JP2016040007A - Mist sauna apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mist sauna apparatus capable of operating according to intention of a user conscious of energy saving.SOLUTION: The mist sauna apparatus includes, on a controller R, an eco-operation switch for receiving an eco-operation command as an operation command of operating under an eco-operation state. When receiving the eco-operation command, the mist sauna apparatus commands a warm water supply device 2 to supply warm water at a second temperature lower than a first temperature, and is configured to operate under the eco-operation state using the supplied warm water for operations of an inside air circulation mechanism A and a mist spray mechanism M. A threshold temperature for determining inside air circulation start timing and a threshold temperature for determining mist spray start timing are differentiated between a normal operation state and the eco-operation state. As for the respective determination threshold temperatures, the determination threshold temperature for the eco-operation state is set lower than the determination threshold temperature for the normal operation state.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a mist sauna device, specifically, an inside air circulation mechanism that sucks in the inside air from the room and performs an operation of warming the inside air with warm water supplied from a hot water supply device and returning it to the room as warm air; A mist spray mechanism that performs an operation of spraying the mist water heated by the hot water supplied from the hot water supply device into the room as a mist, and supplies hot water at the first temperature based on an operation command input to the controller. The hot water supply device is commanded, and the supplied hot water is used to operate in the normal air circulation mechanism and the mist spray mechanism. The internal air circulation mechanism works to return the hot air to the room. The inside air circulation start timing is determined based on the incoming hot water temperature, which is the temperature of the hot water supplied from the hot water supply device, and the mist spray mechanism works to spray the mist indoors. The mist spray start timing relates to a mist sauna apparatus for determining based on the return temperature of hot water is a temperature of the hot water back to the hot water supply device.

  There is a hot water generating hot air generator that receives hot water of a predetermined temperature from outside and generates hot air using the hot water. In particular, a typical example of this type of hot water generating hot air generator is a mist sauna device. It has been known. The mist sauna device has a mist sauna function in the bathroom. Normally, such a mist sauna device operates by receiving supply of high-temperature hot water (80 ° C.) from a water heater that burns fuel and generates hot water by the combustion heat. Examples of hot water sources include those that use hot water obtained by recovering exhaust heat exhausted from heat source equipment such as engines and fuel cells, and that collect hot energy from natural energy such as solar heat to produce hot water. Some use it.

In the case of a system that recovers and uses the former waste heat as hot water, generally, the exhaust heat discharged from the heat source machine is recovered as hot water of about 60 ° C., and the hot water is stored in a hot water storage tank. And it is utilized by the mist sauna apparatus side by paying out warm water timely as needed. In this system, the temperature of the hot water stored in the hot water storage tank is lower than the original required temperature (80 ° C) of the mist sauna device, so the temperature is raised to the required temperature by an auxiliary heat source provided separately and supplied to the mist sauna device. A configuration is adopted.
Even when using the warm water obtained by the latter heat collection, if the temperature of the warm water is lower than the required temperature of the mist sauna device, the temperature is raised by a device such as an auxiliary heat source device and supplied.

  Patent Document 1 also describes a hot water supply device that includes a main hot water generating device that generates hot water and an auxiliary heat source device that can further heat the hot water generated by the main hot water generating device. As an auxiliary heat source machine, what heats up warm water with the combustion heat of a combustor is described. And in this warm water supply apparatus, the warm water produced | generated by operating at least an auxiliary heat source machine is supplied to an air conditioning use, a hot water supply, and a bath use.

JP 2001-296055 A

However, the temperature of the hot water required to operate the mist sauna device is set from the viewpoint of ensuring sufficient comfort for the equipment user. It is often hot water temperature.
Such hot water temperature on the high temperature side is set as the lowest temperature for operating the mist sauna device in the most stable and comfortable state. However, for example, if the user who uses the mist sauna device can tolerate a little inconvenience from the viewpoint of energy saving, it is better to be able to operate according to the user's intention.
Furthermore, as described in Patent Document 1, at least in the case of adopting a system that collects the exhaust heat as warm water or a system that uses the collected heat as warm water as a warm water supply device, The auxiliary heat source unit will be operated to consume fuel, and this will be reversed from the viewpoint of energy saving. That is, it is preferable from the viewpoint of energy saving to use the hot water originally generated or held as it is without operating the auxiliary heat source machine.

  This invention is made | formed in view of said subject, The objective is to provide the mist sauna apparatus which can be drive | operated according to the intention of the user with high energy saving consciousness.

The characteristic configuration of the mist sauna apparatus according to the present invention for achieving the above-described object is that the inside air is sucked from the room, and the inside air is warmed by the hot water supplied from the hot water supply device and returned to the room as the warm air. And a mist spray mechanism that performs an operation of spraying the mist water heated by the warm water supplied from the warm water supply device into the room as a mist,
Based on the operation command input to the controller, the hot water supply device is instructed to supply the hot water at the first temperature, and the supplied hot water is used for the operation of the internal air circulation mechanism and the operation of the mist spray mechanism. Configured to operate in normal operating conditions,
The inside air circulation start timing for returning the warm air to the room by working the inside air circulation mechanism is determined based on the incoming hot water temperature which is the temperature of the hot water supplied from the hot water supply device,
A mist sauna device that determines a mist spray start timing at which the mist spray mechanism works to spray the mist indoors based on a return hot water temperature that is a temperature of hot water to be returned to the hot water supply device,
The controller includes an eco-drive switch that accepts an eco-drive command that is a drive command in an eco-drive state,
When the eco operation command is accepted, the hot water supply device is commanded to supply hot water having a second temperature lower than the first temperature, and the supplied hot water is used to operate the internal air circulation mechanism and the mist spray. It is configured to be operable in the eco-driving state used for the mechanism operation,
The determination threshold temperature of the inside air circulation start timing and the determination threshold temperature of the mist spray start timing are different between the normal operation state and the eco operation state,
Regarding each of the determination threshold temperatures, the determination threshold temperature in the eco-driving state is set lower than the determination threshold temperature in the normal operation state.

According to the above characteristic configuration, when the eco-driving instruction is not accepted, the mist sauna device is required in the normal operation state, that is, the first set in advance in consideration of the comfort for the mist sauna application. The hot water of temperature is received from the hot water supply device, the hot water is generated using the heat of the hot water of the first temperature, and the water for mist is heated, so that the temperature of the mist sauna is high in comfort. Hot air and mist can be generated and supplied to the bathroom.
On the other hand, when the eco-driving instruction is received, the mist sauna device receives the supply of hot water having a second temperature lower than the first temperature from the hot water supply device, and warms the hot water with the second temperature. Wind is generated and mist water is heated. That is, the warm air and mist generated using the heat of the hot water at the second temperature lower than the first temperature required in the normal operation state are the warm air and mist generated using the heat of the hot water at the first temperature. Although the comfort as a mist sauna application becomes lower than that, energy saving performance becomes higher. Therefore, the mist sauna operation can be performed while ensuring a certain level of comfort while placing importance on energy saving.

Further, when the inside air circulation start timing is reached, it is allowed to operate the inside air circulation mechanism to supply warm air into the room. In order to determine that the internal air circulation start timing has been reached, it is necessary that the incoming hot water temperature has reached the determination threshold temperature of the internal air circulation start timing. Similarly, when the mist spray start timing is reached, it is allowed to perform an operation of spraying mist indoors by operating the mist spray mechanism. In order to determine that the mist spray start timing has been reached, it is necessary that the return hot water temperature has reached the determination threshold temperature for the mist spray start timing.
That is, if the determination threshold temperature is relatively low, the energy required on the hot water supply device side to cause the incoming hot water temperature to reach the determination threshold temperature is relatively low. On the other hand, if the determination threshold temperature is relatively high, the energy required on the hot water supply device side to cause the incoming hot water temperature to reach the determination threshold temperature is relatively high. Therefore, the energy required for operating the mist sauna device in the eco operation state is set to operate the mist sauna device in the normal operation state by setting the determination threshold temperature of the eco operation state lower than the determination threshold temperature of the normal operation state. It can be made lower than the energy required for this.
Therefore, it is possible to provide a mist sauna device that can be operated according to the intention of a user with high energy saving awareness.

  Another characteristic configuration of the mist sauna apparatus according to the present invention is a return that is the temperature of the inside air sucked from the room after the operation of the inside air circulation mechanism and before the operation of the mist spraying mechanism starts in the normal operation state. An inside air temperature is detected, and the operation of the mist spray mechanism is started on the condition that the return inside air temperature is equal to or higher than a predetermined set threshold temperature and the return hot water temperature is higher than a determination threshold temperature of the mist spray start timing. In the eco operation state, after the operation of the inside air circulation mechanism, the operation of the mist spray mechanism is started only on the condition that the return hot water temperature is higher than the determination threshold temperature of the mist spray start timing. is there.

According to the above characteristic configuration, in the normal operation state, the return inside air temperature is equal to or higher than the set threshold temperature and the return hot water temperature is higher than the determination threshold temperature for the mist spray start timing is set as the start condition for the mist spray operation. That is, since the return room temperature indicates the room temperature, that the return room temperature is equal to or higher than the set threshold temperature means that the indoor comfort is ensured.
In addition, since the return hot water temperature is the temperature of the hot water that is returned to the hot water supply device after use, when the heat that is newly consumed by the mist spray mechanism is reduced among the heat that the hot water has, that is, the mist spray. When the temperature drop due to heat consumption in the mechanism becomes small, the return hot water temperature becomes relatively high. That is, the fact that the return hot water temperature can be maintained at a high temperature that is equal to or higher than the threshold temperature for determining the mist spray start timing means that the heat taken away when the temperature of the mist water is raised is reduced, that is, the mist water is reduced. It means that it is ready to be heated sufficiently. In other words, it means that a comfortable mist can be sprayed from the mist spray mechanism.
Therefore, in the normal operation state, the indoor temperature is determined by setting the return inside air temperature to be equal to or higher than a predetermined threshold temperature and the return hot water temperature to be higher than the determination threshold temperature for the mist spray start timing. Both the comfort of the mist and the comfort of the temperature of the sprayed mist can be achieved. On the other hand, in the eco-operation state, whether or not the comfort of the indoor temperature can be ensured by only setting the return hot water temperature to be higher than the determination threshold temperature of the mist spray start timing as the mist spray operation start condition. Although it is unclear, it is possible to ensure at least the comfort of the temperature of the sprayed mist.

  Still another characteristic configuration of the mist sauna apparatus according to the present invention is that the hot water supply device includes a main hot water generating device that generates hot water and an auxiliary heat source device that can further heat the hot water generated by the main hot water generating device. Corresponding to the normal operation state, hot water heated to the first temperature is supplied by the auxiliary heat source unit, and the main hot water generation is performed without operating the auxiliary heat source unit corresponding to the eco operation state. The hot water having the second temperature generated by the device is supplied.

  According to the above characteristic configuration, the hot water at the second temperature is raised to the first temperature using the auxiliary heat source device in the normal operation state and then supplied to the mist sauna device, and the hot water at the second temperature is assisted in the eco operation state. It supplies to a mist sauna apparatus at the same temperature (namely, 2nd temperature), without using a heat source machine. That is, since the auxiliary heat source unit is not used in the eco-operation state, the energy consumption of the auxiliary heat source unit that has been generated in the normal operation state can be reduced.

  Still another characteristic configuration of the mist sauna apparatus according to the present invention is such that the main hot water generating device recovers heat discharged from a heat source device or collects heat from natural energy to obtain hot water having the second temperature. In that point.

  According to the said characteristic structure, the main warm water production | generation apparatus can obtain the warm water of 2nd temperature by collect | recovering the heat discharged | emitted from a heat source machine, or collecting from natural energy. As a result, the hot water at the second temperature can be supplied from the hot water supply device to the mist sauna device without operating the auxiliary heat source device. Moreover, energy-saving property can be improved by effectively using the heat collected from natural energy.

  Still another characteristic configuration of the mist sauna apparatus according to the present invention is that the main hot water generating device stores the hot water having the second temperature obtained by collecting heat discharged from a heat source machine or collecting heat from natural energy. This is a device that stores hot water in a tank and supplies hot water at the second temperature from the hot water storage tank when a hot water supply command is received.

  According to the said characteristic structure, the main warm water production | generation apparatus can obtain the warm water of 2nd temperature by collect | recovering the heat discharged | emitted from a heat source machine, or collecting from natural energy. As a result, the hot water at the second temperature can be supplied from the hot water supply device to the mist sauna device without operating the auxiliary heat source device. Further, the hot water at the second temperature is temporarily stored in the hot water storage tank, and the hot water at the second temperature is supplied in accordance with the demand timing of the hot water, so that the hot water can be effectively used.

  Still another characteristic configuration of the mist sauna apparatus according to the present invention is that the hot water supply device generates and supplies hot water having the first temperature or the second temperature with heat generated by combustion of fuel. It is in.

  According to the above characteristic configuration, the temperature of the generated hot water can be adjusted to the first temperature and the second temperature by adjusting the amount of heat generated by the combustion of the fuel.

It is a figure which shows the structure of a hot water utilization system. It is a figure which shows the structure of the hot water supply apparatus of 1st Embodiment. It is a figure explaining switch arrangement of a remote control device. It is a flowchart of switching control of the normal operation state and eco-operation state of 1st Embodiment. It is a flowchart explaining the driving | operation start control in a normal driving | running state. It is a figure explaining control of the mist temperature made to eject to a bathroom. Flow chart explaining driving start control in eco-driving state It is a figure which shows the structure of the hot water supply apparatus of 2nd Embodiment. It is a figure which shows the structure of the hot water supply apparatus of another embodiment. It is a flowchart of switching control of a normal driving state and an ecological driving state. It is a figure explaining switch arrangement of a remote control device of another embodiment.

<First Embodiment>
Hereinafter, the mist sauna apparatus of 1st Embodiment is demonstrated with reference to drawings.
FIG. 1 is a diagram illustrating a configuration of a hot water use system including a mist sauna device and a hot water supply device. FIG. 2 is a diagram illustrating a configuration of the hot water supply device.
The mist sauna device sucks the inside air from the inside of the bathroom 4, warms the inside air with the hot water supplied from the hot water supply device 2, and returns to the bathroom 4 as hot air, and the hot water supply A mist spray mechanism M that performs an operation of spraying the mist water heated by the hot water supplied from the device 2 into the bathroom 4 as mist is provided. Then, the mist sauna device instructs the hot water supply device 2 to supply hot water at the first temperature based on the operation command input to the remote control device R as a controller capable of inputting various control commands, and supplies the hot water supply device 2. The received warm water is configured to be operable in a normal operation state in which the warm air circulating mechanism A and the mist spray mechanism M are used. In addition, the mist sauna apparatus demonstrated by this embodiment is implement | achieved as one function of the bathroom heating dryer which can implement each operation of heating operation of a bathroom, ventilation operation, drying operation, cool air operation, and mist sauna operation. is there.

  A specific configuration example of the mist sauna device will be described. The device body 1 of the mist sauna device heats the air that is ventilated by the circulation fan 7 for circulating and circulating the air in the bathroom 4 and the circulation fan 7. An air conditioning heat exchanger 8, a ventilation fan 9 for ventilating the bathroom 4, and two mist nozzles 11 for jetting mist water supplied through the water supply passage 10 into the bathroom 4 in a mist form are provided in the main body casing 12. Equipped with equipment. The apparatus main body 1 is disposed behind the ceiling of the bathroom 4. The grill plate 13 is installed below the main body casing 12 so as to be positioned on the surface side of the ceiling of the bathroom 4 with the main body casing 12 entering the back side of the ceiling plate 6 of the bathroom 4.

The grill plate 13 is provided with an air inlet 14 and an air outlet 15 in parallel. A circulation ventilation path 16 is formed in the main body casing 12 for sucking air in the bathroom 4 through the air inlet 14 and blowing it out through the air outlet 15. The circulation fan 7 is provided in the circulation ventilation path 16 in such a state that the air in the bathroom 4 sucked to the air inlet 14 and sucked from the air inlet 14 is blown out from the air outlet 15 into the bathroom 4. It has been. Further, an air conditioning heat exchanger 8 is provided in the circulation ventilation path 16 upstream of the circulation fan 7 in the ventilation direction, and heat exchange with the hot water circulated and supplied from the hot water supply device 2 is performed in the circulation ventilation path 16. It is comprised so that the air which ventilates may be heated. In this way, the mist sauna device sucks air in the bathroom 4 through the air inlet 14 by the ventilation action of the circulation fan 7, heats it with the heat exchanger 8 for air conditioning, and blows it into the bathroom 4 through the outlet 15. Thus, the heating operation for heating the inside of the bathroom 4 can be executed.
That is, in this embodiment, the circulation fan 7 and the heat exchanger 8 for air conditioning suck the inside air from the bathroom 4 as a space to be dried, warm the inside air with warm water, and return it to the bathroom 4 as hot air. It functions as a circulation mechanism A.

The forward path 18 of the heat medium circulation path 17 to which hot water is supplied from the hot water supply device 2 installed outside the bathroom 4 is branched into two heat medium branch paths 19 and 20. One of the heating medium branch paths 20 is connected to the air conditioning heat exchanger 8, and the downstream side of the air conditioning heat exchanger 8 in the heating medium branch path 20 is connected to the return path 21 of the heating medium circulation path 17. The hot water heated by the hot water supply device 2 is circulated and supplied to the air conditioner heat exchanger 8 through the heat medium circulation path 17. In the middle of the heat medium branch path 20, a thermal valve 22 is provided that can freely and intermittently supply hot water to the air conditioner heat exchanger 8 by opening and closing the flow path of the heat medium branch path 20.
The other heat medium branch path 19 is provided with a heat medium flow rate adjustment valve 39 that can freely connect / disconnect the heat medium branch path 19 and change and adjust the flow rate of hot water to the heat exchanger 29.
In addition, the forward path 18 of the heat medium circulation path 17 is provided with a heat medium thermistor 5 as hot water temperature detection means for detecting the temperature of the flowing hot water. A return temperature thermistor 56 that detects the temperature of hot water that is used to raise the temperature of the mist water in the heat exchanger 29 and then returned to the hot water supply device 2 is provided in the heat medium branch path 19 on the downstream side of the heat exchanger 29. It has been.

  A bathroom temperature thermistor 23 that detects the temperature of the flowing air as the temperature in the bathroom 4 is provided at a location upstream of the air conditioning heat exchanger 8 in the circulation ventilation path 16. The blower outlet 15 is provided with a movable louver 24 that is oscillated and driven by an electric motor (not shown), and the movable louver 24 can change the blowing direction of the air blown into the bathroom 4 from the blower outlet 15. .

The ventilation fan 9 is provided in the main body casing 12 so as to exhaust the air in the bathroom 4 sucked from the air inlet 14 to the outside through the exhaust duct 25. Due to the ventilation action of the ventilation fan 9, the air in the bathroom 4 is discharged to the outside through the exhaust duct 25, and the bathroom 4 is ventilated.
Two mist nozzles 11 are supported at a portion of the grill plate 13 between the air inlet 14 and the air outlet 15 with the hot water jetting direction downward.

  A hot water generating unit 26 for generating hot water for mist and supplying it to the mist nozzle 11 is provided on the upper portion of the main casing 12. The hot water generating unit 26 supplies hot water to a mist casing 27 through which a mist water is supplied from a water supply or the like, a water supply valve 28 that opens and closes the water supply passage 10, and mist water supplied from the water supply path 10. A heat exchanger 29 that is heated by heat exchange with the hot water circulated and supplied from the device 2, a lower-side passage 30 through which water for mist supplied from the water supply channel 10 and heated by the heat exchanger 29 flows, A drainage valve 32 that opens and closes the flow path of the drainage channel 31 branched from the lower side flow path 30, a hot water thermistor 33 for mist that detects the temperature of hot water flowing through the lower side flow path 30, and the like are provided.

  A mist supply path 34 different from the drainage path 31 is branched from the lower side flow path 30, and the mist supply path 34 is piped in a state extending to the inside of the main body casing 12. The mist supply path 34 is further branched into two branch paths 35 and 36 along the path, and these branch paths 35 and 36 are connected to the mist nozzles 11, respectively. The two branch passages 35 and 36 are provided with mist opening and closing valves 37 and 38, respectively, that can freely and intermittently supply hot water to the mist nozzles 11 by opening and closing the passages.

As described above, the water for mist supplied from the water supply passage 10 is heated by the heat exchanger 29, and the heated warm water is supplied to the mist nozzle 11 through the lower side passage 30 and the mist supply passage 34. It is comprised so that the mist operation which ejects warm water in the mist form from the mist nozzle 11 in the bathroom 4 can be performed.
In other words, in the present embodiment, the mist open / close valves 37 and 38, the water supply valve 28, the mist nozzle 11 and the heat exchanger 29 are provided in the bathroom 4 with the mist water heated by the hot water supplied from the hot water supply device 2 as mist. It functions as a mist spray mechanism M that performs an operation of spraying.

  When the mist sauna operation has not been performed for a long time since the last time the mist sauna operation was performed, the drainage channel 31 is contaminated that has accumulated in the water supply channel 10 or the internal piping of the heat exchanger 29. It is for discharging water for mist to the outside. The drainage treatment using the drainage channel 31 is performed by switching the water supply valve 28 and the drainage valve 32 to the open state while maintaining the mist open / close valves 37 and 38 in the closed state.

Next, the configuration of the hot water supply device 2 will be described with reference to FIG.
In the present embodiment, the hot water supply device 2 includes a main hot water generating device 2A and an auxiliary heat source device 2B. The main hot water generator 2 </ b> A includes a heat source device 50 and a heat storage device 60. The heat source device 50 includes an engine 51 and a generator 52 driven by the engine 51. The electricity generated by the generator 52 is supplied to a power consuming device (not shown).

  The engine 51 is configured to be cooled by engine cooling water. In the present embodiment, the engine coolant circulates through the engine 51 and the heat exchanger 53 in order through the coolant circulation path 54. A cooling water pump 55 is provided in the middle of the cooling water circulation path 54, and the flow rate of the engine cooling water in the cooling water circulation path 54 is adjusted according to the operation of the cooling water pump 55. In the heat exchanger 53, heat is transferred from the engine cooling water to the hot water by exchanging heat between the relatively low-temperature hot water described later and the engine cooling water.

  The heat storage device 60 has a hot water storage tank 61 that collects and stores the exhaust heat from the heat source device 50. The hot water storage tank 61 stores hot water, which is heated by the heat exchanger 53 through the hot water circulating hot water circulation path 62 and returns to the hot water storage tank 61 again. In the present embodiment, the hot water storage tank 61 stores hot water having a relatively high temperature in the upper part thereof, and stores hot water having a relatively low temperature in the lower part thereof so that temperature stratification is formed inside the hot water storage tank 61. It is configured. A hot water circulation pump 63 is provided in the hot water hot water circulation path 62, and the flow rate of the hot water in the hot water hot water circulation path 62 is adjusted according to the operation of the hot water circulation pump 63. Specifically, if the flow rate of the hot water in the hot water circulation path 62 for hot water storage is reduced, that is, if the flow rate of the hot water passing through the heat exchanger 53 per unit time is reduced, the temperature of the hot water after passing through the heat exchanger 53 Is relatively high. On the other hand, if the flow rate of the hot water in the hot water circulation path 62 for hot water storage is increased, that is, if the flow rate of the hot water passing through the heat exchanger 53 per unit time is increased, the temperature of the hot water after passing through the heat exchanger 53 Is relatively low. For example, in the hot water storage tank 61, the operation of the hot water circulation pump 63 is controlled so that hot water of 60 ° C. is stored, and the exhaust heat recovery operation is performed.

  The auxiliary heat source unit 2B is a device that consumes fuel to generate heat and raises the temperature of the hot water with the heat. The auxiliary heat source unit 2B includes a combustor 72 that combusts gas as fuel, a flow rate adjustment valve 70 that adjusts the amount of gas supplied to the combustor 72, and a blower 71 that supplies oxygen (air) to the combustor 72. Is provided. Further, the forward path 18 of the heat medium circulation path 17 through which the hot water sent from the hot water storage tank 61 by the hot water delivery pump 64 flows is drawn into the auxiliary heat source machine 2B. The forward path 18 of the heat medium circulation path 17 flows through the inside of the heat exchanger 73 provided in the auxiliary heat source unit 2B. Further, the heat exchanger 73 is given combustion heat generated in the combustor 72. As a result, the temperature of the hot water flowing through the forward path 18 of the heat medium circulation path 17 is raised by the combustion heat generated in the combustor 72. The amount of heat given from the combustor 72 to the hot water flowing in the forward path 18 of the heat medium circulation path 17 changes according to the amount of combustion heat generated in the combustor 72. That is, by adjusting the amount of gas and the amount of air supplied to the combustor 72, the amount of heat applied to the hot water flowing in the forward path 18 of the heat medium circulation path 17 can be adjusted. For example, the amount of gas and the amount of air supplied to the combustor 72 are adjusted so that the temperature of the hot water thermistor 74 provided in the outward path 18 downstream of the heat exchanger 73 becomes a predetermined temperature.

  FIG. 3 is a diagram illustrating the switch arrangement of the remote control device. The remote controller R as a controller of the present invention includes a timer display unit 40 for displaying a timer time for driving, a mist sauna driving switch 41 for instructing mist sauna driving, and a timer setting switch for changing and setting the driving timer time. 42, a wind direction switch 43 for instructing a change in the blowing direction of the movable louver 24, a drying operation switch 44 for instructing a drying operation, a heating operation switch 45 for instructing a heating operation for heating the bathroom 4, and a ventilation for operating the ventilation fan 9 A ventilation operation switch 46 for instructing operation, a cool air operation switch 47 for instructing cool air operation for operating the circulation fan 7, a stop switch 48 for stopping each operation, and the like are provided. Further, as will be described later, the remote control device R is provided with an eco-operation switch 49 for giving an operation command in an eco-operation state that is an operation state deviating from the normal operation state.

  In addition, various lamps that are turned on when the operation switches 41, 44, 45, 46, 47, 49 are in the ON operation state (mist sauna operation lamp 41a, drying operation lamp 44a, heating operation lamp 45a, ventilation operation lamp) 46a, a cool wind operation lamp 47a, and an eco operation lamp 49a) are provided adjacent to the operation switches.

  Hereinafter, the heating operation, ventilation operation, drying operation, cool air operation, and mist sauna operation of the mist sauna device will be briefly described.

[Heating operation]
The heating operation of the mist sauna device is an operation in which air in the bathroom 4 is taken in and heated, and then the heated air is blown into the bathroom 4. Specifically, the ventilation fan 9 is stopped and the circulation fan 7 is operated, and hot water is supplied from the hot water supply device 2 to the mist sauna device so that the hot air temperature at the outlet 15 is maintained within the set temperature range. As described above, the hot water is circulated and supplied to the air conditioner heat exchanger 8 by controlling the opening and closing of the thermal valve 22 and the hot water supply operation of the hot water supply device 2. As a result, the circulating air heated by the air conditioner heat exchanger 8 is blown into the bathroom 4 from the blowout port 15. As described above, the mist sauna device generates warm air by receiving the supply of hot water from the hot water supply device 2 in the heating operation. Further, the operation state of the circulation fan 7 is adjusted so that the ventilation amount of the air ventilated in the bathroom 4 becomes the ventilation amount for heating, and the movable louver 24 is swung.

[Ventilation operation]
The ventilation operation is an operation in which air sucked from the bathroom 4 is exhausted from the exhaust duct 25. Specifically, the ventilation fan 9 is operated while the operation of the circulation fan 7 is stopped and the thermal valve 22 is kept closed. Further, the operating state is adjusted so that the movable louver 24 is closed.

[Dry operation]
The drying operation is performed, for example, while discharging a part of the air sucked from the inside of the bathroom 4 as a drying space in which a drying object such as clothes containing moisture is arranged after taking a bath to the outside through the exhaust duct 25. In this operation, the remaining air is heated by the air conditioner heat exchanger 8 and then blown into the bathroom 4 from the outlet 15. Specifically, the thermal valve is operated so that the circulating fan 7 is operated and hot water is supplied from the hot water supply device 2 to the mist sauna device so that the hot air temperature at the outlet 15 is maintained within the set temperature range. The hot water supply operation of the hot water supply device 2 is controlled by opening and closing 22 to circulate and supply the hot water to the air conditioner heat exchanger 8 and to operate the ventilation fan 9.

(Cool wind driving)
The cool air operation is an operation in which the air sucked from the bathroom 4 is blown out into the bathroom 4 through the circulation ventilation path 16 without being heated. Specifically, the circulation fan 7 is operated with the thermal valve 22 kept closed, and the ventilation fan 9 is operated so that a part of the air sucked from inside the bathroom 4 is taken outdoors through the exhaust duct 25. In this operation, the remaining air is blown out into the bathroom 4 through the circulation ventilation path 16 without being heated. Moreover, the direction of the movable louver 24 is adjusted so that the blowing direction of the air into the bathroom 4 becomes the set blowing direction for the cool wind operation.

[Mist sauna operation]
The mist sauna operation is an operation of spraying mist in the bathroom 4 while performing the heating operation in the bathroom 4. Specifically, the ventilation fan 9 is stopped and the circulation fan 7 is operated, and hot water is supplied from the hot water supply device 2 to the mist sauna device so that the hot air temperature at the outlet 15 is maintained within the set temperature range. As described above, the hot water is circulated and supplied to the air conditioner heat exchanger 8 by controlling the opening and closing of the thermal valve 22 and the hot water supply operation of the hot water supply device 2. As a result, the same heating operation as described above is performed. Furthermore, the opening / closing control of the water supply valve 28 for adjusting the amount of water supplied to the mist nozzle 11 and the flow rate of hot water to the heat exchanger 29 where the temperature of the water supplied to the mist nozzle 11 is raised are adjustable. The open / close control of the heat medium flow control valve 39 is performed, and the heated water is sprayed from the mist nozzle 11 into the bathroom 4 so that the mist sauna operation is performed.

[Normal driving condition and Eco driving condition]
Of the above heating operation, ventilation operation, drying operation, cool air operation, and mist sauna operation, in the heating operation, drying operation, and mist sauna operation, hot water is supplied from the hot water supply device 2 to the mist sauna device. It is necessary to generate warm air by releasing the heat of the hot water through the heat exchanger 8 for air conditioning. Therefore, the temperature of the hot water supplied from the hot water supply device 2 to the mist sauna device is important for improving the comfort and convenience of heating operation, drying operation, and mist sauna operation.
When the operation control unit 3 detects that the eco-operation switch 49 is turned on by the remote control device R during the heating operation, the drying operation, and the mist sauna operation, the operation control unit 3 sets the eco-operation state as the operation mode of the mist sauna device. Is determined to have been commanded. The eco driving switch 49 is a switch for accepting an eco driving command that is a driving command in an eco driving state that is a driving state deviating from the normal driving state. On the other hand, the operation control unit 3 normally sets the operation mode of the mist sauna device as the operation mode of the mist sauna device while the remote control device does not detect that the eco operation switch 49 is turned ON while the mist sauna operation is being performed. It is determined that the operating state has been commanded. Note that the mist sauna operation switch 41 may be used to instruct the start of the mist sauna operation later when the eco operation switch 49 is turned on first and the eco operation lamp 49a is lit.
Hereinafter, the normal operation state and the eco operation state will be described.

  When the normal operation state is instructed, the operation control unit 3 instructs the hot water supply device 2 to supply the hot water having the first temperature required by the hot water using hot air generator in the normal operation state. In the present embodiment, the first temperature is 80 ° C.

On the other hand, the mist sauna device operates in an eco-operation state in which warm water having a temperature different from the first temperature is received and warm air is generated by the warm water when an eco-operation command is received.
In the present embodiment, as shown in FIG. 2, the source of hot water supplied to the mist sauna device is the hot water storage tank 61 of the main hot water generator 2 </ b> A, and the hot water storage tank 61 collects heat from the heat source device 50. Hot water is stored. For example, as described above, when hot water having a predetermined temperature (for example, a second temperature (60 ° C.) different from the first temperature (80 ° C.)) is stored in the hot water storage tank 61, the hot water storage tank 61 removes the mist sauna. Hot water at the predetermined temperature can be supplied to the apparatus. In other words, it is ensured that the temperature of the hot water supplied to the mist sauna device is relatively high without increasing the temperature of the hot water to the first temperature (80 ° C.) by the auxiliary heat source device 2B. Therefore, although there is a possibility that comfort and convenience are insufficient, the auxiliary heat source unit 2B supplies hot water to the first temperature without raising the temperature to the first temperature, and the temperature is lower than the first temperature. Heating operation, drying operation, and mist sauna operation can be performed using hot water. As described above, the operation control unit 3 supplies hot water having a temperature that is stored in the hot water storage tank 61 to the mist sauna device without using the auxiliary heat source unit 2B in response to the eco-operation state. That is, the operation control unit 3 confirms reception of the eco operation command, outputs an operation prohibition command for the auxiliary heat source device 2B, and raises the temperature of the hot water supplied from the hot water storage tank 61 to the first temperature. When the acceptance of the eco-drive instruction is confirmed, the hot water supply device 2 is instructed to supply the hot water at the second temperature, and the hot water supply at the second temperature is supplied to the mist sauna device. The device 2 is commanded.
As described above, the mist sauna device outputs an operation prohibition command for the auxiliary heat source unit 2B when the acceptance of the eco operation command is confirmed, and commands the hot water supply device 2 to supply hot water at the second temperature, When the second temperature hot water is supplied to operate in the eco operation state and the acceptance of the eco operation command is not confirmed, the operation permission command for the auxiliary heat source machine 2B is output and the first temperature hot water is supplied. Receives and operates in normal operation.

Next, switching control between the normal operation state and the eco operation state will be described. FIG. 4 is a flowchart of switching control between the normal operation state and the eco operation state performed by the operation control unit 3.
When the heating control switch 45, the drying operation switch 44, or the mist sauna operation switch 41 is turned ON, the operation control unit 3 starts any of the heating operation, the drying operation, and the mist sauna operation. The operation state switching control shown in FIG. 4 is performed. Specifically, in step # 10, the operation control unit 3 starts supplying hot water from the hot water supply device 2 when detecting that the operation switch is turned ON. However, the operation control unit 3 stops the operation of the auxiliary heat source unit 2B. Next, in step # 12, the operation control unit 3 determines whether or not the eco operation switch 49 has been turned ON within the set time. Then, the operation control unit 3 proceeds to step # 14 when the eco-operation switch 49 is turned on, and proceeds to step # 16 when the eco-operation switch 49 is not operated.

In step # 14, the operation control unit 3 responds to the ON operation of the eco-operation switch 49 (that is, accepts the eco-operation command), as described above, hot water having a temperature different from the first temperature. The mist sauna device is operated in an eco-driving state that receives supply and generates warm air from the hot water.
On the other hand, in step # 16, the operation control unit 3 starts the operation of the auxiliary heat source unit 2B in response to the eco-operation switch 49 not being turned on (that is, receiving the normal operation command), In Step # 18, the mist sauna device is operated in a normal operation state in which hot water having the first temperature is supplied and hot air is generated by the hot water having the first temperature.

  Next, operation start control in the normal operation state and operation start control in the eco operation state will be described. FIG. 5 is a flowchart for explaining the operation start control in the normal operation state, and FIG. 7 is a flowchart for explaining the operation start control in the eco operation state.

[Operation start control in normal operation state]
As shown in FIG. 5, in step # 20, the operation control unit 3 determines whether or not the state where the detected temperature of the heat medium thermistor 5 is 58 ° C. or more continues for 5 seconds or more. That is, the heat medium thermistor 5 determines whether or not the temperature of the hot water supplied from the hot water supply device 2 to the mist sauna device is stable at least 58 ° C. or higher. The hot water is supplied to the air conditioning heat exchanger 8 and used to generate hot air, and is supplied to the heat exchanger 29 and used to raise the temperature of the mist water. That it is stable at least at 58 ° C. or more can be said that the warm water supplied from the warm water supply device 2 has a sufficient temperature for generating warm air and for heating the mist water.
The operation control unit 3 proceeds to the next step # 22 when the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher for 5 seconds or longer, and repeats step # 20 otherwise. .

  In step # 22, the operation control unit 3 operates the circulation fan 7 to generate hot air using the supplied hot water. As a result, the air sucked from the bathroom 4 is heated by the air-conditioning heat exchanger 8 and supplied from the outlet 15 into the bathroom 4, and the air in the bathroom 4 begins to be warmed. Thus, in the normal operation state, the circulating air 7 as the inside air circulation mechanism A and the heat exchanger 8 for air conditioning work to supply the inside air circulation start timing for returning the warm air into the bathroom 4 from the hot water supply device 2. It is determined based on the incoming hot water temperature which is the temperature of the hot water (that is, the temperature detected by the heat medium thermistor 5).

  Next, in step # 24, the operation control unit 3 determines whether or not the state where the temperature detected by the bathroom temperature thermistor 23 is 25 ° C. or higher continues for 5 seconds or more. That is, it is determined whether or not the air in the bathroom 4 has been sufficiently warmed. The operation control unit 3 proceeds to the next step # 26 when the state where the temperature detected by the bathroom temperature thermistor 23 is 25 ° C. or more continues for 5 seconds or more, and repeats the step # 24 otherwise. .

  Next, after waiting for 3 seconds in the step # 26, the operation control unit 3 moves to the step # 28, and the state where the temperature detected by the return temperature thermistor 56 is 60 ° C. or higher continues for 5 seconds or longer. Moves to the next step # 30, and if not, repeats step # 28. That is, that the state where the detection temperature of the return temperature thermistor 56 is 60 ° C. or more is continuous for 5 seconds or more means that the hot water after passing through the heat exchanger 29 maintains a high temperature state. This means that the temperature of the heat exchanger 29 has been sufficiently raised, and it means that the water for mist can be heated by the heat exchanger 29. As a result, the operation control unit 3 switches the mist open / close valve to the open state in the subsequent step # 30, and switches the water supply valve 28 to the open state in the step # 32, so that the water for mist passes through the heat exchanger 29 to the mist. The nozzle 11 is sprayed into the room. Thus, in the normal operation state, the mist spray start timing for spraying the mist into the room by operating the mist open / close valves 37 and 38, the water supply valve 28, the mist nozzle 11 and the heat exchanger 29 as the mist spray mechanism M It is determined based on the return hot water temperature (that is, the detection temperature of the return temperature thermistor 56), which is the temperature of the hot water returned to the supply device 2.

  In the subsequent operation in the normal operation state, the operation control unit 3 determines that the temperature of the mist ejected into the bathroom 4 (“ejection mist temperature” shown in FIG. 6) is either 75 ° C., 60 ° C., or 55 ° C. It is controlled to become. FIG. 6 is a diagram for explaining the control of the mist temperature to be ejected into the bathroom 4. In this embodiment, the mist temperature ejected to the bathroom 4 can be detected by the mist hot water thermistor 33. Further, in order to adjust the temperature of the mist water detected by the mist hot water thermistor 33 (that is, the mist temperature ejected to the bathroom 4), the operation control unit 3 controls the flow rate of the mist water flowing through the water supply channel 10. do it.

In FIG. 6, the horizontal axis indicates the target temperature of the bathroom 4 that is set in advance when the mist sauna operation is performed from the detected temperature of the bathroom 4 (detected temperature of the bathroom temperature thermistor 23) (“set bathroom temperature” in the figure). It is a value obtained by subtracting. As shown in the figure, the relationship is set such that the greater the temperature difference shown on the horizontal axis, the smaller the mist temperature that is ejected to the bathroom 4. That is, if the detected temperature of the actual bathroom 4 is higher than the set bathroom temperature, the ejection mist temperature is lowered to lower the detected temperature of the actual bathroom 4.
Specifically, if the current ejection mist temperature is 75 ° C., the operation control unit 3 directly sets the ejection mist temperature to 75 ° C. if “the detected temperature of the actual bathroom 4−the set bathroom temperature <+ 1 ° C.”. If “+ 1 ° C. ≦ the detected temperature of the actual bathroom 4−the set bathroom temperature”, the ejection mist temperature is switched to 60 ° C.
Further, when the current ejection mist temperature is 60 ° C., the operation control unit 3 directly sets the ejection mist temperature to 60 if “+ 0.5 ° C. <actual detection temperature of bathroom 4−set bathroom temperature <+ 4 ° C.”. If “+ 4 ° C ≦ actual bathroom 4 detected temperature−set bathroom temperature”, the spray mist temperature is switched to 50 ° C., and “actual bathroom 4 detected temperature−set bathroom temperature ≦ + 0.5 ° C.” ”, The spray mist temperature is switched to 75 ° C.
Alternatively, when the current ejection mist temperature is 50 ° C., the operation control unit 3 maintains the ejection mist temperature as it is at 60 ° C. if “+ 3.5 ° C. <actual detection temperature of the bathroom 4−set bathroom temperature”. If “actual detected temperature of bathroom 4−set bathroom temperature ≦ + 3.5 ° C.”, the mist temperature is switched to 60 ° C.

[Operation start control in eco-drive state]
As shown in FIG. 7, in step # 40, the operation control unit 3 determines whether or not the state where the detected temperature of the heat medium thermistor 5 is 38 ° C. or more continues for 5 seconds or more. That is, the heat medium thermistor 5 determines whether or not the temperature of the hot water supplied from the hot water supply device 2 to the mist sauna device is stable at least at 38 ° C. or more. In the eco-operation state, when the temperature of the warm water is stable at least at 38 ° C., the warm water supplied from the warm water supply device 2 generates warm air and the temperature sufficient to raise the temperature of the mist water. It is considered to have.
The operation control unit 3 proceeds to the next step # 42 when the state where the detected temperature of the heat medium thermistor 5 is 38 ° C. or more continues for 5 seconds or more, and repeats the step # 40 otherwise. .

  In step # 42, the operation control unit 3 operates the circulation fan 7 to generate hot air using the supplied hot water. As a result, the air sucked from the bathroom 4 is heated by the air-conditioning heat exchanger 8 and supplied from the outlet 15 into the bathroom 4, and the air in the bathroom 4 begins to be warmed. As described above, even in the eco operation state, similarly to the normal operation state, the inside air circulation start timing for returning the warm air into the bathroom 4 by the circulation fan 7 and the air conditioner heat exchanger 8 as the inside air circulation mechanism A working. The temperature is determined based on the incoming hot water temperature that is the temperature of the hot water supplied from the hot water supply device 2 (that is, the detected temperature of the heat medium thermistor 5).

Next, in step # 44, the operation control unit 3 proceeds to the next step # 46 when the state where the temperature detected by the return temperature thermistor 56 is 40 ° C. or higher continues for 5 seconds or more. Repeat step # 44. That is, in the eco operation state, when the temperature detected by the return temperature thermistor 56 is 40 ° C. or higher for 5 seconds or more, it is considered that the water for mist can be heated by the heat exchanger 29. ing. As a result, the operation control unit 3 switches the mist open / close valve to the open state in the subsequent step # 46, and switches the water supply valve 28 to the open state in the step # 48 so that the water for mist passes through the heat exchanger 29 to the mist. The nozzle 11 is sprayed into the room. As described above, even in the eco operation state, as in the normal operation state, the mist opening / closing valves 37 and 38 as the mist spray mechanism M, the water supply valve 28, the mist nozzle 11 and the heat exchanger 29 work to bring the mist into the room. The mist spray start timing for spraying is determined based on the return hot water temperature (that is, the temperature detected by the return temperature thermistor 56), which is the temperature of the hot water returned to the hot water supply device 2.
In the eco operation state, the operation control unit 3 assumes that the mist temperature to be ejected to the bathroom 4 (that is, the detected temperature of the mist hot water thermistor 33) is constant at 55 ° C. regardless of the actual detected temperature of the bathroom 4. Control is performed.

  As described above, in the normal operation state, the determination threshold temperature of the inside air circulation start timing is 58 ° C., and the determination threshold temperature of the mist spray start timing is 60 ° C. On the other hand, in the eco-operation state, the determination threshold temperature of the inside air circulation start timing is 38 ° C., and the determination threshold temperature of the mist spray start timing is 40 ° C. Thus, with respect to each determination threshold temperature, the determination threshold temperature in the eco-drive state is set lower than the determination threshold temperature in the normal operation state. If the determination threshold temperature is relatively low, the energy required on the hot water supply device 2 side to cause the incoming hot water temperature, which is the detected temperature of the heat medium thermistor 5, to reach the determination threshold temperature is relatively low. On the other hand, if the determination threshold temperature is relatively high, the energy required on the hot water supply device side to cause the incoming hot water temperature to reach the determination threshold temperature is relatively high. Therefore, the energy required for operating the mist sauna device in the eco operation state is set to operate the mist sauna device in the normal operation state by setting the determination threshold temperature of the eco operation state lower than the determination threshold temperature of the normal operation state. It can be made lower than the energy required for this.

  Furthermore, in the present embodiment, the operation control unit 3 starts the operation of the inside air circulation mechanism A (the circulation fan 7 and the air conditioner heat exchanger 8) in step # 22 in the normal operation state, and then the mist spray mechanism M (mist opening / closing). Before starting the operation of the valves 37 and 38, the water supply valve 28, the mist nozzle 11 and the heat exchanger 29), the return inside air temperature (the temperature detected by the bathroom temperature thermistor 23) which is the temperature of the inside air sucked from the inside of the bathroom 4 is detected. The return inside air temperature is equal to or higher than a predetermined set threshold temperature (step # 24), and the return hot water temperature (the detection temperature of the return temperature thermistor 56) is higher than the determination threshold temperature of the mist spray start timing (step # 28). As a condition, the operation of the mist spray mechanism M is started in step # 30 and step # 32. On the other hand, the operation control unit 3 operates the mist spray mechanism M in the eco operation state only on the condition that the return hot water temperature is higher than the determination threshold temperature of the mist spray start timing after the operation of the inside air circulation mechanism A is started. Has started.

Thus, in the normal operation state, the return inside air temperature is equal to or higher than the set threshold temperature and the return hot water temperature is higher than the determination threshold temperature for the mist spray start timing is set as the start condition for the mist spray operation. That is, since the return room temperature indicates the room temperature, that the return room temperature is equal to or higher than the set threshold temperature means that the indoor comfort is ensured.
Moreover, since the return warm water temperature is the temperature of the warm water that is returned to the warm water supply device after use, it is newly consumed by the inside air circulation mechanism A and the mist spray mechanism M to which the warm water is supplied out of the heat held by the warm water. When the generated heat is reduced, that is, when the temperature drop due to heat consumption in the inside air circulation mechanism A and the mist spray mechanism M is reduced, the return hot water temperature becomes relatively high. That is, the fact that the return hot water temperature can be maintained at a high temperature that is equal to or higher than the threshold temperature for determining the mist spray start timing means that the heat taken away when the temperature of the mist water is raised is reduced, that is, the mist water is reduced. It means that it is ready to be heated sufficiently. In other words, it means that a comfortable mist can be sprayed from the mist spray mechanism M.
Therefore, in the normal operation state, the indoor temperature is determined by setting the return inside air temperature to be equal to or higher than a predetermined threshold temperature and the return hot water temperature to be higher than the determination threshold temperature for the mist spray start timing. Both the comfort of the mist and the comfort of the temperature of the sprayed mist can be achieved. On the other hand, in the eco-operation state, whether or not the comfort of the indoor temperature can be ensured by only setting the return hot water temperature to be higher than the determination threshold temperature of the mist spray start timing as the mist spray operation start condition. Although it is unclear, it is possible to ensure at least the comfort of the temperature of the sprayed mist.

Second Embodiment
In a hot water utilization system including a mist sauna device and a hot water supply device, the configuration of the hot water supply device may be changed. Although the structure of another warm water supply apparatus is demonstrated below, description is abbreviate | omitted about the structure similar to the said embodiment.

FIG. 8 is a diagram illustrating a configuration of the hot water supply device.
In the present embodiment, the hot water supply device 2 includes a main hot water generating device 2A and an auxiliary heat source device 2B. The main hot water generator 2 </ b> A includes a solar heat collector 80 that obtains heat using solar heat, which is natural energy. Specifically, the heat collected by the solar heat collector 80 is transmitted to the heat medium flowing through the heat medium circulation path 82. The heat medium circulation path 82 sequentially passes through the solar heat collector 80 and the heat exchanger 84 provided in the hot water storage tank 81. In this heat exchanger 84, heat exchange is performed between the heat medium flowing through the heat medium circulation path 82 and the hot water stored in the hot water storage tank 81. That is, the main hot water generating device 2 </ b> A is configured such that the heat collected by the solar heat collector 80 is transmitted to the hot water stored in the hot water storage tank 81 in the heat exchanger 84.

Also in this embodiment, a hot water circulation pump 83 is provided in the middle of the heat medium circulation path 82, and the flow rate of the hot water in the heat medium circulation path 82 is adjusted according to the operation of the hot water circulation pump 83. Specifically, if the flow rate of the hot water in the heat medium circulation path 82 is lowered, that is, if the flow rate of the hot water passing through the solar heat collector 80 per unit time is reduced, the hot water after passing through the solar heat collector 80 is reduced. The temperature is relatively high. On the other hand, when the flow rate of the hot water in the heat medium circulation path 82 is increased, that is, when the flow rate of the hot water passing through the solar heat collector 80 per unit time is increased, the hot water after passing through the solar heat collector 80 is increased. The temperature is relatively low. For example, in the hot water storage tank 81, the operation of the hot water circulation pump 83 is controlled so that hot water of 60 ° C. is stored, and the exhaust heat recovery operation is performed.
As described above, the main hot water generating device 2A is constituted by the solar heat collector 80, which is a device that collects heat from natural energy and obtains hot water at the second temperature, thereby obtaining the hot water supply device 2 with high energy saving performance. Can do.

<Another embodiment>
<1>
In the first embodiment, in the example in which the hot water supply device 2 includes the main hot water generating device 2A and the auxiliary heat source device 2B, the heat source device 50 provided in the main hot water generating device 2A has the engine 51 as a heat source. However, the configuration can be changed as appropriate. For example, you may comprise so that the heat source apparatus 50 with which the main hot water production | generation apparatus 2A is provided has a fuel cell as a heat source.
As described above, the hot water supply device 2 only needs to be a device that collects heat discharged from a heat source machine (for example, the engine 51 or the fuel cell) to obtain hot water at the second temperature. Alternatively, as described in the third embodiment, the hot water supply device 2 may be a device that collects heat from natural energy and obtains hot water at the second temperature.

  In the above-described embodiment, the example in which the hot water supply device 2 is configured by a plurality of heat sources, that is, the main hot water generation device 2A and the auxiliary heat source device 2B, has been described, but the hot water supply device 2 may be configured by a single heat source. Good. For example, as shown in FIG. 9, the hot water supply device 2 may be configured by only the auxiliary heat source device 2B described above. In this case, the operation control unit 3 is configured so that the temperature of the hot water thermistor 74 provided in the forward path 18 downstream of the heat exchanger 73 is an appropriate temperature (for example, the first temperature and the second temperature described above). If the amount of gas and the amount of air supplied to the combustor 72 are adjusted, the mist sauna device can be operated in the above-described normal operation state and eco-operation state. In this case, in step # 10 of the flowchart shown in FIG. 4, the auxiliary heat source unit 2B is operated to generate the hot water at the second temperature, thereby starting the hot water supply from the hot water supply device 2. Can be done.

<2>
In the above-described embodiment, the example in which the operation control unit 3 performs the switching control between the normal operation state and the eco operation state based on only whether or not the eco operation switch 49 is turned on has been described. Based on this, switching control between the normal operation state and the eco operation state may be performed. As will be described below, the mist sauna device includes a heat medium thermistor 5 (an example of hot water temperature detection means) that detects the temperature of hot water supplied from the hot water supply device 2 and is detected by the heat medium thermistor 5. An operation control unit 3 (an example of an operation state switching unit) that switches the operation state between the normal operation state and the eco operation state with reference to the hot water temperature is provided. Hereinafter, switching control between the normal operation state and the eco operation state performed by the operation control unit 3 will be described.

FIG. 10 is a flowchart of switching control between the normal operation state and the eco operation state.
When the heating control switch 45, the drying operation switch 44, or the mist sauna operation switch 41 is turned ON, the operation control unit 3 starts any of the heating operation, the drying operation, and the mist sauna operation. The operation state switching control shown in FIG. 10 is performed. Specifically, in step # 50, the operation control unit 3 starts supplying hot water from the hot water supply device 2 when detecting that the operation switch is turned ON. However, the operation control unit 3 stops the operation of the auxiliary heat source unit 2B. Next, in step # 52, the operation control unit 3 determines whether or not the state in which the detected temperature of the heat medium thermistor 5 that detects the temperature of the hot water supplied from the hot water supply device 2 is 58 ° C. or more continues for 5 seconds or more. Judgment is made. Then, the operation control unit 3 proceeds to step # 54 when the state where the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher is continued for 5 seconds or more, and the detected temperature of the heat medium thermistor 5 is 58 ° C. When the above state is not continuous for 5 seconds or more, the process proceeds to step # 58.

Here, the state in which the detected temperature of the heating medium thermistor 5 is 58 ° C. or higher in step # 52 is a state in which the temperature of the heating medium thermistor 5 is 5 seconds or longer. It means that hot water of about 2 temperatures (60 ° C.) can be stably supplied.
On the other hand, the state in which the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher is not continuous for 5 seconds or more is that the second heat source device 2 does not operate when the auxiliary heat source device 2B is not operated. It means a state where hot water of temperature cannot be supplied stably. In this case, when accepting the eco operation instruction and trying to operate the hot water hot air generator in the eco operation state, the temperature of the hot water supplied from the hot water supply device is too low, so the hot water is generated using the hot water. The comfort and convenience of warm air that can be used will be very low.

  Therefore, if the state where the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher is not continuous for 5 seconds or longer, the operation control unit 3 starts the operation of the auxiliary heat source unit 2B in Step # 58. That is, since even hot water of the second temperature cannot be stably supplied from the hot water supply device 2, the operation control unit 3 forcibly supplies the auxiliary heat source device 2B regardless of whether or not the eco operation switch 49 is turned on. Is operated (step # 58), and the mist sauna device is operated in the normal operation state (step # 60). As described above, even if the eco-driving instruction is received, the mist sauna device is not operated in the eco-operating state (particularly, operated in the normal operating state), so that it is possible to avoid the generation of warm air that is very inconvenient.

  On the other hand, when the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher for 5 seconds or longer, the operation control unit 3 turns on the eco operation switch 49 within the set time in step # 54. It is determined whether or not it has been done. Then, the operation control unit 3 proceeds to step # 56 when the eco-operation switch 49 is turned on, and proceeds to step # 58 when the eco-operation switch 49 is not operated.

In step # 56, the operation control unit 3 determines that the eco-operation switch 49 is turned ON (that is, the eco-operation command is accepted), as described above, hot water having a temperature different from the first temperature. The mist sauna device is operated in an eco-driving state that receives supply and generates warm air from the hot water. In this case, since the hot water of about the second temperature (60 ° C.) or more can be stably supplied from the hot water supply device 2, the hot air generated in the mist sauna device does not significantly reduce the convenience. .
On the other hand, the operation control unit 3 operates the auxiliary heat source unit 2B in step # 58 as described above in response to the eco-operation switch 49 not being turned on (that is, receiving the normal operation command). At the same time, in step # 30, the mist sauna device is operated in a normal operation state in which warm water of the first temperature is supplied and hot air is generated by the hot water of the first temperature.

<3>
In the above-described embodiment, the example in which the special eco-operation switch 49 for receiving the eco-operation command is provided in the remote control device R as a controller capable of inputting various control commands has been described, but the special eco-operation switch is not provided. It may be a configuration. For example, FIG. 11 is a diagram illustrating a switch arrangement of a remote control device according to another embodiment. In this example, the remote control device R is not provided with a special eco-operation switch for accepting the eco-operation command. Instead, for example, when the heating operation switch 45 is turned on again while the heating operation is performed, the operation control unit 3 determines that the ON operation is an input of the eco operation command. Similarly, when the drying operation switch 44 or the mist sauna operation switch 41 is turned ON again while the drying operation or the mist sauna operation is performed, the operation control unit 3 performs the ON operation by inputting an eco operation command. Judge that there is. And the driving | operation control part 3 will light the eco driving | operation lamp 49a, if an eco driving | operation instruction | indication is received, and notifies a user that the mist sauna apparatus is operated in the eco driving state.

<4>
In the said embodiment, although demonstrated by exemplifying the temperature of warm water, the temperature mentioned above can be changed suitably. For example, although 80 degreeC was mentioned as an example of 1st temperature and 60 degreeC was mentioned as an example of 2nd temperature, you may employ | adopt other temperature as 1st temperature and 2nd temperature.

  INDUSTRIAL APPLICABILITY The present invention can be used for a mist sauna device that can be operated according to the intention of a user with high energy saving awareness.

2 Hot water supply equipment 2A Main hot water generation equipment 2B Auxiliary heat source unit 4 Bathroom (space to be dried)
7 Circulating fan (Circulation mechanism A)
8 Heat exchanger for air conditioning (Internal air circulation mechanism A)
11 Mist nozzle (Mist spray mechanism M)
28 Water supply valve (mist spray mechanism M)
29 Heat exchanger (mist spray mechanism M)
37 Mist open / close valve (mist spray mechanism M)
38 Mist open / close valve (mist spray mechanism M)
49 Eco-operation switch 50 Heat source device 61 Hot water storage tank 80 Solar collector A Inside air circulation mechanism M Mist spray mechanism R Remote control device (controller)

  The present invention relates to a mist sauna device, specifically, an inside air circulation mechanism that sucks in the inside air from the room and performs an operation of warming the inside air with warm water supplied from a hot water supply device and returning it to the room as warm air; A mist spray mechanism that performs an operation of spraying the mist water heated by the hot water supplied from the hot water supply device into the room as a mist, and supplies hot water at the first temperature based on an operation command input to the controller. The hot water supply device is commanded, and the supplied hot water is used to operate in the normal air circulation mechanism and the mist spray mechanism. The internal air circulation mechanism works to return the hot air to the room. The inside air circulation start timing is determined based on the incoming hot water temperature, which is the temperature of the hot water supplied from the hot water supply device, and the mist spray mechanism works to spray the mist indoors. The mist spray start timing relates to a mist sauna apparatus for determining based on the return temperature of hot water is a temperature of the hot water back to the hot water supply device.

  There is a hot water generating hot air generator that receives hot water of a predetermined temperature from outside and generates hot air using the hot water. In particular, a typical example of this type of hot water generating hot air generator is a mist sauna device. It has been known. The mist sauna device has a mist sauna function in the bathroom. Normally, such a mist sauna device operates by receiving supply of high-temperature hot water (80 ° C.) from a water heater that burns fuel and generates hot water by the combustion heat. Examples of hot water sources include those that use hot water obtained by recovering exhaust heat exhausted from heat source equipment such as engines and fuel cells, and that collect hot energy from natural energy such as solar heat to produce hot water. Some use it.

In the case of a system that recovers and uses the former waste heat as hot water, generally, the exhaust heat discharged from the heat source machine is recovered as hot water of about 60 ° C., and the hot water is stored in a hot water storage tank. And it is utilized by the mist sauna apparatus side by paying out warm water timely as needed. In this system, the temperature of the hot water stored in the hot water storage tank is lower than the original required temperature (80 ° C) of the mist sauna device, so the temperature is raised to the required temperature by an auxiliary heat source provided separately and supplied to the mist sauna device. A configuration is adopted.
Even when using the warm water obtained by the latter heat collection, if the temperature of the warm water is lower than the required temperature of the mist sauna device, the temperature is raised by a device such as an auxiliary heat source device and supplied.

  Patent Document 1 also describes a hot water supply device that includes a main hot water generating device that generates hot water and an auxiliary heat source device that can further heat the hot water generated by the main hot water generating device. As an auxiliary heat source machine, what heats up warm water with the combustion heat of a combustor is described. And in this warm water supply apparatus, the warm water produced | generated by operating at least an auxiliary heat source machine is supplied to an air conditioning use, a hot water supply, and a bath use.

JP 2001-296055 A

However, the temperature of the hot water required to operate the mist sauna device is set from the viewpoint of ensuring sufficient comfort for the equipment user. It is often hot water temperature.
Such hot water temperature on the high temperature side is set as the lowest temperature for operating the mist sauna device in the most stable and comfortable state. However, for example, if the user who uses the mist sauna device can tolerate a little inconvenience from the viewpoint of energy saving, it is better to be able to operate according to the user's intention.
Furthermore, as described in Patent Document 1, at least in the case of adopting a system that collects the exhaust heat as warm water or a system that uses the collected heat as warm water as a warm water supply device, The auxiliary heat source unit will be operated to consume fuel, and this will be reversed from the viewpoint of energy saving. That is, it is preferable from the viewpoint of energy saving to use the hot water originally generated or held as it is without operating the auxiliary heat source machine.

  This invention is made | formed in view of said subject, The objective is to provide the mist sauna apparatus which can be drive | operated according to the intention of the user with high energy saving consciousness.

The characteristic configuration of the mist sauna device according to the present invention for achieving the above object is that a circulation fan capable of sucking air from the room through the air inlet and blowing the sucked room air into the room through the air outlet, and hot water By having the air conditioner heat exchanger capable of performing heat exchange between the hot water supplied from the supply device through the heat medium circulation path and the air sucked from the room by the circulation fan, the air is sucked from the room, The hot air supplied from the hot water supply device warms the sucked indoor air and returns it to the room as hot air , and the hot water supply device supplies the hot medium through the heat medium circulation path. comprising a mist sprayer structure for performing the operation of spraying the chamber warmed mist water by the hot water as a mist,
Based on the operation command input to the controller, the hot water supply device is instructed to supply the hot water at the first temperature, and the supplied hot water is used for the operation of the internal air circulation mechanism and the operation of the mist spray mechanism. Configured to operate in normal operating conditions,
The inside air circulation start timing for returning the warm air to the room by working the inside air circulation mechanism is determined based on the incoming hot water temperature which is the temperature of the hot water supplied from the hot water supply device,
A mist sauna device that determines a mist spray start timing at which the mist spray mechanism works to spray the mist indoors based on a return hot water temperature that is a temperature of hot water to be returned to the hot water supply device,
The controller includes an eco-drive switch that accepts an eco-drive command that is a drive command in an eco-drive state,
When the eco operation command is accepted, the hot water supply device is commanded to supply hot water having a second temperature lower than the first temperature, and the supplied hot water is used to operate the internal air circulation mechanism and the mist spray. It is configured to be operable in the eco-driving state used for the mechanism operation,
The determination threshold temperature of the inside air circulation start timing and the determination threshold temperature of the mist spray start timing are different between the normal operation state and the eco operation state,
For each of the determination threshold temperatures, the determination threshold temperature of the eco driving state is set lower than the determination threshold temperature of the normal driving state ,
The hot water supply device collects heat discharged from a heat source device or generates heat using a solar heat collector that obtains heat using solar heat, and generates heat by consuming fuel. An auxiliary heat source capable of further heating the hot water generated by the main hot water generator with the heat,
Corresponding to the normal operation state, hot water heated to the first temperature by the auxiliary heat source machine is supplied,
Corresponding to the eco-operation state, hot water having the second temperature generated by the main hot water generating device is supplied without operating the auxiliary heat source machine .

According to the above characteristic configuration, when the eco-driving instruction is not accepted, the mist sauna device is required in the normal operation state, that is, the first set in advance in consideration of the comfort for the mist sauna application. The hot water of temperature is received from the hot water supply device, the hot water is generated using the heat of the hot water of the first temperature, and the water for mist is heated, so that the temperature of the mist sauna is high in comfort. Hot air and mist can be generated and supplied to the bathroom.
On the other hand, when the eco-driving instruction is received, the mist sauna device receives the supply of hot water having a second temperature lower than the first temperature from the hot water supply device, and warms the hot water with the second temperature. Wind is generated and mist water is heated. That is, the warm air and mist generated using the heat of the hot water at the second temperature lower than the first temperature required in the normal operation state are the warm air and mist generated using the heat of the hot water at the first temperature. Although the comfort as a mist sauna application becomes lower than that, energy saving performance becomes higher. Therefore, the mist sauna operation can be performed while ensuring a certain level of comfort while placing importance on energy saving.

Further, when the inside air circulation start timing is reached, it is allowed to operate the inside air circulation mechanism to supply warm air into the room. In order to determine that the internal air circulation start timing has been reached, it is necessary that the incoming hot water temperature has reached the determination threshold temperature of the internal air circulation start timing. Similarly, when the mist spray start timing is reached, it is allowed to perform an operation of spraying mist indoors by operating the mist spray mechanism. In order to determine that the mist spray start timing has been reached, it is necessary that the return hot water temperature has reached the determination threshold temperature for the mist spray start timing.
That is, if the determination threshold temperature is relatively low, the energy required on the hot water supply device side to cause the incoming hot water temperature to reach the determination threshold temperature is relatively low. On the other hand, if the determination threshold temperature is relatively high, the energy required on the hot water supply device side to cause the incoming hot water temperature to reach the determination threshold temperature is relatively high. Therefore, the energy required for operating the mist sauna device in the eco operation state is set to operate the mist sauna device in the normal operation state by setting the determination threshold temperature of the eco operation state lower than the determination threshold temperature of the normal operation state. It can be made lower than the energy required for this.
Therefore, it is possible to provide a mist sauna device that can be operated according to the intention of a user with high energy saving awareness.

In addition, the main hot water generator can obtain hot water at the second temperature by using a solar heat collector that collects heat discharged from the heat source device or obtains heat using solar heat. In the normal operation state, the hot water at the second temperature is raised to the first temperature using the auxiliary heat source device and then supplied to the mist sauna device. In the eco operation state, the hot water at the second temperature is used as it is without using the auxiliary heat source device. Is supplied to the mist sauna apparatus at the temperature of (i.e., the second temperature). That is, since the auxiliary heat source unit is not used in the eco-operation state, the energy consumption of the auxiliary heat source unit that has been generated in the normal operation state can be reduced. Moreover, energy-saving property can be improved by effectively using the heat collected by the solar heat collector.

Another characteristic configuration of the mist sauna device according to the present invention is the return that is the temperature of the air sucked from the room after the operation of the inside air circulation mechanism and before the operation of the mist spray mechanism in the normal operation state. An inside air temperature is detected, and the operation of the mist spray mechanism is started on the condition that the return inside air temperature is equal to or higher than a predetermined set threshold temperature and the return hot water temperature is higher than a determination threshold temperature of the mist spray start timing. In the eco operation state, after the operation of the inside air circulation mechanism is started, the operation of the mist spray mechanism is started only on the condition that the return hot water temperature is higher than the determination threshold temperature of the mist spray start timing. .

According to the above characteristic configuration, in the normal operation state, the return inside air temperature is equal to or higher than the set threshold temperature and the return hot water temperature is higher than the determination threshold temperature for the mist spray start timing is set as the start condition for the mist spray operation. That is, since the return room temperature indicates the room temperature, that the return room temperature is equal to or higher than the set threshold temperature means that the indoor comfort is ensured.
In addition, since the return hot water temperature is the temperature of the hot water that is returned to the hot water supply device after use, when the heat that is newly consumed by the mist spray mechanism is reduced among the heat that the hot water has, that is, the mist spray. When the temperature drop due to heat consumption in the mechanism becomes small, the return hot water temperature becomes relatively high. That is, the fact that the return hot water temperature can be maintained at a high temperature that is equal to or higher than the threshold temperature for determining the mist spray start timing means that the heat taken away when the temperature of the mist water is raised is reduced, that is, the mist water is reduced. It means that it is ready to be heated sufficiently. In other words, it means that a comfortable mist can be sprayed from the mist spray mechanism.
Therefore, in the normal operation state, the indoor temperature is determined by setting the return inside air temperature to be equal to or higher than a predetermined threshold temperature and the return hot water temperature to be higher than the determination threshold temperature for the mist spray start timing. Both the comfort of the mist and the comfort of the temperature of the sprayed mist can be achieved. On the other hand, in the eco-operation state, whether or not the comfort of the indoor temperature can be ensured by only setting the return hot water temperature to be higher than the determination threshold temperature of the mist spray start timing as the mist spray operation start condition. Although it is unclear, it is possible to ensure at least the comfort of the temperature of the sprayed mist.

Still another characteristic configuration of the mist sauna apparatus according to the present invention is that the main hot water generator recovers heat discharged from the heat source unit or uses the solar heat to obtain heat by the solar heat collector. The hot water of the second temperature is obtained and stored in the hot water storage tank, and the hot water of the second temperature is supplied from the hot water storage tank upon receipt of the hot water supply command.

According to the said characteristic structure, the main warm water production | generation apparatus can obtain warm water of 2nd temperature with the solar-heat collector which collect | recovers the heat | fever discharged | emitted from a heat-source equipment, or uses solar heat. As a result, the hot water at the second temperature can be supplied from the hot water supply device to the mist sauna device without operating the auxiliary heat source device. Further, the hot water at the second temperature is temporarily stored in the hot water storage tank, and the hot water at the second temperature is supplied in accordance with the demand timing of the hot water, so that the hot water can be effectively used.

It is a figure which shows the structure of a hot water utilization system. It is a figure which shows the structure of the hot water supply apparatus of 1st Embodiment. It is a figure explaining switch arrangement of a remote control device. It is a flowchart of switching control of the normal operation state and eco-operation state of 1st Embodiment. It is a flowchart explaining the driving | operation start control in a normal driving | running state. It is a figure explaining control of the mist temperature made to eject to a bathroom. Flow chart explaining driving start control in eco-driving state It is a figure which shows the structure of the hot water supply apparatus of 2nd Embodiment. It is a figure which shows the structure of the hot water supply apparatus of another embodiment. It is a flowchart of switching control of a normal driving state and an ecological driving state. It is a figure explaining switch arrangement of a remote control device of another embodiment.

<First Embodiment>
Hereinafter, the mist sauna apparatus of 1st Embodiment is demonstrated with reference to drawings.
FIG. 1 is a diagram illustrating a configuration of a hot water use system including a mist sauna device and a hot water supply device. FIG. 2 is a diagram illustrating a configuration of the hot water supply device.
The mist sauna device sucks the inside air from the inside of the bathroom 4, warms the inside air with the hot water supplied from the hot water supply device 2, and returns to the bathroom 4 as hot air, and the hot water supply A mist spray mechanism M that performs an operation of spraying the mist water heated by the hot water supplied from the device 2 into the bathroom 4 as mist is provided. Then, the mist sauna device instructs the hot water supply device 2 to supply hot water at the first temperature based on the operation command input to the remote control device R as a controller capable of inputting various control commands, and supplies the hot water supply device 2. The received warm water is configured to be operable in a normal operation state in which the warm air circulating mechanism A and the mist spray mechanism M are used. In addition, the mist sauna apparatus demonstrated by this embodiment is implement | achieved as one function of the bathroom heating dryer which can implement each operation of heating operation of a bathroom, ventilation operation, drying operation, cool air operation, and mist sauna operation. is there.

  A specific configuration example of the mist sauna device will be described. The device body 1 of the mist sauna device heats the air that is ventilated by the circulation fan 7 for circulating and circulating the air in the bathroom 4 and the circulation fan 7. An air conditioning heat exchanger 8, a ventilation fan 9 for ventilating the bathroom 4, and two mist nozzles 11 for jetting mist water supplied through the water supply passage 10 into the bathroom 4 in a mist form are provided in the main body casing 12. Equipped with equipment. The apparatus main body 1 is disposed behind the ceiling of the bathroom 4. The grill plate 13 is installed below the main body casing 12 so as to be positioned on the surface side of the ceiling of the bathroom 4 with the main body casing 12 entering the back side of the ceiling plate 6 of the bathroom 4.

The grill plate 13 is provided with an air inlet 14 and an air outlet 15 in parallel. A circulation ventilation path 16 is formed in the main body casing 12 for sucking air in the bathroom 4 through the air inlet 14 and blowing it out through the air outlet 15. The circulation fan 7 is provided in the circulation ventilation path 16 in such a state that the air in the bathroom 4 sucked to the air inlet 14 and sucked from the air inlet 14 is blown out from the air outlet 15 into the bathroom 4. It has been. Further, an air conditioning heat exchanger 8 is provided in the circulation ventilation path 16 upstream of the circulation fan 7 in the ventilation direction, and heat exchange with the hot water circulated and supplied from the hot water supply device 2 is performed in the circulation ventilation path 16. It is comprised so that the air which ventilates may be heated. In this way, the mist sauna device sucks air in the bathroom 4 through the air inlet 14 by the ventilation action of the circulation fan 7, heats it with the heat exchanger 8 for air conditioning, and blows it into the bathroom 4 through the outlet 15. Thus, the heating operation for heating the inside of the bathroom 4 can be executed.
That is, in this embodiment, the circulation fan 7 and the heat exchanger 8 for air conditioning suck the inside air from the bathroom 4 as a space to be dried, warm the inside air with warm water, and return it to the bathroom 4 as hot air. It functions as a circulation mechanism A.

The forward path 18 of the heat medium circulation path 17 to which hot water is supplied from the hot water supply device 2 installed outside the bathroom 4 is branched into two heat medium branch paths 19 and 20. One of the heating medium branch paths 20 is connected to the air conditioning heat exchanger 8, and the downstream side of the air conditioning heat exchanger 8 in the heating medium branch path 20 is connected to the return path 21 of the heating medium circulation path 17. The hot water heated by the hot water supply device 2 is circulated and supplied to the air conditioner heat exchanger 8 through the heat medium circulation path 17. In the middle of the heat medium branch path 20, a thermal valve 22 is provided that can freely and intermittently supply hot water to the air conditioner heat exchanger 8 by opening and closing the flow path of the heat medium branch path 20.
The other heat medium branch path 19 is provided with a heat medium flow rate adjustment valve 39 that can freely connect / disconnect the heat medium branch path 19 and change and adjust the flow rate of hot water to the heat exchanger 29.
In addition, the forward path 18 of the heat medium circulation path 17 is provided with a heat medium thermistor 5 as hot water temperature detection means for detecting the temperature of the flowing hot water. A return temperature thermistor 56 that detects the temperature of hot water that is used to raise the temperature of the mist water in the heat exchanger 29 and then returned to the hot water supply device 2 is provided in the heat medium branch path 19 on the downstream side of the heat exchanger 29. It has been.

  A bathroom temperature thermistor 23 that detects the temperature of the flowing air as the temperature in the bathroom 4 is provided at a location upstream of the air conditioning heat exchanger 8 in the circulation ventilation path 16. The blower outlet 15 is provided with a movable louver 24 that is oscillated and driven by an electric motor (not shown), and the movable louver 24 can change the blowing direction of the air blown into the bathroom 4 from the blower outlet 15. .

The ventilation fan 9 is provided in the main body casing 12 so as to exhaust the air in the bathroom 4 sucked from the air inlet 14 to the outside through the exhaust duct 25. Due to the ventilation action of the ventilation fan 9, the air in the bathroom 4 is discharged to the outside through the exhaust duct 25, and the bathroom 4 is ventilated.
Two mist nozzles 11 are supported at a portion of the grill plate 13 between the air inlet 14 and the air outlet 15 with the hot water jetting direction downward.

  A hot water generating unit 26 for generating hot water for mist and supplying it to the mist nozzle 11 is provided on the upper portion of the main casing 12. The hot water generating unit 26 supplies hot water to a mist casing 27 through which a mist water is supplied from a water supply or the like, a water supply valve 28 that opens and closes the water supply passage 10, and mist water supplied from the water supply path 10. A heat exchanger 29 that is heated by heat exchange with the hot water circulated and supplied from the device 2, a lower-side passage 30 through which water for mist supplied from the water supply channel 10 and heated by the heat exchanger 29 flows, A drainage valve 32 that opens and closes the flow path of the drainage channel 31 branched from the lower side flow path 30, a hot water thermistor 33 for mist that detects the temperature of hot water flowing through the lower side flow path 30, and the like are provided.

  A mist supply path 34 different from the drainage path 31 is branched from the lower side flow path 30, and the mist supply path 34 is piped in a state extending to the inside of the main body casing 12. The mist supply path 34 is further branched into two branch paths 35 and 36 along the path, and these branch paths 35 and 36 are connected to the mist nozzles 11, respectively. The two branch passages 35 and 36 are provided with mist opening and closing valves 37 and 38, respectively, that can freely and intermittently supply hot water to the mist nozzles 11 by opening and closing the passages.

As described above, the water for mist supplied from the water supply passage 10 is heated by the heat exchanger 29, and the heated warm water is supplied to the mist nozzle 11 through the lower side passage 30 and the mist supply passage 34. It is comprised so that the mist operation which ejects warm water in the mist form from the mist nozzle 11 in the bathroom 4 can be performed.
In other words, in the present embodiment, the mist open / close valves 37 and 38, the water supply valve 28, the mist nozzle 11 and the heat exchanger 29 are provided in the bathroom 4 with the mist water heated by the hot water supplied from the hot water supply device 2 as mist. It functions as a mist spray mechanism M that performs an operation of spraying.

  When the mist sauna operation has not been performed for a long time since the last time the mist sauna operation was performed, the drainage channel 31 is contaminated that has accumulated in the water supply channel 10 or the internal piping of the heat exchanger 29. It is for discharging water for mist to the outside. The drainage treatment using the drainage channel 31 is performed by switching the water supply valve 28 and the drainage valve 32 to the open state while maintaining the mist open / close valves 37 and 38 in the closed state.

Next, the configuration of the hot water supply device 2 will be described with reference to FIG.
In the present embodiment, the hot water supply device 2 includes a main hot water generating device 2A and an auxiliary heat source device 2B. The main hot water generator 2 </ b> A includes a heat source device 50 and a heat storage device 60. The heat source device 50 includes an engine 51 and a generator 52 driven by the engine 51. The electricity generated by the generator 52 is supplied to a power consuming device (not shown).

  The engine 51 is configured to be cooled by engine cooling water. In the present embodiment, the engine coolant circulates through the engine 51 and the heat exchanger 53 in order through the coolant circulation path 54. A cooling water pump 55 is provided in the middle of the cooling water circulation path 54, and the flow rate of the engine cooling water in the cooling water circulation path 54 is adjusted according to the operation of the cooling water pump 55. In the heat exchanger 53, heat is transferred from the engine cooling water to the hot water by exchanging heat between the relatively low-temperature hot water described later and the engine cooling water.

  The heat storage device 60 has a hot water storage tank 61 that collects and stores the exhaust heat from the heat source device 50. The hot water storage tank 61 stores hot water, which is heated by the heat exchanger 53 through the hot water circulating hot water circulation path 62 and returns to the hot water storage tank 61 again. In the present embodiment, the hot water storage tank 61 stores hot water having a relatively high temperature in the upper part thereof, and stores hot water having a relatively low temperature in the lower part thereof so that temperature stratification is formed inside the hot water storage tank 61. It is configured. A hot water circulation pump 63 is provided in the hot water hot water circulation path 62, and the flow rate of the hot water in the hot water hot water circulation path 62 is adjusted according to the operation of the hot water circulation pump 63. Specifically, if the flow rate of the hot water in the hot water circulation path 62 for hot water storage is reduced, that is, if the flow rate of the hot water passing through the heat exchanger 53 per unit time is reduced, the temperature of the hot water after passing through the heat exchanger 53 Is relatively high. On the other hand, if the flow rate of the hot water in the hot water circulation path 62 for hot water storage is increased, that is, if the flow rate of the hot water passing through the heat exchanger 53 per unit time is increased, the temperature of the hot water after passing through the heat exchanger 53 Is relatively low. For example, in the hot water storage tank 61, the operation of the hot water circulation pump 63 is controlled so that hot water of 60 ° C. is stored, and the exhaust heat recovery operation is performed.

  The auxiliary heat source unit 2B is a device that consumes fuel to generate heat and raises the temperature of the hot water with the heat. The auxiliary heat source unit 2B includes a combustor 72 that combusts gas as fuel, a flow rate adjustment valve 70 that adjusts the amount of gas supplied to the combustor 72, and a blower 71 that supplies oxygen (air) to the combustor 72. Is provided. Further, the forward path 18 of the heat medium circulation path 17 through which the hot water sent from the hot water storage tank 61 by the hot water delivery pump 64 flows is drawn into the auxiliary heat source machine 2B. The forward path 18 of the heat medium circulation path 17 flows through the inside of the heat exchanger 73 provided in the auxiliary heat source unit 2B. Further, the heat exchanger 73 is given combustion heat generated in the combustor 72. As a result, the temperature of the hot water flowing through the forward path 18 of the heat medium circulation path 17 is raised by the combustion heat generated in the combustor 72. The amount of heat given from the combustor 72 to the hot water flowing in the forward path 18 of the heat medium circulation path 17 changes according to the amount of combustion heat generated in the combustor 72. That is, by adjusting the amount of gas and the amount of air supplied to the combustor 72, the amount of heat applied to the hot water flowing in the forward path 18 of the heat medium circulation path 17 can be adjusted. For example, the amount of gas and the amount of air supplied to the combustor 72 are adjusted so that the temperature of the hot water thermistor 74 provided in the outward path 18 downstream of the heat exchanger 73 becomes a predetermined temperature.

  FIG. 3 is a diagram illustrating the switch arrangement of the remote control device. The remote controller R as a controller of the present invention includes a timer display unit 40 for displaying a timer time for driving, a mist sauna driving switch 41 for instructing mist sauna driving, and a timer setting switch for changing and setting the driving timer time. 42, a wind direction switch 43 for instructing a change in the blowing direction of the movable louver 24, a drying operation switch 44 for instructing a drying operation, a heating operation switch 45 for instructing a heating operation for heating the bathroom 4, and a ventilation for operating the ventilation fan 9 A ventilation operation switch 46 for instructing operation, a cool air operation switch 47 for instructing cool air operation for operating the circulation fan 7, a stop switch 48 for stopping each operation, and the like are provided. Further, as will be described later, the remote control device R is provided with an eco-operation switch 49 for giving an operation command in an eco-operation state that is an operation state deviating from the normal operation state.

  In addition, various lamps that are turned on when the operation switches 41, 44, 45, 46, 47, 49 are in the ON operation state (mist sauna operation lamp 41a, drying operation lamp 44a, heating operation lamp 45a, ventilation operation lamp) 46a, a cool wind operation lamp 47a, and an eco operation lamp 49a) are provided adjacent to the operation switches.

  Hereinafter, the heating operation, ventilation operation, drying operation, cool air operation, and mist sauna operation of the mist sauna device will be briefly described.

[Heating operation]
The heating operation of the mist sauna device is an operation in which air in the bathroom 4 is taken in and heated, and then the heated air is blown into the bathroom 4. Specifically, the ventilation fan 9 is stopped and the circulation fan 7 is operated, and hot water is supplied from the hot water supply device 2 to the mist sauna device so that the hot air temperature at the outlet 15 is maintained within the set temperature range. As described above, the hot water is circulated and supplied to the air conditioner heat exchanger 8 by controlling the opening and closing of the thermal valve 22 and the hot water supply operation of the hot water supply device 2. As a result, the circulating air heated by the air conditioner heat exchanger 8 is blown into the bathroom 4 from the blowout port 15. As described above, the mist sauna device generates warm air by receiving the supply of hot water from the hot water supply device 2 in the heating operation. Further, the operation state of the circulation fan 7 is adjusted so that the ventilation amount of the air ventilated in the bathroom 4 becomes the ventilation amount for heating, and the movable louver 24 is swung.

[Ventilation operation]
The ventilation operation is an operation in which air sucked from the bathroom 4 is exhausted from the exhaust duct 25. Specifically, the ventilation fan 9 is operated while the operation of the circulation fan 7 is stopped and the thermal valve 22 is kept closed. Further, the operating state is adjusted so that the movable louver 24 is closed.

[Dry operation]
The drying operation is performed, for example, while discharging a part of the air sucked from the inside of the bathroom 4 as a drying space in which a drying object such as clothes containing moisture is arranged after taking a bath to the outside through the exhaust duct 25. In this operation, the remaining air is heated by the air conditioner heat exchanger 8 and then blown into the bathroom 4 from the outlet 15. Specifically, the thermal valve is operated so that the circulating fan 7 is operated and hot water is supplied from the hot water supply device 2 to the mist sauna device so that the hot air temperature at the outlet 15 is maintained within the set temperature range. The hot water supply operation of the hot water supply device 2 is controlled by opening and closing 22 to circulate and supply the hot water to the air conditioner heat exchanger 8 and to operate the ventilation fan 9.

(Cool wind driving)
The cool air operation is an operation in which the air sucked from the bathroom 4 is blown out into the bathroom 4 through the circulation ventilation path 16 without being heated. Specifically, the circulation fan 7 is operated with the thermal valve 22 kept closed, and the ventilation fan 9 is operated so that a part of the air sucked from inside the bathroom 4 is taken outdoors through the exhaust duct 25. In this operation, the remaining air is blown out into the bathroom 4 through the circulation ventilation path 16 without being heated. Moreover, the direction of the movable louver 24 is adjusted so that the blowing direction of the air into the bathroom 4 becomes the set blowing direction for the cool wind operation.

[Mist sauna operation]
The mist sauna operation is an operation of spraying mist in the bathroom 4 while performing the heating operation in the bathroom 4. Specifically, the ventilation fan 9 is stopped and the circulation fan 7 is operated, and hot water is supplied from the hot water supply device 2 to the mist sauna device so that the hot air temperature at the outlet 15 is maintained within the set temperature range. As described above, the hot water is circulated and supplied to the air conditioner heat exchanger 8 by controlling the opening and closing of the thermal valve 22 and the hot water supply operation of the hot water supply device 2. As a result, the same heating operation as described above is performed. Furthermore, the opening / closing control of the water supply valve 28 for adjusting the amount of water supplied to the mist nozzle 11 and the flow rate of hot water to the heat exchanger 29 where the temperature of the water supplied to the mist nozzle 11 is raised are adjustable. The open / close control of the heat medium flow control valve 39 is performed, and the heated water is sprayed from the mist nozzle 11 into the bathroom 4 so that the mist sauna operation is performed.

[Normal driving condition and Eco driving condition]
Of the above heating operation, ventilation operation, drying operation, cool air operation, and mist sauna operation, in the heating operation, drying operation, and mist sauna operation, hot water is supplied from the hot water supply device 2 to the mist sauna device. It is necessary to generate warm air by releasing the heat of the hot water through the heat exchanger 8 for air conditioning. Therefore, the temperature of the hot water supplied from the hot water supply device 2 to the mist sauna device is important for improving the comfort and convenience of heating operation, drying operation, and mist sauna operation.
When the operation control unit 3 detects that the eco-operation switch 49 is turned on by the remote control device R during the heating operation, the drying operation, and the mist sauna operation, the operation control unit 3 sets the eco-operation state as the operation mode of the mist sauna device. Is determined to have been commanded. The eco driving switch 49 is a switch for accepting an eco driving command that is a driving command in an eco driving state that is a driving state deviating from the normal driving state. On the other hand, the operation control unit 3 normally sets the operation mode of the mist sauna device as the operation mode of the mist sauna device while the remote control device does not detect that the eco operation switch 49 is turned ON while the mist sauna operation is being performed. It is determined that the operating state has been commanded. Note that the mist sauna operation switch 41 may be used to instruct the start of the mist sauna operation later when the eco operation switch 49 is turned on first and the eco operation lamp 49a is lit.
Hereinafter, the normal operation state and the eco operation state will be described.

  When the normal operation state is instructed, the operation control unit 3 instructs the hot water supply device 2 to supply the hot water having the first temperature required by the hot water using hot air generator in the normal operation state. In the present embodiment, the first temperature is 80 ° C.

On the other hand, the mist sauna device operates in an eco-operation state in which warm water having a temperature different from the first temperature is received and warm air is generated by the warm water when an eco-operation command is received.
In the present embodiment, as shown in FIG. 2, the source of hot water supplied to the mist sauna device is the hot water storage tank 61 of the main hot water generator 2 </ b> A, and the hot water storage tank 61 collects heat from the heat source device 50. Hot water is stored. For example, as described above, when hot water having a predetermined temperature (for example, a second temperature (60 ° C.) different from the first temperature (80 ° C.)) is stored in the hot water storage tank 61, the hot water storage tank 61 removes the mist sauna. Hot water at the predetermined temperature can be supplied to the apparatus. In other words, it is ensured that the temperature of the hot water supplied to the mist sauna device is relatively high without increasing the temperature of the hot water to the first temperature (80 ° C.) by the auxiliary heat source device 2B. Therefore, although there is a possibility that comfort and convenience are insufficient, the auxiliary heat source unit 2B supplies hot water to the first temperature without raising the temperature to the first temperature, and the temperature is lower than the first temperature. Heating operation, drying operation, and mist sauna operation can be performed using hot water. As described above, the operation control unit 3 supplies hot water having a temperature that is stored in the hot water storage tank 61 to the mist sauna device without using the auxiliary heat source unit 2B in response to the eco-operation state. That is, the operation control unit 3 confirms reception of the eco operation command, outputs an operation prohibition command for the auxiliary heat source device 2B, and raises the temperature of the hot water supplied from the hot water storage tank 61 to the first temperature. When the acceptance of the eco-drive instruction is confirmed, the hot water supply device 2 is instructed to supply the hot water at the second temperature, and the hot water supply at the second temperature is supplied to the mist sauna device. The device 2 is commanded.
As described above, the mist sauna device outputs an operation prohibition command for the auxiliary heat source unit 2B when the acceptance of the eco operation command is confirmed, and commands the hot water supply device 2 to supply hot water at the second temperature, When the second temperature hot water is supplied to operate in the eco operation state and the acceptance of the eco operation command is not confirmed, the operation permission command for the auxiliary heat source machine 2B is output and the first temperature hot water is supplied. Receives and operates in normal operation.

Next, switching control between the normal operation state and the eco operation state will be described. FIG. 4 is a flowchart of switching control between the normal operation state and the eco operation state performed by the operation control unit 3.
When the heating control switch 45, the drying operation switch 44, or the mist sauna operation switch 41 is turned ON, the operation control unit 3 starts any of the heating operation, the drying operation, and the mist sauna operation. The operation state switching control shown in FIG. 4 is performed. Specifically, in step # 10, the operation control unit 3 starts supplying hot water from the hot water supply device 2 when detecting that the operation switch is turned ON. However, the operation control unit 3 stops the operation of the auxiliary heat source unit 2B. Next, in step # 12, the operation control unit 3 determines whether or not the eco operation switch 49 has been turned ON within the set time. Then, the operation control unit 3 proceeds to step # 14 when the eco-operation switch 49 is turned on, and proceeds to step # 16 when the eco-operation switch 49 is not operated.

In step # 14, the operation control unit 3 responds to the ON operation of the eco-operation switch 49 (that is, accepts the eco-operation command), as described above, hot water having a temperature different from the first temperature. The mist sauna device is operated in an eco-driving state that receives supply and generates warm air from the hot water.
On the other hand, in step # 16, the operation control unit 3 starts the operation of the auxiliary heat source unit 2B in response to the eco-operation switch 49 not being turned on (that is, receiving the normal operation command), In Step # 18, the mist sauna device is operated in a normal operation state in which hot water having the first temperature is supplied and hot air is generated by the hot water having the first temperature.

  Next, operation start control in the normal operation state and operation start control in the eco operation state will be described. FIG. 5 is a flowchart for explaining the operation start control in the normal operation state, and FIG. 7 is a flowchart for explaining the operation start control in the eco operation state.

[Operation start control in normal operation state]
As shown in FIG. 5, in step # 20, the operation control unit 3 determines whether or not the state where the detected temperature of the heat medium thermistor 5 is 58 ° C. or more continues for 5 seconds or more. That is, the heat medium thermistor 5 determines whether or not the temperature of the hot water supplied from the hot water supply device 2 to the mist sauna device is stable at least 58 ° C. or higher. The hot water is supplied to the air conditioning heat exchanger 8 and used to generate hot air, and is supplied to the heat exchanger 29 and used to raise the temperature of the mist water. That it is stable at least at 58 ° C. or more can be said that the warm water supplied from the warm water supply device 2 has a sufficient temperature for generating warm air and for heating the mist water.
The operation control unit 3 proceeds to the next step # 22 when the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher for 5 seconds or longer, and repeats step # 20 otherwise. .

  In step # 22, the operation control unit 3 operates the circulation fan 7 to generate hot air using the supplied hot water. As a result, the air sucked from the bathroom 4 is heated by the air-conditioning heat exchanger 8 and supplied from the outlet 15 into the bathroom 4, and the air in the bathroom 4 begins to be warmed. Thus, in the normal operation state, the circulating air 7 as the inside air circulation mechanism A and the heat exchanger 8 for air conditioning work to supply the inside air circulation start timing for returning the warm air into the bathroom 4 from the hot water supply device 2. It is determined based on the incoming hot water temperature which is the temperature of the hot water (that is, the temperature detected by the heat medium thermistor 5).

  Next, in step # 24, the operation control unit 3 determines whether or not the state where the temperature detected by the bathroom temperature thermistor 23 is 25 ° C. or higher continues for 5 seconds or more. That is, it is determined whether or not the air in the bathroom 4 has been sufficiently warmed. The operation control unit 3 proceeds to the next step # 26 when the state where the temperature detected by the bathroom temperature thermistor 23 is 25 ° C. or more continues for 5 seconds or more, and repeats the step # 24 otherwise. .

  Next, after waiting for 3 seconds in the step # 26, the operation control unit 3 moves to the step # 28, and the state where the temperature detected by the return temperature thermistor 56 is 60 ° C. or higher continues for 5 seconds or longer. Moves to the next step # 30, and if not, repeats step # 28. That is, that the state where the detection temperature of the return temperature thermistor 56 is 60 ° C. or more is continuous for 5 seconds or more means that the hot water after passing through the heat exchanger 29 maintains a high temperature state. This means that the temperature of the heat exchanger 29 has been sufficiently raised, and it means that the water for mist can be heated by the heat exchanger 29. As a result, the operation control unit 3 switches the mist open / close valve to the open state in the subsequent step # 30, and switches the water supply valve 28 to the open state in the step # 32, so that the water for mist passes through the heat exchanger 29 to the mist. The nozzle 11 is sprayed into the room. Thus, in the normal operation state, the mist spray start timing for spraying the mist into the room by operating the mist open / close valves 37 and 38, the water supply valve 28, the mist nozzle 11 and the heat exchanger 29 as the mist spray mechanism M It is determined based on the return hot water temperature (that is, the detection temperature of the return temperature thermistor 56), which is the temperature of the hot water returned to the supply device 2.

  In the subsequent operation in the normal operation state, the operation control unit 3 determines that the temperature of the mist ejected into the bathroom 4 (“ejection mist temperature” shown in FIG. 6) is either 75 ° C., 60 ° C., or 55 ° C. It is controlled to become. FIG. 6 is a diagram for explaining the control of the mist temperature to be ejected into the bathroom 4. In this embodiment, the mist temperature ejected to the bathroom 4 can be detected by the mist hot water thermistor 33. Further, in order to adjust the temperature of the mist water detected by the mist hot water thermistor 33 (that is, the mist temperature ejected to the bathroom 4), the operation control unit 3 controls the flow rate of the mist water flowing through the water supply channel 10. do it.

In FIG. 6, the horizontal axis indicates the target temperature of the bathroom 4 that is set in advance when the mist sauna operation is performed from the detected temperature of the bathroom 4 (detected temperature of the bathroom temperature thermistor 23) (“set bathroom temperature” in the figure). It is a value obtained by subtracting. As shown in the figure, the relationship is set such that the greater the temperature difference shown on the horizontal axis, the smaller the mist temperature that is ejected to the bathroom 4. That is, if the detected temperature of the actual bathroom 4 is higher than the set bathroom temperature, the ejection mist temperature is lowered to lower the detected temperature of the actual bathroom 4.
Specifically, if the current ejection mist temperature is 75 ° C., the operation control unit 3 directly sets the ejection mist temperature to 75 ° C. if “the detected temperature of the actual bathroom 4−the set bathroom temperature <+ 1 ° C.”. If “+ 1 ° C. ≦ the detected temperature of the actual bathroom 4−the set bathroom temperature”, the ejection mist temperature is switched to 60 ° C.
Further, when the current ejection mist temperature is 60 ° C., the operation control unit 3 directly sets the ejection mist temperature to 60 if “+ 0.5 ° C. <actual detection temperature of bathroom 4−set bathroom temperature <+ 4 ° C.”. If “+ 4 ° C ≦ actual bathroom 4 detected temperature−set bathroom temperature”, the spray mist temperature is switched to 50 ° C., and “actual bathroom 4 detected temperature−set bathroom temperature ≦ + 0.5 ° C.” ”, The spray mist temperature is switched to 75 ° C.
Alternatively, when the current ejection mist temperature is 50 ° C., the operation control unit 3 maintains the ejection mist temperature as it is at 60 ° C. if “+ 3.5 ° C. <actual detection temperature of the bathroom 4−set bathroom temperature”. If “actual detected temperature of bathroom 4−set bathroom temperature ≦ + 3.5 ° C.”, the mist temperature is switched to 60 ° C.

[Operation start control in eco-drive state]
As shown in FIG. 7, in step # 40, the operation control unit 3 determines whether or not the state where the detected temperature of the heat medium thermistor 5 is 38 ° C. or more continues for 5 seconds or more. That is, the heat medium thermistor 5 determines whether or not the temperature of the hot water supplied from the hot water supply device 2 to the mist sauna device is stable at least at 38 ° C. or more. In the eco-operation state, when the temperature of the warm water is stable at least at 38 ° C., the warm water supplied from the warm water supply device 2 generates warm air and the temperature sufficient to raise the temperature of the mist water. It is considered to have.
The operation control unit 3 proceeds to the next step # 42 when the state where the detected temperature of the heat medium thermistor 5 is 38 ° C. or more continues for 5 seconds or more, and repeats the step # 40 otherwise. .

  In step # 42, the operation control unit 3 operates the circulation fan 7 to generate hot air using the supplied hot water. As a result, the air sucked from the bathroom 4 is heated by the air-conditioning heat exchanger 8 and supplied from the outlet 15 into the bathroom 4, and the air in the bathroom 4 begins to be warmed. As described above, even in the eco operation state, similarly to the normal operation state, the inside air circulation start timing for returning the warm air into the bathroom 4 by the circulation fan 7 and the air conditioner heat exchanger 8 as the inside air circulation mechanism A working. The temperature is determined based on the incoming hot water temperature that is the temperature of the hot water supplied from the hot water supply device 2 (that is, the detected temperature of the heat medium thermistor 5).

Next, in step # 44, the operation control unit 3 proceeds to the next step # 46 when the state where the temperature detected by the return temperature thermistor 56 is 40 ° C. or higher continues for 5 seconds or more. Repeat step # 44. That is, in the eco operation state, when the temperature detected by the return temperature thermistor 56 is 40 ° C. or higher for 5 seconds or more, it is considered that the water for mist can be heated by the heat exchanger 29. ing. As a result, the operation control unit 3 switches the mist open / close valve to the open state in the subsequent step # 46, and switches the water supply valve 28 to the open state in the step # 48 so that the water for mist passes through the heat exchanger 29 to the mist. The nozzle 11 is sprayed into the room. As described above, even in the eco operation state, as in the normal operation state, the mist opening / closing valves 37 and 38 as the mist spray mechanism M, the water supply valve 28, the mist nozzle 11 and the heat exchanger 29 work to bring the mist into the room. The mist spray start timing for spraying is determined based on the return hot water temperature (that is, the temperature detected by the return temperature thermistor 56), which is the temperature of the hot water returned to the hot water supply device 2.
In the eco operation state, the operation control unit 3 assumes that the mist temperature to be ejected to the bathroom 4 (that is, the detected temperature of the mist hot water thermistor 33) is constant at 55 ° C. regardless of the actual detected temperature of the bathroom 4. Control is performed.

  As described above, in the normal operation state, the determination threshold temperature of the inside air circulation start timing is 58 ° C., and the determination threshold temperature of the mist spray start timing is 60 ° C. On the other hand, in the eco-operation state, the determination threshold temperature of the inside air circulation start timing is 38 ° C., and the determination threshold temperature of the mist spray start timing is 40 ° C. Thus, with respect to each determination threshold temperature, the determination threshold temperature in the eco-drive state is set lower than the determination threshold temperature in the normal operation state. If the determination threshold temperature is relatively low, the energy required on the hot water supply device 2 side to cause the incoming hot water temperature, which is the detected temperature of the heat medium thermistor 5, to reach the determination threshold temperature is relatively low. On the other hand, if the determination threshold temperature is relatively high, the energy required on the hot water supply device side to cause the incoming hot water temperature to reach the determination threshold temperature is relatively high. Therefore, the energy required for operating the mist sauna device in the eco operation state is set to operate the mist sauna device in the normal operation state by setting the determination threshold temperature of the eco operation state lower than the determination threshold temperature of the normal operation state. It can be made lower than the energy required for this.

  Furthermore, in the present embodiment, the operation control unit 3 starts the operation of the inside air circulation mechanism A (the circulation fan 7 and the air conditioner heat exchanger 8) in step # 22 in the normal operation state, and then the mist spray mechanism M (mist opening / closing). Before starting the operation of the valves 37 and 38, the water supply valve 28, the mist nozzle 11 and the heat exchanger 29), the return inside air temperature (the temperature detected by the bathroom temperature thermistor 23) which is the temperature of the inside air sucked from the inside of the bathroom 4 is detected. The return inside air temperature is equal to or higher than a predetermined set threshold temperature (step # 24), and the return hot water temperature (the detection temperature of the return temperature thermistor 56) is higher than the determination threshold temperature of the mist spray start timing (step # 28). As a condition, the operation of the mist spray mechanism M is started in step # 30 and step # 32. On the other hand, the operation control unit 3 operates the mist spray mechanism M in the eco operation state only on the condition that the return hot water temperature is higher than the determination threshold temperature of the mist spray start timing after the operation of the inside air circulation mechanism A is started. Has started.

Thus, in the normal operation state, the return inside air temperature is equal to or higher than the set threshold temperature and the return hot water temperature is higher than the determination threshold temperature for the mist spray start timing is set as the start condition for the mist spray operation. That is, since the return room temperature indicates the room temperature, that the return room temperature is equal to or higher than the set threshold temperature means that the indoor comfort is ensured.
Moreover, since the return warm water temperature is the temperature of the warm water that is returned to the warm water supply device after use, it is newly consumed by the inside air circulation mechanism A and the mist spray mechanism M to which the warm water is supplied out of the heat held by the warm water. When the generated heat is reduced, that is, when the temperature drop due to heat consumption in the inside air circulation mechanism A and the mist spray mechanism M is reduced, the return hot water temperature becomes relatively high. That is, the fact that the return hot water temperature can be maintained at a high temperature that is equal to or higher than the threshold temperature for determining the mist spray start timing means that the heat taken away when the temperature of the mist water is raised is reduced, that is, the mist water is reduced. It means that it is ready to be heated sufficiently. In other words, it means that a comfortable mist can be sprayed from the mist spray mechanism M.
Therefore, in the normal operation state, the indoor temperature is determined by setting the return inside air temperature to be equal to or higher than a predetermined threshold temperature and the return hot water temperature to be higher than the determination threshold temperature for the mist spray start timing. Both the comfort of the mist and the comfort of the temperature of the sprayed mist can be achieved. On the other hand, in the eco-operation state, whether or not the comfort of the indoor temperature can be ensured by only setting the return hot water temperature to be higher than the determination threshold temperature of the mist spray start timing as the mist spray operation start condition. Although it is unclear, it is possible to ensure at least the comfort of the temperature of the sprayed mist.

Second Embodiment
In a hot water utilization system including a mist sauna device and a hot water supply device, the configuration of the hot water supply device may be changed. Although the structure of another warm water supply apparatus is demonstrated below, description is abbreviate | omitted about the structure similar to the said embodiment.

FIG. 8 is a diagram illustrating a configuration of the hot water supply device.
In the present embodiment, the hot water supply device 2 includes a main hot water generating device 2A and an auxiliary heat source device 2B. The main hot water generator 2 </ b> A includes a solar heat collector 80 that obtains heat using solar heat, which is natural energy. Specifically, the heat collected by the solar heat collector 80 is transmitted to the heat medium flowing through the heat medium circulation path 82. The heat medium circulation path 82 sequentially passes through the solar heat collector 80 and the heat exchanger 84 provided in the hot water storage tank 81. In this heat exchanger 84, heat exchange is performed between the heat medium flowing through the heat medium circulation path 82 and the hot water stored in the hot water storage tank 81. That is, the main hot water generating device 2 </ b> A is configured such that the heat collected by the solar heat collector 80 is transmitted to the hot water stored in the hot water storage tank 81 in the heat exchanger 84.

Also in this embodiment, a hot water circulation pump 83 is provided in the middle of the heat medium circulation path 82, and the flow rate of the hot water in the heat medium circulation path 82 is adjusted according to the operation of the hot water circulation pump 83. Specifically, if the flow rate of the hot water in the heat medium circulation path 82 is lowered, that is, if the flow rate of the hot water passing through the solar heat collector 80 per unit time is reduced, the hot water after passing through the solar heat collector 80 is reduced. The temperature is relatively high. On the other hand, when the flow rate of the hot water in the heat medium circulation path 82 is increased, that is, when the flow rate of the hot water passing through the solar heat collector 80 per unit time is increased, the hot water after passing through the solar heat collector 80 is increased. The temperature is relatively low. For example, in the hot water storage tank 81, the operation of the hot water circulation pump 83 is controlled so that hot water of 60 ° C. is stored, and the exhaust heat recovery operation is performed.
As described above, the main hot water generating device 2A is constituted by the solar heat collector 80, which is a device that collects heat from natural energy and obtains hot water at the second temperature, thereby obtaining the hot water supply device 2 with high energy saving performance. Can do.

<Another embodiment>
<1>
In the first embodiment, in the example in which the hot water supply device 2 includes the main hot water generating device 2A and the auxiliary heat source device 2B, the heat source device 50 provided in the main hot water generating device 2A has the engine 51 as a heat source. However, the configuration can be changed as appropriate. For example, you may comprise so that the heat source apparatus 50 with which the main hot water production | generation apparatus 2A is provided has a fuel cell as a heat source.
As described above, the hot water supply device 2 only needs to be a device that collects heat discharged from a heat source machine (for example, the engine 51 or the fuel cell) to obtain hot water at the second temperature. Alternatively, as described in the third embodiment, the hot water supply device 2 may be a device that collects heat from natural energy and obtains hot water at the second temperature.

  In the above-described embodiment, the example in which the hot water supply device 2 is configured by a plurality of heat sources, that is, the main hot water generation device 2A and the auxiliary heat source device 2B, has been described, but the hot water supply device 2 may be configured by a single heat source. Good. For example, as shown in FIG. 9, the hot water supply device 2 may be configured by only the auxiliary heat source device 2B described above. In this case, the operation control unit 3 is configured so that the temperature of the hot water thermistor 74 provided in the forward path 18 downstream of the heat exchanger 73 is an appropriate temperature (for example, the first temperature and the second temperature described above). If the amount of gas and the amount of air supplied to the combustor 72 are adjusted, the mist sauna device can be operated in the above-described normal operation state and eco-operation state. In this case, in step # 10 of the flowchart shown in FIG. 4, the auxiliary heat source unit 2B is operated to generate the hot water at the second temperature, thereby starting the hot water supply from the hot water supply device 2. Can be done.

<2>
In the above-described embodiment, the example in which the operation control unit 3 performs the switching control between the normal operation state and the eco operation state based on only whether or not the eco operation switch 49 is turned on has been described. Based on this, switching control between the normal operation state and the eco operation state may be performed. As will be described below, the mist sauna device includes a heat medium thermistor 5 (an example of hot water temperature detection means) that detects the temperature of hot water supplied from the hot water supply device 2 and is detected by the heat medium thermistor 5. An operation control unit 3 (an example of an operation state switching unit) that switches the operation state between the normal operation state and the eco operation state with reference to the hot water temperature is provided. Hereinafter, switching control between the normal operation state and the eco operation state performed by the operation control unit 3 will be described.

FIG. 10 is a flowchart of switching control between the normal operation state and the eco operation state.
When the heating control switch 45, the drying operation switch 44, or the mist sauna operation switch 41 is turned ON, the operation control unit 3 starts any of the heating operation, the drying operation, and the mist sauna operation. The operation state switching control shown in FIG. 10 is performed. Specifically, in step # 50, the operation control unit 3 starts supplying hot water from the hot water supply device 2 when detecting that the operation switch is turned ON. However, the operation control unit 3 stops the operation of the auxiliary heat source unit 2B. Next, in step # 52, the operation control unit 3 determines whether or not the state in which the detected temperature of the heat medium thermistor 5 that detects the temperature of the hot water supplied from the hot water supply device 2 is 58 ° C. or more continues for 5 seconds or more. Judgment is made. Then, the operation control unit 3 proceeds to step # 54 when the state where the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher is continued for 5 seconds or more, and the detected temperature of the heat medium thermistor 5 is 58 ° C. When the above state is not continuous for 5 seconds or more, the process proceeds to step # 58.

Here, the state in which the detected temperature of the heating medium thermistor 5 is 58 ° C. or higher in step # 52 is a state in which the temperature of the heating medium thermistor 5 is 5 seconds or longer. It means that hot water of about 2 temperatures (60 ° C.) can be stably supplied.
On the other hand, the state in which the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher is not continuous for 5 seconds or more is that the second heat source device 2 does not operate when the auxiliary heat source device 2B is not operated. It means a state where hot water of temperature cannot be supplied stably. In this case, when accepting the eco operation instruction and trying to operate the hot water hot air generator in the eco operation state, the temperature of the hot water supplied from the hot water supply device is too low, so the hot water is generated using the hot water. The comfort and convenience of warm air that can be used will be very low.

  Therefore, if the state where the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher is not continuous for 5 seconds or longer, the operation control unit 3 starts the operation of the auxiliary heat source unit 2B in Step # 58. That is, since even hot water of the second temperature cannot be stably supplied from the hot water supply device 2, the operation control unit 3 forcibly supplies the auxiliary heat source device 2B regardless of whether or not the eco operation switch 49 is turned on. Is operated (step # 58), and the mist sauna device is operated in the normal operation state (step # 60). As described above, even if the eco-driving instruction is received, the mist sauna device is not operated in the eco-operating state (particularly, operated in the normal operating state), so that it is possible to avoid the generation of warm air that is very inconvenient.

  On the other hand, when the detected temperature of the heat medium thermistor 5 is 58 ° C. or higher for 5 seconds or longer, the operation control unit 3 turns on the eco operation switch 49 within the set time in step # 54. It is determined whether or not it has been done. Then, the operation control unit 3 proceeds to step # 56 when the eco-operation switch 49 is turned on, and proceeds to step # 58 when the eco-operation switch 49 is not operated.

In step # 56, the operation control unit 3 determines that the eco-operation switch 49 is turned ON (that is, the eco-operation command is accepted), as described above, hot water having a temperature different from the first temperature. The mist sauna device is operated in an eco-driving state that receives supply and generates warm air from the hot water. In this case, since the hot water of about the second temperature (60 ° C.) or more can be stably supplied from the hot water supply device 2, the hot air generated in the mist sauna device does not significantly reduce the convenience. .
On the other hand, the operation control unit 3 operates the auxiliary heat source unit 2B in step # 58 as described above in response to the eco-operation switch 49 not being turned on (that is, receiving the normal operation command). At the same time, in step # 30, the mist sauna device is operated in a normal operation state in which warm water of the first temperature is supplied and hot air is generated by the hot water of the first temperature.

<3>
In the above-described embodiment, the example in which the special eco-operation switch 49 for receiving the eco-operation command is provided in the remote control device R as a controller capable of inputting various control commands has been described, but the special eco-operation switch is not provided. It may be a configuration. For example, FIG. 11 is a diagram illustrating a switch arrangement of a remote control device according to another embodiment. In this example, the remote control device R is not provided with a special eco-operation switch for accepting the eco-operation command. Instead, for example, when the heating operation switch 45 is turned on again while the heating operation is performed, the operation control unit 3 determines that the ON operation is an input of the eco operation command. Similarly, when the drying operation switch 44 or the mist sauna operation switch 41 is turned ON again while the drying operation or the mist sauna operation is performed, the operation control unit 3 performs the ON operation by inputting an eco operation command. Judge that there is. And the driving | operation control part 3 will light the eco driving | operation lamp 49a, if an eco driving | operation instruction | indication is received, and notifies a user that the mist sauna apparatus is operated in the eco driving state.

<4>
In the said embodiment, although demonstrated by exemplifying the temperature of warm water, the temperature mentioned above can be changed suitably. For example, although 80 degreeC was mentioned as an example of 1st temperature and 60 degreeC was mentioned as an example of 2nd temperature, you may employ | adopt other temperature as 1st temperature and 2nd temperature.

  INDUSTRIAL APPLICABILITY The present invention can be used for a mist sauna device that can be operated according to the intention of a user with high energy saving awareness.

2 Hot water supply equipment 2A Main hot water generation equipment 2B Auxiliary heat source unit 4 Bathroom (space to be dried)
7 Circulating fan (Circulation mechanism A)
8 Heat exchanger for air conditioning (Internal air circulation mechanism A)
11 Mist nozzle (Mist spray mechanism M)
28 Water supply valve (mist spray mechanism M)
29 Heat exchanger (mist spray mechanism M)
37 Mist open / close valve (mist spray mechanism M)
38 Mist open / close valve (mist spray mechanism M)
49 Eco-operation switch 50 Heat source device 61 Hot water storage tank 80 Solar collector A Inside air circulation mechanism M Mist spray mechanism R Remote control device (controller)

Claims (6)

An inside air circulation mechanism that sucks in the inside air from the room and warms the inside air with warm water supplied from a hot water supply device and returns it to the room as warm air, and warms with warm water supplied from the hot water supply device A mist spray mechanism that performs an operation of spraying the water for mist as a mist into the room,
Based on the operation command input to the controller, the hot water supply device is instructed to supply the hot water at the first temperature, and the supplied hot water is used for the operation of the internal air circulation mechanism and the operation of the mist spray mechanism. Configured to operate in normal operating conditions,
The inside air circulation start timing for returning the warm air to the room by working the inside air circulation mechanism is determined based on the incoming hot water temperature which is the temperature of the hot water supplied from the hot water supply device,
A mist sauna device that determines a mist spray start timing at which the mist spray mechanism works to spray the mist indoors based on a return hot water temperature that is a temperature of hot water to be returned to the hot water supply device,
The controller includes an eco-drive switch that accepts an eco-drive command that is a drive command in an eco-drive state,
When the eco operation command is accepted, the hot water supply device is commanded to supply hot water having a second temperature lower than the first temperature, and the supplied hot water is used to operate the internal air circulation mechanism and the mist spray. It is configured to be operable in the eco-driving state used for the mechanism operation,
The determination threshold temperature of the inside air circulation start timing and the determination threshold temperature of the mist spray start timing are different between the normal operation state and the eco operation state,
The mist sauna apparatus in which the determination threshold temperature of the eco-operation state is set lower than the determination threshold temperature of the normal operation state with respect to each of the determination threshold temperatures. In the normal operation state, after the operation of the internal air circulation mechanism is started and before the operation of the mist spray mechanism is started, a return internal air temperature that is the temperature of the internal air sucked from the room is detected, and the return internal air temperature is set to a predetermined setting The operation of the mist spray mechanism is started on the condition that the temperature of the return hot water is higher than a threshold temperature and the return hot water temperature is higher than the determination threshold temperature of the mist spray start timing,
2. The operation of the mist spray mechanism is started under the condition that the return hot water temperature is higher than a determination threshold temperature of the mist spray start timing after the inside air circulation mechanism is started in the eco operation state. The described mist sauna device. The hot water supply device includes a main hot water generating device that generates hot water and an auxiliary heat source device that can further heat the hot water generated by the main hot water generating device,
Corresponding to the normal operation state, hot water heated to the first temperature by the auxiliary heat source machine is supplied,
The mist sauna device according to claim 1 or 2, wherein hot water having the second temperature generated by the main hot water generating device is supplied without operating the auxiliary heat source device in response to the eco-operation state.   The mist sauna apparatus according to claim 3, wherein the main hot water generating device is a device that obtains the hot water at the second temperature by collecting heat discharged from a heat source device or collecting heat from natural energy.   The main hot water generating device stores the hot water having the second temperature obtained by collecting heat discharged from a heat source device or collecting heat from natural energy in a hot water storage tank, and upon receipt of a hot water supply command, The mist sauna apparatus according to claim 3, wherein the mist sauna apparatus is a device that supplies hot water having the second temperature from a hot water storage tank. The mist sauna apparatus according to claim 1 or 2, wherein the hot water supply device is a device that generates and supplies hot water at the first temperature or the second temperature with heat generated by fuel combustion.

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