JP5306058B2 - Hot water supply system and operation method thereof - Google Patents

Description

  The present invention relates to a hot water supply system using a heat pump and an operation method thereof.

  In recent years, air pollution and global warming associated with mass consumption of petroleum resources have become problems, and energy saving of products and facilities and reduction of greenhouse gas emissions have been attempted. Hot spring facilities, hospitals, hotels, leisure facilities, etc. are equipped with hot water supply systems to supply a large amount of hot water, but due to the above problems, many hot water supply systems using heat pumps have been proposed and adopted. (For example, see Patent Document 1).

  The heat pump includes a heat exchanger that exchanges heat between the outside air and the heat medium, a compressor that compresses the heat medium that has undergone heat exchange and a temperature increase, and heat between the compressed heat medium and the object to be heated. The heat exchanger to be exchanged and an expansion valve that expands the heat medium in a compressed state although the temperature is lowered are provided.

  In Patent Document 1, water is used as the heat medium, and heat is exchanged with the exhaust gas discharged from the boiler to prevent heat from being exchanged by the heat exchanger due to low temperature of the outside air. I have to. Note that the heat pump is efficient in that heat about three times the power consumption can be effectively used because it is sufficient to give only the energy required to move the heat medium. Moreover, since it does not use liquid fuel like a boiler, it is not greatly affected by its market price.

  However, in such a hot water supply system using a heat pump, since there is often one tank for storing the generated hot water, its size is large, transportation and installation are not easy, and it takes time to cook again. There was a problem that it took.

  Then, the hot water supply system provided with the some tank is proposed (for example, refer patent document 2). In this system, a plurality of tanks are connected in series, a circulation pump and a hot water supply heat exchanger are provided, a flow path leading from the hot water supply heat exchanger to the upper part of the hot water supply side tank through a flow rate adjustment valve, The flow path led to the lower part of the water supply side tank through the flow rate adjusting valve in parallel from the heat exchanger for operation is configured to be switched by the flow rate adjusting valve. In this system, the flow rate of the hot water supply heat exchanger is adjusted by the flow rate adjustment valve so that the temperature of the hot water supplied from the upper part of the hot water supply side tank can be adjusted. It is configured to boil up with the body.

  Since this hot water supply system includes a plurality of tanks, it is possible to install a plurality of tanks having a small diameter and to reduce an installation space. Also, use midnight power with low power costs, energize the heating element, heat the water in the hot water tank, and use a heat pump to heat up the water outside the midnight power time. Since hot water can be preferentially heated, it has excellent hot water properties.

JP 2008-8581 A JP-A-9-236316

  The conventional hot-water supply system is composed of a plurality of tanks and they are connected in series, so that it is possible to cope with the use load. However, the heating element is energized to add water in the tank. There is a problem that a large amount of electric power is consumed and the electric power cost is increased because of warming.

  Further, in the hot water supply system, when the temperature of the hot water in the hot water supply side tank and the hot water supply side tank is lowered, the heating element is energized to raise the temperature. It takes.

  Further, the hot water supply system determines whether or not the temperature sensor attached to the lower part of the tank is 45 ° C. or higher. When the temperature sensor is lower than 45 ° C., the hot water supply system determines that the hot water has run out. Water is supplied to generate hot water, and stored in the order of the hot water supply side tank and the water supply side tank. Since hot water is stored with priority given to the hot water supply side tank, it is possible to quickly supply hot water. However, since it is not determined that the temperature sensor has reached 55 ° C. or higher, hot water runs out during that time.

  Therefore, it is possible to cope with the usage load of hot water, to reduce power consumption, to prevent running out of hot water, and to further improve the temperature of the system and its operating method. Offer is desired.

  In view of the above problems, the present invention supplies hot water in two hot water heaters, each of which includes a heat pump unit that heats water and a hot water storage tank that stores hot water generated by heating by the heat pump unit, and hot water in the hot water storage tank. When it is detected that the amount of remaining hot water in the hot water storage tank of one water heater is below the set amount or the hot water temperature is lower than the set temperature, the other water heater is activated. A hot water supply system including control means for switching to an operation of circulating hot water generated in the hot water storage tank of the other hot water heater having a capacity smaller than that of the hot water storage tank of one hot water heater.

  In this way, both of the two hot water heaters adopt a heat pump unit, one hot water heater with a large amount of hot water storage is operated by night electricity with low power costs, and the other hot water heater is generally used when the amount of hot water storage is insufficient Since it is operated and replenished with electric power, it is possible to prevent hot water shortage while suppressing power consumption. In addition, since the two water heaters are not connected in series, when the hot water is about to run out, start the operation of the other water heater, and switch when the hot water supply becomes possible, corresponding to the hot water usage load can do. The other hot water supply device has a high responsiveness because the capacity of the hot water storage tank is smaller than that of the one hot water supply device, and the water temperature can be raised to the target temperature and supplied hot water quickly.

  The hot water supply system may further include two exhaust lines that blow warm air discharged from a bathhouse or the like of the facility to each of the two heat pump units. The warm air discharged from the bathhouse or the like can shorten the operation time of the compression means provided in these two heat pump units or lower the discharge pressure, thereby suppressing power consumption.

  The warm air exhausted from the bathhouse of the facility contains water vapor and acid gas, and the heat exchanger that exchanges heat between the warm air exhausted from the bathhouse of the facility and the air exhausted from indoors other than the bathhouse, It can also be set as the structure containing the two exhaust lines which blow the warmed air on each of two heat pump units.

  The warm air discharged from the hot spring facility contains an acidic gas such as carbon dioxide or hydrogen sulfide, and there is a risk of promoting metal corrosion due to the presence of moisture and trace amounts of acid cooled and condensed by the outside air after spraying. As described above, instead of blowing directly to the heat pump unit, heat exchange with air and blowing warmed air can reduce power consumption, facilitate maintenance of the heat pump unit, and maintain the equipment life The operation and maintenance costs can be greatly reduced.

  In this invention, the method of operating the said hot water supply system can also be provided. By providing a hot water supply system having the above configuration and an operation method thereof, it is possible to suppress power consumption, eliminate hot water shortage, and cope with hot water usage load in a short time. The temperature can also be raised.

  This method includes a step of measuring the amount of remaining hot water and the temperature of hot water in a hot water storage tank of one of the water heaters, and whether the amount of remaining hot water is less than a set amount from the measurement result and whether the temperature of the hot water is lower than a set temperature. When it is determined that it is less than the set amount or less than the set temperature, the other hot water heater is activated and is generated in the hot water storage tank of the other hot water heater having a capacity smaller than that of the hot water storage tank of one hot water heater. Switching to an operation in which hot water is circulated.

The figure which showed one structural example of the hot water supply system. The figure which showed an example of the water heater used for a hot-water supply system. The figure which showed another structural example of the hot water supply system. The figure which showed another structural example of the hot water supply system.

  FIG. 1 is a diagram showing one configuration example of a hot water supply system. This hot water supply system includes a circulating means for circulating hot water between two hot water heaters 10 and 20 and a facility such as a hot spring facility, a hospital, a hotel, a hot water pool and the like, and a hot water heater under predetermined conditions. And control means for switching to operation from the hot water heater 10 to the water heater 20.

  The water heaters 10 and 20 include heat pump units 11 and 21 that heat water, and hot water storage tanks 12 and 22 that store hot water generated by heating by the heat pump units 11 and 21. The hot water storage tank 22 has a smaller capacity than the hot water storage tank 12 so that hot water can be supplied quickly. The detailed configuration of the water heaters 10 and 20 will be described later.

  The circulation means is installed in order to circulate hot water in the hot water storage tanks 12 and 22 with a facility to be supplied with hot water. As the circulation means, a circulation pump 30 can be used, and a line pump, a spiral pump, or the like can be used.

  The control means includes a control circuit including a CPU and a memory, and control valves 40 and 41 provided in a hot water supply line connected to the hot water storage tanks 12 and 22. The hot water storage tank 12 is provided with a liquid level meter for measuring the liquid level and a thermometer for measuring the temperature of the hot water, which are used as measuring means. This liquid level gauge is used to measure the amount of remaining hot water. The control circuit acquires the liquid level height and the temperature of hot water from the liquid level meter and thermometer at regular time intervals, and the amount of remaining hot water in the hot water storage tank 12 is equal to or less than a preset set amount, or for supplying hot water. It is determined whether the hot water supply temperature is lower than a preset temperature. This time interval may be any time interval, but can be several minutes to several tens of minutes from the viewpoint of preventing hot water from running out. Further, the request for acquiring the measurement value is appropriately transmitted from the control circuit, and the measurement result can be acquired from the measurement means, without being limited to the fixed time interval.

  When it is determined that the control means is less than the set amount or less than the set temperature, the control means detects that hot water runs out as it is, starts the water heater 20, and circulates the hot water generated in the hot water storage tank 22. Switch to. In the case of switching, the control valve 40 is set to “open” to supply hot water from the hot water storage tank 12, the control valve 41 is set to “open” to start hot water supply from the hot water storage tank 22, and the control valve 40 is set to “closed”. Then, the hot water supply from the hot water storage tank 12 is stopped.

  The hot water heater 10 is operated using nighttime electric power with a low cost unit price, and generates and stores hot water in the hot water storage tank 12 until it reaches a target liquid level. In general, hot water is stored until the hot water storage tank 12 is full. When the hot water in the hot water storage tank 12 is insufficient, the water heater 20 operates for replenishment and supplies hot water.

  The water heaters 10 and 20 receive water from the water supply lines 50 and 51 in the hot water storage tanks 12 and 22, send the water to the heat pump units 11 and 21, and are heated by the heat pump units 11 and 21. By returning to 22, the amount of hot water is increased while producing hot water.

  The hot water storage tanks 12 and 22 may have any shape such as a cylindrical shape. Further, in order to store hot water of less than 100 ° C., the hot water storage tanks 12 and 22 have a strength that can withstand the temperature and does not break, such as carbon steel and stainless steel Formed of steel. The hot water storage tanks 12 and 22 are wound with a heat insulating material or the like so that the temperature of the hot water is not easily lowered.

The capacity of the hot water storage tank 22 is made smaller than the capacity of the hot water storage tank 12, but can be, for example, about 1/2 to 1/4 of the capacity of the hot water storage tank 12, and the capacity of the hot water storage tank 12 is about 10 m ³ . In this case, the capacity of the hot water storage tank 22 can be about 4 m ³ . Since this is an example, it is not limited to this capacity. In addition, the number of water heaters is not limited to two, and the hot water system is composed of three or more water heaters with different hot water storage tank capacities, taking into consideration the required amount of hot water, start-up time, etc. It is also possible to select whether to operate and to set the selected water heater to operate.

  The configuration of the water heaters 10 and 20 will be described in detail with reference to FIG. The water heaters 10 and 20 include heat pump units 11 and 21 and hot water storage tanks 12 and 22. The hot water storage tanks 12 and 22 include a receiving nozzle 60 for receiving water, a delivery nozzle 61 for supplying hot water, and circulation nozzles 62 and 63 for circulating water for heating between the heat pump units 11 and 21. Is provided.

  The heat pump units 11, 21 heat the heat supplied to the hot water storage tanks 12, 22 by the heat absorption means 64 that absorbs the heat of the outside air and gives it to the heat medium, the compression means 65 that compresses the heat medium, and the compressed heat medium. Heating means 66 for expanding, and expansion means 67 for expanding the compressed heat medium and supplying it to the heat absorption means 64.

The heat absorption means 64 includes a ventilation fan that takes in outside air and discharges the internal air, and transfers the heat of the taken outside air to the heat medium to warm the heat medium. Therefore, the heat absorption means 64 includes a heat exchanger that exchanges heat between the outside air and the heat medium, and causes the heat medium to flow in the pipe, bringing the outside air into contact with the pipe and giving the heat of the outside air to the heat medium in the pipe. In order to improve the heat conduction efficiency in the heat exchanger, the heat transfer area can be increased. For example, a tube through which a heat medium flows can be formed in a coil shape, or fins can be provided on the surface of the tube. As the heat medium, a gas that can take a large compression ratio and greatly increases in temperature due to the compression is preferable, and examples thereof include air and carbon dioxide. In addition, an alternative refrigerant called R410A in which CH ₂ F ₂ and C ₂ HF ₅ are mixed can be used.

  The compression unit 65 compresses the heat medium warmed by the heat absorption unit 64. Since the compression performed by the compression means 65 is polytropic compression close to adiabatic compression, the discharge temperature rises depending on the compression ratio. For example, when air is used as the heat medium and air of about 0.1 MPa and about 20 ° C. is compressed to about 0.7 MPa, if there is no heat exchange with the outside, all the energy applied for the compression is all The temperature rises to about 260 ° C. in theory, but in reality, there is a heat loss, which is about 170 to 200 ° C. Although there is heat loss, the temperature is higher than 100 ° C., so that water can be sufficiently heated. The compression means 65 is preferably a volumetric compressor, and examples thereof include a reciprocating compressor and a diaphragm compressor.

  The heat medium thus compressed and brought to a high temperature is sent to the heating means 66 and gives the heat to the water supplied to the hot water storage tanks 12 and 22. The heating means 66 can be a heat exchanger and can be coiled or provided with fins in order to increase the heat transfer area.

  The heat medium whose temperature is lowered by applying heat to the water in the heating means 66 is maintained in a compressed state, and the temperature does not drop below the temperature of the hot water stored in the hot water storage tanks 12 and 22. Thus, the heat absorption means 64 cannot absorb the heat of the outside air. Therefore, the temperature is expanded by the expansion means 67 to lower the temperature. As the expansion means 67, an expansion valve can be used. In the expansion means 67, when the pressure is increased from about 0.1 MPa to about 0.7 MPa by the compression means 65, the pressure can be reduced from about 0.7 MPa to about 0.1 MPa.

  The water heaters 10 and 20 heat the supplied water to make hot water and supply hot water. At that time, it is necessary to supply power to the compressor as the compression means 65. The cost of making the same amount of hot water can be significantly reduced because the heat pump can effectively use about three times the power consumption as described above, and the amount of energy required is also small. Therefore, energy saving can be achieved. Moreover, since no liquid fuel is used, generation of carbon dioxide as a warming gas can be suppressed.

  The water heater 10 has the capability of generating and storing hot water of about 90 ° C. in the hot water storage tank 12 within a specified time. On the other hand, the hot water supply device 20 has the capability of generating and storing hot water of about 60 to 65 ° C. in the hot water storage tank 22 in order to quickly generate and supply hot water. The designated time can be a business heat storage contract time, which is a nighttime power band where the power cost is low.

  Referring to FIG. 1 again, hot water storage tank 12 is connected to hot water supply line 52 and supplies hot water to a facility (not shown). The hot water supply line 52 is connected to the hot water supply line 53 via the control valve 40, and supplies hot water to the facility via the hot water supply line 53. The facilities that receive hot water from the hot water supply line 53 are the above-described hot spring facilities, hospitals, hotels, leisure facilities, and the like. The temperature of the hot water supplied to these facilities can be set to a temperature sufficient for additional cooking such as a large bath, for example, about 60 ° C. or more.

  In the operation of this hot water supply system, first, the amount of remaining hot water and the temperature of hot water in the hot water storage tank 12 of the water heater 10 are measured by a liquid level gauge and a thermometer. Then, the control means receives the result, and from the result, determines whether or not the liquid level is equal to or less than the set level, determines whether the remaining hot water amount is equal to or less than the set amount, and sets the hot water supply temperature Is set to 60 ° C., and it is determined whether or not the thermometer indicates 60 ° C. or higher. For example, when it is detected that the temperature is less than 60 ° C., the control unit gives an instruction to the water heater 20 and the control valves 40 and 41, operates the water heater 20, closes the control valve 40, and sets the control valve 41. The hot water is circulated between the facility and the water heater 20 by setting it to “open”. Since the hot water storage tank 22 is connected to the hot water supply line 54, the hot water storage tank 22 supplies hot water to a facility (not shown) via the control valve 41 and the hot water supply line 53.

  When the control means detects that the liquid level exceeds the set level and indicates 60 ° C. or more, as a normal operation, the control valve 40 is set to “open” and the control valve 41 is set to “closed”. Circulate hot water between facilities.

  In response to an instruction from the control means, the water heater 20 supplies power to the compressor which is an embodiment of the compression means 65, starts the compressor, heats the heat medium, and transfers the heat to water. Produces hot water. The generated hot water is sent to the hot water storage tank 22 and the amount of hot water is increased. When the hot water in the hot water storage tank 22 is, for example, 60 to 65 ° C. and the amount of hot water reaches a specified amount, the control valves 40 and 41 are opened and closed as described above, and hot water supply is started from the hot water storage tank 22. This hot water is sent to the facility via the control valve 41, used in an appropriate amount in the facility, and the remaining hot water is returned by the circulation pump 30.

  It takes a certain amount of time to start the operation of the water heater 20 and to supply hot water from the water heater 20. If hot water cannot be supplied during that time, the hot water will run out. Therefore, in consideration of the time, instead of using up the hot water in the hot water storage tank 12 completely, the liquid level to be switched to the water heater 20 as described above is set, and the minimum temperature at which additional cooking is possible Rather, the hot water supply temperature is set with a margin. For this reason, the hot water does not run out, the hot water can be stably supplied, and the usage load can be accommodated.

  Since the hot water storage tank 22 has a smaller capacity than the hot water storage tank 12 and the temperature to be raised is as low as 60 to 65 ° C., the hot water generator 20 generates hot water at a target temperature and starts hot water supply in a short time. Can do. Moreover, since hot water can be produced | generated by a short time driving | operation, power consumption can also be suppressed.

  When this hot water supply system is installed in a facility such as a hotel, the operation can be switched according to the accommodation reservation status. When the number of reservations is small, only the water heater 20 is operated and hot water is generated only in the hot water storage tank 22. Then, by storing and supplying hot water from there, it is possible to reduce the hot water supply load and greatly reduce the running cost.

  The electric power used in the hot water supply system is only the compressor used as the compression means. If the power consumed by the compressor can be suppressed, the running cost can be further suppressed. The compressor compresses the heat medium from atmospheric pressure to a predetermined pressure, the temperature of the heat medium rises due to the compression, and gives the heat to water and hot water in the hot water storage tank to generate hot water of a predetermined temperature. It is possible. Therefore, hot water having a predetermined temperature can be generated earlier as the temperature of the heat medium is higher.

  When the compression ratio of the heat medium by the compressor is the same, the higher the suction temperature of the heat medium, the higher the discharge temperature. For this reason, it is desirable to raise the temperature of the heat medium entering the compressor.

  In hot spring facilities, hospitals, hotels, leisure facilities, etc., ventilation fans are provided to ventilate the interior as appropriate. Ventilation is also provided in the public baths and bathrooms of these facilities. The air exhausted into the atmosphere by ventilation is warm air (warm air), and if this can be used, the power consumption of the hot water supply system can be further suppressed.

  Therefore, in another embodiment of the hot water supply system of the present invention, as shown in FIG. 3, in addition to the configuration shown in FIG. , 21 include exhaust lines 71 and 72 for spraying.

  The exhaust lines 71 and 72 are disposed so as to blow indoor air sucked in by a ventilation fan or the like toward heat absorption means provided in the heat pump units 11 and 21. The outlet is arranged toward the heat exchanger through which the heat medium flows. These exhaust lines 71 and 72 are wound with a heat insulating material or the like so as not to be cooled by outside air, and the length thereof is shortened as much as possible.

  In the operation in this configuration, a step of blowing warm air discharged from the facility 70 to the heat pump units 11 and 21 of the water heaters 10 and 20 is added. By blowing warm air from the exhaust lines 71 and 72, the heat medium can be efficiently heated regardless of the outside air temperature, and power consumption can be suppressed. For this reason, it is useful in areas with a lot of snow and in winter.

  In the case of a hot spring facility, the warm air exhausted by the bathhouse ventilation may contain water and other acidic gases such as carbon dioxide and hydrogen sulfide. If this warm air is blown as it is, there is a risk of accelerating the corrosion of the heat exchanger made of metal of the heat absorbing means due to the presence of moisture cooled by the outside air and condensed and a trace amount of acid.

  Further, when the outside air temperature is below freezing point, the water vapor is condensed on the outer surface of the heat exchanger of the heat absorbing means, and frost is attached. This does not play a role as a heat exchanger, and does not suppress power consumption, but consumes excess power. Therefore, instead of blowing directly to the heat pump units 11 and 21, before that, the warm air is heat-exchanged with relatively dry air, and the warmed air is blown to prevent corrosion, so that the outer surface of the heat exchanger It is configured to prevent frost formation. Thereby, power consumption can be suppressed, maintenance and management of the heat pump units 11 and 21 can be facilitated, the life of the apparatus can be extended, and operation and maintenance costs can be greatly reduced.

  Specifically, as shown in FIG. 4, in addition to the configuration shown in FIG. 1, a heat exchanger 81 that exchanges heat between warm air discharged from the bathing area of the facility 80 and air discharged from indoors other than the bathing area. And exhaust lines 82 and 83 for blowing air heated by heat exchange to the heat pump units 11 and 21 of the water heaters 10 and 20, respectively.

  As shown in FIG. 4, in the heat exchanger 81, a flow path is formed so that both warm air and air enter from above and exit downward, and water vapor contained in the warm air indirectly heats the air. The water is condensed and discharged from the lower portion of the heat exchanger 81 with certainty.

  This water may contain an acid gas, and the heat exchanger 81 can be provided with a thin resin lining on the inner surface through which warm air flows to prevent corrosion, and FRP (fiber reinforced plastic) as the resin. Etc. can be used.

  The exhaust lines 82 and 83 are disposed so as to blow indoor air sucked in by a ventilation fan or the like toward a heat absorbing means included in the heat pump units 11 and 21 via the heat exchanger 81. Similar to the embodiment shown in FIG. 3, the air outlet is arranged toward the heat exchanger through which the heat medium flows, and the exhaust lines 71 and 72 are wound with a heat insulating material or the like so as not to be cooled by the outside air. His length is shortened as much as possible.

  This configuration is also particularly useful in areas with a lot of snow and in winter, and is useful when operating the water heater 10 in ventilation after bathing at night.

  By adopting the configuration of the embodiment shown in FIG. 3 and FIG. 4, the coefficient of performance (COP) used as a measure of energy consumption efficiency can be improved, and the power consumption can be greatly suppressed.

  The hot water supply system and the operation method thereof according to the present invention have been described in detail with reference to the embodiments shown in the drawings, but the present invention is not limited to the above-described embodiments, and other embodiments and Additions, changes, deletions, and the like can be made within the scope that can be conceived by those skilled in the art, and any aspect is included in the scope of the present invention as long as the effects and advantages of the present invention are exhibited. .

DESCRIPTION OF SYMBOLS 10,20 ... Hot water supply machine 11, 21 ... Heat pump unit, 12, 22 ... Hot water storage tank, 30 ... Circulation pump, 40, 41 ... Control valve, 50, 51 ... Water supply line, 52, 53, 54 ... Hot water supply line, 60 ... Receiving nozzle, 61 ... Sending nozzle, 62, 63 ... Circulating nozzle, 64 ... Heat absorption means, 65 ... Compression means, 66 ... Heating means, 67 ... Expansion means, 70, 80 ... Facility, 71, 72, 82, 83 ... exhaust line, 81 ... heat exchanger

Claims (6)

A hot water supply system that generates and supplies hot water,
Two water heaters comprising a heat pump unit for heating water and a hot water storage tank for storing hot water generated by heating by the heat pump unit;
Circulation means for circulating the hot water in the hot water storage tank to and from the facility to be supplied with hot water;
When it is detected that the amount of remaining hot water in the hot water storage tank of one of the water heaters is equal to or less than a set amount or that the hot water temperature is lower than the set temperature, the other hot water heater is started and the hot water storage tank of the one hot water heater is A hot water supply system including control means for switching to an operation of circulating hot water generated in the hot water storage tank of the other hot water heater having a small capacity.   2. The hot water supply system according to claim 1, comprising two exhaust lines that blow warm air discharged from the facility to each of the heat pump units of the two water heaters. The warm air discharged from the bath of the facility includes water vapor and acid gas,
A heat exchanger that exchanges heat between the warm air exhausted from the bathing area of the facility and air exhausted from indoors other than the bathing area, and the heat pump unit of the two water heaters that are heated by the heat exchange, respectively. The hot-water supply system according to claim 1, comprising two exhaust lines that spray on the water. Circulation that circulates between the two hot water heaters comprising a heat pump unit that heats water and a hot water storage tank that stores hot water generated by heating by the heat pump unit, and the hot water in the hot water storage tank to the facility to be supplied with hot water An operation method of a hot water supply system comprising means, control means, and measurement means,
Measuring the amount of hot water in the hot water storage tank of one of the water heaters and the temperature of the hot water;
From the measurement result by the measuring means, the control means determines whether the amount of remaining hot water is a set amount or less and whether the temperature of the hot water is lower than a set temperature;
When it is determined that the temperature is equal to or less than the set amount or less than the set temperature, the control unit activates the other hot water supply device, and the hot water storage of the other hot water supply device has a smaller capacity than the hot water storage tank of the one hot water supply device. And a step of switching to an operation in which hot water generated in the tank is circulated.   The operation method according to claim 4, further comprising a step of blowing warm air discharged from the facility to each of the heat pump units of the two water heaters. The warm air discharged from the bath of the facility includes water vapor and acid gas,
The step of exchanging heat between the warm air exhausted from the bathhouse of the facility and the air exhausted from indoors other than the bathhouse, and blowing the air warmed by the heat exchange to each of the heat pump units of the two water heaters The operation method according to claim 4, further comprising a step.