JP5564076B2 - Filter cleaning device in bath mist generator - Google Patents

Description

  The present invention includes a mist nozzle that ejects hot water into a mist target space in a mist state, heating means that heats hot water supplied through a hot water supply path and supplies the hot water to the mist nozzle through a hot water supply path for mist, and the mist The present invention relates to a filter cleaning device in a bath mist generator configured to include a filter for filtering hot water supplied to a nozzle.

  Such a bath mist device allows a mist sauna bath to be performed in the mist target space by jetting hot water heated from the mist nozzle installed in the ceiling of the mist target space such as a bathroom in a mist shape. However, in such a bath mist device, conventionally, the filter is provided at the hot water inlet portion of the hot water supply passage (see, for example, Patent Document 1).

JP 2007-6933 A

  The bath mist device is provided with the filter so that dust contained in hot water supplied to the mist nozzle blocks a small-diameter hot water jet hole formed in the mist nozzle and the hot water jet hole is not clogged early. In the conventional configuration, the hot water supply path in the hot water supply unit is provided with the filter, so that the filter is periodically removed every time a predetermined period of use elapses. Maintenance work such as removal is necessary. That is, since hot water is filtered by the filter as the bath mist device is used, dust contained in the hot water accumulates on the upper side of the filter in the hot water flow direction. For example, every time the usage time reaches the set time, it is necessary to manually remove the filter provided in the hot water supply channel to remove the dust adhering to the filter, which is annoying for the user. It was.

  An object of the present invention is to provide a filter cleaning device in a bath mist generating device capable of removing dust deposited and deposited on a filter without troublesomeness.

The filter cleaning device in the bath mist generating apparatus according to the present invention includes a mist nozzle that ejects hot water in a mist target space in a mist state, hot water supplied through a hot water supply path, and the mist through the hot water supply path for mist. A heating means for supplying to the nozzle, and a filter for filtering the hot water supplied to the mist nozzle,
The first characteristic configuration is that a drainage channel that can discharge hot water in a state of branching from the hot water supply channel for mist is provided below the mist nozzle,
The filter is provided in a state of being located on the mist nozzle side from a branching point of the drainage channel in the hot water supply channel for mist,
Hot water supply state for stopping hot water discharge from the drainage channel and supplying hot water heated by the heating means to the mist nozzle through the hot water supply path for mist, and supply of hot water for mist from the heating means The hot water supply to the passage is stopped, and hot water in the tip side supply passage portion located on the side where the mist nozzle is present from the branch point of the drainage passage in the hot water supply passage for the mist is passed in the hot water supply state. A flow path switching means is provided that can be switched to a discharge state in which the filter passes through the filter in a direction opposite to the flow direction and is discharged from the drainage channel,
Switching control means for controlling the operation of the flow path switching means, and command means for commanding the switching control means to switch the operating state,
The flow path switching means is
Mist passage intermittent valve installed in the middle of the hot water supply channel or in the middle of the heating means side than the branch of the drainage channel in the hot water supply channel for mist, and for drainage installed in the drain Comprising a passage intermittent valve,
The switching control means is
When the mist sauna operation is commanded by the command means, a hot water supply process is performed to switch to the hot water supply state that opens the mist passage intermittent valve and closes the drain passage intermittent valve and maintains the state. Run
When the command means instructs the stop of the mist sauna operation, the waste water treatment is performed to switch to the drain state in which the mist passage intermittent valve is closed and the drain passage intermittent valve is opened. It is in the point which is comprised.

  According to the first characteristic configuration, when the flow path switching means is switched to the hot water supply state, the hot water supplied through the hot water supply path is heated by the heating means and the mist nozzle passes through the hot water supply path for mist. The hot water is ejected from the mist nozzle into the mist target space in a mist state. At that time, hot water supplied to the mist nozzle is filtered by the filter by passing through a filter provided in a state of being located on the mist nozzle side of the branch point of the drainage channel in the hot water supply channel for mist, Hot water with little dust is ejected from the mist nozzle, and a mist sauna bath can be performed in the strike target space.

  And, when hot water remains in the tip side supply path portion located on the mist nozzle existing side from the branch point of the drainage path in the hot water supply path for mist, the flow path switching means is switched to the discharge state. And hot water from the heating means to the hot water supply path for mist is stopped, and the hot water in the tip-side supply path portion located on the side where the mist nozzle is present from the branch point of the drainage path in the hot water supply path for mist Is discharged from the drainage channel. At this time, the hot water in the tip side supply path portion located on the side where the mist nozzle is present passes through the filter in the direction opposite to the hot water flow direction in the hot water supply state and is discharged from the drainage path.

  As a result, dust deposited and deposited on the upper side of the flow direction of the filter when hot water flows in the hot water supply state is removed when the hot water in the tip side supply path portion flows in the reverse direction. Drained with hot water. In this way, dust deposited on the filter can be removed simply by switching the flow path switching means to the drained state.

  Therefore, troublesome work such as removing and cleaning the filter is unnecessary, and it has become possible to provide a filter cleaning device in a bath mist generating device that can remove dust adhering to the filter without causing any trouble. .

According to the first feature , when the mist sauna operation is commanded by the command means, the switching control means opens the mist passage intermittent valve and closes the drain passage intermittent valve. The hot water supply process is performed to switch to the hot water supply state and maintain the state. By executing this hot water supply process, hot water heated by the heating means is supplied to the mist nozzle, and can be ejected from the mist nozzle to perform a mist sauna bath in the mist target space.

  Then, when the command means instructs to stop the mist sauna operation, the switching control means closes the mist passage intermittent valve and opens the drain passage intermittent valve to the drainage state. Execute wastewater treatment to switch. That is, by closing the mist passage intermittent valve, the hot water supply from the heating means to the mist hot water supply passage is stopped, and by opening the drain passage intermittent valve, The hot water remaining in the tip side supply channel located on the mist nozzle side of the drainage channel branch point in the hot water supply channel is discharged through the drainage channel and then adheres to the upper side of the filter in the flow direction. The accumulated dust is removed and drained with hot water.

Therefore, according to the first characteristic configuration, the hot water remaining in the tip-side supply path portion of the mist hot water supply path can be used by a simple operation by simply commanding the stop of the mist sauna operation by the command means. It is possible to periodically remove dust from the filter every time the mist sauna operation is performed.

The second characteristic configuration of the present invention, in addition to the first feature configuration, provided with hot-water supply path for supplying hot water heated by supplying water supply passage and the heat source apparatus of tap water as the hot water supplying passage,
The flow path switching means, provided with a hot water supply passage intermittently valve intermittently pre Symbol water water supply passage intermittently valve intermittently the supply passage and the hot water supply passage, tap water into the heat source apparatus state supplied to said heating means The hot water heated in this way can be switched to a state in which it is supplied to the heating means.

According to the second characteristic configuration, when the water supply passage intermittent valve is opened and the hot water supply passage is closed, the tap water supplied through the water supply passage is heated by the heating means and supplied to the mist nozzle. It can be used as cleaning water. Further, when the water supply passage intermittent valve is opened and the hot water supply passage is closed, the hot water heated by the heat source device supplied through the hot water supply passage is heated by the heating means and supplied to the mist nozzle, It can be used as washing water.

  For example, when the outdoor air temperature is low and the water temperature is low, mist sauna operation can be performed appropriately by using hot water heated by a heat source device, and if the washing operation is performed, By using heated hot water heated by the heating means, it becomes possible to sterilize the inside of the filter and the hot water supply hot water passage.

Overall configuration of bath mist device Configuration diagram of heat source machine Mist unit configuration diagram Explanatory drawing showing the operation of the mist unit Explanatory drawing showing the operation of the mist unit Explanatory drawing showing the operation of the mist unit Explanatory drawing showing the operation of the mist unit Flow chart of control operation Configuration diagram of mist unit of another embodiment Configuration diagram of mist unit of another embodiment

Hereinafter, embodiments of a filter cleaning apparatus in a bath mist generating apparatus according to the present invention will be described with reference to the drawings.
This bath mist device heats hot and cold water supplied through an indoor unit 3 and hot water supply passage 4 provided with a mist nozzle 2 that faces hot water in the bathroom 1 as a mist target space in a mist state. Then, a mist unit 6 that supplies the mist nozzle 2 through the mist hot water supply passage 5, a heat source device 7 that circulates and supplies a heat medium to the indoor unit 3 and the mist unit 6 and supplies hot water for hot water supply, and A mist sauna operation in which hot water is jetted in the mist state in the bathroom 1, a heating operation to heat the interior of the bathroom 1, a bathroom It is comprised so that the ventilation operation etc. which ventilate 1 may be performed.

  The indoor unit 3 is installed in a state of entering the back of the ceiling of the bathroom 1 or attached to a wall, and a mist nozzle 2 for ejecting hot water in a mist shape toward the bathroom 1 and heating means for air heating The air in the bathroom 1 is sucked through the heat exchanger 10 and the intake portion 8A of the grill plate 8 installed in a state facing the bathroom 1, and the blower with a movable louver in the grill plate 8 is passed through the heat exchanger 10. A circulation fan 11 as ventilation means for blowing air from the section 8B to the bathroom 1; a ventilation fan 12 for ventilating the air in the bathroom 1 through an exhaust passage (not shown) to the outside; and the heat exchanger 10 The heating medium interrupting valve 13 for interrupting the circulation flow of the heating medium and the indoor unit control unit H1 for controlling the operation of each part are configured.

  As shown in FIG. 2, the heat source device 7 includes a heat medium heating unit 16 including a heat medium heat exchanger 14, a burner 15 that heats the heat medium heat exchanger 14, and the like. The medium heating unit 16 heats hot water as a heat medium stored in the externally open expansion tank 17 by the heat exchanger 14 for the heat medium, and then passes through the external piping line 18 for circulating the heat medium to the indoor unit 3. In addition, a circulation pump 19 that circulates in the mist unit 6 is provided.

  In other words, the heat medium return path 20 connected to one pipe line 18 a of the external pipe line 18 is connected to the inlet side of the expansion tank 17, and the heat connected to the pipe line of the other pipe 18 b of the external pipe line 18. The medium transport path 21 is connected to the outlet side of the heat medium heat exchanger 14, and a heat medium communication path 22 is provided to connect the outlet side of the expansion tank 17 and the inlet side of the heat medium heat exchanger 14. A circulation pump 19 is provided in the middle of the medium communication path 22. Further, a bypass path 23 is provided for bypassing the heat medium flowing through the heat medium return path 21 to the heat medium return path 20, and a heat medium forward thermistor 24 for detecting the temperature of the heat medium is provided in the heat medium forward path 21. Is provided.

  The heat source unit 7 is provided with a hot water supply heating unit 27 including a burner 25 and a hot water supply heat exchanger 26 in addition to the heat medium heating unit 16, and hot water supplied through a water supply path 28 is supplied to the burner 25. Heat is exchanged by a hot water supply heat exchanger 26 heated in this manner, and hot water having a desired temperature is supplied through a hot water supply passage 29. Further, as shown in FIG. 1, the hot water is branched from the hot water supply passage 29 so as to supply hot water to the mist unit 6.

  The water supply passage 28 is provided with a water supply thermistor 30 for detecting the water supply temperature and a water amount sensor 31 for detecting the amount of water supply, and a water supply bypass passage 32 is provided so as to bypass the hot water supply heat exchanger 26. . Furthermore, in the hot water supply passage 29, a hot water supply thermistor 33 that detects the temperature of hot water from the hot water supply heat exchanger 26 and a bypass valve 34 that adjusts the amount of water from the water supply bypass passage 32 are mixed in this order from the upstream side. A hot water thermistor 35 that detects the temperature of the subsequent hot water and a water amount adjustment valve 36 that adjusts the flow rate of the hot water to a set amount are provided.

  A fuel supply passage 37 for supplying fuel gas to the burners 15 and 25 is an electromagnetically operated intermittent valve 38 for intermittently supplying fuel, and the combustion amount of each burner 15 and 25, that is, the fuel supply amount can be changed and adjusted 2. Two electromagnetically operated gas amount control valves 39 are provided, and a fan 40 for supplying combustion air to the burners 15 and 25 is also provided. Although not shown, near the burners 15 and 25, an igniter that performs an ignition operation on the burners 15 and 25 and a frame rod that detects whether or not the burners 15 and 25 are ignited are provided. ing.

  The heat source unit 7 is provided with a heat source unit control unit H2 that controls the operation of each unit. When performing a heating operation for heating the bathroom 1, a mist sauna operation for performing a mist sauna bath, etc., circulation is performed. The pump 19 is circulated so that the combustion state of the burner 15 is controlled so that the temperature of the heat medium detected by the heat medium forward thermistor 24 becomes a set target temperature (for example, 80 ° C.). .

Next, the configuration of the mist unit 6 will be described.
As shown in FIG. 1, the mist unit 6 is installed outside the side wall of the bathroom 1, and is provided in a state of being vertically spaced below the indoor unit 3. And as shown in FIG. 3, the liquid-liquid heat exchanger 42 as the heating means which heats the hot water supplied through the hot water supply channel 41 and supplies it to the mist nozzle 2 through the hot water supply channel 5 for mist, the mist nozzle And a filter 43 that filters the hot water supplied to the water 2, and is further provided with a drainage channel 44 through which the hot water can be discharged while branching from the hot water supply channel 5 for mist. The hot water supply path 5 is provided in a state of being located on the mist nozzle 2 side with respect to the branching point of the drainage path 44 in the hot water supply path 5, stops hot water discharge from the drainage path 44, and the hot water heated by the liquid-liquid heat exchanger 42 is The hot water supply state to be supplied to the mist nozzle 2 through the mist hot water supply passage 5 and the hot water supply from the liquid-liquid heat exchanger 42 to the mist hot water supply passage 5 are stopped, and the mist hot water supply is stopped. A flow path switching means K is provided that can be switched to a discharge state in which the hot water in the tip side supply path portion located on the side where the mist nozzle 2 is present is located with respect to the branch point of the drainage path 44 in the path 5. ing.

  The filter 43 has fine dust so that dust contained in the hot water supplied to the mist nozzle 2 blocks a small-diameter hot water jet hole formed in the mist nozzle 2 so that the hot water jet hole is not clogged early. The hot water is filtered so that it can be received.

  In the mist hot water supply channel 5, a detour 45 is provided to connect the upper part of the flow path with respect to the branch part of the drainage channel 44 and the lower part of the flow path with respect to the installation part of the filter 43. In the hot water supply state, the means K stops the hot water discharge from the drainage channel 44 and stops the hot water flow through the bypass 45, and the hot water heated by the liquid-liquid heat exchanger 42 is used for mist. Hot water supplied from the liquid-liquid heat exchanger 42 to the starting end of the mist hot water supply passage 5 flows to the filter 43 and the drainage passage 44. And the hot water in the downstream side of the flow path from the place where the filter 43 is installed in the hot water supply path 5 for mist is stopped from flowing to the mist nozzle 2 side, and the mist from the liquid-liquid heat exchanger 42 is stopped. Temperature The hot water supplied to the start end of the supply path 5 is guided to the hot water supply path 5 for mist through the detour 45 and can be switched to a backwashing state in which it is discharged through the drain 44 after flowing through the filter 43. ing.

Hereinafter, a specific configuration of the mist unit 6 will be described.
The mist unit 6 includes, as the hot water supply path 41, a water supply path 41a that supplies tap water and a hot water supply path 41b that supplies hot water heated by the heat source unit 7, and supplies the tap water to the liquid-liquid heat exchanger 42. It is configured to be switchable between a supply state and a state in which hot water heated by the heat source unit 7 is supplied to the liquid-liquid heat exchanger 42. The hot water supplied from either the water supply path 41a or the hot water supply path 41b is heated by the liquid-liquid heat exchanger 42 and supplied to the mist nozzle 2 through the hot water supply path 5 for mist. The drainage channel 44 is branched from the middle of the hot water supply channel 5, and the drainage channel 44 is provided with a drainage passage intermittent valve 51 that can intermittently connect the drainage channel 44. Further, a filter 43 for filtering hot water supplied to the mist nozzle 2 is provided in a state of being located on the mist nozzle 2 side with respect to the branch connection point with the drainage channel 44 in the hot water supply channel 5 for mist.

  Then, a damming intermittent valve 48 that can be intermittently connected to the liquid-liquid heat exchanger 42 side of the mist hot water supply channel 5 from the branching point with the drainage channel 44, and damming intermittentness in the mist hot water supply channel 5. A detour 45 that detours between the location on the liquid-liquid heat exchanger 42 side relative to the valve 48 location and the location on the mist nozzle 2 side relative to the location where the filter 43 is located in the hot water supply passage 5 for mist, and the detour route 45 And a bypass detour valve 49 that can be freely interrupted.

The mist hot water supply path includes a first bypass interrupt valve 49a positioned on the filter 43 side and a second bypass interrupt valve 49b positioned on the opposite side of the filter 43 as the bypass interrupt valve 49. 5, the nozzle-side intermittent valve 50 for intermittently connecting the mist nozzle 2 side location with respect to the side-by-side bypass region, and the location of the first bypass-interrupt valve 49 a and the location of the second bypass-interconnect valve 49 b in the bypass 45 A discharge communication passage 52 that communicates the intermediate position with the drainage passage intermittent valve 51 in the drainage channel 44 from the lower side in the direction of drainage, and a communication passage intermittent valve 53 that connects the discharge communication passage 52 are provided. Yes. Further, the mist hot water supply passage 5 is provided with a temperature sensor 54 for detecting the temperature of the hot water after being heated by the liquid-liquid heat exchanger 42.
Although not shown, the water supply passage 41a and the hot water supply passage 41b of the mist unit 6 are provided with strainers having coarser meshes than the filter 43, and the plurality of intermittent valves described above are provided. It avoids the passage of large dust that could be bitten and cause problems.

  Therefore, the flow path switching means K is constituted by the intermittent valves, the bypass circuit 45, the discharge communication path 52, and the like. Further, the hot water supply passage intermittent valve 100 is constituted by the water supply passage intermittent valve 46 and the hot water supply passage intermittent valve 47, and the damming intermittent valve 48 is connected to the drainage passage 44 in the mist hot water supply passage. The mist passage intermittent valve V1 installed in the middle of the liquid-liquid heat exchanger 42 side is also configured.

  The mist unit 6 is provided with a mist unit controller H3 as switching control means for controlling the operation of the flow path switching means K. The mist unit controller H3, the heat source machine controller H2, and The indoor unit control unit H1 is configured to be able to communicate information with each other via a wired or wireless communication means. The control units H1, H2, H3 and the remote control unit R are configured to be able to communicate information with each other by wireless or wired communication means, and according to the command information from the remote control unit R, the heat source unit 7, The indoor unit 3 and the mist unit 6 are controlled so as to be in corresponding operating states.

  In addition, as shown in FIG. 1, the remote control unit R has a heating switch 55 that commands the start and stop of the heating operation, a ventilation switch 56 that commands the start and stop of the ventilation operation, and the start of the mist sauna operation. And a mist sauna switch 57 for instructing a stop, a cleaning switch 58 for instructing the start of a cleaning operation to be described later, and the like.

  When the heating switch 55 of the remote control operation unit R is operated, the heat source unit control unit H2 controls the operating state of the heat source unit 7 so as to circulate and supply the heat medium having the set target temperature through the external pipe line 18, and the indoor unit Heating operation in which the control unit H1 opens the heat medium intermittent valve 13 to operate the circulation fan 12 and blows the air heated by the heat of the heat medium in the heat exchanger 10 to the bathroom 1 to heat the bathroom. Execute. In addition, when the ventilation switch 56 of the remote control operation unit R is operated, the indoor unit control unit H1 performs a ventilation operation in which the ventilation fan 12 is operated to ventilate the bathroom.

  When the mist sauna switch 57 of the remote control operation unit R is operated, the mist unit control unit H3 executes the mist sauna operation, and when the cleaning switch 58 of the remote control operation unit R is operated, the mist unit control unit H3. Is configured to perform a cleaning operation and a bypass cleaning process.

Next, a specific control operation of the mist unit controller H3 will be described below.
As shown in FIG. 4, when the mist sauna operation is instructed by the mist switch 57 of the remote control operation unit R, the mist unit control unit H3 instructs the heat source unit control unit H2 to supply the heat medium (steps 1 and 2). ). The heat source machine control unit H2 controls the combustion state of the burner 15 so that the circulation pump 13 is circulated and the temperature of the heat medium detected by the heat medium forward thermistor 24 becomes a set target temperature (for example, 80 ° C.). To do. As a result, the heat medium heated to the set target temperature is circulated and supplied to the liquid-liquid heat exchanger 42 through the external pipe line 18.

  The mist unit control unit H3 instructs the heat source unit control unit H2 to supply the heat medium, and then executes a hot water temperature rise process (step 3). That is, when the temperature of the hot water heated by the liquid-liquid heat exchanger 42 detected by the temperature sensor 54 is lower than the set temperature, the water supply passage intermittent valve 46, the damming intermittent valve 48, and the drainage passage intermittent The valve 51 is opened, the nozzle-side interrupt valve 50, the first bypass circuit interrupt valve 49a, and the second bypass circuit interrupt valve 49b are closed, and the low-temperature hot water is discharged through the drainage channel 44, and the liquid-liquid heat exchanger This state is maintained until the temperature of the hot water heated by 42 becomes equal to or higher than the set temperature.

  Then, when the temperature of the hot water heated by the liquid-liquid heat exchanger 42 is equal to or higher than the set temperature, a hot water supply process is executed (step 4). That is, the water supply passage intermittent valve 46, the damming intermittent valve 48, and the nozzle side intermittent valve 50 are opened, and the drainage passage intermittent valve 51, the first bypass bypass valve 49a, and the second bypass bypass valve 49b are closed. The hot water supply process is performed to switch to the warm water supply state to be controlled and maintain the state. By performing this hot water supply process, as shown in FIG. 5, the water supplied by the water pressure through the water supply path 41a is supplied to the liquid-liquid heat exchanger 42 through the water supply path 41a. After being heated by a high-temperature heat medium in the liquid heat exchanger 42, it is filtered by the filter 43 and supplied to the mist nozzle 2 through the mist hot water supply path 5.

  Thereafter, when the mist sauna switch 57 of the remote control operation unit R is operated again to instruct the stop of the mist sauna operation, the heat source unit control unit H2 is instructed to stop the supply of the heat medium, and the mist hot water supply path 5 The waste water treatment for draining the remaining hot water is executed (steps 5, 6, and 7). That is, a drainage state in which the interrupting interrupt valve 48, the first bypass interrupting valve 49a, and the second bypass interrupting valve 49b are closed and the drainage passage interrupting valve 51 and the nozzle side interrupting valve 50 are opened. Execute wastewater treatment to switch. By executing this drainage treatment, the remaining hot water remaining in the mist hot water supply channel 5 is drained through the drainage channel 44. At that time, as shown in FIG. 6, the hot water in the hot water supply passage 5 for mist passes through the filter 43 in the direction opposite to the flow direction in the hot water supply state and is discharged from the drainage passage 44 by natural fall. Then, the dust adhered and accumulated on the upper side in the flow direction in the hot water supply state is removed, and the filter 43 is washed. When the first set time set a little longer than the elapsed time required for draining the remaining hot water after the stop of the mist sauna operation is commanded, all the intermittent valves are closed and the drainage treatment is finished (step) 8, 9).

  When the cleaning switch 58 of the remote control operation unit R is operated in a state where the mist sauna operation is not instructed, the filter cleaning process is executed after instructing the heat source device control unit H2 to supply the heat medium (step 10). 11). That is, the hot water supply / interruption valve 47, the first bypass circuit intermittent valve 49a, the second bypass circuit intermittent valve 49b, and the drainage passage intermittent valve 51 are opened, and the water supply channel intermittent valve 46 and the weir intermittent valve 48 are opened. Then, the filter cleaning process is executed to switch to the backflow cleaning state in which the communication passage intermittent valve 53 and the nozzle side intermittent valve 50 are closed and to maintain the state until the second set time has elapsed. By performing this filter cleaning process, as shown in FIG. 7, the hot water supplied after being heated by the heat source unit 7 through the hot water supply passage 41b becomes the hot water supply passage 41b, the bypass 45, the filter 43, the drainage passage. 44 sequentially passes through the filter 43 in the direction opposite to the flow direction in the hot water supply state in the mist sauna operation, and is discharged from the drainage channel 44. The upper side in the flow direction in the hot water supply state The dust deposited and deposited on the filter 43 is removed and the filter 43 is cleaned. In addition, at that time, hot water for hot water heated in advance by the heat source device 7 is heated again by the liquid-liquid heat exchanger 42 to become hot hot water. Can be sterilized.

  When the second set time elapses after the cleaning switch 58 is operated, the filter cleaning process is terminated and the detour cleaning process is executed (steps 12 and 13). This bypass cleaning process opens the hot water supply interrupt valve 47, the damming interrupt valve 48, the first bypass interrupt valve 49a, and the communication passage disconnect valve 53, and the drain passage interrupt valve 51 and the nozzle side interrupt. The valve 50 is closed, and hot water supplied through the hot water supply passage 41aa is discharged through the filter 43, the bypass 45, the discharge communication passage 52, and the drainage passage 44. By performing this detour cleaning process, as shown in FIG. 8, the hot water flow direction is better when the cleaning operation is performed, in other words, the hot water flow direction is lower when the mist sauna operation is performed. The dust deposited and accumulated is removed, the filter is cleaned, and the inside of the detour 45 is also cleaned. When the third set time has elapsed since the execution of the detour cleaning process is started, all the intermittent valves are closed and the detour cleaning process is terminated (steps 14 and 15).

[Another embodiment]
Hereinafter, other embodiments are listed.

(1) In the above embodiment, the bypass bypass valve includes a first bypass interrupt valve located on the filter side and a second bypass interrupt valve located on the opposite side of the filter, and the bypass An intermediate position of the first bypass circuit interrupting valve disposition point and the second bypass circuit discontinuation valve disposition position in the passage 45 is communicated with a lower drainage direction portion of the drainage channel 44 than the drainage passage discontinuity valve 51. The exhaust communication passage 52 and the communication passage interrupting valve 53 that connects and disconnects the discharge communication passage 52 are exemplified, but instead of such a configuration, as shown in FIG. The bypass 45 may include one bypass interrupt valve 49 and may not include the discharge communication path 52 and the communication path disconnect valve 53. With this configuration, the detour cleaning process in the above embodiment cannot be performed.

(2) In the above embodiment, the flow path switching means K causes the hot water supplied through the hot water supply path to pass through the filter in a direction opposite to the flow direction in the hot water supply state from the drainage path. Although illustrated what can be switched to the backflow cleaning state to be discharged, instead of such a configuration, the hot water heated by the heating means is supplied to the mist nozzle through the hot water supply path for mist. A configuration that can be switched only to a supply state, and a discharge state in which hot water in the hot water supply passage for mist passes through the filter in a direction opposite to a flow direction in the hot water supply state and is discharged from the drainage passage, That is, as shown in FIG. 10, the drainage passage intermittent valve 51, the nozzle-side intermittent valve 50, the water supply passage intermittent valve 46, and the water supply passage in the embodiment are provided. Comprising a road intermittent valve 47, the dam for intermittent valve 48, may be configured not to include the bypass passage 45 and the bypass passage intermittent valve 49. In this configuration, the water supply passage intermittent valve 46 and the hot water supply passage intermittent valve 47 constitute a mist passage intermittent valve V1 installed at an intermediate position in the hot water supply passage. However, in this configuration, the filter cleaning process and the detour cleaning process in the above embodiment cannot be performed.

( 3 ) In the above embodiment, in the mist sauna operation, the tap water supplied from the water supply path is heated by the heating means and supplied to the mist nozzle. However, the hot water supply is also used in the mist sauna operation. The hot water supplied from the channel may be heated by the heating means and supplied to the mist nozzle. The tap water supplied from the water supply channel and the hot water supplied from the hot water supply channel are mixed to the heating unit. It may be heated and supplied to the mist nozzle.

( 4 ) In the above embodiment, the liquid-liquid heat exchanger is exemplified as the heating means, but it is not limited to the liquid-liquid heat exchanger, and may be a heat exchanger configured to be heated by a burner while flowing in the passage, Various heating means such as one heated by a power heater can be used.

2 Mist nozzle 5 Hot water supply path for mist 41 Hot water supply path 41a Water supply path 41b Hot water supply path 43 Filter 44 Drainage path
4 6 Water supply path intermittent valve 47 Hot water supply path intermittent valve
5 1 Discontinuous valve for drainage
K channel switching means H3 switching control means R command means V1 mist passage intermittent valve

Claims (2)

A mist nozzle that ejects hot water into the mist target space in a mist state, heating means that heats hot water supplied through the hot water supply path and supplies the hot water to the mist nozzle through the hot water supply path for mist, and is supplied to the mist nozzle A filter cleaning device in a bath mist generating device configured to include a filter for filtering hot and cold water,
A drainage channel that can freely discharge hot water in a state branched from the hot water supply channel for mist is provided below the mist nozzle,
The filter is provided in a state of being located on the mist nozzle side from a branching point of the drainage channel in the hot water supply channel for mist,
Hot water supply state for stopping hot water discharge from the drainage channel and supplying hot water heated by the heating means to the mist nozzle through the hot water supply path for mist, and supply of hot water for mist from the heating means The hot water supply to the passage is stopped, and hot water in the tip side supply passage portion located on the side where the mist nozzle is present from the branch point of the drainage passage in the hot water supply passage for the mist is passed in the hot water supply state. A flow path switching means is provided that can be switched to a discharge state in which the filter passes through the filter in a direction opposite to the flow direction and is discharged from the drainage channel,
Switching control means for controlling the operation of the flow path switching means, and command means for commanding the switching control means to switch the operating state,
The flow path switching means is
Mist passage intermittent valve installed in the middle of the hot water supply channel or in the middle of the heating means side than the branch of the drainage channel in the hot water supply channel for mist, and for drainage installed in the drain Comprising a passage intermittent valve,
The switching control means is
When the mist sauna operation is commanded by the command means, a hot water supply process is performed to switch to the hot water supply state that opens the mist passage intermittent valve and closes the drain passage intermittent valve and maintains the state. Run
When the command means instructs the stop of the mist sauna operation, the waste water treatment is performed to switch to the drain state in which the mist passage intermittent valve is closed and the drain passage intermittent valve is opened. The filter washing | cleaning apparatus in the mist generator for baths comprised. A water supply path for supplying tap water and a hot water supply path for supplying hot water heated by a heat source machine are provided as the hot water supply path,
The flow path switching means includes a water supply path interrupting valve for interrupting the water supply path and a hot water supply path interrupting valve for interrupting the hot water supply path, and a state of supplying tap water to the heating means and the heat source machine 2. The filter cleaning device in a bath mist generating apparatus according to claim 1, wherein the filter is switchable between a state in which heated hot water is supplied to the heating means.

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