JP4876689B2 - Hot water jet air conditioning system - Google Patents

Description

  The present invention relates to a hot water jet air-conditioning system for jetting hot water or water mist and performing humidification heating in a room such as a bathroom or a shower room.

  2. Description of the Related Art Conventionally, a mist device has been proposed in which hot water is sprayed as a mist into a bathroom to perform humidification heating in the bathroom (see, for example, Patent Document 1).

  Such a mist device has a configuration in which one or a plurality of mist nozzles are installed 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

  Conventionally, when any error occurs during the operation of ejecting mist with the mist device, the mist ejection is stopped and notified to the user via an operation unit such as a remote control device.

  The cause of the error may be a malfunction of the hot water supply device in addition to the abnormality occurring on the mist device side. However, since there is no configuration for performing communication between the mist device and the hot water supply device to send and receive information about the error, there is a problem that an error occurring on the hot water heater side cannot be notified.

  The present invention has been made to solve such a problem, and an object thereof is to provide a hot water jet air conditioning system that can notify a user of an error occurring on the hot water supply side.

In order to solve the above-described problems, a hot water jet air-conditioning system according to the present invention is a hot water jet air-conditioning system including a hot water jet air-conditioning system that receives hot water or water supplied from a hot water supply device and jets it as a mist. a water temperature sensor for detecting the temperature of the hot water or the water supplied from the water heater, the temperature of the supplied hot water or water from the water heater is detected by the coolant temperature detection sensor, as well as determining the presence or absence of an abnormality of the water heater, The system side is provided with a control means for determining the presence or absence of an abnormality occurring on the system side from the state on the system side, and notifies the user that the abnormality of the hot water supply device has been detected by the control means, and the system by the control means the detection of the side abnormal comprises informing means for informing the user to distinguish an abnormality occurring in the water heater to the operating means of the system side control means, water The water temperature detected by the detection sensor is compared with the preset lower limit value and upper limit value, and the detected water temperature is less than the lower limit value or exceeds the upper limit value. If it continues for more than an hour, it will perform standby operation and monitor the water temperature, and if it is above or below the installation temperature even after the specified detection time has passed, it is determined that the hot water supply device is abnormal and an abnormality on the system side has been detected. In this case, the user is notified by the notification means .

  In the hot water jet air conditioning system of the present invention, when the operation in the mist mode is started, the hot water supplied from the hot water supply device or the hot water supply state of water is monitored, and the presence or absence of abnormality of the hot water supply device is determined from the change in the water temperature, etc. When a device abnormality is detected, the user is notified.

  According to the hot water jet air-conditioning system of the present invention, it is possible to determine whether or not there is an abnormality in the hot water supply device and to notify the user without performing communication with the hot water supply device. Thereby, when an error occurs, the cause can be easily pursued.

  In addition, since there is no need to communicate with the hot water supply device, a system that can notify an error using an existing hot water supply device can be constructed.

  Hereinafter, an embodiment of a bathroom air conditioning system which is an example of a hot water jet air conditioning system of the present invention will be described with reference to the drawings.

<Overall configuration example of bathroom air-conditioning system according to the present embodiment>
FIG. 1 is a configuration diagram illustrating an example of a bathroom air-conditioning system 1A according to the present embodiment. The bathroom air-conditioning system 1A according to the present embodiment includes a mist generating device 2 that uses hot water as a mist-like mist to be ejected into the bathroom 101, and a bathroom air-conditioning device 3 that heats or ventilates the bathroom 101.

The bathroom air-conditioning system 1A is used in combination with, for example, a heat pump type hot water supply device 4 using natural refrigerant (CO ₂ ) as a supply source of the hot water HW to the mist generating device 2.

  The mist generating device 2 includes a nozzle unit 2A that generates mist, and a valve unit 2B that switches whether hot water (water) supplied from the hot water supply device 4 is supplied to or discharged from the nozzle unit 2A. Here, the mist includes states such as fog, haze and shower.

  The bathroom air conditioning system 1A is operated by operating the mist operation unit 5 installed in the bathroom 101 and the main operation unit 6 installed in the washroom 102 adjacent to the bathroom 101, so that the mist generator 2 and the bathroom air conditioner are operated. The operation mode executed in 3 is selected.

  In the mist operation part 5, operation about the operation mode mainly related to heating is performed, and operation regarding heating is possible during bathing etc. In addition, the main operation unit 6 performs operations for general operation modes including heating, and can perform operations related to heating, ventilation, drying, and the like without entering the bathroom 101.

  The bathroom air conditioning system 1 </ b> A is controlled by a mist control unit 7 provided in the mist generating device 2 and a main control unit 8 provided in the bathroom air conditioning device 3. The mist control unit 7 drives the valve unit 2B of the mist generating device 2 to perform control for switching the presence or absence of ejection of the mist M. Further, the main control unit 8 drives the bathroom air conditioner 3 to suck in the air A from the bathroom 101 and blow it out as hot air HA or blown air, and to control the air A sucked in from the bathroom 101 to the outside. Do.

  The bathroom air-conditioning system 1A communicates between the mist control unit 7 and the main control unit 8 according to the operation mode selected by operating the mist operation unit 5 or the main operation unit 6. Control in which the bathroom air conditioner 3 alone or the mist generator 2 and the bathroom air conditioner 3 are linked is executed.

  As an operation mode selected by operating the mist operation unit 5 or the main operation unit 6 and executed in the bathroom air conditioning system 1A, for example, mist M is ejected by the mist generator 2 and hot air is produced by the bathroom air conditioner 3. A mist mode is provided in which the inside of the bathroom 101 is brought into a mist sauna state of medium temperature and high humidity by interlocking the HA blowing.

  In the mist mode, the hot air HA is blown out by the bathroom air conditioner 3 to raise the temperature in the bathroom 101, and then the mist generator 2 blows out the mist M that has reached a predetermined temperature, so that the bather (use Person)).

  In the mist mode, the temperature in the bathroom 101 and the temperature of the hot water HW to be ejected as the mist M are detected, and it is determined whether or not the state in the bathroom 101 is suitable for bathing. And it notifies to a bather etc. from the main operation part 6.

  Further, the temperature of the hot water HW to be ejected as the mist M is detected, the presence or absence of abnormality in the hot water supply device 4 is determined, and the bather or the like is notified from the mist operation unit 5.

<Configuration example and operation example of mist generator>
FIG. 2 is a block diagram showing an example of a nozzle unit 2A constituting the mist generator 2. FIG. 2 (a) is a plan view of the nozzle unit 2A as viewed from below, and FIG. 2 (b) is a diagram in FIG. 2 (a). 2A is a cross-sectional view of the nozzle unit 2A taken along line AA, and FIG. 2C is a cross-sectional view of the nozzle unit 2A shown in FIG.

  The nozzle unit 2 </ b> A is an example of a hot water spray device, and a plurality of mist nozzles 11 that generate mist are attached to the inside of the main body 13 via supply pipes 12 that supply hot water (water) to the mist nozzles 11.

  Each mist nozzle 11 is connected to one supply pipe 12 and arranged in a line. In this example, when three mist nozzles 11 are arranged at a predetermined interval, each mist nozzle 11 is connected to the supply pipe 12, and hot water is supplied to the supply pipe 12, hot water is supplied to each mist nozzle 11. Are distributed, and mist is ejected from each mist nozzle 11.

  The nozzle unit 2A is installed on the ceiling panel of the bathroom 101 with the main body 13 inserted into the opening formed in the ceiling panel of the bathroom 101 shown in FIG. 1 and the front panel 14 covering the lower opening of the main body 13 being attached. Is done.

  The front panel 14 is formed with a hole portion 14a in accordance with the arrangement of the mist nozzle 11, and the mist nozzle 11 is exposed from the hole portion 14a.

  Here, a long hole 14b into which a screw (not shown) for fixing the front panel 14 is inserted is provided so that the mounting position of the front panel 14 can be moved in a direction perpendicular to the direction in which the mist nozzles 11 are arranged. Thus, each mist nozzle 11 may rotate about the supply pipe 12 in accordance with the position of the hole 14a of the front panel 14 so that the mist ejection direction can be selected when the nozzle unit 2A is installed. .

  For example, the nozzle unit 2A is installed such that the direction in which the mist nozzles 11 are arranged is perpendicular to the direction in which the bathtub 101a and the washing area 101b are arranged in the bathroom 101 shown in FIG. It is possible to select between the side and the washing area 101b side.

  FIG. 3 is a block diagram showing an example of a valve unit 2B constituting the mist generating device 2. The valve unit 2B is an example of a flow path switching device. A hot water supply pipe connection portion 16a to which a pipe 15a from the hot water supply apparatus 4 shown in FIG. 1 is connected and a supply pipe connection portion 16b to which a pipe 15b to the nozzle unit 2A is connected. And a drain pipe connecting portion 16c to which the drain pipe 15c is connected.

  In the valve unit 2B, the hot water supply pipe connection portion 16a and the supply pipe connection portion 16b are connected by the supply pipe 17, and the hot water supply device 4 and the nozzle unit 2A are connected. Further, in the valve unit 2B, the drain pipe 18 branched from the supply pipe 17 is connected to the drain pipe connecting portion 16c, and the hot water supply device 4 and the drain pipe 15c are connected.

  The valve unit 2B is provided with a hot water supply switching electromagnetic valve 19a for switching the presence or absence of hot water supply in the supply pipe 17 upstream of the branching portion 17a with the drainage pipe 18, and in the supply piping 17 downstream of the branching portion 17a with hot water or A supply switching electromagnetic valve 19b that switches the water supply destination to the nozzle unit 2A is provided.

  Furthermore, the valve unit 2B includes a drainage switching electromagnetic valve 19c that switches a supply destination of hot water or water to the drain pipe 15c in the drainage pipe 18.

  Further, the valve unit 2B includes a water temperature detection sensor 20 that detects the temperature of the hot water flowing through the supply pipe 17 or the temperature of the water in the supply pipe 17 between the hot water supply switching electromagnetic valve 19a and the branch portion 17a.

  Here, the supply pipe 17 and the drainage pipe are arranged so that the installation height of the drainage switching solenoid valve 19c provided in the drainage pipe 18 is lower than the installation height of the hot water supply switching solenoid valve 19a and the supply switching solenoid valve 19b provided in the supply pipe 17. By configuring 18 channels, residual water is prevented from staying in the channels.

  4 and 5 are operation explanatory views of the valve unit 2B. At the time of mist ejection, as shown in FIG. 4A, the hot water supply switching electromagnetic valve 19a and the supply switching electromagnetic valve 19b are opened, and the drainage switching electromagnetic valve 19c is closed. Accordingly, the hot water HW supplied from the hot water supply device 4 shown in FIG. 1 flows through the supply pipe 17 and is supplied to the nozzle unit 2A, and the mist M is ejected from the nozzle unit 2A.

  At the time of drainage, as shown in FIG. 4B, the hot water supply switching solenoid valve 19a and the drainage switching solenoid valve 19c are opened, and the supply switching solenoid valve 19b is closed. Thereby, the hot water HW supplied from the hot water supply device 4 flows through the supply pipe 17 and the drain pipe 18 and is drained (EW) from the drain pipe 15c.

  When drainage is stopped, first, as shown in FIG. 5A, the drainage switching electromagnetic valve 19c is opened, the hot water supply switching solenoid valve 19a is closed, and then the supply switching solenoid valve 19b is opened. As a result, the side of the supply pipe 17 connected to the nozzle unit 2A is opened to the atmosphere, so the residual water RW in the supply pipe 17 flows into the drain pipe 18 and is drained from the drain pipe 15c.

  Then, after the elapse of a predetermined time set according to the time required for draining the residual water RW, as shown in FIG. 5B, all of the hot water supply switching solenoid valve 19a, the supply switching solenoid valve 19b, and the drainage switching solenoid valve 19c. Is closed so that the remaining water does not stay in the flow path downstream of the hot water supply switching electromagnetic valve 19a.

<Example of configuration and operation of bathroom air conditioner>
6 is a cross-sectional view showing a configuration example and an operation example of the bathroom air conditioner 3. FIG. 7 is a perspective view of the bathroom air conditioner 3 seen from the lower surface side. An example will be described.

  The bathroom air conditioner 3 is an example of an air conditioner and is referred to as a bathroom heating / ventilating / drying apparatus or the like, and includes a fan unit 32 constituting a ventilation unit and a blowing unit and a heater unit 33 as a heat source. The bathroom air conditioner 3 has a fan unit 32 attached to a main body case 34. The fan unit 32 includes a multi-blade impeller (fan) 35 that is rotationally driven, a fan motor 36 that rotationally drives the impeller 35, and a fan case 37 that is attached with the fan motor 36 and forms an air passage. .

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

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

  FIG. 6A shows a state where the damper 40 is fully closed. When the damper 40 is fully closed, the air passage to the exhaust port 42 is blocked, and a circulation air passage 43 a communicating from the suction port 38 to the blower outlet 41 is formed. For this reason, the position where the damper 40 is fully closed is referred to as the circulation position of the damper 40.

  FIG. 6B shows a state where the damper 40 is fully opened. When the damper 40 is fully opened, the air path to the air outlet 41 is blocked, and a ventilation air path 43b communicating from the suction port 38 to the exhaust port 42 is formed. For this reason, the position where the damper 40 is fully opened is referred to as a ventilation position of the damper 40.

  FIG. 6C shows a state in which the damper 40 is at an intermediate position between the circulation position and the ventilation position. When the damper 40 is set at an intermediate position between the circulation position and the ventilation position, both a circulation air passage 43a communicating from the suction port 38 to the blowout port 41 and a ventilation air passage 43b communicating from the suction port 38 to the exhaust port 42 are formed. . This intermediate position is referred to as a circulation ventilation position.

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

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

These H ⁺ (H ₂ O) _m and O ₂ ⁻ (H ₂ O) _n adhere to the surface of the floating bacteria and chemically react to generate H ₂ O ₂ or .OH as an active species. Since H ₂ O ₂ or .OH exhibits very strong activity, they can surround and remove airborne bacteria. 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 It is possible to remove both floating bacteria in the air of the bathroom 101 shown in FIG.

  The heater unit 33 is an example of a heating unit constituted by an electric heater, and is provided in the above-described air outlet 41. Here, as the heater unit 33, for example, a PTC heater is provided.

  As shown in FIG. 7, the lower surface of the main body case 34 is opened to expose the suction port 38 and the air outlet 41 of the fan portion 32. A temperature detection sensor 31 is provided in the suction port 38, and the temperature of the bathroom 101 can be detected by detecting the temperature of air sucked from the suction port 38.

  In addition, it is good also as a structure which equips the blower outlet 41 with the electrically-driven blowing louver which switches a wind direction.

  The main body case 34 has the front panel 26 attached to the lower surface opening. The front panel 26 is configured to be attachable to and detachable from the main body case 34, and includes a suction grill 45 that faces the suction port 38 of the fan part 32, and a blow grill 46 that faces the blower outlet 41 of the fan part 32. . The front panel 26 is attached to the back side of the suction grill 45 so that the filter 47 can be replaced.

  Furthermore, the main body case 34 includes an exhaust duct connection portion 48 that communicates with the exhaust port 42 of the fan portion 32 on one side surface. In the bathroom air conditioner 3, the exhaust duct 9 shown in FIG.

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

  When the position of the damper 40 is the circulation position shown in FIG. 6A, 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 A sucked from the suction port 38 Is blown out into the bathroom 101 through the circulation air passage 43a from the outlet 41 through the outlet grill 46 of the front panel 26.

  Since the heater part 33 is arrange | positioned at the blower outlet 41 of the circulation air path 43a, when the heater part 33 is driven, the air which passes along the circulation air path 43a is warmed, and the warm air HA blows off from the blowing grill 46a.

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

  When the position of the damper 40 is the ventilation position shown in FIG. 6B, the ventilation air passage 43b from the suction port 38 to the exhaust port 42 is formed in the fan part 32, so that the air sucked from the suction port 38 is Then, the air passes through the ventilation air passage 43b and the exhaust port 42, and further passes through the exhaust duct 9 shown in FIG.

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

  When the position of the damper 40 is the circulation ventilation position shown in FIG. 6C, the circulation air passage 43 a from the suction port 38 to the outlet 41 in the fan unit 32 and the ventilation air passage from the suction port 38 to the exhaust port 42. Since both of 43b are formed, a part of the air sucked from the suction port 38 passes through the circulation air passage 43a and is blown into the bathroom 101 from the blower outlet 41 through the blowout grill 46 of the front panel 26.

  Further, the remaining portion of the air sucked from the suction port 38 passes through the ventilation air passage 43b and the exhaust port 42, and further exhausts from the exhaust grill 9a to the outside through the exhaust duct 9 shown in FIG.

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

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

  In addition, as a bathroom air conditioner, the structure etc. which were provided with the circulation fan and the ventilation fan and the circulation air path and the ventilation air path became independent may be sufficient.

<Example of installation of mist generator and bathroom air conditioner>
The mist generator 2 and the bathroom air conditioner 3 described above are arranged along the longitudinal direction of the bathtub 101a, respectively, as shown in FIG. 1, and the mist generator 2 and the bathroom air conditioner 3 are arranged in the bathtub 101a and the washing place 101b. It is paralleled along the line direction. Moreover, the mist generator 2 is arrange | positioned at the washing place 101b side. The mist M ejection direction of the mist generator 2 and the hot air HA (air blowing) blowing direction of the bathroom air conditioner 3 are directed to the normal washing place 101b side.

<Configuration example of hot water supply system>
FIG. 8 is a configuration diagram showing an outline and a connection form of the hot water supply device 4. Next, an example of the configuration and operation of the hot water supply device 4 will be described.

  The hot water supply device 4 includes a heat pump unit 53 that generates hot water by heat exchange between the atmosphere and the refrigerant and heat exchange between the refrigerant and water, and a hot water storage tank unit 54 that stores the hot water generated by the heat pump unit 53. Prepare.

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

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

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

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

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

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

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

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

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

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

  The water supply pipe 63 is connected to a water supply port 60e provided in the lower part of the tank 60 independently of the outflow port 60b.

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

  The hot water supply pipe 65 is connected to the valve unit 2B of the mist generator 2 shown in FIG. 1, the faucet or shower 101c of the bathtub 101a of the bathroom 101, the faucet 102a of the washroom 102, the faucet (not shown) of the kitchen 103, etc. Supply.

  Next, the operation of the hot water supply device 4 will be described. In the hot water supply device 4, water is supplied from the water supply pipe 63 to the tank 60 of the hot water storage tank unit 54. The water supplied to the tank 60 is supplied to the water heat exchanger 56 of the heat pump unit 53 through the cold water pipe 61b.

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

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

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

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

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

  The hot water taken by the water intake pipe 62 is mixed with the water supplied from the branch water supply pipe 63 b by the hot water supply mixing valve 64. The temperature of hot water supplied from the hot water supply pipe 65 is adjusted by switching the mixing ratio of hot water and water with the hot water supply mixing valve 64. The hot water supplied from the hot water supply pipe 65 is distributed to the mist generating device 2, the bathroom 101, the washroom 102, the kitchen 103, and the like.

  The hot water supply device 4 may be an electric water heater that is not a heat pump system using natural refrigerant, a gas water heater, or a water heater that uses other heat sources.

<Example of control function of bathroom air-conditioning system of this embodiment>
FIG. 9 is a functional block diagram showing an example of the control system of the bathroom air-conditioning system 1A of the present embodiment. Next, the bathroom air-conditioning system 1A including the mist generating device 2, the bathroom air-conditioning device 3, and the hot water supply device 4 described above. The configuration of the control system will be described.

  The bathroom air-conditioning system 1A includes a mist control unit 7 in the mist generating device 2 and a main control unit 8 in the bathroom air-conditioning device 3.

  The mist control unit 7 is an example of a sub-control unit. The mist operation unit 5, the hot water switching electromagnetic valve 19a, the supply switching electromagnetic valve 19b, the drain switching electromagnetic valve 19c, and the water temperature detection of the valve unit 2B described in FIG. A sensor 20 or the like is connected. The mist operation unit 5 is connected to the mist control unit 7 by wire, for example. The mist control unit 7 is connected to a timer 70 that measures time.

  The main control unit 8 is an example of a main control unit. The main operation unit 6, the temperature detection sensor 31 of the bathroom air conditioner 3 described with reference to FIGS. 6 and 7, the heater unit 33, the fan motor 36, and the ion generator. 44, a damper motor 40b for driving the damper 40, and the like are connected. The main operation unit 6 is connected to the main control unit 8 by wire, for example.

  Further, the mist control unit 7 and the main control unit 8 are connected by, for example, a wire.

  The mist control unit 7 and the main control unit 8 are each provided with a CPU, a memory and the like (not shown), and the valve unit of the mist generating device 2 according to the operation in the mist operation unit 5 and the main operation unit 6 and the program stored in advance. 2B and the bathroom air conditioner 3 are controlled.

  That is, the mist control unit 7 and the main control unit 8 communicate according to a predetermined operation in the mist operation unit 5 or the main operation unit 6, and the mist control unit 7 controls the valve unit 2B of the mist generating device 2, The main controller 8 controls the bathroom air conditioner 3 to link the mist generator 2 and the bathroom air conditioner 3 to execute a mist mode for humidifying and heating the bathroom 101 shown in FIG.

  In addition, the main control unit 8 controls the bathroom air conditioner 3 according to a predetermined operation in the main operation unit 6 as an operation of the bathroom air conditioner 3 alone, and a heating operation mode in which the bathroom 101 is heated, and ventilation of the bathroom 101. A ventilation operation mode for performing the operation, a drying operation mode for drying the bathroom 101 and clothes dried in the bathroom 101, and a cool air operation mode for blowing air to a bather or the like.

  FIG. 10 is a configuration diagram illustrating an example of the mist operation unit 5. The mist operation unit 5 is an example of a sub-operation means, and includes a mist operation selection button 71 for selecting operation in the mist mode and operation stop as an operation button for selecting an operation mode. Moreover, the heating operation selection button 72 for selecting the start and stop of the heating operation mode and the strength of heating is provided.

  Further, when the bathroom air conditioner 3 described with reference to FIGS. 6 and 7 is provided with an electric blowout louver that switches the air direction, a louver button 73 that operates the blowout louver is provided. Moreover, the stop button 74 which stops all control is provided.

  The mist operation unit 5 is a mist operation lamp 75 corresponding to the mist operation selection button 71 as a notification means for notifying a bather or the like of the operation state of the mist generator 2 and the bathroom air conditioner 3 and the state in the bathroom 101. Is provided.

  A heating operation lamp 76 associated with the heating operation selection button 72 is also provided. The heating operation lamp 76 includes, for example, a strong heating operation lamp 76a and a weak heating operation lamp 76b according to the degree of heating intensity that can be selected.

  Furthermore, an error lamp 77 is provided for notifying a failure in any of the bathroom air conditioning systems 1A.

  FIG. 11 is a configuration diagram illustrating an example of the main operation unit 6. The main operation unit 6 is an example of main operation means. As an operation button for selecting an operation mode, the operation and stop of the heating operation mode in the bathroom air conditioner 3 alone and the operation in the mist mode in which the mist generating device 2 is linked. And a heating operation selection button 81 for selecting operation stop.

  In addition, a ventilation operation selection button 82 for selecting start and stop of the ventilation operation mode, a dry operation selection button 83 for selecting start and stop of the dry operation mode, and a cool wind for selecting start and stop of the cool air operation mode. An operation selection button 84 is provided.

  Furthermore, a 24-hour ventilation operation selection button 85 for selecting a 24-hour ventilation operation mode in which continuous ventilation is performed with a predetermined ventilation air volume, and a stop button 86 for stopping all controls are provided.

  In addition, when the bathroom air conditioner 3 demonstrated in FIG.6 and FIG.7 is equipped with the electric blowing louver which switches a wind direction, the louver button 87 which operates a blowing louver is provided.

  In addition, the main control unit 6 is a heating operation selection button as a notification means for notifying the bather or the like of the operation mode selected by each operation button, the air volume set in each operation mode, and the state in the bathroom 101, etc. For example, a strong heating operation lamp 81b and a weak heating operation lamp 81c are provided according to the degree of heating intensity that can be selected.

  Further, a ventilation operation lamp 82a associated with the ventilation operation selection button 82, a drying operation lamp 83a associated with the drying operation selection button 83, a cool air operation button 84 associated with the cool air operation selection button 84, and 24-hour ventilation. A 24-hour ventilation operation lamp 85 a corresponding to the operation selection button 85 and an ion operation lamp 88 are provided.

  In addition, when an air volume etc. can be selected in each operation mode, according to the intensity | strength etc. of the air volume which can be selected, a several operation lamp is provided corresponding to each operation button.

  Further, the main operation unit 6 includes a display unit 89 that displays the current time and the like.

  The heating intensity that can be selected with the heating operation selection button 72 of the mist operation unit 5 is not limited to two levels of “strong” and “weak”, but may be three levels such as “strong”, “medium”, and “weak”. Further stages may be used.

  Moreover, according to the strength of the heating which can be selected, you may provide the middle heating operation lamp as the heating operation lamp 76, for example.

  Similarly, the level of heating that can be selected by the heating operation selection button 81 of the main operation unit 6 may be three levels such as “strong”, “medium”, and “weak”, or may be higher. Moreover, according to the heating intensity | strength which can be selected, you may provide a middle heating operation lamp as a heating operation lamp, for example.

  In addition, although the strength of heating operation is switched by, for example, switching the fan air volume, not only the fan air volume is switched, but also the amount of heat generated by the heater in the heater unit 33, the heater energization time, and the heater energization. The temperature to be changed may be changed.

<Operation example of mist mode of this embodiment>
FIG. 12 is a flowchart showing an example of the embodiment of the mist mode executed in the bathroom air-conditioning system 1A of the present embodiment. Next, each drawing shows the flow of processing when the mist mode is executed of the present embodiment. The description will be given with reference.

  Step SA1: A bather or the like presses the mist operation selection button 71 of the mist operation unit 5 installed in the bathroom 101 or humidifies and heats the bathroom 101 or the main operation unit 6 installed in the washroom 102. The heating operation selection button 81 is pressed a predetermined number of times to select the mist mode.

  Step SA2: When the mist operation selection button 71 of the mist operation unit 5 is pressed, the mist control unit 71 of the mist generating device 2 determines that the mist mode is selected, and the mist operation lamp 75 of the mist operation unit 5 blinks. In addition, a mist operation command is transmitted to the main control unit 8 of the bathroom air conditioner 3.

  Here, in the state where the mist operation lamp 75 is blinking in the mist operation unit 5, the operation in the mist mode is started, but in order to increase the temperature of the bathroom 101, the mist operation lamp 75 is in a standby state without ejecting mist. This is notified to a bather or the like in the bathroom 101.

  Step SA3: When receiving the mist operation command from the mist control unit 7, the main control unit 8 determines that the mist mode is selected, and blinks the mist operation lamp 81a of the main operation unit 6.

  Here, in the state where the mist operation lamp 81a is blinking in the main operation unit 6, the operation in the mist mode is started, but the mist operation lamp 81a is in a standby state without ejecting mist in order to raise the temperature of the bathroom 101. This is notified to the user before bathing outside the bathroom 101.

  When the mist mode is selected by pressing the heating operation selection button 81 of the main operation unit 6, the main control unit 8 determines that the mist mode is selected and transmits a mist operation command to the mist control unit 7. . When receiving the mist operation command from the main control unit 8, the mist control unit 7 determines that the mist mode has been selected and causes the mist operation lamp 75 to blink, and returns the mist operation command to the main control unit 8. And the main control part 8 will blink the mist operation lamp 81a, if the reply of the mist operation command from the mist control part 7 is received.

  Step SA4: When starting the operation in the mist mode, the main control unit 8 of the bathroom air conditioner 3 controls the bathroom air conditioner 3 to perform the heating operation. That is, the main control unit 8 controls the fan motor 36 so that the fan air volume becomes “strong”, for example, and energizes the heater unit 33. Further, the damper motor 40b is controlled to bring the damper 40 into the circulating position shown in FIG.

  Thereby, the bathroom air conditioner 3 blows the hot air HA into the bathroom 101 from the blowing grill 46 of the front panel 26 while circulating the air in the bathroom 101. In the bathroom air conditioner 3, since an electric heater such as a PTC heater is used as the heater unit 33, the time from the start of energization until the heater unit 33 is heated to a predetermined temperature is short, and the hot air HA The rise time until blowing out is short. Further, since the fan air volume is set to “strong”, the amount of hot air HA blown out increases.

  Therefore, in the mist mode, the temperature in the bathroom 101 can be raised to a temperature suitable for mist ejection in a short time.

  In addition, in order to notify that the bathroom air conditioner 3 is performing the heating operation, the main control unit 8 transmits a predetermined command to the main operation unit 6 and the mist control unit 7, and the strong heating operation lamp of the main operation unit 6 is transmitted. 81b is turned on, and the strong heating operation lamp 76a of the mist operation unit 5 is turned on.

  Step SA5: The main controller 8 of the bathroom air conditioner 3 detects the temperature TH1 in the bathroom 101 by the temperature detection sensor 31 in order to detect that the inside of the bathroom 101 is in a predetermined state when the operation in the mist mode is started. To do. In this processing step, it is determined whether or not the temperature TH1 in the bathroom 101 has reached a predetermined mist ejection start temperature (for example, 30 ° C.) suitable for mist ejection.

  Step SA6: When the main controller 8 of the bathroom air conditioner 3 determines that the temperature TH1 in the bathroom 101 has become equal to or higher than the mist ejection start temperature (for example, 30 ° C.) in Step SA5 described above, the mist controller of the mist generator 2 The operation permission command is transmitted to 7. When receiving the operation permission command from the main control unit 8, the mist control unit 7 controls the mist generating device 2 to perform the drain operation.

  FIG. 13 is a flowchart showing an example of the drainage operation, and the flow of the drainage operation performed before mist ejection will be described.

  Step SB1: The mist control unit 7 of the mist generator 2 opens the hot water supply switching electromagnetic valve 19a of the valve unit 2B.

  Step SB2: The mist control unit 7 of the mist generator 2 opens the drainage switching electromagnetic valve 19c of the valve unit 2B. Thereby, the hot water HW supplied from the hot water supply device 4 is drained from the drain pipe 15c. At this time, the supply switching electromagnetic valve 19b is closed, and mist is not ejected from the nozzle unit 2A.

  Step SB3: The mist control unit 7 of the mist generating device 2 resets the timer 70 (t = 0) and performs time measurement.

  Step SB4: When the mist control unit 7 of the mist generating device 2 starts the drain operation, the water temperature detection sensor 20 detects the water temperature TH2 of the hot water HW supplied from the hot water supply device 4.

  In this example, it is detected whether the water temperature TH2 of the hot water HW supplied from the hot water supply device 4 has reached a predetermined mist ejection suitable temperature (for example, 30 ° C.) suitable for mist ejection, and the water temperature TH2 is suitable for mist ejection. When the temperature (for example, 30 ° C.) is reached, it is determined that the water temperature is suitable for mist ejection.

  Step SB5: The mist control unit 7 of the mist generating device 2 measures the time t when the water temperature TH2 from the hot water supply device 4 detected by the water temperature detection sensor 20 is lower than the mist ejection compatible temperature (for example, 30 ° C.). It is determined whether a predetermined hot water supply apparatus abnormality detection time has elapsed.

  In this example, after the hot water supply switching electromagnetic valve 19a and the drainage switching electromagnetic valve 19c are opened and hot water supply is started from the hot water supply device 4, the water temperature TH2 is suitable for mist injection even if the time t elapses, for example, 5 minutes. When the temperature does not rise, it is determined that an abnormality has occurred in the hot water supply device 4.

  Step SB6: If the mist control unit 7 of the mist generating device 2 determines that an abnormality has occurred in the hot water supply device 4 from the relationship between the time since the hot water supply device 4 started hot water supply and the water temperature, an error in the mist operation unit 5 The lamp 77 is turned on.

  Here, in a state where the error lamp 77 is lit in the mist operation unit 5, a bather or the like is informed that some abnormality has occurred on the hot water supply device 4 side.

  Step SB7: When the mist control unit 7 of the mist generating device 2 determines that an abnormality has occurred in the hot water supply device 4, in order to stop the drainage treatment before the mist injection, the drainage switching electromagnetic valve 19c is opened and the hot water supply switching is performed. The electromagnetic valve 19a is closed.

  Step SB8: The mist control unit 7 of the mist generator 2 closes the hot water supply switching electromagnetic valve 19a and then opens the supply switching electromagnetic valve 19b. As a result, as shown in FIG. 5A, the side of the supply pipe 17 connected to the nozzle unit 2 </ b> A is opened to the atmosphere, so the remaining water RW in the supply pipe 17 flows to the drain pipe 18. And drained from the drain pipe 15c.

  Step SB9: The mist controller 7 of the mist generator 2 stands by for a predetermined time (for example, 3 seconds) set according to the time required for draining the residual water RW.

  Step SB10: The mist control unit 7 of the mist generating device 2 closes the supply switching electromagnetic valve 19b after a predetermined time set according to the time required for draining the residual water RW.

  Step SB11: The mist control unit 7 of the mist generator 2 closes the drain switching electromagnetic valve 19c after closing the supply switching electromagnetic valve 19b. Thereby, in the mist generator 2, the state which does not make residual water retain in the flow path downstream from the hot water supply switching electromagnetic valve 19a is shifted to the in-error process.

  In the in-error processing, for example, the mist control unit 7 of the mist generator 2 transmits an error command to the main control unit 8 of the bathroom air conditioner 3 to stop the heating operation. A buzzer may be sounded to notify a user or the like that the operation is stopped due to the occurrence of an error.

  Step SB12: When the water temperature TH2 from the hot water supply device 4 detected by the water temperature detection sensor 20 in Step SB4 described above reaches the mist ejection suitable temperature (for example, 30 ° C.), the mist control unit 7 of the mist generating device 2 ejects the mist. It is determined that the water temperature is suitable for the water temperature, and it is determined whether a predetermined hot water supply temperature stabilization time has elapsed since the time t was measured.

  In this example, the hot water supply switching electromagnetic valve 19a and the drainage switching electromagnetic valve 19c are opened, hot water supply is started from the hot water supply device 4, and the water temperature TH2 from the hot water supply device 4 reaches the mist ejection compatible temperature (for example, 30 ° C.). For example, when 5 seconds have elapsed, it is determined that the hot water supply temperature has stabilized, and the processes after step SA7 in the flowchart shown in FIG. 12 are performed.

  Step SB13: The mist control unit 7 of the mist generating device 2 has not yet passed the predetermined hot water temperature stabilization time since the hot water supply switching electromagnetic valve 19a and the drainage switching electromagnetic valve 19c are opened and hot water supply is started from the hot water supply device 4. If it is determined, the timer 70 is reset (t = 0) and the time is measured.

  Step SB14: The mist control unit 7 of the mist generating device 2 starts hot water supply from the hot water supply device 4, and when the hot water supply temperature stabilization time has elapsed after the water temperature TH2 reaches a predetermined mist jetting suitable temperature, it is shown in FIG. Processes after step SA7 in the flowchart are performed.

  Here, in the mist mode, heating of the bathroom 101 is started by the bathroom air conditioner 3, and after the temperature TH1 in the bathroom 101 reaches a predetermined temperature, the drain operation is started by the mist generating device 2, whereby the amount of discharged water Can be reduced.

  Step SA7: When the mist control unit 7 of the mist generating device 2 determines that the water temperature TH2 of the hot water HW supplied from the hot water supply device 4 in the drainage operation described above has become equal to or higher than a predetermined mist ejection compatible temperature (for example, 30 ° C.) The mist operation lamp 75 of the mist operation unit 5 is switched from blinking to lighting, and a buzzer is sounded.

  Here, in a state where the mist operation lamp 75 is lit in the mist operation unit 5, a bather or the like in the bathroom 101 is informed that the mist is ejected in the mist mode.

  In addition, not only the notification by the lamp but before the mist is blown, the buzzer is sounded to prompt the user to leave the room when the user is in the bathroom 101 while wearing clothes.

  Step SA8: The mist control unit 7 of the mist generating device 2 ejects mist, so that the hot water switching electromagnetic valve 19a of the valve unit 2B is opened, the drain switching electromagnetic valve 19c is closed, and the supply switching electromagnetic valve 19b is opened. open. Thereby, the hot water HW of the predetermined temperature supplied from the hot water supply device 4 is supplied to the nozzle unit 2A, and the mist M is ejected by the nozzle unit 2A.

  Step SA9: The main control unit 8 of the bathroom air conditioner 3 detects that the interior of the bathroom 101 is in a predetermined state after transmitting an operation permission command to the mist control unit 7 of the mist generating device 2 in Step SA6 described above. Therefore, the temperature TH1 in the bathroom 101 is detected by the temperature detection sensor 31. In this processing step, the temperature TH1 in the bathroom 101 is higher than the mist ejection start temperature (for example, 30 ° C.), which is the predetermined room temperature described above, which is a condition for starting mist ejection, and is a predetermined bathing suitable temperature (for bathing) ( For example, it is determined whether or not the temperature has reached 35 ° C.

  Step SA10: When the main control unit 8 of the bathroom air conditioner 3 determines that the temperature TH1 in the bathroom 101 has become equal to or higher than the bathing suitability temperature (for example, 35 ° C.) in Step SA9 described above, the mist operation lamp 81a of the main operation unit 6 Switch from blinking to lit.

  Here, in the state where the mist operation lamp 81a is lit in the main operation unit 6, the inside of the bathroom 101 is in a predetermined middle temperature and high humidity mist sauna state, and it is outside the bathroom 101 that it is suitable for bathing. We inform users before bathing.

  In step SA5 shown in FIG. 12, the temperature in the bathroom 101 is detected by the temperature detection sensor 31 and the state in the bathroom 101 is determined. However, the time is measured by a timer, and the bathroom 101 is measured when a predetermined time elapses. It may be determined whether or not the state becomes a state suitable for mist ejection.

  Moreover, you may make it judge the state in the bathroom 101 combining the detection of the room temperature by the temperature detection sensor 31, and the measurement of the elapsed time by a timer.

  Furthermore, it may be determined whether or not the inside of the bathroom 101 is in a state suitable for mist ejection by other means such as a humidity sensor.

  Also in step SA9 shown in FIG. 12, the time may be measured by a timer, and it may be determined that the interior of the bathroom 101 is a mist sauna environment suitable for bathing when a predetermined time elapses. The combination of the detection of the room temperature by 31 and the measurement of the elapsed time by the timer, or other means such as a humidity sensor may be used to determine that the state is suitable for bathing.

  With the above operation, the mist mode in which the warm air HA is blown out by the bathroom air conditioner 3 is executed while the mist generator 2 ejects the mist M into the bathroom 101.

  FIG. 14 is a flowchart showing an example of a standby process during the mist mode operation. Next, a control flow for monitoring the water temperature from the hot water supply device 4 during the mist mode operation and ejecting a mist having an appropriate water temperature will be described.

  Step SC1: During the mist operation, the mist control unit 7 of the mist generating device 2 detects the water temperature TH2 of the hot water HW supplied from the hot water supply device 4 by the water temperature detection sensor 20, and determines whether the water temperature TH2 is less than the ejection lower limit value. To do.

  In this example, when it is detected that the state where the water temperature TH2 is lower than, for example, 25 ° C. continues for 10 seconds, it is determined that the water temperature TH2 is lower than the ejection lower limit value.

  Step SC2: When the mist control unit 7 of the mist generating device 2 determines that the water temperature TH2 from the hot water supply device 4 detected by the water temperature detection sensor 20 has become lower than a predetermined lower limit of ejection, the mist control unit 7 temporarily stops the mist ejection. Do the driving.

  Step SC3: The mist control unit 7 of the mist generating device 2 determines whether the water temperature TH2 from the hot water supply device 4 detected by the water temperature detection sensor 20 exceeds the ejection upper limit value.

  In this example, when it is detected that the state in which the water temperature TH2 has exceeded, for example, 65 ° C. has continued for 10 seconds, it is determined that the water temperature TH2 has exceeded the ejection upper limit value.

  Step SC4: When the mist control unit 7 of the mist generating device 2 determines that the water temperature TH2 from the hot water supply device 4 detected by the water temperature detection sensor 20 has exceeded a predetermined ejection upper limit value, the high temperature standby operation for temporarily stopping the mist ejection I do.

  FIG. 15 is a flowchart illustrating an example of the low-temperature standby operation. Next, a flow of standby processing when the hot water supply temperature from the hot water supply device 4 is lowered will be described.

  Step SD1: The mist control unit 7 of the mist generating device 2 switches the mist operation lamp 75 of the mist operation unit 5 from lighting to blinking in order to notify that the ejection of the mist M is temporarily stopped in the low temperature standby operation. In addition, you may use the alert | report by a buzzer together.

  Step SD2: The mist control unit 7 of the mist generating device 2 closes the supply switching electromagnetic valve 19b in order to stop the ejection of the mist M.

  Step SD3: The mist control section 7 of the mist generating device 2 opens the drainage switching electromagnetic valve 19b after closing the supply switching electromagnetic valve 19b. Thereby, the ejection of mist is stopped and the drainage operation is performed, and the low-temperature standby operation for continuing the hot water supply from the hot water supply device 4 is started.

  Step SD4: When the low temperature standby operation is started, the mist control unit 7 of the mist generating device 2 detects the water temperature TH2 of the hot water HW supplied from the hot water supply device 4 by the water temperature detection sensor 20.

  In this example, it is detected whether the water temperature TH2 of the hot water HW supplied from the hot water supply device 4 has reached a predetermined mist ejection compatible temperature, for example, 30 ° C., and when the water temperature TH 2 reaches, for example, 30 ° C., Judged to have returned to a water temperature suitable for eruption.

  Step SD5: When the water temperature TH2 from the hot water supply device 4 detected by the water temperature detection sensor 20 is less than, for example, 30 ° C., the mist control unit 7 of the mist generating device 2 measures the time t and performs a predetermined hot water supply device abnormality detection time. Determine whether has passed.

  In this example, when the temperature of the hot water supply decreases, in order to determine whether or not an abnormality has occurred in the hot water supply device, for example, drainage is performed for 3 minutes to monitor the water temperature.

  Step SD6: The mist control unit 7 of the mist generating device 2 does not increase the water temperature TH2 to a predetermined value suitable for mist ejection even if a predetermined hot water supply device abnormality detection time (for example, 3 minutes) elapses after the drainage is started. In this case, it is determined that an abnormality has occurred in the hot water supply device 4 and the error lamp 77 of the mist operation unit 5 is turned on.

  Here, in the state where the error lamp 77 is lit in the mist operation unit 5, as described above, it is informed to a bather or the like that some abnormality has occurred on the hot water supply device 4 side. .

  Step SD7: When the mist control section 7 of the mist generating device 2 determines that an abnormality has occurred in the hot water supply device 4, the hot water supply switching electromagnetic valve 19c is opened and the hot water supply switching electromagnetic valve 19a is closed to stop hot water supply. .

  Step SD8: The mist control unit 7 of the mist generator 2 closes the hot water supply switching electromagnetic valve 19a and then opens the supply switching electromagnetic valve 19b. As a result, as shown in FIG. 5A, the side of the supply pipe 17 connected to the nozzle unit 2 </ b> A is opened to the atmosphere, so the remaining water RW in the supply pipe 17 flows to the drain pipe 18. And drained from the drain pipe 15c.

  Step SD9: The mist controller 7 of the mist generator 2 stands by for a predetermined time (for example, 3 seconds) set according to the time required for draining the residual water RW.

  Step SD10: The mist controller 7 of the mist generator 2 closes the supply switching electromagnetic valve 19b after a predetermined time set according to the time required for draining the residual water RW.

  Step SD11: The mist control unit 7 of the mist generator 2 closes the drain switching electromagnetic valve 19c after closing the supply switching electromagnetic valve 19b. Thereby, in the mist generator 2, the state which does not make residual water retain in the flow path downstream from the hot water supply switching electromagnetic valve 19a is shifted to the in-error process.

  In the in-error processing, for example, the mist control unit 7 of the mist generator 2 transmits an error command to the main control unit 8 of the bathroom air conditioner 3 to stop the heating operation.

  Step SD12: When the water temperature TH2 from the hot water supply device 4 detected by the water temperature detection sensor 20 in step SD4 described above reaches the mist ejection compatible temperature, for example, 30 ° C., the mist control unit 7 of the mist generating device 2 ejects the mist. The buzzer is sounded for one second, for example, in order to notify that the water temperature has returned to a suitable temperature and to reinject the mist.

  Step SD13: The mist control unit 7 of the mist generating device 2 opens the supply switching electromagnetic valve 19b to eject mist.

  Step SD14: The mist control unit 7 of the mist generator 2 opens the supply switching electromagnetic valve 19b and then closes the drainage switching electromagnetic valve 19c. Thereby, the hot water HW of the predetermined temperature supplied from the hot water supply device 4 is supplied to the nozzle unit 2A, and the mist M is re-injected by the nozzle unit 2A.

  Step SD15: The mist control unit of the mist generating device 2 switches the mist operation lamp 75 of the mist operation unit 5 from blinking to lighting.

  Here, in the state where the mist operation lamp 75 is lit in the mist operation unit 5, as described above, the bather or the like in the bathroom 101 is notified that the mist is ejected in the mist mode. ing.

  FIG. 16 is a flowchart showing an example of the high-temperature standby operation. Next, a flow of standby processing when the hot water supply temperature from the hot water supply device 4 rises will be described.

  Step SE1: The mist control unit 7 of the mist generating device 2 switches the mist operation lamp 75 of the mist operation unit 5 from lighting to blinking in order to notify that the ejection of the mist M is temporarily stopped in the high temperature standby operation. In addition, you may use the alert | report by a buzzer together.

  Step SE2: The mist control unit 7 of the mist generating device 2 closes the supply switching electromagnetic valve 19b in order to stop the ejection of the mist M.

  Step SE3: The mist control unit 7 of the mist generating device 2 opens the drainage switching electromagnetic valve 19b after closing the supply switching electromagnetic valve 19b. Thereby, the ejection of mist is stopped and the drainage operation is performed, and the high temperature standby operation for continuing the hot water supply from the hot water supply device 4 is started.

  Step SE4: When the high temperature standby operation is started, the mist control unit 7 of the mist generating device 2 detects the water temperature TH2 of the hot water HW supplied from the hot water supply device 4 by the water temperature detection sensor 20.

  In this example, it is detected whether the water temperature TH2 of the hot water HW supplied from the hot water supply device 4 has decreased to a predetermined upper limit temperature, for example, less than 60 ° C., and when the water temperature TH2 has decreased to, for example, less than 60 ° C. Judged to have returned to a water temperature suitable for eruption.

  Step SE5: The mist control unit 7 of the mist generating device 2 measures the time t when the water temperature TH2 from the hot water supply device 4 detected by the water temperature detection sensor 20 is, for example, 60 ° C. or more, and performs a predetermined hot water supply device abnormality detection time. Determine whether has passed.

  In this example, in order to determine whether or not an abnormality has occurred in the hot water supply apparatus when the hot water supply temperature rises, for example, drainage is performed for 3 minutes to monitor the water temperature.

  Step SE6: The mist control unit 7 of the mist generating device 2 does not lower the water temperature TH2 to a predetermined value suitable for mist ejection even if a predetermined hot water supply device abnormality detection time (for example, 3 minutes) elapses after the drainage is started. In this case, it is determined that an abnormality has occurred in the hot water supply device 4 and the error lamp 77 of the mist operation unit 5 is turned on.

  Here, in the state where the error lamp 77 is lit in the mist operation unit 5, as described above, it is informed to a bather or the like that some abnormality has occurred on the hot water supply device 4 side. .

  Step SE7: When the mist control unit 7 of the mist generating device 2 determines that an abnormality has occurred in the hot water supply device 4, in order to stop the hot water supply, the drainage switching electromagnetic valve 19c is opened and the hot water supply switching electromagnetic valve 19a is closed. .

  Step SE8: The mist control unit 7 of the mist generator 2 closes the hot water supply switching electromagnetic valve 19a, and then opens the supply switching electromagnetic valve 19b. As a result, as shown in FIG. 5A, the side of the supply pipe 17 connected to the nozzle unit 2 </ b> A is opened to the atmosphere, so the remaining water RW in the supply pipe 17 flows to the drain pipe 18. And drained from the drain pipe 15c.

  Step SE9: The mist control unit 7 of the mist generator 2 stands by for a predetermined time (for example, 3 seconds) set according to the time required for draining the residual water RW.

  Step SE10: The mist control unit 7 of the mist generator 2 closes the supply switching electromagnetic valve 19b after a predetermined time set according to the time required for draining the residual water RW.

  Step SE11: The mist control unit 7 of the mist generating device 2 closes the drain switching electromagnetic valve 19c after closing the supply switching electromagnetic valve 19b. Thereby, in the mist generator 2, the state which does not make residual water retain in the flow path downstream from the hot water supply switching electromagnetic valve 19a is shifted to the in-error process.

  In the in-error processing, for example, the mist control unit 7 of the mist generator 2 transmits an error command to the main control unit 8 of the bathroom air conditioner 3 to stop the heating operation.

  Step SE12: When the water temperature TH2 from the hot water supply device 4 detected by the water temperature detection sensor 20 in step SE4 described above decreases to, for example, less than 60 ° C., the mist control unit 7 of the mist generating device 2 sets the water temperature suitable for mist ejection. A buzzer is sounded for one second, for example, in order to notify that the mist has been returned and to re-eject the mist.

  Step SE13: The mist control unit 7 of the mist generator 2 opens the supply switching electromagnetic valve 19b in order to eject mist.

  Step SE14: The mist control unit 7 of the mist generator 2 opens the supply switching electromagnetic valve 19b and then closes the drainage switching electromagnetic valve 19c. Thereby, the hot water HW of the predetermined temperature supplied from the hot water supply device 4 is supplied to the nozzle unit 2A, and the mist M is re-injected by the nozzle unit 2A.

  Step SE15: The mist control unit of the mist generating device 2 switches the mist operation lamp 75 of the mist operation unit 5 from blinking to lighting.

  Here, in the state where the mist operation lamp 75 is lit in the mist operation unit 5, as described above, the bather or the like in the bathroom 101 is notified that the mist is ejected in the mist mode. ing.

  FIG. 17 is a flowchart showing an example of an error notification process in the mist mode executed in the bathroom air conditioning system 1A of the present embodiment. Next, an example of the notification process according to the error source will be described.

  Step SF1: The mist control unit 7 of the mist generator 2 detects the presence or absence of an abnormality from the output of the water temperature detection sensor 20 or the like.

  Step SF2: When the mist control unit 7 of the mist generator 2 determines that an abnormality has occurred from the output of the water temperature detection sensor 20, the mist of the mist generator 2, the bathroom air conditioner 3, etc. It is determined whether the error has occurred on the machine side or the error has occurred on the hot water supply apparatus 4 side, such as an abnormality in the hot water supply temperature, as described above.

  Step SF3: When the mist control unit 7 of the mist generating device 2 determines that the error generation source is the mist machine side, the error lamp 77 of the mist operating unit 5 blinks. Here, errors that occur on the mist machine side include abnormal output of each sensor, such as the temperature not being normally detected, or when an error command is transmitted from the bathroom air conditioner 3.

  Step SF4: When the mist control unit 7 of the mist generating device 2 determines that the error generation source is the hot water supply device 4 side, the error lamp 77 of the mist operating unit 5 is turned on as described above. Here, the error that occurs on the side of the hot water supply device 4 includes the case where the hot water supply temperature is too high or too low as described above, the case where hot water supply is not performed, or the like.

  As described above, in the bathroom air-conditioning system 1A according to the present embodiment, whether or not there is an abnormality in the hot water supply device 4 is determined according to the temperature of the hot water supplied from the hot water supply device 4. An abnormality of the hot water supply device 4 can be detected without providing a configuration for performing communication.

  Further, since the error lamp 77 of the mist operation unit 5 notifies the abnormality of the hot water supply device 4, the user can be made aware that an abnormality has occurred in the hot water supply device 4.

  Furthermore, by switching the display form of the error lamp 66 based on an error that has occurred on the mist machine side and an error that has occurred on the hot water supply apparatus 4 side, it is possible to distinguish and notify the user of the device in which an abnormality has occurred.

  In this embodiment, in order to detect the presence or absence of abnormality of the hot water supply device 4 from the water temperature, the water temperature detection sensor is provided as the hot water supply state detection means. However, the water pressure detection sensor is provided with a sensor that detects the water pressure as the hot water supply state detection means. The presence or absence of an abnormality in the hot water supply device 4 may be detected from the change in.

  The present invention is applied to an air conditioning system that performs humidification heating such as in a bathroom or a shower room.

It is a block diagram which shows an example of the bathroom air conditioning system of this Embodiment. It is a block diagram which shows an example of the nozzle unit which comprises a mist generator. It is a block diagram which shows an example of the valve unit which comprises a mist generator. It is operation | movement explanatory drawing of a valve unit. It is operation | movement explanatory drawing of a valve unit. It is sectional drawing which shows the structural example and operation example of a bathroom air conditioner. It is the perspective view which looked at the bathroom air conditioner from the lower surface side. It is a block diagram which shows the outline | summary and connection form of a hot water supply apparatus. It is a functional block diagram which shows an example of the control system of the bathroom air conditioning system of this Embodiment. It is a block diagram which shows an example of a mist operation part. It is a block diagram which shows an example of the main operation part. It is a flowchart which shows an example of the mist mode performed with the bathroom air conditioning system of this Embodiment. It is a flowchart which shows an example of drainage driving | operation. It is a flowchart which shows an example of the standby process during mist mode driving | operation. It is a flowchart which shows an example of a low-temperature standby operation. It is a flowchart which shows an example of a high temperature standby operation. It is a flowchart which shows an example of the process at the time of the error in mist mode driving | operation.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1A ... Bathroom air conditioning system, 2 ... Mist generator, 2A ... Nozzle unit, 2B ... Valve unit, 3 ... Bathroom air conditioner, 4 ... Hot water supply device, 5 ... Mist Operation unit, 6 ... main operation unit, 7 ... mist control unit, 8 ... main control unit, 11 ... mist nozzle, 15c ... drain pipe, 19a ... hot water supply switching solenoid valve, 19b ... Supply switching solenoid valve, 19c ... Drainage switching solenoid valve, 20 ... Water temperature detection sensor, 31 ... Temperature detection sensor, 32 ... Fan part, 33 ... Heater part, 71 ..Mist operation selection button, 75 ... Mist operation lamp, 81 ... Heating operation selection button, 81a ... Mist operation lamp, 101 ... Bathroom, 102 ... Washing room

Claims (2)

In a hot water jet air conditioning system equipped with a hot water jetting device that receives hot water or water from a hot water supply device and jets it as a mist,
The hot water jetting device is
A water temperature detection sensor for detecting the temperature of hot water or water supplied from the hot water supply device;
The hot water supplied from the hot water supply device detected by the water temperature detection sensor or the water temperature of the water is determined based on whether there is an abnormality in the hot water supply device, and whether there is an abnormality occurring on the system side from the state on the system side. A control means for judging is provided on the system side ,
Notifying the user that the abnormality of the hot water supply device has been detected by the control means, and notifying the user that the abnormality of the system side has been detected by the control means, distinct from the abnormality occurring in the hot water supply device. Provide notification means in the operation means on the system side ,
The control means performs a comparison between the water temperature detected by the water temperature detection sensor and a preset lower ejection limit and ejection upper limit.
If the detected water temperature is less than the lower limit of ejection or exceeds the upper limit of ejection, and continues for a predetermined time or longer, a standby operation is performed to monitor the water temperature,
When the temperature is equal to or higher than the installation temperature even after a predetermined detection time has elapsed, it is determined that the hot water supply device is abnormal, and the user is notified by the notification means in distinction from the fact that a system-side abnormality has been detected. A hot water jet air conditioning system. An air conditioner that at least performs a heating operation for heating a bathroom in which mist is ejected by the hot water jetting device;
The operation means for selecting a mist mode for interlocking heating operation by the air conditioner and ejection of mist by the hot water spray device is installed in the bathroom,
When an abnormality is notified by the notification means provided in the operation means, the hot water jetting device and the air conditioner are stopped, and the notification means provided in the operation means is generated in the hot water supply device. 2. The hot water jet air conditioning system according to claim 1 , wherein the abnormality and the abnormality occurring on the system side are distinguished and notified by lighting and blinking of the display lamp .

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