JP4770373B2 - Hot water jetting device, hot water supply system, and room applying it - Google Patents

Description

  The present invention relates to a hot water jetting apparatus, a hot water supply system, and a chamber to which these are applied, which are suitable for application to a mist sauna apparatus that jets hot water supplied from a hot water heater. Specifically, it is equipped with a power supply unit that controls the drainage operation of the mist generating device based on temperature detection information obtained by detecting the drainage temperature, preset drainage set time and jetting set temperature, and water in the piping is Regardless of whether it is cold or warm, it is possible to efficiently control the discharge operation of water such as residual water, and even when the mist generator is used longer or when the mist generator is used continuously, always The hot water at the jetting set temperature can be jetted.

  Conventionally, an apparatus called a mist sauna apparatus or the like that sprays hot water into a bathroom as mist and heats the bathroom has been proposed (for example, see 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

  The conventional mist sauna apparatus has the following problems.

  i. According to the rising drainage operation at the start of mist sauna operation, the drainage operation of residual water etc. is not efficiently controlled both in terms of drainage setting time and hot water discharge amount, whether the water in the pipe is cold or warm is the current situation. The water in this case contains warm water.

  Therefore, there is a possibility that the mist ejection temperature differs between the person who first enters the mist of the day and the second person who immediately enters the mist following the first person. In particular, when the use interval of the mist generating device becomes long or when the mist generating device is used continuously, hot water at the jetting set temperature cannot be jetted.

  ii. Moreover, according to the above-described drainage operation, it is necessary to drain, for example, 2 liters / minute as a flow rate at which the hot water supply device starts to discharge hot water when the mist sauna operation starts. In this case, it is only necessary to secure 2 liters / minute for starting up the mist sauna, and it is useless to drain the hot water too much.

  iii. In order to prevent freezing of pipes in winter, it is necessary to drain hot water regularly at low temperatures, but the drainage flow at that time is preferably small for energy saving.

  iv. Although it is necessary to throw away the residual water in the pipe at the start of the mist sauna operation, it is desirable to drain the water in a short time, so that it is possible to drain a large amount of residual water at a time. As described above, the conventional mist sauna apparatus uses a drain valve that opens and closes uniquely to perform a drain operation and does not control the flow rate adjustment according to the purpose of drainage. In the case of a drain valve that opens and closes uniquely, the drainage flow rate becomes constant.

  The present invention has been created in view of the above-described problems, and a hot water jetting device, a hot water supply system, and a hot water jetting system capable of always jetting hot water at a jetting set temperature regardless of whether the water in the pipe is cold or warm. The purpose is to provide an applied room.

A hot water jetting apparatus according to the present invention includes a hot water supply valve that supplies hot water from a hot water supply source, a jet valve that is connected to one pipe branched from the hot water supply valve, and jets hot water, and is branched from the hot water valve. A drain valve connected to the other pipe for draining water, a detection means for detecting a drain temperature by the drain operation of the drain valve and outputting temperature detection information, temperature detection information output from the detection means, Control means for controlling the drainage operation of the drainage valve based on the drainage set time and the jetting set temperature, the control means inputs temperature detection information, compares the drainage temperature with the jetting set temperature, and the drainage temperature is until more jetting set temperature, continuing the draining operation by drain valve, Yusuke the drainage temperature reaches the set value, a state of stopping the drainage operation by drain valve after discharging the warm water drainage set time Rukoto It is characterized by

  According to the hot water ejection device according to the present invention, the hot water supply valve supplies hot water from a hot water supply source through a pipe. The ejection valve is connected to one pipe branched from the hot water supply valve and ejects hot water. The drainage valve is connected to the other pipe branched from the hot water supply valve and drains residual water or hot water. The detection means detects the drain temperature by the drain operation of the drain valve and outputs temperature detection information. On the premise of this, the control means controls the drainage operation of the drainage valve based on the temperature detection information output from the detection means, the preset drainage setting time and the ejection preset temperature.

For example, the control means inputs temperature detection information, compares the drainage temperature with the jetting set temperature, and continues the drainage operation by the drainage valve until the drainage temperature becomes equal to or higher than the jetting set temperature. When waste water temperature reaches the set value, that having a state of stopping the drainage operation by drain valve after discharging the warm water drainage set time. Therefore, whether the water in the pipe is cold or warm, the discharge operation of water such as residual water can be efficiently controlled both in terms of the drainage setting time and the hot water discharge amount.

The hot water supply system according to the present invention detects hot water supplied from a hot water supply device, hot water supplied from the hot water supply device, or hot water jetting means capable of performing a drainage operation, and a drainage temperature by the drainage operation of the hot water jetting unit. a detecting means for outputting a temperature detection information, the temperature detection information output from the detection means, and control means for controlling the draining operation of the hot water jetting devices based on drainage set time and jetting the set temperature, the control means The temperature detection information is input, the drainage temperature is compared with the jetting set temperature, and the drainage operation by the hot water jetting means is continued until the drainage temperature exceeds the jetting set temperature, and when the drainage temperature reaches the set value, and it is characterized in Rukoto to have a state of stopping the drainage operation by hot water jetting means from the discharged hot water drainage set time.

According to the hot water supply unit according to the present invention, since the hot water jetting device according to the present invention is applied, the control means inputs temperature detection information, compares the drainage temperature with the jetting set temperature, and the drainage temperature is jetted. until the above temperature continues drainage operation by hot water jetting means, the drainage temperature reaches the set value, to Suspend drainage operation by hot water jetting means from the discharged hot water drainage set time. Therefore, whether the water in the pipe is cold or warm, the discharge operation of water such as residual water can be efficiently controlled both in terms of the drainage setting time and the hot water discharge amount.

The chamber according to the present invention is a chamber to which hot water supplied from a water heater is jetted or hot water jetting means capable of draining operation is attached, and detects the temperature of drainage by the draining operation of the hot water jetting means. Detecting means for outputting temperature detection information and control means for controlling the drainage operation of the hot water jetting device based on the temperature detection information outputted from the detection means, the drainage setting time and the jetting set temperature, and the control means The temperature detection information is input, the drainage temperature is compared with the jetting set temperature, and the drainage operation by the hot water jetting means is continued until the drainage temperature becomes equal to or higher than the jetting set temperature. , and it is characterized in Rukoto to have a state of stopping the drainage operation by hot water jetting means from the discharged hot water drainage set time.

According to the chamber according to the present invention, since the hot water ejection device according to the present invention is applied, the control means inputs temperature detection information, compares the drainage temperature and the ejection set temperature, and the drainage temperature is the ejection set temperature. until the above continues drainage operation by hot water jetting means, the drainage temperature reaches the set value, to Suspend drainage operation by hot water jetting means from the discharged hot water drainage set time. Therefore, whether the water in the pipe is cold or warm, the discharge operation of water such as residual water can be efficiently controlled both in terms of the drainage setting time and the hot water discharge amount.

According to the hot water jetting apparatus according to the present invention, the hot water jetting apparatus includes control means for controlling the drainage operation of the hot water jetting apparatus based on the temperature detection information obtained by detecting the drainage temperature, the drainage setting time, and the jetting set temperature. The means inputs the temperature detection information, compares the drainage temperature with the jetting set temperature, and continues the draining operation by the hot water jetting means until the drainage temperature exceeds the jetting set temperature, and the drainage temperature reaches the set value. then, a shall which have a state of stopping the drainage operation by hot water jetting means from the discharged hot water drainage set time.

  With this configuration, when the drainage temperature is equal to or higher than the jetting set temperature, it is possible to execute a hot water discharge operation that reduces the amount of hot water in the pipe to be discharged compared to when the residual water is discharged, and the drainage temperature is below the jetting set temperature. In some cases, it is possible to execute a residual water discharge operation in which the discharge amount of the residual water in the pipe is made larger than that during the warm water discharge. Therefore, even when the water in the pipe is cold or warm, it is possible to efficiently control the discharge operation of water such as residual water. Thereby, even when the use interval of the hot water jetting apparatus becomes long and when the hot water jetting apparatus is continuously used, hot water at the jetting set temperature can always be jetted.

  According to the hot water supply unit according to the present invention, the hot water ejection device according to the present invention is applied. Therefore, when the drainage temperature is equal to or higher than the ejection set temperature, the discharge amount of the hot water in the pipe is less than that at the time of residual water discharge. When the drainage temperature is lower than the jetting set temperature, it is possible to execute the residual water discharge operation in which the discharge amount of the residual water in the pipe is larger than that during the warm water discharge.

  With this configuration, it is possible to efficiently control the discharge operation of water such as residual water, whether the water in the pipe is cold or warm. Thereby, even when the use interval of the hot water jetting apparatus becomes long and when the hot water jetting apparatus is continuously used, hot water at the jetting set temperature can always be jetted.

  According to the chamber according to the present invention, since the hot water ejection device according to the present invention is applied, when the drainage temperature is equal to or higher than the ejection set temperature, the discharge amount of the hot water in the pipe is made smaller than that during the residual water discharge. The hot water discharge operation can be executed, and when the drainage temperature is lower than the jetting set temperature, the residual water discharge operation in which the discharge amount of the residual water in the pipe is made larger than that during the hot water discharge can be executed.

  With this configuration, it is possible to efficiently control the discharge operation of water such as residual water, whether the water in the pipe is cold or warm. Thereby, even when the use interval of the chamber to which the hot water jetting unit is attached becomes long, or when the chamber to which the hot water jetting unit is attached is continuously used, hot water at the jetting set temperature can always be jetted. .

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a conceptual cross-sectional view showing a configuration example of a bathroom system 1 as a first embodiment according to the present invention.

<Whole bathroom system>
A bathroom system 1 shown in FIG. 1 constitutes an example of a hot water supply system, and a hot water jetting apparatus according to the present invention is applied thereto. This bathroom system 1 includes a mist generating device 2, a bathroom air conditioner 3, and a heat pump type hot water supply device 4. The mist generating device 2 is disposed on the ceiling of the bathroom 101 so as to eject hot water (mist) in the form of a mist into the bathroom 101. This mist generating device 2 generates mist using hot water discharged from a hot water supply device 4 that constitutes an example of a hot water supply source, a hot water heater, and the like.

  The mist generating device 2 includes a solenoid valve unit 2A, a power supply unit 2B, and a nozzle unit 2C. A plurality of solenoid valves are provided inside the solenoid valve unit 2A so as to switch between discharge of hot water discharged from the hot water supply device 4 or residual water in the pipe. The electromagnetic valve unit 2A is placed behind the ceiling of the bathroom 101, but is disposed near the inspection port 101a provided on the ceiling of the bathroom 101.

  The solenoid valve unit 2A includes a hot water supply pipe 2a for receiving hot water discharged from the hot water supply device 4, a nozzle pipe 2b for supplying hot water to the nozzle unit 2C, and a drain for draining hot water (residual water). The pipe 2c is connected. The open end of the drain pipe 2c is made to face the drain pan 101c disposed on the lower surface of the bathtub 101b. Here, the hot water supply pipe 2a constitutes a first hot water path, the nozzle pipe 2b constitutes a second hot water path, and the drain pipe 2c constitutes a third hot water path.

  The electromagnetic valve unit 2A is connected to a power supply unit 2B that constitutes an example of a control means. A mist operation unit 7 is connected to the power supply unit 2B. The power supply unit 2B is disposed behind the ceiling of the bathroom 101 in the same manner as the electromagnetic valve unit 2A, and controls opening / closing of a plurality of electromagnetic valves provided in the unit based on an operation command from the mist operation unit 7. Execute.

  In this example, when the drainage temperature is equal to or higher than the jetting set temperature when the drainage operation (hereinafter referred to as mist sauna operation) is started, the power supply unit 2B executes the warmwater discharge operation to reduce the discharge amount of the hot water in the pipe. When the drainage temperature is lower than the jetting set temperature, a residual water discharge operation is performed to increase the discharge amount of the residual water in the pipe. A nozzle unit 2C is connected to the electromagnetic valve unit 2A, and is provided with a nozzle arranged toward the inside of the bathroom so as to eject a mist of hot water. The nozzle unit 2C is attached to the ceiling surface, for example.

  The bathroom air conditioner 3 is also disposed on the ceiling of the bathroom 101, and the bathroom 101 is heated and ventilated. As a heat source of the bathroom air conditioner 3, an electric heater built in the bathroom air conditioner 3 is used. A ventilation duct 8 is connected to the bathroom air conditioner 3, and a ventilation grill 8 a is connected to the ventilation duct 8. The ventilation grill 8a has an exhaust port, and is attached with the exhaust port facing the outside of the bathroom.

  The above-described electromagnetic valve unit 2A is connected to a hot water supply device 4 to warm water using a heat source obtained by compressing refrigerant gas. The hot water supply device 4 is disposed outdoors and supplies hot water or supplies water to the mist generating device 2 and the bathroom 101. The hot water from the hot water supply device 4 is also supplied to the hot water tap 102a of the basin of the washroom 102.

  In addition, the main operation part 6 and the mist operation part 7 are connected to the mist generating apparatus 2 and the bathroom air conditioner 3, and mist generation and an air conditioning operation | movement are performed based on these operation. The main operation unit 6 is a remote control (remote control) device connected to a control unit (not shown in FIG. 1) built in the bathroom air conditioner 3 by an electric cable 6a. The main operation unit 6 (hereinafter referred to as “air-conditioning remote controller 6”) is attached to the wall of the washroom 102. The mist operation unit 7 is a remote control device connected to a control unit (not shown in FIG. 1) built in the power supply unit 2B by an electric cable 7a. The mist operation unit 7 (hereinafter referred to as “mist remote controller 7”) is attached to the wall of the bathroom 101.

  In addition, a human body detection sensor 69A is attached to the bathroom 101, for example, the front panel 26 of the bathroom air conditioner 3. When the bathroom user enters the bathroom, the detection is made and an entry detection signal S69 is output. To be made. The human body detection sensor 69A is configured using, for example, an infrared sensor (see Japanese Patent Laid-Open No. 10-142351).

  Thus, the bathroom system 1 which applied the hot water ejection apparatus and the hot water supply system is comprised. Hereinafter, an example of the internal configuration of the electromagnetic valve unit 2A and a control example thereof will be described.

<Solenoid valve unit>
FIG. 2 is a front view showing a configuration example of the electromagnetic valve unit 2A. The electromagnetic valve unit 2A shown in FIG. 2 has a housing 2A ′. In this example, when one side surface of the housing 2A ′ is opened, the arrangement of the electromagnetic valves in the electromagnetic valve unit can be seen.

  The casing 2A ′ has a connecting portion 2a ′ for connecting the hot water supply pipe 2a, a connecting portion 2b ′ for connecting the nozzle pipe 2b, and a connecting portion 2c for connecting the drain pipe 2c. ′ Is attached and fixed.

  In this example, a hot water supply electromagnetic valve 2d, which is an example of a hot water supply valve, is attached to the connection portion 2a 'inside the housing 2A' so that hot water from the hot water supply device 4 is supplied. An electromagnetic valve 2e for a mist unit, which is an example of an ejection valve, is attached to one pipe 2j branched from the electromagnetic valve 2d so as to supply hot water to the nozzle unit 2C. The downstream side (the other end) of the electromagnetic valve 2e is attached to the connection portion 2b ′.

  An electromagnetic valve 2f, which is an example of a drain valve, is disposed at a position lower than the electromagnetic valve 2e, and is attached to the other pipe 2k branched from the electromagnetic valve 2d so as to discharge water, residual water, and the like. To be made. The water here includes warm water. The downstream side (the other end) of the electromagnetic valve 2f is attached to the connecting portion 2c ′. That is, one end of the electromagnetic valve 2d is connected to the connection portion 2a ', and one end of the electromagnetic valve 2e is connected to the other end of the electromagnetic valve 2d via the pipe 2j. The other end of the electromagnetic valve 2e is connected to the connection portion 2b ′. Furthermore, the pipe 2k branched from the pipe 2j is connected to one end of the electromagnetic valve 2f, and the connecting portion 2c 'is connected to the other end of the electromagnetic valve 2f.

  In addition to the solenoid valves 2d, 2e, and 2f, a temperature detection sensor 2h is disposed inside the solenoid valve unit 2A. The temperature detection sensor 2h is attached to the pipe 2j, for example, and detects the temperature of water (hot water) flowing through the pipe 2j after passing through the electromagnetic valve 2d and outputs a temperature detection signal S2h. In this example, when the mist sauna operation is started, the drainage temperature due to the drainage operation of the electromagnetic valve 2f is detected, and the temperature detection signal S2h (temperature detection information) is output from the temperature sensor 2h to the power supply unit 2B.

<Power supply unit>
The electromagnetic valve 2d, the electromagnetic valve 2e, and the electromagnetic valve 2f described above are connected to the power supply unit 2B, and the temperature detection signal S2h output from the temperature sensor 2h, the preset drainage set time t, and the ejection set temperature TH are set. Based on this, the drain operation of the electromagnetic valve 2f is controlled. For example, when the drainage temperature T1 is equal to or higher than the jetting set temperature TH at the start of the mist sauna operation, the power supply unit 2B executes the warm water discharge operation that reduces the discharge amount of the hot water in the pipe. Further, when the drainage temperature T1 is lower than the ejection set temperature TH, a residual water discharge operation for increasing the discharge amount of the residual water in the pipe is executed.

  In the power supply unit 2B, for example, the temperature detection signal S2h is input, the drainage temperature T1 is compared with the ejection set temperature TH, and when the drainage temperature T1 is equal to or higher than the ejection set temperature TH, After discharging the mist, the drain operation of the mist generator 2 is stopped. When the drainage temperature T1 is lower than the ejection set temperature TH, the drain operation of the mist generator 2 is continued until the drainage temperature T1 reaches the ejection set temperature TH, and the drainage temperature T1 reaches the ejection set temperature TH. The drain operation of the mist generator 2 is stopped.

  In addition, if the predetermined time is exceeded by the time the drain temperature T1 reaches the jetting set temperature TH, the drainage for the drain set time t can be prevented. The drainage set time t described above may be varied including zero based on the time required for the drainage temperature T1 to reach the jetting set temperature TH.

  3A to 3C are diagrams showing an operation example of the electromagnetic valve unit 2A when the mist sauna operation is started. In the electromagnetic valve unit 2A shown in FIG. 3A, the state is just before the mist sauna operation is started, and all the electromagnetic valves 2d, 2e, and 2f in the electromagnetic valve unit are closed. This state is also a state in which the mist sauna operation is stopped and waiting for its start.

  According to the solenoid valve unit 2A shown in FIG. 3B, in the drainage control at the time of starting the mist sauna operation, the solenoid valve 2d for hot water supply and the solenoid valve 2f for drainage in the solenoid valve unit are in an open state. The solenoid valve 2e is controlled to be closed. In this control, the hot water I from the hot water supply pipe 2a (see FIG. 1) is supplied from the connecting portion 2a ′ to the electromagnetic valve 2f for drainage through the solenoid valve 2d and the pipe 2k, and the drainage temperature T1 is set to be ejected. Residual water in the piping is discharged so that the temperature is equal to or higher than the temperature TH. At this time, the temperature of water (hot water) flowing through the pipe 2j after passing through the electromagnetic valve 2d is detected, and a temperature detection signal S2h is output from the temperature detection sensor 2h to the power supply unit 2B.

  In the power supply unit 2B, the temperature detection signal S2h is input, the drainage temperature T1 is compared with the ejection set temperature TH, and when the drainage temperature T1 is equal to or higher than the ejection set temperature TH, the hot water I is discharged for the drainage set time t. Then, the electromagnetic valve 2f is closed to stop the draining operation. If the drainage temperature T1 is lower than the ejection set temperature TH, the drainage operation is continued with the solenoid valve 2f opened until the drainage temperature T1 reaches the ejection set temperature TH, and the drainage temperature T1 is set to the ejection set temperature TH. The draining operation of the electromagnetic valve 2f is stopped at the time point coincident with.

  According to the electromagnetic valve unit 2A shown in FIG. 3C, in the hot water supply control during the mist sauna operation, the electromagnetic valve 2e for the mist unit is opened while the electromagnetic valve 2d is opened. By opening the electromagnetic valve 2e, the hot water I from the hot water supply pipe 2a is supplied to the nozzle pipe 2b (see FIG. 1) from the connection part 2a ′ through the electromagnetic valve 2d, the pipe 2j, the electromagnetic valve 2e, and the connection part 2b ′. . Hot water I is ejected from the mist nozzle unit 2C. At this time, the electromagnetic valve 2f for drainage remains closed.

  4A and 4B are diagrams showing an operation example of the electromagnetic valve unit 2A when the mist sauna operation is stopped. According to the electromagnetic valve unit 2A shown in FIG. 4A, in the drainage control after the mist sauna operation is stopped, the hot water supply electromagnetic valve 2d is closed. Next, by opening the electromagnetic valve 2f for drainage, the remaining water (hot water) II from the connection pipe 2b 'is drained through the electromagnetic valve 2f through the pipes 2j and 2k. At this time, since the electromagnetic valve 2e remains open, the air III is taken into the electromagnetic valve 2e and the pipes 2j and 2k through the connection pipe 2b '. Thereby, the residual water II in the connection pipe 2b ′, the electromagnetic valve 2e, the pipe 2j, and 2k can be discharged to the drain pan 101c through the electromagnetic valve 2f.

  In this example, the solenoid valve 2e for the mist unit is closed after a predetermined time, for example, after 3 seconds, and the electromagnetic valve 2f for drainage is closed. As a result, as shown in FIG. 4B, all the electromagnetic valves 2d, 2e, and 2f in the electromagnetic valve unit are closed. It is made to wait for the next mist sauna operation.

<Nozzle unit>
5A to 5C are diagrams illustrating a configuration example of the nozzle unit 2C. 5A is a front view of the nozzle unit 2C, FIG. 5B is a plan view seen from the lower side of the nozzle unit 2C, and FIG. 5C is a side view of the nozzle unit 2C.

  In the nozzle unit 2C shown in FIG. 5A, a plurality of nozzles 2m for ejecting mist are arranged in the lower part in the longitudinal direction, three in this case as shown in FIG. It comprises a portion 2Ca and fixed portions 2Cb1 and 2Cb2 arranged on both sides of the movable portion 2Ca in the longitudinal direction. The fixed portions 2Cb1 and 2Cb2 are fixed to the ceiling of the bathroom 101 and pivotally support the movable portion 2Ca so as to be rotatable. As shown in FIG. 5C, the movable portion 2Ca has a structure that can swing left and right with respect to the rotation axis.

  For example, the fixed portion 2Cb1 includes a drive mechanism (not shown) including a motor, a speed reduction mechanism, and the like for rotationally driving the movable portion 2Ca. With this drive mechanism, the movable part 2Ca can be rotated so that the nozzle 2m is directed in a predetermined direction. However, it is possible to adopt a structure in which the direction can be arbitrarily switched manually without providing a drive mechanism for rotationally driving the movable portion 2Ca.

  The fixing portion 2Cb2 includes a connecting portion 2n for connecting the nozzle pipe 2b (see FIG. 1). The hot water I supplied from the nozzle pipe 2b to the connection part 2n is supplied to each nozzle 2m through a pipe in the fixed part 2Cb2 and a pipe in the movable part 2Ca (not shown), and is ejected as mist.

<Bathroom air conditioner>
6 and 7 are diagrams illustrating a configuration example of the bathroom air conditioner 3. FIG. 6 is a cross-sectional view showing an example of the internal configuration of the bathroom air conditioner 3.

  The bathroom air conditioner 3 shown in FIG. 6 includes a fan unit 32 and a heater unit 33 as a heat source. The fan unit 32 is attached to the main body case 34. The fan unit 32 includes a multi-blade fan 35 that is rotationally driven, a motor 36 that rotationally drives the fan 35, and a fan case 37 that is mounted with the motor 36 and forms an air passage.

  The fan 35 is arranged vertically. A lower surface of the fan case 37 along the axial direction of the fan 35 is opened and serves as a suction port 38. In addition, one side surface of the fan case 37 along the direction orthogonal to the axial direction of the fan 35 opens, and an air path switching unit 39 is provided in the opening.

  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, and communicates with the air path switching unit 39 and includes an exhaust port 42 on one side surface. In this case, depending on the position of the damper 40, an air passage communicating from the suction port 38 to the air outlet 41 or an air passage communicating from the suction port 38 to the exhaust port 42 is formed.

  A heater portion 33 is attached to a predetermined position of the above-described air outlet 41 so as to heat the discharged air. An electric heater that constitutes a heating unit is used for the heater unit 33. By exhausting warm air from the air outlet 41 into the bathroom, the temperature of the mist is prevented from being lowered and the interior of the bathroom is heated.

The fan case 37 includes an ion generator 44 at a predetermined position of the suction port 38 on the upstream side of the heater unit 33. The ion generator 44 exposes the ion emission surface to the circulation air passage 43a formed by setting the damper 40 to the circulation position or the 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 extremely strong activity, they can surround and inactivate airborne bacteria in the air. Here, .OH is one kind of active species, and represents radical OH.

  Accordingly, 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 approximately the same number of positive ions and negative ions is blown, thereby allowing floating bacteria contained in the circulating air to 1 can remove both floating bacteria in the air of the bathroom 101 shown in FIG. 1 to suppress the occurrence of mold and the like.

  FIG. 7 is a perspective view showing an exploded example of the bathroom air conditioner 3. The bathroom air conditioner 3 shown in FIG. 7 has a structure in which the front panel 26 can be removed (disassembled) from the main body case 34. In this example, a temperature detection sensor 69 is attached to a portion corresponding to the suction port 38 of the main body case 34. The temperature detection sensor 69 is for detecting the temperature of the bathroom 101.

  In FIG. 7, the lower surface of the main body case 34 is opened so that the suction port 38 and the air outlet 41 are exposed. The front panel 26 is attached to the lower surface opening of the main body case 34. The front panel 26 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 part 32, and a blow grill 46 facing the blower outlet 41 of the fan part 32. A filter 47 (not shown) is replaceably attached to the back side of the suction grill 45 of the front panel 26. The main body case 34 includes an exhaust duct connecting portion 48 that communicates with the exhaust port 42 of the fan portion 32 on one side surface. An exhaust duct 8 as shown in FIG. 1 is connected to the exhaust duct connection portion 48.

  8A to 8C are diagrams illustrating an operation example of the bathroom air conditioner 3. FIG. 8A is a cross-sectional view showing a state example in which the damper 40 is fully closed. In this example, when the damper 40 of the bathroom air conditioner 3 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.

  Further, as shown in FIG. 8A, when the damper 40 is set to the circulation position and the fan 35 is driven to rotate by the motor 36, air is sucked from the suction port 38 and blown out from the blower outlet 41 through the circulation air passage 43a. At this time, when the heater unit 33 is energized, the heater unit 33 is heated to heat the air passing through the air outlet 41, and hot air is blown out from the air outlet 41. Here, as the heater section 33, for example, a PTC (Positive Temperature Coefficient) heater can be used.

  FIG. 8B is a cross-sectional view showing a state example in which the damper 40 is fully opened. According to the bathroom air conditioner 3 shown in FIG. 8B, when the damper 40 is fully opened, the air passage to the air outlet 41 is blocked, and the ventilation air passage 43 b 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. 8C is a cross-sectional view showing an example of a state in which the damper 40 is at an intermediate position between the circulation position and the ventilation position. According to the bathroom air conditioner 3 shown in FIG. 8C, when the damper 40 is set at an intermediate position between the circulation position and the ventilation position, the circulation air passage 43a communicated from the air inlet 38 to the air outlet 41, and the air inlet 38 to the air outlet 42. Both ventilation air passages 43b communicated with each other are formed. This intermediate position is referred to as a circulation ventilation position.

  Subsequently, an operation example of the bathroom air conditioner 3 will be described. In the bathroom air conditioner 3, for example, when the motor 36 is driven to rotate, the fan 35 of the fan unit 32 rotates. When the fan 35 rotates, the air in the bathroom 101 is sucked from the suction port 38 of the fan part 32 through the suction grill 45 of the front panel 26.

  When the position of the damper 40 is at the circulation position shown in FIG. 8A, the circulation air passage 43a from the suction port 38 to the blowout port 41 is formed in the fan part 32, so that the air sucked from the suction port 38 is The air passes through the passage 43a and is blown out into the bathroom 101 from the air outlet 41 through the air outlet grill 46 of the front panel 26.

  Since the heater portion 33 is disposed at the outlet 41 of the circulation air passage 43a, the air passing through the circulation air passage 43a is heated by the heater portion 33 and blown out from the outlet grill 46 by driving the heater portion 33. . Thereby, when the motor 36 is rotationally driven with the damper 40 as the circulation position, when the heater unit 33 is driven, hot air can be blown into the bathroom 101 while circulating the air in the bathroom 101. .

  When the position of the damper 40 is in the ventilation position shown in FIG. 8B, the ventilation air passage 43b from the suction port 38 to the exhaust port 42 is formed in the fan portion 32, so that the air sucked from the suction port 38 is ventilated. The air passes through the passage 43b and the exhaust port 42, and further passes through the exhaust duct 8 shown in FIG. 1 to be exhausted from the exhaust grill 8a to the outdoors. Thereby, when the motor 36 is rotationally driven with the damper 40 as a ventilation position, steam and moisture in the bathroom 101 are exhausted.

  When the position of the damper 40 is in the circulation ventilation position shown in FIG. 8C, 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 in the fan portion 32 are provided. Thus, a part of the air sucked from the suction port 38 passes through the circulation air passage 43a and is blown out from the blower outlet 41 into the bathroom 101 through the blowout grill 46 of the front panel 26, and the other is a ventilation airway. 43 b and the exhaust port 42, and further through the exhaust duct 8 shown in FIG. 1 to be exhausted from the exhaust grill 8 a to the outdoors.

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

<Heat pump hot water supply system>
FIG. 9 is a block diagram illustrating a configuration example of the heat pump type hot water supply apparatus 4. A hot water supply device 4 shown in FIG. 9 supplies hot water I to the mist generating device 2, the bathroom 101, the washroom 102, the kitchen 103, and the like shown in FIG.

  The hot water supply device 4 includes a heat pump unit 53 and a hot water storage tank unit 54. The heat pump unit 53 generates hot water I by heat exchange between the atmosphere and the refrigerant gas and heat exchange between the refrigerant gas and water. The hot water storage tank unit 54 stores the hot water I generated by the heat pump unit 53. For example, the hot water storage tank unit 54 has a hot water storage capacity of 300 to 500 liters.

  The heat pump unit 53 includes an air heat exchanger 55 and a water heat exchanger 56. The air heat exchanger 55 performs heat exchange between the atmosphere and the refrigerant gas to increase the temperature of the refrigerant gas. The water heat exchanger 56 performs heat exchange between the refrigerant gas and water to increase the temperature of the water.

  The heat pump unit 53 is provided with a fan 55a and a refrigerant pipe 57. The fan 55a is used to supply the air heat to the air heat exchanger 55. The refrigerant pipe 57 is connected between the air heat exchanger 55 and the water heat exchanger 56 and used to circulate refrigerant gas between the air heat exchanger 55 and the water heat exchanger 56.

  The heat pump unit 53 includes a compressor 58 in addition to the fan 55a and the refrigerant pipe 57. The compressor 58 is disposed between the air heat exchanger 55 and the water heat exchanger 56 and is disposed on the downstream side of the air heat exchanger 55. The refrigerant is exchanged in the air heat exchanger 55 and flows through the refrigerant pipe 57. Used to compress the gas and raise the temperature further.

  The heat pump unit 53 is provided with an expansion valve 59 between the air heat exchanger 55 and the water heat exchanger 56 and on the downstream side of the water heat exchanger 56. The expansion valve 59 is used to expand the refrigerant gas flowing through the refrigerant pipe 57 after being heat-exchanged by the water heat exchanger 56 to lower the temperature.

  A hot water storage tank unit 54 is connected to the heat pump unit 53 and includes a tank 60 for storing hot water I generated by the heat pump unit 53. The tank 60 is supplied with water at the lower side and is supplied with hot water I at the upper side, and stores the hot water I in a stepped state in which the temperature on the upper side is higher than that on the lower side.

  The heat pump unit 53 and the hot water storage tank unit 54 are connected between the water heat exchanger 56 and the tank 60 by a hot water pipe 61a and a cold water pipe 61b. For example, 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.

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

  In addition, a water intake pipe 62 and a hot water supply pipe 63 are connected to the tank 60. The intake pipe 62 is used for taking hot water I stored in the tank 60. The intake pipe 62 includes a high temperature part intake pipe 62a and an intermediate temperature part intake pipe 62b. The high temperature part intake pipe 62a is connected to a high temperature part intake 60c provided at the upper part of the tank 60 independently of the inflow port 60a. The intermediate temperature portion intake pipe 62b is connected to an intermediate temperature portion intake port 60d provided below the high temperature portion intake port 60c.

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

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

  Furthermore, the hot water storage tank unit 54 includes a hot water mixing valve 64 that mixes the hot water I supplied from the intake pipe 62 and the water supplied from the branch water supply pipe 63a. The hot water supply mixing valve 64 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 I supplied from the intake water pipe 62 and the water supplied from the branch water supply pipe 63a. The temperature of the hot water I supplied from 65 is adjusted. Normal temperature water can also be discharged.

  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 and the faucet of the kitchen 103 (not shown), and supplies hot water I or water. In addition, a mist hot water supply pipe 65 a is connected to the hot water supply pipe 65 connected to the bathroom 101. The mist generator 2 is connected to the mist hot water supply pipe 65a branched here.

  Next, an operation example of the heat pump type hot water supply apparatus 4 will be described. In the hot water supply device 4, first, 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 gas flowing through the refrigerant pipe 57, and the temperature of the refrigerant gas rises. The refrigerant gas that has been heat-exchanged by the air heat exchanger 55 is compressed by the compressor 58, so that the temperature further increases.

  Then, the refrigerant gas 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 gas 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 I is generated. Is done. The refrigerant gas 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 I produced | generated by heat-exchange with the water heat exchanger 56 is returned to the tank 60 by the hot water piping 61a. As a result, the tank 60 stores hot water I and water in a state where the upper side has a high temperature and the lower side has a low temperature. The hot water I stored in the tank 60 is taken in by a water intake pipe 62. Here, when the temperature of the supply hot water is high, the hot water I is taken from the high temperature portion intake pipe 62a, and when the temperature of the supply hot water is low, the switch valve 62c takes the warm water I from the intermediate temperature portion intake pipe 62b.

  The hot water I taken by the water intake pipe 62 is mixed with the water supplied from the branch water supply pipe 63b by the hot water supply mixing valve 64. The temperature of the hot water I supplied from the hot water supply pipe 65 is adjusted by switching the mixing ratio of the hot water I and water with the hot water supply mixing valve 64. Of course, room temperature water can also be sent to the hot water supply pipe 65. Hot water I or water supplied from the hot water supply pipe 65 is distributed to the bathroom 101, the washroom 102, and the kitchen 103. Thereby, the hot water I or water is supplied to the mist generating device 2 through the mist hot water supply pipe 65a branched from the hot water supply pipe 65.

<Air conditioning remote control, mist remote control>
FIG. 10 is a front view illustrating a configuration example of an operation surface of the mist remote controller (mist operation unit) 7. The mist remote controller 7 shown in FIG. 10 includes a bathing mist button 7b for selecting the bathing mist mode operation and operation stop. Corresponding to the button 7b, a light emitting element 7b 'such as an LED (Light Emitting Diode) that is controlled to emit light when the mode is selected is provided above the button 7b. Further, the mist remote controller 7 is provided with an operation stop button 7d for stopping the operation in the bath mist mode. A light emitting element 7d 'indicating that the operation is stopped is provided above the operation stop button 7d.

  FIG. 11 is a front view illustrating a configuration example of an operation surface of the air-conditioning remote controller (main operation unit) 6. The air-conditioning remote controller 6 shown in FIG. 11 has a bathing mist button 6b for selecting the bathing mist mode operation and operation stop. The bathing mist button 6b is a button corresponding to the bathing mist button 7b of the mist remote controller 7 described above. Corresponding to the button 6b, a light emitting element 6b 'such as an LED that is controlled to emit light when the mode is selected is provided.

  The air-conditioning remote controller 6 includes a clothing drying button 6d for selecting operation and stoppage of the clothes drying mode, a cool air button 6e for selecting operation and stoppage of the cool air mode, and heating for selecting operation and stop of the heating mode. The button 6f and the ventilation button 6g which selects the operation | movement of a standard ventilation mode, the operation | movement of a bathroom drying mode, and those driving | operation stop are provided. Corresponding to these buttons 6d to 6g, for example, light emitting elements 6d ', 6e', 6f ', 6g1', 6g2 'such as LEDs that are controlled to emit light during operation are provided.

  The air-conditioning remote control 6 displays a time, bathroom temperature, operation mode, and the like, a display element 6i configured by an LCD (liquid crystal display element), a segment LED, and the like, and an up / down key for setting a timer time, 6j. Information operated and instructed by the main operation unit 6 is output to the power supply unit 2B as an operation signal S6.

<Control system for bathroom air conditioner and mist generator>
FIG. 12 is a block diagram illustrating a configuration example of a control system of the bathroom air conditioner 3 and the mist generator 2.

  The bathroom air conditioner 3 shown in FIG. 12 includes a control unit 5A having a CPU (Central Processing Unit). The air conditioning remote controller 6 described above is connected to the control unit 5A of the bathroom air conditioner 3 via an electric cable 6a. In this example, the operation signal S6 is output from the air-conditioning remote controller 6 to the control unit 5A via the electric cable 6a. As described above, the temperature detection sensor 69 for detecting the temperature in the bathroom 101 attached to the suction port 38 is connected to the control unit 5A. A temperature detection signal S69 is output from the temperature detection sensor 69 to the control unit 5A.

  As described above, the human body detection sensor 69A attached to the front panel 26 of the bathroom air conditioner 3 is connected to the control unit 5A. A human body detection signal S69a is output from the human body detection sensor 69A to the control unit 5A.

  The control unit 5A is supplied with a signal S69b indicating whether or not this switch is turned on from the bathroom lighting switch 69B. Control signals S36, S40c, S33, and S44 for controlling operations are supplied from the control unit 5A to the motor 36, the damper motor 40c, the heater unit 33, and the ion generator 44.

  A power supply unit 2B shown in FIG. 12 includes a power supply unit 2Ba, a solenoid valve drive unit 2Bb, and a control unit 2Bc having a CPU. The power supply unit 2Ba generates a DC voltage of 24V used for driving the solenoid valve, a DC voltage for driving the motor of the nozzle unit 2C, and the like from a household AC power source, for example, AC 100V.

  A solenoid valve drive unit 2Bb and a control unit 2Bc are connected to the power supply unit 2Ba, and a solenoid valve that constitutes the solenoid valve unit 2A using a DC voltage of 24V generated by the power supply unit 2Ba under the control of the control unit 2Bc. 2d, 2e, 2f are driven. In this case, the solenoid valves 2d, 2e, and 2f are each opened by applying a driving voltage of DC 24 [V]. With the drive voltage = 0 [V], each of the solenoid valves 2d, 2e, 2f is closed.

  As described above, the temperature detection sensor 2h attached to the electromagnetic valve unit 2A is connected to the control unit 2Bc. In this example, a temperature detection signal S2h is output from the temperature detection sensor 2h to the control unit 2Bc. The control unit 2Bc is provided with a timer (not shown), and counts the drainage time of hot water (residual water) drained by the electromagnetic valves 2d and 2f when the mist sauna operation starts and outputs elapsed time information.

  In the control unit 2Bc, the temperature detection signal S2h is input, the drainage temperature T1 is compared with the ejection set temperature TH, and when the drainage temperature T1 is equal to or higher than the ejection set temperature TH, the hot water I is discharged for the drainage set time t. After that, the electromagnetic valve 2f is closed to stop the draining operation. If the drainage temperature T1 is lower than the ejection set temperature TH, the drainage operation is continued with the solenoid valve 2f opened until the drainage temperature T1 reaches the ejection set temperature TH, and the drainage temperature T1 is set to the ejection set temperature TH. The draining operation of the electromagnetic valve 2f is stopped at the time point coincident with.

  The mist remote controller 7 described above is connected to the control unit 2Bc of the power supply unit 2B via an electric cable 7a. An operation signal S7a is output from the mist remote controller 7 to the control unit 2Bc via the electric cable 7a. The control unit 2Bc controls the operation of the electromagnetic valve driving unit 2Bb, and controls the direction of the nozzle 2m of the nozzle unit 2C using a DC voltage generated by the power supply unit 2Ba.

  Further, the control unit 5A of the bathroom air conditioner 3 and the control unit 2Bc of the power supply unit 2B are connected to each other so that the bathroom air conditioner 3 and the mist generating device 2 can be linked. For example, the communication control signal S5a is output from the control unit 5A to the control unit 2Bc, and the mist sauna operation is executed based on the content specified by the air conditioning remote controller 6. On the contrary, the communication control signal S5a may be output from the control unit 2Bc to the control unit 5A, and the air conditioning operation may be executed based on the contents designated by the mist remote controller 7.

  Subsequently, an operation example of the bathroom unit 1 will be described. In this example, the operation example of the bathroom unit 1 will be described by dividing it into six: a bath mist mode, a ventilation standard mode, a bathroom drying mode, a heating mode, a cool air mode, and a clothes drying mode.

<Operation of bathing mist mode>
FIG.13 and FIG.14 is a flowchart which shows the operation example (the 1 and 2) of this bathing mist mode. In this example, when the bath mist button 7b is pushed by the mist remote controller 7 and the bath mist is turned on, or when the bath mist button 6b is pushed and the bath mist is turned on by the air conditioning remote controller 6, the bath mist mode is set. This mode of operation is started. When the bath mist is turned off or when a stop is instructed, the mist generating device 2 immediately shifts to drainage control and performs a draining process.

  With these as operating conditions, the bathing mist is turned on in step ST1 of the flowchart shown in FIG. 13 to start the operation. For example, the power supply unit 2B performs ON control of the hot water supply valve in step ST2. At this time, the control unit 2Bc applies a predetermined driving voltage to the electromagnetic valve 2d for hot water supply of the electromagnetic valve unit 2A via the electromagnetic driving unit 2Bb to open the electromagnetic valve 2d.

  Next, the power supply unit 2B executes the drain valve ON control in step ST3. At this time, the control unit 2Bc applies a predetermined drive voltage to the electromagnetic valve 2f for drainage via the electromagnetic drive unit 2Bb to open the electromagnetic valve 2f (see FIG. 2). Hot water I supplied from the hot water supply apparatus 4 through the water supply pipe 2a is supplied to the drain pipe 2c through the electromagnetic valve 2d and the electromagnetic valve 2f (see FIGS. 1 and 2).

  In step ST4, the control unit 2Bc resets a timer (not shown). At this time, the timer is set to drainage time t = 0. The timer counts the drain time t of warm water (residual water) drained by the solenoid valves 2d and 2f and outputs elapsed time information to the control unit 2Bc.

  In step ST5, the control unit 2Bc compares the ejection set temperature TH with the drainage temperature T1 to determine the magnitude (T1 ≧ TH, TH> T1). At this time, based on the detection output of the temperature detection sensor 2h, the control unit 2Bc determines whether or not the drain temperature T1 of the hot water I is equal to or higher than the jetting set temperature TH, for example, 35 ° or higher. When the drainage temperature T1 is lower than the ejection set temperature TH (T1 <TH), the process proceeds to step ST6.

  In step ST6, the control unit 2Bc compares the first drainage set time (timer set time) t1 and the drainage time t to determine whether or not there is a lapse (t ≦ t1, t> t1). When the drainage time t is equal to or less than the drainage set time t1 (t ≦ t1), the process returns to step ST5 and continues to detect (monitor) the drainage temperature T1. As a result, when the mist sauna operation is started, if the drainage temperature T1 is the jetting set temperature TH, the mist sauna can be stopped after draining for a few seconds. If the drainage time t exceeds the drainage set time t1 (t> t1), the drainage temperature T1 does not rise to the jetting set temperature TH, so that the process proceeds to step ST16 and an error routine is executed. In this routine, a failure or the like of the hot water supply system is warned, and the cause of the failure is displayed on an LCD or LED (not shown).

  When the drainage temperature T1 becomes equal to or higher than the ejection set temperature TH within the drainage set time t1 in the above-described step ST5 (T1 ≧ TH), the process proceeds to step ST7. In step ST7, the control unit 2Bc compares the second drainage set time (timer set time) t2 with the drainage time t to determine whether or not there is a lapse (t ≦ t2, t> t2). When the drainage time t is equal to or less than the drainage set time t2 (t ≦ t2), the process proceeds to step ST8 and the timer is reset. At this time, the timer is set to drainage time t = 0. Thereafter, the process proceeds to step ST9, the control unit 2Bc waits for the third drainage set time t3, and then proceeds to step ST10.

  If the relationship between the drainage set time t2 and the drainage time t is t> t2 in step ST7 described above, the process proceeds to step ST10. In step ST10, the control unit 2Bc performs ON control of the mist valve and executes mist generation processing. At this time, the control unit 2Bc applies a predetermined driving voltage to the electromagnetic valve 2e for the mist unit via the electromagnetic driving unit 2Bb to open the electromagnetic valve 2e. When the electromagnetic valve 2e is opened, the hot water I supplied from the hot water supply device 4 through the water supply pipe 2a is supplied to the nozzle pipe 2b via the electromagnetic valve 2d and the electromagnetic valve 2e (see FIGS. 1 to 3B). . Thus, after the temperature of the hot water I supplied to the electromagnetic valve unit 2A rises to the ejection set temperature TH or higher, the mist generation process is performed, so that a person existing in the bathroom 101 can feel chills by the mist. I don't feel it.

  Thereafter, in step ST11, the control unit 2Bc performs the drain valve OFF control. At this time, in the electromagnetic valve unit 2A, the electromagnetic valve 2f is closed. Next, in step ST12, it is determined whether the bathing mist button 7b or 6b has been pressed and the bathing mist has been turned off, or whether the operation stop button 7d has been pressed and a stop has been instructed. When the bath mist is turned off or the stop is instructed, the process proceeds to step ST13.

  In step ST13, the control unit 2Bc performs drainage control to perform drainage processing. In this case, in the solenoid valve unit 2A, the solenoid valve 2d for hot water supply is closed and the solenoid valve 2f for drainage is opened (see FIG. 4A). Thereby, the hot water I remaining in the nozzle pipe 2b is drained to the drain pipe 2c through the electromagnetic valves 2e and 2f. At this time, since the electromagnetic valve 2e remains open, the air III is taken into the electromagnetic valve 2e and the pipes 2j and 2k through the connection pipe 2b '. Thereby, the residual water (warm water) II in the connecting pipe 2b ′, the electromagnetic valve 2e, the pipe 2j and 2k can be discharged to the drain pan 101c through the electromagnetic valve 2f. (See FIGS. 1 and 4A).

  Then, in step ST14, it is determined whether or not a predetermined time required for the draining process, for example, t = 3 seconds has elapsed. When the predetermined time has elapsed, the process proceeds to step ST15. In step ST15, stop processing is performed. In this case, in the electromagnetic valve unit 2A, the electromagnetic valve 2e and the electromagnetic valve 2f are closed (see FIG. 4B). At this time, the nozzle unit 2C is also controlled, and the direction of the nozzle 2m is returned to the original position. By this stop processing, a series of operations in the bathing mist mode is completed in step ST16.

<Operation of ventilation standard mode>
FIG. 15 is a flowchart illustrating an operation example of the ventilation standard mode. In this example, when the ventilation button 6g is pushed by the air-conditioning remote controller 6 and the ventilation standard is turned on, the ventilation standard mode is set, and the operation of this mode is started. For example, in step ST51 of the flowchart shown in FIG. 15, the operation starts when the ventilation standard is turned on.

  Next, in step ST52, the motor 36 of the bathroom air conditioner 3 is energized and the fan 35 is rotated. In this case, the damper 40 is fully opened, that is, the ventilation position (see FIG. 8B).

  In this case, since the ventilation air passage 43b from the suction port 38 to the exhaust port 42 is formed in the fan part 32, the air sucked from the suction port 38 passes through the ventilation air passage 43b and the exhaust port 42, and 1 is exhausted from the exhaust grill 8a to the outside through the exhaust duct 8 shown in FIG. 1 (ventilation operation). Thereby, steam and moisture in the bathroom 101 are exhausted.

  Next, in step ST53, it is determined whether the timer set time has elapsed. This timer setting time can be arbitrarily set by the user using, for example, the up / down key 6j of the air-conditioning remote controller 6. When the set time has elapsed, the operation of the fan ventilation operation of the bathroom air conditioner 3 is stopped in step ST54, and thereafter, the series of operations in the ventilation standard mode ends in step ST55.

<Operation in bathroom drying mode>
FIG. 16 is a flowchart illustrating an operation example of the bathroom drying mode. In this example, when the ventilation button 6g is pushed by the air-conditioning remote controller 6 and the bathroom drying is turned on, the bathroom drying mode is set, and the operation in this mode is started. For example, in step ST81 of the flowchart shown in FIG. 16, the operation starts when the bathroom drying is turned on.

  Next, in step ST82, the motor 36 of the bathroom air conditioner 3 is energized and the fan 35 is rotated. In this case, the damper 40 is set to an intermediate position between the circulation position and the ventilation position, that is, the circulation ventilation position (see FIG. 8C).

  In this case, since both the circulation air path 43a from the suction port 38 to the blower outlet 41 and the ventilation air path 43b from the suction port 38 to the exhaust port 42 are formed in the fan part 32, the air sucked from the suction port 38 Is partly blown into the bathroom 101 through the circulation air passage 43a from the air outlet 41 through the air outlet grill 46 of the front panel 26, and the other is passed through the ventilation air passage 43b and the exhaust port 42, as shown in FIG. Exhaust air is exhausted from the exhaust grill 8a through the exhaust duct 8 shown (circulation ventilation operation). Thereby, steam and moisture in the bathroom 101 are exhausted while circulating the air in the bathroom 101.

  In step ST82, the ion generator 44 generates the aforementioned positive ions and negative ions. Thus, since positive ions and negative ions are released into the bathroom 101 in a state where the circulation ventilation operation is performed, generation of mold on the inner wall and floor surface of the bathroom 101 can be suppressed.

  Next, in step ST83, it is determined whether the timer set time has elapsed. This timer setting time can be arbitrarily set by the user using, for example, the up / down key 6j of the air-conditioning remote controller 6. When the set time has elapsed, in step ST84, the circulation ventilation operation and the ion generation operation of the bathroom air conditioner 3 are stopped, and then, in step ST85, a series of operations in the bathroom drying mode ends.

<Operation in heating mode>
FIG. 17 is a flowchart illustrating an operation example of the heating mode. In this example, when the heating button 6f is pressed by the air conditioning remote controller 6 to turn on the heating, the heating mode is set, and the operation of this mode is started. For example, in step ST91 of the flowchart shown in FIG. 17, the operation is started by turning on the heating.

  Next, in step ST92, the heater unit 33 of the bathroom air conditioner 3 is energized, and the heater unit 33 is heated. Further, the motor 36 of the bathroom air conditioner 3 is energized and the fan 35 is rotated. In this case, the damper 40 is fully closed, that is, the circulation position (see FIG. 8A).

  In this case, since the circulation air path 43a from the suction port 38 to the blower outlet 41 is formed in the fan part 32, the air sucked from the suction port 38 passes through the circulation air path 43a and is warmed by the heater part 33. Then, the air is blown out from the air outlet 41 into the bathroom 101 through the air outlet grill 46 of the front panel 26 (circulation operation). Thereby, the inside of the bathroom 101 is warmed.

  Next, in step ST93, it is determined whether the timer set time has elapsed. This timer setting time can be arbitrarily set by the user using, for example, the up / down key 6j of the air-conditioning remote controller 6. When the set time has elapsed, the operation of the bathroom air conditioner 3 is stopped in step ST94. That is, energization to the heater unit 33 and the motor 36 of the bathroom air conditioner 3 is stopped. Thereafter, in step ST95, a series of operations in the heating mode ends.

<Operation in cool breeze mode>
FIG. 18 is a flowchart illustrating an operation example of the cool breeze mode. In this example, when the cool air button 6e is pressed by the air conditioner remote controller 6 to turn on the cool air, the cool air mode is set and the operation of this mode is started. For example, in step ST111 of the flowchart shown in FIG. 18, the operation is started by turning on the cool breeze.

  Next, in step ST112, the motor 36 of the bathroom air conditioner 3 is energized and the fan 35 is rotated. In this case, the damper 40 is set to an intermediate position between the circulation position and the ventilation position, that is, the circulation ventilation position (see FIG. 8C).

  In this case, since both the circulation air path 43a from the suction port 38 to the blower outlet 41 and the ventilation air path 43b from the suction port 38 to the exhaust port 42 are formed in the fan part 32, the air sucked from the suction port 38 Is partly blown into the bathroom 101 through the circulation air passage 43a from the air outlet 41 through the air outlet grill 46 of the front panel 26, and the other is passed through the ventilation air passage 43b and the exhaust port 42, as shown in FIG. Exhaust air is exhausted from the exhaust grill 8a through the exhaust duct 8 shown (circulation ventilation operation). Thereby, steam and moisture in the bathroom 101 are exhausted while circulating the air in the bathroom 101.

  Next, in step ST113, it is determined whether the timer set time has elapsed. This timer setting time can be arbitrarily set by the user using, for example, the up / down key 6j of the air-conditioning remote controller 6. When the set time has elapsed, in step ST114, the operation of the circulation ventilation operation of the bathroom air conditioner 3 is stopped, and then, in step ST115, the series of operations in the cool air mode ends.

<Operation in clothes drying mode>
FIG. 19 is a flowchart illustrating an operation example of the clothes drying mode. In this example, when the clothes drying button 6d is pressed by the air-conditioning remote controller 6 and the clothes drying is turned on, the clothes drying mode is set, and the operation of this mode is started. For example, in step ST131 of the flowchart shown in FIG. 19, the operation starts when the clothes drying is turned on.

  Next, in step ST132, the heater unit 33 of the bathroom air conditioner 3 is energized, and the heater unit 33 is heated. Further, the motor 36 of the bathroom air conditioner 3 is energized and the fan 35 is rotated. In this case, the damper 40 is set to an intermediate position between the circulation position and the ventilation position, that is, the circulation ventilation position (see FIG. 8C).

  In this case, in the fan part 32, both the circulation air path 43a from the suction port 38 to the blower outlet 41 and the ventilation air path 43b from the suction port 38 to the exhaust port 42 are formed. A part of the air sucked from the suction port 38 passes through the circulation air passage 43a, is heated by the heater 33, and blown out from the blower outlet 41 into the bathroom 101 through the blowout grill 46 of the front panel 26. 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. 1 (circulation ventilation operation). As a result, while the air in the bathroom 101 is circulated, the moisture in the bathroom 101 is exhausted, and the clothes are dried.

  Next, in step ST133, it is determined whether the timer set time has elapsed. This timer setting time can be arbitrarily set by the user using, for example, the up / down key 6j of the air-conditioning remote controller 6. When the set time has elapsed, in step ST134, the operation of the circulation ventilation operation of the bathroom air conditioner 3 is stopped, and then, in step ST135, the series of operations in the clothes drying mode is completed.

  As described above, according to the bathroom unit 1 to which the mist generating apparatus as the first embodiment is applied, the power supply unit 2B sets the temperature detection signal S2h output from the temperature sensor 2h in advance when the mist sauna operation starts. The drainage operation of the electromagnetic valve 2f is controlled based on the drainage set times t1, t2, t3 and the jetting set temperature TH.

  In this example, when the warm water I is discharged at the drainage set time t1 at step ST6 and the drainage temperature T1 becomes equal to or higher than the ejection set temperature TH at step ST5, the drainage time t exceeds the drainage set time t2 at step ST7. In addition, after opening the solenoid valve 2e in step ST10, the drain operation of the solenoid valve 2f is stopped in step ST11.

  If the drain temperature T1 is lower than the ejection set temperature TH in step ST5, the drain operation is continued with the solenoid valve 2f opened in step ST6 until the drain temperature T1 reaches the ejection set temperature TH, and step ST5 When the drainage temperature T1 coincides with the ejection set temperature TH, and then the drainage time t exceeds the drainage set time t2 in step ST7, the solenoid valve 2e is opened in step ST10, and then the solenoid valve 2f is set in step ST11. The drainage operation is stopped.

  Further, if the drainage temperature T1 coincides with the ejection set temperature TH in step ST5, and then the drainage time t becomes equal to or less than the drainage set time t2 in step ST7, the timer is reset in step ST8, and the third in step ST9. The drainage operation of the solenoid valve 2f is stopped in step ST11 after waiting for the drainage set time t3 and opening the solenoid valve 2e in step ST10.

  Thus, regarding the rising drainage operation at the start of the mist sauna operation, the power supply unit 2B is configured such that when the drainage temperature T1 is equal to or higher than the ejection set temperature TH, the discharge amount of the hot water I in the pipe is less than when the residual water is discharged. Execute hot water discharge operation to reduce. When the drainage temperature T1 is lower than the jetting set temperature TH, the residual water discharge operation is performed in which the discharge amount of the residual water in the pipe is made larger than that during the warm water discharge.

  Therefore, whether the water in the pipe is cold or warm, the discharge operation of water such as residual water can be efficiently controlled by both the drainage set times t1, t2 and t3 and the hot water discharge amount. As a result, both the person who first enters the mist in the day and the second person who immediately enters the mist following the first person can be bathed in hot water equal to or higher than the ejection set temperature TH. As described above, even when the use interval of the mist generating device 2 becomes long and when the mist generating device 2 is continuously used, the hot water I having the jetting set temperature can be always jetted.

  FIG.20 and FIG.21 is a flowchart which shows the operation example (the 1 and 2) at the time of the bathing mist mode in the bathroom unit 1 as a 2nd Example.

<Operation of bathing mist mode>
In this example, when the bath mist button 7b is pressed by the mist remote controller 7 and the bath mist is turned on, or when the bath mist button 6b is pressed and the bath mist is turned on by the air conditioning remote controller 6, the bath mist mode is set. This mode of operation is started. Further, a case where bathroom air conditioning processing is executed prior to drainage control will be described as an example. When the bath mist is turned off or when a stop is instructed, the mist generating device 2 immediately shifts to drainage control and performs a draining process.

  With these as operating conditions, the bathing mist is turned on in step ST21 of the flowchart shown in FIG. For example, in the power supply unit 2B, the heater unit 33 of the bathroom air conditioner 3 is energized in step ST22, and the heater unit 33 is heated. Further, the motor 36 of the bathroom air conditioner 3 is energized and the fan 35 rotates. In this case, the damper 40 is fully closed, that is, the circulation position (see FIG. 8A).

  At this time, since the circulation air passage 43a from the suction port 38 to the air outlet 41 is formed in the fan portion 32, the air sucked from the suction port 38 passes through the circulation air passage 43a and is heated by the heater portion 33. The air is blown into the bathroom 101 from the air outlet 41 through the air outlet grill 46 of the front panel 26. Further, the nozzle unit 2C is controlled and rotated so that the nozzle 2m faces the bathtub 101b side. This prevents mist from being applied to the person's head.

  Next, it transfers to step ST23 and control part 2Bc performs ON control of a hot water supply valve. At this time, the control unit 2Bc applies a predetermined driving voltage to the electromagnetic valve 2d for hot water supply of the electromagnetic valve unit 2A via the electromagnetic driving unit 2Bb to open the electromagnetic valve 2d.

  Next, the power supply unit 2B executes the drain valve ON control in step ST24. At this time, the control unit 2Bc applies a predetermined drive voltage to the electromagnetic valve 2f for drainage via the electromagnetic drive unit 2Bb to open the electromagnetic valve 2f (see FIG. 2). Hot water I supplied from the hot water supply apparatus 4 through the water supply pipe 2a is supplied to the drain pipe 2c through the electromagnetic valve 2d and the electromagnetic valve 2f (see FIGS. 1 and 2).

  In step ST25, the control unit 2Bc resets a timer (not shown). At this time, the timer is set to drainage time t = 0. The timer counts the drain time t of warm water (residual water) drained by the solenoid valves 2d and 2f and outputs elapsed time information to the control unit 2Bc.

  In step ST26, the control unit 2Bc compares the ejection set temperature TH and the drainage temperature T1 to determine the magnitude (T1 ≧ TH, TH> T1). At this time, based on the detection output of the temperature detection sensor 2h, the control unit 2Bc determines whether or not the drain temperature T1 of the hot water I is equal to or higher than the jetting set temperature TH, for example, 35 ° or higher. When the drainage temperature T1 is lower than the ejection set temperature TH (T1 <TH), the process proceeds to step ST26.

  In step ST27, the control unit 2Bc compares the first drainage set time (timer set time) t1 with the drainage time t to determine whether or not there is a lapse (t ≦ t1, t> t1). When the drainage time t is equal to or less than the drainage set time t1 (t ≦ t1), the process returns to step ST26 and the detection (monitoring) of the drainage temperature T1 is continued. If the drainage time t exceeds the drainage set time t1 (t> t1), the drainage temperature T1 does not rise to the jetting set temperature TH, so that the process proceeds to step ST38 and an error routine is executed. In this routine, a failure or the like of the hot water supply system is warned, and the cause of the failure is displayed on an LCD (not shown).

  When the drainage temperature T1 becomes equal to or higher than the ejection set temperature TH within the drainage set time t1 in the above-described step ST26 (T1 ≧ TH), the process proceeds to step ST28. In step ST28, the controller 2Bc drainage set time (timer set time) t2 is compared with the drainage time t to determine whether or not there is a lapse (t ≦ t2, t> t2). When the drainage time t is equal to or less than the drainage set time t2 (t ≦ t2), the process proceeds to step ST29 and the timer is reset. At this time, the timer is set to drainage time t = 0. Thereafter, the process proceeds to step ST30, and the control unit 2Bc waits for the third drainage set time t3, and then proceeds to step ST31.

  If the relationship between the drainage set time t2 and the drainage time t is t> t2 in step ST28 described above, the process proceeds to step ST31. In step ST31, the control unit 2Bc performs ON control of the mist valve and executes mist generation processing. At this time, the control unit 2Bc applies a predetermined driving voltage to the electromagnetic valve 2e for the mist unit via the electromagnetic driving unit 2Bb to open the electromagnetic valve 2e. When the electromagnetic valve 2e is opened, the hot water I supplied from the hot water supply device 4 through the water supply pipe 2a is supplied to the nozzle pipe 2b via the electromagnetic valve 2d and the electromagnetic valve 2e (see FIGS. 1 to 3B). . Thus, after the temperature of the hot water I supplied to the electromagnetic valve unit 2A rises to the ejection set temperature TH or higher, the mist generation process is performed, so that a person existing in the bathroom 101 can feel chills by the mist. I don't feel it.

  Thereafter, in step ST32, the control unit 2Bc executes the drain valve OFF control. At this time, in the electromagnetic valve unit 2A, the electromagnetic valve 2f is closed. Next, in step ST33, it is determined whether or not the bath mist button 7b or 6b has been pressed to turn off the bath mist, or the operation stop button 7d has been pressed to instruct a stop. If bathing mist is turned off or a stop is instructed, the process proceeds to step ST34.

  In step ST34, the operation of the bathroom air conditioner 3 is stopped. That is, energization to the heater unit 33 and the motor 36 of the bathroom air conditioner 3 is stopped. Thereafter, in step ST35, the control unit 2Bc executes drainage control to perform drainage processing. In this case, in the solenoid valve unit 2A, the solenoid valve 2d for hot water supply is closed and the solenoid valve 2f for drainage is opened (see FIG. 4A). Thereby, the hot water I remaining in the nozzle pipe 2b is drained to the drain pipe 2c through the electromagnetic valves 2e and 2f. At this time, since the electromagnetic valve 2e remains open, the air III is taken into the electromagnetic valve 2e and the pipes 2j and 2k through the connection pipe 2b '. Thereby, the residual water (warm water) II in the connecting pipe 2b ′, the electromagnetic valve 2e, the pipe 2j and 2k can be discharged to the drain pan 101c through the electromagnetic valve 2f. (See FIGS. 1 and 4A).

  Then, in step ST36, it is determined whether or not a predetermined time necessary for the water draining process, for example, t = 3 seconds has elapsed. When the predetermined time has elapsed, the process proceeds to step ST37. In step ST37, stop processing is performed. In this case, in the electromagnetic valve unit 2A, the electromagnetic valve 2e and the electromagnetic valve 2f are closed (see FIG. 4B). At this time, the nozzle unit 2C is also controlled, and the direction of the nozzle 2m is returned to the original position. By this stop processing, a series of operations in the bathing mist mode is completed in step ST39.

  Thus, according to the operation example in the bath mist mode in the bathroom unit 1 as the second embodiment, at the start of the mist sauna operation, the bathroom air-conditioning process is performed in step ST22, the temperature in the bathroom 101 is increased, and the bathroom In a state in which the inside of 101 is circulated and ventilated, the power supply unit 2B performs an electromagnetic operation based on the temperature detection signal S2h output from the temperature sensor 2h, the preset drainage set times t1, t2, t3, and the jetting set temperature TH. The draining operation of the valve 2f is controlled.

  In this example, when the warm water I is discharged for the drainage set time t1 in step ST27 and the drainage temperature T1 becomes equal to or higher than the ejection set temperature TH in step ST26, the drainage time t exceeds the drainage set time t2 in step ST28. In addition, after opening the solenoid valve 2e in step ST31, the drain operation of the solenoid valve 2f is stopped in step ST32.

  If the drainage temperature T1 is lower than the jetting set temperature TH in step ST26, the drainage operation is continued with the electromagnetic valve 2f opened in step ST27 until the drainage temperature T1 reaches the jetting set temperature TH, and step ST26. When the drainage temperature T1 coincides with the ejection set temperature TH, and then the drainage time t exceeds the drainage set time t2 in step ST28, the solenoid valve 2e is opened in step ST131, and then the solenoid valve 2f is switched in step ST32. The drainage operation is stopped.

  Further, if the drainage temperature T1 coincides with the ejection set temperature TH in step ST26, and then the drainage time t becomes equal to or less than the drainage set time t2 in step ST28, the timer is reset in step ST29, and the third in step ST30. The drainage operation of the solenoid valve 2f is stopped in step ST32 after waiting for the set drainage time t3 and opening the solenoid valve 2e in step ST31.

  As described above, regarding the rising drainage operation at the start of the mist sauna operation, the power supply unit 2B discharges the hot water I in the pipe when the drainage temperature T1 is equal to or higher than the ejection set temperature TH while performing the bathroom air conditioning process. Execute the warm water discharge operation to reduce the amount of waste water than when the residual water is discharged. When the drainage temperature T1 is lower than the jetting set temperature TH, the residual water discharge operation is performed in which the discharge amount of the residual water in the pipe is made larger than that during the warm water discharge.

  Therefore, whether the water in the pipe is cold or warm, the discharge operation of the remaining water or hot water I is efficiently controlled in both the drainage set times t1, t2, t3 and the hot water discharge amount, as compared with the first embodiment. become able to. As a result, both the person who first enters the mist in the day and the second person who immediately enters the mist following the first person can be bathed in hot water equal to or higher than the ejection set temperature TH.

  FIG. 22 is a front view showing a configuration example of the electric / electromagnetic valve unit 201 as the third embodiment. The electric / solenoid valve unit 201 shown in FIG. 22 has a housing 2A ′. In this example, when one side surface of the housing 2A ′ is opened, the arrangement of the electromagnetic valve and the electric valve in the electromagnetic valve unit can be seen.

  Connected to the housing 2A 'is a connection 2a' for connecting the hot water supply pipe 2a described in the first embodiment, a connection 2b 'for connecting the nozzle pipe 2b, and a drain pipe 2c. And a connecting portion 2c 'for mounting.

  In this example, an electromagnetic valve 2d for hot water supply, which is an example of a hot water supply valve, is attached to the connecting portion 2a 'inside the housing 2A' so as to control supply (ON-OFF) of hot water from the hot water supply device 4. To be made. A solenoid valve 2e for a mist unit, which is an example of an ejection valve, is attached to one pipe 2j branched from the solenoid valve 2d, and supply of hot water to the nozzle unit 2C is controlled (ON-OFF). . The downstream side (the other end) of the electromagnetic valve 2e is attached to the connection portion 2b ′.

  At a position lower than the electromagnetic valve 2e, a variable flow type electric valve 2g is disposed and attached to the other pipe 2k branched from the electromagnetic valve 2d to adjust the discharge flow rate of hot water or residual water. It is made to drain. The downstream side (the other end) of the motor-operated valve 2g is attached to the connecting portion 2c ′. That is, one end of the electromagnetic valve 2d is connected to the connection portion 2a ', and one end of the electromagnetic valve 2e is connected to the other end of the electromagnetic valve 2d via the pipe 2j. The other end of the electromagnetic valve 2e is connected to the connection portion 2b ′. Further, the pipe 2k branched from the pipe 2j is connected to one end of the motor-operated valve 2g, and the connecting portion 2c 'is connected to the other end of the motor-operated valve 2g.

  In addition to the solenoid valves 2d, 2e, and 2f, a temperature detection sensor 2h is disposed inside the electric / solenoid valve unit 201 described above. The temperature detection sensor 2h is attached to the pipe 2j, for example, and detects the temperature of water (hot water) flowing through the pipe 2j after passing through the electromagnetic valve 2d and outputs a temperature detection signal S2h. In this example, when the mist sauna operation is started, the drainage temperature T1 accompanying the discharge amount adjusting operation of the motor operated valve 2g is detected, and the temperature detection signal S2h (temperature detection information) is output from the temperature sensor 2h to the power supply unit 301 (not shown). The

  23A and 23B are a top view and a partially fragmented front view showing a configuration example of the electromagnetic valve 2d and the like. The electromagnetic valve 2d shown in FIG. 23A has a main body 211 having a predetermined shape. A water supply port 212 is provided on one side of the main body 211 and is engaged with the connecting portion 2a 'described above. A drain outlet 213 is provided on the other side of the main body 211 and is connected to the pipe 2j described above.

  In FIG. 23B, a partition chamber 215 having a predetermined opening 214 is provided in the main body 211. The water control valve 216 is arranged so as to be able to be driven up and down so as to cover the opening 214 of the partition chamber 215. The water control valve 216 has upper and lower mandrels 217 and has a top shape. The water control valve 216 is made of a rubber material. The lower mandrel 217 b of the water control valve 216 is engaged with the guide hole 218, and the upper mandrel 217 a is disposed so as to be inserted into the coil magnetic axis of the solenoid 219. The solenoid 219 is provided above the partition chamber 215 while maintaining water tightness.

  A pressing spring 221 is arranged between a predetermined portion on the solenoid side and the water control valve 216. When the solenoid 219 does not operate, the water control valve 216 is always in the opening direction so as to cover the opening 214. Energized to press. A terminal 220 is provided on the main body 211. The terminal 220 is connected to the solenoid 219, and a drive voltage for driving the solenoid valve 2f is applied.

  When the electromagnetic valve 2d is configured in this way and a drive voltage is applied to the terminal 220, the solenoid 219 generates a suction force that overcomes the biasing force of the pressing spring 221, and the upper mandrel 217a of the water control valve 216 is pulled upward. The water control valve 216 moves upward to open the water channel so that the lid of the opening 214 is removed. When the drive voltage is 0 [V], the pressing spring 221 always presses the water control valve 216 in the opening direction, so that the flow channel is closed.

  24A and 24B are a top view showing a configuration example of the motor-operated valve 2g and the like, and a front view of partial crushing. A motor-operated valve 2g shown in FIG. 24A has a main body 411 having a predetermined shape. One of the main body portions 411 is provided with a water supply port 412 and is engaged with the connection portion 2a 'described above. A drain port 413 is provided on the other side of the main body 411 and is connected to the pipe 2j described above.

  In FIG. 24B, a partition chamber 415 having an opening (not shown) is provided in the main body 411. The needle valve 416 is arranged so as to be driven up and down so as to penetrate the opening of the partition chamber 415. One end of the needle valve 416 is engaged with a valve shaft 417a that can move up and down. The other end of the needle valve 416 has a conical shape. The needle valve 416 is made of a metal material. The lower part of the needle-like valve 416 is engaged with an inverted conical opening (not shown). The valve shaft 417a is engaged with the rotor 414 of the stepping motor 419. A male screw is provided on the outer side of the valve shaft 417a, and is engaged with a female screw provided on the inner side of the rotor 414. The stepping motor 419 has an electromagnetic coil for a stator (not shown) and is provided above the partition chamber 415 while maintaining water tightness.

  The terminal 420 is connected to the stepping motor 419 and applied with a driving voltage for rotationally driving the electric valve 2g. When the motor-operated valve 2g is configured in this way and a driving voltage is applied to the terminal 420, the stepping motor 419 rotates the rotor 414, so that the internal thread of the external thread rotor 414 outside the valve shaft 417a is screwed. As a result, the conical needle valve 416 engaged with the valve shaft 417a comes out upward from the reverse conical opening. When a reverse driving voltage is applied, the needle valve 416 moves while the conical needle valve 416 rotates to the reverse conical opening. The amount of movement is proportional to the amount of running water. As a result, the hot water flow rate is adjusted. 25A to 25C are diagrams showing an example of the operation of the electric / electromagnetic valve unit 201 when the mist sauna operation is stopped. In the electric / electromagnetic valve unit 201 shown in FIG. 25A, the electromagnetic valves 2d and 2e in the electromagnetic valve unit are in an open state immediately before the mist sauna operation is stopped. The motor-operated valve 2g is fully closed. That is, this state is a state during the operation of the mist sauna.

  According to the electric / solenoid valve unit 201 shown in FIG. 25B, in the drainage control after stopping the mist sauna operation, the solenoid valve 2d for hot water supply in the solenoid valve unit is opened under the control of the power supply unit 301. Thus, the electromagnetic valve 2e for the mist unit is controlled to be closed, and the electric valve 2g drains the water by adjusting the amount of warm water discharged. In this control, the hot water I from the hot water supply pipe 2a (see FIG. 1) is supplied from the connecting portion 2a ′ to the electric valve 2g for adjusting the amount of drainage through the solenoid valve 2d and the pipe 2k, and the drainage temperature T1 is frozen. The hot water in the piping is discharged so that the temperature becomes equal to or higher than the prevention set temperature TH ′. At this time, the temperature of water (warm water) flowing through the pipe 2j after passing through the electromagnetic valve 2d is detected, and a temperature detection signal S2h is output from the temperature detection sensor 2h to the power supply unit 301.

  The power supply unit 301 receives the temperature detection signal S2h, compares the drainage temperature T1 with the freeze prevention set temperature TH ′, and if the drainage temperature T1 is equal to or lower than the freeze prevention set temperature TH ′, the preset drainage. After discharging hot water I for a set time, the motor-operated valve 2g is closed to stop the draining operation. When the drainage temperature T1 exceeds the freeze prevention set temperature TH ', the monitoring is continued until the drainage temperature T1 becomes equal to or lower than the freeze prevention set temperature TH'. According to the electric / electromagnetic valve unit 201 shown in FIG. 25C, when the drainage temperature T1 exceeds the freeze prevention set temperature TH ′, all the electromagnetic valves 2d and 2e and the electric valves 2g are closed when the mist sauna operation is stopped. State. It is made to wait for the next mist sauna operation. Thus, if the electromagnetic valve 2d described in the first embodiment is left as it is and the electromagnetic valve 2f (drainage opening / closing valve) is changed to the electric valve 2g capable of adjusting the flow rate, drainage control according to the purpose of drainage can be performed efficiently. It becomes like this.

  FIG. 26 is a block diagram illustrating a configuration example of a control system of the bathroom air conditioner 3 and the mist generator 2 according to the third embodiment.

  According to the configuration example of the control system shown in FIG. 26, the power source unit 301 is connected to the motor / solenoid valve unit 201. The power supply unit 301 includes a power supply unit 2Ba, a solenoid valve drive unit 2Bb, and a control unit 2Bc having a CPU. The power supply unit 2Ba generates a DC voltage of 24V used for driving the solenoid valve, a DC voltage for driving the motor of the nozzle unit 2, and the like from a household AC power source, for example, AC 100V.

  An electromagnetic valve drive unit 2Bb and a control unit 2Bc are connected to the power supply unit 2Ba, and an electric / electromagnetic valve unit 201 is configured using a DC voltage of 24V generated by the power supply unit 2Ba under the control of the control unit 2Bc. The electromagnetic valves 2d and 2e and the motor operated valve 2g are driven. In this case, the solenoid valves 2d and 2e are each opened by applying a driving voltage of DC 24 [V]. When the drive voltage = 0 [V], each of the solenoid valves 2d and 2e is closed. The motor-operated valve 2g is directly controlled by the control unit 2Bc. For example, the pulse signal S2g is supplied to the stepping motor 419 shown in FIG. 24B to control the movement amount of the needle valve 416. Thereby, the amount of drainage can be adjusted.

  A temperature detection sensor 2h attached to the pipe 2j of the electric / electromagnetic valve unit 201 is connected to the control unit 2Bc. In this example, a temperature detection signal S2h is output from the temperature detection sensor 2h to the control unit 2Bc. In the control unit 2Bc, the temperature detection signal S2h is input, for example, the drainage temperature T1 is compared with the freeze prevention set temperature TH ′, and if the drainage temperature T1 is equal to or lower than the freeze prevention set temperature TH ′, the drainage control is executed. To do. In addition, about control of the bathroom air conditioner 3, since it is the same as that of a 1st Example, the description is abbreviate | omitted.

FIG. 27 is a flowchart illustrating a control example in the mist sauna operation stop in the power supply unit 301.
For example, while the mist sauna operation is stopped, the control unit 2Bc compares the drain temperature T1 with the freeze prevention set temperature TH ′ in step ST41 of the flowchart shown in FIG. At this time, when the mist sauna operation is stopped, the temperature detection sensor 2h detects the temperature of the pipe 2j connected to the solenoid valve 2d or the temperature of hot water staying in the pipe 2j and outputs a temperature detection signal S7h. . The control unit 2Bc acquires the drainage temperature T1 from the temperature detection signal S7h, compares the preset freezing prevention set temperature TH ′ with the drainage temperature T1, and determines the presence or absence of drainage adjustment control. When the drainage temperature T1 exceeds the freeze prevention set temperature TH ′, the monitoring is continued until the drainage temperature T1 becomes equal to or lower than the freeze prevention set temperature TH ′.

  When the drainage temperature T1 is equal to or lower than the freeze prevention set temperature TH ', the process proceeds to step ST42, and the power supply unit 301 controls the hot water supply valve to be ON. The electric / solenoid valve unit 201 shown in FIG. 25B receives a predetermined drive voltage from the power supply unit 301, and in a state where the solenoid valve 2d for hot water supply in the solenoid valve unit is opened based on this drive voltage, The electromagnetic valve 2e for the mist unit is closed.

  Next, in step ST43, the control unit 2Bc controls the motor operated valve 2g so as to make the drain valve opening “small”. In the motor operated valve 2g shown in FIG. 24B, the stepping motor 419 rotates forward based on the pulse signal S2g output from the control unit 2Bc, and the needle valve 416 adjusts the amount of warm water to drain. Accordingly, the hot water I from the hot water supply pipe 2a (see FIG. 1) is supplied from the connecting portion 2a ′ to the electric valve 2g for adjusting the amount of drainage through the solenoid valve 2d and the pipe 2k, and the drainage temperature T1 is prevented from freezing. The hot water in the pipe is discharged so as to be equal to or higher than the set temperature TH ′.

  In step ST44, the control unit 2Bc compares the drain temperature T1 with the freeze prevention set temperature TH '. At this time, the temperature detection sensor 2h detects the temperature of the hot water flowing through the pipe 2j connected to the electromagnetic valve 2d and outputs the temperature detection signal S2h during the freeze prevention operation. The control unit 2Bc acquires the drainage temperature T1 from the temperature detection signal S2h, compares the previous freeze prevention set temperature TH ′ with the current drainage temperature T2, and determines whether or not the drainage temperature T2 exceeds the freeze prevention set temperature TH ′. Is determined. If the drainage temperature T2 is equal to or lower than the freeze prevention set temperature TH ', the monitoring is continued. Accordingly, if the anti-freezing set temperature TH 'has not been reached, the drainage is continued until the anti-freezing set temperature TH' is reached, and the drainage can be stopped when the anti-freezing set temperature TH 'is reached.

  When the drainage temperature T2 exceeds the freeze prevention set temperature TH ', the process proceeds to step ST45 and the hot water supply valve is controlled to be OFF. In the electric / electromagnetic valve unit 201 shown in FIG. 25B, when the drive voltage is set to 0 [V] from the power supply unit 301, the electromagnetic valve 2d is closed. The electromagnetic valve 2e for the mist unit remains closed.

  Then, it transfers to step ST46 and control part 2Bc controls the motor operated valve 2g so that a drain valve may be made into a fully closed state. In the motor-operated valve 2g shown in FIG. 24B, the stepping motor 419 rotates reversely based on the pulse signal S2p output from the control unit 2Bc, and the needle valve 416 is inserted into the reverse cone-shaped opening (not shown). 0, that is, a fully closed state. Thereafter, returning to step ST41, the control unit 2Bc compares the drainage temperature T1 with the freeze prevention set temperature TH ', and repeats the above-described processing.

  Thus, according to the control example during the mist sauna operation stop in the power supply unit 301 as the third embodiment, the electromagnetic valve 2d (hot water supply valve) is maintained without changing the electromagnetic valve 2f described in the first embodiment. Is changed to the electric valve 2p capable of adjusting the flow rate, it becomes possible to efficiently perform drainage control according to the purpose of drainage. Moreover, the drainage temperature T1 associated with the discharge amount adjustment operation of the motor operated valve 2g is detected, and the temperature detection signal S2h (temperature detection information) is output from the temperature sensor 2h to the power supply unit 301. In the power supply unit 301, the discharge amount of the motor-operated valve 2g can be adjusted based on the temperature detection signal S2h, so that the pipe freezing can be prevented with a small volume of hot water.

FIG. 28 is a conceptual diagram showing a configuration example of the electric / solenoid valve unit 202 as the fourth embodiment.
The electric / solenoid valve unit 202 shown in FIG. 28 has a housing 2A ′. In this example, when one side surface of the housing 2A ′ is opened, the arrangement of the electromagnetic valve and the electric valve in the electromagnetic valve unit can be seen.

  Connected to the housing 2A 'is a connection 2a' for connecting the hot water supply pipe 2a described in the first embodiment, a connection 2b 'for connecting the nozzle pipe 2b, and a drain pipe 2c. And a connecting portion 2c 'for mounting.

  In this example, an electric valve 2p for adjusting the flow rate, which is an example of a hot water supply valve, is attached to the connection portion 2a 'inside the housing 2A', and the flow rate adjustment control (flow rate variable) of hot water from the hot water supply device 4 is performed. It is made like. An electromagnetic valve 2e for a mist unit, which is an example of an ejection valve, is attached to one pipe 2j branched from the motor-operated valve 2p so as to control supply (ON-OFF) of hot water to the nozzle unit 2C. . The downstream side (the other end) of the electromagnetic valve 2e is attached to the connection portion 2b ′.

  A solenoid valve 2f for drainage is disposed at a position lower than the solenoid valve 2e, and is attached to the other pipe 2k branched from the motor operated valve 2p to control drainage of hot water and residual water (ON-OFF). To be made. The downstream side (the other end) of the electromagnetic valve 2f is attached to the connecting portion 2c ′. That is, one end of the motor-operated valve 2p is connected to the connecting portion 2a ', and one end of the electromagnetic valve 2e is connected to the other end of the motor-operated valve 2p via the pipe 2j. The other end of the electromagnetic valve 2e is connected to the connection portion 2b ′. Furthermore, the pipe 2k branched from the pipe 2j is connected to one end of the electromagnetic valve 2f, and the connecting portion 2c 'is connected to the other end of the electromagnetic valve 2f.

  In addition to the electric valve 2p and the electromagnetic valves 2e and 2f, a temperature detection sensor 2h is disposed inside the electric / electromagnetic valve unit 202 described above. The temperature detection sensor 2h is attached to the pipe 2j, for example, and detects the temperature of water (hot water) flowing through the pipe 2j after passing through the motor-operated valve 2p and outputs a temperature detection signal S7h. In this example, when the mist sauna operation is stopped, the drainage temperature T1 accompanying the discharge amount adjustment operation of the solenoid valve 2f is detected, and the temperature detection signal S2h (temperature detection information) is output from the temperature sensor 2h to the power supply unit 302 (not shown). The

  FIGS. 29A to 29C are diagrams illustrating an operation example of the electric / electromagnetic valve unit 202 when the mist sauna operation is stopped. In the electric / electromagnetic valve unit 202 shown in FIG. 29A, the electric valve 2p and the electromagnetic valve 2e in the electromagnetic valve unit are in a state immediately before the mist sauna operation is stopped. The electromagnetic valve 2f is fully closed. That is, this state is a state during the operation of the mist sauna.

  According to the electric / electromagnetic valve unit 202 shown in FIG. 29B, in the drainage control after the mist sauna operation is stopped, the opening degree of the electric valve 2p for hot water supply in the electromagnetic valve unit is controlled under the control of the power supply unit 302. The amount of warm water discharged is adjusted, the mist unit electromagnetic valve 2e is controlled to be closed, and the electromagnetic valve 2f is opened to drain water. In this control, the hot water I from the hot water supply pipe 2a (see FIG. 1) is supplied from the connecting portion 2a ′ to the electromagnetic valve 2f through the electric valve 2p for adjusting hot water supply and the pipe 2k, and the drainage temperature T1 is frozen. The hot water in the piping is discharged so that the temperature becomes equal to or higher than the prevention set temperature TH ′. At this time, the temperature of the water (warm water) flowing through the pipe 2j after passing through the electric valve 2p is detected, and the temperature detection signal S2h is output from the temperature detection sensor 2h to the power supply unit 302.

  In the power supply unit 302, the temperature detection signal S2h is input, the drainage temperature T1 is compared with the freeze prevention set temperature TH ′, and if the drainage temperature T1 is equal to or lower than the freeze prevention set temperature TH ′, the preset drainage is set. After discharging the hot water I for a set time, the electromagnetic valve 2f is closed to stop the draining operation. When the drainage temperature T1 exceeds the freeze prevention set temperature TH ', the monitoring is continued until the drainage temperature T1 becomes equal to or lower than the freeze prevention set temperature TH'. According to the electric / solenoid valve unit 202 shown in FIG. 29C, when the drainage temperature T1 exceeds the freeze prevention set temperature TH ′, the electric valve 2p, the electromagnetic valves 2e and 2f are closed when the mist sauna operation is stopped. Made. It is made to wait for the next mist sauna operation. Thus, if the solenoid valve 2d (hot water supply valve) is changed to the electric valve 2p capable of adjusting the flow rate without changing the solenoid valve 2f described in the first embodiment, drainage control according to the drainage purpose can be efficiently performed. become.

  FIG. 30 is a block diagram illustrating a configuration example of a control system of the bathroom air conditioner 3 and the mist generator 2 according to the fourth embodiment.

  According to the configuration example of the control system shown in FIG. 30, the power source unit 302 is connected to the motor / solenoid valve unit 202. The power supply unit 302 includes a power supply unit 2Ba, a solenoid valve drive unit 2Bb, and a control unit 2Bc having a CPU. The power supply unit 2Ba generates a DC voltage of 24V used for driving the solenoid valve, a DC voltage for driving the motor of the nozzle unit 2, and the like from a household AC power source, for example, AC 100V.

An electromagnetic valve driving unit 2Bb and a control unit 2Bc are connected to the power supply unit 2Ba, and an electric / electromagnetic valve unit 202 is configured using a DC voltage of 24V generated by the power supply unit 2Ba under the control of the control unit 2Bc. The motorized valve 2p and the electromagnetic valves 2e and 2f are driven. In this case, the solenoid valves 2e and 2f are each opened by applying a driving voltage of DC 24 [V]. When the drive voltage = 0 [V], each of the solenoid valves 2e and 2f is closed.
The motor-operated valve 2p is directly controlled by the control unit 2Bc. For example, the pulse signal S2p is supplied to the stepping motor 419 shown in FIG. 24B to control the movement amount of the needle valve 416. Thereby, the hot water supply amount of warm water can be adjusted now.

  A temperature detection sensor 2h attached to the pipe 2j of the electric / solenoid valve unit 202 is connected to the controller 2Bc. In this example, a temperature detection signal S2h is output from the temperature detection sensor 2h to the control unit 2Bc. In the control unit 2Bc, the temperature detection signal S2h is input, for example, the drainage temperature T1 is compared with the freeze prevention set temperature TH ′, and if the drainage temperature T1 is equal to or lower than the freeze prevention set temperature TH ′, the drainage control is executed. To do. In addition, about control of the bathroom air conditioner 3, since it is the same as that of a 1st Example, the description is abbreviate | omitted.

FIG. 31 is a flowchart showing an example of control during the mist sauna operation stop in the power supply unit 302.
In step ST61 of the flowchart shown in FIG. 31, the control unit 2Bc compares the drainage temperature T1 with the freeze prevention set temperature TH ′. At this time, when the mist sauna operation is stopped, the temperature detection sensor 2h detects the temperature of the pipe 2j connected to the motor-operated valve 2p or the temperature of the hot water staying in the pipe 2j and outputs a temperature detection signal S2h. . The control unit 2Bc acquires the drainage temperature T1 from the temperature detection signal S7h, compares the preset freezing prevention set temperature TH ′ with the drainage temperature T1, and determines the presence or absence of drainage adjustment control. When the drainage temperature T1 exceeds the freeze prevention set temperature TH ′, the monitoring is continued until the drainage temperature T1 becomes equal to or lower than the freeze prevention set temperature TH ′.

  When the drainage temperature T1 is equal to or lower than the freeze prevention set temperature TH ', the process proceeds to step ST62, and the power supply unit 302 controls the flow rate of the hot water supply valve. At this time, the electric / solenoid valve unit 202 shown in FIG. 29B controls the electric valve 2p so that the hot water supply valve opening degree is “small”. In the motor-operated valve 2p shown in FIG. 24B, the stepping motor 419 rotates forward based on the pulse signal S2p output from the control unit 2Bc, and the needle valve 416 adjusts the hot water supply amount to adjust the hot water supply amount. To be made.

  Next, in step ST63, the control unit 2Bc controls the drain valve to be ON. For example, when a predetermined drive voltage is input from the power supply unit 302 and the electromagnetic valve 2f for drainage in the electromagnetic valve unit is open based on the drive voltage, the electromagnetic valve 2e for the mist unit is closed To be made. Thus, the hot water I whose flow rate has been adjusted from the hot water supply pipe 2a (see FIG. 1) is supplied from the connecting portion 2a ′ to the electromagnetic valve 2f for drainage through the electric valve 2p and the pipe 2k, and the drainage temperature T1 is The hot water in the pipe is discharged so as to be equal to or higher than the freeze prevention set temperature TH ′.

  In step ST64, the control unit 2Bc compares the drain temperature T1 with the freeze prevention set temperature TH '. At this time, the temperature detection sensor 2h detects the temperature of the hot water flowing through the pipe 2j connected to the motor operated valve 2p and outputs a temperature detection signal S7h during the freeze prevention operation. The control unit 2Bc acquires the drainage temperature T1 from the temperature detection signal S7h, compares the previous freeze prevention set temperature TH ′ with the current drainage temperature T2, and determines whether or not the drainage temperature T2 exceeds the freeze prevention set temperature TH ′. Is determined. If the drainage temperature T2 is equal to or lower than the freeze prevention set temperature TH ', the monitoring is continued. Accordingly, if the anti-freezing set temperature TH 'has not been reached, the drainage is continued until the anti-freezing set temperature TH' is reached, and the drainage can be stopped when the anti-freezing set temperature TH 'is reached.

  When the drainage temperature T2 exceeds the freeze prevention set temperature TH ', the process proceeds to step ST65 and the hot water supply valve is fully closed. In the motor-operated valve 2p shown in FIG. 24B, the stepping motor 419 reversely rotates based on the pulse signal S2p output from the control unit 2Bc, and the needle-like valve 416 is inserted into an inverted conical opening (not shown). 0, that is, a fully closed state.

  Then, it transfers to step ST66 and control part 2Bc carries out OFF control of the drain valve. For example, in the electric / electromagnetic valve unit 202 shown in FIG. 29B, the drive voltage from the power supply unit 302 to the electromagnetic valve 2f is set to 0 [V], so that the electromagnetic valve 2f is closed. The electromagnetic valve 2e for the mist unit remains closed. Then, returning to step ST61, the control unit 2Bc compares the drainage temperature T1 with the freeze prevention set temperature TH ', and repeats the above-described processing.

  Thus, according to the control example during the mist sauna operation stop in the power supply unit 302 as the fourth embodiment, the electromagnetic valve 2d (hot water supply valve) is maintained without changing the electromagnetic valve 2f described in the first embodiment. Is changed to the electric valve 2p capable of adjusting the flow rate, it becomes possible to efficiently perform drainage control according to the purpose of drainage. Moreover, the drainage temperature T1 associated with the hot water supply amount adjustment operation of the electric valve 2p is detected, and the temperature detection signal S2h (temperature detection information) is output from the temperature sensor 2h to the power supply unit 302. Since the power supply unit 302 can adjust the amount of hot water supplied to the motor-operated valve 2p based on the temperature detection signal S2h, the pipe freezing can be prevented with a small volume of hot water as in the third embodiment. It should be noted that by making the hot water supply valve adjustable, it is possible to vary the amount of hot water ejected during mist sauna operation.

  32A and 32B are conceptual diagrams showing a configuration example of the electric / electromagnetic valve units 203 and 204 according to the fifth embodiment.

  The electric / solenoid valve unit 203 shown in FIG. 32A is suitable for a floor-standing type mist generator (not shown), and has a housing 2A ′. Also in this example, when one side surface of the housing 2A ′ is opened, the arrangement of the electromagnetic valves 2d and 2e and the electric valve 2g in the electric / electromagnetic valve unit can be seen.

  In the housing 2A ′, the connecting portion 2a ′ for connecting the water supply pipe 2a described above, the connecting portion 2b ′ for connecting the nozzle pipe 2b in the same manner, and the connecting portion 2c for connecting the drain pipe 2c. ′ Is attached and fixed.

  In this example, an electromagnetic valve 2d for water supply or hot water supply is attached to the connection portion 2a 'inside the housing 2A' so that water or hot water from the hot water supply device 4 is supplied. A pipe 2i connected to the electromagnetic valve 2d is branched in a T shape. One of the pipes 2j ′ is provided with a solenoid valve 2e for a mist nozzle so as to supply water or hot water to the nozzle unit 2C. The downstream side (the other end) of the electromagnetic valve 2e is attached to the connection portion 2b ′. An electric valve 2g for adjusting the drainage flow rate is disposed at a position lower than the electromagnetic valve 2e, and is attached to the other pipe 2k 'branched from the pipe 2i so as to adjust the flow rate during drainage. The downstream side (the other end) of the motor-operated valve 2g is attached to the connecting portion 2c ′.

  The electric / solenoid valve unit 204 shown in FIG. 32B is also suitable for a floor-standing mist generator (not shown), and has a housing 2A ′. Also in this example, when one side surface of the housing 2A ′ is opened, the arrangement of the motor-operated valve 2p and the solenoid valves 2e and 2f in the motor / solenoid valve unit can be seen.

  In this example, an electromagnetic valve 2p for water supply or hot water supply flow rate adjustment is attached to the connection portion 2a 'inside the housing 2A' so as to adjust the supply amount of water or hot water from the hot water supply device 4. . A pipe 2i connected to the electromagnetic valve 2p is branched into a T shape. One of the pipes 2j ′ is provided with a solenoid valve 2e for a mist nozzle so as to supply water or hot water to the nozzle unit 2C. The downstream side (the other end) of the electromagnetic valve 2e is attached to the connection portion 2b ′. At a position lower than the electromagnetic valve 2e, an electric valve 2f for drainage is disposed and attached to the other pipe 2k 'branched from the pipe 2i so as to drain water. The downstream side (the other end) of the electromagnetic valve 2f is attached to the connecting portion 2c ′.

  Thus, even when the electric / electromagnetic valve units 203 and 204 having the piping structure as the fifth embodiment are applied to the third and fourth embodiments, the power supply unit 302 uses the temperature detection signal S2h. Since the flow rate can be adjusted by the motor-operated valve 2g, the motor-operated valve 2p, etc., it is possible to prevent the pipe from being frozen with a small volume of hot water, as in the third and fourth embodiments. Of course, by making the hot water supply valve adjustable, it is possible to vary the amount of hot water ejected during mist sauna operation.

  The present invention is extremely suitable when applied to a bathroom unit that ejects hot water or water supplied from a hot water supply apparatus.

It is a conceptual diagram of a section showing an example of composition of bathroom system 1 as the 1st example concerning the present invention. It is a front view which shows the structural example of 2 A of solenoid valve units. AC is a diagram which shows the operation example at the time of the mist sauna operation | movement start of 2 A of solenoid valve units. A and B are diagrams showing an operation example of the electromagnetic valve unit 2A when the mist sauna operation is stopped. AC is a figure which shows the structural example of 2 C of nozzle units. It is sectional drawing which shows the internal structural example of the bathroom air conditioner 3. FIG. It is a perspective view which shows the example of decomposition | disassembly of the bathroom air conditioner 3. FIG. AC is a figure which shows the operation example of the bathroom air conditioner 3. FIG. It is a block diagram which shows the structural example of the heat pump type hot water supply apparatus. It is a front view which shows the structural example of the operation surface of the mist remote control (mist operation part) 7. FIG. It is a front view which shows the structural example of the operation surface of the air-conditioning remote control (main operation part) 6. FIG. It is a block diagram which shows the structural example of the control system of the bathroom air conditioner 3 and the mist generator 2 which concern on a 1st Example. It is a flowchart which shows the operation example (the 1) of bathing mist mode. It is a flowchart which shows the operation example (the 2) of bathing mist mode. It is a flowchart which shows the operation example of ventilation standard mode. It is a flowchart which shows the operation example of bathroom drying mode. It is a flowchart which shows the operation example of heating mode. It is a flowchart which shows the operation example of a cool breeze mode. It is a flowchart which shows the operation example of clothing drying mode. It is a flowchart which shows the operation example (the 1) at the time of the bathing mist mode in the bathroom unit 1 as a 2nd Example. It is a flowchart which shows the operation example (the 2) at the time of the bathing mist mode in the bathroom unit 1. It is a front view which shows the structural example of the motor / electromagnetic valve unit 201 as a 3rd Example. A and B are a top view showing a configuration example of the electromagnetic valve 2d and the like, and a front view of partial crushing. A and B are a top view showing a configuration example of the motor-operated valve 2g and the like, and a front view of partial crushing. FIGS. 8A to 8C are diagrams illustrating an operation example of the electric / electromagnetic valve unit 201 when the mist sauna operation is stopped. It is a block diagram which shows the structural example of the control system of the bathroom air conditioner 3 and the mist generator 2 which concern on a 3rd Example. It is a flowchart which shows the example of control in the mist sauna operation | movement stop in the power supply part unit. It is a conceptual diagram which shows the structural example of the motor / electromagnetic valve unit 202 as a 4th Example. FIGS. 8A to 8C are diagrams illustrating an operation example of the electric / solenoid valve unit 202 when the mist sauna operation is stopped. It is a block diagram which shows the structural example of the control system of the bathroom air conditioner 3 and the mist generator 2 which concern on a 4th Example. It is a flowchart which shows the example of control in the mist sauna operation | movement stop in the power supply part unit 302. FIG. A and B are conceptual diagrams showing configuration examples of the electric / electromagnetic valve units 203 and 204 as the fifth embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Bathroom system, 2 ... Mist generator, 2A ... Solenoid valve unit, 2A '... Housing, 2B, 301, 302 ... Power supply unit, 2C ... Nozzle unit, 2a ... water supply piping, 2b ... nozzle piping, 2c ... drain piping, 2a'-2c '... connection part, 2d-2f ... solenoid valve, 2g, 2p ... motorized valve, 2h ... temperature detection sensor, 2i-2k ... piping, 3 ... bathroom air conditioner, 4 ... hot water supply device, 6 ... main operation unit (air conditioner remote control), 6a, 7a, 80a ...・ Electric cable, 7: Mist operation unit (mist remote controller), 7a: Electric cable, 8 ... Exhaust duct, 26 ... Front panel, 69 ... Temperature detection sensor, 69A ... Human body Detection sensor, 69B ... Bathroom lighting switch, 101 ... Bath , 101a ··· inspection port, 101b ··· tub, 101c ··· drain pan, 201 to 204 ... electric or solenoid valve unit

Claims (9)

A hot water supply valve for supplying hot water from a hot water source;
An ejection valve that is connected to one pipe branched from the hot water valve and ejects the hot water;
A drain valve connected to the other pipe branched from the hot water valve and draining water;
Detecting means for detecting drainage temperature by draining operation of the drain valve and outputting temperature detection information;
Control means for controlling the drainage operation of the drainage valve based on temperature detection information output from the detection means, drainage setting time and jetting set temperature ,
The control means includes
Enter the temperature detection information, compare the drainage temperature and the jetting set temperature,
Until the drainage temperature is equal to or higher than the jetting set temperature, the drainage operation by the drainage valve is continued,
Wherein the drainage temperature reaches the set value, the hot water jetting device according to claim Rukoto to have a state of stopping the drainage operation by the drain valve after discharging the warm water drainage set time. The control means includes
Enter the temperature detection information,
Compare the waste water temperature and the jetting set temperature,
Until the drainage temperature is equal to or higher than the set temperature , the drainage operation by the drainage valve is continued,
When the drainage time from the start of drainage until the drainage temperature becomes equal to or higher than the jetting set temperature has not passed the drainage setting time, the drainage operation of the drainage valve is stopped after discharging the warm water for the drainage setting time . The hot water jetting device according to claim 1. The drain valve includes
The hot water jetting device according to claim 1, wherein a valve capable of adjusting the discharge flow rate of the water is used. In the hot water valve,
The hot water jetting device according to claim 1, wherein a valve capable of adjusting the discharge flow rate of the water is used. A water heater,
Hot water supplied from the water heater, or hot water jetting means capable of draining;
Detecting means for detecting temperature of drainage by draining operation of the hot water jetting means and outputting temperature detection information;
Control means for controlling the drainage operation of the hot water ejection device based on temperature detection information output from the detection means, drainage set time and jetting set temperature ,
The control means includes
Enter the temperature detection information,
Compare the waste water temperature and the jetting set temperature,
Until the drainage temperature becomes equal to or higher than the jetting set temperature, the drainage operation by the hot water jetting means is continued,
Wherein the drainage temperature reaches the set value, the hot water supply system according to claim Rukoto to have a state of stopping the drainage operation by the hot water spouting means after discharging the warm water drainage set time. The control means includes
Enter the temperature detection information,
Compare the waste water temperature and the jetting set temperature,
The drainage operation by the hot water jetting means is stopped while notifying a malfunction of the hot water supply system when the drainage temperature after the drainage set time is less than the jetting set temperature. 5. A hot water supply system according to 5 . The drain valve includes
The hot water supply system according to claim 5 , wherein a valve capable of adjusting the discharge flow rate of the water is used. In the hot water valve,
The hot water supply system according to claim 5 , wherein a valve capable of adjusting the discharge flow rate of the water is used. A room in which hot water supplied from a water heater is ejected, or a hot water ejection means capable of draining is attached,
Detecting means for detecting temperature of drainage by draining operation of the hot water jet means and outputting temperature detection information;
Control means for controlling the drainage operation of the hot water jetting device based on temperature detection information output from the detection means, a preset drainage setting time and a jetting set temperature ,
The control means inputs the temperature detection information, compares the drainage temperature and the ejection set temperature,
Until the drainage temperature becomes equal to or higher than the jetting set temperature, the drainage operation by the hot water jetting means is continued,
When the drainage temperature reaches the set value, the chamber, characterized in Rukoto to have a state of stopping the drainage operation by the hot water spouting means after discharging the warm water drainage set time.

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