JP4735046B2 - Bathroom air conditioning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bathroom air conditioning system capable of heating a bathroom in a short time. <P>SOLUTION: A bathroom heating system 1A as this bathroom air conditioning system comprises a mist generating device 2 spouting mist by hot water, a bathroom heating/ventilating/drying device (bathroom air conditioner) 3 for heating and ventilating a bathroom 101, and a heat pump hot water supply system 4 supplying hot water to the mist generating device 2 or the like. In heating the bathroom, the mist is spouted by the mist generating device 2, and the bathroom 101 is heated by hot air by the bathroom heating/ventilating/drying device 3. Thus, a mist-sauna state of intermediate temperature and high humidity can be prepared in the bathroom 101 in a short time. <P>COPYRIGHT: (C)2007,JPO&amp;INPIT

Description

  TECHNICAL FIELD The present invention relates to a bathroom air-conditioning system provided with a hot-water spraying apparatus that ejects hot water or water mist, and a bathroom air-conditioning apparatus having an air-conditioning function such as bathroom heating and ventilation. More specifically, the hot water mist jetting by the hot water jetting device and the bathroom heating by the bathroom air conditioner are linked to enable the bathroom to be in a middle temperature and high humidity mist sauna state in a short time.

  2. Description of the Related Art Conventionally, an apparatus called a mist sauna apparatus or the like that ejects hot water as a mist into a bathroom and heats the bathroom has been proposed. (For example, refer to Patent Document 1).

  The mist sauna device has a configuration in which one or a plurality of mist nozzles are provided on a wall surface of a bathroom or the like, and hot water supplied from a water heater is used as a mist to be ejected into the bathroom.

Japanese Examined Patent Publication No. 6-59301

  However, in the conventional mist sauna device, the bathroom is heated only by the ejection of mist, so the amount of heat necessary to raise the temperature of the bathroom to a temperature suitable for bathing is insufficient, and heating takes time. There was a problem.

  The present invention has been made to solve such a problem, and an object thereof is to provide a bathroom air conditioning system capable of heating a bathroom in a short time.

In order to solve the above-described problems, a bathroom air-conditioning system according to the present invention is provided with a hot water or water spray device having a mist nozzle that receives supply of hot water or water and generates mist, and a bathroom that blows air or warm air according to an operation mode. The controller includes a control unit that executes a mist mode in which the operation of the air conditioner, the hot water jet device, and the bathroom air conditioner is linked. The control unit sets the mist in the hot water jet device as the mist jet amount as the first jet amount. A first mist mode that blows or blows warm air in the bathroom air conditioner with the amount of air blown out into the bathroom as the first air amount, and the same amount of blowout as the first blowout amount according to a preset set temperature of the bathroom , Or, while changing the amount of spray in a range smaller than the first amount of spray, mist is sprayed with a hot water spray device, and the amount of air blown into the bathroom is weaker than the first amount of air And executes switching the second mist mode for blowing air blowing or warm air in the bathroom air conditioner as the second air volume.

In the bathroom air-conditioning system according to the present invention , the mist is ejected with the first ejection amount by the hot water ejection device, and the bathroom is heated before bathing by blowing air or warm air with the first air volume. In addition, during bathing, mist is ejected by the hot water jetting device while changing the jetting amount within the range equal to the first jetting amount or less than the first jetting amount according to the preset temperature of the bathroom. At the same time, heating of the bathroom is continued with a second air volume that is weaker than the first air volume.

  According to the bathroom air-conditioning system of the present invention, the mist is jetted by the hot water jetting device and the bathroom is heated by hot air by the bathroom air-conditioning device, so that the bathroom is brought into a middle temperature and high humidity mist sauna state in a short time. be able to.

  In addition, by switching between the first mist mode used before bathing and the second mist mode used during bathing, etc., during the bathing, temperature drop and temperature rise are suppressed, and the mist is at a desired temperature. Sauna can be maintained.

  Hereinafter, an embodiment of a bathroom heating system as a bathroom air-conditioning system of the present invention will be described with reference to the drawings.

<Overall configuration example of the bathroom heating system according to the first embodiment>
FIG. 1 is a configuration diagram illustrating an example of a bathroom heating system 1A according to the first embodiment. The bathroom heating system 1A according to the first embodiment includes a mist generating device 2 that ejects mist-like hot water (mist) into the bathroom 101, and a bathroom heating as a bathroom air conditioner that performs heating and ventilation of the bathroom 101. A ventilation dryer 3 and a heat pump hot water supply system 4 for supplying hot water to the mist generator 2 and the bathroom 101 are provided.

  The bathroom heating system 1 </ b> A uses a heat pump hot water supply system 4 as a hot water source of the mist generator 2. Moreover, the electric heater built in the bathroom heating ventilation drying apparatus 3 is utilized as a heat source of the bathroom heating ventilation drying apparatus 3. Then, the operation of the mist generating device 2 and the operation of the bathroom heating / ventilating / drying device 3 are linked to each other so that the inside of the bathroom 101 is brought into a middle temperature and high humidity mist sauna state in a short time.

  The bathroom heating system 1 </ b> A is controlled by, for example, a main control unit 5 provided in the bathroom heating / ventilation / drying apparatus 3, and the main control unit 5 includes a main operation unit 6 and a bathroom 101 installed in a washroom 102 adjacent to the bathroom 101. A predetermined control is executed in response to an operation of the mist operation unit 7 installed in the apparatus.

  The main operation unit 6 is, for example, a remote control device wired with the main control unit 5 by an electric cable 6a, and the mist operation unit 7 is a remote control device wirelessly connected with the main control unit 5 by infrared communication. As an example, it is possible to perform operations such as starting and stopping the heating operation at the bathroom undressing place 102 and switching the mist ejection state in the bathroom 101.

<Configuration Example of Mist Generating Device of First Embodiment>
2 and 3 show a first embodiment of the mist generator 2, and the configuration of the mist generator 2A of the first embodiment will be described next. Here, FIG. 2A is a plan view of the mist generating device 2A viewed from the lower surface side, and FIG. 2B is a cross-sectional view taken along line AA of FIG. 3A is a sectional view taken along line BB in FIG. 2A, and FIG. 3B is a sectional view taken along line CC in FIG.

  The mist generating device 2A of the first embodiment is an example of a hot water jetting device, and includes a mist nozzle 11A that generates mist, a supply control valve device 12 that switches supply of hot water or water to the mist nozzle 11A, and a mist nozzle 11A. An axial flow fan unit 13 that atomizes the generated mist and blows it out, and a body case 14 that forms an air passage for ejecting the mist atomized by the axial flow fan unit 13 are provided.

  The axial fan unit 13 is an example of a diffusing unit, and includes a fan motor 15 and a propeller fan 16 that is rotationally driven by the fan motor 15. The fan motor 15 is an example of a driving unit, and the shaft 15a is arranged vertically.

  The propeller fan 16 is an example of an impeller, and a plurality of blades 16a are attached at a predetermined attachment angle. In the present embodiment, the propeller fan 16 includes, for example, four blades 16a, and the end portions of the adjacent blades 16a have a predetermined interval in the axial direction and an overlapping portion 16b in the rotational direction. is there. Thus, the propeller fan 16 is configured such that no gap is formed between the blades 16a when viewed from the axial direction.

  The axial fan unit 13 has a propeller fan 16 attached to a shaft 15 a of a fan motor 15, and the propeller fan 16 is rotationally driven by the fan motor 15, so that air containing mist is axially directed to the propeller fan 16. Inflow and outflow in the axial direction.

  The mist nozzle 11A is supplied with warm water or water, and ejects it in the form of a mist. The mist nozzle 11 </ b> A is arranged at a position along the rotation locus of the blades 16 a of the propeller fan 16 on the upstream side with respect to the air flow direction generated when the propeller fan 16 of the axial fan unit 13 is rotationally driven. The mist is ejected toward the blade 16a of the propeller fan 16.

  In this embodiment, for example, the same number of mist nozzles 11A as the number of blades 16a of propeller fan 16 are arranged at equal intervals along the rotation trajectory of blades 16a of propeller fan 16. Accordingly, the mist nozzles 11 </ b> A are arranged side by side on the circumference at the same intervals as the intervals between the blades 16 a of the propeller fan 16.

  The main body case 14 has, for example, a rectangular parallelepiped outer shape and is partitioned by a cylindrical air passage forming wall portion 17. The upper end of the air passage forming wall portion 17 is connected to the lower surface of the ceiling portion of the main body case 14. Further, the air passage forming wall portion 17 has a part of the outer peripheral surface connected to the two opposite side surfaces of the main body case 14. Furthermore, a part of the outer peripheral surface of the air passage forming wall portion 17 is connected to the other two side surfaces of the main body case 14 through two partition wall portions 17a. Thereby, the outer peripheral surface of the air passage forming wall portion 17 is supported by the two opposing side surfaces of the main body case 14 and the four partition wall portions 17a.

  In addition, it is good also as a structure which provides the rib 17b between the partition wall parts 17a, and supports the outer peripheral surface of the air path formation wall part 17 further.

  The main body case 14 includes a first blowing air passage 18 inside the air passage forming wall portion 17 and a second blowing air passage 19 and a suction air passage 20 outside the air passage forming wall portion 17. The first blowing air passage 18 is formed as a cylindrical space whose outer periphery is partitioned by the air passage forming wall portion 17. Moreover, the 2nd blowing wind path 19 is formed in the two places which oppose on both sides of the 1st blowing wind path 18 around the wind path formation wall part 17, for example. Further, the suction air passage 20 is formed around the air passage forming wall portion 17 at, for example, four places partitioned by the second blow-out air passage 19 and the partition wall portion 17a.

  In the main body case 14, the axial fan unit 13 is attached to the first blowing air passage 18. That is, the main body case 14 has the fan motor 15 of the axial fan unit 13 attached to the upper surface of the ceiling portion of the first blowing air passage 18. The shaft 15a of the fan motor 15 projects vertically through the ceiling portion of the first blowing air passage 18, and the propeller fan 16 is attached to the shaft 15a. The first blowing air passage 18 has a diameter larger than the diameter of the propeller fan 16, and the propeller fan 16 is configured to be rotatable within the first blowing air passage 18.

  Further, the main body case 14 includes a nozzle mounting portion 21 around the shaft 15a of the fan motor 15 on the lower surface of the ceiling portion of the first blowing air passage 18, and the nozzle mounting portion 21 has the above-described predetermined arrangement with the mist nozzle. 11A is attached.

  In addition, in order to prevent water leakage from the first blowing air passage 18 side to the fan motor 15 side, a shielding blade 22 is provided on the shaft 15 a between the propeller fan 16 and the nozzle mounting portion 21. The shielding blade 22 is, for example, a disk whose bottom surface has a wave shape, and rotates together with the propeller fan 16.

  The shielding blade 22 covers the base portion of the shaft 15a of the fan motor 15 protruding from the nozzle mounting portion 21 so as to repel mist and the like diffused upward by hitting the propeller fan 16 and leaking water to the fan motor 15 side. prevent. Moreover, by making the lower surface of the shielding blade 22 into a wave shape, the mist is diffused to promote atomization.

  Each suction air passage 20 and the first blow-off air passage 18 communicate with each other via a suction air passage communication port 23 formed in the air passage forming wall portion 17. The suction air passage communication port 23 is formed so as to penetrate the upper portion of the air passage forming wall portion 17 higher than the mounting position of the propeller fan 16.

  Here, for example, the upper portion of the suction air passage 20 is configured with a curved surface so that turbulence does not occur when air flows from the suction air passage 20 through the suction air passage communication port 23 to the first blowout air passage 18. To do. For this reason, for example, the four corners of the upper part of the main body case 14 may be configured with curved surfaces having large diameters.

  In addition, the first blowing air passage 18 and the second blowing air passage 19 communicate with each other through a blowing air passage communication port 24 formed in the air passage forming wall portion 17. The blowout air passage connection port 24 is formed so as to penetrate the air passage forming wall portion 17 in the vicinity of the height equivalent to the attachment position of the propeller fan 16, and the mesh plate portion 24a is attached thereto. The net-like plate part 24a is formed of, for example, a fine wire mesh, and atomizes the mist passing through the blowout air passage connection port 24.

  In the main body case 14, the lower part of the first air outlet 18 is opened to form a first air outlet 18 a, and the lower part of each second air outlet 19 is opened to form a second air outlet 19 a. Is formed. Furthermore, the lower part of each suction air path 20 opens, and the suction inlet 20a is formed.

  As a result, an air passage is formed from each suction port 20a through each suction air passage 20 and connected to the first blow-out air passage 18 through the suction air passage communication port 23 to reach the first air outlet 18a. In addition, an air passage is formed from the first air outlet 18 to the second air outlet 19 through the air outlet connecting port 24 to the second air outlet 19a.

  The main body case 14 includes a drain pan 25 that is a drain member at the lower portion of the air passage forming wall portion 17. The drain pan 25 has a ring shape that matches the shape of the air passage forming wall portion 17, has a groove into which the lower end of the air passage forming wall portion 17 is inserted, and is transmitted through the inner peripheral surface and the outer peripheral surface of the air passage forming wall portion 17. Receive drops of water.

  Further, the drain pan 25 is provided with a drain hose port 25a at one place in the circumferential direction so that water received from the air passage forming wall portion 17 can be drained from the drain hose port 25a. For this reason, the drain pan 25 is in an inclined state so that the drain hose port 25a side is lowered. The drain pan 25 may be detachable from the air passage forming wall 17 or the like so that cleaning can be performed.

  The main body case 14 includes a front panel 26 at the bottom. The front panel 26 is configured integrally with the front panel of the bathroom heating / ventilating / drying apparatus 3 shown in FIG. 1, and the main body case 14 includes a hook portion 14a for fixing the front panel 26, and the front panel 26 is detachable. It is attached.

  The front panel 26 includes a blowout grill 26a that communicates with the first blowout port 18a and the second blowout port 19a and blows out the atomized mist. The front panel 26 includes a suction grill 26b that communicates with the suction port 20a and sucks air.

  In the mist generating device 2A, for example, the auxiliary mist nozzle 27 may be provided in the second air outlet 19a so that mist can be preliminarily blown out at the operation start stage or the like. As the auxiliary mist nozzle 27, for example, one of the second air outlets 19a is provided with an auxiliary mist nozzle 27a having a small water droplet diameter of the mist, and the other second air outlet 19a has a coarse water droplet diameter of the mist. It is good also as a structure which is equipped with the auxiliary | assistant mist nozzle 27b and blows off the mist from which a water droplet diameter differs as needed.

  FIG. 4 is a configuration diagram illustrating an example of the supply control valve device 12. The supply control valve device 12 includes a supply switching electromagnetic valve 28 that switches whether hot water or water is supplied, a three-way switching electromagnetic valve 29 that switches a supply destination of hot water or water, and an individual switching electromagnetic that switches a mist nozzle 11A that ejects mist. A valve 30 is provided.

  The supply switching electromagnetic valve 28 is provided in a supply pipe 31 a connected to the heat pump water heater 4 shown in FIG. 1 and switches presence / absence of supply of hot water or water from the heat pump water heater 4. The three-way switching electromagnetic valve 29 is an example of a flow path switching valve and is provided on the downstream side of the electromagnetic valve 28, and switches the supply destination of hot water or water to the mist nozzle 11A or the drain pipe 31b that is a discharge unit.

  The mist generating device 2A of this example includes four mist nozzles 11A, and has a configuration in which hot water or water is supplied to all the mist nozzles 11A by branching a pipe downstream of the three-way switching electromagnetic valve 29. The individual switching electromagnetic valve 30 is provided corresponding to each mist nozzle 11A, and switches the mist nozzle 11A that ejects mist by switching the mist nozzle 11A that supplies hot water or water.

  Further, the supply pipe 31a is provided with a water temperature detection sensor 31c as a water temperature detecting means, and the temperature of the hot water flowing through the supply pipe 31a is detected.

  The drain pipe 31b is connected to a drain pipe (not shown) connected to the drain hose port 25a of the drain pan 25 shown in FIGS. 2 and 3, and drains water outside the building (not shown) where the bathroom 101 shown in FIG. Do.

<Mist ejection operation example of the mist generator of the first embodiment>
Next, an example of the mist ejection operation in the mist generator 2A according to the first embodiment will be described with reference to FIGS. In addition, although hot water or water can be supplied to the mist nozzle 11A, in the following example, hot water shall be supplied.

  The mist generating device 2A switches the supply destination of the hot water to the drain pipe 31b by the three-way switching electromagnetic valve 29 shown in FIG. 4, opens the supply switching electromagnetic valve 28, and when supplying hot water, After draining from the pipe 31b and the water temperature detection sensor 31c detecting a predetermined temperature, the supply destination of the hot water is switched to the mist nozzle 11A by the three-way switching solenoid valve 29, and the individual switching solenoid valve 30 is opened. Hot water is supplied.

  When the fan motor 15 is driven to rotate, the propeller fan 16 of the axial fan unit 13 rotates in the direction indicated by the arrow a in FIG. In this example, the diameter of the propeller fan 16 is set to 150 mm as an example, and the rotation speed of the fan motor 15 is set to 3000 rpm as an example.

  Here, in the mist generating device 2A, when mist ejection is started, the rotation of the fan motor 15 is started, and then the supply of hot water to the mist nozzle 11A is started, so that the propeller fan 16 has a predetermined speed. After the rotation, the ejection of mist from the mist nozzle 11A is started.

  When the propeller fan 16 rotates in the direction of arrow a, the air in the bathroom 101 flows from the suction air passage 20 communicated by the first blow air passage 18 and the suction air passage connection port 23 through the suction grille 26b of the front panel 26. Inhaled.

  The air sucked from the suction grille 26 b of the front panel 26 is sucked from the suction air passage 20 through the suction air passage connection port 23 into the first blowout air passage 18, and passes through the first blowout air passage 18 to the front. It blows out into the bathroom 101 from the blowing grill 26a of the panel 26.

  When the supply of hot water to the mist nozzle 11A is started after the rotation of the propeller fan 16 is started, the mist is ejected from the mist nozzle 11A. Here, the temperature of the mist ejected from the mist nozzle 11A is controlled by the temperature of the hot water supplied from the heat pump hot water supply system 4 to the mist nozzle 11A. The details of the heat pump hot water supply system 4 will be described later.

  The mist ejected from the mist nozzle 11A collides with the blades 16a of the propeller fan 16 and is diffused, and the water droplet diameter becomes finer and atomized. For example, the water droplet diameter is about 3 to 5 microns.

  The mist that has been atomized by colliding with the blades 16a of the propeller fan 16 passes through the first air outlet 18a formed in the axial direction of the propeller fan 16 by the air flow generated by the rotation of the propeller fan 16. The air is blown into the bathroom 101 through the blow grill 26a of the front panel 26.

  Thereby, from the blowing grill 26a of the front panel 26, the mist according to the temperature of the hot water supplied from the heat pump hot water supply system 4 is mixed with the air according to the temperature of the bathroom 101 and blown out. Is warmed while being humidified.

  The mist generating device 2A includes a plurality of mist nozzles 11A, four in this example, and the number of mist nozzles 11A that supply hot water is switched by the individual switching electromagnetic valve 30.

  As a result, the number of mist nozzles 11A that eject mist is switched depending on whether hot water is supplied or not, and the amount of mist ejected from the blow grill 26a of the front panel 26 is increased by increasing the number of mist nozzles 11A that eject mist. Will increase.

  Further, by reducing the number of mist nozzles 11A that eject mist, the amount of mist ejected from the blow grill 26a of the front panel 26 is reduced.

  A part of the mist colliding with the blades 16 a of the propeller fan 16 diffuses in the radial direction of the propeller fan 16. The mist diffused in the radial direction enters the second blowing air passage 19 from the blowing air passage connecting port 24 formed in a part of the outer periphery of the air passage forming wall portion 17 in accordance with the mounting position of the propeller fan 16. Since the blowout air passage connection port 24 is provided with a net-like plate portion 24a composed of a fine wire mesh, the mist passing through the net-like plate portion 24a of the blowout air passage connection port 24 has a finer water droplet diameter. Atomized. The mist atomized through the mesh plate portion 24a of the blowout air passage connection port 24 is blown out into the bathroom 101 from the second blowout port 19a through the blowout grill 26a of the front panel 26.

  A part of the mist that collides with the blade 16 a of the propeller fan 16 and diffuses in the radial direction adheres to the inner peripheral surface of the air passage forming wall portion 17 and is transmitted through the inner peripheral surface of the air passage forming wall portion 17. Fall. A part of the mist that has passed through the blowout air passage connection port 24 adheres to the outer peripheral surface of the air passage forming wall portion 17 and falls along the outer peripheral surface of the air passage forming wall portion 17.

  A drain pan 25 is provided at the lower portion of the air passage forming wall portion 17, and water drops that fall along the inner and outer peripheral surfaces of the air passage forming wall portion 17 are collected by the drain pan 25 and drained from the drain hose port 25 a. . The drain hose port 25a is connected to the outside of the building through a drain hose (not shown), and the water collected by the drain pan 25 is drained outside the building, for example.

  Here, the mist which collided with the blade | wing 16a of the propeller fan 16 and spread | diffused to the radial direction hits the air path formation wall part 17 strongly. In this example, the air passage forming wall portion 17 is supported on the outer peripheral surface by the two opposing two side surfaces of the main body case 14 and the four partition wall portions 17a. Thereby, while preventing the deformation | transformation of the air path formation wall part 17 by water pressure, a collision sound is restrained low.

  Moreover, the mist which collided with the propeller fan 16 and spread | diffused upward is rebounded by the shielding blade | wing 22, and the water leak to the fan motor 15 side is prevented. Moreover, by making the lower surface of the shielding blade 22 into a wave shape, when the mist collides with the shielding blade 22 that is rotationally driven together with the propeller fan 16, it is diffused and atomization is promoted.

  When stopping the mist ejection, the mist generating device 2A stops the rotational drive of the fan motor 15 after a predetermined time has elapsed after stopping the mist ejection from the mist nozzle 11A.

  In addition, after the mist ejection is stopped, the supply switching solenoid valve 28 and the individual switching solenoid valve 30 are closed, and drainage is performed from the drain pipe 31b connected to the three-way switching solenoid valve 29, so that no accumulated water remains. In this way, it is possible to prevent the adhesion of chlorine and impurities and dripping of water.

  Here, the time from when the mist ejection from the mist nozzle 11A is stopped to when the rotational drive of the fan motor 15 is stopped is, for example, the time from when the water droplets attached to the propeller fan 16 etc. are blown off and dried. Etc. are set in consideration. This prevents water droplets from falling from the blowout grill 26a of the front panel 26 after the operation of the mist generator 2A is stopped.

  In the mist generating device 2A, as described above, there is a time lag from when the propeller fan 16 starts to rotate until the mist is ejected by the mist nozzle 11A. For this reason, when the propeller fan 16 starts rotating, the mist may be ejected from the auxiliary mist nozzle 27a and the auxiliary mist nozzle 27b until the mist ejection from the mist nozzle 11A is started.

  The auxiliary mist nozzles 27a and 27b can warm the washing area of the bathroom 101 simultaneously with the start of the rotation of the propeller fan 16 by setting the mist blowing direction as the washing area direction of the bathroom 101.

  It should be noted that the timing of stopping the mist ejection from the auxiliary mist nozzles 27a and 27b is a predetermined time after the mist ejection is started by the mist nozzle 11A or after the mist ejection is started by the mist nozzle 11A. Later. Furthermore, the timing for stopping the mist ejection from the auxiliary mist nozzles 27a and 27b is not the time, but the temperature and humidity in the bathroom 101 are detected by a detection means (not shown) and stopped when the temperature and humidity reach a predetermined level. You may make it do.

<Configuration Example of Bathroom Heating Ventilation Drying Device of First Embodiment>
5 and 6 show a first embodiment of the bathroom heating / ventilating / drying apparatus 3, and the configuration of the bathroom heating / ventilating / drying apparatus 3A according to the first embodiment will be described. Here, FIG. 5 is a cross-sectional view showing the internal configuration of the bathroom heating / ventilation drying apparatus 3A, and FIG. 6 is a plan view of the bathroom heating / ventilation drying apparatus 3A as viewed from the lower surface side.

  3A of bathroom heating ventilation drying apparatuses of 1st Embodiment are provided with the fan unit 32 and the heater part 33 as a heat source. In the bathroom heating / ventilating / drying apparatus 3 </ b> A, the fan unit 32 is attached to the main body case 34. The fan unit 32 includes a multi-blade impeller (fan) 35 that is rotationally driven, a fan motor 36 that rotationally drives the impeller 35, and a fan case 37 that is attached with the fan motor 36 and forms an air passage. .

  The fan unit 32 has an impeller 35 arranged vertically, and the fan case 37 has a lower surface along the axial direction of the impeller 35 that opens to form a suction port 38. In addition, the fan case 37 is provided with an air path switching unit 39 that is open on one side surface along the tangential direction of the impeller 35.

  The air path switching unit 39 includes a damper 40 that switches the air path. The damper 40 receives a driving force of a damper motor, which will be described later, via a cam 40a, and rotates around a shaft 40b to perform an opening / closing operation. The fan case 37 communicates with the air path switching unit 39 and includes a blower outlet 41 on the lower surface thereof, and communicates with the air path switching unit 39 and includes an exhaust port 42 on one side surface. An air passage communicating from the air outlet 38 to the air outlet 41 or an air passage communicating to the exhaust port 42 is formed.

  FIG. 5A shows a state where the damper 40 is fully closed. When the damper 40 is fully closed, the air passage to the exhaust port 42 is blocked, and a circulation air passage 43 a communicating from the suction port 38 to the blower outlet 41 is formed. For this reason, the position where the damper 40 is fully closed is referred to as the circulation position of the damper 40.

  FIG. 5B shows a state where the damper 40 is fully opened. When the damper 40 is fully opened, the air path to the air outlet 41 is blocked, and a ventilation air path 43b communicating from the suction port 38 to the exhaust port 42 is formed. For this reason, the position where the damper 40 is fully opened is referred to as a ventilation position of the damper 40.

  FIG. 5C shows a state in which the damper 40 is at an intermediate position between the circulation position and the ventilation position. When the damper 40 is set at an intermediate position between the circulation position and the ventilation position, both a circulation air path 43a communicating from the intake port 38 to the outlet 41 and a ventilation air path 43b communicating from the intake port 38 to the exhaust port 42 are formed. . This intermediate position is referred to as a circulation ventilation position.

  The fan case 37 includes an ion generator 44 on the upstream side of the heater unit 33. The ion generator 44 is an example of an ion generating means, and an ion emission surface is exposed to a circulation air passage 43a formed by setting the damper 40 to a circulation position or a circulation ventilation position.

The ion generator 44 generates both positive ions and negative ions or negative ions. The principle of generation of positive ions and negative ions is that a corona discharge is caused by boosting and applying an AC voltage taken from a household AC power source or the like between a pair of electrodes opposed so as to interpose a dielectric, Oxygen or water in the air is ionized by receiving energy by ionization, and H ⁺ (H ₂ O) _m (m is an arbitrary natural number) and O ₂ ⁻ (H ₂ O) _n (n is an arbitrary natural number). The main ions are emitted.

These H ⁺ (H ₂ O) _m and O ₂ ⁻ (H ₂ O) _n adhere to the surface of the floating bacteria and chemically react to generate H ₂ O ₂ or .OH as an active species. Since H ₂ O ₂ or .OH exhibits a very strong activity, they can surround and inactivate airborne bacteria in the air. Here, .OH is one kind of active species, and represents radical OH.

  Thus, in association with the operation of the fan unit 32, approximately the same number of positive ions and negative ions are generated, and air containing substantially the same number of positive ions and negative ions is blown, whereby floating bacteria contained in the circulating air and It is possible to inactivate both airborne bacteria in the air in the bathroom 101 shown in FIG.

  The heater unit 33 is an example of a heating unit constituted by an electric heater, and is provided in the above-described air outlet 41. As shown in FIG. 5A, when the position of the damper 40 is set to the circulation position and the impeller 35 is rotationally driven by the fan motor 36, air is sucked from the suction port 38 and passes through the circulation air passage 43a from the blower outlet 41. Blow out. When the heater unit 33 is energized, the heater unit 33 is heated to heat the air passing through the outlet 41 and warm air is blown out from the outlet 41. Here, as the heater unit 33, for example, a PTC heater is provided.

  As shown in FIG. 6, the lower surface of the main body case 34 is opened to expose the air inlet 38 and the air outlet 41 of the fan unit 32. The main body case 34 has the front panel 26 attached to the lower surface opening.

  The front panel 26 is configured integrally with the front panel 26 of the mist generating apparatus 2 </ b> A described with reference to FIGS. 2 and 3 and is configured to be detachable from the main body case 34. The front panel 26 includes a suction grill 45 facing the suction port 38 of the fan unit 32 and a blow grill 46 facing the blow outlet 41 of the fan unit 32. The front panel 26 is attached to the back side of the suction grill 45 so that the filter 47 can be replaced.

  Furthermore, the main body case 34 includes an exhaust duct connection portion 48 communicating with the exhaust port 42 of the fan unit 32 on one side surface. In the bathroom heating / ventilating / drying apparatus 3 </ b> A, the exhaust duct connection unit 48 is connected to the exhaust duct 8 shown in FIG. 1.

  In the bathroom heating / ventilating / drying apparatus 3A, when the fan motor 36 is driven to rotate, the impeller 35 of the fan unit 32 rotates. When the impeller 35 is driven to rotate, the air in the bathroom 101 is sucked from the suction port 38 of the fan unit 32 through the suction grill 45 of the front panel 26.

  If the position of the damper 40 is the circulation position shown in FIG. 5A, the circulation air passage 43a from the suction port 38 to the blowout port 41 is formed in the fan unit 32, so that the air sucked from the suction port 38 is Then, the air passes through the circulation air passage 43a and is blown out from the air outlet 41 into the bathroom 101 through the air outlet grill 46 of the front panel 26.

  Since the heater part 33 is arrange | positioned in the blower outlet 41 of the circulation air path 43a, the air which passes along the circulation air path 43a is warmed by driving the heater part 33, and it blows off from the blowing grill 46a.

  Thus, when the fan motor 36 is rotationally driven with the damper 40 as the circulation position, when the heater unit 33 is driven, hot air is blown into the bathroom 101 while circulating the air in the bathroom 101.

  If the position of the damper 40 is the ventilation position shown in FIG. 5B, the ventilation air passage 43b from the suction port 38 to the exhaust port 42 is formed in the fan unit 32, so that the air sucked from the suction port 38 is Then, the air passes through the ventilation air passage 43b and the exhaust port 42, and further passes through the exhaust duct 8 shown in FIG.

  Thereby, when the fan motor 36 is rotationally driven with the damper 40 as the ventilation position, steam and moisture in the bathroom 101 are exhausted.

  When the position of the damper 40 is the circulation ventilation position shown in FIG. 5C, the circulation air path 43 a from the suction port 38 to the blowout port 41 and the ventilation airflow path from the suction port 38 to the exhaust port 42 in the fan unit 32. Since both of 43b are formed, a part of the air sucked from the suction port 38 passes through the circulation air passage 43a and is blown into the bathroom 101 from the blower outlet 41 through the blowout grill 46 of the front panel 26.

  Further, a part of the air sucked from the suction port 38 passes through the ventilation air passage 43b and the exhaust port 42, and is further exhausted from the exhaust grill 8a to the outside through the exhaust duct 8 shown in FIG.

  Thereby, when the fan motor 36 is rotationally driven with the damper 40 as the circulation ventilation position, when the heater unit 33 is not driven, the steam and moisture in the bathroom 101 are exhausted while circulating the air in the bathroom 101. Is done.

  In addition, when the heater unit 33 is driven, steam and moisture in the bathroom 101 are exhausted while circulating the air in the bathroom 101 and blowing hot air into the bathroom 101.

<Configuration example of heat pump hot water supply system of the first embodiment>
FIG. 7 shows a first embodiment of the heat pump hot water supply system 4, and then the configuration of the heat pump hot water supply system 4A of the first embodiment will be described. Here, FIG. 7 is a block diagram showing an outline and connection form of the heat pump hot water supply system 4A.

  The heat pump hot water supply system 4A of the first embodiment includes a mist generator 2 (2A) shown in FIG. 1, a heat pump water heater 51A that supplies hot water to the bathroom 101 and the like, and the temperature of hot water supplied to the mist generator 2 And a temperature / pressure control device 52A for controlling the hot water supply pressure.

  The heat pump water heater 51A includes a heat pump unit 53 that generates hot water by heat exchange between the atmosphere and the refrigerant and heat exchange between the refrigerant and water, and a hot water storage tank unit 54 that stores the hot water generated by the heat pump unit 53. Is provided.

  The heat pump unit 53 performs heat exchange between the air and the refrigerant, and raises the temperature of the water by exchanging heat between the air heat exchanger 55 that raises the temperature of the refrigerant and the refrigerant and water. A water heat exchanger 56 is provided.

  The heat pump unit 53 connects the air heat exchanger 55 and the water heat exchanger 56 to the air heat exchanger 55 by connecting the air heat exchanger 55 and the water heat exchanger 56 to the air heat exchanger 55. 56 is provided with a refrigerant pipe 57 for circulating the refrigerant to and from 56.

  Furthermore, the heat pump unit 53 compresses the refrigerant that flows through the refrigerant pipe 57 after being heat-exchanged by the air heat exchanger 55 between the air heat exchanger 55 and the water heat exchanger 56 on the downstream side of the air heat exchanger 55. And a compressor 58 for further raising the temperature. Further, the heat pump unit 53 expands the refrigerant that flows through the refrigerant pipe 57 after being heat-exchanged by the water heat exchanger 56 between the air heat exchanger 55 and the water heat exchanger 56 on the downstream side of the water heat exchanger 56. And an expansion valve 59 for lowering the temperature.

  The hot water storage tank unit 54 includes a tank 60 that stores the hot water generated by the heat pump unit 53. The tank 60 stores hot water in a stratified state in which water is supplied to the lower side and hot water is supplied to the upper side, and the temperature on the upper side is higher than that on the lower side.

  In the heat pump unit 53 and the hot water storage tank unit 54, the water heat exchanger 56 and the tank 60 are connected by a hot water pipe 61a and a cold water pipe 61b, and the cold water pipe 61b includes a pump 61c.

  The hot water pipe 61 a connects between the outflow side of the water heat exchanger 56 and the inflow port 60 a provided on the upper side of the tank 60. The cold water pipe 61 b connects between the inflow side of the water heat exchanger 56 and the outlet 60 b provided on the lower side of the tank 60.

  The pump 61c sucks water from the outlet 60b of the tank 60 through the cold water pipe 61b and supplies it to the water heat exchanger 56, and the hot water generated through the water heat exchanger 56 is passed through the hot water pipe 61a. The tank 60 is supplied from the inlet 60a.

  In addition, the hot water storage tank unit 54 is connected to the tank 60 with a water intake pipe 62 for taking in hot water stored in the tank 60 and a water supply pipe 63 for supplying water to the tank 60.

  The intake pipe 62 includes a high-temperature portion intake pipe 62a connected to a high-temperature portion intake port 60c provided at the upper part of the tank 60 independently of the inflow port 60a, and an intermediate-temperature portion intake port provided below the high-temperature portion intake port 60c. An intermediate temperature intake pipe 62b connected to 60d is provided.

  In addition, the intake pipe 62 includes a switching valve 62c at the junction of the high temperature portion intake pipe 62a and the intermediate temperature portion intake pipe 62b, and the intake source in the tank 60 is switched to the high temperature portion intake port 60c or the intermediate temperature portion intake port 60d.

  The water supply pipe 63 is connected to a water supply port 60e provided in the lower part of the tank 60 independently of the outlet 60b, and includes a branch water supply pipe 63a branched in front of the tank 60.

  Furthermore, the hot water storage tank unit 54 includes a hot water supply mixing valve 64 that mixes hot water supplied from the intake pipe 62 and water supplied from the branch water supply pipe 63a. The hot water supply mixing valve 64 is provided at the junction of the water intake pipe 62 and the branch water supply pipe 63a, and switches the mixing ratio of the hot water supplied from the water intake pipe 62 and the water supplied from the branch water supply pipe 63a to the hot water supply pipe 65. Adjust the temperature of hot water supplied from.

  The hot water supply pipe 65 is connected to the shower 101a and the bathtub 101b of the bathroom 101 shown in FIG. 1, the faucet 102a of the washroom 102, the faucet (not shown) of the kitchen 103, and the like, and supplies hot water.

  Further, the mist hot water supply pipe 65a is branched from the hot water supply pipe 65 connected to the bathroom 101, and the temperature / pressure control device 52A is connected to the mist hot water supply pipe 65a.

  The temperature / pressure control device 52A includes a pressurizing device 66 that increases the hot water supply pressure of hot water supplied from the heat pump water heater 51A, and a heating device 67 that increases the temperature of the hot water whose hot water pressure is increased.

  The pressurization device 66 is, for example, a pressurization pump provided in the mist hot water supply pipe 65a, and increases the hot water supply pressure by increasing the amount of water supplied. The heating device 67 is, for example, a hot water circulation type heating device that circulates hot water through a pipe (not shown) arranged around the mist hot water supply pipe 65a and heats the hot water flowing through the mist hot water supply pipe 65a.

  Further, the temperature / pressure control device 52 </ b> A includes a mixing valve 68 that mixes hot water supplied from the mist hot water supply pipe 65 a and water supplied from the mist water supply pipe 63 b branched from the water supply pipe 63. The mixing valve 68 is provided at the junction of the mist hot water supply pipe 65a and the mist water supply pipe 63b on the downstream side of the heating device 67, and hot water whose temperature has been raised by the heating device 67 and water supplied from the mist water supply pipe 63b. Change the mixing ratio.

  The mist generator 2 shown in FIG. 1 and the like is connected to a mist hot water supply pipe 65 a on the downstream side of the mixing valve 68. For example, a mist hot water supply pipe 65a on the downstream side of the mixing valve 68 is connected to the supply pipe 31a shown in FIG.

  Thereby, the mixing ratio 68 of the hot water whose temperature has been raised by the heating device 67 and the water supplied from the mist water supply pipe 63b are switched by the mixing valve 68, so that the hot water supplied to the mist generating device 2 (2A) The temperature is adjusted.

<Operation Example of Heat Pump Hot Water Supply System of First Embodiment>
Next, the operation of the heat pump hot water supply system 4A will be described. In the heat pump hot water supply system 4 </ b> A, water is supplied from the water supply pipe 63 to the tank 60 of the hot water storage tank unit 54. The water supplied to the tank 60 is supplied to the water heat exchanger 56 of the heat pump unit 53 through the cold water pipe 61b.

  In the heat pump unit 53, the air is supplied to the air heat exchanger 55 by the fan 55a, heat exchange is performed with the refrigerant flowing through the refrigerant pipe 57, and the temperature of the refrigerant rises. The refrigerant whose heat has been exchanged by the air heat exchanger 55 is compressed by the compressor 58, whereby the temperature further rises.

  The refrigerant that has been compressed by the compressor 58 and raised in temperature is supplied to the water heat exchanger 56. Thereby, in the water heat exchanger 56, heat exchange is performed between the refrigerant whose temperature has been increased by heat exchange and compression with the atmosphere and the water supplied from the hot water storage tank unit 54, and hot water is generated. The

  The refrigerant heat-exchanged by the water heat exchanger 56 is expanded by the expansion valve 59 to lower the temperature, and is supplied to the air heat exchanger 55 again.

  Moreover, the hot water produced | generated by exchanging heat with the water heat exchanger 56 is returned to the tank 60 by the hot water piping 61a. Thereby, the tank 60 stores hot water and water in a state where the upper side is stratified with a high temperature and the lower side with a low temperature.

  The hot water stored in the tank 60 is taken in by the intake pipe 62. Here, when the temperature of the supplied hot water is high, hot water is taken from the high temperature portion intake pipe 62a by the switching valve 62c, and when the temperature of the supplied hot water is low, the hot water is taken from the intermediate temperature portion intake pipe 62b.

  The hot water taken by the water intake pipe 62 is mixed with the water supplied from the branch water supply pipe 63 b by the hot water supply mixing valve 64. The temperature of hot water supplied from the hot water supply pipe 65 is adjusted by switching the mixing ratio of hot water and water with the hot water supply mixing valve 64. The hot water supplied from the hot water supply pipe 65 is distributed to the bathroom 101, the washroom 102, and the kitchen 103.

  On the other hand, the hot water supplied from the hot water supply pipe 65 is supplied to the mist generator 2 (2A) by the mist hot water supply pipe 65a after the temperature and the hot water supply pressure are controlled by the temperature / pressure control device 52A. That is, the temperature / pressure control device 52A raises the hot water supply pressure of the hot water supplied to the mist hot water supply pipe 65a by the pressurization device 66. Thereby, the hot water supplied from the heat pump water heater 51A is raised to a hot water supply pressure suitable for generating mist in the mist generator 2 (2A).

  The hot water supplied to the mist hot water supply pipe 65a and having the hot water supply pressure raised by the pressurizing device 66 is heated by the heating device 67 to raise the temperature. The hot water supplied from the heat pump water heater 51A is limited to the hot water supply temperature set in the bathroom 101 or the like, but the temperature is raised by the heating device 67 of the temperature / pressure control device 52A, so that the heat pump water heater 51A side Regardless of the limitation of the hot water supply temperature, the temperature of the hot water supplied to the mist generator 2 (2A) is controlled.

  For example, the temperature of the hot water supplied to the mist generator 2 (2A) can be raised from the hot water supply temperature of the hot water supplied from the heat pump water heater 51A. Further, by mixing the hot water supplied from the mist hot water supply pipe 65a with a controlled hot pressure and the water supplied from the mist hot water supply pipe 63b by the mixing valve 68, the mixing ratio of the hot water and water is switched to generate mist. The temperature of the hot water supplied to the apparatus 2 (2A) can be controlled. For example, it is possible to supply only water.

<Control function example of the bathroom heating system of the first embodiment>
FIG. 8 is a functional block diagram showing an example of a control system of the bathroom heating system 1A according to the first embodiment. Next, the mist generator 2A, the bathroom heating / ventilating / drying apparatus 3A, and the heat pump hot water supply system 4A are provided. The configuration of the control system of the bathroom heating system 1A will be described.

  The bathroom heating system 1A is controlled by, for example, the main control unit 5 provided in the bathroom heating ventilation drying apparatus 3A. The main control unit 5 is an example of a control unit, such as the heater unit 33, the fan motor 36, the ion generator 44, the damper motor 40b for driving the damper 40, etc. Is connected.

  The main control unit 5 includes the fan motor 15 of the mist generating device 2A described with reference to FIGS. 2 and 3, the supply switching solenoid valve 28 and the three-way switching solenoid valve 29 of the supply control valve device 12 described with reference to FIG. The switching electromagnetic valve 30 and the water temperature detection sensor 31c are connected.

  Furthermore, the main controller 5 is connected to the pressurization device 66, the heating device 67, the mixing valve 68, and the like of the temperature / pressure control device 52A of the heat pump hot water supply system 4A described with reference to FIG.

  In order to detect the temperature of the bathroom 101, for example, a temperature detection sensor 69 is attached to the suction port 38 of the fan case 32, for example, inside the front panel 26 of the bathroom heating / ventilation / drying apparatus 3 </ b> A. Is connected to the main control unit 5.

  The main control unit 5 is connected to a main operation unit 6 and a mist operation unit 7. As described with reference to FIG. 1, the main operation unit 6 is connected, for example, by wire, and the mist operation unit 7 is connected wirelessly.

  The main control unit 5 includes a CPU, a memory, and the like (not shown), and according to operations in the main operation unit 6 and the mist operation unit 7 and a program stored in advance, the mist generating device 2A, the bathroom heating ventilation drying device 3A, The temperature / pressure control device 52A of the heat pump hot water supply system 4A is controlled.

  That is, the main control unit 5 controls the temperature / pressure control device 52A of the bathroom heating / ventilation / drying device 3A, the mist generating device 2A, and the heat pump hot water supply system 4A according to a predetermined operation in the main operation unit 6 and the mist operation unit 7, The mist mode for performing mist heating of the bathroom 101 shown in FIG. 1 is executed by interlocking the bathroom heating / ventilating / drying apparatus 3A and the mist generating apparatus 2A.

  The main control unit 5 controls the bathroom heating / ventilation / drying device 3A according to a predetermined operation in the main operation unit 6 as a single operation of the bathroom heating / ventilation / drying device 3A. A ventilation mode for ventilating 101, a drying mode for drying clothes or the like dried in the bathroom 101, and a cool air mode for blowing air to a bather or the like are selectively executed.

  FIG. 9 is a configuration diagram illustrating an example of the main operation unit 6. The main operation unit 6 is an example of main operation means, and includes a display unit 71 and various operation buttons. The main operation unit 6 includes, as an operation button, a mist mode button 72 for selecting a mist mode for performing mist heating of the bathroom 101 by interlocking the bathroom heating / ventilating / drying device 3A and the mist generating device 2A.

  Further, as a single operation of the bathroom heating / ventilation drying apparatus 3A, a heating mode button 73 for selecting a heating mode, a ventilation mode button 74 for selecting a ventilation mode, a drying mode button 75 for selecting a drying mode, and a cool air mode are selected. A cool breeze mode button 76 is provided. Furthermore, a setting button 77 for performing various settings is provided. In order to make the selected operation mode visible, a lamp 78 may be provided corresponding to each button.

  FIG. 10 is a configuration diagram illustrating an example of the mist operation unit 7. The mist operation unit 7 is an example of a sub-operation means, and includes an operation selection button 79 for selecting operation and stop of operation in the mist mode, and a temperature setting button 80 for setting the temperature (warming state) in the bathroom 101 in the mist mode. Prepare.

  In this example, since the temperature setting is performed by switching the amount of mist ejection, for example, a “strong” button 80a, a “medium” button 80b, and “weak” are displayed as the temperature setting button 80, for example, to indicate the amount of mist ejection. ] Button 80c.

<Operation example of the bathroom heating system according to the first embodiment>
Next, operation | movement of 1 A of bathroom heating systems of 1st Embodiment provided with the mist generator 2A mentioned above, the bathroom heating ventilation drying apparatus 3A, and the heat pump hot-water supply system 4A is demonstrated.

  In the bathroom heating system 1A of the first embodiment, the bathroom 101 is heated by the bathroom heating / ventilating / drying apparatus 3A while the mist is jetted by the mist generating apparatus 2A, and the bathroom 101 is in a mist sauna state of medium temperature and high humidity. Mist mode is executed.

  In the mist mode, the main control unit 5 is taking a bath as a first mist mode in which the bathroom 101 is heated in advance before taking a bath and in a second mist mode in which the bathroom 101 is heated during taking a bath. Execute by switching the mist mode. Moreover, when mist mode is complete | finished by operation of a bather etc., the post-mist ventilation mode which ventilates the bathroom 101 is performed.

  FIG. 11 is an operation table showing a combination pattern of operations of the respective parts of the mist generating device 2A when the mist mode is executed.

  In the operation table shown in FIG. 11, whether or not the fan motor 15 of the mist generating device 2A is driven is set for each operation mode that is switched when the mist mode is executed. In this example, the fan motor 15 is always driven during the mist ejection.

  In the operation table shown in FIG. 11, the number of mist nozzles 11 </ b> A that eject mist is set so as to be switchable depending on the operation mode that is switched when the mist mode is executed and the selection of a bather or the like.

  Here, the operation pattern of the mist generator 2A shown in FIG. 11 is an example.

  FIG. 12 is an operation table showing a pattern of combinations of operations of the respective parts of the bathroom heating / ventilating / drying apparatus 3A when the mist mode is executed.

  The operation table shown in FIG. 12 is set so that the number of rotations of the fan motor 36 of the bathroom heating / ventilating / drying apparatus 3A can be switched between, for example, “strong” and “standard” for each operation mode switched when the mist mode is executed. The Further, the position of the damper 40 is set for each operation mode. Further, whether or not the heater unit 33 is driven is set for each operation mode.

  Here, what is described in FIG. 12 is an example of the operation pattern of the bathroom heating / ventilating / drying apparatus 3A when the mist mode is executed.

<Operation example of mist mode of the first embodiment>
FIG. 13 is a flowchart showing the first embodiment of the mist mode executed in the bathroom heating system 1A of the first embodiment. Next, the processing at the time of executing the mist mode of the first embodiment The flow will be described.

  Step SA1: A bather or the like presses the mist mode button 72 of the main operation unit 6 installed in the bathroom undressing place 102 to turn on the mist mode switch to heat the bathroom 101 before bathing.

  Step SA2a: When the mist mode button 72 of the main operation unit 6 is pressed, the main control unit 5 determines that the mist mode is selected, and first executes the pre-bath mist mode as the mist mode.

  In the pre-bathing mist mode, the main control unit 5 controls the mist generating device 2A according to the operation table of FIG. 11, rotates the propeller fan 16 by rotating the fan motor 15 as described above, and the first ejection amount The supply control valve device 12 is controlled so that mist is ejected from all the mist nozzles 11A so as to obtain the pre-bath ejection amount.

  As a result, the mist generating device 2 </ b> A ejects the mist atomized by the propeller fan 16 from the blowing grill 26 a of the front panel 26 into the bathroom 101.

  The mist ejected by the mist generating device 2A uses the hot water generated by the heat pump hot water supply unit 4A described with reference to FIG. In the heat pump hot water supply system 4A, the temperature and the hot water supply pressure of the hot water supplied to the mist generator 2A are controlled by the temperature / pressure controller 52A as described above.

  Thus, the hot water supplied from the heat pump water heater 51A is pressurized to a hot water pressure suitable for generating mist at the mist nozzle 11A, regardless of the control of the hot water pressure at the heat pump water heater 51A.

  Moreover, the hot water supplied from the heat pump water heater 51A is a temperature suitable for setting the bathroom 101 in the mist sauna state (for example, about 60 ° C.) regardless of the limitation of the hot water temperature set in the shower or the like of the bathroom 101. ). Accordingly, the mist is ejected from the mist nozzle 11A at a desired temperature and ejection amount.

  In the mist mode before bathing, since the mist is ejected from all the mist nozzles 11A, in this example, all of the four mist nozzles 11A, the amount of mist ejection is maximized.

  Step SA2b: In the pre-bath mist mode, the main control unit 5 controls the bathroom heating / ventilating / drying device 3A according to the operation table of FIG. 12 so that the fan airflow becomes “strong” as the pre-bath heating airflow that is the first airflow. In addition to controlling the fan motor 36, the heater 33 is energized. Moreover, let the damper 40 be a circulation position.

  Thereby, 3 A of bathroom heating ventilation drying apparatuses blow off warm air in the bathroom 101 from the blowing grill 46 of the front panel 26, circulating the air in the bathroom 101. FIG. In the bathroom heating / ventilating / drying apparatus 3A, an electric heater such as a PTC heater is used as the heater unit 33. Therefore, the time from the start of energization to the heating of the heater unit 33 to a predetermined temperature is short. The rise time until blowing out is short.

  And in the mist mode before bathing, since the fan air volume in the fan unit 32 is set to "strong", the blowing amount of warm air increases.

  Therefore, in the mist mode before bathing, the mist is generated by the mist generating device 2A at the maximum and the hot air is blown out with the fan air flow set to “strong” by the bathroom heating / ventilating / drying device 3A. It can be set as the mist sauna state of medium temperature high humidity (temperature 40-45 degreeC, humidity 100%).

  Step SA3: The main control unit 5 detects the temperature of the bathroom 101 by the temperature detection sensor 69 provided in the suction port 38 of the fan unit 32 in order to detect that a predetermined state is reached when the pre-bath mist mode is started. . When the temperature of the bathroom 101 has not reached the predetermined upper limit value of the heating temperature before bathing, the main control unit 5 continues the mist mode before bathing.

  Step SA4a: When determining that the temperature of the bathroom 101 has reached the upper limit value of the heating temperature before bathing from the output of the temperature detection sensor 69, the main control unit 5 switches the operation mode from the mist mode before bathing to the mist mode during bathing.

  That is, in the mist mode during bathing, the main control unit 5 controls the mist generating device 2A according to the operation table of FIG. 11, and sets the setting information according to the set temperature selected by the temperature setting button 80 of the mist operating unit 7. Switch to the amount of mist ejection.

  Here, the main control unit 5 stores information on the set temperature selected by the mist operation unit 7 at the previous execution of the mist mode, and when the operation mode is switched to the bathing mist mode, the set temperature at the previous operation is stored. The number of mist nozzles 11A that eject mist is switched according to the information.

  For example, when the “strong” button 80a in the temperature setting button 80 is pressed by the mist operation unit 7 during the previous operation, the main control unit 5 causes the mist from all the mist nozzles 11A according to the operation table of FIG. Continue to erupt.

  Further, when the “middle” button 80 b is pressed in the mist operation unit 7 during the previous operation, the main control unit 5 controls the individual switching electromagnetic valve 30 of the supply control valve device 12 to eject the mist. Is switched to “3” in this example.

  Further, when the “weak” button 80c is pressed in the mist operation unit 7 during the previous operation, the main control unit 5 controls the individual switching electromagnetic valve 30 of the supply control valve device 12 to eject the mist. Is switched to “2” in this example.

  Note that the initial value of the number of mist nozzles 11A that eject mist in the mist mode during bathing during the first operation is set to “4” in this example.

  Step SA4b: In the bathing mist mode, the main control unit 5 controls the bathroom heating / ventilating / drying device 3A according to the operation table of FIG. 12 so that the fan airflow becomes “standard” as the heating airflow during bathing which is the second airflow. In addition, the fan motor 36 is controlled and energization to the heater unit 33 is continued. Further, the damper 40 holds the circulation position.

  As a result, the bathroom heating / ventilating / drying apparatus 3A circulates the air in the bathroom 101 and blows out hot air from the blowing grill 46 of the front panel 26 with a smaller fan air volume than in the mist mode before bathing.

  Therefore, in the mist mode during bathing, the amount of mist ejected by the mist generating device 2A is switched according to the selection by the temperature setting button 80 of the mist operating unit 7, and the fan airflow is changed to “standard” by the bathroom heating ventilation drying device 3A. By blowing out the warm air as “,” it is possible to prevent the warm air from directly hitting the bather and to keep the inside of the bathroom 101 in the mist sauna state while suppressing the temperature rise in the bathroom 101.

  Step SA5: When the main control unit 5 switches the operation mode to the bathing mist mode, the temperature detection sensor 69 detects the temperature of the bathroom 101. The main control unit 5 sets the upper limit value of the temperature in the bathroom 101 for each set temperature corresponding to the amount of mist ejected selected by the temperature setting button 80 of the mist operation unit 7, and the temperature of the bathroom 101 is selected. If the upper limit of the set temperature has not been reached, continue the mist mode during bathing.

  Step SA6a: When the main control unit 5 determines from the output of the temperature sensor 69 that the temperature of the bathroom 101 has reached the upper limit value of the set temperature corresponding to the selected mist ejection amount, the operation mode is set to the bathing mist mode. Switch to mist output reduction mode during bathing.

  That is, in the mist output lowering mode during bathing, the main control unit 5 controls the mist generating device 2A according to the operation table of FIG. 11 to reduce the number of mist nozzles 11A that eject mist. In this example, the individual switching electromagnetic valve 30 of the supply control valve device 12 is controlled to switch the number of mist nozzles 11A that eject mist to, for example, “1”.

  Step SA6b: In the bathing mist output lowering mode, the main controller 5 controls the bathroom heating / ventilating / drying device 3A according to the operation table of FIG. 12, stops the fan motor 36, and stops energizing the heater 33. Then, the operation of the bathroom heating ventilation drying apparatus 3A is stopped.

  Step SA7: When the operation mode is switched to the bathing mist output lowering mode, the main control unit 5 detects the temperature of the bathroom 101 by the temperature detection sensor 69. The main control unit 5 sets the lower limit value of the temperature in the bathroom 101 for each set temperature corresponding to the amount of mist ejected selected by the temperature setting button 80 of the mist operation unit 7, and the temperature of the bathroom 101 is selected. If the lower limit of the set temperature has not been reached, the mist output lowering mode is continued during bathing.

  If the main control unit 5 determines from the output of the temperature sensor 69 that the temperature of the bathroom 101 has reached the lower limit value of the selected set temperature, the main control unit 5 returns to step SA4 described above and sets the operation mode to the bathing mist mode. Switch.

  That is, the main control unit 5 increases the number of mist nozzles 11A that eject mist according to the operation table of FIG. 11 according to the set temperature selected by the temperature setting button 80 of the mist operation unit 7, and The operation of the bathroom heating / ventilation / drying apparatus 3A is resumed according to the operation table.

  Step SA8: The main control unit 5 monitors the output of the mist operation unit 7 during execution of the mist mode during bathing.

  Step SA9: When determining that the temperature setting button 80 has been pressed from the output of the mist operation unit 7, the main control unit 5 controls the mist generating device 2A according to the operation table shown in FIG. The number of mist nozzles 11 </ b> A that eject mist is switched according to the set temperature selected by the button 80. In the bathroom heating / ventilating / drying apparatus 3A, the fan motor 36 is controlled so that the fan airflow becomes “standard”, and energization to the heater unit 33 is continued.

  Next, a process for stopping the mist mode will be described. Here, the stop of the mist mode is executed by pressing the mist mode button 72 of the main operation unit 6 or the operation selection button 79 of the mist operation unit 7.

  Step SA10a-1: The bather presses the mist mode button 72 of the main operation unit 6 to turn off the mist mode switch.

  Step SA10a-2: When the mist mode button 72 of the main operation unit 6 is pressed, the main control unit 5 controls the supply control valve device 12 to stop the supply of hot water to all the mist nozzles 11A and The rotation drive of the motor 15 is stopped. Thereby, the ejection of mist from the mist generator 2A is stopped.

  Step SA10b-1: The bather presses the operation selection button 79 of the mist operation unit 7 to turn off the mist mode switch.

  Step SA10b-2: When the operation selection button 79 of the mist operation unit 7 is pressed, the main control unit 5 controls the supply control valve device 12 to stop the supply of hot water to all the mist nozzles 11A and The rotation drive of the motor 15 is stopped. Thereby, the ejection of mist from the mist generator 2A is stopped.

  Step SA10b-3: When the operation selection button 79 of the mist operation unit 7 is pressed to stop the mist generating device 2A, the main control unit 5 measures the preset heating operation time. The heating operation time is the time from when the mist is stopped to the operation mode until the operation mode is switched to the post-mist ventilation mode.

  If the operation selection button 79 of the mist operation unit 7 is pressed during the execution of the mist mode during bathing, it is considered that the bather is still in the bathroom 101. When the bather is in the bathroom 101 and the heating by the bathroom heating / ventilation drying apparatus 3A is stopped and the post-mist ventilation mode is executed, the bather feels cold. For this reason, when the operation selection button 79 of the mist operation unit 7 is operated during execution of the mist mode during bathing, the heating operation time is set and the operation of the bathroom heating / ventilation drying apparatus 3A in the heating mode is continued. The heating operation time is set to about 30 minutes, for example.

  Step SA11: When the mist button 72 of the main operation unit 6 is pressed to stop the mist generating device 2A, the main control unit 5 controls the bathroom heating ventilation drying device 3A according to the operation table of FIG. The operation mode of the drying device 3A is switched to the post-mist ventilation mode.

  Further, after the operation selection button 79 of the mist operation unit 7 is pressed and the mist generating device 2A is stopped, the main control unit 5 stops bathroom heating ventilation drying according to the operation table of FIG. The device 3A is controlled to switch the operation mode of the bathroom heating ventilation drying device 3A to the post-mist ventilation mode.

  That is, the main control unit 5 controls the fan motor 36 so that the fan air volume becomes “strong” and stops energization of the heater unit 33. Moreover, let the damper 40 be a circulation ventilation position.

  Thereby, bathroom heating ventilation drying apparatus 3A exhausts the air in bathroom 101 outside, circulating the air in bathroom 101. Therefore, the humidity in the bathroom 101 which is in the mist sauna state of medium temperature and high humidity in the mist mode is exhausted to prevent generation of mold and the like.

  Next, a process when the post-mist ventilation mode is stopped will be described. The post-mist ventilation mode is automatically stopped after a preset ventilation operation time has elapsed. Moreover, you may make it perform by pressing the ventilation mode button 74 of the main operation part 6. FIG.

  Step SA12a: When the operation mode of the bathroom heating / ventilation / drying apparatus 3A is switched to the post-mist ventilation mode, the main control unit 5 measures a preset ventilation operation time.

  Step SA12b: When the operation mode of the bathroom heating / ventilation / drying apparatus 3A is switched to the post-mist ventilation mode, the main control unit 5 monitors the output of the main operation unit 6 and determines whether or not the ventilation mode button 74 has been pressed. To do.

  Step SA13: The main control unit 5 switches the operation mode of the bathroom heating / ventilation drying apparatus 3A to the post-mist ventilation mode, and then stops the fan motor 36 and stops the post-mist ventilation mode when a predetermined ventilation operation time has elapsed. To do.

  The main control unit 5 switches the operation mode of the bathroom heating / ventilation / drying apparatus 3A to the post-mist ventilation mode, and then stops the fan motor 36 after the mist when the ventilation mode button 74 of the main operation unit 6 is pressed. Stop ventilation mode.

<Operation example of mist mode of second embodiment>
FIG.14 and FIG.15 is a flowchart which shows 2nd Embodiment of the mist mode performed with the bathroom heating system 1A of 1st Embodiment, Next, at the time of mist mode execution of 2nd Embodiment The processing flow will be described.

  Step SB1: A bather or the like presses the mist mode button 72 of the main operation unit 6 installed in the bathroom undressing place 102 to turn on the mist mode switch to heat the bathroom 101 before bathing.

  Step SB2a: When the mist mode button 72 of the main operation unit 6 is pressed, the main control unit 5 determines that the mist mode is selected, and first executes the pre-bath mist mode as the mist mode.

  In the mist mode before bathing, the main controller 5 controls the temperature / pressure control device 52A of the heat pump hot water supply system 4A described with reference to FIG. 4 and drives the pressurization device 66 to supply hot water supplied from the heat pump water heater 51A. Increase pressure. Further, the heating device 67 is driven to increase the temperature of the hot water supplied from the heat pump water heater 51A. Furthermore, the water supply from the mist water supply pipe 63b is stopped by the mixing valve 68, and the hot water supply from the mist hot water supply pipe 65a is fully opened.

  Further, the main control unit 5 controls the mist generating device 2A, rotates the propeller fan 16 by rotating the fan motor 15 as described above, and controls the supply control valve device 12 to control all the mist nozzles 11A. Mist is ejected.

  Thus, the mist generating device 2A blows out the mist atomized by the propeller fan 16 from the blowing grill 26a of the front panel 26 into the bathroom 101.

  The mist ejected by the mist generator 2A uses hot water generated by the heat pump hot water supply unit 4A. In the heat pump hot water supply system 4A, the temperature and the hot water supply pressure of the hot water supplied to the mist generator 2A are controlled by the temperature / pressure controller 52A as described above.

  Thus, the hot water supplied from the heat pump water heater 51A is pressurized to a hot water pressure suitable for generating mist at the mist nozzle 11A, regardless of the control of the hot water pressure at the heat pump water heater 51A.

  Moreover, the hot water supplied from the heat pump water heater 51A is a temperature suitable for setting the bathroom 101 in the mist sauna state (for example, about 60 ° C.) regardless of the limitation of the hot water temperature set in the shower or the like of the bathroom 101. ).

  Therefore, mist is ejected from the mist nozzle 11A at a desired temperature and ejection amount.

  In the mist mode before bathing, since the mist is ejected from all the mist nozzles 11A, in this example, all of the four mist nozzles 11A, the amount of mist ejection is maximized.

  Step SB2b: In the pre-bath mist mode, the main controller 5 controls the bathroom heating / ventilating / drying device 3A according to the operation table of FIG. 12, controls the fan motor 36 so that the fan air volume becomes “strong”, and the heater The unit 33 is energized. Moreover, let the damper 40 be a circulation position.

  Thereby, 3 A of bathroom heating ventilation drying apparatuses blow off warm air in the bathroom 101 from the blowing grill 46 of the front panel 26, circulating the air in the bathroom 101. FIG.

  And in the mist mode before bathing, since the fan air volume in the fan unit 32 is set to "strong", the blowing amount of warm air increases.

  Therefore, in the mist mode before bathing, the mist is generated by the mist generating device 2A at the maximum and the hot air is blown out with the fan air flow set to “strong” by the bathroom heating / ventilating / drying device 3A. It can be set as the mist sauna state of medium temperature high humidity (temperature 40-45 degreeC, humidity 100%).

  Step SB3: When the pre-bath mist mode is started, the main control unit 5 detects the temperature of the bathroom 101 by the temperature detection sensor 69 provided in the suction port 38 of the fan unit 32. When the temperature of the bathroom 101 has not reached the predetermined upper limit value of the heating temperature before bathing, the main control unit 5 continues the mist mode before bathing.

  Step SB4a: When the main control unit 5 determines that the temperature of the bathroom 101 has reached the upper limit of the pre-bath heating temperature from the output of the temperature detection sensor 69, the main control unit 5 switches the operation mode from the pre-bath mist mode to the bathing mist mode.

  That is, in the mist mode during bathing, the main control unit 5 controls the temperature / pressure control device 52A of the heat pump hot water supply system 4A, switches the pressurization amount by the pressurization device 66, and uses the temperature setting button 80 of the mist operation unit 7 to switch. The hot water supply pressure of the hot water supplied from the heat pump water heater 51A is changed so that the amount of mist ejected according to the selected set temperature is obtained. Further, heating by the heating device 67 is continued. Furthermore, the hot water supply side is fully opened by the mixing valve 68. The number of mist nozzles 11A that eject mist may not be changed.

  Here, the main control unit 5 stores information on the set temperature selected by the mist operation unit 7 at the previous execution of the mist mode, and when the operation mode is switched to the bathing mist mode, the set temperature at the previous operation is stored. Switch the amount of mist ejected according to the information.

  For example, when the “strong” button 80a in the temperature setting button 80 is pressed in the mist operation unit 7 during the previous operation, the main control unit 5 causes the mist nozzle 11A to eject from the mist nozzle 11A with the same ejection amount as in the mist mode before bathing. The mist continues to erupt.

  Further, when the “middle” button 80b is pressed in the mist operation unit 7 during the previous operation, the main control unit 5 weakens the ejection amount from the mist mode before bathing.

  Further, when the “weak” button 80c is pressed in the mist operation unit 7 during the previous operation, the main control unit 5 weakens the ejection amount compared to the case where the “medium” button 80b is selected.

  Step SB4b: In the mist mode during bathing, the main controller 5 controls the bathroom heating / ventilating / drying device 3A according to the operation table of FIG. 12, controls the fan motor 36 so that the fan air volume becomes “standard”, and the heater The energization of the unit 33 is continued. Further, the damper 40 holds the circulation position.

  As a result, the bathroom heating / ventilating / drying apparatus 3A circulates the air in the bathroom 101 and blows out hot air from the blowing grill 46 of the front panel 26 with a smaller fan air volume than in the mist mode before bathing.

  Therefore, in the mist mode during bathing, the amount of mist ejected by the mist generating device 2A is switched according to the selection by the temperature setting button 80 of the mist operating unit 7, and the fan airflow is changed to “standard” by the bathroom heating ventilation drying device 3A. By blowing out the warm air as “,” it is possible to prevent the warm air from directly hitting the bather and to keep the inside of the bathroom 101 in the mist sauna state while suppressing the temperature rise in the bathroom 101.

  Step SB5: When the main control unit 5 switches the operation mode to the bathing mist mode, the temperature detection sensor 69 detects the temperature of the bathroom 101. The main control unit 5 sets the upper limit value of the temperature in the bathroom 101 for each set temperature corresponding to the amount of mist ejected selected by the temperature setting button 80 of the mist operation unit 7, and the temperature of the bathroom 101 is selected. If the upper limit of the set temperature has not been reached, continue the mist mode during bathing.

  Step SB6a: When the main control unit 5 determines from the output of the temperature sensor 69 that the temperature of the bathroom 101 has reached the upper limit value of the set temperature corresponding to the selected amount of mist ejection, the operation mode is set to the bathing mist mode. Switch to mist output reduction mode during bathing.

  That is, the main control unit 5 lowers the amount of pressurization by the pressurizing device 66 and further reduces the amount of mist ejected in the mist output lowering mode during bathing.

  Step SB6b: In the mist output lowering mode during bathing, the main controller 5 controls the bathroom heating / ventilating / drying device 3A according to the operation table of FIG. 12, stops the fan motor 36, and stops energizing the heater 33. Then, the operation of the bathroom heating ventilation drying apparatus 3A is stopped.

  Step SB7: When the operation mode is switched to the mist output lowering mode during bathing, the main control unit 5 detects the temperature of the bathroom 101 by the temperature detection sensor 69. The main control unit 5 sets the lower limit value of the temperature in the bathroom 101 for each set temperature corresponding to the amount of mist ejected selected by the temperature setting button 80 of the mist operation unit 7, and the temperature of the bathroom 101 is selected. If the lower limit of the set temperature has not been reached, the mist output lowering mode is continued during bathing.

  Further, when the main control unit 5 determines from the output of the temperature sensor 69 that the temperature of the bathroom 101 has reached the lower limit value of the selected set temperature, the main control unit 5 returns to step SB4 described above and sets the operation mode to the bathing mist mode. Switch.

  Step SB8: The main control unit 5 monitors the output of the mist operation unit 7 during execution of the mist mode during bathing.

  Step SB9: When determining that the temperature setting button 80 is pressed from the output of the mist operation unit 7, the main control unit 5 switches the pressurization amount by the pressurizing device 66 and selects it with the temperature setting button 80 of the mist operation unit 7. Change to the amount of mist ejected according to the set temperature. In the bathroom heating / ventilating / drying apparatus 3A, the fan motor 36 is controlled so that the fan airflow becomes “standard”, and energization to the heater unit 33 is continued.

  Here, the mist operation unit 7 may be provided with a cold water mist mode button for selecting an operation mode in which mist is ejected by water instead of hot water.

  Step SB10: The bather presses a cold water mist mode button (not shown) to turn on the cold water mist mode switch.

  Step SB11a: When a cold water mist mode button (not shown) is pressed, the main controller 5 does not change the amount of pressurization by the pressurization device 66, and the heating by the heating device 67 stops. Further, the mixing valve 68 stops the hot water supply from the mist hot water supply pipe 65a, and the water supply from the mist water supply pipe 63b is fully opened.

  Step SB11b: When a chilled water mist mode button (not shown) is pressed, the main control unit 5 controls the bathroom heating / ventilation / drying device 3A, controls the fan motor 36 so that the fan air volume becomes “standard”, and the heater unit The energization to 33 is stopped. Further, the damper 40 is set to a circulation ventilation position.

  As a result, the bathroom heating / ventilating / drying apparatus 3 </ b> A blows out cool air corresponding to the temperature of the bathroom 101 from the blowout grill 46 of the front panel 26 while circulating the air in the bathroom 101.

  Next, a process for stopping the mist mode will be described. Here, the stop of the mist mode is executed by pressing the mist mode button 72 of the main operation unit 6 or the operation selection button 79 of the mist operation unit 7.

  Step SB12a-1: The bather presses the mist mode button 72 of the main operation unit 6 to turn off the mist mode switch.

  Step SB12a-2: When the mist mode button 72 of the main operation unit 6 is pressed, the main control unit 5 controls the temperature / pressure control device 52A to stop the pressurization and heating of the hot water supplied to the mist generating device 2A. . Further, the supply control valve device 12 is controlled to stop the supply of hot water to all the mist nozzles 11A, and the rotation drive of the fan motor 15 is stopped. Thereby, the ejection of mist from the mist generator 2A is stopped.

  Step SB12b-1: The bather presses the operation selection button 79 of the mist operation unit 7 to turn off the mist mode switch.

  Step SB12b-2: When the operation selection button 79 of the mist operation unit 7 is pressed, the main control unit 5 controls the temperature / pressure control device 52A to stop the pressurization and heating of the hot water supplied to the mist generating device 2A. . Further, the supply control valve device 12 is controlled to stop the supply of hot water to all the mist nozzles 11A, and the rotation drive of the fan motor 15 is stopped. Thereby, the ejection of mist from the mist generator 2A is stopped.

  Step SB12b-3: When the operation selection button 79 of the mist operation unit 7 is pressed to stop the mist generating device 2A, the main control unit 5 measures the preset heating operation time.

  Step SB13: When the mist button 72 of the main operation unit 6 is pressed to stop the mist generating device 2A, the main control unit 5 controls the bathroom heating ventilation drying device 3A according to the operation table of FIG. The operation mode of the drying device 3A is switched to the post-mist ventilation mode.

  Further, after the operation selection button 79 of the mist operation unit 7 is pressed and the mist generating device 2A is stopped, the main control unit 5 stops bathroom heating ventilation drying according to the operation table of FIG. The device 3A is controlled to switch the operation mode of the bathroom heating ventilation drying device 3A to the post-mist ventilation mode.

  That is, the main control unit 5 controls the fan motor 36 so that the fan air volume becomes “strong” and stops energization of the heater unit 33. Moreover, let the damper 40 be a circulation ventilation position.

  Thereby, bathroom heating ventilation drying apparatus 3A exhausts the air in bathroom 101 outside, circulating the air in bathroom 101. Therefore, the humidity in the bathroom 101 which is in the mist sauna state of medium temperature and high humidity in the mist mode is exhausted to prevent generation of mold and the like.

  Next, a process when the post-mist ventilation mode is stopped will be described. The post-mist ventilation mode is automatically stopped after a preset ventilation operation time has elapsed. Moreover, you may make it perform by pressing the ventilation mode button 74 of the main operation part 6. FIG.

  Step SB14a: When the operation mode of the bathroom heating / ventilation / drying apparatus 3A is switched to the post-mist ventilation mode, the main control unit 5 measures a preset ventilation operation time.

  Step SB14b: When the operation mode of the bathroom heating / ventilation / drying apparatus 3A is switched to the post-mist ventilation mode, the main control unit 5 monitors the output of the main operation unit 6 to determine whether or not the ventilation mode button 74 has been pressed. To do.

  Step SB15: After switching the operation mode of the bathroom heating / ventilation / drying apparatus 3A to the post-mist ventilation mode, the main control unit 5 stops the fan motor 36 and stops the post-mist ventilation mode after a predetermined ventilation operation time has elapsed. To do.

  The main control unit 5 switches the operation mode of the bathroom heating / ventilation / drying apparatus 3A to the post-mist ventilation mode, and then stops the fan motor 36 after the mist when the ventilation mode button 74 of the main operation unit 6 is pressed. Stop ventilation mode.

<Example of waste water treatment at the start of mist mode>
When the mist mode is terminated and the hot water supply to the mist generating device 2A is stopped, the temperature of the hot water remaining in the mist hot water supply pipe 65a and the supply pipe 31a of the supply control valve device 12 connected to the mist hot water supply pipe 65a decreases. To do. For this reason, at the start of the mist mode, a mist ejection preparation operation is performed for draining water from the mist hot water supply pipe 65a and the supply pipe 31a.

  The mist ejection preparation operation is executed at the start of the pre-bath mist mode in step SA2a described in FIG. 13 and step SB2a described in FIG. That is, when the main control unit 5 starts the pre-bath mist mode, the supply control valve device 12 shown in FIG. 4 opens the supply switching electromagnetic valve 28 using the three-way switching electromagnetic valve 29 as the hot water supply destination as the drain pipe 31b. .

  Thereby, the hot water supplied from the heat pump hot water supply system 4A is not supplied to the mist nozzle 11A, but is drained from the drain pipe 31b. Therefore, the hot water whose temperature has remained in the mist hot water supply pipe 65a and the supply pipe 31a is drained without being ejected from the mist nozzle 11A.

  The main control unit 5 monitors the output of the water temperature detection sensor 31c, and when the temperature of the hot water flowing through the supply pipe 31a reaches a predetermined value (for example, 60 ° C.), the main controller 5 determines the supply destination of the hot water by the three-way switching electromagnetic valve 29 Switch to the 11A direction. Thereby, warm water is supplied from the heat pump hot water supply system 4A to the mist nozzle 11A.

  In the pre-bath mist mode, mist is ejected from all the mist nozzles 11A in this example, so the main control unit 5 controls the individual switching electromagnetic valve 30 to supply hot water to all the mist nozzles 11A.

  When the operation of the mist generating device 2A is stopped in steps SA10a-2 and b-2 described in FIG. 13 and SB12a-2 and b-2 described in FIG. 15, the main control unit 5 performs three-way switching. The supply destination of the hot water by the electromagnetic valve 29 is switched in the direction of the drain pipe 31b, and the supply switching electromagnetic valve 28 is closed to stop the mist ejection.

<Example of residual water discharge treatment of mist nozzle>
The mist nozzle 11A has a small hole diameter of φ0.5 to 0.8 mm, and after the mist mode is finished, if hot water remains in a pipe or the like connected to the mist nozzle 11A, the chlorine that is an impurity contained in the residual water is generated. There is a possibility that the mist nozzle 11A will collect and clogging will occur after aging. For this reason, you may provide the mechanism which can discharge | emit residual water at the time of completion | finish of mist mode.

  FIG. 16 is a configuration diagram illustrating an example of a residual water discharge device provided in the mist generator 2 (2A). The residual water discharge device 91 supplies an air compressor 92 for supplying compressed air to the mist nozzle 11A and hot water to the mist nozzle 11A to the supply pipe 31a downstream of the supply control valve device 12 described in FIG. A three-way switching electromagnetic valve 93 that switches whether to supply compressed air is provided.

  Next, the residual water discharge operation by the residual water discharge device 91 will be described. In steps SA10a-2 and b-2 described in FIG. 13 and SB12a-2 and b-2 described in FIG. 15, when the operation of the mist generating device 2A is stopped, the supply control valve device 12 supplies hot water. After stopping, the air compressor 92 is connected to the mist nozzle 11A by the three-way switching electromagnetic valve 93. And by driving the air compressor 92, compressed air is sent to the mist nozzle 11A. Thereby, the moisture remaining in the mist nozzle 11A is blown off. Therefore, since the residual water at the mist nozzle 11A is removed, it is possible to prevent clogging due to impurities in the water.

<Example of antibacterial treatment of bathroom by bathroom heating system>
When the mist mode is executed in the bathroom heating system 1A provided with the mist generating device 2 (2A), the inside of the bathroom 101 is in a mist sauna state of medium temperature and high humidity. For this reason, the post-mist ventilation mode is executed at the end of the mist mode to exhaust the moisture in the bathroom 101.

  However, mold may be generated by water droplets remaining on the wall or ceiling of the bathroom 101. For this reason, you may provide the mechanism which can supply the ion with which an antimicrobial effect is acquired to the bathroom 101. FIG.

  FIG. 17 is a configuration diagram showing an example of an ion generator provided in the mist generator 2 (2A). The ion generator 94 is provided in the supply piping 31a downstream of the supply control valve device 12, and supplies silver ions or alkali ions to the hot water flowing through the supply piping 31a.

  Next, the ion supply operation by the ion generator 94 will be described. When the mist mode described with reference to FIGS. 13, 14, and 15 is executed, silver ions or alkali ions are supplied to the hot water supplied to the mist nozzle 11 </ b> A by the ion generator 94. Thereby, mist containing silver ions or alkali ions is ejected from the mist nozzle 11A. Therefore, mist containing silver ions or alkali ions is blown out into the bathroom 101, and the antibacterial effect of silver ions or alkali ions prevents the growth of mold.

  Here, in the bathroom heating system 1A, the bathroom 101 may be antibacterial using the ion generator 44 provided in the bathroom heating / ventilating / drying apparatus 3A.

  That is, when the post-mist ventilation mode is started in step SA11 described in FIG. 13 and step SB13 described in FIG. 15, the ion generator 44 generates both positive ions and negative ions. Thereby, both positive ions and negative ions are supplied to the air passing through the circulation air passage 43a shown in FIG. 5, and air containing substantially the same number of positive ions and negative ions is blown out to the bathroom 101. Therefore, the floating bacteria contained in the air circulated by the bathroom heating / ventilating / drying apparatus 3A and the floating bacteria in the air of the bathroom 101 are inactivated to prevent mold growth.

  The mist generator 2 (2A) may include both the residual water discharge device 91 described with reference to FIG. 16 and the ion generator 94 described with reference to FIG.

<Installation example of mist generator>
FIG. 18 is a configuration diagram illustrating a first installation example of the mist generating device 2 (2A). In the bathroom heating system 1A in which the mist generating device 2 and the bathroom heating ventilation drying device 3 (3A) are linked, the mist generation device 2 is installed side by side with the bathroom heating ventilation drying device 3 on the ceiling panel 101c of the bathroom 101.

  The mist generating device 2 includes a mounting flange portion 14b in the main body case 14 described with reference to FIGS. 2 and 3, and the main body case 14 is fitted into an opening formed in the ceiling panel 101c of the bathroom 101, and the mounting flange portion 14b is interposed. It is attached with a screw 14c.

  The mist generating device 2 and the bathroom heating / ventilation / drying device 3 may each have an independent front panel, but as described with reference to FIGS. 2, 3 and 5, etc., the mist generating device 2 and the bathroom heating / ventilating / drying device 3 The front panel 26 may be integrated with the device 3. If the front panel 26 is integrated with the mist generating device 2 and the bathroom heating / ventilating / drying device 3, the front panel 26 is installed in one place on the ceiling panel 101c of the bathroom 101, so that the design is improved.

  FIG. 19 is a configuration diagram showing a second installation example of the mist generating device 2 (2A). The mist generator 2 is installed on the wall surface 101 d of the bathroom 101. Even when the mist generating device 2 is installed on the wall surface 101d of the bathroom 101, the main body case 14 is fitted into an opening formed on the wall surface of the bathroom 101, and is attached with the mounting screw 14c via the mounting flange portion 14b.

  When installing the mist generating device 2 on the wall surface 101d of the bathroom 101, the front panel 26c of the mist generating device 2 and the front panel 26d of the bathroom heating / ventilating / drying device 3 are independent.

  Thus, the mist generator 2 (2A) can be installed on either the ceiling or the wall surface of the bathroom 101 by changing the front panel, and the workability is improved. Here, if the mist generator 2 is installed on the ceiling of the bathroom 101, the mist can be taken from the ceiling.

  On the other hand, if the mist generator 2 is installed on the wall surface of the bathroom 101, it is possible to prevent the mist from spraying on the head. And the mist generator 2 can be installed in the installation place according to a user's request by enabling selection of the installation place of the mist generator 2 at the time of construction.

<Operation Example of Bathroom Heating Ventilation Dryer of First Embodiment>
Next, the operation of the bathroom heating / ventilation drying apparatus 3A alone will be described. FIG. 20 is an operation table showing patterns of combinations of operation modes and operation of each part in the bathroom heating / ventilation drying apparatus 3A alone.

  In the operation table shown in FIG. 20, for each operation mode, the rotation speed of the fan motor 36 of the bathroom heating / ventilation drying apparatus 3A is set to be switched to, for example, “standard”, and the selected operation mode is set. The corresponding air volume can be obtained.

  Further, the position of the damper 40 is set for each operation mode. Further, whether or not the heater unit 33 is driven is set for each operation mode. Here, what is shown in FIG. 20 is an example of the operation pattern of the bathroom heating ventilation drying apparatus 3A.

  The heating mode is an operation mode in which the bathroom heating / ventilating / drying apparatus 3A alone heats the bathroom 101. When the heating mode button 73 is pressed in the main operation unit 6 shown in FIG. 9, the main control unit 5 is in the heating mode. The fan motor 36, the heater unit 33, and the damper motor 40b are driven by determining that the selection has been made.

  In the heating mode, the damper motor 40b is controlled so that the position of the damper 40 becomes the circulation position shown in FIG.

  In addition, when the fan motor 36 is controlled so that the fan air volume becomes “standard” and the impeller 35 is driven to rotate, the air suction from the suction port 38 of the fan unit 32 through the suction grille 45 of the front panel 26 is performed. Air is inhaled.

  If the position of the damper 40 is the circulation position, the circulation air passage 43a from the suction port 38 to the blowout port 41 is formed in the fan unit 32, so that air sucked from the suction port 38 passes through the circulation air passage 43a. The air is blown into the bathroom 101 from the air outlet 41 through the air outlet grill 46 of the front panel 26.

  And since the heater part 33 is arrange | positioned at the blower outlet 41 of the circulation air path 43a, when the heater part 33 is turned on and the heater part 33 is heated, the air which passes along the circulation air path 43a will be warmed, and the blowing grille 46 will be heated. Blow out from.

  Thereby, the inside of the bathroom 101 can be heated while circulating the air in the bathroom 101 with the bathroom heating ventilation drying apparatus 3A alone.

  The ventilation mode is an operation mode in which the bathroom heating / ventilating / drying apparatus 3A alone performs ventilation of the bathroom 101. When the ventilation mode button 74 is pressed in the main operation unit 6 shown in FIG. The fan motor 36 and the damper motor 40b are driven by determining that the selection has been made.

  In the ventilation mode, the damper motor 40b is controlled so that the position of the damper 40 becomes the ventilation position shown in FIG.

  In addition, when the fan motor 36 is controlled so that the fan air volume becomes “standard” and the impeller 35 is driven to rotate, the air suction from the suction port 38 of the fan unit 32 through the suction grille 45 of the front panel 26 is performed. Air is inhaled.

  When the position of the damper 40 is the ventilation position, a ventilation air passage 43b from the suction port 38 to the exhaust port 42 is formed in the fan unit 32. Therefore, air sucked from the suction port 38 is exhausted from the ventilation air passage 43b and the exhaust air. The air is exhausted from the exhaust grill 8a to the outside through the opening 42 and further through the exhaust duct 8 shown in FIG.

  Thereby, by executing the ventilation mode, steam and moisture in the bathroom 101 can be discharged to suppress dew condensation and the like, and generation of mold can be suppressed. Even in the ventilation mode of the bathroom heating / ventilation drying apparatus 3A alone, ventilation may be performed while circulating the air in the bathroom 101 with the damper 40 as the circulation ventilation position, as in the above-described post-mist ventilation mode.

  The drying mode is an operation mode for drying clothes and the like in the bathroom 101 by the bathroom heating / ventilation drying apparatus 3A alone. When the drying mode button 75 is pressed in the main operation unit 6 shown in FIG. Determines that the drying mode has been selected, and drives the fan motor 36, the heater section 33, and the damper motor 40b.

  In the dry mode, the damper motor 40b is controlled so that the position of the damper 40 becomes the circulation ventilation position shown in FIG.

  In addition, when the fan motor 36 is controlled so that the fan air volume becomes “standard” and the impeller 35 is driven to rotate, the air suction from the suction port 38 of the fan unit 32 through the suction grille 45 of the front panel 26 is performed. Air is inhaled.

  When the position of the damper 40 is the circulation ventilation position, both the circulation air passage 43a from the suction port 38 to the blowout port 41 and the ventilation air passage 43b from the suction port 38 to the exhaust port 42 are formed in the fan unit 32. Therefore, a part of the air sucked from the suction port 38 passes through the circulation air passage 43a and is blown out into the bathroom 101 from the blowout port 41 through the blowout grill 46 of the front panel 26. Then, the heater section 33 is turned on and the heater section 33 is heated, so that the air passing through the circulation air passage 43a is warmed and the hot air is blown out from the blowing grill 46.

  Further, a part of the air sucked from the suction port 38 passes through the ventilation air passage 43b and the exhaust port 42, and is further exhausted from the exhaust grill 8a to the outside through the exhaust duct 8 shown in FIG.

  Accordingly, by executing the drying mode, warm air can be blown out into the bathroom 101 to dry clothes and the like. Moreover, moisture in the bathroom 101 can be discharged, and drying of clothes can be promoted.

  The cool breeze mode is an operation mode in which the bathroom heating / ventilating / drying apparatus 3A alone blows air into the bathroom 101. When the cool breeze mode button 76 is pressed in the main operation unit 6 shown in FIG. The fan motor 36 and the damper motor 40b are driven by determining that the selection has been made.

  In the cool breeze mode, the damper motor 40b is controlled so that the position of the damper 40 becomes the circulation ventilation position shown in FIG.

  In addition, when the fan motor 36 is controlled so that the fan air volume becomes “standard” and the impeller 35 is driven to rotate, the air suction from the suction port 38 of the fan unit 32 through the suction grille 45 of the front panel 26 is performed. Air is inhaled.

  When the position of the damper 40 is the circulation ventilation position, both the circulation air passage 43a from the suction port 38 to the blowout port 41 and the ventilation air passage 43b from the suction port 38 to the exhaust port 42 are formed in the fan unit 32. Therefore, a part of the air sucked from the suction port 38 passes through the circulation air passage 43a and is blown out into the bathroom 101 from the blowout port 41 through the blowout grill 46 of the front panel 26. In the cool breeze mode, the heater unit 33 is not driven, so that air corresponding to the temperature of the bathroom 101 blows out from the blowout grill 46.

  Further, a part of the air sucked from the suction port 38 passes through the ventilation air passage 43b and the exhaust port 42, and is further exhausted from the exhaust grill 8a to the outside through the exhaust duct 8 shown in FIG.

  Thus, by executing the cool air mode, the cool air according to the temperature in the bathroom 101 is blown out while circulating the air in the bathroom 101, and the bathroom heating / ventilating / drying apparatus 3A can be used as a fan in summer or the like. it can.

<Configuration Example of Mist Generating Device of Second Embodiment>
In the bathroom heating system 1A described above, the mist generator 2A having a configuration in which the mist is atomized by a propeller fan as the mist generator 2 has been described as an example. However, the mist generator 2 is not limited thereto. . For example, you may provide the structure which atomizes mist using a net-like member.

  FIG. 21 shows a second embodiment of the mist generator 2, and the configuration of the mist generator 2B of the second embodiment will be described next. Here, FIG. 21A is a plan view of the mist generator 2B viewed from the lower surface side, and FIG. 21B is a cross-sectional view taken along the line DD of FIG.

  The mist generator 2B according to the second embodiment includes a mist nozzle 11A that generates mist, a supply control valve device 12 that switches supply of hot water or water to the mist nozzle 11A, and a mist generated by the mist nozzle 11A. And a main body case 82 to which the mist nozzle 11A, the net portion 81, and the like are attached.

  The main body case 82 has, for example, a rectangular parallelepiped outer shape, and a cylindrical mist blowing space 83 is formed therein. The mist nozzle 11A is disposed in the upper part of the mist blowing space 83, and the net 81 is attached to the lower opening of the mist blowing space 83 so as to face the mist nozzle 11A.

  A plurality of mist nozzles 11A are arranged in the mist blowing space 83, and in this example, four mist nozzles 11A are arranged at equal intervals in the circumferential direction as in the mist generating apparatus 2A of the first embodiment. The

  Control of the supply of warm water or water to the mist nozzle 11A is performed by the supply control valve device 12 described in FIG. 4, and the presence / absence of mist ejection and the number of mist nozzles 11A for ejecting mist are switched.

  The net portion 81 is an example of a net member, and has a circular shape that closes the lower opening of the mist blowing space 83, and has a conical shape that has a convex central portion and is inclined toward the outer peripheral side. The net diameter of the net part 81 is, for example, about 0.2 to 0.4 mm.

  The main body case 82 has an air outlet 83a formed in a lower portion of a mist outlet space 83 to which the net portion 81 is attached. The main body case 82 includes a drain pan 84 at the air outlet 83 a around the net portion 81. The drain pan 84 has a ring shape that matches the shape of the mist blowing space 83, has a groove connected to the inner wall surface of the mist blowing space 83a and the outer periphery of the mesh portion 81, and the inner wall surface of the mesh portion 81 and the mist blowing space 83 is Receive drops of water that fall down.

  Further, the drain pan 84 is provided with a drain hose port 84a at one place in the circumferential direction so that water received from the inner wall surface of the net part 81 and the mist blowing space 83 can be drained from the drain hose port 84a. For this reason, the drain pan 84 is in an inclined state so that the drain hose port 84a side is lowered. The drain pan 84 may be detachable from the main body case 82 so that cleaning can be performed.

  The main body case 82 includes the front panel 26 at the lower part. The front panel 26 is configured integrally with the front panel of the bathroom heating / ventilating / drying apparatus 3 in a form in which the mist generating device 2B is attached to the ceiling of the bathroom 101 as shown in FIG. The main body case 82 includes a hook portion 82a for fixing the front panel 26, and the front panel 26 is detachably attached.

  The front panel 26 includes an outlet grill 26a that communicates with the outlet 83a and blows out the mist atomized by the net 81.

  In addition, in the form which attaches the mist generator 2B to the wall surface of the bathroom 101 as shown in FIG. 19, an independent front panel is provided.

  Here, the mist generating device 2B may be provided with an auxiliary mist nozzle 27 around the air outlet 83a, for example, so that mist can be preliminarily blown out at the operation start stage or the like. Further, a plurality of auxiliary mist nozzles 27 may be provided, and mists having different water droplet diameters may be blown out as necessary.

<Example of Mist Ejection Operation of Mist Generator of Second Embodiment>
Next, an example of a mist ejection operation in the mist generator 2B of the second embodiment will be described.

  The mist generating device 2B switches the hot water supply destination to the mist nozzle 11A by the three-way switching electromagnetic valve 29 shown in FIG. 4, opens the supply switching electromagnetic valve 28, and opens the individual switching electromagnetic valve 30. Hot water is supplied from the heat pump hot water supply system 4 shown in FIG.

  When hot water is supplied to the mist nozzle 11A, the mist is ejected from the mist nozzle 11A. The mist ejected from the mist nozzle 11 </ b> A passes through the net portion 81, and the water droplet diameter becomes finer and is atomized. The mist atomized by the net 81 is blown out into the bathroom 101 from the blowout port 83a through the blowout grill 26a of the front panel 26.

  Accordingly, when the mist mode described with reference to FIG. 13 is executed in the bathroom heating system provided with the mist generating device 2B, in the mist mode before bathing, the mist is ejected from all the mist nozzles 11A, thereby reducing the mist ejection amount. In addition to the maximum, the bathroom 101 can be heated in a short time by blowing out the warm air with the fan air volume set to “strong” in the bathroom heating / ventilating / drying apparatus 3A.

  Further, in the mist mode during bathing, the temperature of the bathroom 101 can be adjusted by increasing / decreasing the amount of mist ejected by switching the number of mist nozzles 11A that eject mist according to the selection in the mist operation unit 7. .

  A part of the mist colliding with the net part 81 adheres to the net part 81. Since the net part 81 has a convex shape at the center and is inclined toward the outer peripheral side, water droplets attached to the net part 81 flow to the drain pan 84 along the inclination.

  Further, part of the mist ejected from the mist nozzle 11 </ b> A adheres to the inner wall surface of the mist blowing space 83. The water droplets attached to the inner wall surface of the mist blowing space 83 fall along the inner wall surface of the mist blowing space 83 and flow to the drain pan 84.

  And the water collect | recovered with the drain pan 84 drains from the drain hose port 84a. The drain hose port 84a is connected to the outside of the building via a drain hose (not shown), and the water collected by the drain pan 84 is drained outside the building, for example.

  In the mist generating apparatus 2B of the second embodiment described above, it is not necessary to include a driving unit such as a propeller fan, so that the configuration can be simplified and the apparatus can be reduced in size and atomized. It is possible to provide a mist generating device that can eject mist at low cost.

<Configuration Example of Mist Generating Device of Third Embodiment>
FIG. 22 shows a third embodiment of the mist generator 2, and the configuration of the mist generator 2C of the third embodiment will be described next.

  The mist generator 2C of the third embodiment includes a mist nozzle 11B that generates mist, and a main body case 14b to which the mist nozzle 11B and the like are attached. The mist nozzle 11B receives supply of warm water or water and blows it out in a mist form. A plurality of mist nozzles 11B are arranged, and in this example, four mist nozzles 11B are arranged at equal intervals in the circumferential direction as in the mist generating apparatus 2A of the first embodiment. The arrangement of the mist nozzles 11B is not limited to this example, and may be arranged in a row, for example.

  And the mist nozzle 11B is rotatably supported via the ball joint part 11c, and is a structure which can switch the mist ejection direction.

  The main body case 14b includes a front panel 26e at the bottom. The front panel 26e is configured integrally with the front panel of the bathroom heating / ventilating / drying apparatus 3 in a form in which the mist generating device 2C is attached to the ceiling of the bathroom 101 as shown in FIG. In addition, in the form which attaches 2 C of mist generators to the wall surface of the bathroom 101 as shown in FIG. 19, an independent front panel is provided.

  The mist nozzle 11B is attached so as to be exposed from the front panel 26e, and the bather can operate the mist nozzle 11B to switch the mist ejection direction.

  Control of the supply of hot water to the mist nozzle 11B is performed by the supply control valve device 12 described in FIG. 4, and the presence / absence of mist ejection and the number of mist nozzles 11B that eject mist are switched.

<Example of Mist Ejection Operation of Mist Generating Device of Third Embodiment>
Next, an example of the mist ejection operation in the mist generating apparatus 2C of the third embodiment will be described.

  When the hot water supply destination is switched to the mist nozzle 11B by the three-way switching electromagnetic valve 29 shown in FIG. 4 and the supply switching electromagnetic valve 28 is opened, and the individual switching electromagnetic valve 30 is opened, the mist generating device 2C is connected to the mist nozzle 11B. Hot water is supplied from the heat pump hot water supply system 4 shown in FIG.

  When hot water is supplied to the mist nozzle 11B, the mist is ejected from the mist nozzle 11B and blown into the bathroom 101.

  Accordingly, when the mist mode described with reference to FIG. 13 is executed in the bathroom heating system provided with the mist generating device 2C, in the mist mode before bathing, the mist is ejected from all the mist nozzles 11B, thereby reducing the mist ejection amount. In addition to the maximum, the bathroom 101 can be heated in a short time by blowing out the warm air with the fan air volume set to “strong” in the bathroom heating / ventilating / drying apparatus 3A.

  Further, in the mist mode during bathing, the temperature of the bathroom 101 can be adjusted by increasing or decreasing the amount of mist ejected by switching the number of mist nozzles 11B that eject mist according to the selection in the mist operation unit 7. .

  The mist nozzle 11B is configured to be switchable in the mist ejection direction by being supported via the ball joint portion 11c, and the bather operates the mist nozzle 11B to determine the mist ejection direction. Direction.

  For example, the mist ejection direction can be adjusted so that the mist is sprayed directly on the bather. Moreover, the mist ejection direction can be adjusted so that the mist does not blow directly on the bather.

  In the mist generating apparatus 2C of the third embodiment described above, since it is not necessary to include a driving unit such as a propeller fan, the configuration can be simplified and the apparatus can be downsized. Moreover, since the mist ejection direction can be selected at the time of bathing or the like, the mist can be ejected according to the request of the bather.

  In the mist generating apparatus 3C of the third embodiment, the mist ejection direction is switched manually, but may be automatically performed using an actuator or the like. In this case, the mist ejection direction may be switched between the pre-bathing mist mode and the bathing mist mode.

<Mist nozzle replacement configuration example>
The mist generating device 2B according to the second embodiment and the mist generating device 2C according to the third embodiment described above change the hole diameter and flow path shape of the mist nozzle 11A or the mist nozzle 11B, so that the mist is ejected. Can be switched. For example, the mist particle diameter and flow rate can be changed, and the mist ejection shape can be changed to a fan shape or a cone shape. For this reason, you may provide the mechanism in which the mist nozzle 11 (A, B) can be attached and detached and replaced.

  FIG. 23 is a cross-sectional view showing an example of a nozzle exchange device, FIG. 23 (a) shows a state where the mist nozzle 11 is fixed, and FIG. 23 (b) shows a state where the mist nozzle 11 is removable.

  The nozzle changing device 85 includes a sleeve 86 into which the mist nozzle 11 is inserted, a locking claw portion 87 that locks the mist nozzle 11 inserted into the sleeve 86, and locking of the mist nozzle 11 by the locking claw portion 87. A detachable operation cover 88 for releasing the lock is provided.

  The sleeve 86 has an inner diameter in which the insertion portion 11d of the mist nozzle 11 is fitted, and includes an opening 86a that projects the locking claw portion 87 to the inner peripheral surface. Note that an O-ring 11 e is fitted in the insertion portion 11 d of the mist nozzle 11 to shield the sleeve 86.

  The locking claw 87 is attached to the outside of the sleeve 86 so as to be elastically deformable, and protrudes from the opening 86a to the inner peripheral surface of the sleeve 87.

  The detachable operation cover 88 is attached so as to be slidable with respect to the sleeve 86 outside the locking claw portion 87. The detachable operation cover 88 is urged by a spring 88a and is held at a fixed position shown in FIG. In addition, the attachment / detachment operation cover 88 includes a fixed holding portion 88b on the inner peripheral surface that comes into contact with the locking claw portion 87 when in the fixed position.

  Next, the operation of the nozzle replacement device will be described. First, in a state where the mist nozzle 11 is fixed to the nozzle changing device 85, as shown in FIG. 23A, the insertion portion 11d of the mist nozzle 11 is inserted into the sleeve 86, and the locking claw portion 87 is inserted into the sleeve 86. It protrudes from the inner peripheral surface of the mist nozzle 11 and is locked to the insertion portion 11 d of the mist nozzle 11.

  The attachment / detachment prevention cover 88 is biased by the spring 88a and is in the fixed position, so that the fixing holding portion 88b of the attachment / detachment prevention cover 88 abuts on the engagement claw portion 87 and prevents the engagement claw portion 87 from being retracted. To do.

  Thereby, the latching claw part 87 does not come off from the insertion part 11d of the mist nozzle 11, and the mist nozzle 11 is fixed to the nozzle replacement device 85. Accordingly, hot water is supplied from the supply pipe 31a to the mist nozzle 11, and the mist is ejected. At this time, the mist nozzle 11 is not detached by the hot water supply pressure.

  When removing the mist nozzle 11, as shown in FIG. 23B, the attachment / detachment prevention cover 88 is slid against the spring 88a, and the attachment / detachment prevention cover 88 is moved to the removal position.

  When the attachment / detachment prevention cover 88 is moved to the removal position, the fixed holding portion 88 b of the attachment / detachment prevention cover 88 is detached from the locking claw portion 87. Accordingly, when the mist nozzle 11 is pulled in the direction of the arrow, the locking claw portion 87 is pushed by the insertion portion 11 d of the mist nozzle 11, and the locking claw portion 87 is retracted to the opening 86 a of the sleeve 86. Then, the insertion portion 11 d of the mist nozzle 11 gets over the locking claw portion 87, and the mist nozzle 11 is detached from the sleeve 86.

  When attaching the mist nozzle 11 to the nozzle changing device 85, when the detachment prevention cover 88 is set to the fixed position and the mist nozzle 11 is pushed into the sleeve 86, the insertion portion 11d of the mist nozzle 11 pushes the locking claw portion 87. The latching claw 87 is retracted from the opening 86a of the sleeve 86 by being elastically deformed. When the insertion portion 11d of the mist nozzle 11 gets over the locking claw portion 87, the shape of the locking claw portion 87 is restored and locked to the insertion portion 11d of the mist nozzle 11.

  In this manner, in the nozzle replacement device 85, the mist nozzle 11 can be removed by sliding the attachment / detachment prevention cover 88, and the mist nozzle 11 can be attached by pushing the mist nozzle 11, so that the mist nozzle 11 can be easily attached and detached.

  Thereby, a plurality of types of mist nozzles 11 having different mist ejection shapes, particle diameters, flow rates, etc. are prepared, and the mist nozzles 11 are exchanged, so that the mist ejection shapes, flow rates, etc. according to the preference of the bather Can be changed. Further, even in the mist generating device 2A of the first embodiment, if the mist nozzle 11A can be replaced by including the nozzle changing device 85, maintenance can be easily performed when a problem such as clogging occurs. Become.

  FIG. 24 is a cross-sectional view showing a modified example of the mist nozzle attached to the nozzle changing device 85. The modified mist nozzle 11 'has a shape in which, for example, the nozzle portion 11f is branched into three parts, and is configured such that three mists can be ejected by one mist nozzle 11'. As a result, the plurality of nozzle portions 11f can be replaced at a time.

<Configuration Example of Heat Pump Hot Water Supply System of Second Embodiment>
FIG. 25 shows a second embodiment of the heat pump hot water supply system 4, and the configuration of the heat pump hot water supply system 4B of the second embodiment will be described next. Here, FIG. 25 is a configuration diagram showing an outline and a connection form of the heat pump hot water supply system 4B, and the elements having the same configurations as those of the heat pump hot water supply system 4A of the first embodiment are denoted by the same reference numerals.

  The heat pump hot water supply system 4B of the second embodiment controls the mist generator 2 shown in FIG. 1, the heat pump water heater 51B that supplies hot water to the bathroom 101, and the hot water supply pressure supplied to the mist generator 2. The temperature / pressure control device 52B is provided.

  The heat pump water heater 51B includes a heat pump unit 53 that generates hot water by heat exchange between the atmosphere and the refrigerant and heat exchange between the refrigerant and water, and a hot water storage tank unit 54 that stores the hot water generated by the heat pump unit 53. Is provided.

  Since the configuration of the heat pump unit 53 is the same as that of the heat pump hot water supply system 4A of the first embodiment, the description thereof is omitted here.

  The hot water storage tank unit 54 includes a tank 60 that stores the hot water generated by the heat pump unit 53. The tank 60 stores hot water in a stratified state in which water is supplied to the lower side and hot water is supplied to the upper side, and the temperature on the upper side is higher than that on the lower side.

  In the heat pump unit 53 and the hot water storage tank unit 54, the water heat exchanger 56 and the tank 60 are connected by a hot water pipe 61a and a cold water pipe 61b, and the cold water pipe 61b includes a pump 61c.

  In addition, the hot water storage tank unit 54 is connected to the tank 60 with a water intake pipe 62 for taking in hot water stored in the tank 60 and a water supply pipe 63 for supplying water to the tank 60.

  Furthermore, the hot water storage tank unit 54 includes a hot water supply mixing valve 64a that mixes hot water supplied from the intake pipe 62 and water supplied from the branch water supply pipe 63a. The hot water supply mixing valve 64a is provided at the junction of the intake water pipe 62 and the branch water supply pipe 63a, and switches the mixing ratio of the hot water supplied from the intake water pipe 62 and the water supplied from the branch water supply pipe 63a to the hot water supply pipe 65. Adjust the temperature of hot water supplied from.

  The hot water supply pipe 65 is connected to the shower 101a and the bathtub 101b of the bathroom 101 shown in FIG. 1, the faucet 102a of the washroom 102, the faucet (not shown) of the kitchen 103, and the like, and supplies hot water.

  The hot water storage tank unit 54 includes a mist intake pipe 62 d that takes in hot water stored in the tank 60. The mist intake pipe 62d is connected to a high-temperature part intake 60f provided at the upper part of the tank 60.

  Moreover, the hot water storage tank unit 54 includes a hot water supply mixing valve 64b that mixes hot water supplied from the mist intake pipe 62d and water supplied from the branch water supply pipe 63c. The hot water supply mixing valve 64b is provided at the junction of the mist intake pipe 62d and the branch water supply pipe 63c, and switches the mixing ratio of the hot water supplied from the mist intake pipe 62d and the water supplied from the branch water supply pipe 63c. The temperature of the hot water supplied to the hot water supply pipe 65a is adjusted.

  A temperature / pressure control device 52B is connected to the mist hot water supply pipe 65a. The temperature / pressure control device 52 </ b> B includes a pressurization device 66 that increases the hot water supply pressure of hot water supplied from the heat pump water heater 51.

  The temperature / pressure control device 52 </ b> B includes a mixing valve 68 that mixes the hot water supplied from the mist hot water supply pipe 65 a and the water supplied from the mist water supply pipe 63 b branched from the water supply pipe 63. The mixing valve 68 is provided at the junction of the mist hot water supply pipe 65a and the mist water supply pipe 63b on the downstream side of the pressurizing device 66, and hot water supplied from the mist hot water supply pipe 65a and water supplied from the mist water supply pipe 63b. Change the mixing ratio.

  The mist generator 2 shown in FIG. 1 and the like is connected to a mist hot water supply pipe 65 a on the downstream side of the mixing valve 68. For example, a mist hot water supply pipe 65a on the downstream side of the mixing valve 68 is connected to the supply pipe 31a shown in FIG.

  Thereby, the hot water which raised the hot-water supply pressure with the pressurization apparatus 66 is supplied to the mist generator 2 (2A).

<Operation example of the heat pump hot water supply system of the second embodiment>
Next, the operation of the heat pump hot water supply system 4B will be described. In addition, since the process of producing | generating warm water with the heat pump hot water supply system 4B and the process of supplying warm water to the bathroom 101 grade | etc., Are the same as the heat pump hot water supply system 4A of 1st Embodiment, description is abbreviate | omitted here.

  The hot water supplied to the mist generator 2 is taken from the tank 60 through the mist intake pipe 62d. The hot water taken by the mist intake pipe 62d is mixed with the water supplied from the branch water supply pipe 63c by the hot water supply mixing valve 64b. The temperature of hot water supplied from the mist hot water supply pipe 65a is adjusted by switching the mixing ratio of hot water and water by the hot water supply mixing valve 64b.

  Here, the mist intake pipe 62d and the mist hot water supply pipe 65a are independent of the intake water pipe 62 and the hot water supply pipe 65 that supply hot water to the bathroom 101 and the like, and therefore there is no limitation on the hot water supply temperature of the hot water supplied to the bathroom 101 or the like. I do not receive it.

  The hot water supplied from the mist hot water supply pipe 65a is supplied to the mist generating device 2 after the temperature and the hot water supply pressure are controlled by the temperature / pressure control device 52B. That is, the temperature / pressure control device 52B increases the hot water supply pressure of the hot water supplied to the mist hot water supply pipe 65a by the pressurization device 66. Thereby, the hot water supplied from the heat pump water heater 51 is raised to a hot water supply pressure suitable for generating mist in the mist generator 2.

  Further, by mixing the hot water supplied from the mist hot water supply pipe 65a with the hot water pressure controlled and the water supplied from the mist water supply pipe 63b by the mixing valve 68, the mixing ratio of the hot water and water is switched to generate mist. The temperature of the hot water supplied to the apparatus 2 is controlled.

  That is, since the hot water taken in by the mist intake pipe 62d is a high temperature of about 85 to 90 ° C., it is mixed with water by the mixing valve 68 and controlled to a temperature suitable for ejection from the mist generator 2 (for example, about 60 ° C.). Is done. It is also possible to stop the supply from the mist hot water supply pipe 65a side and supply only water.

<Overall configuration example of the bathroom heating system according to the second embodiment>
FIG. 26 is a configuration diagram illustrating an example of a bathroom heating system 1B according to the second embodiment. The bathroom heating system 1B according to the second embodiment performs a mist generating device 2 that ejects mist into the bathroom 101, a bathroom heating / ventilating / drying device 3 that heats and ventilates the bathroom 101, and the bathroom 101. A radiant heating device 111A and a heat pump hot water supply system 4 for supplying hot water to the mist generator 2, the bathroom 101, and the like are provided.

  The bathroom heating system 1B uses a heat pump hot water supply system 4 as a hot water source of the mist generator 2. Moreover, the electric heater built in the bathroom heating ventilation drying apparatus 3 is utilized as a heat source of the bathroom heating ventilation drying apparatus 3. Then, the operation of the mist generating device 2 and the operation of the bathroom heating / ventilating / drying device 3 are linked to make the inside of the bathroom 101 into a middle temperature and high humidity mist sauna state in a short time, and the mist generating device 2 and the radiant heating device 111A. The mist ejected from the mist generator 2 is reheated.

  Here, as the mist generating device 2, the mist generating device 2A of the first embodiment described in FIG. 2 and the like, the mist generating device 2B of the second embodiment described in FIG. Any of the mist generator 2C of the third embodiment may be used.

  Moreover, as the bathroom heating ventilation drying apparatus 3, the bathroom heating ventilation drying apparatus 3A of 1st Embodiment demonstrated in FIG. 5 may be sufficient.

  Furthermore, the heat pump hot water supply system 4 may be either the heat pump hot water supply system 4A of the first embodiment described in FIG. 7 or the heat pump hot water supply system 4B of the second embodiment described in FIG.

  The bathroom heating system 1 </ b> B is controlled by, for example, a main control unit 5 provided in the bathroom heating / ventilation / drying apparatus 3, and the main control unit 5 includes a main operation unit 6 and a bathroom 101 installed in a washroom 102 adjacent to the bathroom 101. A predetermined control is executed in response to an operation of the mist operation unit 7 installed in the apparatus.

  The main operation unit 6 is, for example, a remote control device wired with the main control unit 5 by an electric cable 6a, and the mist operation unit 7 is a remote control device wirelessly connected with the main control unit 5 by infrared communication. As an example, it is possible to perform operations such as starting and stopping the heating operation at the bathroom undressing place 102 and switching the mist ejection state in the bathroom 101.

<The structural example of the radiation heating apparatus of 1st Embodiment>
FIG. 27 is a configuration diagram illustrating an example of the radiant heating device 111A according to the first embodiment. Next, the configuration of the radiant heating device 111A will be described. In addition, Fig.27 (a) is a sectional side view which shows the internal structure of radiant heating apparatus 111A, FIG.27 (b) is a lower surface sectional view which shows the internal structure of radiant heating apparatus 111A.

  The radiant heating device 111A includes a heater 112, a fan 113 that blows air to the heater 112, and a main body case 114 to which the heater 112, the fan 113, and the like are attached.

  The heater 112 is an example of radiant heat radiation means, and is, for example, a rod-shaped carbon heater that radiates radiant heat. The heater 112 may be another radiant heater such as a halogen heater.

  The fan 113 is configured by a sirocco fan or the like, for example, and a blower duct 115 connected to the fan 113 extends along the heater 112. The air duct 115 includes a plurality of air holes 115 a in the longitudinal direction, and supplies the air from the fan 113 to the entire longitudinal direction of the heater 112.

  The main body case 114 includes an opening 116 that radiates radiant heat from the heater 112. A guard member 116 a that protects the heater 112 and the like is attached to the opening 116. Further, the main body case 114 includes a reflection plate 117 facing the opening 116. The reflector 117 reflects the radiant heat radiated from the heater 112 toward the opening 116.

  The radiant heating device 111 </ b> A is attached to the wall surface or the like of the bathroom 101 with the opening 116 facing the mist flow ejected from the mist generating device 2 as shown in FIG. 26.

  Thus, when the radiant heating device 111 </ b> A is driven in a state where the mist is ejected by the mist generating device 2, the mist is reheated by the radiant heat from the heater 112.

<Operation Example of Bathroom Heating System of Second Embodiment>
Next, the operation of the bathroom heating system 1B according to the second embodiment will be described with reference to FIGS.

  In the bathroom heating system 1B, when the mist mode button 72 of the main operation unit 6 shown in FIG. 9 is pressed, the main control unit 5 determines that the mist mode is selected, and first sets the mist mode before bathing as the mist mode. Execute.

  In the pre-bath mist mode, the main control unit 5 controls the mist generating device 2 to eject mist. Hot water is supplied to the mist generating device 2 from the heat pump hot water supply system 4. For example, in the case of the heat pump hot water supply system 4A shown in FIG. 7, the hot water heated by the temperature / pressure control device 52A is increased and the heated hot water is mist generated. Supplied to the device 2.

  If the mist generating device 2 is the mist generating device 2A of the first embodiment shown in FIG. 2 or the like, the propeller fan 16 is rotated and the mist is ejected from all the mist nozzles 11A, thereby propeller fans. The mist atomized by 16 is ejected.

  In the mist mode before bathing, the main control unit 5 controls the bathroom heating / ventilating / drying device 3 to blow out hot air. If the bathroom heating / ventilating / drying apparatus 3 is the bathroom heating / ventilating / drying apparatus 3A of the first embodiment shown in FIG. 5, the fan motor 36 is controlled so that the fan air volume becomes “strong”, and Energize. Moreover, let the damper 40 be a circulation position.

  Thereby, 3 A of bathroom heating ventilation drying apparatuses blow off warm air in the bathroom 101, circulating the air in the bathroom 101. FIG. And in the mist mode before bathing, since the fan air volume is set to “strong”, the amount of hot air blown out increases.

  Therefore, in the mist mode before bathing, the mist is blown out with the mist generating device 2 (2A) being the maximum, the hot air is blown out with the bathroom airflow ventilation drying device 3 (3A) with the fan airflow being “strong”, The bathroom 101 can be brought into the mist sauna state in a short time.

  When the main control unit 5 detects the temperature of the bathroom 101 and determines that the temperature of the bathroom 101 has reached the upper limit value of the pre-bath heating temperature set when the pre-bath mist mode is executed, the operation mode is set to the pre-bath mist. Switch from mode to mist mode during bathing.

  That is, the main control unit 5 stops the bathroom heating / ventilating / drying apparatus 3 and controls the radiant heating apparatus 111A to energize the heater 112 in the bathing mist mode. Further, in the mist mode during bathing, the main control unit 5 ejects the mist from the mist generating device 2 at an ejection amount corresponding to the set temperature selected by the temperature setting button 80 of the mist operation unit 7 shown in FIG. Continue.

  Thereby, the bathroom 101 is heated by the radiant heat from the heater 112 of the radiant heating device 111A, and the mist ejected from the mist generating device 2 is reheated, and the bathroom 101 maintains the mist sauna state. In the mist mode during bathing, the bathroom heating / ventilating / drying apparatus 3 is stopped, so that the blowing of warm air is stopped and the bather is not exposed to the warm air. This prevents the bather from feeling cold.

  In the mist mode during bathing, the radiant heating device 111A is switched on and off and the amount of mist ejected is switched according to the temperature of the bathroom 101, and the temperature of the bathroom 101 is set to the temperature setting of the mist operation unit 7. Control is performed so as to maintain the set temperature selected by the button 80.

  When the main operation unit 6 or the mist operation unit 7 is operated to instruct the end of the mist mode, the main control unit 5 controls the mist generating device 2 to stop the mist ejection. Further, the radiant heating device 111A is controlled to stop energization of the heater 112. Further, the main control unit 5 controls the bathroom heating / ventilating / drying apparatus 3 to execute the post-mist ventilation mode described above to perform circulation ventilation of the bathroom 101.

  This exhausts moisture from the bathroom 101 in a mist sauna state, thereby preventing mold from occurring after the mist mode. Then, the post-mist ventilation mode is ended by an operation of a bather or the like or a timer timing.

  In the bathroom heating system 1B including the bathroom heating / ventilating / drying device 3 and the radiant heating device 111A, as a heating mode that does not use the mist generating device 2, warm air is heated by the bathroom heating / ventilating / drying device 3 in the heating mode before bathing, The bathroom heating / ventilation / drying device 3 is stopped in the bathing heating mode, and heating is performed by the radiant heat of the radiant heating device 111A.

  Thereby, in the heating mode before bathing, the bathroom 101 can be heated in a short time, and in the heating mode during bathing, it is possible to prevent the bather from being exposed to wind (warm air).

<Overall configuration example of the bathroom heating system according to the third embodiment>
FIG. 28 is a configuration diagram illustrating an example of a bathroom heating system 1C according to the third embodiment. The bathroom heating system 1C according to the third embodiment includes a mist generating device 2 that ejects mist into the bathroom 101, and a bathroom heating ventilation drying device 3C that includes the radiant heating device 111B to heat and ventilate the bathroom 101. And a heat pump hot water supply system 4 for supplying hot water to the mist generator 2, the bathroom 101, and the like.

  The bathroom heating system 1 </ b> C uses a heat pump hot water supply system 4 as a hot water source of the mist generator 2. Moreover, the electric heater incorporated in 3 C of bathroom heating ventilation drying apparatuses is utilized as a heat source of the warm air of the bathroom heating ventilation drying apparatus 3C. Then, the operation of the mist generator 2 and the operation of the bathroom heating / ventilation / drying apparatus 3C are linked to make the interior of the bathroom 101 into a mist sauna state of medium temperature and high humidity in a short time, and the mist generating apparatus 2 and the bathroom heating / ventilation drying process. The mist ejected from the mist generator 2 is reheated in conjunction with the radiant heating device 111B of the device 3C.

  Here, as the mist generating device 2, the mist generating device 2A of the first embodiment described in FIG. 2 and the like, the mist generating device 2B of the second embodiment described in FIG. Any of the mist generator 2C of the third embodiment may be used.

  The heat pump hot water supply system 4 may be either the heat pump hot water supply system 4A of the first embodiment described in FIG. 7 or the heat pump hot water supply system 4B of the second embodiment described in FIG.

  The bathroom heating system 1B is controlled by, for example, a main control unit 5 provided in the bathroom heating ventilation drying device 3C, and the main control unit 5 includes a main operation unit 6 and a bathroom 101 installed in a washroom 102 adjacent to the bathroom 101. A predetermined control is executed in response to an operation of the mist operation unit 7 installed in the apparatus.

  The main operation unit 6 is, for example, a remote control device wired with the main control unit 5 by an electric cable 6a, and the mist operation unit 7 is a remote control device wirelessly connected with the main control unit 5 by infrared communication. As an example, it is possible to perform operations such as starting and stopping the heating operation at the bathroom undressing place 102 and switching the mist ejection state in the bathroom 101.

<Configuration example of bathroom heating / ventilating / drying device equipped with radiant heating device>
FIG. 29 is a block diagram showing an example of a bathroom heating / ventilation / drying apparatus 3C provided with a radiant heating apparatus 111B. Next, the configuration of the bathroom heating / ventilation / drying apparatus 3C provided with a radiant heating apparatus 111B will be described. FIG. 29 is an exploded perspective view of the bathroom heating / ventilating / drying apparatus 3C as viewed from below.

  The internal configuration of the bathroom heating / ventilating / drying apparatus 3C is the same as that of the bathroom heating / ventilating / drying apparatus 3A of the first embodiment described with reference to FIG. 5, and includes a fan unit 32 and a heater unit 33. Although not shown in FIG. 29, a damper or the like for switching the air path is provided.

  3C of bathroom heating ventilation drying apparatuses are equipped with the radiant heating apparatus 111B in the front panel 26f. The radiant heating device 111 </ b> B includes a heater 118. The heater 118 is an example of radiant heat radiating means, and is, for example, a rod-shaped carbon heater that radiates radiant heat. The heater 118 may be another radiant heater such as a halogen heater.

  The front panel 26 f includes an opening 26 g that radiates radiant heat from the heater 118. A guard member 26h that protects the heater 118 and the like is attached to the opening 26g. Further, the front panel 26f includes a reflecting plate 119 facing the opening 26g. The reflector 119 reflects the radiant heat radiated from the heater 118 in the direction of the opening 26g.

  For example, the front panel 26f may be configured integrally with the front panel of the mist generating device 2 as shown in FIG. 28, or may be an independent form as shown in FIG. The radiant heating device 111 </ b> B is attached so that the opening 26 g faces the mist flow ejected from the mist generating device 2.

  Thus, when the radiant heating device 111B is driven in a state where the mist is ejected by the mist generating device 2, the mist is reheated by the radiant heat from the heater 118.

<Operation example of bathroom heating system according to the third embodiment>
Next, the operation of the bathroom heating system 1C of the third embodiment will be described with reference to FIGS.

  In the bathroom heating system 1C, when the mist mode button 72 of the main operation unit 6 shown in FIG. 9 is pressed, the main control unit 5 determines that the mist mode has been selected, and first sets the mist mode before bathing as the mist mode. Execute.

  In the pre-bath mist mode, the main control unit 5 controls the mist generating device 2 to eject mist. Hot water is supplied to the mist generating device 2 from the heat pump hot water supply system 4. For example, in the case of the heat pump hot water supply system 4A shown in FIG. 7, the hot water heated by the temperature / pressure control device 52A is increased and the heated hot water is mist generated. Supplied to the device 2.

  If the mist generating device 2 is the mist generating device 2A of the first embodiment shown in FIG. 2 or the like, the propeller fan 16 is rotated and the mist is ejected from all the mist nozzles 11A, thereby propeller fans. The mist atomized by 16 is ejected.

  In the mist mode before bathing, the main control unit 5 controls the bathroom heating / ventilation drying apparatus 3C to blow out hot air. That is, the main control unit 5 controls the fan motor 36 shown in FIG. 5 and the like so that the fan air volume becomes “strong” and energizes the heater unit 33. Moreover, let the damper 40 be a circulation position.

  Thereby, 3 C of bathroom heating ventilation drying apparatuses blow off warm air in the bathroom 101, circulating the air in the bathroom 101. FIG. And in the mist mode before bathing, since the fan air volume is set to “strong”, the amount of hot air blown out increases.

  Therefore, in the mist mode before bathing, the mist is blown out with the mist generating device 2 (2A) at the maximum amount, and the hot air is blown out with the fan air amount set to “strong” in the bathroom heating / ventilating / drying device 3C. The bathroom 101 can be in a mist sauna state.

  When the main control unit 5 detects the temperature of the bathroom 101 and determines that the temperature of the bathroom 101 has reached the upper limit value of the pre-bath heating temperature set when the pre-bath mist mode is executed, the operation mode is set to the pre-bath mist. Switch from mode to mist mode during bathing.

  That is, in the mist mode during bathing, the main control unit 5 controls the bathroom heating / ventilating / drying device 3C to stop the fan unit 32 and the heater unit 33, and controls the radiant heating device 111B to energize the heater 118. I do. Further, in the mist mode during bathing, the main control unit 5 ejects the mist from the mist generating device 2 at an ejection amount corresponding to the set temperature selected by the temperature setting button 80 of the mist operation unit 7 shown in FIG. Continue.

  Thereby, the bathroom 101 is heated by the radiant heat generated by the heater 118 of the radiant heating device 111B, and the mist ejected from the mist generating device 2 is reheated, so that the bathroom 101 maintains the mist sauna state. In the mist mode during bathing, the fan unit 32 and the heater unit 33 of the bathroom heating / ventilating / drying apparatus 3 are stopped, so that the blowing of warm air is stopped and the bather is not exposed to warm air. The bather can be prevented from feeling cold.

  In the mist mode during bathing, the temperature of the bathroom 101 is set to the temperature setting of the mist operation unit 7 by switching on / off the radiant heating device 111B and switching the amount of mist ejected according to the temperature of the bathroom 101. Control is performed so as to maintain the set temperature selected by the button 80.

  When the main operation unit 6 or the mist operation unit 7 is operated to instruct the end of the mist mode, the main control unit 5 controls the mist generating device 2 to stop the mist ejection. Further, the radiant heating device 111B is controlled to stop energization of the heater 118. Furthermore, the main control unit 5 controls the bathroom heating / ventilation / drying device 3 </ b> C, executes the post-mist ventilation mode described above, and performs circulation ventilation of the bathroom 101.

  This exhausts moisture from the bathroom 101 in a mist sauna state, thereby preventing mold from occurring after the mist mode. Then, the post-mist ventilation mode is ended by an operation of a bather or the like or a timer timing.

  In the bathroom heating system 1B including the bathroom heating / ventilation drying apparatus 3C having the radiant heating apparatus 111B, as the heating mode of the bathroom heating / ventilation drying apparatus 3C alone, warm air heating by the bathroom heating / ventilation drying apparatus 3C is performed in the heating mode before bathing. The hot air blowing by the bathroom heating / ventilation drying device 3C is stopped in the bathing heating mode, and heating is performed by the radiant heat of the radiant heating device 111B.

  Thereby, in the heating mode before bathing, the bathroom 101 can be heated in a short time, and in the heating mode during bathing, it is possible to prevent the bather from being exposed to wind (warm air).

<Modified example of bathroom heating system>
In each of the above-described embodiments, the bathroom heating / ventilating / drying apparatus 3 includes one fan and a damper and can circulate and exhaust the air in the bathroom as an example. (Ventilation) The fan may be provided independently.

  In addition, the mist mode before bathing and the mist mode during bathing are switched according to the temperature detected by the temperature sensor 69, but it is linked with a bathroom lighting switch (not shown) provided outside the bathroom 101 or by a human sensor provided in the bathroom. A bather may be detected, and the mist mode before bathing may be switched to a mist during bathing. Furthermore, the mist mode before bathing and the mist mode during bathing may be provided in the main operation unit 6 and the mist operation unit 7 separately to switch between the mist mode before bathing and the mist mode during bathing.

  Further, warm air is blown into the bathroom 101 by the bathroom heating / ventilating / drying device 3 interlocked with the mist generating device 2 in the mist mode before bathing and in the mist mode during bathing. Heating may be performed using the mist of

  Moreover, the bathroom heating ventilation drying apparatus 3 as a bathroom air conditioner may be one in which a ventilation apparatus and a heating apparatus are separately provided and interlocked. Furthermore, the bathroom air conditioner may be a heating device or a blower that does not have a ventilation function.

  The present invention is applied to a bathroom heating system including a mist generating device and a bathroom heating / ventilating / drying device.

It is a lineblock diagram showing an example of the bathroom heating system of a 1st embodiment. It is a block diagram which shows an example of the mist generator of 1st Embodiment. It is a block diagram which shows an example of the mist generator of 1st Embodiment. It is a block diagram which shows an example of a supply control valve apparatus. It is an internal block diagram which shows an example of the bathroom heating ventilation drying apparatus of 1st Embodiment. It is the block diagram which looked at the bathroom heating ventilation drying apparatus of 1st Embodiment from the lower surface side. It is a lineblock diagram showing an example of the heat pump hot-water supply system of a 1st embodiment. It is a functional block diagram which shows an example of the control system of the bathroom heating system of 1st Embodiment. It is a block diagram which shows an example of the main operation part. It is a block diagram which shows an example of a mist operation part. It is an operation | movement table which shows the pattern of the combination of operation | movement of each part of the mist generating apparatus at the time of mist mode execution. It is an operation | movement table which shows the pattern of the combination of operation | movement of each part of the bathroom heating ventilation drying apparatus at the time of mist mode execution. It is a flowchart which shows 1st Embodiment of the mist mode performed with the bathroom heating system of 1st Embodiment. It is a flowchart which shows 2nd Embodiment of the mist mode performed with the bathroom heating system of 1st Embodiment. It is a flowchart which shows 2nd Embodiment of the mist mode performed with the bathroom heating system of 1st Embodiment. It is a block diagram which shows an example of the residual water discharge apparatus with which a mist generator is equipped. It is a block diagram which shows an example of the ion generator with which a mist generator is equipped. It is a block diagram which shows the 1st example of installation of a mist generator. It is a block diagram which shows the 2nd installation example of a mist generator. It is an operation | movement table which shows the pattern of the combination of the operation mode in a bathroom heating ventilation drying apparatus single-piece | unit, and each part operation | movement. It is a block diagram which shows an example of the mist generator of 2nd Embodiment. It is a block diagram which shows an example of the mist generator of 3rd Embodiment. It is sectional drawing which shows an example of a nozzle replacement | exchange apparatus. It is sectional drawing which shows the modification of the mist nozzle attached to a nozzle exchange apparatus. It is a block diagram which shows an example of the heat pump hot-water supply system of 2nd Embodiment. It is a block diagram which shows an example of the bathroom heating system of 2nd Embodiment. It is a block diagram which shows an example of the radiation heating apparatus of 1st Embodiment. It is a block diagram which shows an example of the bathroom heating system of 3rd Embodiment. It is a block diagram which shows an example of the bathroom heating ventilation drying apparatus provided with the radiation heating apparatus.

Explanation of symbols

1A, 1B, 1C ... Bathroom heating system (bathroom air conditioning system), 2A, 2B, 2C ... Mist generating device, 3A, 3C ... Bathroom heating ventilation drying device (bathroom air conditioning device), 4A, 4B .. Heat pump hot water supply system, 5 ... main control unit, 6 ... main operation unit, 7 ... mist operation unit, 11A, 11B ... mist nozzle, 12 ... supply control valve device, 13 ..Axial fan section, 16 ... propeller fan, 26 ... front panel, 28 ... supply switching solenoid valve, 29 ... three-way switching solenoid valve, 30 ... individual switching solenoid valve, 31a ..Water supply piping, 31b ... Drain piping, 31c ... Water temperature detection sensor, 32 ... Fan unit, 33 ... Heater unit, 40 ... Damper, 44 ... Ion generator, 51A, 51B ... Heat pump water heater 52A, 52B ... temperature / pressure control device, 53 ... heat pump unit, 54 ... hot water storage tank unit, 55 ... air heat exchanger, 56 ... water heat exchanger, 57 ... refrigerant piping 58 ... Compressor 59 ... Expansion valve 60 ... Tank 60a ... Inlet, 60b ... Outlet, 60c ... High temperature water intake, 60d ... Medium temperature part Intake port, 60e ... supply port, 60f ... high temperature part intake port, 61a ... hot water pipe, 61b ... cold water pipe, 62 ... intake pipe, 62a ... high temperature part intake pipe, 62b ... Middle temperature intake pipe, 62d ... Mist intake pipe, 63 ... Water supply pipe, 63a ... Branch water supply pipe, 63b ... Mist water supply pipe, 63c ... Branch water supply pipe, 64a, 64b ... Hot water mixing valve, 65 ... Hot water piping, 65a Mist hot water supply pipe, 66 ... pressurizing device, 67 ... heating device, 68 ... mixing valve, 69 ... temperature detection sensor, 71 ... display unit, 72 ... mist mode button, 73 ... Heating mode button, 74 ... Ventilation mode button, 75 ... Drying mode button, 76 ... Cool air mode button, 77 ... Setting button, 78 ... Lamp, 79 ... Operation selection Button, 80 ... Temperature setting button, 81 ... Net, 101 ... Bathroom, 102 ... Washroom, 103 ... Kitchen, 111A, 111B ... Radiant heating device

Claims (13)

A hot water jetting device having a mist nozzle that receives warm water or water and generates mist;
A bathroom air conditioner that blows air or warm air according to the operation mode;
Comprising a control means for executing a mist mode for interlocking operation of the hot water jetting device and the bathroom air conditioner;
In the mist mode, the control means ejects mist from the hot water jetting device using the mist jetting amount as the first jetting amount, and blows or warms the airflow from the bathroom air conditioner as the first airflow. The first mist mode to blow out the wind;
While spraying mist with the hot water jetting device while changing the jetting amount in the range smaller than the first jetting amount or the same jetting amount as the first jetting amount according to the preset temperature of the bathroom set in advance , The bathroom air-conditioning system is characterized by switching and executing a second mist mode in which the bathroom air-conditioning apparatus blows air or warm air as a second air volume weaker than the first air volume. The control means, when the detected temperature of the bathroom detected by the temperature detection means reaches a predetermined temperature for switching the operation mode,
Or when the bathroom lighting switch provided outside the bathroom is operated,
Or, when a bather is detected by a human sensor installed in the bathroom,
The bathroom air-conditioning system according to claim 1, wherein the first mist mode is switched to the second mist mode when the mist mode switch provided in the operation means is operated . The hot water jetting device is
It has an impeller that is rotationally driven by the driving means, and air flows in from the axial direction and flows out in the axial direction, and the mist ejected from the mist nozzle collides with the rotationally driven impeller to make a fine mist Diffusion means to
Claim 1, wherein the impeller is formed in the axial direction of the impeller along the flow of air generated by being rotated, characterized in that a blow-out port for blowing out the fine mist of the mist Or the bathroom air conditioning system of Claim 2 . The hot water jetting device is
The bathroom air conditioning system according to claim 1 or 2, further comprising a net-like member that allows the mist ejected from the mist nozzle to pass therethrough and atomizes the passing mist . Generating hot water by heat exchange between the heat exchange and the refrigerant and the water between the air and the refrigerant, claims 1, characterized in that it comprises a heat pump water heater for supplying the hot water jetting device 5. The bathroom air conditioning system according to any one of 4 above. The bathroom air conditioning system according to any one of claims 1 to 5, wherein the bathroom air conditioner includes an electric heater and generates warm air. The bathroom air conditioner includes ventilation means for sucking air in the bathroom and exhausting it to the outside,
The said control means performs the post-mist ventilation mode which ventilates the said bathroom with the said bathroom air conditioner after the said mist mode, The any one of the Claims 1-6 characterized by the above-mentioned. Bathroom air conditioning system. The bathroom air conditioner includes ion generating means for generating positive ions and negative ions and supplying air ions to be blown out.
The control means sucks air in the bathroom as the post-mist ventilation mode, blows out air while generating both positive ions and negative ions by the ion generating means, and sucks air in the bathroom The bathroom air-conditioning system according to claim 7 , wherein the bathroom air-conditioning system is exhausted . The operation means includes
Main operating means installed outside the bathroom;
Sub-operating means installed in the bathroom,
The main operation means includes a mist mode button for selecting start and stop of the mist mode,
The auxiliary operating means according to claim 1, comprising: the operation selection button for selecting the stop of the mist mode, and a temperature setting button for setting the set temperature of the bath of the mist mode to the user The bathroom air conditioning system according to any one of claims 8 to 9 . The bathroom air conditioner includes ventilation means for sucking air in the bathroom and exhausting it to the outside,
When the control unit is selected to stop the mist mode by the main operation unit, the control unit stops the mist mode, and executes a post-mist ventilation mode for ventilating the bathroom with the bathroom air conditioner,
When the stop of the mist mode is selected by the sub-operating means, the mist jetting by the hot water jetting device stops and the hot air blowing by the bathroom air conditioner continues, and the preset heating operation time The bathroom air-conditioning system according to claim 9 , wherein after the lapse of time, the post-mist ventilation mode is executed . When the temperature of the bathroom detected by the temperature detecting means reaches the upper limit value of the set temperature corresponding to the heating state set by the sub-operating means, the control means discharges mist from the hot water jetting device. The bathroom air-conditioning system according to claim 9 , wherein the bathroom air-conditioning system is configured to reduce the amount and stop blowing air or hot air from the bathroom air-conditioning apparatus . The hot water jetting device includes a flow path switching valve for switching a hot water supply destination to the mist nozzle or a discharge unit, and a water temperature detecting means for detecting the temperature of the hot water,
When the control means starts the mist mode, the flow path switching valve switches the supply destination of the hot water to the discharge section to perform the waste water, and when the temperature of the hot water detected by the water temperature detection means reaches a predetermined value, The bathroom air conditioning system according to any one of claims 1 to 11, wherein a hot water supply destination is switched to the mist nozzle by a flow path switching valve . The hot water ejecting device and the bathroom air-conditioner and arranged on the ceiling of the bathroom, of claims 1 to 12, characterized in that it comprises a front panel covering together the hot water jetting device and the bathroom air-conditioner The bathroom air conditioning system according to any one of the above.

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