JP2006284030A - Bath device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bath device capable of preventing unnecessary irradiation of ultraviolet ray, elongating service life of a lamp, and providing bathing with clean hot water for a long period. <P>SOLUTION: This bath device is provided with a photo-cleaning device S exercising antiseptic action by irradiation of ultraviolet ray on a circulation passage 29 for keeping heat in which bath hot water 4 is circulated. An ultraviolet ray lamp 66 of the photo-cleaning device S is switched on when a circulation pump of the circulation passage 29 for keeping heat, is switched on. After the circulation pump 38 is stopped, the irradiation of ultraviolet ray by the photo-cleaning device S is continued for a prescribed time. The photo-cleaning device S has a photocatalyst support 67. A photo-cleaning signal is transmitted from a remote controller for operation. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a bath apparatus.

  When bathing at home, I want to take the so-called first bath, which is clean water. For this reason, in recent years, an optical clean device (bath sterilizer) that disinfects and purifies hot water from a bathtub and returns it to the bathtub may be disposed (see, for example, Patent Document 1). As shown in FIG. 5, the optical clean apparatus includes a sterilization tank 91, a plurality of photocatalyst carriers 92... Filled in the sterilization tank 91, and a photocatalyst carrier 92. And an ultraviolet lamp 93 for irradiating.

  The sterilization tank 91 is provided with an inflow nozzle 94 and an outflow nozzle 95, the bathtub 96 and the inflow nozzle 94 are connected by a first pipe 97, and the bathtub 96 and the outflow nozzle 95 are connected by a second pipe 98. It is connected. For this reason, a circulation path 99 is formed in which hot water is led out from the bathtub 96 and returned to the bathtub 96. That is, when the circulation pump (not shown) is driven, the hot water in the bathtub 96 enters the sterilization tank 91 from the inflow nozzle 94 via the first pipe 97, flows in the sterilization tank 91, and flows from the outflow nozzle 95 to the first. It returns to the bathtub 96 through 2 piping 98.

When irradiated with ultraviolet rays, the photocatalyst is excited by the ultraviolet rays and exhibits sterilizing power. For this reason, when hot water flows through the sterilization tank 91, the photocatalyst carrier 92 .... is irradiated with ultraviolet rays, so that the photocatalyst carrier 92 .. The sterilized hot water is returned to the bathtub 96.
JP 2000-217991 A

  However, in the optical clean apparatus described in Patent Document 1, the ultraviolet lamp 93 is irradiated when the bath water is circulated. For this reason, the lifetime of the lamp is reduced due to the continuous irradiation of ultraviolet rays, and the irradiation power is lost due to unnecessary irradiation of ultraviolet rays.

  The present invention has been made to solve the above-mentioned conventional drawbacks, and its purpose is to avoid unnecessary irradiation of ultraviolet rays, to extend the lamp life, and to bathe clean hot water over a long period of time. It is in providing the bath apparatus which can do.

  Accordingly, the bath apparatus of claim 1 is a bath apparatus in which the light clean device S that exhibits a sterilizing action by ultraviolet irradiation is disposed in the heat retaining circuit 29 through which the bath water 4 circulates. The UV lamp 66 of the optical clean device S is turned ON when the circulation pump is turned ON.

  The bath apparatus according to claim 2 is a bath apparatus in which an optical clean device S that exhibits a sterilizing action by ultraviolet irradiation is disposed in a heat-retaining circulation path 29 through which the bath water 4 circulates, and light is transmitted from a remote controller for operation. A clean signal is transmitted, and the ultraviolet lamp 66 of the optical clean device S is turned on when the circulation pump 38 of the heat retaining circuit 29 is turned on.

  The bath apparatus according to claim 3 is characterized in that the ultraviolet ray irradiation of the optical clean device S is continued for a predetermined time after the circulation pump 38 is stopped.

  The bath apparatus according to claim 4 is a bath apparatus in which an optical clean apparatus S that exhibits a sterilizing action when irradiated with ultraviolet rays is disposed in a heat insulation circulation path 29 through which the bath water 4 circulates, and the optical clean apparatus S is a photocatalyst. It has a carrier 67, and is characterized by starting the ultraviolet irradiation of the optical clean device S by transmitting a pump drive signal, and then starting to drive the circulation pump 38 of the heat retaining circuit 29.

  The bath apparatus according to claim 5 is a bath apparatus in which an optical clean apparatus S that exhibits a sterilizing action when irradiated with ultraviolet rays is disposed in a heat insulation circulation path 29 through which bath water circulates, and the optical clean apparatus S is supported by a photocatalyst. It has a body 67, and when the pump drive signal is transmitted, the ultraviolet ray irradiation of the optical clean device S and the driving of the circulation pump 38 of the heat retaining circuit 29 are started simultaneously.

  According to the bath apparatus of claim 1, since the ultraviolet lamp of the light clean device is turned on by turning on the circulation pump of the heat retaining circuit, in this state, the sterilization (cleaning of the bath water by the light clean device) Sterilization) operation works. For this reason, the bath water becomes clean hot water, and the bather can take a bath in the so-called first bath feeling. In addition, during the non-warming operation in which the circulation pump is not driven, irradiation of the ultraviolet lamp is stopped, and unnecessary irradiation can be prevented. For this reason, the lifetime of the ultraviolet lamp can be extended, the power consumption can be reduced and the cost can be reduced, and clean bathing of hot water can be performed over a long period of time.

  According to the bath apparatus of claim 2, when the optical clean signal is transmitted from the remote controller for operation, and the circulation pump of the heat retaining circuit is turned on, the ultraviolet lamp of the optical clean apparatus is turned on. Therefore, if the user wants to perform sterilization (sterilization) operation, by operating the remote control and sending a light clean signal, the bath water can be made into clean water, You can take a bath as if you were taking a bath. Moreover, if the optical clean signal is not transmitted, the ultraviolet lamp will not be turned on. Furthermore, if the circulation pump is not turned on, the ultraviolet lamp will not be turned on. Unnecessary irradiation can be avoided. For this reason, like the bath apparatus of the said Claim 1, while being able to prolong the lifetime of an ultraviolet lamp, reduction of power consumption can be achieved and cost reduction can be achieved, and bathing of clean hot water over a long period of time becomes possible.

  According to the bath apparatus of claim 3, since the ultraviolet irradiation of the optical clean device is continued for a predetermined time after the circulation pump is stopped, the flow of bath water due to inertia when the circulation pump is stopped, Ultraviolet rays can be irradiated for a predetermined time. For this reason, the bactericidal action by ultraviolet irradiation can be exhibited efficiently.

  According to the bath apparatus of the fourth aspect, in the optical clean apparatus, there are a bactericidal action by ultraviolet irradiation and a bactericidal action by a photocatalytic action, and an organic substance decomposing power can be exhibited. For this reason, this optical clean apparatus can exhibit the outstanding bactericidal action and organic substance decomposition | disassembly effect | action. Further, when the optical clean device is irradiated with ultraviolet rays, the photocatalyst carrier is irradiated with ultraviolet rays, thereby generating OH radicals on the surface of the photocatalyst carrier. Thereafter, since the driving of the circulation pump in the heat retention circuit starts, the generated OH radicals flow out to the piping constituting the heat retention circuit, and the inside of the piping is sterilized (sterilized) by this photocatalytic action. . For this reason, in this bath apparatus, the outstanding hygiene as the whole apparatus is securable.

  According to the bath apparatus of claim 5, when the pump driving signal is transmitted, the ultraviolet irradiation of the optical clean device and the driving of the circulation pump of the heat-retention circuit are started simultaneously, so that unnecessary irradiation of ultraviolet rays is performed. Can be avoided. For this reason, like the bath apparatus of the said Claim 1, while being able to prolong the lifetime of an ultraviolet lamp, reduction of power consumption can be achieved and cost reduction can be achieved, and bathing of clean hot water over a long period of time becomes possible. In addition, in the optical clean device, there are a sterilizing effect by ultraviolet irradiation and a sterilizing effect by photocatalytic action, and an organic substance decomposing ability can also be exhibited. For this reason, the sterilization effect | action and organic substance decomposition | disassembly effect | action which were excellent with the optical clean apparatus similarly to the said bath apparatus of the said Claim 4 can be exhibited.

  Next, specific embodiments of the bath apparatus of the present invention will be described in detail with reference to the drawings. FIG. 1 shows a simplified diagram of this bath apparatus, and a heat pump type hot water heater is used for this bath apparatus. The heat pump type water heater includes a tank unit (hot water storage unit) 1 and a heat source unit (heat pump unit) 2, and heats water (hot water) in the tank unit 1 by the heat pump unit 2.

  The tank unit 1 includes a hot water storage tank 3 and supplies hot water stored in the hot water storage tank 3 to the bathtub 4 and the like. That is, the hot water storage tank 3 is provided with a water supply port 5, a drain port 6, and a water intake port 7 on the bottom wall, and has a hot water inlet 8, a hot water outlet 9, and a hot water outlet 10 on the upper wall. A hot water return port 11 is provided. The intake port 7 and the hot water inlet 8 are connected via a heating circuit 12 for returning the hot water heated by the heat pump unit 2 to the hot water storage tank 3, and the hot water outlet 10 and the hot water return port. 11 is connected via a bath circulation path 13 for keeping hot water in the bathtub 4. A water supply pipe 14 is connected to the water supply port 5, and a drainage pipe 15 is connected to the drainage port 6. A hot water supply pipe 16 is connected to the hot water outlet 9, a mixing valve 17 is interposed in the hot water supply pipe 16, and a main water supply pipe 18 is connected to the mixing valve 17. The hot water supply pipe 16 is provided with a valve 19 that allows inflow into the mixing valve 17, and the water supply main pipe 18 is provided with a valve 20 that allows inflow into the mixing valve 17. That is, the hot water from the hot water storage tank 3 and the tap water from the main water supply pipe 18 are mixed by the mixing valve 17 to become the appropriate temperature water, and this appropriate temperature water is supplied to the shower or the like via the FLS 39.

  A hot water filling pipe 21 for supplying hot water to the bathtub 4 (hot water supply) and a drain pipe 22 are connected to the hot water supply pipe 16, and a mixing valve 23 is interposed in the hot water filling pipe 21. The hot water filling pipe 21 is provided with a valve 24 that allows inflow into the mixing valve 23. The hot water filling pipe 21 includes a first pipe 21a and a second pipe 21b. The valve 24 is provided in the first pipe 21a, and an open / close valve 25, a drain valve 26, an FLS 27, and a valve 28 are interposed in the second pipe 21b. The second pipe 21b is connected to a heat retaining circuit 29 through which hot water in the bathtub 4 circulates. An optical clean device S is interposed in the heat retaining circulation path 29. A drainage pipe 33 is connected to the drain valve 26.

  The heat retaining circulation path 29 includes a first pipe 31 and a second pipe 32 connected to the connection adapter 30 of the bathtub 4. The first pipe 31 is connected to the hot water inlet 74 (see FIG. 3) of the optical clean apparatus S, and the second pipe 32 is connected to the hot water outlet 75 (see FIG. 3) of the optical clean apparatus S. The second pipe 32 includes a first flow path 36 that is closer to the bathtub 4 than the merging portion 35 of the second pipe 21 b and a second flow path 37 that is closer to the optical clean device S than the merging section 35. A circulation pump 38 is interposed in the first flow path 36.

  For this reason, if the on-off valve 25 is closed and the circulation pump 38 is driven, the hot water in the bathtub 4 flows out into the first pipe 31, and the optical clean device S enters the second pipe 32 through the second pipe 32. Return to bathtub 4. That is, the hot water in the bathtub 4 circulates in the circulation path 29. The solid line arrow in FIG. 1 indicates the flowing direction of hot water during the circulation.

  When the on-off valve 25 is opened, hot water from the hot water storage tank 3 is discharged from the hot water outlet 9 and enters the circulation path 29 via the hot water filling pipe 21, and from the junction 35 to the first flow path 36 and Enters the second flow path 37 and enters the bathtub 4 from the first flow path 36. Further, the second pipe 37 enters the first pipe 31 through the optical clean device S, and enters the bathtub 4 from the first pipe 31. That is, when hot water is supplied to the bathtub 4, the hot water is supplied to the bathtub 4 via the first pipe 31 and the second pipe 32. The dotted line arrows in FIG. 1 indicate the flowing direction of hot water in this state.

  By the way, a heat exchange path 40 is interposed in the second pipe 32 of the heat retaining circuit 29. That is, a heat exchanger 41 and a circulation pump 42 are interposed in the bath circulation path 13, and when the circulation pump 42 is driven, hot water from the hot water storage tank 3 is transferred from the hot water outlet 10 to the circulation path 13. Flows out through the circulation path 13 and returns to the hot water storage tank 3 from the hot water return port 11. For this reason, heat exchange between the hot water flowing through the heat exchanging path 40 and the hot water in the bathtub 4 circulating through the heat retaining circulation path 29 is performed, and a heat retaining operation in which the hot water in the bathtub 4 is warmed can be performed. Further, a water flow switch 44, a hot water temperature detector (thermistor) 45, and a water level sensor 46 are arranged in the first pipe 31 of the heat retaining circuit 29, and are connected to the second pipe 21 b of the hot water filling pipe 21. A temperature detector (thermistor) 47 for detecting the hot water temperature when the hot water is filled is arranged.

  The water supply main pipe 18 is provided with an open / close valve 48 and a valve 49 that allows water supply from the water supply source only to the open / close valve 48, and the water pipe branched from the water supply main pipe 18. 14 is provided with a valve 50 that allows water supply from the water supply main pipe 18 only to the water supply port 5 side.

  Next, the heat pump unit 2 will be described. The heat pump unit 2 includes a refrigeration cycle R. The refrigeration cycle R includes a compressor 51, a water heat exchanger 53 that constitutes a heat exchange path 52, and a pressure reducing mechanism ( An electric expansion valve) 54 and an air heat exchanger 55 are connected in order. The circulation path 12 includes a first circulation path 12 a having a heat exchange path 52 and a second circulation path 12 b for returning hot water (heated water) from the first circulation path 12 a to the hot water storage tank 3. Have. One end of the first circulation path 12 a is connected to the water intake 7, and the other end is connected to one end of the second circulation path 12 b via the switching valve 56. The other end of the second circulation path 12 b is connected to the hot water inlet 8. The first circulation path 12a is provided with a water circulation pump 57 and on-off valves 58 and 59, and the second circulation path 12b detects the temperature of hot water in the second circulation path 12b to increase the temperature. A temperature detector 60 is provided for preventing overshoot. The switching valve 56 is connected to a drain pipe 62 having an open / close valve 61 interposed therebetween.

  Accordingly, if the switching valve 56 is switched to connect the first circulation path 12a and the second circulation path 12b and the water circulation pump 57 is driven, the hot water flowing out from the water intake 7 circulates in this circulation path 12. The hot water can be returned from the hot water inlet 8 to the hot water storage tank 3. For this reason, while driving the compressor 51, the water circulation pump 57 is driven (actuated). Then, stored water (hot water) flows out from the water intake 7 provided at the bottom of the hot water storage tank 3, and this flows through the heat exchange path 52 of the circulation path 12. Further, the refrigerant discharged from the compressor 51 returns to the compressor 51 via the water heat exchanger 53, the decompression mechanism 54, and the air heat exchanger 55 in order. Therefore, hot water flowing through the heat exchange path 52 of the circulation path 12 is heated by the water heat exchanger 53. For this reason, the heated hot water is returned from the hot water inlet 8 to the upper part of the hot water storage tank 3. By continuously performing such an operation, a boiling operation in which hot water is stored in the hot water storage tank 3 is performed. In addition, temperature detectors (remaining hot water thermistors) 63a, 63b, 63c, and 63d are disposed on the side wall of the hot water storage tank 3 to measure the temperature of the hot water in the hot water storage tank 3.

  Next, the optical clean device S will be described. As shown in FIGS. 3 and 4, the optical clean device S includes a casing 65, an ultraviolet lamp 66 inserted into the casing 65, and a plurality of bead-like shapes arranged so as to cover the outer periphery of the ultraviolet lamp 66. A single photocatalyst carrier 67... Is provided.

  The casing 65 is made of a metal such as stainless steel, and has a cylindrical casing main body 68, a first lid 69 that closes one end side opening of the casing main body 68, and a second lid that closes the other end side opening of the casing main body 68. 70, a first joint 71 to which the first pipe 31 of the heat retaining circuit 29 is connected is attached to the first lid 69, and a support for supporting the ultraviolet lamp 66 is supported to the second lid 70. A cylinder 73 is attached. Further, as shown in FIG. 4, a second joint 72 is attached to the other end opening side of the peripheral wall of the casing body 68, and the first flow of the second pipe 32 of the heat retaining circuit 29 is attached to the second joint 72. It is connected to the path 37. The casing main body 68 includes a first cylindrical body 68a and a second cylindrical body 68b, and a band member 85 made of an elastic member such as rubber is externally fitted so as to cover the joint portion.

  In this case, the first joint 71 constitutes the hot water inlet 74 of the optical clean device S, and the second joint 72 constitutes the hot water outlet 75 of the optical clean device S. For this reason, the hot water inlet 74 opens along the axial direction of the casing 65, and the hot water outlet 75 opens in a direction orthogonal to the axial direction of the casing 65. Note that when the hot water in the bathtub 4 is kept warm in the heat-retention circulation path 29, the hot water enters the casing 65 from the hot water inlet 74 and flows out of the hot water outlet 75 from the casing 65. Conversely, hot water enters the casing 65 from the hot water outlet 75 and flows out of the hot water inlet 74 from the casing 65.

  Further, the ultraviolet lamp 66 has a rod-like light emitter 76 disposed along the axial center of the casing 65, and the tip surface of the tip portion 66a is rounded with a convex spherical surface. The light emitter 76 includes a main body portion 76a and a glass portion 76b that covers the main body portion 76a. Ultraviolet rays are irradiated radially from the light emitter 76 toward the first lid body 69 from the front end portion 66a.

  The photocatalyst carrying body 67 is a silica gel carrying a photocatalyst, and is a sphere as a whole. As the photocatalyst, titanium oxide, zinc oxide, or the like can be used. When the photocatalyst is irradiated with ultraviolet rays, OH radicals are generated by the ultraviolet rays, thereby exhibiting sterilizing power and also exhibiting organic matter decomposing power. Silica gel is excellent in adsorptivity and is preferable for a photocatalyst support, has high ultraviolet light permeability, and is excellent in bacteria adsorption. In addition, as a magnitude | size of the photocatalyst carrier 67, a diameter shall be about 6 mm-10 mm, for example.

  The photocatalyst carrier 67 is housed in a bag 77 and disposed on the outer periphery of the ultraviolet lamp 66. The bag body 77 is composed of a double-bottomed cylindrical body made of a metal net. For this reason, a storage chamber 80 is provided between the inner peripheral wall 78 and the outer peripheral wall 79, and a plurality of photocatalyst carriers 67 are stored in the storage chamber 80. At this time, the bag body 77 is externally fitted to the light emitter 76 such that the inner peripheral wall 78 is disposed along the outer surface of the rod-shaped light emitter 76. Thereby, the inner hot water flow path 82a in which the photocatalyst carrier 67 is disposed can be configured. A space 83 is provided between the tip 77a of the bag 77 (having a rounded shape corresponding to the tip 66a of the ultraviolet lamp 66) and the hot water inlet 74, and the bag 77 A gap 84 is formed between the outer peripheral wall 79 and the inner peripheral surface 81 of the casing body 68, and the space 83 and the gap 84 constitute an outer hot water channel 82 b in which the photocatalyst carrier 67 is not disposed. Therefore, as indicated by the arrow B in FIG. 3, the hot water that has entered the casing 65 from the hot water inlet 74 flows as indicated by the arrow C in the outer hot water flow path 82b, and as indicated by the arrow D in FIG. , And flows out from the hot water outlet 75. The mesh size of the metal mesh is preferably larger than the mesh size of the filter of the connection adapter 30 in order to prevent the suspended matter in the bathtub 4 from being clogged. Further, in order not to flow out from the bag body 77, it is necessary to make the mesh smaller than the photocatalyst carrier 67. Therefore, the hot water that has entered the casing 65 from the hot water inlet 74 also flows in the inner hot water flow path 82 a and flows out from the hot water outlet 75.

  For this reason, as shown in FIG. 1, the hot water in the bathtub 4 enters the hot water inlet 74 of the bath hot water sterilizer S and flows through the inner hot water flow channel 82a and the outer hot water flow channel 82b as shown in FIG. Spill from. At this time, the ultraviolet lamp 66 is turned on, and the photocatalyst carrier 67 accommodated in the bag body 77 is irradiated with ultraviolet rays. As a result, the photocatalyst of the photocatalyst carrier 67 can generate OH radicals by this ultraviolet ray, exhibit sterilizing power, and can also exhibit organic substance decomposing power. When the hot water flows through the inner hot water flow path 82a, the hot water comes into contact with the photocatalyst carrier 67, and the photocatalyst carrier 67 has a bead shape. Can be greatly increased. For this reason, the hot water which contacts the photocatalyst carrier 67 can be sterilized and organic matter can be efficiently decomposed, and stable sterilization and purification can be achieved. As a result, the bath water is cleaned, and the bather can always take a bath in the sense of a so-called bath. Although OH radicals also flow out to the outer hot water channel 82b, they are less than the surface of the photocatalyst carrier 67 and the vicinity thereof. For this reason, the sterilization rate and organic matter decomposition rate per one time of the hot water flowing through the inner hot water channel 82a and the outer hot water channel 82b are not so high as a whole, but the entire hot water in the bathtub 4 can be removed by circulation. Fungus and organic matter can be decomposed. A channel through which the bath water flows can be secured in the outer hot water channel 82b. For this reason, the hot water flowing through the outer hot water flow path 82b flows smoothly in the casing 65, and the burden on the circulation pump 38 can be reduced. At the time of heat retention, the flow rate per short time for heat exchange is not reduced, It can keep warm efficiently.

  In addition, since the photocatalyst carrier 67 is housed in the bag 77 made of a metal mesh, the ultraviolet light irradiated from the ultraviolet lamp 66 is diffusely reflected by hitting the metal mesh, and a large amount of ultraviolet light is photocatalyzed. Irradiation to the carrier 67 can be performed, and the sterilizing power and the organic matter decomposing power can be increased. Further, the hot water flowing in the optical clean device S hits the bag body 77, the flow is disturbed, and more organic matter comes into contact with the photocatalyst carrier 67, and the organic matter capturing property is improved. Further, since the casing 65 is formed of a cylindrical body made of metal such as stainless steel, the ultraviolet rays are reflected on the inner peripheral surface 81 of the casing 65, and the photocatalyst carrier 67 has the ultraviolet lamp 66 side and the inner peripheral surface 81 of the casing 65. Ultraviolet rays are irradiated from the side. For this reason, the photocatalytic action (sterilization action etc.) of the photocatalyst carrier 67 can be improved.

  By the way, when the hot water is filled, the hot water enters the optical clean device S from the hot water outlet 75 and flows out from the hot water inlet 74, contrary to the time of keeping warm. That is, when the hot water is filled or when the hot water in the bathtub 4 is added, the circulation pump 38 of the heat retaining circuit 29 is not driven, and the photocatalyst carrier 67 is not irradiated with ultraviolet rays from the ultraviolet lamp 66. For this reason, clean hot water from the hot water storage tank 3 flows through the optical clean device S, so that the optical clean device S can be cleaned with the clean hot water flow. Therefore, even if the photocatalyst support 67 cannot be irradiated with ultraviolet rays due to the life of the ultraviolet lamp 66 or the like, the captured organic matter is not accumulated in the optical clean device S.

  In this way, the bath water is cleaned at the time of heat retention, and the bather can take a bath in the so-called bath feeling. In addition, when filling with hot water or adding hot water, the photocatalyst carrier 67 is stopped from being irradiated with ultraviolet rays, and the optical clean device S is cleaned with a clean hot water flow. Thus, stable sterilization and purification of bath water can be achieved. That is, the bath water is cleaned at the time of heat insulation, and the optical clean device S is washed at the time of filling or adding hot water, so that the sterilization of the bath water by the photocatalytic action and the cleaning of the optical clean device S are alternately performed. be able to.

  In the bath apparatus, the light clean operation for sterilizing bath water by irradiating ultraviolet rays is controlled as shown in the time chart of FIG. In FIG. 2, the optical clean operation ON / OFF, the bath circulation pump 38 ON / OFF, the optical clean signal ON / OFF, and the bath water temperature (bath temperature) T are shown in order from the bottom. Turning on the light clean operation turns on the ultraviolet lamp 66, turning off the light clean operation turns off the ultraviolet lamp 66, and the light clean signal is a sterilization operation (light) from a remote controller for driving operation (not shown). Clean operation) command signal.

  In this case, if the hot water temperature T decreases, a heat insulation operation is performed in which the hot water is circulated through the heat insulation circuit 29. By turning on the optical clean signal, the circulation pump 38 and the ultraviolet lamp are turned on. At the same time, the optical clean operation is started. When the hot water temperature T rises to a predetermined temperature (set temperature), the circulation pump 38 is turned off and stopped. After the circulation pump 38 stops, the ultraviolet lamp 66 continues to be on for a predetermined time (for example, 15 seconds to 20 seconds), and then is turned off. This OFF state continues until the hot water temperature T is lowered and the circulation pump 38 is turned ON again. When the circulation pump 38 is turned on, the ultraviolet lamp 66 is turned on. Thereafter, the same operation is repeated to keep the temperature of the bath water. However, if the optical clean signal is in the OFF state, the ultraviolet lamp 66 remains OFF and the optical clean operation is not performed.

  In the above bath device, the UV lamp 66 of the optical clean device is turned ON when the circulation pump of the heat retaining circuit 29 is turned ON. In this state, sterilization (sterilization) is performed to clean the bath water using the optical clean device S. Driving works. For this reason, the bath water becomes clean hot water, and the bather can take a bath in the so-called first bath feeling. In addition, during the non-warming operation in which the circulation pump 38 is not driven, the irradiation of the ultraviolet lamp 66 is stopped, and unnecessary irradiation can be prevented. For this reason, the lifetime of the ultraviolet lamp 66 can be extended, the power consumption can be reduced and the cost can be reduced, and clean hot water can be bathed for a long time.

  In addition, an optical clean signal is transmitted from the remote controller for driving operation, and the ultraviolet lamp 66 of the optical clean device S is turned on when the circulation pump 38 of the heat retaining circuit 29 is turned on. When the user or the like wants to perform sterilization (sterilization) operation, the bath water can be made clean by operating the remote controller. Moreover, if the optical clean signal is not transmitted, the ultraviolet lamp 66 will not be turned on. Furthermore, if the circulation pump 38 is not turned on, the ultraviolet lamp 66 will not be turned on. Can be avoided.

  Furthermore, since the UV irradiation of the optical clean device S is continued for a predetermined time after the circulation pump 38 is stopped, the ultraviolet ray is irradiated for a predetermined time with respect to the flow of bath water due to inertia when the circulation pump 38 is stopped. Can be irradiated. For this reason, the bactericidal action by ultraviolet irradiation can be exhibited efficiently. Moreover, since the optical clean apparatus S is provided with the ultraviolet lamp 66 and the photocatalyst carrier 67, in the optical clean apparatus S, sterilization action by ultraviolet irradiation (sterilization action by ultraviolet rays) and sterilization action by photocatalysis action. In addition to the ability to decompose organic matter. For this reason, this optical clean apparatus S can exhibit an excellent sterilization effect and organic matter decomposition effect.

  By the way, the photocatalyst generates OH radicals when irradiated with ultraviolet rays. Therefore, after generating OH radicals on the surface of the photocatalyst carrier 67 by irradiating with ultraviolet rays, for example, by driving the circulation pump 38 after 30 seconds, the generated OH radicals enter the heat retaining circuit 29. You may make it flow out. When OH radicals flow out into the heat retaining circuit 29, the piping constituting the heat retaining circuit 29 can also be sterilized (sterilized) by this photocatalytic action. Thereby, the hygiene which was excellent as the whole apparatus is securable.

  Although specific embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and various modifications can be made within the scope of the present invention. For example, in the above-described embodiment, the photocleaning apparatus S has a plurality of photocatalyst carriers 67... However, since the sterilizing power is exhibited even with only ultraviolet rays, the photocatalyst carrier 67 is not provided. It may be a thing. In this case, since ultraviolet rays exhibit a high sterilizing power when the wavelength is 253.7 nm, it is preferable that the optical clean device S can irradiate ultraviolet rays having this wavelength, but it is not limited thereto. Further, the ultraviolet frequency of the ultraviolet lamp 66 in the case of having the photocatalyst carrier 67 can be arbitrarily set as long as the photocatalyst generates OH radicals when irradiated to the photocatalyst carrier 67. Furthermore, the photocatalyst carrier 67 may be disposed in the entire casing 65 without forming the outer hot water channel 82b as the optical clean device S. That is, the bag body 77 may not be provided. Further, the casing 65 is not limited to a cylindrical shape, and the photocatalyst carrier 67 can be of various shapes such as a short columnar body and a vertical body. The bath apparatus is not limited to a heat pump type hot water heater as shown in FIG. 1, that is, a water heater provided with the tank unit 1 and the heat pump unit 2, but in a bath apparatus provided with a circulation path through which hot water in a bathtub circulates. Any optical clean device S may be provided in the circulation path. That is, a supply path for supplying clean hot water to the bathtub 4 when the hot water is filled and a circulation path for keeping the hot water in the bathtub 4 at the time of heat insulation are provided independently. S may be arranged. Furthermore, the heating source may be thermal power or electricity other than the heat pump type heating source, and the hot water heated by the heating source is directly supplied to the bathtub 4 without providing the hot water storage tank 3. May be. Furthermore, as a heat exchange means in the circulation path 29, another heating source (for example, an electric heater or the like) may be used without using the hot water in the hot water storage tank 3.

It is a simplified diagram showing an embodiment of a bath device of the present invention. It is a time chart figure of optical clean operation. It is a side view shown in the partial cross section of the optical clean apparatus used for the said bath apparatus. It is an AA line expanded sectional view of the above-mentioned FIG. It is a simplified diagram of a conventional bath apparatus.

Explanation of symbols

  4 .. Bathtub, 29 ... Heat insulation circuit, 38 ... Circulation pump, 66 ... UV lamp, 67 ... Photocatalyst carrier, S ... Optical clean device

Claims (5)

  A bath device in which a light clean device (S) that exhibits a bactericidal action when irradiated with ultraviolet rays is disposed in a heat insulation circuit (29) through which bath water circulates, and the circulation pump ON of the heat insulation circuit (29) is turned ON. The bath apparatus characterized in that the ultraviolet lamp (66) of the light clean device (S) is turned on by the above.   An optical clean device (S) that exhibits a bactericidal action when irradiated with ultraviolet rays is a bath device in which a hot water circulation circuit (29) in which bath water circulates is disposed, and an optical clean signal is transmitted from a remote controller for operation. And the ultraviolet lamp (66) of the light clean device (S) is turned on when the circulation pump (38) of the heat retaining circuit (29) is turned on.   3. The bath apparatus according to claim 1, wherein after the circulation pump (38) is stopped, the UV irradiation of the optical clean device (S) is continued for a predetermined time.   An optical clean device (S) that exhibits a bactericidal action when irradiated with ultraviolet rays is a bath device in which a hot water circulation circuit (29) in which bath water circulates is disposed. The bath apparatus is characterized in that the ultraviolet irradiation is started, and thereafter the circulation pump (38) of the heat retaining circuit (29) is started to be driven.   A bath device in which a light clean device (S) that exhibits a bactericidal action when irradiated with ultraviolet rays is disposed in a heat-retaining circuit (29) through which bath water circulates, and when the pump drive signal is transmitted, A bath apparatus characterized by simultaneously starting ultraviolet irradiation of the clean apparatus (S) and driving of the circulation pump (38) of the heat retaining circuit (29).