth port.

Claims

With a hot water storage tank,
A heat exchanger for exchanging heat between the hot water of the hot water storage tank and the hot water of the bath;
A bathtub circulation path connecting the bathtub and the heat exchanger;
A bathtub circulation pump provided in the bathtub circulation path;
A hot water circulation path connecting the hot water storage tank and the heat exchanger;
A tank circulation pump provided in the hot and cold water circulation path;
A controller for controlling operations of the bathtub circulation pump and the tank circulation pump;
The controller is
A bathtub heat recovery operation for driving the bathtub circulation pump and the tank circulation pump and recovering the heat of the hot and cold water of the bathtub into the hot and cold water of the hot water storage tank;
A bathtub cleaning operation of driving the bathtub circulation pump and circulating hot water of the bathtub;
A hot water supply apparatus for carrying out both the bathtub heat recovery operation and the bathtub cleaning operation before the hot and cold water of the bathtub is drained.
The controller is
By giving priority to suppression of energy consumption or giving priority to cleaning,
The hot water supply apparatus according to claim 1, wherein a driving order of the bathtub circulation pump and the tank circulation pump is changed.
The controller is
When priority is given to suppressing energy consumption,
Implement the bathtub heat recovery operation,
After that, the tank circulation pump is stopped, and the hot water circulation system according to claim 2, wherein driving of the bathtub circulation pump is continued.
The controller is
When priority is given to cleaning,
Conduct the bathtub cleaning operation,
Thereafter, the tank circulation pump is driven to carry out the bathtub heat recovery operation.
After that, the hot water supply apparatus according to claim 2, wherein the tank circulation pump and the bathtub circulation pump are stopped.
The controller is
When the bathtub heat recovery operation is performed before the hot and cold water of the bathtub is drained, and then priority is given to cleaning,
Implementing a reheating operation of driving the bathtub circulation pump and the tank circulation pump to repel the hot and cold water of the bathtub;
The hot water supply apparatus according to claim 2, wherein the bathtub cleaning operation is performed thereafter.
The controller is
After stopping the bathtub cleaning operation, the bathtub heat recovery operation is performed,
After that, the hot water supply apparatus according to claim 5, wherein the bathtub cleaning operation is performed again.
The controller is
Before performing the reheating operation, the tank circulation pump and the bathtub circulation pump are stopped,
After that, the hot water supply system according to claim 5 or 6, wherein the reheating operation is performed by driving the tank circulation pump and the bathtub circulation pump again.
The controller is
The hot water supply apparatus according to any one of claims 3 to 7, wherein the stop of the tank circulation pump is determined based on a differential temperature between the temperature of the hot water of the hot water storage tank and the temperature of the hot water of the bath.
The hot water supply device according to any one of claims 1 to 8, wherein an additive is introduced before the bathtub cleaning operation is performed.