JP6688668B2 - Bathroom air conditioner - Google Patents

Description

  The technique disclosed in this specification relates to a bathroom air conditioner.

  The bathroom air conditioner disclosed in Patent Document 1 includes a gas-liquid heat exchanger, a liquid-liquid heat exchanger that is connected in parallel to the gas-liquid heat exchanger, and a heat medium that sends a heat medium to the gas-liquid heat exchanger. Sending water to the liquid-liquid heat exchanger, and a heat-medium outward path, a second heat-medium outward path that branches from the first heat-medium outward path and sends a part of the heat medium that flows through the first heat-medium outward path to the liquid-liquid heat exchanger. A first water supply channel is provided. In addition, the bathroom air conditioner includes a mist nozzle and a second water supply passage that sends water from the liquid-liquid heat exchanger to the mist nozzle. The bathroom air conditioner detects the temperature of the first heat medium valve that opens and closes the first heat medium outward path, the second heat medium valve that opens and closes the second heat medium outward path, and the temperature of the heat medium flowing through the first heat medium outward path. The heating medium temperature sensor, the mist valve for opening and closing the second water supply passage, the bathroom temperature sensor for detecting the temperature in the bathroom, and the control means. This bathroom air conditioner can perform mist operation. In the mist operation, the gas-liquid heat exchanger heats the air sent into the bathroom by the heat medium sent to the gas-liquid heat exchanger by the first heat medium outward path. Further, the liquid-liquid heat exchanger heats the water sent to the liquid-liquid heat exchanger by the first water supply path by the heat medium sent to the liquid-liquid heat exchanger by the second heat medium outward path. Moreover, the mist nozzle sprays the water sent from the liquid-liquid heat exchanger to the mist nozzle through the second water supply passage into a mist into the bathroom.

  In the bathroom air conditioner of Patent Document 1, the control means opens the first heat medium valve and the second heat medium valve while keeping the mist valve closed at the start of the mist operation. When the first heat medium valve is opened, the heat medium flows through the first heat medium outward path and is sent to the gas-liquid heat exchanger. When the second heat medium valve is opened, the heat medium flows through the second heat medium outward path and is sent to the liquid-liquid heat exchanger.

  Further, the control means then opens the mist valve when the temperature in the bathroom detected by the bathroom temperature sensor reaches a predetermined reference bathroom temperature. When the mist valve is opened, water is sent from the liquid heat exchanger to the mist nozzle, and mist-like water is sprayed from the mist nozzle into the bathroom.

  In the bathroom air conditioner of Patent Document 1, both the first heat medium valve and the second heat medium valve are opened at the start of the mist operation, and the heat medium is present in both the gas-liquid heat exchanger and the liquid-liquid heat exchanger. Sent. In the gas-liquid heat exchanger, the heating medium heats air, and in the liquid-liquid heat exchanger, the heating medium heats water. Therefore, in the bathroom air conditioner of Patent Document 1, both the air and the water are heated by the heat medium immediately after the start of the mist operation.

JP, 2006-071143, A

  In the bathroom air conditioner of Patent Document 1, the heat medium is sent to both the gas-liquid heat exchanger and the liquid-liquid heat exchanger at the start of the mist operation, and immediately after the start of the mist operation, both air and water are simultaneously heated by the heat medium. Be heated. Therefore, the heat of the heat medium is wasted in the liquid-liquid heat exchanger. That is, in a bathroom air conditioner capable of performing mist operation, it is not necessary to heat the water with the liquid-liquid heat exchanger immediately after the start of mist operation, but the liquid-liquid heat exchanger does not need to be heated until the mist-like water is sprayed into the bathroom. Water may be heated with a heat exchanger. Therefore, when water is heated in the liquid-liquid heat exchanger in the previous stage, the heat of the heat medium is wastefully wasted in the liquid-liquid heat exchanger.

  Therefore, the present specification provides a technique in which the heat of the heat medium is not wasted by the heat released from the liquid-liquid heat exchanger.

The bathroom air conditioner disclosed in this specification includes a gas-liquid heat exchanger, a liquid-liquid heat exchanger that is connected in parallel to the gas-liquid heat exchanger, and a first heat medium that sends a heat medium to the gas-liquid heat exchanger. An outward path, a first heat medium return path for returning the heat medium from the gas-liquid heat exchanger, and a part of the heat medium flowing through the first heat medium outward path branching from the first heat medium outward path, and a part of the liquid medium heat exchanger To the second heat medium return path to be sent to the first heat medium return path and to return the heat medium from the liquid-liquid heat exchanger to the second heat medium return path, and to the first heat medium to the liquid-liquid heat exchanger It has a waterway. In addition, the bathroom air conditioner includes a mist nozzle and a second water supply passage that sends water from the liquid-liquid heat exchanger to the mist nozzle. Further, the bathroom air conditioner includes a first heat medium valve that opens and closes the first heat medium outward path or the first heat medium return path, a second heat medium valve that opens and closes the second heat medium outward path or the second heat medium return path, and a first heat medium valve. 1 Heat medium temperature sensor that detects the temperature of the heat medium flowing through the heat medium outward path, a mist valve that opens and closes the first water supply path or the second water supply path, a bathroom temperature sensor that detects the temperature in the bathroom, and gas-liquid heat A circulation fan for circulating air between the exchanger and the bathroom and a control means are provided. This bathroom air conditioner can perform mist operation. In the mist operation, the gas-liquid heat exchanger heats the air sent into the bathroom by the heat medium sent to the gas-liquid heat exchanger by the first heat medium outward path, and the liquid-liquid heat exchanger uses the first water path. The water sent to the liquid-liquid heat exchanger is heated by the heat medium sent to the liquid-liquid heat exchanger through the second heat medium outward path, and the mist nozzle is changed from the liquid-liquid heat exchanger to the mist nozzle by the second water path. The water sent to is made into a mist and sprayed in the bathroom. The control means performs a process of opening the first heat medium valve with the second heat medium valve and the mist valve closed at the start of the mist operation , and with the circulation fan stopped, and a heat medium temperature sensor. When the detected temperature of the heat medium reaches a predetermined reference heat medium temperature, the process of driving the circulation fan is executed in this order, and in the mist operation, the process of driving the circulation fan is executed and then the bathroom temperature sensor The process of opening the second heat medium valve and the process of opening the mist valve when the temperature in the bathroom detected by the temperature reaches the predetermined first reference bathroom temperature and the process of opening the mist valve are executed in this order. Is configured.

  According to such a configuration, at the start of the mist operation, the second heat medium valve is in the closed state, so that the heat medium in the second heat medium outward path does not flow. Therefore, at the start of the mist operation, the heat medium is not sent to the liquid-liquid heat exchanger. When the control means opens the first heat medium valve in this state, the heat medium in the first heat medium outward path flows and the heat medium is sent to the gas-liquid heat exchanger. As described above, according to the above configuration, the heat medium can be sent to the gas-liquid heat exchanger in a state where the heat medium is not sent to the liquid-liquid heat exchanger. Therefore, at the start of the mist operation, the heat medium can be concentrated and sent to the gas-liquid heat exchanger without being sent to the liquid-liquid heat exchanger, and heat is wasted due to heat radiation from the heat medium in the liquid-liquid heat exchanger. It can prevent consumption. In this case, although there is heat dissipation from the heat medium in the gas-liquid heat exchanger, heat dissipation in the gas-liquid heat exchanger is used for subsequent heating in the bathroom, so heat is wasted. There is no end. After that, the control means opens the second heat medium valve when the temperature of the heat medium detected by the heat medium temperature sensor reaches a predetermined reference heat medium temperature, and then opens the mist valve. As a result, the heat medium can be sent to the liquid-liquid heat exchanger after the temperature of the heat medium has risen, and the water sent to the mist nozzle can be heated by the heat medium.

  As described above, according to the above configuration, the heat medium is first sent only to the gas-liquid heat exchanger, and then the heat medium is sent to the liquid-liquid heat exchanger, so that heat is radiated from the liquid-liquid heat exchanger. The heat of the heat medium is not wasted.

  According to such a configuration, since the circulation fan is stopped at the start of the mist operation, air does not circulate between the bathroom and the gas-liquid heat exchanger before the heat medium becomes high in temperature. Therefore, low-temperature air that has not been heated so much by the gas-liquid heat exchanger is not sent into the bathroom. After that, when the temperature of the heat medium detected by the heat medium temperature sensor reaches the reference heat medium temperature, the circulation fan is driven. Thereby, the air heated by the high-temperature heat medium can be sent into the bathroom, and the warm air can be sent into the bathroom.

  With such a configuration, the heat medium can be sent to the liquid-liquid heat exchanger after the temperature in the bathroom detected by the bathroom temperature sensor reaches the first reference bathroom temperature. Therefore, until the temperature in the bathroom rises, the heat medium can be concentrated and sent only to the gas-liquid heat exchanger without sending the heat medium to the liquid-liquid heat exchanger. Thereby, the air sent into the bathroom can be preferentially heated by the gas-liquid heat exchanger until the temperature in the bathroom rises. Then, after the air in the bathroom has warmed up, the heat medium can be sent to the liquid-liquid heat exchanger. Then, in the liquid-liquid heat exchanger, the water to be sent to the mist nozzle is heated by the heat medium. As described above, first, the air to be sent into the bathroom is preferentially heated by the gas-liquid heat exchanger, so that the temperature rising rate in the bathroom can be increased.

  Further, in the above bathroom air conditioner, the control means, in the mist operation, the temperature in the bathroom detected by the bathroom temperature sensor after executing the process of driving the circulation fan is higher than the first reference bathroom temperature. It may be configured to execute the process of opening the mist valve when the second reference bathroom temperature is reached.

  With such a configuration, it is possible to send water from the liquid-liquid heat exchanger to the mist nozzle after the temperature in the bathroom detected by the bathroom temperature sensor reaches the second reference bathroom temperature. Therefore, mist-like water can be sprayed into the bathroom after the temperature in the bathroom becomes high.

  In the above bathroom air conditioner, the control means performs the process of opening the mist valve in the mist operation when the predetermined time elapses after the process of opening the second heat medium valve. It may be configured.

  With such a configuration, even if the temperature in the bathroom detected by the bathroom temperature sensor cannot be used for control by the controller, the temperature in the bathroom rises after the second heat medium valve is opened. It is possible to secure the time to do. Then, after the temperature in the bathroom becomes high, water can be sent from the liquid-liquid heat exchanger to the mist nozzle. Therefore, mist-like water can be sprayed into the bathroom after the temperature in the bathroom becomes high.

It is a figure which shows schematic structure of the bathroom air conditioner and gas heat source machine of an Example. It is a flow chart which shows the processing of the 1st example which a controller performs. 6 is a timing chart of the processing of the first embodiment. It is a flow chart which shows processing of other examples which a controller performs. It is a flow chart which shows the processing of the 2nd example which a controller performs. It is a timing chart of the processing of the second embodiment. 7 is a timing chart of processing of a conventional technique.

  As shown in FIG. 1, the bathroom air conditioner 1 according to the embodiment is used by being connected to a gas heat source device 100. Therefore, first, the configuration of the gas heat source device 100 will be described. The gas heat source device 100 includes a cistern 101, a gas burner 102, and a heat exchanger 103. The gas heat source device 100 also includes a heating heat medium passage 104, a feeding heat medium passage 105, a returning heat medium passage 106, and a pump 107.

  The cistern 101 stores a heat medium inside. As the heat medium, for example, water or antifreeze can be used. The gas burner 102 burns gas to heat the heat exchanger 103. The heat exchanger 103 heats the heat medium by exchanging heat between the combustion gas and the heat medium. Heat exchange is performed while the heat medium flows through the heat exchanger 103.

  One end of the heating heat medium passage 104 is connected to the cistern 101. The other end of the heating heat medium passage 104 is connected to the heat exchanger 103. The heating heat medium passage 104 sends the heat medium from the cistern 101 to the heat exchanger 103.

  One end of the heat transfer medium passage 105 is connected to the heat exchanger 103. The other end of the feeding heat medium passage 105 is connected to a first heat medium outward passage 21a of the bathroom air conditioner 1 described later. The heat transfer medium passage 105 sends the heat medium from the heat exchanger 103 to the first heat medium outward route 21 a of the bathroom air conditioner 1.

  One end of the return heat medium passage 106 is connected to a first heat medium return passage 21b of the bathroom air conditioner 1 described later. The other end of the return heat medium passage 106 is connected to the cistern 101. The return heat medium passage 106 sends the heat medium from the first heat medium return passage 21 b of the bathroom air conditioner 1 to the cistern 101.

  The pump 107 is provided in the heating heat medium passage 104. The pump 107 pushes the heat medium in the heating heat medium passage 104 under pressure to circulate the heat medium in the heating heat medium passage 104, the feed heat medium passage 105, and the return heat medium passage 106.

  Next, the configuration of the bathroom air conditioner 1 will be described. The bathroom air conditioner 1 is a device for air conditioning the bathroom 5. For example, the bathroom air conditioner 1 heats or dries the bathroom 5. Further, the bathroom air conditioner 1 can execute a mist operation of spraying mist-like water into the bathroom 5.

  The bathroom air conditioner 1 includes a first heat medium passage 21, a heat medium temperature sensor 7, and a gas-liquid heat exchanger 2. The bathroom air conditioner 1 also includes a circulation fan 4, a ventilation fan 9, and a bathroom temperature sensor 8.

  The first heat medium passage 21 includes a first heat medium outward passage 21a and a first heat medium return passage 21b. One end of the first heat medium outward path 21a is connected to the feed heat medium path 105 of the gas heat source device 100. The other end of the first heat medium outward path 21a is connected to the gas-liquid heat exchanger 2. The first heat medium outward path 21 a sends the heat medium from the sending heat medium path 105 of the gas heat source device 100 to the gas-liquid heat exchanger 2.

  One end of the first heat medium return path 21b is connected to the gas-liquid heat exchanger 2. The other end of the first heat medium return path 21b is connected to the return heat medium path 106 of the gas heat source device 100. The first heat medium return path 21b sends the heat medium from the gas-liquid heat exchanger 2 to the return heat medium path 106 of the gas heat source device 100.

  A first heat medium valve 31 is provided in the first heat medium outward path 21a. The first heat medium valve 31 is a thermal valve. The first heat medium valve 31 opens and closes the first heat medium outward path 21a. When the first heat medium valve 31 is opened, the heat medium is sent from the gas heat source device 100 to the gas-liquid heat exchanger 2 via the first heat medium outward path 21a, and the gas-liquid heat exchanger 2 causes the first heat medium to flow. The heat medium is returned to the gas heat source device 100 via the return path 21b. When the first heat medium valve 31 is closed, it is sent from the gas heat source device 100 to the gas / liquid heat exchanger 2 via the first heat medium outward path 21a, and then from the gas / liquid heat exchanger 2 to the first heat medium return path 21b. The flow of the heat medium returned to the gas heat source device 100 through the flow stops.

  The heat medium temperature sensor 7 is provided in the first heat medium outward path 21a. The heat medium temperature sensor 7 detects the temperature of the heat medium flowing through the first heat medium outward path 21a. The heat medium temperature sensor 7 detects the temperature of the heat medium after being heated by the gas heat source device 100 and before being heat-exchanged by the gas-liquid heat exchanger 2. As the heat medium temperature sensor 7, a thermistor whose resistance value changes with temperature change can be used.

  The gas-liquid heat exchanger 2 is, for example, a hot water coil. The gas-liquid heat exchanger 2 heats air by exchanging heat between the heat medium and air. The gas-liquid heat exchanger 2 heats the air sent into the bathroom 5 by the heat of the heat medium heated by the gas heat source unit 100 and sent to the gas-liquid heat exchanger 2. Heat exchange is performed while the heat medium flows through the gas-liquid heat exchanger 2.

  The circulation fan 4 is arranged adjacent to the gas-liquid heat exchanger 2. The circulation fan 4 is driven by a motor 4a. The circulation fan 4 blows air by rotating. The circulation fan 4 sends the air in the bathroom 5 to the gas-liquid heat exchanger 2 and sends the air heated by the gas-liquid heat exchanger 2 into the bathroom 5. That is, the circulation fan 4 circulates air between the gas-liquid heat exchanger 2 and the bathroom 5. A variable louver 87 is arranged in the middle of the route from the circulation fan 4 to the bathroom 5. The variable louver 87 can change the wind direction of the air blown into the bathroom 5 by the circulation fan 4. The variable louver 87 is driven by the motor 87a.

  The ventilation fan 9 is driven by the motor 9a. The ventilation fan 9 ventilates the air in the bathroom 5 by rotating. The ventilation fan 9 exhausts the moist air in the bathroom 5 to the outside of the bathroom 5.

  The bathroom temperature sensor 8 is arranged adjacent to the gas-liquid heat exchanger 2. The bathroom temperature sensor 8 is provided at a position facing the bathroom 5. The bathroom temperature sensor 8 detects the temperature inside the bathroom 5. More specifically, the bathroom temperature sensor 8 detects the temperature of the air when the circulation fan 4 sends the air in the bathroom 5 to the gas-liquid heat exchanger 2. As the bathroom temperature sensor 8, a thermistor whose resistance value changes with changes in temperature can be used.

  The bathroom air conditioner 1 also includes a second heat medium passage 22 and a liquid-liquid heat exchanger 3. Further, the bathroom air conditioner 1 includes a first water supply passage 41, a second water supply passage 42, a mist nozzle 6, and a controller 90 (an example of control means).

  The second heat medium passage 22 includes a second heat medium outward passage 22a and a second heat medium return passage 22b. One end of the second heat medium outward passage 22a is connected to the first heat medium outward passage 21a upstream of the first heat medium valve 31 and the heat medium temperature sensor 7. The second heat medium outward path 22a branches from the first heat medium outward path 21a. Part of the heat medium flowing through the first heat medium outward path 21a flows into the second heat medium outward path 22a. The other end of the second heat medium outward path 22a is connected to the liquid-liquid heat exchanger 3. The second heat medium outward path 22a sends the heat medium from the first heat medium outward path 21a to the liquid-liquid heat exchanger 3.

  One end of the second heat medium return path 22b is connected to the liquid-liquid heat exchanger 3. The other end of the second heat medium return path 22b is connected to the first heat medium return path 21b. The second heat medium return path 22b merges with the first heat medium return path 21b. The second heat medium return path 22b sends the heat medium from the liquid-liquid heat exchanger 3 to the first heat medium return path 21b. The heat medium flowing through the second heat medium return path 22b merges with the heat medium flowing through the first heat medium return path 21b.

  A second heat medium valve 32 is provided in the second heat medium return path 22b. The second heat medium valve 32 is a flow control valve. The second heat medium valve 32 opens and closes the second heat medium return path 22b. When the second heat medium valve 32 is opened, the heat medium is sent from the first heat medium outward path 21a to the liquid-liquid heat exchanger 3 via the second heat medium outward path 22a, and the liquid-liquid heat exchanger 3 moves to the second state. The heat medium is returned to the first heat medium return path 21b via the heat medium return path 22b. When the second heat medium valve 32 is closed, it is sent from the first heat medium outward path 21a to the liquid-liquid heat exchanger 3 via the second heat medium outward path 22a, and then from the liquid-liquid heat exchanger 3 to the second heat medium return path. The flow of the heat medium returned to the first heat medium return path 21b via 22b is stopped.

  The liquid-liquid heat exchanger 3 is, for example, a plate heat exchanger. The liquid-liquid heat exchanger 3 heats low-temperature water by heat exchange of high-temperature heat medium and low-temperature water. The liquid-liquid heat exchanger 3 is connected in parallel to the gas-liquid heat exchanger 2. A part of the heat medium sent to the gas-liquid heat exchanger 2 by the first heat medium outward path 21a is sent to the liquid liquid heat exchanger 3 by the second heat medium outward path 22a. The heat medium that has undergone heat exchange in the liquid-liquid heat exchanger 3 is sent to the first heat medium return passage 21b by the second heat medium return passage 22b. The liquid-liquid heat exchanger 3 heats the water sent to the mist nozzle 6 by the heat of the heat medium heated by the gas heat source device 100 and sent to the liquid-liquid heat exchanger 3. Heat exchange is performed while the heat medium flows through the liquid-liquid heat exchanger 3.

  One end of the first water supply passage 41 is connected to a tap water supply source (not shown), and the tap water is supplied to the first water supply passage 41. The other end of the first water supply passage 41 is connected to the liquid-liquid heat exchanger 3. The first water supply passage 41 sends tap water to the liquid-liquid heat exchanger 3.

  The first water supply passage 41 is provided with a check valve 53 and a water supply valve 52. The check valve 53 prevents the backflow of water flowing through the first water supply passage 41. The water supply valve 52 is a solenoid valve. The water supply valve 52 opens and closes the first water supply passage 41. When the water supply valve 52 is opened, water flows through the first water supply passage 41. When the water supply valve 52 is opened, water is sent to the liquid-liquid heat exchanger 3 via the first water supply passage 41. When the water supply valve 52 is closed, the flow of water in the first water supply passage 41 is stopped.

  Further, a bypass 43 is connected to the first water supply passage 41. One end of the detour 43 is connected to the first water supply passage 41 on the upstream side of the water supply valve 52. The other end of the bypass 43 is connected to the first water supply passage 41 on the downstream side of the water supply valve 52. The bypass 43 sends water from the first water supply passage 41 upstream of the water supply valve 52 to the first water supply passage 41 downstream of the water supply valve 52.

  The bypass 43 is provided with a first overpressure relief valve 55. The first overpressure relief valve 55 opens and closes the bypass 43. When the first overpressure relief valve 55 is opened, water flows in the bypass 43. When the first overpressure relief valve 55 is closed, the flow of water in the bypass 43 is stopped. The first overpressure relief valve 55 is opened when the water pressure between the water supply valve 52 and the check valve 53 becomes excessively high. When the first overpressure relief valve 55 is in the open state, the water pressure in the first water supply passage 41 decreases.

  One end of the second water supply passage 42 is connected to the liquid-liquid heat exchanger 3. The other end of the second water supply passage 42 is connected to the mist nozzle 6. The second water supply passage 42 sends water from the liquid-liquid heat exchanger 3 to the mist nozzle 6. A mist temperature sensor 81 is provided in the second water supply passage 42. The mist temperature sensor 81 detects the temperature of the water flowing through the second water supply passage 42. The mist temperature sensor 81 detects the temperature of water after heat exchange in the liquid-liquid heat exchanger 3. As the mist temperature sensor 81, a thermistor whose resistance value changes with temperature change can be used.

  A mist valve 51 is provided in the second water passage 42. The mist valve 51 is a solenoid valve. The mist valve 51 opens and closes the second water supply passage 42. When the mist valve 51 is opened, water flows through the second water supply passage 42. When the mist valve 51 is opened, water is sent from the liquid-liquid heat exchanger 3 to the mist nozzle 6. When the mist valve 51 is closed, the flow of water in the second water supply passage 42 is stopped.

  A water discharge passage 44 is connected to the second water supply passage 42. One end of the water discharge passage 44 is connected to the second water supply passage 42 on the upstream side of the mist valve 51. The other end of the water discharge channel 44 is open. The water discharge passage 44 discharges a part of the water flowing through the second water supply passage 42 to the outside.

  The water discharge passage 44 is provided with a second overpressure relief valve 56. The second overpressure relief valve 56 opens and closes the water discharge passage 44. When the second overpressure relief valve 56 is opened, water flows through the water discharge passage 44 and is discharged. When the second overpressure relief valve 56 is closed, water does not flow to the water discharge passage 44 and is not discharged. The second overpressure relief valve 56 is opened when the water pressure between the mist valve 51 and the liquid-liquid heat exchanger 3 becomes excessively high. When the second overpressure relief valve 56 is opened, the water pressure in the second water supply passage 42 decreases.

  The mist nozzle 6 sprays the water sent to the mist nozzle 6 by the second water supply passage 42 in the form of mist. The mist nozzle 6 is arranged so as to face the bathroom 5. The mist nozzle 6 sprays mist-like water into the bathroom 5.

  The controller 90 controls the operation of each component of the bathroom air conditioner 1. The control by the controller 90 will be described later.

  Next, the operation of the bathroom air conditioner 1 will be described. The processing executed by the controller 90 will be described with reference to the flowchart of FIG. 2 and the timing chart of FIG.

(First embodiment)
First, in the initial state, the heat medium heated by the gas heat source device 100 is sent to the first heat medium outward path 21a of the bathroom air conditioner 1 by the sending heat medium path 105. Further, in the initial state, the first heat medium valve 31 provided in the first heat medium outward path 21a of the bathroom air conditioner 1 is assumed to be in the closed state. In addition, it is assumed that the second heat medium valve 32 provided in the second heat medium return path 22b is in the closed state. In this case, the heat medium in the first heat medium passage 21 (the first heat medium outward passage 21a and the first heat medium return passage 21b) does not flow, and the heat medium is not sent to the gas-liquid heat exchanger 2. Further, the heat medium in the second heat medium passage 22 (the second heat medium outward passage 22a and the second heat medium return passage 22b) is not flowing, and the heat medium is not sent to the liquid-liquid heat exchanger 3. .

  Further, in the initial state, tap water is being sent to the first water supply passage 41 of the bathroom air conditioner 1. Further, it is assumed that the water supply valve 52 provided in the first water supply passage 41 is in the closed state. Further, it is assumed that the mist valve 51 provided in the second water supply passage 42 is in the closed state. In this case, the water in the first water supply passage 41 and the second water supply passage 42 is not flowing, and the water is not sent to the mist nozzle 6.

  Further, in the initial state, the circulation fan 4 is stopped. Therefore, the air is not circulating between the gas-liquid heat exchanger 2 and the bathroom 5, and the air heated by the gas-liquid heat exchanger 2 is not sent to the bathroom 5. The temperature inside the bathroom 5 is detected by the bathroom temperature sensor 8. In the initial state, the temperature in the bathroom detected by the bathroom temperature sensor 8 (the temperature Tr detected by the bathroom temperature sensor 8) is still low.

  When the mist operation is started from the above initial state, the controller 90 of the bathroom air conditioner 1 executes the following processing.

  As shown in FIGS. 2 and 3, first, in S11, the controller 90 opens the first heat medium valve 31 provided in the first heat medium outward path 21a of the bathroom air conditioner 1. When the first heat medium valve 31 is opened, the heat medium in the first heat medium passage 21 (the first heat medium outward passage 21a and the first heat medium return passage 21b) starts to flow. Therefore, the heat medium is sent from the sending heat medium passage 105 of the gas heat source device 100 to the first heat medium outward passage 21a, flows through the first heat medium outward passage 21a, and is sent to the gas-liquid heat exchanger 2.

  When the heat medium flows through the first heat medium outward path 21a, the temperature of the heat medium is detected by the heat medium temperature sensor 7 provided in the first heat medium outward path 21a. At the time of S11, the temperature of the heat medium detected by the heat medium temperature sensor 7 (detection temperature Tw of the heat medium temperature sensor 7) is still low. After that, the detection temperature Tw of the heat medium temperature sensor 7 rises with the passage of time (see FIG. 3).

  In the gas-liquid heat exchanger 2, the air sent into the bathroom 5 is heated by the heat medium sent to the gas-liquid heat exchanger 2 from the first heat medium outward path 21a. Air is heated by heat exchange between the heat medium and air. At this time, the circulation fan 4 is stopped, so that the air heated by the gas-liquid heat exchanger 2 is not sent into the bathroom 5. Therefore, the temperature inside the bathroom 5 detected by the bathroom temperature sensor 8 (the temperature Tr detected by the bathroom temperature sensor 8) is still low (see FIG. 3). The heat medium that has undergone heat exchange in the gas-liquid heat exchanger 2 flows through the first heat medium return path 21b. The heat medium after the heat exchange is sent to the return heat medium passage 106 of the gas heat source device 100 by the first heat medium return passage 21b.

  In subsequent S12, the controller 90 determines whether or not the detected temperature Tw of the heat medium temperature sensor 7 is equal to or higher than a predetermined reference heat medium temperature Ta. The predetermined reference heat medium temperature Ta is, for example, 40 ° C. When the detected temperature Tw of the heat medium temperature sensor 7 is equal to or higher than the predetermined reference heat medium temperature Ta (40 ° C.), the controller 90 determines Yes in S12 and proceeds to S13. When the detected temperature Tw of the heat medium temperature sensor 7 is not (less than) the predetermined reference heat medium temperature Ta (40 ° C.) or more, the controller 90 determines No in S12 and stands by.

  In subsequent S13, the controller 90 drives the circulation fan 4. When the circulation fan 4 is driven, air circulates between the gas-liquid heat exchanger 2 and the bathroom 5, and the air heated by the gas-liquid heat exchanger 2 is sent to the bathroom 5. At the time of S13, the temperature of the heat medium is higher than that at the time of S11. The air heated by the high-temperature heating medium is sent into the bathroom 5. As a result, the temperature inside the bathroom 5 rises and the temperature Tr detected by the bathroom temperature sensor 8 rises (see FIG. 3).

  In subsequent S14, the controller 90 opens the second heat medium valve 32 provided in the second heat medium return path 22b. The order of the steps S13 and S14 is not particularly limited, and the circulation fan 4 may be driven after the second heat medium valve 32 is opened. Also, both may be executed simultaneously. When the second heat medium valve 32 is opened in S14, the heat medium in the second heat medium passage 22 (the second heat medium outward passage 22a and the second heat medium return passage 22b) starts to flow. Moreover, since the second heat medium outward path 22a is connected to the first heat medium outward path 21a, a part of the heat medium flowing through the first heat medium outward path 21a flows to the second heat medium outward path 22a. The heat medium flowing through the second heat medium outward path 22a is sent to the liquid-liquid heat exchanger 3.

  The heat medium is sent to the liquid-liquid heat exchanger 3 from the second heat medium outward path 22a. In the liquid-liquid heat exchanger 3, the water in the liquid-liquid heat exchanger 3 is heated by the heat medium sent to the liquid-liquid heat exchanger 3 through the second heat medium outward path 22a. Water is heated by heat exchange between the heat medium and water. The heat medium that has undergone heat exchange in the liquid-liquid heat exchanger 3 flows through the second heat medium return path 22b. The heat medium after the heat exchange is sent to the first heat medium return passage 21b by the second heat medium return passage 22b.

  In subsequent S15, the controller 90 determines whether or not the temperature Tr detected by the bathroom temperature sensor 8 is equal to or higher than a predetermined reference bathroom temperature Tb. The predetermined reference bathroom temperature Tb is 25 ° C., for example. When the detected temperature Tr of the bathroom temperature sensor 8 is equal to or higher than the predetermined reference bathroom temperature Tb (25 ° C.), the controller 90 determines Yes in S15 and proceeds to S16. On the other hand, when the detected temperature Tr of the bathroom temperature sensor 8 is not (less than) the predetermined reference bathroom temperature Tb (25 ° C.) or more, the controller 90 determines No in S15 and stands by.

  In subsequent S16, the controller 90 simultaneously opens the water supply valve 52 provided in the first water supply passage 41 and the mist valve 51 provided in the second water supply passage 42. When the water supply valve 52 and the mist valve 51 are opened, the water in the first water supply passage 41 and the second water supply passage 42 starts to flow. The water flowing through the first water supply passage 41 is sent to the liquid-liquid heat exchanger 3. Further, the water flowing through the second water supply passage 42 is sent to the mist nozzle 6. The water heated by the liquid-liquid heat exchanger 3 is sent to the mist nozzle 6. The mist nozzle 6 makes the water sent to the mist nozzle 6 by the second water supply passage 42 into a mist and sprays it into the bathroom 5. The water heated by the liquid-liquid heat exchanger 3 is sprayed into the bathroom 5. After that, mist-like water is sprayed into the bathroom 5 until the mist operation ends.

  The configuration and operation of the bathroom air conditioner 1 have been described above. As is clear from the above description, the bathroom air conditioner 1 includes the gas-liquid heat exchanger 2, the liquid-liquid heat exchanger 3 connected in parallel to the gas-liquid heat exchanger 2, and the gas-liquid heat exchanger 2. The first heat medium forward path 21a for sending the heat medium, the first heat medium return path 21b for returning the heat medium from the gas-liquid heat exchanger 2, and the first heat medium forward path 21a branch off from the first heat medium forward path 21a. The second heat medium forward path 22a for sending a part of the heat medium flowing through the liquid-liquid heat exchanger 3 and the first heat medium return path 21b are joined together to return the heat medium from the liquid-liquid heat exchanger 3 The heat medium return path 22b and the first water supply path 41 for sending water to the liquid-liquid heat exchanger 3 are provided. Further, the bathroom air conditioner 1 includes a mist nozzle 6 and a second water supply passage 42 that sends water from the liquid-liquid heat exchanger 3 to the mist nozzle 6. Further, the bathroom air conditioner 1 flows through the first heat medium outward path 21a, the first heat medium valve 31 that opens and closes the first heat medium outward path 21a, the second heat medium valve 32 that opens and closes the second heat medium return path 22b. The heating medium temperature sensor 7 that detects the temperature of the heating medium, the mist valve 51 that opens and closes the second water supply path 42, the bathroom temperature sensor 8 that detects the temperature in the bathroom 5, and the controller 90 are provided. This bathroom air conditioner 1 can execute mist operation. In the mist operation, the gas-liquid heat exchanger 2 heats the air sent into the bathroom 5 by the heat medium sent to the gas-liquid heat exchanger 2 by the first heat medium outward path 21a, and the liquid-liquid heat exchanger 3 The water sent to the liquid-liquid heat exchanger 3 by the first water supply path 41 is heated by the heat medium sent to the liquid-liquid heat exchanger 3 by the second heat medium going path 22a, and the mist nozzle 6 makes the second water send. Water sent from the liquid-liquid heat exchanger 3 to the mist nozzle 6 by the water passage 42 is made into a mist and sprayed in the bathroom 5. The controller 90 performs a process of opening the first heat medium valve 31 while keeping the second heat medium valve 32 and the mist valve 51 closed at the start of the mist operation (see S11 of FIG. 2), and the heat medium temperature sensor. A process of opening the second heat medium valve 32 when the temperature of the heat medium detected by 7 reaches a predetermined reference heat medium temperature Ta (see S12 and S14 of FIG. 2), and opening the mist valve 51. It is configured to execute the processing for setting the state in this order (see S16 in FIG. 2).

  According to such a configuration, since the second heat medium valve 32 is closed at the start of the mist operation, the heat medium in the second heat medium outward path 22a is not flowing. Therefore, the heat medium is not sent from the second heat medium outward path 22a to the liquid-liquid heat exchanger 3. When the controller 90 opens the first heat medium valve 31 in this state, the heat medium in the first heat medium outward path 21a flows and the heat medium is sent to the gas-liquid heat exchanger 2. As described above, according to the above configuration, while the heat medium sent from the gas heat source device 100 is at a low temperature, the heat is not sent to the liquid-liquid heat exchanger 3 while the heat medium is not sent to the liquid-liquid heat exchanger 3. A medium can be sent. Therefore, the heat medium can be concentrated and sent to the gas-liquid heat exchanger 2 without being sent to the liquid-liquid heat exchanger 3 at the start of the mist operation, and the heat generated by the heat medium in the liquid-liquid heat exchanger 3 is radiated. It is possible to prevent wasteful consumption of. In this case, although heat is radiated from the heat medium in the gas-liquid heat exchanger 2, heat is wasted because the heat radiated in the gas-liquid heat exchanger 2 is used for heating the bathroom 5 thereafter. It will not be consumed by. Further, while the heat medium sent from the gas heat source device 100 is at a low temperature, the water staying inside the liquid-liquid heat exchanger 3 is not unnecessarily heated. It is possible to suppress the pressure rise of the water inside. After that, the controller 90 opens the second heat medium valve 32 when the temperature of the heat medium detected by the heat medium temperature sensor 7 reaches the reference heat medium temperature Ta, and then opens the mist valve 51. To do. Thereby, after the temperature of the heat medium sent from the gas heat source device 100 becomes high, the heat medium is sent to the liquid-liquid heat exchanger 3 and the water sent to the mist nozzle 6 can be heated.

  As described above, according to the bathroom air conditioner 1 described above, at the start of the mist operation, the heat medium is sent only to the gas-liquid heat exchanger 2 and then the heat medium is also sent to the liquid-liquid heat exchanger 3. The heat of the heat medium is not wasted due to the heat radiation from the liquid-liquid heat exchanger 3.

  On the other hand, in the conventional bathroom air conditioner, as shown in FIG. 7, the first heat medium valve 31 is opened and the second heat medium valve 32 is opened at the start of the mist operation. . Therefore, the heat medium is sent to both the gas-liquid heat exchanger 2 and the liquid-liquid heat exchanger 3 at the start of the mist operation. In the gas-liquid heat exchanger 2, the air in the vicinity of the gas-liquid heat exchanger 2 is heated by the heat medium, and in the liquid-liquid heat exchanger 3, the water retained in the liquid-liquid heat exchanger 3 is heated by the heat medium. It Both air and water are heated by the heat medium from the start of the mist operation. Therefore, heat is wasted due to heat dissipation in the liquid-liquid heat exchanger 3, and the temperature of the water retained inside the liquid-liquid heat exchanger 3 rises, leading to an increase in water pressure. In the conventional technique, since the water pressure in the liquid-liquid heat exchanger 3, the first water supply passage 41, and the second water supply passage 42 becomes high, as shown in S201 of FIG. 7, the first overpressure relief valve 55 and the second overpressure relief valve 55 are provided. It is necessary to open the pressure relief valve 56.

  Further, as is clear from the above description, the bathroom air conditioner 1 further includes the circulation fan 4 that circulates air between the gas-liquid heat exchanger 2 and the bathroom 5. Further, the controller 90 opens the first heat medium valve 31 with the circulation fan 4 stopped at the start of the mist operation (see S11 of FIG. 2), and the heat medium detected by the heat medium temperature sensor 7 It is configured to execute the process of driving the circulation fan 4 in this order when the temperature of 1 reaches a predetermined reference heat medium temperature Ta (see S12 and S13 of FIG. 2).

  According to such a configuration, since the circulation fan 4 is stopped at the start of the mist operation, air circulates between the bathroom 5 and the gas-liquid heat exchanger 2 before the heat medium becomes high in temperature. There is no. Therefore, low-temperature air that is not heated so much in the gas-liquid heat exchanger 2 is not sent into the bathroom 5. After that, when the temperature of the heat medium detected by the heat medium temperature sensor 7 reaches the reference heat medium temperature Ta, the circulation fan 4 is driven. Thereby, the air heated by the high-temperature heat medium can be sent into the bathroom 5, and the warm air can be sent into the bathroom 5.

  Although one embodiment has been described above, the specific mode is not limited to the above embodiment. In the following description, the same components as those in the above description will be designated by the same reference numerals and description thereof will be omitted.

  In the above embodiment, the controller 90 determines in S15 whether the temperature Tr detected by the bathroom temperature sensor 8 is equal to or higher than a predetermined reference bathroom temperature, and in accordance with the determination result, opens the mist valve 51 in S16. However, the configuration is not limited to this. In another embodiment, as shown in FIG. 4, the controller 90 may determine in S15 whether or not a predetermined time has elapsed since the second heat medium valve 32 was opened. When the predetermined time has elapsed since the second heat medium valve 32 was opened, the controller 90 determines Yes in S15 and proceeds to S16. On the other hand, when the predetermined time has not elapsed since the second heat medium valve 32 was opened, the controller 90 determines No in S15 and stands by.

  In the bathroom air conditioner 1 described above, the controller 90 executes the process of opening the mist valve 51 when a predetermined time has elapsed after executing the process of opening the second heat medium valve 32 in the mist operation. (See S15 and S16 of FIG. 4).

  With such a configuration, even when the temperature in the bathroom 5 detected by the bathroom temperature sensor 8 cannot be used for the control by the controller 90, the bathroom 5 is opened after the second heat medium valve 32 is opened. It is possible to secure a time for the temperature inside to rise. Then, after the temperature inside the bathroom 5 becomes high, the mist valve 51 can be opened and water can be sent from the liquid-liquid heat exchanger 3 to the mist nozzle 6. Therefore, mist-like water can be sprayed in the bathroom 5 after the temperature in the bathroom 5 becomes high.

(Second embodiment)
In the second embodiment, as shown in FIGS. 5 and 6, after the controller 90 drives the circulation fan 4 in S13 and before opening the second heat medium valve 32 in S14, in S31, the bathroom It is determined whether the temperature Tr detected by the temperature sensor 8 is equal to or higher than a predetermined first reference bathroom temperature Tb1. The predetermined first reference bathroom temperature Tb1 is 20 ° C., for example. When the detected temperature Tr of the bathroom temperature sensor 8 is equal to or higher than the predetermined first reference bathroom temperature Tb1 (20 ° C.), the controller 90 determines Yes in S31 and proceeds to S14. On the other hand, when the detected temperature Tr of the bathroom temperature sensor 8 is not (less than) the predetermined first reference bathroom temperature Tb1 (20 ° C.) or more, the controller 90 determines No in S31 and stands by.

  In S15 subsequent to S14, the controller 90 determines whether or not the temperature Tr detected by the bathroom temperature sensor 8 is equal to or higher than a predetermined second reference bathroom temperature Tb2. The predetermined second reference bathroom temperature Tb2 is 25 ° C., for example. When the detected temperature Tr of the bathroom temperature sensor 8 is equal to or higher than the predetermined second reference bathroom temperature Tb2 (25 ° C.), the controller 90 determines Yes in S15 and proceeds to S16. On the other hand, when the detected temperature Tr of the bathroom temperature sensor 8 is not (less than) the predetermined second reference bathroom temperature Tb2 (25 ° C.) or more, the controller 90 determines No in S15 and stands by. The second reference bathroom temperature Tb2 (25 ° C) is higher than the first reference bathroom temperature Tb1 (20 ° C).

  In the bathroom air conditioner 1 described above, in the mist operation, the controller 90 performs the process of driving the circulation fan 4 and then the temperature Tr in the bathroom 5 detected by the bathroom temperature sensor 8 is a predetermined first reference bathroom temperature Tb1. When it reaches, the process for opening the second heat medium valve 32 is configured to be executed (see S31 and S14 in FIG. 5).

  With such a configuration, the heating medium can be sent to the liquid-liquid heat exchanger 3 after the detected temperature Tr of the bathroom temperature sensor 8 reaches the first reference bathroom temperature Tb1. Therefore, until the temperature in the bathroom 5 rises, the heat medium can be concentrated and sent only to the gas-liquid heat exchanger 2 without sending the heat medium to the liquid-liquid heat exchanger 3. As a result, the air sent to the bathroom 5 can be preferentially heated by the gas-liquid heat exchanger 2 until the temperature inside the bathroom 5 rises. Then, after the air in the bathroom 5 has warmed up, the heat medium can be sent to the liquid-liquid heat exchanger 3. Then, in the liquid-liquid heat exchanger 3, the water to be sent to the mist nozzle 6 is heated. From the above, first, the air sent into the bathroom 5 is preferentially heated by the gas-liquid heat exchanger 2, so that the temperature rising rate in the bathroom 5 can be increased as shown in FIG.

  Further, according to the above configuration, the heat medium is not sent to the liquid-liquid heat exchanger 3 until the temperature Tr detected by the bathroom temperature sensor 8 reaches the first reference bathroom temperature Tb1 (20 ° C.). Therefore, the water for sending to the mist nozzle 6 is not heated by the liquid-liquid heat exchanger 3, so that the water temperature and the water pressure do not rise. As a result, the water pressure in the liquid-liquid heat exchanger 3 and the water pressure in the first water supply passage 41 and the second water supply passage 42 do not rise.

  As shown in FIGS. 3 and 6, comparing the second embodiment with the first embodiment, in the second embodiment, the rising speed of the temperature Tr detected by the bathroom temperature sensor 8 is faster than that in the first embodiment. Therefore, in the second embodiment, the air in the bathroom 5 can be warmed up faster.

  Moreover, in the bathroom air conditioner 1 described above, the controller 90 performs the process of driving the circulation fan 4 in the mist operation, and then the temperature Tr in the bathroom 5 detected by the bathroom temperature sensor 8 is the first reference bathroom temperature Tb1. It is configured to execute the process of opening the mist valve 51 when the predetermined second reference bathroom temperature Tb2 higher than that is reached (see S15 and S16 in FIG. 5).

  With such a configuration, after the temperature Tr detected by the bathroom temperature sensor 8 reaches the second reference bathroom temperature Tb2, the mist valve 51 is opened and water is sent from the liquid / liquid heat exchanger 3 to the mist nozzle 6. be able to. Therefore, mist-like water can be sprayed in the bathroom 5 after the temperature in the bathroom 5 becomes high.

  In the above embodiment, the first heat medium valve 31 is provided in the first heat medium outward path 21a, but the configuration is not limited to this. In another embodiment, the first heat medium valve 31 may be provided in the first heat medium return path 21b instead of the first heat medium outward path 21a. The first heat medium valve 31 opens and closes the first heat medium return path 21b. When the first heat medium valve 31 is opened, the heat medium in the first heat medium passage 21 (the first heat medium outward passage 21a and the first heat medium return passage 21b) flows.

  Further, in the above embodiment, the second heat medium valve 32 is provided in the second heat medium return path 22b, but the present invention is not limited to this configuration. In another embodiment, the second heat medium valve 32 may be provided in the second heat medium outward path 22a instead of the second heat medium return path 22b. The second heat medium valve 32 opens and closes the second heat medium outward path 22a. When the second heat medium valve 32 is opened, the heat medium in the second heat medium passage 22 (the second heat medium outward passage 22a and the second heat medium return passage 22b) flows.

  Further, in the above embodiment, the mist valve 51 is provided in the second water supply passage 42, but the configuration is not limited to this. In another embodiment, the mist valve 51 may be provided in the first water supply passage 41 instead of the second water supply passage 42. The mist valve 51 opens and closes the first water supply passage 41. When the mist valve 51 is opened, water in the first water supply passage 41 and the second water supply passage 42 flows.

  Specific examples of the present invention have been described above in detail, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. The technical elements described in the present specification or the drawings exert technical utility alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technique illustrated in the present specification or the drawings can simultaneously achieve a plurality of objects, and achieving the one object among them has technical utility.

1: Bathroom air conditioner 2: Gas-liquid heat exchanger 3: Liquid-liquid heat exchanger 4: Circulation fan 4a: Motor 5: Bathroom 6: Mist nozzle 7: Heat medium temperature sensor 8: Bathroom temperature sensor 9: Ventilation fan 9a: Motor 21: 1st heat transfer medium path 21a: 1st heat transfer path 21b: 1st heat transfer path 22: 2nd heat transfer path 22a: 2nd heat transfer path 22b: 2nd heat transfer path 31: 1st heat transfer valve 32: 2nd heat transfer valve 41: 1st water supply path 42: 2nd water supply path 43: Detour 44: Water discharge path 51: Mist valve 52: Water supply valve 53: Check valve 55: 1st overpressure relief valve 56: 2nd overpressure relief valve 81: Mist temperature sensor 87: Variable louver 87a: Motor 90: Controller 100: Gas heat source machine 101: Sistern 102: Gas burner 103: Heat exchanger 104: Heating heat medium passage 105: Sending heat Medium path 106: Ri heat medium passage 107: pump

Claims (3)

A gas-liquid heat exchanger,
A liquid-liquid heat exchanger connected in parallel to the gas-liquid heat exchanger,
A first heat medium outward path for sending a heat medium to the gas-liquid heat exchanger;
A first heat medium return path for returning the heat medium from the gas-liquid heat exchanger,
A second heat medium outward path branched from the first heat medium outward path and sending a part of the heat medium flowing through the first heat medium outward path to the liquid-liquid heat exchanger;
A second heat medium return path that joins the first heat medium return path and returns the heat medium from the liquid-liquid heat exchanger;
A first water passage for sending water to the liquid-liquid heat exchanger;
With a mist nozzle,
A second water passage for sending water from the liquid-liquid heat exchanger to the mist nozzle;
A first heat medium valve for opening and closing the first heat medium outward path or the first heat medium return path;
A second heat medium valve for opening and closing the second heat medium outward path or the second heat medium return path;
A heat medium temperature sensor for detecting the temperature of the heat medium flowing through the first heat medium outward path;
A mist valve for opening and closing the first water passage or the second water passage,
A bathroom temperature sensor that detects the temperature in the bathroom,
A circulation fan that circulates air between the gas-liquid heat exchanger and the bathroom,
Equipped with control means,
A bathroom air conditioner capable of performing mist operation,
The mist operation is
The gas-liquid heat exchanger heats air sent into the bathroom by the heat medium sent to the gas-liquid heat exchanger by the first heat medium outward path,
The liquid-liquid heat exchanger heats the water sent to the liquid-liquid heat exchanger by the first water supply path by the heat medium sent to the liquid-liquid heat exchanger by the second heat medium outward path,
The mist nozzle is an operation of spraying water sent from the liquid-liquid heat exchanger to the mist nozzle by the second water supply passage into the mist into the bathroom.
The control means opens the first heat medium valve while keeping the second heat medium valve and the mist valve in the closed state at the start of the mist operation and keeping the circulation fan stopped. The process of driving the circulation fan when the temperature of the heat medium detected by the heat medium temperature sensor reaches a predetermined reference heat medium temperature is executed in this order, and the circulation fan is operated in the mist operation. A process of opening the second heating medium valve when the temperature in the bathroom detected by the bathroom temperature sensor reaches a predetermined first reference bathroom temperature after executing the driving process, and the mist valve A bathroom air conditioner that is configured to perform the processing for opening the door in this order. In the mist operation, the control unit has a predetermined second reference bathroom temperature in which the temperature in the bathroom detected by the bathroom temperature sensor after executing the process of driving the circulation fan is higher than the first reference bathroom temperature. The bathroom air conditioner according to claim 1 , which is configured to perform a process of opening the mist valve when the temperature reaches a predetermined value. In the mist operation, the control means is configured to perform a process of opening the mist valve when a predetermined time has elapsed after performing a process of opening the second heat medium valve. The bathroom air conditioner according to claim 1 , wherein:

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